SE501444C2 - Cooling system for a retarded vehicle - Google Patents

Abstract

A cooling system for a vehicle equipped with retarder incorporates an engine cooling circuit, a retarder cooling circuit and a radiator (11) which is common to both circuits. The retarder cooling circuit (24), which is arranged in a circuit parallel with the radiator (11), incorporates a retarder cooler (23) and an extra cooling medium pump (25). This cooling medium pump (25) is operated separately and is arranged to operate during the time when the retarder (2) is activated. The fact that the retarder cooling circuit (24) is connected substantially directly to the radiator (11) eliminates the problems which are due to the presence in the engine cooling circuit of a thermostat and to the presence in the engine cooling circuit of a cooling medium pump (16) which depends on the engine speed.

Description

"501 4544 10 15 20 25 30 35 the retarder cooler. It only takes a few seconds to heat the coolant locally in the retarder cooler to boiling temperature, which is to be compared with the fact that it usually takes a few minutes to fully open the thermostat from a completely closed position. An additional factor to Note that the coolant pump is usually mechanically driven by the engine and thus has an engine speed dependent capacity.In a braking process, it is natural for the driver to release the accelerator pedal and engine brakes, with the result that the engine speed decreases with decreasing speed with lower pump capacity as a result. there is a risk of boiling the refrigerant during retarder braking.

In order to reduce this risk, it is known to apply a special driving direction to the retarder braking which comprises the driver shifting down before braking in order to increase the engine speed, and thereby increase the capacity of the refrigerant pump. A further way is to reduce the brake capacity of the retarder so that not so much heat can be developed in it. But at the same time, this is a measure that reduces the benefit of the retarder.

In order to compensate for the reduced pump capacity at low engine speeds, it is known, for example, from US 5,095,855 to provide an additional refrigerant pump in the cooling system. This auxiliary pump is electrically driven and is connected in series with the ordinary refrigerant pump, but this is only operated when the temperature of the refrigerant exceeds a certain temperature. In a cooling system without a retarder cooler, this solution should work as intended. If, on the other hand, this solution is used in a cooling system with a retarder cooler, which possibility per se is not mentioned either, the above-mentioned disadvantages remain.

The auxiliary pump is operated in dependence on the coolant temperature, with the result that this cooling system will also react too slowly for the rapid temperature changes that occur when the retarder is activated. It is likely that the refrigerant will start boiling much earlier than the pump has time to start and affect the refrigerant circulation. In addition, if a wax-type thermostat customary for cooling systems is included in the cooling system, it is too slow to have time to redirect all flow to the cooler before boiling occurs locally in the retarder cooler.

A further feature of known systems is that the braking ability of the retarder can be completely absent or greatly reduced in cases where the cooling thereof ceases to function. This can occur, for example, if the engine stops so that the cooling of the refrigerant pump ceases. Although the retarder is often considered an extra brake that is intended as a complement to the vehicle's regular brakes, the retarder also constitutes an extra brake that can be used as an emergency brake in cases where the regular brakes cease to function. However, known cooling systems which include retarder coolers and motor-driven refrigerant pumps have the disadvantage that the retarder's braking capacity is absent if the engine stops, whereby the possibility of using the retarder as an emergency brake in practice ceases.

OBJECTS OF THE INVENTION The object of the present invention is to obviate, or at least substantially reduce, the disadvantages which characterize the known solutions in which a retarder cooler enters an engine cooling system. One purpose is thus to ensure adequate cooling and prevent the risk of local boiling in the retarder cooler even in cases where the engine is operated at low engine speed and the retarder is used for vehicle braking. Another object is to enable an optimal and efficient utilization of the retarder without consciously having to reduce its braking ability due to the risk of boiling. A further purpose is that the cooling system in cases where the retarder is not used should be able to be designed in an optimal way with regard to the engine's ordinary cooling needs. In addition, the cooling system must be simple and inexpensive and not require any more extensive modifications of the other components of the cooling system in cases where the cooling system is supplemented with a retarder cooler.

A further purpose of great importance is to enable the use of the retarder as an emergency brake in most operating cases in cases where the vehicle's ordinary brakes have ceased to function.

