Gearshift for manually-controlled gearboxes

专利摘要:
This invention relates to a gear shifting device for manual gearboxes. For gear shifting such gearboxes relatively great force is required, which the driver has to invest for every shifting operation. The shifting procedure, therefore, can be a very tiresome and exacting work for drivers of vehicles with manual gearboxes. In order to simplify and facilitate such shifting work, the present gear shifting device is equipped with a side position cylinder (2a,202) with a piston rod (11,203), which is connected to the shifter of the gearbox and movable to different predetermined positions for adjusting the shifter to a side position point corresponding to the selected gear, and a shift point cylinder (2b,204) with a piston rod (14,205), which is connected to the shifter of the gearbox and movable to different positions for moving the shifter to a shift point corresponding to the selected gear by swinging the shifter in one direction or the other, and means are provided to prevent the movement of said piston rods until declutching has taken place and to prevent return of the clutch to traction position until the gear has been engaged in the gearbox.
公开号:SU1648245A3
申请号:SU813370050
申请日:1981-12-11
公开日:1991-05-07
发明作者:Бострем Карл-Йохан
申请人:Karl Jokhan Bostrem；
IPC主号:

专利说明:

one
(21) 3370050/11
(86) PCT / SE 81/00113 (13.04.81)
(22) 11.12.81
(31) 8002794-9; 8006835-6
(32) 04/14/80; 09/30/80
(33) SE
(46) 07.05.91. Nyup. I 17
(71) Karl-Johan Vostrei
(72) Karl-Johan Bostrem (SE) (53) 629.113 (088.8)
(56) USSR Author's Certificate No. 121352, cl. In 60 K 41/08, 1958.
(54) TRANSMISSION SWITCHING DEVICE FOR MANUAL TRANSMISSION GEARS
(57) The invention relates to a gear shift device for manual shift gearboxes. The purpose of the invention is to increase efficiency by facilitating manual gearbox gear shifting. The gearshift device (SCP) contains a lateral position cylinder 8 with an axis that

