• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:

    公开号:SE1251444A1
    申请号:SE1251444
    申请日:2012-12-18
    公开日:2014-05-20
    发明作者:Zoltan Kardos;Ola Hall
    申请人:Scania Cv Ab;
    IPC主号:
    专利说明:

    With this, the radiator is frequently exposed to large temperature changes with a shortened service life as a result.
    SE 532 354 shows a cooling system with a thermostat and a sensing body which senses the temperature of the coolant in one. pilot line. The pilot line receives a small portion of the coolant flow from an inlet line to the internal combustion engine. In this case, the sensing body senses the temperature of the coolant after it has cooled in the radiator. This provides a much faster feedback at times when the coolant provides rapid temperature changes in the radiator. With the help of such a pilot line, the problem of temperature cycling can be substantially avoided.
    SUMMARY OF THE INVENTION The object of the present invention is to provide a cooling system in a vehicle of the type mentioned in the introduction where the thermostat obtains a rapid feedback in the case of operation when the coolant receives a rapid temperature change in connection with two components in the cooling system.
    This object is achieved with the features in the characterizing part of claim 1. In cooling systems of the type mentioned in the introduction, there are two components that can quickly change the temperature of the coolant, namely the cooler and the intermittently activatable component. At operating times when the thermostat opens, the coolant that is led to the radiator receives a rapid and abrupt cooling. At operating times when said component is activated, the coolant which cools said component receives a rapid and abrupt heating. The internal combustion engine is a third component of the cooling system that affects the temperature of the coolant. The internal combustion engine does not usually affect the coolant temperature as quickly.
    According to the present invention, the thermostat senses the temperature of the coolant in a pilot line. With the help of a pilot line, the temperature of the coolant can be sensed at other places in the cooling system than where the thermostat is located. In this case, the temperature of the coolant is sensed at two places in the cooling system which are located substantially immediately downstream of the two components which can provide a rapid change of the temperature of the coolant. By means of such a pilot line which alternately receives coolant from two relevant positions in the cooling system, temperature changes of the coolant can be quickly indicated and accompanied by a corresponding rapid thermostat control. In the case of operation in which the intermittently activatable component is not activated or when it requires a small cooling effect, the pilot line receives coolant from the first line section. In such operating times, the cooling system receives a rapid feedback when the coolant is led to the radiator with a sudden drop in temperature as follows d. In operating cases when said component is activated and requires a high cooling power, coolant is led to the pilot line via the second inlet portion. In such operating conditions, the cooling system receives a rapid feedback when the component is activated with a sudden heating of the coolant as a result.
    According to an embodiment of the present invention, the valve arrangement comprises a three-way valve. By means of a three-way valve, the first inlet portion and the second inlet portion can be connected in a simple and fast manner alternately to the pilot line.
    Said control means may comprise a control unit adapted to receive information regarding at least one parameter indicating whether said component requires a lower or a higher cooling effect of the coolant than said threshold value and to set the valve arrangement in the first position or in the second position by means of this information . Such a control unit may constitute an electrical control unit which receives information from another control unit in the vehicle which, for example, controls the activation of said component. Thus, the control unit can obtain information indicating whether said component is activated and how much cooling power is required by the cooling system to cool the component. Alternatively, the control unit may receive information from a sensor which detects a pair of signals indicating whether said component is activated or not.
    According to an embodiment of the present invention, said component is a hydraulic retarder. Hydraulic decelerators are auxiliary brakes commonly used in heavy vehicles to reduce wear on the vehicle's wheel brakes. In a conventional hydraulic retarder, a working medium in the form of oil is led through a toroidal space created by a rotor part and a stator part. The oil provides a strong heating as it brakes the rotor part in relation to the stator part in said space. The hot oil is led to a heat exchanger where it is cooled by the coolant in the cooling system. At times when the retardem is activated, the cooling system is heavily loaded, it is therefore of great importance that the cooling of the coolant starts without delay when the retardem is activated. The hydraulic retarder can have coolant as the working medium. In this variant of hydraulic retarder, the coolant is thus led through the toroidal space instead of oil. The coolant here provides a direct heating in the retarder. In this case, a faster heating of the coolant takes place and a cooling of the coolant without delay is here even more relevant in this case than when the retarder is conventional.