Brief description of the invention In accordance with the invention, the desired objects are obtained by designing the cooling system with the features stated in the characterizing part of claim 1.

By arranging the operation of the second pump in accordance with the invention in dependence on the activation of the retarder, it is possible for an increased coolant flow to be started immediately and before the coolant temperature has time to increase. In this way, an increased margin is obtained before the cooking risk arises. By arranging the second pump and the retarder cooler in a separate circuit, this circuit does not become dependent on the ordinary thermostat. This means that you completely avoid the disadvantages that are due to the inertia of the thermostat and that you also avoid the pressure drop that the thermostat causes. In a conventional cooling system with a wax-type thermostat, it is not uncommon for the thermostat to account for half of the pressure drop of the entire cooling system. This means that half of the energy used to drive the pump is only used to overcome the thermostat's pressure drop. As a direct consequence of the invention, the second pump does not need to be dimensioned with respect to the pressure drop of the thermostat 10 15 20 25 30 35 ¿5n1 444 By using a separately driven pump for circulation of coolant through the retarder cooling circuit, this circulation becomes independent of the motor operation. The retarder can thus be used for braking even when the engine stops.

In an advantageous embodiment of the invention, the second pump and the retarder cooler are arranged in a separate cooling circuit which is parallel to the cooler. This embodiment is easy to apply to an existing cooling system because the application does not require any major intervention in the rest of the cooling system. It is also possible to dimension the cooling system according to the engine's cooling needs without having to consider the impact of the retarder cooler and the other pump.

In another advantageous embodiment, the retarder cooler is arranged in a line which is also included in the engine cooling circuit and which is thus always flowed through by cooling medium during the normal operation of the engine. In this case, the coolant conducted to the engine cooling ducts will first flow through the retarder cooler. This embodiment enables the retarder, by being controlled according to a special program at the start of the engine, to be used to accelerate the heating of the engine. The retarder is switched on to perform braking work at the same time as the engine is run with throttle, whereby the heat generated in the retarder raises the coolant temperature, which in turn quickly raises the engine temperature up to the normal operating temperature.

Further advantages and features of the invention will become apparent from the following description which exemplifies two embodiments of the invention. 501 Å44 10 15 20 25 30 35 List of figures The description is made with reference to the attached schematic drawings of the engine cooling system in which a second coolant pump and a retarder cooler are included. Fig. 1 shows an embodiment where the second pump and the retarder cooler are arranged in a separate cooling circuit, and Fig. 2 the pump is connected in the same cooling circuit as the engine an alternative embodiment where the second ordinary coolant pump.

Description Fig. 1 schematically shows a cooling system for an internal combustion engine 1, for example a diesel engine which is used as a drive engine for a heavier vehicle such as a truck or a bus. Arranged in the engine are cooling ducts 3 which form part of the engine's coolant circuit and which are flowed through by coolant in order to cool the engine. The refrigerant is a liquid, which is suitably a mixture of water and glycol. An outlet 5 from the engine's cooling ducts 3 is connected via a first line 6 to a thermostat housing 7, housing a thermostat, i.e. a valve controlled by the coolant temperature. The thermostat housing 7 is in turn connected both to a second line 8 and to a bypass line 9. The second line 8 is connected to the inlet 10 of a cooler 11, the outlet 12 of which is connected to the inlet via a third and a fourth line 13 and 14, respectively. 15 to an ordinary refrigerant pump 16, which is mechanically driven by the engine. An outlet 17 from the refrigerant pump 16 is directly connected to an inlet 18 to the engine cooling ducts 3. The indicated bypass 9 is in addition to the connection to the thermostat housing 7 connected to a connection between the third and fourth lines 13 and 14, respectively and thus forms one with the cooler 11 6501 444 arranged in parallel which enables cooling medium to be bypassed by the cooler 11 in dependence on the thermostat housed in the thermostat housing 7. The ordinary coolant pump 16 is mechanically driven by the engine crankshaft and its capacity is consequently dependent on the operating speed of the engine. The current cooling system as described so far constitutes an engine cooling circuit which is in itself conventional for today's engines.

