 SPEED CONTROL STRUCTURE AND METHOD FOR WORK VEHICLE
专利摘要:
A work vehicle speed control structure comprising: an operational shift member (24), and a means (29) for detecting its position; an operational element of constant speed and means for detecting its position; a continuously variable speed change device and, for the latter, a position detection device; operational means for operating the operational element; and control means (31) of the operative means which determines a target shift operational position based on the positions of the constant speed operational element and an operation member of the continuously variable speed changing device and data. correlating thereto, and controls the operating means for moving the shift operation member (24) to the target position. 公开号:FR3017917A1 申请号:FR1551659 申请日:2015-02-26 公开日:2015-08-28 发明作者:Eiji Nishi;Keishiro Nishi;Atsushi Shinkai;Yasunobu Nakatani;Taichi Fujiwara 申请人:Kubota Corp; IPC主号:
专利说明:
[0001] BACKGROUND OF THE INVENTION The present invention relates to a speed control structure and the control method for a work vehicle. [0002] Such a work vehicle usually comprises, inter alia, an operational gearshift element intended to be handled by a driver, a means for detecting the operational position of the operational gearshift element, a variable gearshift device continuously receiving energy from the engine of the works vehicle; shift position detecting means for detecting the operational shift position of the continuously variable shifting device; operational means for shifting the continuously variable shifter; control means for controlling the operational means. There is a work vehicle with a mechanical servo mechanism where the servo valve controls the servo drive which controls the swashplate of a variable stroke pump from a continuously variable hydraulic speed shifter to a position which is the position of a gearshift pedal based on the position of the pedal detected by a valve control linkage and the position of the detected pump swashplate by a control wheelhouse. See for example, 3P11-91379. There is also a work vehicle with an electronic servocontrol where the control device controls the flow of a hydraulic fluid to a servo-motor for the swash plate of the pump of a variable stroke pump so that the swash plate is actuated to a position corresponding to the position that was made to a shift pedal based on the actuated position detected by the pedal sensor and the position that was taken to the swash plate, detected by a swash plate sensor. However, in the mechanical servo control mechanism or in the electronic servo control mechanism mentioned above, the swash plate is simply controlled to move to a position corresponding to the position that was made to the change pedal. of speed. Thus, the greater the difference between the position corresponding to the position that was made to the gearshift pedal and the position of the swash plate is large, the more the control delay tends to increase, resulting in a "Sensation" can be improved and making it difficult to maintain a high level of nervousness. SUMMARY OF THE INVENTION An object of the invention is to provide a speed control structure and method for a work vehicle, facilitating performance enhancement such as nervousness or sensation. According to a first aspect of the invention, the speed control structure for a construction vehicle according to the present invention comprises: an operational shift member for manipulation by a driver; means for detecting the position of the gear shift operating element; a continuously variable speed change device which receives energy from the engine of the work vehicle; shift position detecting means for detecting the operational shift position of the continuously variable shifting device; operational means for shifting the continuously variable shifter; control means for controlling the operating means, wherein the control means: (a) determines a target shift operational position based on the detected information from the actuated position detection means and predetermined correlation data, performing correlating the operated position of the shifting operational element and the shifting operational position of the continuously variable shifting device, and (b) calculating the shift between the shifting operational position of the shifter the continuously variable speed changing device and the actual gear shift operating position based on the determined target gear shift operational position and the detected information from the gear shift position detecting means, and (c) determining a target operational speed for the disp a continuously variable speed changeover apparatus based on the calculated deviation and other correlation data, effecting the correlation of the deviation with an operational speed at which the continuously variable shifter is actuated, and (d ) controls the operating means so that the continuously variable speed changeover device is actuated to the target shift operational position and the target operational speed. According to a second aspect of the invention, the speed control structure for a construction vehicle according to the present invention comprises: an operational shift element configured to automatically return to a zero speed position; means for detecting the position of the shift operation member; A constant speed operational element configured to be held in any actuated position; means for detecting the held position of the constant speed operating element; a continuously variable speed change device which receives energy from the engine of the work vehicle; shift position detecting means for detecting the position of the shifting operation of a shifting operational member of the continuously variable shifting device; Operational means for operating the shifting operational member; control means for controlling the operational means; characterized in that the control means determines a target shift operational position based on information detected by the held position detecting means and information detected by the position detecting means of the position detection means. shifting and based on correlation data correlating the held position with the operational shift position and controlling the operating means such that the shifting operational member is moved to the operational position of target speed change. According to a third aspect of the invention, for a work vehicle having an operational shift member for manipulation by a driver, means for detecting the position of the operating member of the shifting, a continuously variable shifting device which receives energy from the engine of the work vehicle; shift position detecting means for detecting the operational shift position of the continuously variable shifting device; operational means for shifting the continuously variable shifting device; a control means for controlling the operating means, the method according to the present invention for controlling the speed of such a work vehicle comprises the steps of: determining a target shift operational position based on the information detected by the means actuated position sensing device and predetermined correlation data correlating the actuated position of the shifting operational element and the operational shift position of the continuously variable shifting device; calculates the difference between the target operational shift position of the continuously variable speed changeover device and the actual gearshift operational position based on the determined target gearshift operational position and the detected information from the shift position detection; determines a target operational speed for the continuously variable speed change device, based on the calculated deviation, and other correlation data correlating the deviation with the operational speed at which the device continuously variable speed change is operated; and controls the operating means such that the continuously variable speed change device 5 is actuated to the target shift operational position and the target operational speed. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a side view of a tractor, as an example of a construction vehicle, FIG. 2 is a schematic drawing showing the tractor's gearbox, FIG. 3 is a side view. in section showing part of the tractor gearbox, FIG. 4 is a sectional plan view showing part of the tractor gearbox, FIG. 5 is a diagram showing the hydraulic circuit, FIG. block diagram showing the control structure, FIG. 7 is a graph showing the correlation between the actuated positions of the gearshift pedal and the positions that have been taken to the swash plate of the pump, FIG. is a curve showing the correlation between the swash plate deviations and the target operating speeds, FIGS. 9A, 9B, 9C are curves showing the correlation between the swash plate positions and the 10 (A) and 10 (B) are curves showing the movement of the pump swashplate when varying the position of the motor swash plate, respectively in the upward direction. downward and upwardly, FIGS. 11 (A), 11 (B) and 11 (C) show how the position of the pump's swash plate is displayed on a liquid crystal display device. in different situations, Fig. 12 is a sectional plan view showing a mechanical servo mechanism, Fig. 13 is a hydraulic circuit diagram showing the servo mechanism and the permutation mechanism; Fig. 14 is a hydraulic circuit diagram showing an arrangement where only an electronic servo mechanism is used; Fig. 15 is a hydraulic circuit diagram showing an arrangement where only a mechanical servocontrol mechanism is used; Fig. 16 is a side view of a tractor in a different embodiment, Fig. 17 is a block diagram showing the control structure; Fig. 18 is a graph showing the correlation between the swash plate deviations and FIG. 19 is a graph showing the correlation between the positions of the constant speed lever and the positions of the pump swash plate, FIG. Fig. 21 is a perspective view showing the braking sensor, Fig. 21 is a side view showing a portion of the braking sensor, Fig. 22 is a graph showing the correlation between the actuated positions of the shifter and the shifter. the positions of the pump swash plate in another embodiment, FIG. 23 is a curve showing the angular positions of the swash plate relative to the time for different mode settings, Fig. 24 is a graph showing a hysteresis between the swash plate positions and the servo pressure. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The complete side view of the tractor as an example of a work vehicle is shown in FIG. 1. This tractor comprises a front frame 2 which supports the engine 1 via a vibration isolator. , front wheels 3 supported on each side of the front frame 2, a gearbox case 4 also acting as a chassis connected to the engine 1 and rear wheels 5 arranged on each side of the box case 4. The portion of the driver 8 of the works vehicle is equipped with a steering wheel 6, the driver's seat 7, etc., above a gear case 4. The tractor has several sensors, as described below. These sensors are known and conventional sensors, such as rotation sensors, which may be of optical or magnetic or other type, and will not be described in detail below. [0003] As shown in FIGS. 2 to 4, the energy of the engine 1 is transmitted to the continuously variable hydrostatic variable speed change device (example of a continuously variable speed change device) 10, acting as the main device for changing the speed of the engine. speed, via the main clutch of the dry type 9, etc. The motive power from the continuously variable hydrostatic variable speed change device 10 is transmitted to the left and right front wheels 3 and the left and right rear wheels 5 through the gear type gear shifter (example 11), acting as an auxiliary shifting device which can be brought into three speed positions, the high, medium and low speed positions, the differential gear mechanism 12 for the front wheels or the differential mechanism 13 for the rear wheels. The energy for an operation performed by the hydrostatic-type variable speed changeover device 10 is transmitted to the PTO shaft 15 via a hydraulically operated clutch 14, etc. The gearbox case 4 is made by connecting the following four housing parts: the first housing part 4A, containing the main clutch 9, etc., the second housing part 4B, containing the variable speed shifting device. continuously hydrostatic type 10, etc., the third housing portion 4C, containing the operational clutch 14, etc., and the fourth housing portion 4D, containing the gear type gear shifter 11, etc. [0004] As shown in FIGS. 2 to 5, the hydrostatic type continuously variable speed changing device 10 has an axial piston type variable displacement pump 16, an axial piston type variable displacement motor 17, etc., which are housed in the second housing portion 4B, where the energy from the variable-speed pump 16, whose speed is not changed, is outputted as the operating energy and the shifting energy from the variable stroke motor 17 is output as energy for displacement. The charge oil from the charge pump 21 driven by the motor energy is supplied to a closed circuit 20 via a charge oil path 22, a valve 23, and the like. which is formed by connecting the variable stroke pump 16 and the variable stroke motor 17 by the first oil path 18 and the second oil path 19. As shown in FIGS. 1 and 4 through 6, FIG. 8, this tractor is equipped with a servo-control mechanism 25, with which an oscillating plate (hereinafter referred to as the pump swash plate) 16A of the variable-stroke pump 16 is actuated, based on the action on the gearshift pedal 20 (example of the shifting operational element) 24, which is pushed to its neutral position. As shown in FIGS. 4 to 6, the servo-control mechanism 25 comprises a hydraulic pump cylinder 26 for continuously operating the pump 16A swash plate (example of operational means), a servovalve 27 which regulates the flow of the fluid hydraulic to the hydraulic pump cylinder 26, a control valve 28 which maintains the hydraulic pressure of the servovalve 27 to a predetermined value, a pedal sensor (example of operative position detection means) 29, having a potentiometer 30 for detecting the position that was made to the shift pedal 24 and a swash plate sensor (example of shift position detecting means) 30, having a potentiometer which detects the operational position of the swash plate of the pump 16A according to the value of the actuation of the pump cylinder 26 and a control device (example of control means) 31 , comprising a microcomputer at the input of which are applied sensed information from sensors, such as the pedal sensor 29, the swash plate sensor 30, etc. The pump cylinder 26 is housed in the second housing portion 4B with a forward deceleration spring 32 and a reverse deceleration spring 33, biasing the swash plate 16A towards its neutral position. When a hydraulic fluid is supplied to the hydraulic chamber 34 for forward gearshift, the swashplate of the pump 16A is actuated in a forward speed increase (or acceleration) direction to the against the pushing force of the forward deceleration spring 32. When the hydraulic fluid is supplied to the hydraulic chamber 35 for reverse gear shifting, the swashplate of the pump 16A is actuated in a direction of increase. The servo-valve 27 has an electromagnetic proportional valve 36 for the forward direction, for controlling the flow of hydraulic fluid to the hydraulic chamber 34 for the forward movement of the engine. pump cylinder 26 and an electromagnetic proportional valve 37 for reverse, which controls the flow of hydraulic fluid to the hydraulic chamber 35 for reversing the speed of the pump cylinder 26. The regulating valve 28 distributes the hydraulic fluid supplied by the feed pump 38 for the power steering, to the operational clutch 14 and the power steering device hydraulic 39 with a suitable pressure for each operation. The path of the feed oil 41 to the servovalve 27 is connected to the pressure port 28A of the regulating valve 28 to which the feed oil path 40 is connected to the operational clutch 14. [0005] The controller 31 has at least one MPU, memory and other known circuits required to perform a communication function and other functions and algorithms described in the specification. As shown in FIG. 6, the control device 31 possesses the cartographic data (example of the correlation data) correlating the position that has been taken (or actuation position) with the gearshift pedal. 