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it is combined with the gearshift lever of the gearbox and is able to move to different predetermined positions to set the gearshift lever to the side position point corresponding to the gear selected. The USH also contains a cylinder 9 of a shift point with a piston valve, which is connected to the gearshift lever of the gearbox and has the ability to move to different predetermined positions to move the shift lever. The invention relates to a gearshift device for manual gearboxes that includes a gearbox. range selector control, at least for engaging reverse gear, forward gear and neutral position, and shifter leash, unified with the gear lever and driven by a bandwidth control unit.
The purpose of the invention is to increase efficiency by facilitating manual gearbox gear shifting.
Figure 1 shows the gearshift device, top view; 2 shows a gearshift cylinder, a longitudinal section; on fig.Z - section aa in figure 2; FIG. 4 is a section B — H in FIG. 2; on FIG. 3 is a section B-B in FIG. 4; figure 6 - connecting cylinder, longitudinal section; 7 is a hydraulic circuit diagram of the device; Fig. 8 is a hydraulic diagram of the valve of the lateral position when the reverse gear is engaged, first or sixth gear; 9 - the same, with the inclusion of the fourth, fifth, ninth or tenth transmission; Fig. 10 is a hydraulic connection circuit for a distribution control valve; in fig. 11 is a hydraulic connection diagram for a shift point valve; Fig. 12 illustrates the hydraulic circuit for connecting the cylinder of the shift point when the first gear is engaged; 13 shows the gears being guided into the gearshift point corresponding to the gear selected by turning the gearshift lever in one or the other direction, and means for preventing porganev cylinder rods 8 and H from moving until the clutch is disengaged and for preventing the clutch from returning to the traction position until the transmission is engaged in the transmission. 1 hp f-ly, 33 ill.
ska clutch valve connection circuit; Fig. 14 is a hydraulic circuit for connecting the valve of the shift point when the second gear is engaged; Fig. 15 is a hydraulic circuit for connecting the cylinder of the shift point when the second gear is engaged; Fig. 16 is a hydraulic clutch valve interlocking circuit; Fig. 17 shows a gear shift device installed in a vehicle with a manual gear shift and equipped with a gear shift device for semi-automatic or fully automatic gear shift, horizontal section; Fig. 18 shows a distributor included in the gear shift device, a section; on Fig - section GG on Fig; on Fig - section dD on Fig; FIG. 21 is a section view E — E of FIG. 18; on Fig-section on Fig; Fig. 23 illustrates a hydraulic wiring diagram of a gear shifting device for semi-automatic or fully automatic gear shifting of a five-speed gearbox; Fig. 24 is a hydraulic wiring diagram of a gear shifting device for a ten-speed gearbox; Figure 25 is a hydraulic wiring diagram for a gear shift device for passenger cars; Fig. 26 shows a combination of a vehicle comprising at least two drive engines and two gearboxes, to illustrate the additional use of a gear shifter, side view; FIGS. 27 and 28 are a hydraulic wiring diagram of a modification of a gear shift device intended for semi-automatic shifting of a six or twelve-speed manual transmission; Figure 29 shows the cylinder of the gearshift point included in the gearshift device with the shut-off clutch valve in the neutral position, section; Fig. 30 shows a shut-off valve for the clutch in the position of the shift point; Fig. 31 is a side position cylinder incorporated in a gear shifting device; on Fig - cylinder side
positions intended for use-20 dachas respectively. in cylindrical
calling in gearboxes with three lateral positions, cut; Fig. 33 shows a connecting cylinder with means for adjusting the draft position and automatic switching on and off, a slit.
The device comprises a gearbox 1 of a known type mounted in a vehicle. A cylinder 2 of the gearshift mechanism with a clutch stopper for shifting movements and a conventional gearshift lever 3 (for manual shifting or gear selection with pre-selection of gears), which is lengthened by connecting to it through a universal joint of the extension rod 4 and By means of this rod, it is connected to the cylinder of the gearshift mechanism via the side position valve 5 and the gearshift valve valve 6. When the gear shift lever 3, when shifting gears, moves laterally to a predetermined gear shift point, i.e. to any one of points A, B, or C on line D of the neutral position, the extension rod ha 4 rotates, thereby its connecting lever 7 is displaced linearly and the valve 5 is actuated. When the gear shift lever 3 moves to the specified shift point, The mile 4 is displaced linearly and actuates the valve 6.
The cylinder 2 of the gear mechanism I transmission, which contains the cylinder 8
the lateral position and the gearshift point 9 is connected to the shift rod (not shown) of the gearbox via the gearshift lever 10, which is fixed to the axis 11, which can be rotated and moved in the cylinder body 12 and which through the cam 13 enters engagement with a square bore 14 in the piston rod 15. The cam 13, together with the lever 10, can be moved relative to the bore 14 in the longitudinal direction between the two extreme positions. The piston rod 15 is provided with two pistons 16 and 17, which are displaced on both sides of the switching lever 10 by idlers 18 and 19 (Fig. 2). Of these pistons, piston 17 is mounted for movement on rod 15 so 5 that it can move from p 5 to current 15 and piston 16. In neutral position piston 17 abuts against one end wall of cylinder (Fig.2) and is also kept in closet to it position due to
0 constant increased working movement, which is supposed to be 6-8 kg / cm, while the piston 16 is located at the center of the pilindrial cavity 18 and externally undergoes an action of a constant reduced working pressure that is 2 times less increased working pressure, i.e. is 3-4 kg / cm2. The difference between these two working pressures is the actual working pressure. Thus, as long as the indicated working pressures prevail, the gear lever is retained
5 is in a neutral position.
The stem is installed and sealed on the outside of each piston 16 and 17 in the end walls 20 bolted and the protruding ends
0 rod is placed in the casing. To prevent rotation of the gatok 15 above the square hole, a guide pin 21 is mounted. An axis 11 carrying the lever 10 is attached at one end of
5 is united by means of keys to a cone, 22 plates of a three-way shut-off Valve 23 of the clutch, which in the position shown in Figs. 4 and 5 is in indirect communication with the connection 5
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body cylinder 24 (FIG. 6) and which in its other two positions relieves pressure in the connection going to or from cylinder 24, i.e. connects it to the atmosphere. Between the bearing shell 25 for the axis 11 and the cone 22, a spring 26 is clamped, which holds the cone 22 in its pressed position against the seat in the box 27 of the clutch valve and allows the axis 11 to move in the axial direction without affecting the cone 22.
On the other side of the gear lever 10, the axle 11 is also supported in the bearing shell 2 and in contact with the piston rod 28 which is provided with two pistons 29 and 30, each of which is located on one side of the intermediate part 31, which is connected to the cylinder body 32 and which is mounted for movement by the rod 28. One of the pistons, namely the piston 24, is mounted for movement on the cylinder 28, while the other piston 30 is rigidly attached to the hammer 28.
In the neutral position, the two pistons 29 and 30 are in the position shown in Fig. 4, in which the piston 29 abuts against the bearing shell 25 and the locking element on the rod 28, and the piston 30 is located in the center of its cylindrical cavity 33. In this position, the piston 29 is driven by increased working pressure, while piston 30 is driven at the end facing the pore of the horn 29 by reduced working pressure and at the other end a pressure of zero, i.e. the lever 10 is held in the neutral position, and thus in the position of the shift point B (Fig. 1) with the effective working pressure.
The lever 10 is fixed on the axis 11 by means of locking screws 34 having conical heads at the end, which are included in the conical recesses 35 on the axis 11. To allow some adjustment of the lever 10 in the lateral direction on the axis 11, the distance between the conical recesses 35 on the axis 11 is slightly greater than the distance between the threaded holes for the screws 34 in the collar
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lever 36; cavity 38 has air outlets 37 for removing air from it and communicates with the shut-off valve; A spring 26 is placed in cavity 38 (Lig.4).
The indicated overpressure and underpressure are maintained at a constant desired level by means of a pressure tank 39 and a tank 40 respectively, which through filters 41, adjustable pressure relief valves 42 and check valves 43 are connected to a common compressed air generator (not shown) of the transport means (Fig.7). The pressure tank 39 is connected via a pipe 44 to a cylindrical cavity 9 for a piston 17, which is under increased working pressure in the neutral position, and a pressure tank 40 through a pipe 45 is connected to a cylindrical cavity 18 of the piston 16 and to the cavity between the intermediate piece 32 and the piston 30, which is subject to increased working pressure at least in a neutral position. Similarly, via conduit 46, the pressure end of the piston 30 is connected to the pressure pipe 44. Valve 5 is located in the pipe 46 and in the neutral position it relieves pressure at the pressure end of the piston 30 (Fig. 7).
The valve 5 is connected via a pipe 47 to a distributor valve 48 installed in the pipe 49, which is in the open position in the neutral position for supplying a raised or low operating pressure to the piston.
When shifting gears, valve 5 is actuated by a gear shift lever 3. When the lever moves to the left to position A of the gearshift point to engage reverse gear, first gear or sixth gear, valve 5 is activated so that it relieves pressure at the pressure end of the piston 30, but connects pipe 47 to pressure pipe 44, thereby distribution valve 48 closes and reduces the pressure at the pressure end of the piston 29, which becomes zero. Since the pressure at the pressure end of the piston 30 is zero, the reduced working pressure acting on the side
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low pressure, the piston 29 can move the piston 30. Thus, the gear shift lever 10 moves to the left (Fig. A) to the first bobcany position to engage reverse gear, first or sixth gear (Fig. 8).
When the lever 3 is moved in the opposite direction to the position C of the shift point for switching on the fourth, fifth, ninth or tenth gear, valve 5 is activated so that it connects pipe 46 to the pressure end of piston 30 and releases pressure in pipe 47 As a result, the control valve 48 opens the pipe 49. Thus, the increased working pressure will act through the pipe 46 to the discharge end of the piston 30 and, thus, the piston 30 with the rod 28 is shifted to the right (FIG. 4) towards its friend The bo lateral position for switching on the fourth, fifth, ninth or tenth gear is (FIG. 9) When switching on other gears, the gear shift lever 10 remains unused in the central (neutral) position.
When the gear is engaged, the lever 3 moves -or forward or backward relative to the position of the shift point, and thereby the valve 6 of the shift point is actuated in one or the other direction. The inlet of said valve 6 is connected through a pipe 50, including a switch valve 51, which is connected to a pipe 45, with a connecting valve 52, which is controlled by turning the vehicle coupled on and off and communicating through a pipe 53 to a pressure pipe 44. Inputs E and F valve 6 are connected to pipeline 45 through pipeline 54, which is equipped with a control valve 55, which is connected to pipe 50 between the switch valve 51 and connecting valve 52 through pipe 56. In neutral the position of the valve 55 is open and thus the reduced working pressure prevails at the inputs E and F of the valve of the gear shift point, as well as in two pipes 57 and 58 connected to the outlets G and K of the valve, the latter of which are connected
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One end is connected to porgan 16, the other end of which is in constant communication with low pressure pipe 45, while pipe 57 is connected to a distribution valve 59 installed in pressure pipe 44 to actuate said control valve pressure, which the neutral position corresponds to a reduced working pressure and which is balanced by an appropriate control pressure on the other side of the valve 59, which always corresponds to a reduced working pressure and ensures It is via a conduit 60 connected to conduit 45 of low pressure.
When the gear shift is off, i.e. when the clutch pedal is activated, the oil pressure in the connecting cylinder 24 increases in a known manner and thus its two pistons 61 and 62 (Fig. 6) are moved separately. One porgaen 61 turns through the piston rod 63 of the rocker 64 counterclockwise (Fig. 7), thus the lever actuates the connecting valve 52 in such a way that it connects the valve 6 to the pressure pipe 44. After that, at the inlet H of the valve point gear shift is dominated by increased working pressure.
The cylinder 24 is also under the action of compressed air having a pressure that can be equal to a reduced working pressure or any pressure chosen but which should not exceed the increased working pressure. When the oil pressure is increased by depressing the clutch pedal, the piston 62 in the cylinder 24 is also displaced and thereby opens the connection through the cylinder 24 to its outlet L, which is connected through a valve 66 to a valve (pneumatic chamber) 67 regulating pressure through the valve-switch 65 which helps in turning the cowl 64 when it experiences the effect of air pressure in the pipe 66.
A pipeline 68 is connected to line 66 between cylinder 24 and switch valve 65, which