    According to an embodiment of the present invention, the vehicle also comprises an exhaust brake and that said control means is adapted to set the valve arrangement in the first position and in the second position depending on the pressure of the coolant in the cooling system. A coolant purp provides a pressure increase of the coolant of a value related to the speed of the coolant pump. Coolant purns are essentially always driven by the internal combustion engine with a suitable transmission. This results in a pressure in the cooling system which is related to the speed of the internal combustion engine. Heavy vehicles often also include an exhaust brake as an auxiliary brake. An exhaust brake requires a high engine speed to provide effective braking. At times when the retarder and the exhaust brake are activated, an automatic downshift of the vehicle takes place if necessary, which results in the internal combustion engine always having a high speed when the auxiliary burners are activated. The high speed of the internal combustion engine results in the coolant pump receiving a high speed, which creates a high pressure in the cooling system. In this case, a high pressure in the cooling system is an indication that the retarder has been activated.
    According to an embodiment of the present invention, said control means is adapted to set the valve arrangement in the first position and in the second position depending on the pressure of the coolant in the line which receives coolant from said component.
    The coolant pump thus provides a pressure increase which is related to the speed of the coolant pump. The pressure becomes greatest in connection with the outlet of the coolant pump to gradually decrease in the direction of flow of the coolant towards the inlet of the coolant pump. In this case, the valve arrangement is controlled by the pressure in the line which receives coolant from the retarder. The pressure here is usually of a sufficiently large value to indicate that the retarder is activated.
    According to an embodiment of the present invention, the first inlet portion comprises a first one-way valve and a throttle and the second inlet portion comprises a second one-way valve which is loaded by a spring, said spring being dimensioned so that the second one-way valve opens when the pressure in the cooling system exceeds one. certain level. Since the pressure in the inlet line to the internal combustion engine is greater than in the line which receives coolant from the retarder, a throttle must be arranged in the first inlet portion. The throttling can consist of the entire second inlet being provided with a flow channel which has smaller dimensions than the corresponding fate channel of the second pipe section. Alternatively, the first conduit portion may be provided with a local throttle. The choke must also be of a size so as to compensate for the pressure with which the spring loads the second one-way valve in the second inlet portion.
    With such a solution, the coolant in the second conduit portion can obtain a higher pressure than the coolant in the first conduit portion. This is necessary for coolant from the other line section to be able to be led to the pilot line.
    According to an embodiment of the present invention, the coolant purpen is arranged in the line which introduces coolant into the internal combustion engine and that the first inlet portion receives the coolant in the line in a position downstream of the coolant purpen. The coolant here has its highest pressure in the cooling system in a position downstream of the coolant pinip. This facilitates the flow of coolant through the first conduit portion to the pilot conduit. The pilot line may have an outlet located in a bypass line which conducts lryl liquid from the thermostat to the inlet line of the dry combustion engine.
    The bypass clearance is located in a more downstream position in relation to the pressure side of the coolant pump than the lines in the cooling system from which coolant is led into the first pipe section and into the second pipe section. Thus, a lower pressure is obtained at the outlet of the pilot line than in said inlet portions. This pressure difference enables a fl fate of coolant from each of the respective inlet portions to the pilot line and back to the regular cooling system without additional fl fate components.
    BRIEF DESCRIPTION OF THE DRAWINGS In the following, as examples, preferred embodiments of the invention are described with reference to the accompanying drawings, in which: Fig. 1 shows a cooling system in a vehicle according to a first embodiment of the invention, Figs. 2 shows a cooling system in a vehicle according to a second embodiment of the invention and.