24, with the operational position of the swashplate of the pump 16A, and a control means of the swashplate of the pump 31A having the control program which actuates the swashplate of the pump 16A by controlling the actuation of the proportional valve 36 for forward or proportional valve 37 for reverse, based on the map data and the detected information or signals from the pedal sensor 29, the detected information from the swash plate sensor 30, etc. The mapping data of the control plate of the pump 31A swashplate correspond to the position that was made to the shift pedal 24 and the operational position of the swashplate of the pump 16A, so that that the higher the value of actuating the neutral point of the gearshift pedal 24 in a forward speed increasing direction, the greater the operational value from the idle position of the swashplate of the pump 16A towards a forward speed increase direction is large, and such that the greater the value of the actuation of the neutral position of the shift pedal 24 in a direction of speed increase in reverse is large, more the operating value of the idle of the swashplate of the pump 16A in a direction of increasing speed in reverse is large (see Figure 7). The control program of the control plate of the pump 31A swashplate determines the operative position of the swashplate of the pump 16A corresponding to the position that was made to the shift pedal 24 detected by the sensor of the pedal 29, as the target operating position of the pump swing plate 16A, based on the stored map data and the sensed information from the pedal sensor 29. Based on the determined target operational position and the sensed information from the sensor. of the swash plate 30, the actuation of the proportional valve 36 for the forward and the proportional valve 37 for the reverse gear is controlled so that the target operational position of the swashplate of the pump 16A and the actual operational position are in agreement. By this control operation, the vehicle can advance or retreat at the speed according to the position that was made to the gearshift pedal 24. That is to say that the servo mechanism 25 is the electronically controlled type, where the control plate of the pump 31A control plate actuates the proportional valve 36 for the forward or the proportional valve 37 for the reverse, to actuate the pump cylinder 26 so as to operating the swashplate of the pump 16A of the hydrostatically variable variable speed changing device 10 based on the sensed information from the pedal sensor 29 and the sensed information from the swash plate sensor 30. The servo mechanism Directly controls the pump cylinder 26 with the outlet pressure of proportional valve 36 for forward or proportional valve 3 7 for reverse, passing through the pressure port 28A of the regulating valve 28 (direct acting type). Stable pilot control pressure can be obtained and operational control of the pump cylinder 26 can be performed with sufficient accuracy, as compared to an arrangement where the pump cylinder 26 is driven with the outlet pressure from the oil path 22 where the pressure varies due to the pressure fluctuation in the closed circuit 20 of the hydrostatically-variable variable speed changing device 10 or variations in the rotational speed of the engine. As a result, the vehicle speed control performs a forward or a reverse gear at a speed in accordance with the position that was made to the shift pedal 24 with sufficient accuracy based on the detected information from the vehicle. pedal sensor 29 and the sensed information from the swash plate sensor 30, while using a direct acting type servo mechanism 25 which is relatively inexpensive. The control device 31 comprises: an operating program which calculates the difference between the target operating position of the oscillating plate of the pump 16A determined by the control means of the swashplate of the pump 31A and the actual operating position 301 7 9 1 7 12 based on the target operational position of the swashplate of the pump 16A and the detected information from the swash plate sensor 30; a plurality of map data (exemplary correlation data) correlating the deviation of the target operational position of the pump swing plate 16A with the actual operational position and the operating speed of the pump swing plate 16A; and the first operational speed determination means 31B comprises the control program which determines the target operational speed of the pump swashplate 16A, based on these map data and on the calculated result of the operational program. Each map datum of the first operational speed determination means 31B correlates the offset of the swashplate of the pump 16A with the operational speed of the swashplate of the pump 16A (see FIG. 8), so that when there is a large difference between the actual operational position of the swashplate of the pump 16A, detected by the swash plate sensor 30, and the target operating position of the swashplate of the pump 16A, determined by the control means. of the swash plate 20 of the pump 31A, the operational speed of the swashplate of the pump 16A becomes larger and thus, the operational speed of the swashplate of the pump 16A for a given offset of the swashplate of the pump 16A in reverse is less than the operational speed of the swashplate of the pump 16A for a given offset 25 of the swashplate of the pump 16A in operation with ant. The control program of the first operational speed determination means 31B is set such that the operational speed of the pump 16A swashplate corresponding to the offset of the swashplate of the calculated pump 16A 16A is determined as the speed. The operational target of the pump 16A swashplate, based on the mapping data and the calculation result of the operational program. The determined target operating speed is also outputted by controlling the swashplate of the pump 31A. [0006] In the vehicle speed control, the control program of the pump swashplate control means 31A controls the actuation of the proportional valve 36 for forward or proportional valve 37 for the reverse, so that the swashplate of the pump 16A is operated at the target operational speed determined by the first operational speed determination means 31B. By this control operation, the thrust can be controlled while improving the response property of the swashplate of the pump 16A to the actuation of the gearshift pedal 24. As a result, the speed of the vehicle can reach quickly and accurately the speed determined by the position 10 that was made to the gearshift pedal 24. Since the operational speed of the swashplate of the pump 16A in reverse is less than the operating speed of the swashplate of the pump 16A in a forward motion, and that the speed change actuation of the hydrostatic-type variable speed changeover device 10 in reverse is performed more progressively in comparison with the speed change actuation of the device continuously variable hydrostatic type 10 forward movement, it becomes easy to perform an operation in a reverse gear of the hydrostatic-type variable speed changing device 10 during a reverse gear while it is difficult to obtain speed detection with respect to a forward gear. The controller 31 includes data modification means 31C with the control program that modifies the map data used by the first operational speed determination means 31B. As described below, the data modification means 31C is set such that the map data used by the first operational speed determination means 31B is suitably modified according to the various situations. The data modifying means 31C modifies the mapping data correlating the offset of the swashplate of the pump 16A with the operational speed of the swashplate of the pump 16A, based on the actuated position of a dial. control (example of driver-operated control) 42 having a potentiometer in the driver's station 8, so that when the control dial 42 is further actuated on the fast side relative to the reference position , the operation of the swashplate of the pump 16A is performed more quickly by modifying the mapping so that the offset of the swashplate of the pump 16A corresponds to the operating speed of the swashplate of the pump 16A so that the The operating speed of the pump 16A swashplate for a given offset of the swashplate of the pump 16A becomes faster. On the other hand, when the regulating dial 42 is further actuated on the slow side relative to the reference position, the operating speed of the swashplate of the pump 16A up to the distance from the swashplate of the pump 16A is lower, so that the operation of the swash plate of the pump 16A is performed more gradually. That is, by operating the regulating dial 42, a response to a speed change operation of the hydrostatically variable variable speed change device 10 by the shift pedal 24 may be modified according to the wishes of a driver, resulting in improved gear changing characteristics. The data modification means 31C modifies the map data based on detected information from the temperature sensor 43 by which the temperature of the hydraulic fluid supplied to the regulating valve 28 is detected, so that the operational speed of the plateau The oscillation of the pump 16A is correlated with the given offset of the swashplate of the pump 16A, so that the operational speed of the swashplate of the pump 16A for the offset of the swashplate of the pump 16A is progressive in response. to a decrease in the temperature of the oil, such that the lower the temperature of the hydraulic fluid, the more the operation of the swashplate of the pump 16A is carried out progressively. That is, the system considers that the viscosity of the hydraulic fluid becomes large and the response of the swash plate of the pump 16A becomes slower with the decrease in the temperature of the hydraulic fluid. The target operating speed of the pump 16A swashplate is set lower with a lower temperature of the hydraulic fluid. This can help to avoid a thrust resulting from the decrease of the pump 16A swash plate response, which is more likely to occur when the hydraulic fluid temperature is not taken into account and the temperature of the hydraulic fluid is reduced. low. [0007] The data modifying means 31C modifies the mapping data correlating the offset of the swashplate of the pump 16A with the operating speed of the swashplate of the pump 16A, based on the detected information from the secondary shifting sensor. (example of speed ratio detecting means) having a potentiometer which detects the speed ratio of the gear type gear shifter 11, based on the operational position of the secondary gear shift lever 44 in the 8, such that the higher the speed ratio of the gear type gear shifter 11, the greater the speed at which the operation of the swashplate of the pump 16A is performed. Accordingly, the means 31C modifies the map correlating the offset of the pump 16A swashplate with the operational speed of the swashplate of the pump 16A, so that the operational speed of the swashplate of the pump 16A for a given offset of the swashplate of the pump 16A is greater in response to the increase in the gear ratio of the gear type gear shifter 11. That is, the target operational speed of the swashplate The oscillation of the pump 16A is set at a higher speed, considering that the response to the operation of the swashplate of the pump 16A becomes slower as the gear ratio of the shifting device of the gear 11 is attached to the side of the higher speeds. Thus, irrespective of the gear ratio of the gear type gear shifter 11, the response during a shifting operation of the hydrostatic type variable speed shifter 10 by the gear change pedal speed 24 is consistent. The data modification means 31C modifies the card to be used for the data performing the correlation of the offset of the swashplate of the pump 16A with the operating speed of the swashplate of the pump 16A, so that the higher the operating speed of the the shift pedal 24 is slow, plus the swash plate of the pump 16A is operated progressively, based on the information detected from the operational speed detecting means 46 which detects the operating speed of the shift pedal 24, so that with a decrease in the operational speed of the shift pedal 24, the operational speed of the swashplate of the pump 16A for a given offset of the swashplate of the pump 16A becomes more progressive. The operating speed of the shift pedal 24 is achieved by differentiating the output of the pedal sensor 29 from time. Accordingly, it is considered that the detection means 46 includes the pedal sensor 29 and the control device 31. Accordingly, even if the shift pedal 24 is operated very slowly, the movement of the pump's swash plate 16A is delayed with respect to the operation of the shift pedal 24. Thus, since the possibility that the operation of the swashplate of the pump 16A follows the actuation 20 of the shift pedal 24, causing a shifting in echelon, can be avoided, a regular gear change operation of the hydrostatic variable speed change device 10 by the shift pedal 24 can be performed, regardless of the operating speed of the speed shift pedal 24. The operational speed detection means 46 includes the pedal sensor 29 and the operating program 1 includes the data modification means 31C for calculating the operating speed of the shift pedal 24 based on the detected information from the pedal sensor 29. The data modifying means 31C modifies the map data for use in the map data correlating the offset of the swashplate of the pump 16A with the operational speed of the swashplate of the pump 16A based on the detected information from the swash plate sensor 30, so that when detects that the operational position of the swashplate of the pump 16A is close to neutral or in neutral, the operation of the swashplate of the pump 16A is performed smoothly so that the operational speed of the swashplate of the pump 16A for a given offset of the swashplate of the pump 16A is limited on the low speed side. Accordingly, when the swashplate of the pump 16A is located near neutral or in neutral, even if the shift pedal 24 is depressed suddenly, since the swashplate of the pump 16A is not operated quickly in the direction of the increase of the speed with the intervention operation, the swashplate of the pump 16A is actuated gently in the direction of the increase of the speed. Thus, even if the intervention operation of the shift pedal 24 is performed very quickly, a regular start is ensured without sudden start or sudden acceleration from a very slow speed. The data modifying means 31C modifies the map data used performing the correlation of the offset of the swashplate of the pump 16A with the operating speed of the swashplate of the pump 16A, based on the detected information from the rotation sensor ( example of load detecting means 47) which detects the rotational speed of the motor and the target operating position of the swashplate of the pump 16A determined by the control means of the swashplate of the pump 31A, so that when the The operational target of the swashplate of the pump 16A is set on the low speed side, when the rotational speed of the motor is low, the operation of the swashplate of the pump 16A is carried out rapidly so that, in response to the decrease the rotational speed of the engine, the operational speed of the swashplate of the pump 16A for a given gap of the The oscillating water of the pump 16A becomes larger. The map data is modified so that when it is detected that the target operating position of the swashplate of the pump 16A has been set on the high speed side as the rotational speed of the motor increases, the actuation of the swash plate of the The pump 16A is smoothly constructed so that the operating speed of the pump 16A swash plate for a given offset of the pump swash plate becomes slow in response to the increase in rotational speed. of the motor. If the shift pedal 24 is operated on the deceleration side when the rotational speed of the motor is low due to an increase in the transport load, etc., the swashplate of the pump 16A is actuated rapidly. in the deceleration direction in response to actuation, attenuating the excessive load of the motor. This decreases the engine stall problem despite the fact that the shift pedal 24 is operated in the deceleration direction, because the reduction of the engine load is too slow due to a slow response of the engine. hydrostatically variable variable speed shifter 10. When the shift pedal 24 is operated on the acceleration side as the rotational speed of the engine increases due to a reduction in the transport load, etc., since the actuation in the direction of increasing the speed of the swash plate of the pump 16A, based on the actuation is carried out gently, the rapid increase in the speed of the vehicle resulting from the actuation of Increasing the speed of the 16A pump swashplate with the increase of the motor rotation speed is avoided. That is, the speed change actuation of the hydrostatically variable variable speed changing device 10 by the shift pedal 24 can be performed perfectly regardless of the variation of the rotational speed. of the motor. The data modification means 31C modifies the map data correlating the offset of the swashplate of the