is connected to the inlet of the shut-off valve 23. The outlet of this valve is connected via pipeline 69 to the switch valve 65 and, if necessary, a quick-release valve 70 is installed, quickly reducing pressure in the pipeline 69. In the inlet pipelines and at the outlet of the valve 23, the pressure in the neutral position is zero.
Thus, the specified air pressure generated in the pipe 66 when the clutch pedal is pressed causes the valve 65 to close off the 6 I pipe leading to the outlet of the gate valve and opens the connection to the bell 67, which contributes; the opening by means of a connecting valve 52 of the connection between the pressure pipe 44 and valve 6, the valve switch 51 closes the low pressure pipe 45 and the valve 55 under the action of high pressure in the pipe 50 occupies the position shown in Fig. 10, in which the pressure at inputs E and F The valve of the shift point drops to zero through conduit 54 and conduit 45 closes. Pressure in conduits 57 and 58 also becomes zero, but this has no effect on control valve 59 or Porganu 16 kg cylinder 17 point shifting.
When the shift lever 3 is moved, for example, to the shift point to activate the first gear, the valve 6 after the pistons 29 and 30 of the lateral position cylinder are in the position shown in FIG. 8, in the position shown in FIG. 11, in which The inlet H of said valve is connected with its outlet K, an increased working pressure acts on the piston 16 of the cylinder of the gearshift point, which is connected to the engine 15, while the piston 16 with its cylinder 15, which in this position is movable relative to the piston 17, moves to the extreme right position (Fig. 12). The axis 11 is rotated by a lever 10 connected to the rod, and the lever 10 simultaneously actuates the coil of the gate.
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shy gears to activate the desired gear. Due to the rotation of the axis 11, the valve 23 occupies a position (Fig. 13) in which the pressure in the pipe 69 drops, while the pressure in the pipe 68 remains unchanged.
When the clutch pedal is released, it takes up its original position and the connecting valve 52, which is in the initial position (Fig. 7), is activated, the connection with the pressure pipe 44 is interrupted and the pressure in the pipeline 50 becomes zero. This means that valve 51 connects pipe 45 to pipelines 50 and -58, the pressure side of the piston 16 is still under pressure, which at least corresponds to a lower working pressure and, thus, the piston 16 is not activated. Simultaneously with the pressure drop in the pipe 50 to zero, the distribution valve 55 also takes effect, occupying the position shown in Fig. 7, and the distribution valve 59 is again under the action of reduced operating pressure, which, however, cannot change the position of valve 5.
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due to the same control pressure in line 60 on the other side of the valve. In this way, the gearshift process is completed, in which, for example, the first gear is engaged, and the gearshift device is ready for the next gearshift process.
When vehicle speed increases, when a higher gear is required, this can be done manually in this way by pressing the clutch pedal and moving the lever 3 to the desired gear shift point (with the clutch pedal (released) or by pre-selecting the desired gears, i.e., the gear shift lever is first moved to the desired gear shift point and then the pre-selected gear is engaged by pressing the clutch pedal and. Thus, the device shifting can be used for shifting or manually for switching the transmission from the preselection of all transmissions.
It is assumed that the second transmission must be included with a preliminary selection. Therefore, first, the lever 3 is moved from the shift point for the first gear to the lateral position of point A (Fig. 1), the valve 6 returns to the position shown in Lig.7, in which the valve input H is blocked, while the two lines 57 and 58 connected to the low pressure pipeline 45. The shift lever then moves to the position of the shift point C, thereby returning the valve 5 to the neutral position (Fig. 7), which means that pressure relief has been released in both lines 46 and 47, there is no control pressure on the distribution valve 48 and this the valve is displaced to the position shown in Fig. 7, and opens the message of the pressure pipe 49 to the high-pressure side porin 29, which is subjected to the action of the increased working pressure.
Thus, the piston 29 moves with the axis 11 and the piston 30 to the neutral position (Fig. 7) without actuating the check valve 23, which still remains in the position shown in Fig. 13. After that, the lever is moved to the shift point to activate the second gear, the valve 6 moves to the position shown in Fig. 11, in which the valve inlet H is connected to its outlet G, and the inlet F is connected to the outlet K. Thus, pipelines 57 and 58 do not change when the pistons 16 and 17 take
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conditions regarding pressure. Pistons 16 and 17 of the shift point cylinder and control valve 59 have no effect, but the pre-engaged gear remains in the engaged state.
When it is now necessary to switch on the pre-selected gear, the driver only has to press the clutch pedal, the connecting valve 52 in the manner described opens the connection between the pressure pipe 44 and the inlet H of the valve
the position shown in FIG. The shut-off valve 23 takes the position shown in Fig. 16 and releases pressure in the pipe 69. After that (first, the clutch can return from the neutral position to the pull position. The connecting valve 53 is again activated, breaking the connection between the high pressure pipe 44 and the input H of the valve of the shift point and relieves pressure in the pipeline 50, the valve-switch 51 and the control valve 55 re0
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6. The distribution valve 55 occupies the position shown in Fig. 14 and releases pressure in the pipelines 54 and 8. This means that the pressure on the pressure side of the piston 16 is zero and, since the control pressure in the pipe 57 becomes higher than the control pressure in the pipe. In line 60 on the other side of distribution valve 59 in pressure pipe 44, this valve takes the position shown in Figure 11, as a result of which pressure is released in the cylindrical cavity 19 and the pressure in it becomes equal to zero.
The pressure on the high pressure sides of the pistons 16 and 17 becomes zero and the reduced working pressure, which through the low pressure pipeline 45 constantly acts on the low pressure side of the piston 16, causes the piston 16 to move from its extreme position (Fig. 12) to another extreme position ( 15) through the central or neutral position. From this position, the piston 16 through the rod 15 also moves the piston 17 to its other extreme position (Fig. 15). During the movement of the pistons 16 and 17, the axis 11 is rotated by the lever 10 and thereby the cone 22 of the clutch stop valve moves to its other extreme position (Fig. 16) and passes the position shown in Fig. 7, in which the pipes 68 and 69 going to the shut-off valve 23 and from it are interconnected and block the clutch so that there can be no its return stroke until the gear shift is carried out. Gear shifting ends when pistons 16 and 17 take over.
the position shown in FIG. The shut-off valve 23 takes the position shown in Fig. 16 and releases pressure in the pipe 69. After that (first, the clutch can return from the neutral position to the pull position. The connecting valve 53 is actuated again, breaking the connection between the high pipeline 44 the pressure and the input H of the valve of the shift point and relieves the pressure in the pipe 50, the valve switch 51 and the control valve 55 pe
they are boosted in the manner described, and the reduced working pressure prevails in the pipes 58 and 57. The distribution valve 59 and the pistons 16 and 17 are not actuated, which thus remain in their extreme position (Fig. 15).
It can be assumed that the next gear shift should take place directly from the second to the fifth by pre-selection of gears. For this purpose, the lever 3 moves (without first pressing the clutch pedal) from the point of shifting the second gear to side position C (Fig. 1), the valve 6 returns to the position shown in Fig. 7 without any actuation of the distribution valve at 59 pistons 16 and 17, while valve 5 is so regulated (its valve 71 moves to the right in FIG. 7) that its inlet is connected to pipe 46 and it is resetting
the pressure in the pipe 47. This means that on the pressure side of the piston 30 of the cylinder of the lateral position, an oscillating operating pressure has an effect. pressure and it moves to its extreme position, where it rests against intermediate piece 31 and displaces piston Itok 23 relative to piston 29, which in its extreme position abuts against bearing shell 24. Axle 11 and lever 10 attached to it move to the right in FIG. 4 to the position shown in FIG. 9, which in the gearshift diagram is the lateral position for the fourth, fifth and tenth gears
When the lever 3 is then moved to the shift point for fifth gear, valve 6 is actuated. which moves to the position shown in FIG. 14, which is common to shift points, as appropriate. first, third, fifth, sixth, eighth and tenth programs. In this position, the valve of the gearshift point and its inlet H are connected to the pipeline 58, while the pipeline 57 is connected to the outlet and to the pipeline 54. Since reduced operating pressure still prevails at the inlet I and pipeline 54, there is no pressure difference when the valve moves the shift point from the position shown in Fig. 7 to the position shown in Fig. 14, and thus due to the lack of
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the pressure differential is not actuated by the control valve 59 and the piston 16 of the shift point cylinder. This differential pressure is first formed when the clutch pedal is depressed. When the clutch pedal is now pressed to shift to a preselected gear, i.e. the fifth gear is driven by the connecting valve 52 in the same way as the rocker 64, connected to the pressure regulating bell 67 and the connecting cylinder 24, so that the pipe 50 is connected to the pressure pipe 44, an increased working pressure acts on the pressure side of the piston 16 The pressure through the pipe 58 and at the same time the control valve 55 (Fig. 10) is so regulated by the increased pressure that it relieves pressure in the pipe 54 as well as in the pipe 57 going to the distribution valve 59.
Thus, the control pressure on the side of the valve 59 connected to the pipe 57 is zero, and the control pressure acting on the other side of the valve is able to transfer this valve 59 to the position shown in Fig. 7, in which the pressure side of the piston 17, the shift point valve valve acts as an overpressure, with the result that the pistons 17 and 16 are moved from the position shown in FIG. 15 to the position shown in FIG. 12, while simultaneously turning the gear shift lever so as to engage the fifth gear in the gearbox and move the cone 22 of the clutch stop valve to the position shown in FIG. Initially, when the cone 22 takes the indicated position, in which the pressure in the pipe 69 is depressed, the clutch pedal can return to the traction position to engage the gear, and thus also the connecting valve 52 breaks the connection between the pressure pipe 44 and the gearshift cylinder input H and relieves pressure in the pipeline 50, thereby valve-5
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the switch 51 and the control valve 55 are adjusted in a similar way, so that a reduced pressure prevails in the pipes 58 and 57. There is no pressure differential that could trigger the control valve 59 or the cylinder pistons 16 and 17 of the shift point, which remain in the position shown in Figure 12, until the next gear shift takes place.
The manual shift gearbox (marked by dash-dotted gear changes, implementations) is equipped with a mechanism 72, which is the highest stop gear 98.
and lower gear, which through pipelines 73 and 74 is connected to pipe 50 and pipe 66, respectively, with the latter through a quick-release valve 75 and through a switch valve 76.
YcTpoftcTBOj installed on a vehicle with a five-speed manual-shift gearbox (Fig. 17) is intended for semi-automatic or fully automatic gear shifting and with electric control of the cylinder 2 gearshift connected to the gearbox 1, i
In this modification, the gear lever is shown rigidly connected to a gear wheel 77 mounted pivotally on a steering column, with which a gear operates, fixed on an axis 78 mounted pivotally on a steering column, the axis being connected through a swivel or flexible axis 79 with the axis 80 in the distributor 81. Thus, when the lever 3 is rotated, the axis 80 of the distributor rotates at a corresponding angle and on this axis a number of cams 82-85 are mounted, which are fixed one relative to other
means of studs 86 and can be replaced. These cams, in order of priority, are called: a position-locking disk 87, on the periphery of which there are 12 holes 88, a connecting cam disk 89 having 12 notches 90 on the periphery, a cam 91 of the gearshift points and a cam 92 of the transition from high to low.
The axis 80 is installed in the bearing 93 in the back of the 94 distributor
and on axis 80, cams 82-85 are held with the possibility of replacement by means of a washer 95 and a bolt 96. K-i
This rear part is attached to the sleeve, the surrounding cams, which directly in front of the position locking disk 87 carries two spring-loaded locking pins 97 and 98, which are placed to interact with the recesses 88 of this disk in order to block it, and the axis 80 is in the off position carried out by the locking pin 97, and accordingly in the
Immediately in front of the cam 83 in the sleeve 99 there is a connection breaker 100 which, by means of a contact 0