    Fig. 3 shows a cooling system in a vehicle according to a third embodiment of the invention. DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS OF THE INVENTION Fig. 1 shows a cooling system for cooling an internal combustion engine in a schematically shown vehicle 2. The coolant is circulated in the cooling system by means of a cooling liquid pump 4 provided in the feed After the coolant has passed through the internal combustion engine 1, it is led, via a line 5, to an intensely activatable component in the form of a hydraulic retarder 6. The cooling system is thus used for cooling an additional component in addition to the internal combustion engine 1. The retarder 6 is in this case a hydraulic retarder that uses coolant as the working medium. The vehicle 1 also comprises an additional auxiliary brake in the form of a sehematically shown exhaust brake 7. Auxiliary brakes such as retarders 6 and exhaust brakes 7 are often used in heavy vehicles 2 to reduce the wear on the ordinary wheel brakes. The coolant is led from the retarder 6, via an outlet line 8 for the retarder 6, to a thermostat 9.
    The thermostat 9 is adjustable in a closed position as it conducts the coolant from the line 9 to a bypass line 10 which is connected to the inlet line 4 to the internal combustion engine 1. The thermostat 9 is adjustable in an open position when it conducts coolant from the line 8 to a radiator 12, via a line 1 1. The radiator 12 is mounted at a front portion of the vehicle 2. A radiator 13 sucks a cooling air stream through the radiator 12 so that the coolant circulating through the radiator 12 provides efficient cooling. After the coolant has cooled in the cooler 12, it is led, via a return line 14, back to the inlet line 4 and the coolant pump 3.
    The thermostat 9 is connected to a sensing body 15. The sensing body 15 may comprise a sleeve with a closed space which is occupied by a wax substance. The wax substance has the property that it increases in volume as it melts and turns into a liquid phase. The closed space of the sensing body 15 can be defined by a flexible membrane which is fixed to a guide pin.
    The stylus is connected at an opposite end to the thermostat 9. When the wax is in a solid state, the thermostat is kept in the closed position by means of the diaphragm and the guide pin.
    At times when the wax inside the sensor body 15 melts, it increases in volume so that the membrane and the guide pin obtain a displacement which puts the thermostat 9 in the open position. The sensor body 15 is arranged in a pilot line 16.
    The pilot line 16 comprises a first inlet port 16a having an opening for receiving coolant from the inlet line 4 in a position between the coolant pump 3 and the internal combustion engine 1. The first inlet portion 16a directs coolant to a three-way valve 17. The pilot line 16 comprises a second inlet portion 16b having an opening for receiving coolant from the retarder outlet line 8.
    The opening of the second inlet portion 1619 is located in the outlet line 8 of the retarder 6. The second inlet portion 16b also conducts coolant to the three-way valve 17. The pilot line 16 conducts coolant from the three-way valve 17 to an outlet opening in the bypass line 10.
    The sensor body 15 is adapted to sense the temperature of the coolant in the pilot line 16.
    A control unit 18 is adapted to control the three-way valve 17 with information from a brake control 19 or other component in the vehicle which can at least inform whether the retarder 6 is activated or not. Advantageously, the control unit also receives information about the braking power of the retarder 6 or similar parameters which are related to the cooling power that the retarder 6 requires.
    During operation of the combustion engine 1, coolant is circulated through the cooling system.
    The control unit 18 receives information from the brake control 19 which indicates whether the retarder is activated or not. When the control unit 18 receives information indicating that the retarder 6 is not activated, it sets the three-way valve 17 in the first position. Coolant is thus led from the first inlet portion 16a to the pilot line 16. The sensing body 15 thus senses the coolant temperature in the inlet line 4 to the pre-combustion engine 1. If the coolant has a lower temperature than the control temperature of the thermostat 9, the thermostat 9 is set to the closed position. The coolant in the line 8 is in this case led to the bypass line 10 and thus to the internal combustion engine 1 without cooling. If the sensing body 15 senses that the coolant has a higher temperature than the control temperature of the thermostat 9, the thermostat 9 is set to the open position. The coolant in the line 8 is in this case led to the cooler 12 for cooling before it is led to the internal combustion engine 1.