In this case, the vehicle is equipped with a retarder 2, which is an auxiliary brake connected to the vehicle's transmission. The retarder 2 in this example is of the hydraulic type, by which is meant that the braking action is achieved by forcing its hydraulic fluid to circulate in the retarder under resistance. This means that during braking, the hydraulic fluid will absorb the heat generated during a braking process and which results in a rapid temperature rise of the hydraulic fluid. In order to dissipate the heat of the hydraulic fluid by means of the engine cooling system and its cooler 11, the retarder 2 comprises a retarder cooler 23, which in practice consists of a heat exchanger arranged between the hydraulic fluid of the retarder 2 and the cooling medium of the cooling system. The retarder cooler 23 is connected in a separate, with the cooler 11 parallel retarder cooling circuit 24, which also comprises an additional coolant pump 25. This coolant pump 25 is driven separately, which means that its capacity is independent of the vehicle engine operating speed or other engine parameters.

In this example, the pump 25 is driven by an electric motor and its driving takes place under the influence of an electric control system 26. Alternatively, the pump 25 can be driven by a hydraulic motor. The control system 26 is also connected to a sensor 21 arranged at the retarder 2 in order to indicate to the control unit 26 whether the retarder is activated or not. The pump 25 is advantageously of the displacement type, for example of the wing pump type, whereby the advantage is obtained that the pump 25 at standstill also prevents flow of coolant through the retarder cooling circuit 24. The pump 25 outlet is connected to the inlet 27 of the retarder cooler 23, but can alternatively be connected to its outlet 28. The retarder cooling circuit 24 also includes lines for connection to the engine cooling system on the one hand at a connection between the radiator outlet 12 and the third line 13 and on the other side at the cooler 11 inlet 10.

The function of the described cooling system is as follows.

Initially, it is assumed that the retarder 2 is not activated and that the auxiliary refrigerant pump 25 is not operated. This pump 25 will thus block the flow through the retarder cooling circuit 24. On the other hand, the ordinary coolant pump 16 will, depending on the speed of the engine 1, circulate cooling medium through the engine cooling circuit, ie through the engine cooling channels 3 and on to the thermostat housing 7. through the radiator ll, the bypass 9 or divided by both. The cooling system then operates in a conventional manner and the retarder cooler 23 and the auxiliary pump 25 do not act in any way. As the driver of the vehicle activates the retarder 2 and this in a manner known per se achieves a braking, the control unit 26 receives from the sensor 21 an indication of this with the consequence that the operation of the auxiliary coolant pump 25 starts substantially simultaneously with the activation of the retarder 2.

Cooling medium will then be sucked in from the cooler 11's outlet 12 and pumped through the retarder cooling circuit 24 with the retarder cooler 23 and eats to the cooler inlet 10. At the cooler inlet 10, cooling medium which has passed the engine cooling channels 3, provided the thermostat is open, is connected to the cooling medium from the retarder cooler . If the capacity of the auxiliary pump 25 substantially exceeds 23 to pass jointly through the cooler l1 of the ordinary pump 16, a larger proportion of the flow from the retarder cooler 23 will also be led to the cooler 11. This can lead to a slightly impaired cooling of the coolant from the engine cooling ducts 3. However, since the engine is operated with low load during a braking process and thus generates a relatively small amount of heat, this is not critical for the engine during the braking process. Preferably, both refrigerant pumps 16,25 are dimensioned with respect to capacity and pressure so that the circulation through the retarder cooling circuit 24 and the engine cooling circuit under at least the majority of operating conditions is optimal. This means, among other things, that the auxiliary pump 25 should not give rise to any backflow in the engine cooling circuit at normal engine speeds and preferably also allow a sufficient cooling of cooling medium from the engine cooling circuit.

In connection with the retarder braking ceasing, this is detected by the sensor 21 and the control unit 26 can thereby interrupt the operation of the auxiliary pump 25. In essence, the auxiliary pump 25 must be arranged to be operated during the time the retarder 2 is activated. However, it may be more appropriate to let the pump run for another while as the temperature of the coolant after braking may be elevated.

It may also be possible for the driver to reactivate the retarder shortly, and this could lead to a number of repeated switches on and off. For these reasons, the control unit 26 includes control means which maintains the operation of the pump 25 for a certain predetermined time, of the order of 30 seconds to a few minutes, after the activation of the retarder has ceased. Alternatively, the control unit 26 may be connected to means sensing the temperature of the coolant to interrupt the operation of the pump when the coolant temperature falls below a certain temperature.