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The first pin 101, acting as a cam follower, interacts with the disk 89 to disengage, i.e.. breaking the current circuit when the contact pin 101 enters into the hatch 90, and for the purpose of connection, i.e. closing the circuit when pin 101 contacts parts 102 between recesses 90 "Directly in front of the cam 91, in the sleeve 99, there is a set of gear selectors 103-113 corresponding to the number of gears and neutral position interrupter 114, which must be turned on and off depending on from the position of the cam 91. In addition, an interrupter is installed directly in front of the cam 92 in the sleeve for switching on and off depending on the position of the cam 85.
For semi-automatic gear changes, only the electrical connection diagram for the five-speed manual gearbox (Fig. 23) and the pneumatic connection diagram of the proposed gear shifter, the latter of which is slightly different from the one shown in Fig. 7, is shown. The parts are in their neutral position (Fig. 23); locking pin 97 in recess 88, contact pin 100 of interrupter - B recess 90 (marked with a dotted line in Fig. 20) and cam 91 (marked with a dotted line in Fig. 21) - in a position directly in front of the interrupter 114, the contact pin of which is held down position and cam
85 is in the position marked in Fig. 22 with a dashed line, the last cam not being necessary for a five-speed gearbox without a high and low gear mechanism.
In the neutral position, the breaker 114 closes the circuit 115 leading to the electric valve 116, which in this position releases pressure in the conduits 68 and 69 of the shut-off valve 23, and the reverse gear position interrupter 103 and the first gear change point interrupter 104, close circuit 117, going to the electric valve 118 in the damper 119 of the dead position, in which the oil tank 120 is connected to the auxiliary cylinder 121 by the connecting bell 67, which regulates the pressure through the pipeline 122 with the non-return valve 123. nnogo auxiliary cylinder conduit 124 passes through the electro-valve 118 back to the oil tank 120.
To activate the first gear, the lever 3 is turned down, thereby the axis 80 of the distributor rotates in the direction indicated by the arrow 125 (Fig. 19). As a result, the breaker pin 101 is recessed by the disk 89 and closes the circuit
126 going to the electric valve
127 which connects the pressure pipe 44 to the pipe 66. A switch valve
65 blocks the connection to the pipe 69, while the bell 67 and the oil in the tank 120 experience an overpressure effect, causing the clutch to be turned off and turning by the bell of the rocker arm 64, which opens the connecting valve 52, with the result that this valve is connected to the pressure pipe 44 with a pipe 50. The increased pressure that now prevails in pipe 50 causes, by means of a pressure sensor (converter) 128, which is not actuated by wounding under reduced working pressure, a short circuit pi 129 extending to the control bulb 130S is preferably located in the cab winch, not the driver which indicates ivyklyuchenie engagement. The increased pressure in the pipeline 50 further causes
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By means of the valve 51, the blocking of the low pressure pipeline 45 and the opening of the connection to the valve of the gear shift point, which in this case consists of two electrically controlled valves 131 and 132, whose inlet is connected to the pipeline 50 and is normally closed. The outlet of the valve 131 is connected via pipeline 58 to the pressure side of the piston 16 of the cylinder of the gear shift point, while the outlet of the valve 132 is connected through pipe 57 to the low pressure side of the piston 17 of the cylinder of the gear point, the pressure side of which through the pipe 60 is connected directly to the pressure pipeline 44 and, thus, is constantly experiencing increased working pressure. Thus, in the position shown in Fig.235, the pressure in the pipelines 57 and 58 is zero.
Thus, the control valve 59 used in the circuit (FIG. 7) is not present in the example shown in FIG.
When the cam 91, during its rotation caused by the gear shift lever 3, passes the neutral position breaker 114, having the feature that the locking pin 98 snaps into the recess 88 in the cam disc 87, the circuit 115 is broken and thus the valve 116 takes a position in which conduit 44 is connected to conduit 68. Increased operating pressure also prevails in conduit 69, with the result that inactive pressure transducer 133 causes the circuit 134 to go to A control light 135, preferably located in the driver’s cabin, to indicate gear changes. The increased working pressure in the conduit 69 also prevents the clutch from being too prematurely disengaged.
While the breaker 114 breaks the circuit 115, it connects the circuit 136 connected to the circuit 126, and the circuit 136, as well as the circuit 115, includes the contact 137, which is controlled by the pulse counter 138 in response to engine speed vehicle at
number of revolutions of the engine idle.
The next step in the gearshift process is that the cam 91 actuates the interrupter 104, which breaks the circuit 117, thereby the valve 118 of the tram position takes its other position, which means that the oil from the auxiliary cylinder 121 must pass two throttle flaps 139 for returning to the oil tank 120. A soft (smooth) engagement of the thrust is performed when such a need arises, the Interrupter 104 at the same time as it breaks the circuit 117, also closes the circuit 140, id conductive to electrical dvuhpoeitsionnomu kla- Pan 141, which is one of the valves 141 and 142, lateral position - for the pistons 29 and 30, the lateral position of the cylinder. The valve 141 in its normally open position (Fig. 23) connects the pipe 44 to the pipe 49 connected to the pressure side of the piston, while the other valve 142 in its normally closed position (Fig. 23) depressurizes the pressure side. the piston through the pipeline 46.
Thus, when the circuit 140 closes, valve 14t takes up its second position, in which it depresses pressure in pipe 49, so that the pressure on the pressure side of the piston becomes zero and the portions 29 likewise cause the transfer of the lever 10 to the lateral position for switching the first gear (Lig.12) When the pressure in the pipeline falls below a predetermined value, for example 0.2 kg / cm--, the pressure sensor 143 closes the circuit 144 going to the relay 145, which turns on and closes the circuit 146 going to the valve 131 occupying its other position, and where its inlet, where the increased working pressure prevails, is connected to the pipe 58. Thus, the piston 16 on the pressure side experiences the action of the increased working pressure and thereby moves to the position shown in Fig. 12 for inclusion in the box the transmission of the first gear and at the same time the cone 22 of the shut-off clutch valve rotates and occupies the position shown in Fig. 13, in which pressure is released in line 69. When the pressure in line 69 drops below a predetermined value, which should be higher than the notable working pressure, for example, it can be 5 kg / cm2, pressure sensor 13 breaks the circuit 34 and the control light 135 goes off, which indicates the completion of the gearshift process and switching on desired gear.
When lever 3 is in the position for the first gear, the stopper gate enters the recess in the disk 87 and determines the individual gear shift position. At the same time that this position is reached, the contact pin 101 of the chopper enters the recess 90 in the disk 89 and thereby breaks the circuit 126, with the result that the electric valve 127 takes the position shown in Fig. 23 to release the pressure in the pipe 66 and bell 67. Thereafter, the clutch smoothly returns to its original position. In doing so, the valve 53 returns to its normal position in which it depresses the pressure in the pipe 50. When the pressure in this pipe falls below a predetermined value, which must be higher than the reduced working pressure, for example, it may be 5 kg / cm 2, The pressure sensor 128 breaks the circuit 129, thereby turning off the control lamp 130, indicating that the clutch is engaged.
To enable the clutch to be disengaged without disengaging the transmission in the driver's cabin, there is a push pin 147, which, when depressed, closes the circuit 148 extending from all the breakers 103-113, with the exception of the circuit coming from the neutral position breaker 114. Chain 148 is connected to circuit 126 after the chopper and the clutch is disengaged. Upon the subsequent release of the contact 147, the chain 148 is broken and the clutch may return to the thrust position.
When the second gear is engaged, the lever 3 is turned further in the same direction, with the result that the breaker 100 closes the circuit 126, the clutch and the cam 91 are disengaged
leaves the breaker 104, as a result of which the breaker breaks the circuit 140, which means that the valve 141 takes the position shown in FIG. 23, and connects pipelines 44 and 49 between each other. The pressure sensor 143 breaks the circuit 144 and the pistons 29 and the cylinder 30 of the lateral position is returned to the position which is also the lateral position for the second and third gears. When the circuit 146 is broken, the relay 145 is also disconnected and the circuit 146 is broken, the valve 131 returns to the position shown in Fig. 23, which depressurizes the pipe 58 and the piston 16 returns from the position shown in Fig. 12 to shown in Fig. 23, and the clutch check valve cone 22 takes the position shown in Fig. 23. The pressure in line 69 becomes equal to the increased working pressure and the pressure sensor 133 is actuated to connect the pilot light 22.
When the cam 91 is then actuated by the interrupter 105 for the second gear, it closes the circuit 149 that goes to the valve 142, which moves to another position where its inlet, which is dominated by overpressure, is connected to the pipeline 57. Thus The pistons 16 and 17 move to the position shown in Fig. 15, and through the lever 10 in the gearbox, the second gear is engaged and the cone of the clutch stop valve rotates and takes the position shown in Fig. 16, at which the pressure in the pipeline is released. 69. Ka Only breaker 100 breaks the circuit 126, the clutch is returned to the traction position, thereby damping t go- Vågå position osuschestvlets only through a throttle valve 139.
When the third gear is engaged after the clutch is disengaged, the interrupter 106 closes and the circuit 146 closes after the relay 145, since in this case it is not necessary to actuate the pistons 29 and 30 of the lateral position cylinder. Then the transfer switching process is performed.
In the semi-automatic gearshift device, it is possible to re-0
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jumping through one or more gears without affecting the gear engaged. To this end, in the driver's cabin there is a contact 1 56, actuated by a foot or a hand, which is connected in the chains 146 and 149 after all the breakers 103-113. In order to clarify its function, we assume that direct shifting from second to fourth gear is necessary. Contact 150 is actuated at the same time or after lever 3 is moved from the gearshift point corresponding to the second gear, thereby closing circuit 126 and breaking circuit 149, resulting in valve 132 moving to the position shown in Fig. 23, and the pressure in pipeline 57 is depressed to move the pistons 16 and 17 to the neutral position, shown in AIG.23. However, since these circuits break earlier, nothing happens. When the cam 91 then comes into contact with the chopper 106 for third gear, nothing happens, as the circuit 146 is already broken by the actuated contact 156. Before lever 3 moves to the gearshift point corresponding to the fourth gear, contact 150 is released for closing two circuits 14.6 and 149. When the cam 88 then actuates the interrupter 107, it closes the circuit 151, going to the valve 142, which moves to its second position and connects the pipeline 44 to the pipeline 46, resulting in the piston 30 Pushes the lever 10 to the side position for the fourth or fifth gear shifting point. When the pressure in the pipe 46 rises above a predetermined value, for example 5 kg / cm, the pressure sensor 152 closes the circuit 153, going to the relay 154, which turns on and closes the circuit 149, going to the valve 132, the pistons 16 and 17 move to the position shown in Fig. 15, for switching on the fourth gear in the gearbox and moving the check valve to the position shown in Fig. 16, as a result of which pressure in the pipe 69 is released. Interrupter 100 then returns to the traction position. For the fifth gear, a relay 155 is provided which, when actuated, closes the circuit 146 leading to the valve 131 to move the pistons 16 and 17 to the position shown in Figure 12 for switching to the fifth gear box.
To engage the reverse gear, which can only be carried out from the neutral position, before the lever 3 can be moved to the position corresponding to the reverse gear, contact 156 must first be closed, preferably located in the driver's cab. When the specified contact is closed, the Iro contact also closes the - 140 circuit, thereby relieving the pressure in the pipe 49 and the pistons 29 and 30 of the lateral position cylinder move the lever to the lateral position corresponding to the reverse gear shift point (Fig. 8). The shift lever can be moved to a point corresponding to the reverse gear, with the result that breaker 114 breaks circuit 115 leading to electric valve 116 and closes circuit 136 leading to circuit 126, which is already closed by breaker 100 to engage the clutch. At the gearshift point of the reverse gear, the cam 91 actuates the interrupter 103, so that the circuit 117 passing through the interrupter 104 to the damper valve 118 is broken, and the circuit 149 leading to the valve 132 closes, thereby entering the A of this valve is connected to the pipeline and the pistons 16 and 17 are moved to the position shown in Fig. 15 to activate the reverse gear in the gearbox. When the clutch returns to the traction position, it is damped by two throttle valves 139 in the damper 119.
The known top / bottom gear cylinder (Fig. 23) does not introduce any difficulties or problems, but is very simple to use the proposed semi-automatic or fully automatic type gear shifter also in manual transmissions equipped with high and low gears. transfers of which are thus doubled. Electrical circuit pre0