    After a cold start of the vehicle, the thermostat 9 initially leads the coolant to the bypass line 10 and the internal combustion engine 1. without cooling. When the coolant has warmed up to the control temperature, the thermostat 9 opens so that coolant is led to the cooler 12. In this case, the coolant provides a suddenly lowered temperature in the cooler 12. Since the pilot line 16 receives coolant, via the inlet portion 16a, from the inlet line 4, the cooling system obtains a rapid indication that the temperature of the coolant has dropped. The tin state 9 is closed and the coolant is led to eat for a period without cooling to the combustion engine 1. With such rapid feedback and control of the thermostat 9, a stable coolant temperature can be obtained relatively quickly and with relatively few adjustments of the thermostat 9. The problem of temperature cycling can thus be avoided. When the control unit 18 receives information from the brake control 19 indicating that the retarder 6 has been activated, it sets the three-way valve 17 in the second position. Coolant is thus led from the second inlet portion 16b to the pilot line 16. The sensor cup 15 thus senses the coolant outlet line S of the coolant. The thermostat 9 has a control temperature which is dimensioned according to the temperature that coolant has in the inlet line 4 to the temperature of the internal combustion engine outlet 1. is substantially always higher than in the inlet line 4 to the internal combustion engine 1. Especially when the retarder 6 has been activated, the coolant has substantially always a higher temperature than the control temperature of the terinostat 9.
    The sensor body 15 senses that the coolant has a higher temperature than the control temperature and the thermostat 9 is thus set in an open position as soon as the retarder 6 has been activated. As a result, the coolant provides optimal cooling as soon as the retarder 6 has been activated. Since a retarder 6 essentially always requires a high cooling effect, it is an advantage that the thermostat 9 is set in the open position as quickly as possible and is kept in this position for the entire time that the retarder 9 is activated. Alternatively, the control unit 18 can estimate the cooling effect for the retarder 6 and adjust the three-way valve 17 only when the retarder 6 has a cooling effect above a threshold value which is greater than zero.
    Fig. 2 shows an alternative embodiment of the cooling system. In this case, the first inlet portion 16a comprises a one-way valve 16e and a throttle 10i. The second inlet portion 16b comprises a one-way valve 16d and a spring 16e which defines an opening pressure for the one-way valve 16d. The throttle 16f is dimensioned so that a pressure drop is obtained in the first inlet line 16a of a size such that the coolant in the first line portion 16a receives a lower pressure than the coolant in the second line portion 16b in connection with the pilot line 16. During operating cases when the pressure line retarder outlet 8 is not high enough to open the one-way valve. 16d, coolant is passed from the first conduit portion 16a to the pilot line 16. During operating times when the pressure in the conduit 8 is high enough to open the one-way valve 16d, coolant is led from the second conduit portion 16b to the pilot conduit 16 because the coolant in the second conduit portion 16b has a higher pressure in the first conduit portion 16a adjacent to the pilot conduit 16.
    The coolant pump 3 is driven in a conventional manner by the internal combustion engine I with a suitable transmission (not shown). The coolant purge 3 thus obtains a speed which is related to the speed of the internal combustion engine 1. The pressure increase which the coolant receives when it is pressurized by the coolant pump 3 varies with the speed of the coolant pump 3 and thus with the speed of the internal combustion engine 3. The pressure of the coolant in the cooling system thus becomes higher the higher the speed that the coolant pump 3 and the combustion engine 1 have. The magnitude of the pressure gradually decreases with the distance from the pressure side of the coolant pump 3 to its suction side. Since the pressure drop in the cooler 12 is relatively large, a relatively large part of the pressure with which the coolant is pressed can be detected by the coolant pump 3 in the line 8.