pump 16A with the operating speed of the swashplate of the pump 16A, based on the detected information from the brake sensor ( example of brake detection means 49) having a potentiometer which detects actuation of the brake mechanism (not shown) from the operating position of the brake pedal 48 in the driver's station 8 so that when the braking mechanism executes the braking operation, the operation in the direction of the deceleration of the swashplate of the pump 16A is carried out rapidly so that the operating speed of the swashplate of the pump 16A for a given distance from the 16A pump swash plate increases, taking into account the decrease in vehicle speed by the brake operation age of the braking mechanism. This avoids interference between the hydrostatic-type variable variable speed change device 10 and the braking mechanism during the braking operation when the shift pedal intervention operation 24 is stopped and the operation of the brake pedal 48 is performed. This thus facilitates the increase of the operational life of the hydrostatic-type variable speed changeover device 10 as well as the braking mechanism. The data modifying means 31C modifies the mapping data correlating the offset of the swashplate of the pump 16A with the operational speed of the swashplate of the pump 16A, based on the detected information from the speed sensor. of the vehicle (speed sensing means) 50 which detects the speed of the vehicle from the output rotational speed of the gear type gear shifter 11, so that when the vehicle speed is slow, the The operating speed of the pump swashplate 16A for a given offset of the swashplate of the pump 16A is performed slowly, so that the operation of the swashplate of the pump 16A is progressive, in response to the decrease in speed. of the vehicle. Advancing at low speed, the response of the swashplate of the pump 16A to actuation of the shift pedal 25 24 becomes less sensitive, facilitating the execution of a progressive adjustment operation of the required vehicle speed at low speed. speed. The data modifying means 31C modifies the map data correlating the offset of the pump 16A swashplate with the operational speed of the swashplate of the pump 16A based on the detected information from the swash plate sensor. And the target operating position of the swashplate of the pump 16A determined by the control means of the swashplate of the pump 31A, so that when the target operating position of the swashplate of the pump 16A is set to the side 35 of the speed increase relative to the actual operational position, the operation of the swash plate of the pump 16A is performed more gently and so that when the target operating position of the swashplate of the pump 16A is set on the slowdown side relative to the actual operational position, the actuation of the swash plate of the pump 16A is t is performed rapidly and so that when the dead point is between the target operational position of the swashplate of the pump 16A and the actual operative position of the swashplate of the pump 16A, the actuation of the swashplate of the pump 16A is performed much faster. [0008] Accordingly, depending on the relationship of the target operational position of the pump swashplate 16A and the actual operational position, the operational speed of the swashplate of the pump 16A for a given offset of the swashplate of the pump 16A varies. [0009] Responses to the speed increase operation and the slowing operation of the hydrostatic continuously variable speed change device 10 by the shift pedal 24 can be made different by this method. Since the increase of the engine load by a speed increase operation of the hydrostatic-type variable speed changeover device 10 is reduced and the load of the engine by a slowdown operation of the variable speed shifter In the hydrostatic-type continuous mode 10 is reduced, a motor stall due to a speed change operation of the hydrostatically variable variable speed changing device 10 by the shift pedal 24 during a heavy load can be prevented effectively. . Since the operating delay of the swashplate of the pump 16A in response to an operation of the shift pedal 24 is prevented, the shifting operation of the hydrostatic type continuously variable speed shifter 10 in operation before or in reverse by the shift pedal 24 can be performed comfortably. The data modifying means 31C modifies the mapping data correlating the offset of the swashplate of the pump 16A with the operational speed of the swashplate of the pump 16A, based on the information detected from the sensor 301 7 9 1 7 21 of the swash plate 30 and the target operating position of the swashplate of the pump 16A determined by the control means of the swashplate of the pump 31A, so that when starting the movement of the vehicle, when the swash plate of the 16A pump is actuated in the direction of increasing the speed relative to neutral, the operation of the swashplate of the pump 16A is performed smoothly, so that the operational speed of the swashplate of the pump 16A for a given offset of the swashplate of the pump 16A becomes slower at the beginning of the run and so that when the vehicle is stopped when an operatio n of slowing of the swashplate of the pump 16A is carried out from a speed increasing position to the neutral position, the operation of the swashplate of the pump 16A is carried out at a higher speed, so that at the moment When the vehicle stops, the operational speed of the oscillating plate of the pump 16A for a given offset of the swashplate of the pump 16A becomes faster. This allows the modifications of the response to the starting run and the stopping run by the action of the shift pedal 24. This also makes it easier to prevent possible abrupt acceleration at the start of vehicle movement. As the map data of the first operational speed determination means 31B, map data for the forward travel for the operational gearshift speed at the time of a forward travel and the map data for the travel in progress. the reverse gear for the speed change operational speed at the time of reverse travel can be provided separately, so that the data modification means 31C has different map data to be used, based on the detected information from pedal sensor (forward / reverse path detection means) 29. When the forward travel deceleration spring 32 and the reverse travel deceleration spring 33 perform a dead center return operation (deceleration operation) of the pump's swashplate 16A, the inertia at the time of the a towing operation, etc. , may make it difficult to perform the operation of slowing down to the idle position of the swashplate of the pump 16A, despite the slowing operation of the shift pedal 24. Thus, despite the deceleration operation of the shift pedal 24 based on the detected information from the pedal sensor 29 and the sensed information from the swash plate sensor 30, when a deceleration operation is detected of the swashplate of the pump 16A with the forward deceleration spring 32 or the reverse deceleration spring 33 is not performed, the control means of the swash plate of the pump 31A controls the actuation of the valve proportional 36 for a forward run or proportional valve 37 for reverse travel on the opposite side to the side used to operate the swashplate of the pump 16A with respect to the current operating position. Thus, the pump cylinder 26 is forced to operate in the direction in which the deceleration operation of the swashplate of the pump 16A is effected to the neutral position. Accordingly, even if the swashplate of the pump 16A does not decelerate, although the speed at which the shift pedal 24 is actuated is slowed due to inertia, for example during a towing operation, etc. . the deceleration operation of the swashplate of the pump 16A can be performed by a forced operation of the pump cylinder 26 by the operational control of the proportional valve 36 for a forward travel or the proportional valve 37 for a run in reverse by the control means of the swash plate of the pump 31A. The stalling performance of the work vehicle engine incorporating the hydrostatically variable variable speed changeover device 10 is shown in FIG. 9 (A). These engine stalling performances are determined by the output torque of the engine 1, the pressure of the hydrostatically variable variable speed changing device 10 and the operating position (swash plate angle) of the swashplate of the pump 16A. The line L shown in Fig. 9 (A) is a motor stall performance line where the rotational speed of the motor and the operational shift position of the swashplate 301 of the pump 16A are at the moment of maximum loading on the hydrostatically variable variable speed change device 10, at which a significant pressure limitation of the hydrostatic type variable variable speed change device 10 releases the pressure due to the payload. In Fig. 9 (A), the rotational speed of the motor is plotted against the rotation speed determined at 100% and the operating position of the swashplate of the pump 16A shown relative to 100% for the position of maximum acceleration (maximum swing angle). The stalling performance of the work vehicle engine incorporating the hydrostatically variable continuous variable speed change device 10 is explained with reference to FIG. 9 (A). When the operational burden to drive tools, etc. , other than the forward load is applied to the motor 1 with the swashplate of the pump 16A held in a certain operating position, as shown in point a, the rotational speed of the motor and the operating position 16A of the swash plate of the pump can arrive in the region Za below the line of performance of 20 engine L stall. In this case, when the operational load other than the advancement charge, etc. , is stable, even if the forward load increases, the rotational speed of the motor does not decrease. However, if the operational charge other than the advancement charge, etc. , 25 increases, the rotational speed of the motor decreases and the motor 1 stops or stalls. With the swashplate of the pump 16A held in a certain operating or operative position, as represented by point b, when the rotational speed of the motor and the operating position of the swashplate of the pump 16A are located in the region Zb outside the engine stalling performance line L, if the forward load increases, the rotation speed of the engine decreases and the engine 1 stops. With the swash plate of the pump 16A held in a certain operating position, when the rotational speed of the motor and the operating position of the swashplate of the pump 16A are located in the region Zc as represented by point c, if the advancing load increases, the rotational speed of the motor decreases until it reaches the line of engine L timing performance. When it reaches the L engine stalling performance line, the rotational speed of the engine is stabilized. The engine stalling performance line L is such that as the output of the engine 1 decreases, the operating position of the swashplate of the pump 16A for a given engine rotational speed in FIG. 9 (A) becomes weaker. That is, the smaller the output of the engine 1, the more likely it is that a stall of the engine will occur due to an overload during an acceleration by intervention on the shift pedal. in a course with a significant advancement load or climbing a hill. To solve this problem, as shown in FIG. 6, the controller 31 includes automatic control means of the swashplate of the pump 31D which changes the operating position of the swashplate of the pump 16A based on the engine load. As shown in FIGS. 6 and 9 (B), the automatic control means of the swashplate of the pump 31D includes an operational program which calculates the value of the decrease (value of the engine speed drop) from the a determined rotational speed of the rotational speed of the motor based on the detected information from the adjustment rotation sensor (e.g., an adjustment rotational speed detecting means) 52 having a potentiometer which detects the speed of rotation of the motor; setting rotation of a motor 1 from the operating position of the accelerator lever 51 in the driver station 8 and information detected from the rotation sensor 47, a plurality of map data (example correlation) performing the correlation of the rotational speed of the motor with the operating position of the swashplate of the pump 16A and a control program which activates The pump 16A is swung by controlling the actuation of the proportional valve 36 for a forward run or the proportional valve 37 for reverse travel, based on the result of the operation. calculation and map data of the operational program. Each chart data of the automatic control means of the 31D pump swashplate is determined based on the L engine timing performance line. The rotational speed of the motor and the operating position of the swashplate of the pump 16A are also correlated so that when the rotational speed of the motor decreases to the predetermined motor rotation region h, the speed of the If the rotation is small, the limit operating position is close to neutral and so that the limit operative position of the pump 16A swashplate is not fixed in neutral (see Fig. 9 (B)). For a more detailed explanation, as shown in Fig. 9 (B), in the first region h1, when the amount of engine speed decrease is low among the predetermined engine rotation regions, the engine rotational speed and the operating position of the swashplate of the pump 16A is correlated so that the value of the variation of the swashplate of the pump 16A is large for a given variation value of the rotational speed of the motor. In the second region h2, when the engine speed drop value is larger than the first hl region, the engine rotation speed and the operating position of the pump 16A swing plate are correlated so that the the value of the variation of the swashplate of the pump 16A is small for a given variation value of the rotational speed of the engine and so as to have a stabilization point p where the rotational speed of the motor does not decrease due to the advancement charge. The rotational speed of the motor and the operating position of the swashplate of the pump 16A are correlated in the third region h3 where the value of the engine speed drop is greater than in the second region h2, so that that the value of the variation of the swashplate of the pump 16A is large for the given value of variation of the speed of rotation of the motor. The control program of the automatic control means of the pump 31D swashplate determines the operating position of the swashplate of the pump 16A corresponding to the value of the engine speed drop that the program The operational limit was calculated as the operating limit position of the pump swashplate 16A, based on the result of the calculations and the map data of an operational program and controls the actuation of the proportional valve 36 for a running run. forward or proportional valve 37 for reverse travel, based on the determined limit operational position and sensed information from the swash plate sensor 30, such that the limit operative position of the pump swash plate 16A is in agreement with the actual actuating position. That is, with the automatic control means of the swashplate of the pump 31D, when the rotational speed of the motor decreases to the first region h1 due to an increase in the load of the motor , the load control is performed when the driving torque is increased while avoiding stalling of the motor by gently returning the swashplate of the pump 16A in the direction of slowing down and reducing the rotational speed of the motor. When the rotational speed of the motor reaches the second region h2, despite this load control, the load control can be implemented, avoiding stalling of the motor while giving priority to increasing the driving torque. by decreasing the value of the deceleration operation of the swash plate and increasing the driving torque while allowing the driver to feel the load of the engine. If the load on the engine is an advancing load, the rotational speed of the engine stops decreasing below the stabilization point p when the speed has reached point p. The difference between Fig. 9B and Fig. 9C is that the vertical axis of Fig. 9C represents the rotational speed of the motor. Max indicates the map data setting for a heavy load and IDL indicates the map data setting for light load. When the rotational speed of the engine decreases to the third region h3 due to a load other than an advancing load, for example, by lifting operation of a liftable tool, a load control can be implemented, setting the drive torque while giving priority to engine stall prevention by returning the swashplate of the pump 16A in the direction of retarding a significant amount and by reducing the rate of decrease of the rotational speed of the motor. With this command, a load control preventing engine stall due to overload can be performed during a loader operation when a front loader A is connected to the tractor or during a plowing operation when the plowing device is connected to the loader. tractor, etc. , even if the driver performs a gearshift without taking into account the operational load, etc. thus, an improvement in the system response can be expected. In addition, since the limit operative position of the pump 16A swashplate is never set to neutral, the swashplate of the pump 16A is not returned to neutral by this load control. Accordingly, the possibility of the pump 16A swashplate returning to neutral and the vehicle unintentionally starting backing up by the load control during climbing a hill is avoided. The controller 31 includes a plurality of map data correlating the rate of change of the rotational speed of the motor with the operating speed of the swashplate of the pump 16A. It comprises a second operational speed determination means 31E having a control program which determines the target operational speed for the pump 16A swashplate, based on these map data and the detected information from a sensor detection means. 