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A leased device for use in a ten-speed gearbox or five-speed gearbox with higher and lower gears (Lig.24) is shown in the gearshift phase, in which the cam 91 is located between the choppers 108 and 109, i.e. interrupters for fifth and sixth gears, and interrupter 100 closes the circuit 126 leading to the clutch electrical valve 127, while interrupter 114 is in the position preceding its switching by cam 92 to open the circuit 157 leading to the electrically controlled valve low gear, and the closure of the circuit 127, going to an electrically controlled valve 158 top gear, i.e. for shifting from lower gear to higher gear, which takes place between the fifth and test gears. These two valves are connected to the pressure pipe 44 through pipe 159, which is provided with a valve 160 located in the gearbox and having such a design that air can pass through it when it is in the neutral position. Each of the valves is connected to one of the sides of the piston 161 of the upper / lower cylinder 162 through a pipeline 163 and a pipeline 164, respectively.
When, by turning the distributor axis 80 | through the lever 3, the high / low gear chopper is switched, the current to the valve 165 is stopped, the valve takes its other position and through pressure pipe 163 it relieves pressure on one side of the piston. After breaking the chain 157, the chain 166, going to the valve 158, closes, causing the valve to take its other position, in which it connects the pressure pipe 159 to the pipe 164. At the same time, the piston 161 on the side where there is no pressure release is under the action of pressure and moves to its other extreme position for high gear. When the piston leaves its extreme position corresponding to the low gear (FIG. 24), the circuit 168 is broken between the circuit 157 and one to with the contact pin of the chopper 108, and when the piston 161 occupies its extreme position corresponding to the high gear engagement, a similarly inductive sensor 169 closes the circuit 170 between the circuit 166 and one contact pin of the chopper 109. Thus, even in the case of the chopper closure The 100 or 109 lateral position valves 141 and 142 and the gear shift points 131 and 132 remain de-energized until the piston 161 takes up the corresponding extreme position and thus neither the gear nor the transmission pole They may be included "as long as the piston 161 does not take its appropriate end position.
When this happens and the breaker 108 actuates the cam 91, the circuit 170 closes toward the circuit 140 and thereby the valve 141 moves the lever 10 to the lateral position for the sixth gear, after which the pressure sensor 143 in the manner described closes the circuit 144, resulting in relay 145 triggers and valve 131 causes the sixth gear to engage and the cone 22 of the shut-off valve of the clutch is turned to the position shown in FIG. 13, as a result of which pressure in the pipeline 69 is relieved. Waiting for interrupters 108 and 109 for the fifth and sixth gears, the contact pin 101 of which in this position is located in the recess 90 of the cam disc (Fig. 24) and thus breaks the circuit 126 going to the electric clutch valve 127, this the valve can still be energized through the circuit 136, which is connected to the circuit 126 directly behind the chopper 100 and passes through the chopper 114 and the chopper or contact 137, controlled by the engine speed through the pulse counter 138 pulses (Fig. 23). Contact 137 is designed so that it closes the circuit 136 when the engine speed drops below a predetermined value, for example, 600 rpm, and breaks the specified target when the engine speed is exceeded, a predetermined value, for example, 1200 rpm. This means that when the engine speed during gear shifting becomes less than 600 rpm, to activate the clutch valve 127 and to move the clutch to the traction position, the engine speed must be increased by expanding the throttle valve, at least 1200 rpm, since otherwise the contact 137 will break the circuit 136 and thereby stop the supply of current to the jiany 127, so that this valve moves to the pressure relief position in the pipe 66 and the clutch returns to the pull position. most wasp damping is applied when the clutch returns to the thrust position by means of two throttle flaps 139, in addition to damping the reverse gear, first and second gears, also from the sixth to the tenth gear in the sense that the chain 168 breaks as soon as the piston 161 leaves position corresponding to the lower gear.
Some of the valves 141 and 142 must not only be actuated when shifting to reverse gear, first, fourth and fifth gears, but also when shifting to sixth, ninth and tenth gears. For this purpose, the interrupters 109, 112, and 113 are connected respectively to the interrupters 104,107 and 108 via a circuit 171 (FIG. 24). while the breakers 110 and 111 are connected via circuit 172, respectively, to breakers 105 and 106. Contact 156 must be closed to activate the reverse gear.
The clutch pedal, which is usually not necessary, may not be available, but it must be used in combinations of vehicles with more than one engine (Fig. 25) to carry out simultaneous and synchronous gear changes in the gearboxes of these engines.
In order to obtain fully automatic gear shifting with the help of the proposed gear shifting device, it is necessary to provide in addition to an automatic shift mechanism, including, for example, the reverse gear position, stationary position, neutral position, driving and one or two additional gears.
positions of forward gear, for example only speed control, which controls the turning cylinder mounted on the distributor axis 80 to pivot in response to the speed and load of the distributor axis and its cams to automatically engage the necessary gear. However, it is more convenient to equip the gear changer with a minicomputer, to which information would be supplied regarding the speed, degree of throttle opening, thrust force, which could be measured in the engine intake manifold, and fuel consumption, which, on the basis of this information, would determine transmission at a certain point in time and gave control pulses to electrically controlled valves, which ensure a shift to the desired gear, either directly to the indicated valves themselves or to via micro-interrupters 103-113. Thus, by using a minicomputer, the distributor 81 can be eliminated.
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The proposed device is switchable
Neither gear can also be used in passenger cars. The wiring diagram of the gear selector for semi-automatic shifting of the four-speed gearbox of a passenger car by means of the distribution means 17 is provided with high and low gears and, thus, can be an eight-speed gearbox (Fig. 25).
Pipelines 68 and 69, coming from the clutch valve 23, are connected from two sides to the valve-switch 65, so that when the circuit breaker 100 closes the circuit 126 leading to the valve, an increased working pressure is created not only
in the pipe 66 and the bell 67, but also in the pipe 69, and thereby the valve piston 65 is subject to the same pressure on both sides and occupies a central position for blocking the pipe 66 and locking the clutch in the off position until it is included in gearbox need gear „
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In addition, the lateral position pistons of the lateral position should be moved to the lateral position, swung in FIG. 8, to engage the reverse gear and to the lateral position, shown in FIG. 9, to activate the third and fourth gears
Thus, for engaging the first and second gears, the lateral position cylinder should not be actuated. Damping damping is provided for reverse gear and first gear and for semi-automatic gear changes works almost as shown in Fig. 23. The electrical valve 116 shown in Fig. 23 is omitted in Fig. 25, and also the circuit 115, the interrupter 114 in Fig. 25 of a one-way action.
The separation means 173 is connected to a top / low gear cylinder 174, which is connected via pipelines 175 and 176 to an electric valve 177. which is connected via pipe 178 to pipe 50 and to which is connected a chain 179, having a contact 180, preferably located on gear shift lever 3, for engaging high and low gears.
To switch on the highest gear, contact 180 is activated, thereby closing circuit 179, and electric valve 177 is adjusted to relieve pressure in pipe 176 and on one side of the piston of cylinder 174 and to connect a pipe in which pressure is released in this position valve 52, with conduit 175 on the other side of the piston. As soon as lever 3 moves to a new gear shift point, the clutch disengages as indicated in conduit 50; in the conduits 178 and 175, an increased working pressure is created to move the piston 181 of the cylinder 174 to the position corresponding to the highest gear. The transition from top to bottom is accomplished by activating contact 180 so that the chain 179 breaks.
When, for example, higher the pole gear must be activated directly from the second gear, contact 180 is activated so that 10
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valve 177 was used to release pressure in pipe 176 and pipe 175 connected to pipeline 178. After that, foot 182 was actuated with a foot, which closes circuit 136 and circuit 126 leading to clutch electric valve 127, which does not act on the clutch Addition to pipelines 50, 178 and 175 to engage the transmission coupling. Upon the subsequent release of the contact 182, the chains 136 and 126 break the clutch back to the traction position.
Pipeline 183 (Figures 7 and 25) inserts pressure regulators 42, which are set to a predetermined level by buttons 184, shown schematically. Pipeline 183 extends from the upper chamber 185 of the pressure regulator for increased operating pressure to the pipeline leading from the pressure regulator for reduced operating pressure. This has the advantage that the pressure differential between the increased and decreased working pressures is kept almost constant, even if one or the other working pressure varies up or down for various reasons.
A gear changer (Figs. 27 and 28) is connected to a six-speed gearbox with a manual shift of a known type, which is equipped with an overrun gear. On this axis 186 there is a gear lever (not shown) for the gearbox gears, which should move depending on the selected gear. first, in one of the four lateral positions marked by points M, N, O, –P, by linearly shifting the axis 186 and then turning it, which must move to the desired gear shift point for inclusion in the box th transmission gear selection. For a linear displacement of the axis and with it the gear lever to a given point of the lateral position, the gear shift device includes a lateral position cylinder 187, which is connected to the axis 186 by its piston shaft 188, and to turn the gear lever 186 to rotate the gear lever
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At a given gearshift point, the gearshift device includes a gearshift cylinder 189, which with its piston rod 190 is pivotally connected to a rotary joint 191, which by means of dowels or fasteners is fixed without the possibility of rotation on the axis 186. articulation in its longitudinal direction. Cylinder 189 at its other end is preferably pivotally attached to the transaxle case or to some other fixed point, and a cylinder 187 may be suitably mounted on the transaxle case,
Cylinder 18-7 of the lateral position (Figs.27-32) includes three pistons 192-194, each of which is located in cylindrical cavities 195 and 196 and respectively in cavity 197 in cylinder 187, of which piston 192 is rigidly fixed on porine rod 188 while the other two pistons 193 and 194 are mounted on the rod 188 with the possibility of movement and more precisely on the narrow part 198 of the rod, on which the piston 192 is also attached (Fig. 23).
Cylinder 187 is assembled in three parts using a threaded joint, namely, an end wall 199 in which a cylindrical cavity 197 for a piston 194 is formed, an intermediate part (partition) 200 in which a cylindrical cavity for a piston 193 is formed and which is provided with a partition separating cylindrical cavities 196 and 197 from each other, and in which the piston rod is slidably mounted to the narrow portion 198, and the end face wall 201 in which a cylindrical cavity 195 for the piston 192 is formed and which has an annular An pack 202 facing the piston 193 and acting as a limiter for the movement of the piston 193, another restriction of movement of which is the partition 200. As well as the piston 194, the restriction of movement of which is the indicated partition and end wall 199, the piston 193 is installed so that can occupy one of two extreme positions, and between these extreme positions
has a stroke corresponding to the distance between the points of the lateral position of the gearbox. Since there is no partition between the cylindrical cavities 195 and 196, the piston 193 acts in its extreme positions as a limiter for the movements of the piston 192, the other limiting movement of which is the end wall 201. To ensure the space between the pistons 192 and 193 even in when piston 192 is in its extreme position, abutted against piston 193, the latter has a central portion 203 protruding in the direction of piston 192, which thus limits movement of piston 192 and prevents schenie pistons with slitiem- state. The distance between the piston 192 and the face central part 203 in the position shown in Fig. 31, in which the piston is in an intermediate position, is the same as the distance between the piston and the end wall 201 and corresponds to the distance between the points lateral position of the box
gears.
In the position shown in Fig. 31, the piston 194 is held in position pressed against the end wall 199, and the piston 193 is pressed against the protrusion 202 under the action of a constant increased working pressure that acts on the pressure sides of the pistons 193 and 194 facing one the other, and which in the embodiments of the device (Figs.27-32) is 6.6 kg / cm, while the piston 192, which can occupy four different positions, is held in an intermediate position (Fig. 31) permanently lowered operating pressure prevailing - in the cavity between pistons 192 and 1 93 and thus acting on the low pressure sides of the said pistons, in this case, a component equal to half the increased working pressure. As long as the pressure on the pressure side of the piston 192 is zero, the reduced working pressure acting on the low pressure side of the piston tends to move the piston 192 and with it the rod 193 to the left in FIG. 31, but this prevents the piston 194 from resting on 204 from