    The vehicle 2 comprises a retarder 6 and an exhaust brake 7. In connection with an activation of the auxiliary brakes, both the retarder 6 and the exhaust brake 7 are generally activated. An exhaust brake 7 requires a high engine speed to provide a good braking effect.
    The brake system in the vehicle 2 thus provides an automatic downshift if required when the exhaust brake 7 is activated so that it provides an effective braking effect. Since the coolant pump 3 is driven by the combustion engine 1, it obtains a correspondingly high speed when the auxiliary brakes 6, 7 are activated. A high speed of the coolant pump results in a high pressure in the cooling system. The spring 16e is adapted to open the one-way valve when the pressure in the line 8 exceeds a predetermined pressure value. When the internal combustion engine 1 is a diesel engine, this pressure value can correspond to a speed of the diesel engine 1 of the order of 1600-1700 rpm.
    During operation of the internal combustion engine 1, coolant is circulated through the cooling system. At operating times when the combustion engine 1 is operated at a low speed, a low pressure is obtained in the cooling system. The pressure in the line 8 is thus lower than the pressure required to open the one-way valve 16d against the action of said spring 16e. Thus, coolant is led from the first line portion 16a, via the one-way valve i6c and the throttle l6f to the pilot line 16. The sensor body 15 senses the temperature of the coolant in the pilot line 16 which in this case corresponds to the coolant temperature in the inlet line 4 to the internal combustion engine 1. control temperature, the thermostat 9 is set to the closed position. The coolant in the line 8 is in this case led to the bypass line 10 and thus to the internal combustion engine 1 without cooling in the radiator 12. If the sensor body 15 senses that the coolant has a higher temperature than the control temperature of the thermostat 9, the thermostat 9 is set to the open position. The coolant in line 8 is in this case led to the cooler 12 for cooling before it is led back to the internal combustion engine 1. 10 15 20 25 30 35 10 At operating times when a pressure is created in line 8 above a certain value, the one-way valve l6d opens against the action of the spring 16e. Thus, coolant is led from line 8 to pilot line 16. The coolant which is led into pilot line 16 from line 8 has a lower pressure so that the coolant in the first line portion 16a. Thus, coolant from the first conduit portion 16a can reach the pilot line 16. The sensing body 15 senses the coolant temperature pilot line 16 which in this case corresponds to the coolant temperature in the retarder outlet line 8. The thermostat 9 control temperature is rated according to the temperature of coolant in the inlet line 4 to the inlet line 4. The temperature of the coolant line 8 is substantially always a higher temperature than in the inlet line 4. When the internal combustion engine is operated at a high speed or when the retarder 6 has been activated, the coolant in line 8 has substantially always a higher temperature than the control temperature of the thermostat 9. As a result, the sensing body 15 sets the thermostat 9 in an open position as soon as the auxiliary side brakes 6, 7 are activated with a braking effect above a threshold value defined by the pressure in the line 8. A rapid feedback is thus obtained an effective cooling of the coolant at operating times when the retarder is activated with a braking effect above the threshold value. If the pressure in the cooling system rises above the said value at times when the retarder is not activated, it usually means that the internal combustion engine is heavily loaded.
    With this solution, a fast feedback and an efficient cooling of the coolant is thus also obtained in the case of operation when the internal combustion engine 1 is heavily loaded.