In connection with the retarder 2 being activated, this is sensed by the sensor 21, which influences the control unit to activate the additional refrigerant pump 25. This leads to coolant from the retarder cooler 23 outlet 28 being supplied with flow through the retarder cooling circuit 24 and directly to the radiator. inlet 10. This flow is thus completely independent of the thermostat housed in the thermostat housing 7.

The refrigerant will thereby be cooled as much as possible in the cooler II even if its temperature is initially low. This cooling of the refrigerant means that the risk of boiling in connection with the heat development in the retarder is reduced. When the retarder 2 in connection with a braking process retards the cooler 23, the coolant is partly cooled down and in addition the flow of coolant through begins to give off heat in the retarder cooler high by activating the auxiliary pump 25.

In order to enhance this function, the invention in a modified embodiment can be arranged so that the driver can manually activate the auxiliary pump 25 immediately, for example if the coolant temperature is abnormally high.

Fig. 2 shows an alternative embodiment of the invention which includes the same components as mentioned above, but arranged in an alternative manner. The components therefore have the same reference numerals as used above where possible. The main feature of the embodiment according to Fig. 2 is that the retarder cooler 23 is arranged in the fourth line 14, ie the line between the cooler outlet 12 and the inlet 15 of the ordinary pump 16 and which line 14 also enters the engine cooling circuit. The auxiliary pump 25, on the other hand, is arranged in a separate line 31 between the outlet 28 of the retarder cooler and the inlet 10 of the cooler. The line 31 further comprises a non-return valve 32 intended to prevent coolant from flowing in the reverse direction when pump 25 is not activated and in case pump 25 is of a different type than the displacement type. The non-return valve 32 10 15 20 25 30 35 tsø1 444 ll can of course also be used together with a displacement type pump to further ensure that no cooling medium passes the pump 25 in the wrong direction. However, if the pump is of the displacement type, the non-return valve 32 can normally be disconnected. Likewise, for the same reason, the cooling system shown in Fig. 1 should be supplemented with a corresponding non-return valve if the pump 25 is not of the displacement type.

The function of the embodiment shown in Fig. 2 is substantially the same as what has been described above with reference to Fig. 1. When retarder 2 is not activated, the auxiliary pump 25 is not activated either. Flow of coolant through the line 31 is prevented by the pump if it is of the displacement type, and in addition, where applicable, by the non-return valve 32. Analogously to what is described above, coolant is pumped by the ordinary pump 16 through the engine cooling channels 3 and on to the thermostat housing 7. to the cooler 11 and / or the bypass 9 depending on the temperature of the coolant. Thereafter, the coolant is connected to the fourth line 14 and passes through the retarder cooler 23, the pump inlet 15 and the pump 16 for re-circulation through the cooling channels 3 of the engine.

Deactivation of the auxiliary pump 25 takes place analogously to what has been described above with reference to Fig. 1.

The design according to Fig. 2 also has an advantage which can be used in connection with starting the engine to accelerate the heating of the engine to normal operating temperature.

When starting the engine, the temperature of the coolant is low and the coolant will be led by the thermostat through the bypass 9 as there is no cooling need. It is then assumed that the retarder 2 is not activated. By the driver activating a special heating function in the retarder's control system (not shown) the retarder is equipped to perform a braking work at the same time as the vehicle is otherwise driving normally. In this case, however, no activation of the extra pump 25 takes place. This means that the retarder 2 performs a braking work which increases the load on the engine and which thus accelerates the heating and that the heat generated in the retarder is directly supplied to the coolant in the retarder cooler 23. engine cooling ducts 3 accelerate engine heating.

With this heating program, the retarder 2 cannot be equipped to brake at full power due to the risk of boiling. This heating function is stored as a program in the retarder control system and which retarder control system is also connected to the pump control unit 26. However, since this heating function is not directly included in the present invention, the description is delimited from further indications thereof.