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narrow to the wide part of the rod 188. Thus, the piston 192 is held in an intermediate position (Fig. 31). which corresponds to the lateral position point O for third and fourth gear.
When an elevated working pressure is discharged on the pressure side of the piston 194, the reduced working pressure acting on the low dalen side of the piston 192 is able to move the piston 192 to its extreme position against the end wall 201 and the piston 194 moves to its other extreme position, where it rests on the baffle 202 and thus occupies the position corresponding to the lateral position for the fifth and sixth gears. To adjust the lateral position N and M points for the first and second gears and, respectively, reverse gears, the piston 192 on the pressure side is exposed to increased working pressure and, thereby, the piston 192 moves to its extreme position in which it rests against the protruding part 203 of the piston 193, and with the piston 193 in the leftmost position in FIG. 23, the point of the lateral position is adjusted. When the piston 193 is in its right extreme position, the point M of the lateral position is adjusted for the reverse gear. In addition, when the piston 192 is moved all the way into the piston 193 between these pistons, the working pressure is maintained at the same constant level by, for example, a pressure reducing valve or similar means (not shown).
The shift point cylinder 189 serves to rotate the axis 186 and, together with it, the gear lever for switching on a gear in a gear box after adjusting a given point of the lateral position by means of the lateral position cylinder and contains two pistons 205 and 206, each of which is located respectively in The camshaft cavities 207 and 208. The piston 206 is rigidly fixed to the piston rod 190 of the cylinder 189, while the other piston 205 is mounted for movement relative to the rod 190 and
supported on a pin axle, movably mounted in the end wall of the cylinder 209 (Fig. 29). The yoke 190 is mounted movably in the other end wall 210 of the cylinder and in the intermediate part 211, which separates the cylindrical cavities from one another.
207 and 200. In the neutral position (Fig. 29), the rod 190 with its free end abuts against the piston 205, in which for this purpose a recess 212 is made on the side 213 facing
to the intermediate part 211, and is held in this position pressed against the piston 205 under the action of a reduced working pressure, which acts on the low pressure side of the piston 213, i.e. the side facing the end wall 210, the piston 205 on its side in the neutral position (Fig. 29) is held in a position pressed against the intermediate piece 211 with increased pressure, which constantly degrades to the pressure side of this piston, i.e. The side facing the end wall 209. g. As this pressure exceeds the reduced working pressure acting on the low pressure side of the piston 206, this piston is held in a neutral position in the center of its cylindrical cavity
208 with the ability to move in one or the other direction to rotate the axis 186 in order to activate a specified gear in the transmission.
These elevated and lowered working pressures are maintained at a predetermined constant level each by means of a high pressure vessel 214 and a vessel 215, respectively, which are connected through a filter 216, adjustable pressure reducing valves 217 and a pressure pipe 213 to a common compressed air generator (not shown). facilities. The vessel 214 for increased working pressure is connected through the pressure pipe 219 to the cylindrical cavity 207 of the cylinder 189 on the pressure side of the piston inside it and to the cylindrical cavities 195-197 of the cylinder 187 on the pressure side of the corresponding piston through taps 220-222, each of which equipped with electrically controlled valves 223-225. Valves 224 and 225 are usually open to maintain increased
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operating pressure on the pressure side of the pistons 193 and 194, while the valve 223 is normally closed and in this position releases pressure in the cylindrical cavity 195 on the pressure side of the piston to zero pressure.
- The pressure pipe 219 is further connected to the inlet of the electrically controlled valve 226, which is normally closed and at the outlet of which in the closed position of the valve pressure is released (Fig. 28). The outlet is connected through pipe 227, the switching valve 228 is connected to the two inlet closed electrically controlled valves 229 and 230 shift points. The outlet of the valve 229 is connected via pipe 231 to the cylindrical cavity 208 of the cylinder 189 on the pressure side of the piston 206, while the outlet of the other valve 230 is connected via pipe 232 to another cylindrical cavity 207 of the cylinder 189 on the low pressure side of piston 205.
The vessel 215 for reduced operating pressure is connected via a low pressure pipeline 233 to the cylindrical cavity 208 of the cylinder 189 on the low pressure side of the corresponding piston and to the cylinder space 187 between the pistons 192 and 193 and to the switch valve 228. I
The device (Figures 27 and 28) provides a pipe 234 for supplying compressed air to actuate the clutch, which is connected to pipe 218 in front of the filter 216 and goes to the inlet of the normally closed connecting valve 235 and to the inlet of two electrically controlled valves 236 to implement switching on and off the gear part, i.e. parts with higher and lower gears.
I
The outlet of the valve 235 is connected via a pipe 237 to the inlet of a shut-off valve 238 of a clutch located directly connected to the cylinder 189. The output of said shut-off valve is connected via a pipeline 239 to a pipeline 237 through a switch valve 240, which, in turn, is connected via a pipeline 241 with clutch pressure oil tank 242.
The valve 238 includes a movable part, which consists of the stock 190 of the cylinder 189 and in which for this purpose a relatively wide annular groove 243 is made (FIG. 29). In the neutral position, the groove 243 is located directly in front of the inlet and communicates with a valve 244 formed in the valve box 245 surrounding the flow 190 and the other end of which communicates with the groove 246 extending in the direction of the rod 190 and completely covering it, side of the valve box facing the rod. A groove 246 communicates with a groove 247 formed on the outside of the valve box and completely enclosing the stem, located directly in front of the outlet of the check valve. The outlet is located in the cylindrical housing 248, which encloses the groove 247 and contains part of the valve box and which is fastened to the end wall 210 of the cylinder 189 with its flange. The valve box 245 is screwed to the other flanged part of the housing for the end part 250 of the rod of reduced diameter and between the said end part of the rod and the sliding sleeve 249, the sealing sleeve 251 is fixed. I
In box 245 there is an outlet
The bore 252, which in all positions of the piston 206 communicates with the cavity 253, is located between the end portion 250 of the rod and the box 245. In the neutral position (Fig. 29), the cavity 253 has an axial extension that at least corresponds to the piston stroke 206 from its intermediate position to the extreme positions. The channel in the rod 190 communicates with one or more openings 254, which in all positions of the piston 206 communicate with opening 252 through cavity 253, with this cavity and communicates through openings 255 with two groove and 256 and 257, which are formed as a ring on the periphery itoka were combined output stspleni The check valve 252 with a hole in each end position of the piston, i.e. exactly
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like gearshift. At the right gearshift point of the piston (Fig. 30), the groove 257 communicates with the groove 246 in the box 245, thereby releasing the pressure through the opening 252. However, the inlet valve in this position is kept closed by the stem part 258 and the corresponding stem part 259 provided on the other side of the groove 243 for closing the inlet of the check valve at the other gearshift point, in which the outlet R communicates with the orifice 252 in the groove 257, which is formed in the stem.
The gearshift device (Figures 27 and 28) is driven electrically by means of a control system adapted for semi-automatic gear changes and can be adapted to perform gear changes manually or without prior selection of gears or for fully automatic gear changes.
The semi-automatic control system (Fig. 27) includes a connecting cam disc placed in a distributor (not shown) and capable of being turned by means of the gear shift lever 260. The disk in expanded form interacts with a connecting chopper 261 having a fixed position relative to this disk, and the chopper 261 closes the circuit 262 leading to the connecting valve 235 when the chopper pin 263 is driven by the protruding portion 264 (266) of the disk 265 and breaks said chain when pin 263 enters a recess in disc 265. Furthermore, in said distributor, there is a gear cam 267 that rotates simultaneously with disc 265 and is positioned directly a row of interrupters 268-275 shift points corresponding to the number of gears and a neutral position interrupter, with interrupters set to turn on and off depending on the position of the cam 267.
In the gear shifter in the neutral position (Fig. 27), the circuit 262 is broken and the neutral position interrupter 269 is turned off. Suppose that the first transmission is to be included. To this end, the shift lever is rotated downward in FIG. 27, and the disc 265 and cam 267 are also rotated in the direction indicated by the arrow 276 in FIG. Before the cam 267 of the neutral-position interrupter is closed, the interrupter 261 closes with the protruding portion 264 of the disc 265 and the circuit 262 closes toward the valve 235. This opens the valve and causes the connection of the discharge pipe 234 to the pipeline 241 that goes to the oil reservoir - Coupling 242, for engaging it, and with conduit 237 leading to the inlet of the adhesion valve of the adhesion. Since this input is in neutral with the output, a high pressure will also prevail in line 239, and a pressure sensor 277 installed at a relatively low pressure, such as 0.25 kg / cm, will cause a short circuit 278 from the current source 279. for example, a battery to a control light 280, which lights up and indicates the start of the clutch disengagement process. Each of the choppers 278, with the exception of the neutral position breaker 269, is connected to the circuit 278, and the circuit 281, which is connected to the working contact 282 through the valve 226 and current flows through it first, when triggering the contact 282 by the release lever 283 - laziness that takes place first with the clutch completely disengaged. When the clutch is disengaged, contact 282 is activated, and right after that, current flows through circuit 281, distribution valve 226 opens and connects pressure pipe 234 to pipe 227 leading to valves 229 and 230, which are closed in this position. Therefore, a valve 228, between which and the valve 226 can be located a throttle valve, blocks the connection to the low pressure pipe 233.
,,
At the same time, as the disc 265 is rotated, the cam 267 also rotates from the chopper 269 to the chopper 270 for the first gear, which thereby closes and closes the circuit 284 going to the valve 223 of the cylinder 187. The valve opens and the piston of the cylinder 187 goes to the pressure pipe Q 5
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is not exposed to increased working pressure and moves to its extreme position, corresponding to the lateral position point N for the first and second gears, up to the stop in the protruding part 203 of the piston 193 remaining in its extreme left position (Fig. 31). Thereby, the shift lever is set to the N position of the lateral position.
When the pressure in the outlet 220, in which the pressure sensor 285 is installed, set at a predetermined pressure, for example 6.0 kg / cm, exceeds the specified pressure, this sensor is activated and closes the circuit 286 going to the relay 287, with the result that this relay the circuit 288 turns on and closes, which goes to the valve 229, which opens and the piston 206 of the cylinder 189 from its pressure side is exposed to an increased working pressure. The hinge 206 and its rod 190 are moved to the left (Fig. 29) and to the right (Fig. 28), with the result that the axis 186 with the gearshift lever on it rotates and engages the first gear in the gearbox.
When rod 190 reaches this gearshift point, the clutch valve is inlet closed by stem part 258, while pressure is released at its outlet through outlet port 252. Thus, the pressure in line 239 connected to the outlet drops when pressure in it becomes lower than the pressure on which the i277 sensor is installed, which causes the circuit 278 to break. Since this circuit is also connected to valve 235 installed between the indicated circuit and diode 289, the current flow to valve 235 also stops (in this section In position, the breaker 211 breaks through the disk 265 a chain 262, which goes to the valve 235, which is subsequently supplied with current through the chain 278) and, thus, the valve 235 again takes a position (FIG. 28), in which pressure is released in the pipelines 241 and 237 through the outlet B of the connecting valve. At the same time, the air pressure in the oil tank 242 drops and the clutch can return to the traction position.
4116
When cam 267 leaves chopper 264, this chopper closes the circuit 290 between the clutch disabling circuit 262 and the idle contact 241, which is controlled by a pulse counter 292 in response to engine speed. engine speed, which means that the circuit 290 is not powered by the current when the engine speed exceeds the specified idle speed. Circuit 290 provides for