    Fig. 3 shows an alternative embodiment of the cooling system. In this case, the first conduit portion 16a and the second conduit portion 16b are controlled by a slidable valve body 20 which can be defined as a three-way valve. The valve body 20 is held in a first position by means of a spring 16g. When the valve body 20 is in a first position, the first conduit portion 16a is connected to the pilot conduit 16 at the same time, the valve body 20 breaks the connection between the second conduit portion 16b and the pilot conduit 16. The second conduit portion 16b includes a conduit portion 16b1 acting on the valve body 20 in an opposite direction against the spring l6g. The spring 16g is dimensioned so that it holds the valve body 20 in the first position with a predetermined pressure. When a higher pressure is created in the line 8 and thus in the line part 16b1 than the pressure exerted by the spring 16g, the valve body 20 is displaced to a second position. In the second position, the valve body 20 connects the second conduit portion 16b to the pilot conduit 16 while the connection between the second conduit portion 16b and the pilot conduit 16 is broken. 10 15 20 25 30 35 11 During operation of the internal combustion engine 1, coolant circulates through the cooling system. During operation when the combustion engine 1 is operated at a low speed, a low pressure is obtained in the cooling system. The pressure in the line 8 is thus lower than the pressure required to open the one-way valve 16d. Thus, coolant is led from the first line portion 16a to the pilot line 16. The sensor body 1S senses the temperature of the coolant pilot line 16 which in this case corresponds to the temperature of the coolant in the inlet line 4 to the combustion engine I. If the coolant has a lower temperature than the thermostat 9, the thermostat 9 .
    The coolant in the line 8 is in this case led to the bypass line 10 and thus to the combustion engine 1 without cooling in the cooler 12. If the sensor body 15 senses that the coolant has a higher temperature than the control temperature of the thermostat 9, the thermostat 9 is set to the open position. The coolant line 8 is in this case led to the radiator 12 for cooling before it is led back to the internal combustion engine in.
    In the case of operation when a pressure is created in the line 8 above the determined value, the one-way valve l6d opens against the action of the spring l6e. Thus, coolant is led from line 8 to pilot line 16. The sensor body 15 senses the coolant temperature in pilot line 16 which in this case corresponds to the coolant temperature in the retarder outlet line 8. The thermostat 9's control temperature is rated according to the temperature of coolant in the inlet line 4 for combustion.
    The temperature of the cooling liquid in the line 8 is substantially always higher than in the inlet line 4. Especially when the combustion engine is operated at a high speed or when the retarder 6 has been activated, the coolant in the line 8 has substantially always a higher temperature than the control temperature of the tin state 9. As a result, the sensing body 15 places the thermostat 9 in an open position as soon as the auxiliary wells 6, 7 are activated with a well power above a threshold value defined by the pressure in the line 8. A rapid feedback is obtained there, an effective cooling of the coolant at operating times when the retarder is activated with a braking effect above a threshold value. At the same time, a rapid feedback is obtained, an efficient cooling of the coolant at operating times when the internal combustion engine 1 is operated at a high speed. A high engine speed usually means that the engine is heavily loaded and that the coolant should be given a good cooling.
    The invention is in no way limited to the embodiment described in the drawing but can be varied slightly within the scope of the claims. The intermittently actuatable component is exemplified as a hydraulic retarder in the liner forks. However, the 12 intermittently activatable component may be of any component that requires a high cooling effect.
    权利要求:
    Claims (10)
    [1]
    A cooling system in a vehicle for cooling an internal combustion engine (1) and an intermediate activatable component (6), the cooling system comprising a coolant purp (3) adapted to circulate coolant in the cooling system, a cooler (5) for cooling the coolant, a pilot line (16) comprising a first inlet portion (16a) where coolant is received from a line (4) in the cooling system which leads coolant into the dry combustion engine (1), a sensing body (15) adapted to sense the temperature of the coolant in the pilot line (l 6) and a thermostat (9) which. is adapted to direct the coolant to the internal combustion engine (I) without cooling when the sensor body (15) senses that the temperature of the coolant in the pilot line (16) is lower than a control temperature and to direct the coolant to the radiator (12) before it is led to the internal combustion engine (1). (15) sensing that the temperature of the coolant in the pilot line (16) is higher than the control temperature, characterized in that the pipe (16) comprises a second inlet portion (16b) which receives coolant from a line (8) in the cooling system which receives coolant from said component ( 6), a valve arrangement (160, 16d, 17, 20) which in a first position conducts coolant from the first inlet portion (16a) to the pilot line (in 6) and in a second position conducts coolant from the second inlet portion (16b) to the pilot line (16) and control means (16b1, 16e, 16g, 18), which is adapted to set the valve arrangement in the first position when said component requires a lower cooling effect than a threshold value and id a second position when said component (6) requires a higher cooling effect than the threshold value.