30 speed of variation 53 which detects the speed of variation of the speed of rotation of the motor. Each map datum of the second operational speed determination means 31E correlates the rate of change of the engine rotational speed with the operating speed of the pump's swashplate 16A so that the higher the speed of change of the motor rotation speed is high, the greater the operational speed of the swashplate of the pump 16A becomes large. The control program of the second operational speed determination means 31E sets the operational speed of the swashplate of the pump 16A corresponding to the rate of change of the rotational speed of the motor that the variation speed detection means 53 has detected. As the target operational speed of the pump 16A swashplate, based on the stored map data and the detected information from the variation rate detecting means 53 and the determined target operational speed is output by means of automatic control. swing plate of the 31D pump. The control program of the automatic control means of the pump 31D swash plate controls the actuation of the proportional valve 36 for forward travel or the proportional valve 37 for reverse travel, so that the The swash plate of the pump 16A is actuated at the target operational speed determined by the second operational speed determination means 31E. Thus, good load control taking into account the rate of change of the rotational speed of the motor is possible. Despite the changes in the speed of variation of the rotational speed of the engine, the driving comfort is maintained during a decrease or an increase in the rotational speed of the engine. In addition, the operation of decelerating the swashplate of the pump 16A towards the reduction of the rotational speed of the motor can be carried out with sufficient response and the stall of the motor resulting from the delay of actuation of the swash plate of the pump. 16A can be avoided. The variation rate detecting means 53 comprises the rotation sensor 47 and the operational program of the second operational speed determining means 31E which calculates the rate of change of the rotational speed of the engine based on the detected information from rotation sensor 47. The data modification means 31C includes a control program which modifies the map data used by the automatic control means of the swashplate 31D of the pump 31D and the second operational speed determining means 31E . The data modification means 31C modifies the map data used by the automatic control means of the swashplate of the pump 31D, in map data correlating the speed of rotation of the motor with the operating position of the swash plate of the the pump 16A, based on the detected information from the fixed rotation sensor 52, such that the lower the fixed rotation speed of a motor 1, the lower the value of the control of the swash plate of the pump 16A for a given change in the rotational speed of the motor (see Figure 9) is large. It also modifies the map data used by the second operational speed determination means 31E, in map data correlating the speed of variation of the rotational speed of the engine with the operational speed of the swashplate of the pump 16A. based on the detected information from the secondary shift sensor 45, such that the lower the gear ratio of the gear type gear shifter 11, the greater the actuation of the swash plate of the pump 16A becomes fast and so that the operating speed of the swashplate of the pump 16A becomes greater for a speed of variation of the rotational speed of the motor with a reduction of gear ratio of the gear shifter type to gear 11. That is, a suitable charge control is chosen based on the map data by considering the determined rotational speed of the motor 1. Accordingly, regardless of the fixed rotational speed of a motor 1, engine stalling due to overload can be effectively avoided. Depending on the gear ratio of the gear type gear shifter 11 whose speed is changed on the low speed side when carrying out a operation with a larger load, the map data is set such that so that the lower the gear ratio, the greater the operational speed of the swashplate of the pump 16A is large for a ratio of variation of the speed of rotation of the given engine. Accordingly, a deceleration operation of the swashplate of the pump 16A can be performed rapidly in response to a rapid reduction in the rotational speed of the motor when operating with a large load. As a result, motor stalling due to overload can be reliably avoided. Although not shown, a manually operated operational speed determination device (operational speed determination means) is provided and includes a potentiometer or a switch for setting the target operational speed of the pump 16A swashplate during a period of time. load control, etc. The automatic control means of the swash plate of the pump 31D can be set so that it controls the actuation of the proportional valve 36 for the forward direction or the proportional valve 37 for the reverse, so that the swashplate of the pump 16A is actuated at the target operating speed determined by this operational speed determination device by considering the operational load which varies according to the type of tool attached. An operational tool for a data modification control (control means) comprising a potentiometer, a switch, etc. , can be provided by data modification means 31C in the driver station 8 to control a variation of the map data used by the automatic control means of the swashplate of the pump 31D or the second operational speed determination means 31E. This makes it possible to modify the cartographic data according to the attached tool. This tractor is equipped with a switching mechanism 54 which switches the swash plate (motor swashplate) 17A of the variable capacity motor 17 between the high and low positions. The switching mechanism 54 comprises a hydraulic cylinder 55 which actuates the motor swashplate 17A, a permutation valve 56 which controls the flow of hydraulic fluid to the cylinder 55, an electromagnetic control valve 57 which actuates this permutation valve 56, a high pressure selection valve 58 which actuates the supply of hydraulic fluid from the closed circuit 20 of the hydrostatically variable continuous variable speed change device 10 to this control valve 57, a switching lever 59 arranged in the lower left position relative to the steering wheel 6, a lever sensor 60 having a switch which detects the actual position of this switching lever 59 and a motor 31F swashplate control means that has the control device 31 as a control program which performs the up-and-down switching operation of the oscillation plate. the motor 17A based on the sensed information from this lever sensor 60. The cylinder 55 for the engine and the variable capacity engine 17 are removably housed in the second housing portion 4B of the gearbox case 4. When the switching lever 59 is actuated to a low speed position based on the sensed information from a lever sensor 60, the motor 31F swash plate control means performs a high to low switching control which switches the motor 17A swash plate from the high speed position to the low speed position and turns on the corresponding indicator lamp 61. When the shift lever 59 is operated in a high speed position, it also performs a low to high switch control which switches the motor 17A swing pad from the low speed position to the high speed position and turns on the lamp. corresponding indicator 62. That is, when the vehicle speed drops substantially due to an increase in load while climbing a hill where a field operation with the shift lever 59 in the high speed position, the force drive to the right and left front wheels 3 and the right and left rear wheels 5 can be increased by switching the switching lever 59 to a low speed position from a high speed position so that the vehicle can continue to to mount or continue the work operation. The indicator lamps 61 and 62 are arranged in the console panel 63 disposed below the steering wheel 6. The motor swashplate control means 31F stores the current operating position of the swashplate of the pump 16A in the high-to-low switch control based on the sensed information from the swash plate sensor 30 and calculates a desired position. 30A pump 32A slugging target actuation and controls the actuation of proportional valve 36 for forward or proportional valve 37 for reverse, so that operation The deceleration of the swashplate of the pump 16A is performed at a predetermined operational speed to the calculated slowing target actuation position. The means 31F controls the actuation of the proportional valve 36 or 37 and the control valve 57 such that after the swashplate of the pump 16A has reached the slowing target operating position, an accelerated return 10 of the swashplate of the pump 16A to the operating position stored at the predetermined operating speed and the swap operation of the swashplate of the motor 17A from the high speed position to the low speed position at a predetermined speed , are performed simultaneously (see Figure 10 (A)). Further, in the high to low switching control, based on the sensed information from the swash plate sensor 30, the current operating position of the swashplate of the pump 16A is stored and the target operating position is stored. slowing of the swashplate of the pump 16A is calculated. Actuation of the proportional valve 36 for forward or proportional valve 37 for the reverse and actuation of the control valve 57 are controlled so that the deceleration operation of the pump swash plate 16A to the slowdown target actuation position calculated at the operating speed 25 and the operation of the switch from a low speed position to the high speed position of the motor 17A swashplate at the operating speed are performed simultaneously . After that, actuation of the proportional valve 36 for forward or proportional valve 37 for the reverse is controlled so that the swashplate of the pump 16A is returned to the actuated position stored at the predetermined speed. [See Figure 10 (B)]. That is, when switching the motor 17A swashplate to a low speed position from a high speed position, performing not only the switching operation but also the accelerating operation of the At the same time, the variation of capacity of the variable capacity motor 17 generated by the switching operation to the low speed position of the swashplate of the motor 17A from a high speed position can be shifted by the variation of capacity of the variable capacity pump 16 generated by the acceleration actuation of the swash plate of the pump 16A. In addition, when switching the motor 17A swash plate to a high speed position from a low speed position, by not only operating the switch but also a deceleration operation of the swashplate of the pump 16A simultaneously, the variation of capacity in the variable capacity motor 17 generated by the switching operation to the high speed position of the motor 17A swash plate from a low speed position can be shifted by the capacity variation in the variable capacity pump 16 generated in connection with the deceleration operation of the swash plate of the pump 16A. As a result, the shifting shock generated by a switching actuation of the swashplate of the motor 17A can be attenuated. In addition, although not shown, a high speed response valve may be used in place of the swap valve 56. When the motor 31F swashplate control means performs the switching operation of the motor swashplate 17A, the high speed response valve is operatively controlled so that the operational speed of the swashplate of the motor 17A can decrease. so as to slow down any variation in capacity in the variable capacity engine 17 generated during switching of the engine 17A swashplate, attenuating the shifting shock resulting from the change in capacity in the variable capacity engine 17. [0010] During a course with the swashplate of the motor 17A switched into the high speed position, the motor 31F swash plate control means can perform the high to low switching control together with the braking operation of a system braking system based on the detected information from the brake sensor 49 so as to improve the braking operation. The 31F motor swashplate control means may also be configured to perform high to low switching control during a course with the motor swashplate 17A switched to the position at high speed based on the detected information from the pedal sensor 29 and the sensed information from the swash plate sensor 30, regardless of the decelerating operation of the shift pedal 24 when it has been detected that the operation of decelerating the swashplate of the pump 16A with the forward deceleration spring 32 or the reverse deceleration spring 33 is not performed so that the high-to-low switching control can effect a deceleration operation if the deceleration operation of the swashplate of the pump 16A is not performed due to inertia during a In addition, the 31F motor swashplate control means may be configured to perform the switch control, etc., in spite of the deceleration operation of the shift pedal. from the operational speed detecting means 46, when the swashplate of the engine 17A is switched to the high speed position and when the operating speed of the shift pedal 24 is greater than a predetermined operational speed so as to avoid unexpected start-up and abrupt acceleration. As shown in FIG. 1, the shift lever 59 is installed such that the use end is located near the left portion of the steering wheel 6. This allows a high to low switching operation of the swash plate. of the engine 17A without lifting the hands of the steering wheel 6. In addition, when the front loader A (see FIG. 6) is connected to the tractor, the up / down switching operation of the motor 17A swash plate can be carried out without lifting the hands of the control lever for actuating the front loader (not shown) arranged on the right side of a steering wheel 6. As shown in FIGS. 4 to 6, the control device 31 comprises a 31G Auto Motor Swash Plate Control Medium as a control program. The automatic motor 31G swashplate control means performs an automatic high-to-low switching control which switches the motor 17A swash plate into the low speed position from the high speed position and turns on the corresponding indicator lamp 61 when detected, based on the information detected from the pedal sensor 29, that the operating position of the shift pedal 24 is actuated in the predetermined operating position or the operating zone when it has been detected that the rotational speed of the motor has decreased to the speed of the low to high switching motor near a predetermined maximum torque output rotation frequency or the low to high switching motor speed region set for a position of given operation of the shift pedal 24 based on the maximum torque output characteristic of a n motor 1 and the value of the engine speed drop calculated by the operational program of the automatic control means of the swashplate of the pump 31D. The automatic control of the 31G motor swashplate also performs the low to high switching control which switches the swashplate of the motor 17A to a high speed position from a low speed position and turns on the corresponding indicator lamp 62 when it has been detected, based on the value of the engine speed drop attained by the engine rotational speed up to the speed of the low to high switching motor near a predetermined fixed rotational speed or the region of the engine. switching motor speed low to high and when operating the shift pedal 24 to the previously set operating position or operating zone is detected based on the detected information from the pedal sensor 29. [0011] More specifically, if the actuation