A contact 293 is drawn for realizing it extends into the sleeve 306, which is when manually closed or broken the chain 290, which is preferably located in the driver's cabin, is desired.
R is the same time as closes- f. with interrupter 270 by cam 267, the circuit 294 also closes, going to the electrically controlled valve 295 in the damper 296 of the throat position. Valve 295 is connected to interrupters 25 at least for lower gears, such as reverse gear, first, second and third gears (FIG. 27), but damping of the direct position can be performed for all gears by connecting circuit 294 to all interruptors are 268-275. A valve 295 is installed in the pipe 297 between the clutch oil tank 292 and the inlet / outlet of the clutch distributor cylinder 298, the input / output leading directly into the cylinder 298 to the pressure side of the piston 299 (Figure 33). Valve 295 is shunted by a pipeline with a check valve 300, which allows oil to flow from tank 242 to the inlet and outlet of the distribution cylinder, but not in the opposite direction through the shunt pipeline.
35
40
The shaft is movably mounted in the cylindrical bore 307 in the end wall 304, and is open to the piston 299 of the cylinder through a groove 308, formed in the end wall and enclosing the sleeve and a series of radial holes 309 in the sleeve 306. Inside the sleeve 306, closer to its open end, is formed a cylindrical bearing surface 310, the width in the axial direction or the length of which corresponds to the slip or the coupling coupling distance. Through said support surface extends and occupies the position shown in FIG. 33, a piston rod 311 connected to a piston 299, and the rod is provided with a piston 312 of a tine position, having such dimensions that it can pass tightly through the bearing surface 310. The position of the sleeve is relatively the piston 312 can be changed by means of an adjusting screw, which can be locked by a lock-nut 313; Thus, the thrust position can be adjusted using the adjusting screw. When the clutch is disengaged, the oil is pressed into the cylinder 298 except for the oil, which, when returning, is. Go through the inlet / outlet through the coupling sleeves to the traction position, squeezed out through the inlet / outlet of the distribution cylinder, must flow through the valve 295, from its entrance to the output or from the output to the output. The outlet is connected to line 297 between the valve and tank 242 through line 301, which contains two throttle valves 302 and 303, the latter of which is a needle valve or similar throttle valve, which is controlled in response to the gas pedal position or engine speed. so degree
50
55
306, which rests on the adjusting screw 314 and then held in this position even when the piston 312 passes through the bearing surface 310 during the movement of the piston 299 from its extreme position to its other extreme position marked by the line 315 and in which The clutch disengages completely (FIG. 33). Then the piston 299 is held in this extreme position until the valve 235, after switching on the transmission, takes up using a sensor.
42
0
throttling increases with the number of engine revolutions, i.e. the higher the engine speed, the greater the flow through the throttle 303. In this case, the clutch is very smoothly operated without any jerks and without the need to use the clutch pedal.
An inlet / outlet is located in one end wall 304 of the clutch cylinder 298, which communicates via line 305 with line 297 and which.
The shaft is movably mounted in the cylindrical bore 307 in the end wall 304, and is open to the piston 299 of the cylinder through a groove 308, formed in the end wall and enclosing the sleeve and a series of radial holes 309 in the sleeve 306. Inside the sleeve 306, closer to its open end, is formed a cylindrical bearing surface 310, the width in the axial direction or the length of which corresponds to the slip or the coupling coupling distance. Through said support surface extends and occupies the position shown in FIG. 33, a piston rod 311 connected to a piston 299, and the rod is provided with a piston 312 of a tine position, having such dimensions that it can pass tightly through the bearing surface 310. The position of the sleeve is relatively the piston 312 can be changed by means of an adjusting screw, which can be locked by a lock-nut 313; Thus, the thrust position can be adjusted using the adjusting screw. When the clutch is disengaged, the oil is pushed into the cylinder 298, except through the inlet / outlet through the sleeve.
306, which rests on the adjusting screw 314 and then held in this position even when the piston 312 passes through the bearing surface 310 during the movement of the piston 299 from its extreme position to its other extreme position marked by the line 315 and in which The clutch disengages completely (FIG. 33). Then the piston 299 is held in this extreme position until the valve 235, after switching on the transmission, takes up using a sensor.
The pressure position 277 (Fig. 28) is used to relieve pressure in the pipe 241. At the same time, the oil pressure in the hydraulic clutch system is reduced, so that the return spring of the clutch is able to return the cylinder piston 299 to engage the clutch. Oil is squeezed out of cylinder 298 through sleeve 306 until piston 312 enters bearing surface 310 and locks connection through sleeve 306, which occurs at the start of the clutch operation. This position is marked on Fig. 33 by line 316 and, since the connection through the sleeve 306 and the inlet / outlet is closed by the piston 312, oil can flow out only through the inlet / outlet, thereby moving the piston to brake and smoothly engaging . When dealing with lower gears, oil flows from inlet / outlet through pipe 300, in which the flow is choked by choke 302 and choke 303, which is controlled depending on the number of revolutions of the engine. It also contributes to the smooth engagement of the clutch, free from jerks.
When the clutch is fully engaged and the piston 299 occupies the position indicated in Fig. 28 by the line 317, the piston 312 exits the bearing surface 310 and the connection again opens through the sleeve 306 and the inlet / outlet and then the piston 299 moves relatively quickly to its extreme position.
At the beginning of the bonding process, i.e. when the piston 299 of the cylinder 298 leaves its extreme left position (FIG. 33), the clutch release lever 283 returns, which causes a break in the contact 282 of the circuit 281 and the valve 226 moves to the position shown in FIG. 33, while its output is depressurized and the valve 228 is switched so that the low pressure pipe 233 is connected to the pipe 227. Thus, the piston 206 of the cylinder 189 on the pressure side is subjected to a reduced working pressure until the next switching valve takes place. garden.
Suppose that it is necessary to carry out the inclusion of the second transmission. Gear shift lever 260 moves to second shift point.
Q 5 0 5 0
d,
five
transmission, indicated by arrow 318, the disk 265 actuates a contact that closes the circuit 262 and thereby the point E of the lateral position is adjusted by moving the piston 192. At the same time, the pressure sensor 285 closes the circuit 286, thereby turning on the relay closes the circuit leading to the valve 230, which opens as a result, and the piston 205 of the cylinder 189 from the low pressure side is subjected to increased working pressure; the two pistons 205 and 206 move to their left extreme positions (Fig. 29) to engage the second gear in the gearbox by turning the axis 186 and the gear lever mounted on it. The clutch is then engaged in the manner described.
Each gear shift is similar, however, to engage the reverse gear, first manually press contact 319 to close circuit 284 to valve 223, which opens so that increased working pressure is exerted on piston 192. Relay 320 is not actuated, but when interrupter 268 closes circuit 321 to relay 322, circuit 324 closes toward valve 224, causing it to close. Here, pressure is released in the outlet 221 and on the pressure side of the piston 193 of the cylinder 187, and the side position point is first adjusted to engage the reverse gear. When the pressure in the outlet 221 drops below a predetermined value, for example 0.25 kg / cm, the pressure sensor 323 closes the circuit and the relay 322 closes the circuit leading to the valve 230, as a result of which it opens and. causes reverse gear to engage.
As in the tap 221, a tap 325 is connected to the tap 222, which actuates when the pressure in the tap drops below a predetermined value, for example 0.25 kg / cm /, and thus closes the circuit 326 to relay 327, connected to a sixth gear chopper, to close the circuit to valve 230, the corresponding relay 328 is connected to a fifth gear chopper to close the circuit 288 going to the 45
16,225
229. To control the valve, two breakers are connected to it for the fifth and test transmissions through the circuit to which the relays are connected.
The lateral position cylinder (Fig. 24) is designed for a transmission with three points of lateral position and therefore is equipped with only two pistons. In this case, there is no need for a piston 193.
In circuit 278, there is a relay 329, which is normally closed and thus maintains circuit 278 in the closed state. When the engine speed drops to idle speed and circuit 290, current flows and thereby engages clutch through circuit 262 and valve 235 and at the same time, relay 329 turns off, which breaks circuit 278, thereby all gears whose interrupters are located after relay 329 in circuit 278 is turned off. Now the driver can choose any gear and when he then increases the engine speed, the gear selected is automatically activated as a result of breaking the chain 290.
To illustrate another application of the proposed gear shifting device (Fig. 26), a combination of vehicles is shown with two separate engines and gearboxes, one of which is mounted on a towing vehicle and the other on a trailer attached to the vehicle. Using the proposed gear shifting device, one can simply and efficiently simultaneously and simultaneously shift gears in the gearboxes of both engines and also turn off one or the other engine and use the thrust force of just one engine, it is also possible to combine vehicle combinations and increase them load capacity up to 120 tons.
The invention may be modified, for example, with fully automatic control of the gearshift process by computer or similar means — there is no need to synchronize the gearbox.
With this idea, a pulse transmitter can be installed on the engine on the outgoing shaft of the gearbox, which would register the corresponding number of engine revolutions.
8245
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to
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go dd
35
50
55
in the form of signals to a mini-computer, which, on the basis of this information, would select the necessary transmissions.
During the gearshift process, the control means controls the engine speed 1W. When it is necessary to change gears, the engine is first unloaded, thus the previously engaged gear easily leaves its gearshift point. The control means adjusts the engine speed so that it agrees with the gear engaged. The regulator is then turned off and after that the gas pedal acts as usual for foot control. In this way, quick and smooth gear changes are performed and the clutch should only be used when starting and stopping, which means that its service life is significantly increased. Since non-synchronized transmissions can be used, their cost and weight are significantly reduced, while fuel consumption is reduced, since synchronization is not required.