The invention can be embodied in alternative embodiments within the scope of the appended claims. In the description and in the claims it is stated that the retarder cooler 23 is connected to the inlet 10 and outlet 12 of the cooler 11. By these inlets 10 and outlet 12 is meant not only what is arranged on the cooler 11 itself but also the lines 8, 13 which are connected to the inlet. 10 and the outlet 12, respectively, or other conduits which can be used for corresponding connections.

In the description, a sensor 21 and a control unit 26 are used to detect activation of the retarder 2 and to control the operation of the second pump 25. In a simple embodiment, these components can also consist of simple components, for example the sensor can be the control that the driver uses when activating the retarder and the control unit can consist of a simple relay. Both the control unit 26 and the sensor 21 therefore do not always have to consist of components which are usually referred to by these terms, but they can consist of all components which function in an analogous manner.

In the two embodiments exemplified above, the auxiliary pump 25 has been assumed to be driven by an electric motor and the control unit 26 has regulated the drive of the pump by regulating the electric motor. In an alternative embodiment, the pump does not have to be driven by any electric motor. Instead, the drive can be provided by the pump 25 being connected to other drive means which impart drive to the pump during the time the retarder is activated. Such a drive means can for instance consist of a driving force connection with the vehicle's transmission, for example with the output shaft from the vehicle's gearbox or with a power take-off on the gearbox. Such a driving connection must then comprise a detachable connection such as, for example, an electromagnetic connection in order to enable activation and deactivation of the pump in an analogous manner. A control unit designed analogously to what has been described is then used to activate the electromagnetic clutch to switch on the drive of the auxiliary pump when the retarder is activated. What is really important is really only that activation of the retarder also entails activation of the extra pump in some way during the time the retarder is activated.

Claims (8)

501 444 10 15 20 25 30 35 14 Patent claim A cooling system for a retarded motor vehicle comprising an engine cooling circuit for cooling (1) (24) cooling the retarder (2), the engine cooling circuit (11). (16) for circulating coolant through the engine of the motor vehicle and a retarder cooling circuit for, an engine cooler comprises a first coolant pump cooling channels (3), and a thermostat housing (7) with a thermostat housed therein sensing the coolant temperature to control the coolant through the engine cooler ( ll) and / or through a bypass (9) past the engine cooler (ll), and wherein the retarder cooling circuit (24) comprises a retarder cooler (23) intended to transfer heat generated to the coolant in the retarder (2) during braking processes, characterized in that the retarder cooling circuit ( 24) consists of a circuit parallel to the engine cooler (ll) which on one side is (10) the side is connected to the outlet of the engine cooler (ll) (12), that the retarder cooling circuit (24) coolant pump (25), and connected to the engine cooler (ll) inlet and a second comprises a second that the second refrigerant pump (25) is connected to drive means which are arranged to impart drive to the second pump (25) during the time the retarder (2) is activated . Cooling system according to claim 1 (25) drive is controlled under the influence of a control unit (26), characterized in that the second pump that the control unit (26) is connected to a sensor (21) sensing the activation of the retarder, and (26) the refrigerant pump (25) for driving during the retarder that the control unit is arranged to control the second actuation. 10 15 20 25 30 íso1 444. 15 Cooling system according to claim 1 or 2, characterized in that the second coolant pump (25) is driven by an electric motor or a hydraulic motor. Cooling system according to claim 2, characterized in that the second pump (25) is connected to the vehicle's transmission via a propulsion-transmitting connection, which comprises a coupling controlled by the control unit (26). Cooling system according to one of the preceding claims, characterized in that the second refrigerant pump (25) with an outlet is directly connected to the inlet (27) of the retarder cooler (23). A cooling system according to any one of the preceding claims (23) is arranged in a line (14) common to the engine cooling circuit and that this line (14) at the outlet of the retarder cooler (28) is connected to both the inlet (15) of the first refrigerant pump (16) and to the second coolant pump (25) characterized by the retarder cooler inlet. Cooling system according to any one of the preceding claims, characterized in that the retarder cooling circuit (24) (32) flows through the retarder cooling circuit (24) in a direction comprising a non-return valve which blocks is opposite to the normal flow direction of the second pump (25). 501 444 16 Cooling system according to any one of the preceding claims, characterized in that the other refrigerant pump (25) is of the displacement type which, when stationary, blocks the flow of refrigerant through the pump 5 (25). 10