position of the pedal 24, whose maximum trample position is 100%, is 50% or less, for example, a high-to-low automatic switching command is performed when the velocity motor rotation rate drops to 85% of the motor speed. If the operating position of the pedal 24 is 90% or more, the automatic up / down switching control is performed when the motor rotation speed decreases to 70% or less. When the rotational speed of the motor rises to 90% or more, the automatic low-to-high switching control is executed when the operating position of a pedal 24 is operated at 80% or higher. That is, a high load condition is naturally assumed when the value of the engine speed drop is large when the shift pedal 24 is operated by a larger amount. However, if a certain amount of engine speed drop occurs when the value of the operation operation of the shift pedal 24 is low, a high load condition is also assumed, where a larger fall of motor rotation speed is expected with a large intervention operation of the pedal 24. Accordingly, even if the value of the engine speed drop is low, the high-low switching control is carried out so as to ensure a sufficient driving force. Accordingly, even if the driver does not perform a gearshift operation by considering the operating load, etc., a heavy load operation requiring a large driving force can continue without stalling the engine. As the driver tends to desire greater acceleration as the load decreases and the rotational speed of the motor increases to near the predetermined fixed rotational speed, a low to high switching command is made and the speed of the vehicle is increased. This avoids the disadvantage of performing a low-to-high switching control resulting in an unexpected acceleration despite the reduction by the driver of the value of the intervention operation on the shift pedal 24 to slow down with a decrease. of the charge. In the high-to-low switching control of the motor 31G swashplate automatic control means, when the switching operation is performed, the vehicle speed is low due to the travel load and it is assumed that the change shock speed is low. As a result, the control for mitigating the shifting shock as in the high-to-low switching control in the 31F motor swashplate control means is not performed. Actuation of the proportional valve 36 for forward or proportional valve 37 for reverse is controlled so that the operation of the engine 17A swash plate switch is made from a high position. speed to a low speed position at the predetermined operational speed. After switching the motor 17A swash plate to a low speed position, this state is maintained for a predetermined period of time (e.g., for 2 seconds). On the other hand, in the low-to-high switching control of the motor 31G swash plate control means, the same control actuation as in the low-to-high switching control in the motor swash plate control means. 31F is performed and the shifting shock generated by the low-to-high switching operation of the swashplate of the motor 17A is attenuated. After switching the motor swashplate 17A to a high speed position, this state is maintained for a predetermined period of time (for example, for 2 seconds). It is also possible to configure the motor 31G swash plate control means to perform the high to low automatic switching control that switches the motor 17A swash plate from the high speed position to the position at the high speed position. low speed and turn on the corresponding indicator lamp 61, when it has been detected that the rotational speed of the motor has decreased to the speed of the low to high switching motor near a predetermined maximum torque output rotation speed or to the low to high switching motor speed region based on the maximum torque output characteristics of the motor 1 and the value of the motor speed drop calculated by the operating program of the automatic control means of the motor. swash plate of the pump 31D and so that it performs a low to high automatic switching control which switches the swash plate of the motor 35 17A from the low speed position to a high speed position, as it is detected that the rotational speed of the motor has increased to the speed of the low to high switching motor near the speed predetermined fixed rotation speed up to the low to high switching motor speed region, based on a motor speed drop value and illuminates the corresponding indicator lamp 62. [0012] The controller 31 includes mode switching means 31H as a control program which switches the control mode executed based on the operation of the mode determining device 64 having a normally open switch on the control panel. display 63. When an ON signal is applied to the input in connection with the pressing on the mode determining device 64, the mode switching means 31H switches the transmission control mode between a manual control mode, a semi-automatic control mode or an automatic control mode and lights indicator lamps 65 to 67 corresponding to each control mode. In the manual control mode, it performs the speed control using the control actuation of the pump swing plate control means 31A and the switch control using the control actuation of the swing plate control means. 31F engine. In the semi-automatic control mode, it performs the speed control using the control actuation of the pump swing plate control means 31A and a load control using the control actuation of the automatic control means of the pump. oscillating plate of the pump 31D and a switching command using the control actuation of the motor 31F swashplate control means, so that priority can be given to the load control as opposed to the speed control . In the automatic control mode, the mode switching means 31H performs velocity control using the control actuation of the pump swashplate control means 31A and a load control using the control actuation of the control means. automatic control of 31D pump swash plate and the automatic switching control using the control operation of the 31G motor swash plate automatic control means so that the priority is given to the load control as opposed to the speed control and that the load control and the automatic switching control are appropriately coordinated. That is, when the manual control mode is selected, the swashplate of the pump 16A is operated based on the operating position of the shift pedal 24, etc., so that reaching the target actuating position corresponding to the operating position of the shift pedal 24 with the target operating speed. The motor 17A swashplate is also switched between the high and low positions based on the operation of the shift lever 59. The swashplate of the pump 16A is operated based on the operating position of the treadle. shifting 24, etc., so as to achieve the target actuation position corresponding to the operating position of the shift pedal 24 with the target operational speed. When a fall in engine speed occurs, based on the value of the engine speed drop, etc., it is also actuated to arrive at the limit operational position corresponding to a speed drop value. of the engine at the target operating speed and the swashplate of the engine 17A is switched between the high and low positions based on the operation of the shift lever 59. When the automatic control mode is selected, the swash plate of the pump 16A is actuated to achieve the target operating position corresponding to the operating position of the shift pedal 24 at the target operating speed. When the engine speed drops, the swashplate of the pump 16A is actuated to arrive at the limit operative position corresponding to a speed drop value of the engine at the target operational speed, based on the value of the speed drop. engine, etc. The swashplate of the engine 17A is also switched between the high and low positions according to a suitable sequencing based on the operating position of the shift pedal 24 or the value of the engine speed drop, etc. [0013] Accordingly, if the manual control mode is selected, for example, for a light load path and load operation or if the semi-automatic control mode is selected by climbing a relatively steep hill and for an operation. of average load or if the automatic control mode is selected by climbing a very steep hill or for a heavy loading operation, this course and this operation can be carried out without increasing the load of the driver. Note that in the load control in the automatic control mode, the lower limit motor speed of a motor 1 is set lower than the load control in the semi-automatic control mode, so that the sensitivity of the control is set to a low level, which tends to cause a drop in engine speed. As a result, the automatic switching control that switches the motor 17A swashplate to a low speed position can be easily performed. In addition, when the operation of the switch in the low speed position of the motor 17A swash plate based on the operation of the shift lever 59 is effected in the automatic control mode, since it is impossible to perform a switching operation in the low speed position of the motor 17A swash plate by an automatic switching command, the control mode automatically switches from the automatic control mode to the semi-automatic control mode. As shown in FIG. 6, the console panel 63 includes the liquid crystal display device 69 where the display can be changed between a vehicle speed display mode and a remaining fuel display mode. etc., based on the operation of the display switching switch 68. This liquid crystal display device 69 displays the target operating position 69A or the limiting operating position 69B and the current position 69C of the oscillating plate of the pump 16A which changes at any time, when the pump swash position display mode is selected by operation of the display swap switch 68. That is, by selecting the pump swash position display mode, the movement of the swashplate of the pump 16A can be easily controlled. It will be appreciated that FIG. 6 (A) shows the case where the target actuation position 69A for acceleration for the swashplate of the pump 16A is fixed. Figure 6 (B) shows the case where the swashplate of the pump 16A is actuated to the target operating position 69A for acceleration. FIG. 6 (C) shows the case where the target actuating position 69A or the limiting operating position 69B for a slowing down of the swashplate of the pump 16A is fixed. When a tool such as a front loader A is set vertically movable with the height sensor 70 having a potentiometer detecting the height position of the tool, the data modification means 31C modifies the map data. , effecting the correlation of the operating position of the shift pedal 24 with the operating position of the swashplate of the pump 16A used by the swinging plate control means of the pump 31A, to the map data. for lifting the tool stored in the pump swash plate control means 31A based on the detected information from the height sensor 70, when the tool is lifted to the position of height greater than the predetermined height (for example, a height position exceeding the height of an automobile). In comparison with the commonly used map data, the map data for the lifting of the tool determines the operating position of the swashplate of the pump 16A for a given operating position of the shift pedal 24 towards a lower speed (see Figure 7). Since the control plate of the pump 31A swash plate uses these map data, the speed of the vehicle is limited to low speeds and high speed travel is prevented when the tool is lifted higher than a fixed height. As shown in FIGS. 4 and 5, the servo-control mechanism 25 comprises a servovalve 27, a regulating valve 28 and the swash plate sensor 30 and the oil temperature sensor 43 which are housed in the housing 71 connected in such a manner. releasable by bolts through the right portion of the second housing portion 4B into a gear housing 4 and is embodied as an electronically actuated unit mechanism 72. This electronically actuated mechanism 72 can be easily replaced by a mechanical type by replacing it with a mechanical unit 76 of the one-piece type by incorporating the operational shaft 73 operatively connected to the gearshift pedal 24 via the wheelhouse mechanism 5 ( not shown) of a type of mechanism as shown in FIGS. 12 and 13 and the servovalve 74 which comprises a slide which controls the flow of the hydrated fluid the element 25 to the cylinder 26 for the pumps in the housing 75 which is connected by bolts to the right part of the second housing part 4B in a gearbox case 4. In addition, the element numbered 77, shown in FIG. Figs. 4 and 12 is a link arm used in the electronic type servo mechanism as a feedback arm provided between the cylinder 26 for the pumps and the swash plate sensor 30 and used in the mechanical servo mechanism. 78, as an actuating / feedback combination arm provided between the cylinder 26 for the pumps and the operating shaft 73 for operating the servovalve 74. In addition, the numbered elements 78 and 79 shown in FIGS. are connection openings formed in the abutting surface against the second housing portion 4B of the housing 71 for connection to the connecting openings 80 and 81 when the electrically actuated mechanism electronics 72 is connected by bolts to the right portion of the second housing portion 4B. As shown in FIGS. 4 and 5, the switching mechanism 54 with the swap valve 56, the control valve 57 and the high pressure selection valve 58, is embodied as a unit in one block. control mechanism 84 due to the fact that it is housed in the housing 83 releasably connected by bolts to the left-hand part of the second housing part 4B of the gearbox housing 4. The device can be modified to a motor specification 30 adjustable to a fixed engine specification relatively simply by replacing the operating mechanism 84 with a plate 85 as shown in Figures 12 and 14 to cover the bonding holes 86-91 formed in the surface with the operating mechanism 84 of the second housing part 4B and replacing the variable capacity motor 17 in the second housing part 4B by the fixed capacity motor 92 and removing the cylinder 55 for engine. In addition, the elements with reference numerals 93 to 98 shown in FIG. 5 are communication ports formed in the surface connected to the second crankcase portion 4B of the housing 83 which are connected to each port. corresponding communication device 86 to 91 of the second housing portion 4B when the switching mechanism 54 is bolted to the left side of the second housing portion 4B. Due to the aforementioned structure, the arrangement can be simply changed between an arrangement having the adjustable motor and the electronic type servo mechanism (see Fig. 5), an arrangement with an adjustable motor and the mechanism mechanical type servo control 78 (see Fig. 13), an arrangement with a fixed motor specification and the electronic servo mechanism 25 (see Fig. 14) and an arrangement with a fixed motor 15 and the servo-control mechanism 78 of the type mechanical (see Figure 15) to reduce costs because elements can be shared and facilitate the management of elements. As shown in FIG. 6, the end regions of the operating zone of the shift pedal 24 can be determined as high speed regions and a region between the two ends as a low speed region. and the motor swashplate control means 31F can be arranged to control the actuation of the control valve 57 based on the sensed information from the pedal sensor 29, so that when the pedal of the speed 24 is actuated to a low speed region, the swashplate of the engine 17A switches to a low speed position and when the shift pedal 24 is actuated to a high speed region, the swashplate of the engine 17A is located in a high speed position to use the shift pedal 24 also as an operational element for a permut The end regions of the operating zone of the shift pedal 24 can be fixed as a high speed region and the control means of the swashplate can be fixed at a high speed region. Motor 31F can be arranged to control actuation of control valve 57, based on the detected information from pedal sensor 29 so that when shift pedal 24 is actuated to a high speed region, the motor swashplate 17A is switched to a high speed position to use the shift pedal 24 also as an operational element for high to low switching of the variable capacity motor 17. Thus, when the shift pedal 24 is also used as an operational element to switch the variable capacity engine 17, a mechanism The expansion valve (not shown) may be provided to indicate the limit of the operating zone of the shift pedal 24. Another embodiment of the present invention is then described. The same reference numbers are used for the same elements as in the above-mentioned embodiment and descriptions of the same elements are not repeated. Cruise speed control (constant speed control) is then described. As shown in FIGS. 1 and 17, the driver station 8 includes the cruise gear lever (cruise operational tool) 143 only for forward gearshift that can be held in a shift position. arbitrary by a friction type holding mechanism (not shown). As shown in FIG. 17, the position of the cruise speed lever 143 is detected by the lever sensor (exemplary holding position detecting means) 144 which includes a potentiometer. A lever sensor 144 outputs the hold position of the sensed cruise lever 143 to the controller 31. As shown in FIG. 17, the control means 31 includes a cruise control 31P. to change the speed depending on the operating position of the cruise control lever 143. As shown in FIGS. 17 and 19, the cruise control means 31P includes map data correlating the flight position. maintaining the cruise control lever 143 with the operational position of 301 7 9 1 7 shift of the swashplate of the pump 16A and a control program which controls the actuation of the proportional valve 36 for forward operation, based on the map data and the detected information from a lever sensor 144, etc. The cruising speed control means 31P map data correlates the operating position of the cruise control lever 143 with the operational shift position of the swashplate of the pump 16A (see FIG. 19). ) so that the higher the actuated value of the cruise control lever 143 from the neutral position (zero speed position) in the direction of the forward speed increase, the greater the operational value of the swash plate of the pump 16A relative to the neutral position in the direction of travel forward is large. The above-mentioned map data may be replaced by a correlation equation correlating the actuating position of the cruise control lever 14 with the operational shift position of the swinging plate of the pump 16A. The control program of the cruise control means 31P determines the operational shift position of the swashplate of the pump 16A corresponding to the holding position of the cruise control lever 143 detected by the lever sensor. 