    [2]
    Cooling system according to claim 1, characterized in that the valve arrangement comprises a three-way valve (17).
    [3]
    Cooling system according to claim 1 or 2, characterized in that said control means comprises a control unit (18) adapted to receive information (19) regarding at least one pair of networks indicating whether said component (6) requires a lower or a higher cooling power than said threshold value and to set the valve arrangement (17) in the first position or in the second position by means of this information.
    [4]
    Cooling system according to any one of the preceding claims, characterized in that said component is a hydraulic retarder (6). 10 15 20 25 14
    [5]
    5.. Cooling system according to Claim 4, characterized in that the hydraulic retarder (6) has coolant as working medium.
    [6]
    Cooling system according to claim 4 or 5, characterized in that the vehicle also comprises an exhaust brake (7) and that said control means (16b1, 16e, 16g) is adapted to set the valve arrangement in the first position and in the second position depending on the pressure of the coolant in the cooling system.
    [7]
    Cooling system according to claim 6, characterized in that said control means (16b1, 16e, 10g) is adapted to set the valve arrangement in the first position and in the second position depending on the pressure of the coolant in the line (8) which receives coolant from said component ( 6).
    [8]
    Cooling system according to claim 6 or 7, characterized in that the first inlet portion (16a) comprises a first one-way valve (16c) and a throttle (16t) and that the second inlet portion (16b) comprises a second one-way valve (16d) held in a closed position of a spring (16c), said spring (16c) being dimensioned so that the second one-way valve (16e) opens, so that coolant is led from the second inlet portion (10b) to the pilot line (16), when the pressure in the cooling system exceeds a certain level.
    [9]
    Cooling system according to one of the preceding claims, characterized in that the coolant pump (3) is arranged in the line (4) which leads coolant to the combustion engine (1) and in that the first inlet portion (16a) receives coolant in the line (4) in a downstream position coolant purpen (3).
    [10]
    The cooling system according to any one of the preceding claims, characterized in that the pilot line (16) has an outlet located in a bypass line (10) which leads coolant from the tin state (9) to the inlet line (4) of the internal combustion engine.
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    FR2933738B1|2008-07-11|2010-08-13|Renault Sas|METHOD FOR CONTROLLING COOLANT FLOW RATE|
    SE535781C2|2011-04-29|2012-12-18|Scania Cv Ab|Cooling system for cooling an internal combustion engine|CN104359651B|2014-12-03|2017-04-05|中国北方车辆研究所|A kind of hydraulic retarder becomes liquid filled ratio dynamic characteristic Visualization method|
    CN104458231B|2014-12-03|2017-04-05|中国北方车辆研究所|A kind of hydraulic retarder fixes liquid filled ratio dynamic characteristic Visualization method|
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    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    SE1251444A|SE536681C2|2012-12-18|2012-12-18|Cooling system in a vehicle|SE1251444A| SE536681C2|2012-12-18|2012-12-18|Cooling system in a vehicle|
    KR1020157019535A| KR20150097749A|2012-12-18|2013-11-25|Cooling system in a vehicle|
    BR112015013733A| BR112015013733A2|2012-12-18|2013-11-25|cooling system in a vehicle|
    EP13864357.2A| EP2935822B1|2012-12-18|2013-11-25|Cooling system in a vehicle|
    PCT/SE2013/051384| WO2014098711A1|2012-12-18|2013-11-25|Cooling system in a vehicle|
    RU2015129114/06A| RU2602019C1|2012-12-18|2013-11-25|Cooling system in vehicle|
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