权利要求:
Claims (2)
[1]
1. A gear device for manual gearboxes, adapted to be attached to the gearbox to control the gearshift lever when the selected gearbox is engaged in the gearbox, containing a gearshift lever, kinematically connected to the gearshift lever, connected to lateral position cylinder and gearshift cylinder rods, a device for preventing the movement of rods before disengaging the clutch and preventing the clutch from engaging prior to engaging the transmission, the cylinder rods are mutually perpendicular to each other, and a control system including s is an air pressure source connected to a receiver connected to the clutch shut-off valve and to the shift point cylinder that is different In order to increase efficiency
by facilitating the gears of the manual gearbox, it is equipped with a second receiver, side position valve, control valves with control elements, control valves controlled by an IHOM connecting valve, shift valves, quick release valve, pressure control pneumatic chamber, the side position cylinders and gear shift points are made in the same housing, the side position cylinder includes two pistons mounted on the ends of the current, the size In the first and second chambers, one of the pistons is mounted movably relative to the rod at the inner wall of one of the chambers, and the other is fixed to the gas cylinder and installed in the middle of the other working chamber, the cylinder of the gear point includes two pistons mounted on one end of the rod and a partition between them, placed in the chamber, while the first porgaen is fixed on the rod and is located in the middle of the chamber formed by the end wall of the chamber and the partition, and the second is movably mounted on the rod and placed near the end wall and another part of the chamber, where the side position valves and gear shift points are made by three-position five-linear with control cavities with elements kinematically connected with the gear shift lever, and the device for preventing the movement of rods before disengaging the clutch the gears include a three-way shut-off valve that includes a cone plate fixed with a key on the other end of the cylinder of the switching point gears and installed in the valve box fitted with inlets and outlets, the first receiver is connected to the first chamber of the lateral position cylinder through the first controlled distribution valve, the secondary receiver is connected to one of the cavities of the second chamber of the lateral position cylinder with a cavity between the intermediate bulkhead and the second piston of the switching point cylinder, the first receiver being connected through the second controlled distribution valve to the cavity between the a daily partition and a second porin of the cylinder of the shift point, as well as with the second valve line of the lateral position, the fourth line of which is connected to the control element of the second distribution valve, and the fifth line is connected to the cavity between the end of the chamber and the first piston of the shift point cylinder, with This second receiver is connected to one control cavity of the first controlled distribution valve, through the control valve to the third and fifth valve lines of the gear shift point and The first valve switch is connected to the fourth valve line of the gearshift point and to the control valve of the control valve, and is also connected to a controlled connecting valve that is connected to the main receiver, and the control element of the connecting valve is kinematically connected to the clutch control, wherein the first and second valve lines of the shift point are respectively connected with another control cavity of the first distribution valve and with another cavity of the second cylinder chamber In the lateral position, the inlet opening of the check valve box is connected via a second valve-switch with a hydraulic line to a pneumatic pressure control chamber, the stem of which is kinematically connected with the clutch control body, and through a third valve-switch connected to the connecting cylinder, the stem of which is connected with the middle part of the clutch control, and the outlet box of the check valve box is connected via a quick release valve to the second switch valve.
[2]
2. The device as defined in claim that the side position valve and the gear shift point valve include corresponding solenoid controlled valves that are electrically connected to an electrical circuit through the switch, the switch being designed to interact with the gearshift disk, kinematically related to the clutch control,
connected with a shift lever, the shut-off valve is made with
cottages, while coaxially disk precision-electromagnetic control.
The gearshift kit is located,
a cam disc configured to interact with a switch is electrically connected FIG. 5
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同族专利:

---

公开号 | 公开日

---

WO1981003000A1|1981-10-29|

---

EP0038787A2|1981-10-28|

---

EP0038787B1|1987-08-12|

---

US4516669A|1985-05-14|

---

CA1176954A|1984-10-30|

---

DE3176359D1|1987-09-17|

---

EP0038787A3|1982-01-20|

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FR2620150B1|1987-03-31|1990-01-19|Case Co J I|SAFETY DEVICE FOR FITTING A SELF-PROPELLED MACHINE WITH STABILIZERS, IN PARTICULAR A PUBLIC WORKING MACHINE OF THE BACKHOE LOADER TYPE|

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US6588537B2|2000-08-25|2003-07-08|Bombardier Inc.|Gear shift assembly for straddle-type vehicle|

法律状态:

优先权:

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申请号 | 申请日 | 专利标题

---

SE8002794A|SE422037B|1980-04-14|1980-04-14|Gearshift device|

---

SE8006835A|SE462120B|1980-09-30|1980-09-30|Shifting arrangement for manual gearboxes|

---