144 as the target operating position of the pump swing plate 16A, based on the stored map data and the sensed information from a lever sensor 144 and controls the actuation of the proportional valve 36 for forward operation. , based on the determined target actuating position and the sensed information from the swash plate sensor 30, so that the target operating position of the swashplate of the pump 16A is in agreement with the operational shift position. real. This allows a control where the forward vehicle speed is adjusted according to the holding position of the cruise control lever 143 simply by operating the cruise gear lever 143 in a desired position against the force. The comparatively low maintenance maintains the cruise control lever 143 in arbitrary operating positions. As shown in FIG. 17, the control means 31 includes a third operational speed determination means 311 for determining the operating speed during a gearshift to the speed dependent on the holding position of the gear lever. 143. As shown in FIGS. 17 and 18, the third operational speed determination means 313 includes an operational program which calculates the deviation from the target operating position of the pump's swashplate 16A and the operating position of the actual speed change based on the target operating position of the pump's swashplate 16A determined by the cruise control 31P and the sensed information from the swash plate sensor 30, a plurality of map data as correlation data performing the correlation of the gap of the action position 16A pump swashplate target and the actual shifting operational position with the operational speed of the swashplate of the pump 16A and a control program which determines the target operational speed of the swashplate of the pump 16A based on these map data and the results of the calculation of an operational program. Each cartographic data of the third operational speed determination means 31J correlates the offset of the pump 16A swashplate with the operational speed of the swashplate of the pump 16A so that when the difference in the operating position of the actual shift of the pump 16A swashplate detected by the swash plate sensor 30 and the target operating position of the swashplate of the pump 16A 30 determined by the cruise control means 31P is large, the speed The operation of the pump 16A swashplate is large and so that the operating speed of the swashplate of the pump 16A by the control actuation of the cruise control means 31P becomes slower than the operating speed of the swash plate. of the pump 16A by the control actuation of the gearshift control means 301 7 9 1 7 47 31A (dashed line in FIG. 18). The aforementioned mapping data can be replaced by the correlation equation as correlation data correlating the deviation from the target operating position of the pump 16A swashplate with the operational change position. actual speed with the operational speed of the 16A pump swash plate. The control program of the third operational speed determination means 313 determines the operating speed of the pump swing plate 16A corresponding to the offset of the calculated pump swash plate 16A as the target operating speed of the pump swash plate. 16A, based on the stored map data and the calculation result of an operational program, and outputs the target operational speed determined by cruise control 31P. The control program of the cruise control 31P is arranged to control the actuation of the proportional valve 36 for forward operation so that the swashplate of the pump 16A is operated at the target operational speed determined by the third operational speed determination means 313. With this command, the operating speed during the shift operation of the swashplate of the pump 16A by operating the cruise gear lever 143 becomes slower than the operating speed when the actuation of the swashplate of the pump 16A by actuation of the gearshift pedal 24. Consequently, by improving the response of the shifting operation by the gearshift pedal 24, it is possible to prevent a rapid variation of the vehicle speed by actuation of the cruise control lever 143, thus making the op cruising speed determination ration by the cruise lever 143 easy to perform. The data modifying means 31C modifies the map data used by the third operational speed determination means 31J, based on the actuating position of the dial of the setting dial 42, into map data performing 301 7 9 7 48 the correlation of the offset of the swashplate of the pump 16A with the operating speed of the swashplate of the pump 16A, so that the greater the value of the actuation of the adjustment dial 42 of the fast side with respect to a reference position is large, the operation of the pump 16A swashplate speed change 5 becomes fast, so that the operational speed of the swashplate of the pump 16A for a given offset of the swash plate of the pump 16A becomes big. It also modifies the map data into data correlating the offset of the swashplate of the pump 16A with the operating speed of the swashplate of the pump 16A so that the value of the operation of the adjustment dial 42 s increases. is performed on the slow side relative to a reference position, the more the speed change operation of the swashplate of the pump 16A slows and so that the operational speed of the swashplate 15 of the pump 16A for a given gap of the plateau 16A pump oscillation becomes slower. That is, by actuating the adjustment dial 42, the sense of actuation of a speed change operation of the hydrostatically-equilibrated variable-speed change-over device 10 with the speed lever of FIG. cruise 143 can be modified according to the wish of a driver as well as the sensation of actuation of the gear shift operation of the hydrostatic-type variable speed-change device by the shift pedal 24, improving thus the actuating sensation or the operational shift response. Fig. 23 shows a curve for the angular position of the pump's swashplate with respect to time when the adjusting dial 142 is set on the fast side and a curve for the angular position of the swashplate of the pump 16A relative to the time during control of the cruising speed and a curve representing the angular position of the swashplate of the pump 16A with respect to time when the setting dial 142 is set on the slow side. As shown in FIG. 17, the control device 31 comprises, as control programs, an actuation switching means 31K which switches the control means to operate, a means of permutation of the 31G notification device which switches the operational state of the notification device 145 comprising a lamp in the driver's station 8 and a cruising speed control stop means 31M to stop the control operation of the control means of the cruising speed 31P. The notification device 145 may be a liquid crystal display device, a buzzer, etc. The operation switching means 31K is configured to execute the next command. It compares the position of target actuation (operational position of shift of the swashplate of the pump 16A corresponding to the position of actuation of the shift pedal 24) of the swashplate of the pump 16A determined by the command of the shift control means 31A with the target operating position (operational shift position of the swashplate of the pump 16A corresponding to the holding position of the cruise control lever 143) of the swashplate of the pump 16A determined by the control actuation of the cruise control 31P. The control means is modified based on the comparison so that the control means (between the shift control means 31A and the cruise control means 31P) for which the speed corresponding to the target actuation position is greater. The permutation means of the notification device 31L performs the following command. The notification device 145 is turned off based on the detected information from the pedal sensor 29 or the sensed information from a lever sensor 144, etc., when it detects that the cruise control lever 143 is in the neutral position and when a shift pedal intervention operation 24 is detected, the cruise lever 143 being detected as being in the neutral position. The notification device 145 is turned on based on the detected information from the pedal sensor 29, the detected information from a lever sensor 144, etc. when it detects that the operational shift position 301 7 9 1 7 of the swashplate of the pump 16A corresponding to the holding position of the cruise control lever 143 is on the acceleration side relative to the operational position of the shift of the swashplate of the pump 16A corresponding to the position of actuation of the shift pedal 24. The notification device 145 (turned on and off in succession) is flashed based on the detected information from the pedal sensor 29, the detected information from a lever sensor 144, etc., while it is detected that the cruise control lever 143 is located in the remote operating position from the neutral position etc. It is detected that the operational shift position of the swashplate of the pump 16A corresponding to the operating position of the shift pedal 24 is in the operational position of shifting of the swashplate of the corresponding pump 16A. at the holding position of the cruise control lever 143 or the acceleration side with respect to the operational shift position. The cruise control 31M is set to perform the next command. When the intervention operation to the speed change region in reverse of the shift pedal 24 is detected, based on the detected information from the pedal sensor 29 during the forward operation in speed cruiser under the control of the cruise control 31P or when both pedals of the pair of side brake pedals 147 in the driver's station 8 are detected to be actuated based on the sensed information from the sensor 146, the actuation of the proportional valve 36 for the forward direction is controlled so that the swashplate of the pump 16A is actuated to the neutral position at the operating speed for a speed control stop of predetermined cruise. At this time, unless actuation to the neutral position of the cruise control lever 143 is detected on the basis of the sensed information from a lever sensor 144, the control actuation of the control means of 31P cruise speed is stopped. [0014] In addition, when sensing information from a lever sensor 144 when a motor 1 starts is detected, the cruise lever 143 is not located in the stitch position. dead or when a cruise control lever acceleration actuation 143 is detected based on the sensed information from a lever sensor 144 when traveling in reverse, the control actuation of the control means 31P cruising speed is stopped until it detects the operation of the cruise control lever 143 in the neutral position. If the shift pedal 24 is operated forward forwards, while the cruise gear lever 143 is in the neutral position, the swashplate of the pump 16A is operated in a position on the side. forward acceleration corresponding to the operating position of the shift pedal 24 and the body of the vehicle is advancing at the speed depending on the operational shift position. When this occurs, the notification device 145 is turned off to notify that the system is in the normal state of progress when performing a shift operation only by the shift control means 31A. If the shift pedal 24 is operated on the reverse side while the cruise control lever 143 is in the neutral position, the swashplate of the pump 16A is actuated to the operational shift position. speed on the reverse side corresponding to the position of actuation of the gearshift pedal 24 and the vehicle body retreats at the speed imposed by the operational shift position. The notification device 145 is also extinguished in the case where it is notified that the system is in the normal state of progress. If a pivoting operation is effected in the direction of the acceleration of the cruise control lever 143, the shift pedal 24 being in the neutral position, the swashplate of the pump 16A changes speed towards the gear shift operational position on the forward acceleration side corresponding to the cruising lever position 301 7 9 1 7 52 143 and the vehicle body travels forward at cruising speed , at the speed determined by the operational shift position. In this case, the notification device 145 is turned on to notify that the system is in the forward state at cruise speed under the control of the cruise control 31P. If the cruise control lever 143 pivots in the direction of the acceleration during a forward travel by actuation of the shift pedal 24, the body of the vehicle 10 advances at a speed corresponding to the operating position of the shift pedal 24 until the target operating position (target operating position of the cruising speed control means 31P) of the swashplate of the pump 16A determined by the command of the control means 31P is the acceleration side with respect to the target actuation position (target actuation position of the shift control means 31A) of the pump 16A swashplate determined by the shift control means 31A. Meanwhile, the notification device 145 turns off to notify that the system is in a normal travel state. At this time, if the target actuation position in the cruise control means 31P is on the acceleration side rather than the target actuating position in the speed change control means 31A by an operation. pivoting in the direction of the cruise control gear acceleration 143 or the gearshift pedal deceleration operation 24, the vehicle body is advanced at the speed dependent on the operating position of the gear lever 143, which results in the cruising speed depending on the holding position of the cruising speed lever 143. In this case, the notification device 145 is lit to notify that the system is in the state. cruising speed in the forward direction. If the shift pedal 24 is operated in the forward acceleration direction during the forward cruise state based on the operation of the cruise control lever 143, the vehicle travels to the cruise speed at the speed dependent on the holding position of the cruise control lever 143 until the target operating position determined by the shift control means 31A is the same as the position of target actuation determined by the cruise control 31P or the acceleration side with respect to the target operating position determined by the cruise control 31P. [0015] Meanwhile, the notification device 145 is turned on to notify that the system is in the cruising state in the forward direction. At this time, the vehicle is advancing at the speed depending on the operating position of the shift pedal 24 if the target operating position determined by the shift control means 31A becomes the same as the driving position. target actuation determined by the cruise control 31P or is on the acceleration side with respect to the target operating position determined by the cruise control 31P by actuating the cruise control pedal 31P. shifting 24 in the direction of the acceleration course forward. In this case, the notification device 145 flashes to notify that the system is in the acceleration priority state when priority is given to the shift operation by the control of the shift control means 31A. in the forward cruise state by the cruise control 31H control means. At this time, if the target actuation position of the shift control means 31A is on the deceleration side with respect to the target actuating position in the cruise control means 31P by the actuation of deceleration of the gearshift pedal 24, the vehicle again makes a course at the cruising speed at the speed depending on the holding position of the cruise control lever 143. 301 7 9 1 7 54 In this case, the Notification device 145 illuminates to notify that the system is in the cruising state in forward gear. If the shift pedal 24 is actuated in the direction of the acceleration path in reverse or the two side brake pedals 147 are operated in the cruising speed state in the forward direction when actuating the cruise control lever 143, the vehicle speed is progressively slowed down to the speed determined by the position of actuation of the shift pedal 24 from the speed determined by the holding position of the cruise control lever 143 and the vehicle is advancing at the speed as a function of the operating position of the shift pedal 24. In this case, the notification device 145 is turned off to notify that the system is in the normal travel state. After having actuated the shift pedal 24 in the direction of the acceleration path in reverse or after the two side brake pedals 147 are operated in the cruising speed state in reverse, based on the actuation of the cruise control lever 143, it becomes possible to carry out the journey 20 at the cruising speed in the forward direction of the vehicle at the speed which is a function of the operating position of the cruise control lever 143 by lowering the lever cruising speed 143 in the neutral position. The speed-keeping mechanism A comprises the cylinder 26 for the pumps, a regulating valve 28, the swash plate sensor 30, the control device 31, the proportional valve 36 for the forward direction, the cruise control lever 143 , the lever sensor 144, etc. The above-mentioned structure allows advantageous coordination between the gearshift pedal 24 and the gearshift operation by the cruise control lever 143 while the driver is informed of the speed change operation. the progress made by these operations. A return mechanism in the neutral position may be provided which, for example, may include an electromagnetic cylinder, etc., so that the cruise control lever 143 is automatically returned to the neutral position, when the shift pedal 24 is actuated in the direction of the acceleration path in reverse or after the two side brake pedals 147 are operated in the forward cruising state based on the actuation the cruise control lever 143, so as to further improve the gearshift operation. As shown in FIGS. 20 and 21, the brake sensor 146 includes a single normally closed switch 148 and a pair of angled links 149. The bent links 149 are arranged between the coordinated arm 147A and the brake pedal on the corresponding side 147 and the panel frame 50 located in front of the side brake pedal 147 so as to extend and contract. The normally closed switch 148 is maintained in the open state by the bearing operation by the two bent links 149 in the braking state where the two side brake pedals 147 are not actuated [see Fig. 20]. During the rotational braking state where one of the side brake pedals 147 is depressed, the circuit is held open by the pressure operation by the elbow connection 149 connected to the side brake pedal 147 which is not actuated. [see Figure 21 (A)]. In the braking state where the two side brake pedals 147 are actuated, the circuit returns to a closed state due to the fact that neither of the two bent links 149 is depressed on the switch [see FIG. 21 (B )]. [0016] That is, a simple structure having the single normally closed switch 148 for a pair of side brake pedals 147 can provide reliable detected information based upon the actuation of the two brake pedals 147. When 16A pump swash plate speed change operation is performed by the electronic type servo drive mechanism 25 as shown in Fig. 24, a hysteresis occurs between the operating position of the swashplate of the pump 16A and a pressure servo control (operational physical force on the swashplate of the pump 16A). Accordingly, when the shift operation of the swashplate of the pump 16A is effected by the control actuation of the shift control means 31A on the basis of the operation of the the shift pedal 24 without taking into account this hysteresis, when the switching between the acceleration operation and the deceleration by the shift pedal 24 is performed, the difference of the servo-control pressure at the time of the acceleration actuation to the current position of the swashplate of the pump 16A and the servocontrol pressure at the time of the deceleration operation by the hysteresis causes the maintenance of the swashplate of the pump 16A despite the actuation of the 10 shift pedal 24 in a current position until the difference is canceled by actuation of the actuating mechanism 25 based on the actuation 24. That is, in the rear shift operation by the shift pedal 24, the response of the swash plate of the pump 16A decreases and the driver can feel the opposite effect. For this purpose, as shown in FIG. 17, the control device 31 comprises the compensation means 31Q which compensates for the difference between the servo-control pressure at the moment of the acceleration actuation up to the current position of the swash plate. of the pump 16A and the servo control pressure at the time of the deceleration operation during the deceleration acceleration operation by the shift pedal 24. The compensation means 31Q includes an operational program which calculates the position after the fixed period of time of the shift pedal 24, based on the information detected from the pedal sensor 29, the correlation data correlating the servo-control pressure at the moment of the actuation. acceleration for a given operating position of the swashplate of the pump 16A with the servo-control pressure at the time of operation deceleration ration, and a control program that controls the actuation of a servo valve 27, based on the result of the calculation of the operational program and the correlation data. [0017] Based on the information detected from the pedal sensor 29, the operating program of the compensating means 31Q detects the current position 0 of the shift pedal 24 and calculates the operating speed w and predicts the actuating position 13 (= O + cot) of the shift pedal 24 after a fixed time based on these detection results and calculation results. Since the correlation data of the compensation means 31Q has a value (average value) Ai of the difference of the current value la supplied to a servovalve 27 at the time of the acceleration actuation and the current value Ib supplied to a servovalve 27 at the time of the deceleration operation for a given actuating position 10 of the oscillating plate of the pump 16A which is required to compensate for the difference between the servo-control pressure Fa at the time of the acceleration actuation and the pressure Fb servo control at the time of the deceleration operation for a given operating position of the swash plate of the pump 16A. [0018] The control program of the compensation means 31Q compares the predicted actuating position [3, which is the calculation result of the operational program, with the current position 0, and controls the actuation of the servo-valve 27 so that the difference Af of the servo pressure Fa at the time of the acceleration actuation and the servo pressure Fb at the time of the deceleration operation for the current position of the swashplate of the pump 16A is compensated based on the data. correlation when the difference exceeds the predetermined setting a. More specifically, when the forward deceleration operation from the forward acceleration actuation of the shift pedal 24 is detected based on the sensed information from the pedal sensor 29, the current position 0 of the shift pedal 24 obtained is compared to the predicted actuating position [3, which is the result of the calculation of the operational program. When the difference becomes greater than the predetermined value 03 <0.a), to decrease the servo-control pressure F corresponding to the current position of the swashplate of the pump 16A rapidly from the servo-control pressure Fa at the moment of actuation acceleration to the servo-control pressure Fb at the time of the deceleration operation, the current is immediately decreased to the current value Ib to obtain the servo-control pressure Fb at the time of the operation. deceleration corresponding to the current position of the swashplate of the pump 16A by subtracting the difference value Ai from the current value la to obtain the servo-control pressure Fa at the time of the acceleration actuation corresponding to the current position of the plate oscillating pump 16A. When a switch to the accelerating operation in the forward direction since the forward deceleration operation of the shift pedal 24 is detected based on the detected information from the pedal sensor 29, the position current 8 of the shift pedal 24 obtained at this time is compared to the predicted actuating position p, which is the calculation result of an operational program. When the difference becomes greater than the predetermined value (f3> 0.a), to increase the servo control pressure F corresponding to the current position of the swashplate of the pump 16A rapidly from the servo pressure Fb at the time of operation from deceleration to the servo-control pressure Fa at the time of the deceleration operation to the servo-control pressure Fa at the moment of the acceleration actuation, the current is immediately increased to the current value la to obtain the pressure of the servocontrol Fa at the time of the acceleration actuation corresponding to the current position of the swashplate of the pump 16A by adding the value of the difference Ai to the current value Ib to obtain the servocontrol pressure Fb at the moment of the deceleration operation corresponding to the current position of the swashplate of the pump 16A. When switching to the reverse deceleration operation from the reverse acceleration actuation of the shift pedal 24 is detected based on the sensed information from the pedal sensor 29, the current position e of the shift pedal 24 obtained at this time is compared to the predicted actuation position p, which is the calculation result of an operational program. When the difference becomes greater than the predetermined setting (8 <0.a), to decrease the servo control pressure F corresponding to the current position of the swashplate of the pump 16A rapidly from the pressure of 301 7 9 1 7 59 servo Fa at the time of the acceleration actuation up to the servo pressure Fb at the time of the deceleration operation Fb, the current is immediately reduced to the current value Ib to obtain the servo control pressure Fb at the moment of the deceleration operation corresponding to the current position of the swashplate of the pump 16A by subtracting the difference value Ai from the current value la to obtain the servo-control pressure Fa at the time of the acceleration actuation corresponding to the position current of the swashplate of the pump 16A. [0019] When the switching to the reverse acceleration operation from the reverse deceleration operation of the shift pedal 24 is detected based on the detected information from the pedal sensor 29, the current position 0 of the subsequent shift pedal 24 is compared with the predicted actuation position 13, which is the result of the calculation of the operational program. When the difference becomes greater than the predetermined setting ((> 0.a), to increase the servo-control pressure F corresponding to the current position of the swashplate of the pump 16A rapidly from the servo-control pressure Fb at the time of the deceleration to the servo-control pressure Fa at the time of the acceleration actuation, the current is immediately increased to the current value la to obtain the servo-control pressure Fa at the moment of the acceleration actuation corresponding to the position current of the swashplate of the pump 16A by adding the value of the difference Ai to the current value Ib to obtain the servo-control pressure Fb at the moment of the deceleration operation corresponding to the current position of the swashplate of the pump 16A As a result, in the deceleration operation in operation 30 forward after switching to the downward slowing forward since the acceleration forward of the gearshift pedal 24, the servo control pressure Fa corresponding to the swashplate of the pump 16A decreases to the servo-control pressure Fb at the time of the forward deceleration operation corresponding to the operating position of the shift pedal 24 quickly with the operation of the shift pedal 301 7 9 1 7 60 24, improving the response of the deceleration operation of the swash plate of the pump 16A to the operational shift position for the forward gear corresponding to the operating position of the shift pedal 24. [0020] In the forward acceleration actuation after switching to the forward acceleration since the forward slowing down of the shift pedal 24, the servo pressure Fb for the swashplate of the pump 16A increases. rapidly with the operation of the shift pedal 24 10 to the servo-control pressure Fa at the time of the forward acceleration actuation corresponding to the actuation position of the shift pedal 24, improving the response of the pump 16A swash plate acceleration actuation to the forward gear shift operational position corresponding to the operating position of the shifting pedal 24. In FIG. reverse deceleration operation after switching to deceleration in reverse since acceleration in reverse of the engine pedal. In the case of the speed shift 24, the pressure of the servo-controller Fa towards the swashplate of the pump 16A decreases rapidly to the servo-control pressure Fb at the moment of the reverse deceleration operation corresponding to the position of actuation of the pedal. with the operation of the shift pedal 24, improving the response in a deceleration operation of the swashplate of the pump 16A to the operational gearshift position for reverse gear corresponding to the position of actuation of the shift pedal 24 by the response. In the reverse acceleration operation after switching to acceleration in reverse since the reverse deceleration of the shift pedal 24, the servo pressure Fb for the swashplate of the pump 16A increases. rapidly with the operation of the shift pedal 24 to the servo-control pressure Fa at the time of the reverse-acceleration actuation corresponding to the operating position of the shift pedal 24, improving the response in the acceleration actuation of the swashplate of the pump 16A to the operational position of shifting for reverse gear corresponding to the operating position of the shifting pedal. speed 24. [0021] That is, since the ability to perform a shift operation of the swashplate of the pump 16A by considering the hysteresis that exists between the operating position of the swashplate of the pump 16A and a servo control pressure, by the electronic type servocontrol control mechanism 25, the response delay of the pump hinged platen 16A can be effectively controlled, improving the response quality to the actuation of the hysteresis. driver. The hysteresis that exists between the operating position of the swashplate of the pump 16A and a servo pressure is influenced by the temperature of the hydraulic fluid supplied to the cylinder 26 for the pumps. The lower the temperature of the hydraulic fluid, the lower the difference M of the servo-control pressure Fa at the time of the acceleration actuation to the actuation position of the swashplate of the pump 16A and the servo-control pressure Fb at the moment the deceleration operation becomes large. Accordingly, the hydraulic circuit to the cylinder 26 for the pumps includes the oil temperature sensor 43 which senses the temperature of the hydraulic fluid supplied to a regulating valve 28. The compensation means 31Q also takes into consideration the fact that the higher the the temperature of the hydraulic fluid supplied to a regulating valve 28 is low, plus the difference M of the servo-control pressure Fa at the moment of the acceleration actuation to the operating position of the swashplate of the pump 16A and the pressure of Fb servocontrol at the time of the deceleration operation becomes large. The compensating means 31Q is also configured to change the value of the difference Δi between the current value la supplied to a servovalve 27 at the time of the acceleration actuation and the current value Ib supplied to a servovalve 27 at the moment. of the deceleration operation, based on the detected information from the oil temperature sensor 43. [0022] To further describe, the compensation means 31Q includes the mapping data correlating the temperature of the hydraulic fluid supplied to a regulating valve 28 with the correction coefficient which compensates for the difference value of the current. Have. The mapping data correlates the temperature with the correction coefficient of the hydraulic fluid such that the lower the temperature of the hydraulic fluid, the larger the value Ai of the difference of a current value becomes. The control program of the compensation means 31Q also selects the correction coefficient as a function of the temperature of the hydraulic fluid, on the basis of the detected information from the map data and the oil temperature sensor 43 and multiplies the value Ai of the difference of a current value by the correction coefficient, so that the value Ai of the difference of a current value is corrected to the correct value as a function of the temperature of the hydraulic fluid at that moment. That is, in response to the fact that the lower the temperature of the hydraulic fluid supplied to the regulating valve 28, the lower the difference Af of the servo-control pressure Fa at the time of the acceleration actuation, at the operating position of the swash plate of the pump 16A and the servo pressure Fb at the time of the deceleration operation becomes large. The current difference value Δ 1 is also correspondingly modified to a larger value. [0023] Thus, when the accelerating or decelerating operation by the shift pedal 24 is detected, the servo pressure F corresponding to the current position of the swashplate of the pump 16A can be rapidly changed to the corresponding servo pressure. to the shift operation 30 after the switching actuation regardless of the temperature of the hydraulic fluid supplied to the cylinder 26 for the pumps. Accordingly, this allows a speed change operation that can control the response delay by considering the hysteresis variation by the temperature of the hydraulic fluid supplied to the cylinder 26 for the pump 16A's swashplate pumps. [0024] The control device 31 comprises, as a control program, the control means which requests a start and a stop of the control operation by means of shift control 31A. [0025] The control means provides a command to stop the control by means of shift control 31A when it is detected that the shift pedal 24 is actuated in the neutral position based on the detected information from the pedal sensor 29, if it is detected that the oscillating plate of the pump 16A has arrived in the adjustment position near the predetermined dead point position, based on the information detected from the swash plate sensor 30 and if detecting that the speed of the vehicle has decreased to the fixed low speed set in advance, based on the output of the vehicle speed sensor (speed sensing means) 50 which detects the speed of the vehicle according to the output rotational speed of the gear type gearshift device 11. The gearshift control means 31A is also controlled to stop the control when it has not been detected that the shift pedal 24 has been actuated in the neutral position based on the sensed information from the pedal sensor 29 and that the oscillating plate is detected. of the pump 16A has been actuated to the region of the opposite gear shift operation beyond the neutral position, based on the sensed information from the swash plate sensor 30. That is, that when the shift pedal 24 arrives in the neutral position by the decelerating operation of the shift pedal 24, the swashplate of the pump 16A 30 is actuated to the position of the operation of shifting (neutral position) corresponding to the neutral position of the shift pedal 24 by the control actuation of the shift control means 31A based on the act and ionizing and by the thrust force of the forward deceleration spring 32 or the reverse deceleration spring 33. [0026] 301 7 9 1 7 64 When the swash plate of the pump 16A reaches the adjustment position close to the predetermined neutral position by this deceleration operation, it is determined whether the speed of the vehicle has decreased to the predetermined fixed speed . When it has not decreased to a set speed, the control operation of the shift control means 31A continues. On the other hand, if the vehicle speed has decreased to the predetermined set speed, the shift control means 31A stops the control operation and the swashplate of the pump 16A moves to the control position. dead point by the thrust force of the deceleration spring in forward 32 or the deceleration spring in reverse 33. In addition, until the moment the gear shift pedal 24 has arrived in the neutral position by the decelerating operation of the shift pedal 24 or when it reaches the neutral position, if the swashplate of the pump 16A is actuated to the shift operation region to the opposite side of the beyond the neutral position, the shift control means 31A interrupts the control operation, so that the swashplate of the pump 16A moves to the neutral position by the thrust force of the forward deceleration spring 32 or the reverse deceleration spring 33. Various settings are possible for the fixed speed. It is here set at a sufficiently low speed so that the swash plate of the pump 16A is not actuated in the direction of acceleration by the inertia of advancement against the thrust of the deceleration spring in motion Thus, despite the difference between the swashplate of the pump 16A and the swash plate sensor 30 caused by the lapse of time, when the shift pedal 24 is in the neutral position, the swashplate of the pump 16A is reliably located in the neutral position. This avoids a problem where the vehicle is advancing despite the shift pedal 24 being in the neutral position due to the disagreement between the swashplate of the pump 16A and the swash plate sensor 30. In these circumstances, since the speed of the vehicle is sufficiently low, the acceleration actuation of the swashplate of the pump 16A caused by the inertia during the course is also avoided. When the swashplate of the pump 16A is in the neutral position by the pushing force of the forward deceleration spring 32 or the reverse deceleration spring 33, the control means compares the neutral position. actual (zero velocity actual position) of the swashplate of the pump 16A detected by the swash plate sensor 30 to the fixed dead position 10 (fixed zero velocity position) of the swashplate of the pump 16A which has been fixed from to match the neutral position of the shift pedal. When it is detected that the shift pedal 24 is actuated in the direction corresponding to the direction in which the actual dead point position of the oscillating plate of the pump 16A is displaced relative to the fixed neutral position of the plate oscillating from the pump 16A based on the detected information from the result of the comparison and the pedal sensor 29, the control means requests the interruption of the control by the shift control means 31A to that the gearshift pedal 24 arrives at the actuating position corresponding to the actual neutral position of the swashplate of the pump 16A. When the shift pedal 24 arrives at an actuation position corresponding to the actual dead point position of the swashplate of the pump 16A, the shift control means 31A is instructed to begin control. On the other hand, if it is detected that the shift pedal 24 is actuated in the direction opposite to the direction corresponding to the direction in which the actual dead point position of the swashplate 30 of the pump 16A is displaced by relative to the fixed dead position of the swashplate of the pump 16A, the shift control means 31A is requested to initialize the command. Thus, when the acceleration actuation of the shift pedal 24 is effected in the direction corresponding to the direction in which the actual zero speed position of the swashplate of the pump 16A is displaced relative to the position of the fixed speed of the pump 16A swashplate, the swashplate of the pump 16A moves into the neutral position by the thrust force of the forward deceleration spring 32 and the reverse deceleration spring 33 up to the shift pedal 24 arrives at the actuating position corresponding to the actual zero speed position of the swashplate of the pump 16A. When the shift pedal 24 arrives at the actuating position corresponding to the actual zero speed position of the swashplate of the pump 16A, the shift control means 31A also starts the control. The acceleration actuation of the swashplate of the pump 16A as a function of the actuation of the shift pedal 24 is effected by the control against the thrust force of the forward deceleration spring 32 or of the deceleration spring 15 in reverse 33. On the other hand, when the accelerating actuation of the shift pedal 24 is made in the direction opposite to the direction corresponding to the direction in which the position of zero speed The actual displacement of the swashplate of the pump 16A is shifted with respect to the zero speed setting position of the swashplate of the pump 16A, the shift control means 31A starts the control and an acceleration actuation of the swash plate. of the pump 16A as a function of the actuation of the shift pedal 24 is made against the thrust force of the deceleration spring in Thus, this solves the problem such as during the acceleration actuation from the zero velocity position of the shift pedal 24, the swash plate of the The pump 16A is actuated in the opposite direction to the direction of manipulation of the shift pedal 24 due to disagreements between the swashplate of the pump 16A and the swash plate sensor 30 caused by the flow. time, causing the vehicle to move in the opposite direction to the direction of manipulation of the gearshift pedal 24. 35 [Other Embodiments] 301 7 9 1 7 67 [1] The work vehicle may be an overlapping type rice planting machine, an overlapping type mowing machine or a forestry loader. [2] The continuously variable speed change device 5 may be of the belt type, etc. [3] The correlation data may include a plurality of correlation equations that correspond to various conditions and / or may include multipliers corresponding to various conditions. [4] A planetary gear transmission may be used in place of the variable step speed device 11. [5] An electric cylinder, an electric cylinder or a hydraulic motor, etc., may be used as a control means 55. [6] The shift control 24 may be a shift lever, etc.
权利要求:
Claims (4) [0001] REVENDICATIONS1. A speed control structure for a work vehicle comprising: a shift operation member (24) configured to automatically return to a zero speed position; means for detecting the position which has been applied to the shifting operational member (24); a constant speed operational element configured to be held in any actuated position; position detecting means held to detect the held position of the constant velocity operating element; a continuously variable speed change device (10) which receives energy from the engine (1) of the work vehicle; A shift position detecting means (30) for detecting the position of the shifting operation of a shifting operational member (24) of the continuously variable shifting device (10) ; operational means (16A) for operating the shift operational element (24); control means (31) for controlling the operating means (16A); characterized in that the control means (31) determines a target shift operational position based on information detected by the held position detecting means and information detected by the shift position detecting means ( 30) and based on correlation data correlating the held position with the operational shift position and controls the operating means (16A) such that the shift operational member (24) is moved. to the target shift operational position. [0002] A speed control structure according to claim 1, characterized in that the control means (31) determines a target operational speed based on correlation data correlating the difference between the operational shift position. detected by the shift position detection means (30) and the target shift operational position, with an operational speed of the shift control element, and controls the operating means (16A) of such that the shift control element is operated at the target operating speed. [0003] A method of controlling the speed of a work vehicle, the work vehicle having a shift operative member (24) configured to automatically return to a zero speed position; means for detecting the position which has been applied to the shifting operational member (24); a constant speed operational element configured to be held in any actuated position; position detecting means held to detect the held position of the constant velocity operating element; a continuously variable speed change device (10) which receives energy from the engine (1) of the work vehicle; a shift position detecting means (30) for detecting the operational shift position of an operational shift member (24) of the continuously variable shifter (10); operational means (16A) for operating the shift operation element (24); control means (31) for controlling the operational means (16A), the method comprising the steps of: determining a target shift operational position based on information detected by the held position detecting means and the information detected by the shift position detecting means (30) and based on correlation data correlating the held position with the operational shift position; and controlling the operating means (16A) such that the shifting operational member (24) is brought into the target shift operational position. [0004] A method according to claim 3, characterized by determining a target operational speed based on correlation data correlating the difference between the actual gear shift operational position detected by the change position detecting means. the speed (30) and the target gearshift operational position, with an operational speed at which the shift control member is actuated; and controlling the operating means (16A) such that the shift operating member (24) is operated at the target operating speed.
类似技术:
公开号 | 公开日 | 专利标题 FR3017917B1|2019-06-28|SPEED CONTROL STRUCTURE AND METHOD FOR WORK VEHICLE FR2891605A1|2007-04-06|Load control structure for work vehicle e.g. tractor, has control device controlling pump swash plate such that operating position of continuously variable speed change device moves to limit operating position FR2891338A1|2007-03-30|CHARGE CONTROL STRUCTURE FOR VEHICLES FOR MAJOR WORKS. US6849028B2|2005-02-01|Propelling transmission control apparatus for a working vehicle having a hydrostatic stepless transmission JP4436647B2|2010-03-24|Hydraulic drive vehicle travel control device and hydraulic drive vehicle KR100563537B1|2006-03-27|Change Speed Control System FR2806455A1|2001-09-21|HYDRAULIC CONTROL SYSTEM FOR CONTINUOUSLY VARIABLE TRANSMISSION JP4568669B2|2010-10-27|Work vehicle load control structure JP3999618B2|2007-10-31|Hydraulic drive vehicle travel control device and hydraulic drive vehicle JP4585417B2|2010-11-24|Tractor load control structure JP2007092953A|2007-04-12|Operating oil supply structure of working vehicle JP4838072B2|2011-12-14|Automatic transmission structure of tractor JP4585495B2|2010-11-24|Work vehicle load control structure JP5364196B2|2013-12-11|Work vehicle load control device JP2007092954A|2007-04-12|Shift operation structure of working vehicle JP4580320B2|2010-11-10|Work vehicle load control structure JPH1054450A|1998-02-24|Working vehicle
同族专利:
公开号 | 公开日 CN1940353A|2007-04-04| KR20070037317A|2007-04-04| JP4528238B2|2010-08-18| FR2891604B1|2016-02-12| FR3017917B1|2019-06-28| KR100819955B1|2008-04-07| FR2891604A1|2007-04-06| CN100501196C|2009-06-17| US20070137338A1|2007-06-21| JP2007092950A|2007-04-12| US7613560B2|2009-11-03|
引用文献:
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法律状态:
2015-09-10| PLFP| Fee payment|Year of fee payment: 10 | 2016-09-23| PLFP| Fee payment|Year of fee payment: 11 | 2017-09-07| PLFP| Fee payment|Year of fee payment: 12 | 2018-08-06| PLFP| Fee payment|Year of fee payment: 13 | 2018-10-05| PLSC| Search report ready|Effective date: 20181005 | 2019-08-21| PLFP| Fee payment|Year of fee payment: 14 | 2020-08-12| PLFP| Fee payment|Year of fee payment: 15 | 2021-08-12| PLFP| Fee payment|Year of fee payment: 16 |
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申请号 | 申请日 | 专利标题 JP2005286074|2005-09-30| JP2005286074A|JP4528238B2|2005-09-30|2005-09-30|Speed control structure of work vehicle| FR0654007A|FR2891604B1|2005-09-30|2006-09-28|SPEED CONTROL STRUCTURE AND METHOD FOR WORK VEHICLE| 相关专利
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