EP0157167A1 - Cooling system for internal-combustion engines - Google Patents

Abstract

Cooling circuit for internal combustion engines with an overpressure valve (17), which limits the pressure in the flow (5) to a value at full thermal utilization of the cooling circuit, at which the pressure on the suction side (16) of the coolant pump (3) also at full head the coolant pump is always above the boiling pressure of the coolant, so that the efficiency of the cooling function is improved.

Description

The invention relates to a cooling circuit according to the design of claim 1. In cooling circuits of this type, it is customary to arrange a pressure relief valve and a vacuum valve in the filler cap. To use a working temperature of the coolant composed of water, anti-freeze and corrosion protection, which is above the boiling temperature in the atmosphere, pressure relief valves with an opening value of approx. 0.8 to 1.5 bar overpressure are used. The filler cap and the pressure relief valves are arranged either in the flow or return of the cooling circuit, for example shortly after exiting the machine's cooling jacket and after the cooler valve of a thermostat arranged there, in the flow line itself, in the flow or return water tank of vertical or cross flow -Coolers or also in an expansion tank which absorbs the thermal expansion of the coolant with an air cushion or serves for air collection and separation with a bypass flow and filling connection line to the suction side of the coolant pump.

With the arrangement of an approx. 1 bar pressure relief valve in the flow area of the cooling circuit, which is currently common in practice, this results in the operation of the machine with the highest delivery rate of the coolant pump and thus highest pressure difference between the suction side of the coolant pump and the connection point of the pressure relief valve, the coolant pressure on the suction side of the coolant pump drops regularly to the boiling pressure of the coolant if the boiling temperature of 1 bar is provided as the highest permissible coolant temperature. A further pressure drop is not possible due to physical laws, because at least the proportion of water in the coolant changes to steam when the pressure drops to boiling pressure, which is sufficient to establish an equilibrium state between liquid and vaporous parts at boiling pressure. The vapor bubbles sucked in by the coolant pump condense again due to the pressure increase in the pump, but the delivery rate of the coolant pump is reduced by the sucked-in volume of the steam produced and cavitation occurs in the pump itself due to the sudden collapse of the steam bases with its known effects on the Pump life on.

With the arrangement of the filler cap, which is also common in practice, with an approx. 1 bar pressure relief valve in the pressure area of the suction side of the coolant pump, the pressure in the cooling circuit is higher than the pressure difference between the various arrangements, even on the suction side of the coolant pump. This pressure corresponds directly to the opening value of the pressure relief valve. With constant heating of the coolant and a steady increase in the delivery rate of the coolant pump by steadily increasing the engine speed, the overpressure on the suction side of the coolant pump is always above the boiling pressure of the coolant with sufficient certainty up to the corresponding maximum permissible coolant temperature, so that vapor bubbles form on the Suction side and largely also cavitation within the coolant pump are excluded. However, as soon as the engine speed drops, in particular until idling, after the opening value of the pressure relief valve has at least approximately been reached, there is both a drop in the flow pressure and an increase in the pressure drop on the pump suction side. However, since the opening value of the upper pressure valve was at least approximately reached on the latter, such a volume fraction of the coolant or of the air cushion in the expansion tank is ejected by the pressure relief valve that the pressure in the entire cooling circuit according to the law of the communicating vessels is in accordance with the opening value of the pressure - sets valves. There is usually only a small pressure difference between the suction side of the coolant pump and its pressure side at idle speed, which can be neglected in this consideration. If the engine speed is then brought back to the previous maximum value, the pressure in the flow area increases by the reduced proportion that corresponds to the volume proportion that has escaped at the overpressure valve. The pressure on the suction side of the coolant pump also drops by a corresponding value up to the boiling pressure of the coolant at the given coolant temperature.

As a result of this functional sequence, once the engine speed has dropped once, even with this arrangement and dimensioning of the pressure relief valve, there is no security against boiling on the suction side of the coolant pump and cavitation in the coolant pump. In addition, due to the low pressure and the resulting reduced delivery capacity of the coolant pump, there is also increased vapor bubble formation at the hottest points of the machine's cooling jacket, especially in the cylinder head. As a result, the heat transfer to the coolant is impaired by an insulating vapor boundary layer and the efficiency of the cooling as a whole is reduced. Finally, the reduced heat transfer to the environment due to the lower flow velocity in the cooler also contributes to this.

In cooling circuits in which an overpressure valve with an opening value of up to approximately 1.5 bar overpressure is effective on the suction side of the coolant pump, as is used in particular on high-performance, sport and racing engines, the function sequence described above also occurs at a customary maximum permissible coolant temperature of around 120 ° C, no loss in the efficiency of the cooling. At this opening pressure value of the overpressure valve, however, when the coolant is also heated for the first time and the engine speed rises in the supply area of the cooling circuit, an excess pressure which is far above the durability limit of conventional coolers builds up. An overpressure of approximately 1.5 bar on the pump suction side results in an overpressure in the flow range of approximately 2.5 to 3 bar with a pressure difference to the flow range of approximately 1 to 1.5 bar.

DE-Z-Technische Rundschau No. 46, October 29, 1971, contains information that the delivery head of coolant pumps can assume considerable values, that an appropriate admission pressure should prevail, depending on the coolant temperature, to avoid cavitation at the pump inlet, and that when an expansion tank is arranged and thus the pressure relief valve in the flow at the pump inlet has the lowest pressure. For the latter arrangement of the pressure relief valve, however, no design information for its pressure relief opening value is included in order to meet the requirements.

On the contrary, pressure curves up to overpressure opening values of 0.5 and 1.2 bar are shown, which cannot meet these requirements, especially since these only relate to the temperature-related changes in the static coolant pressure without taking into account the superimposed dynamic pressure influences of the refer to changing coolant pump delivery rates. The additional buffer volume proposed for this purpose in this document for the storage of air in a compensating tank connected to the return area by means of a spring-loaded piston sliding in a cylinder does not take into account the dynamic influences on the coolant pressure curve in the cooling circuit, nor is it a suggestion to further develop a cooling circuit with a coolant pressure in the Flow range controlled pressure relief valve included.

The object of the invention is to develop a cooling circuit of the type described in claim 1 so that both a drop in the pressure on the suction side of the coolant pump to the boiling pressure is avoided and an excessively high pressure build-up in the flow area, especially in the flow water box of the cooler, is excluded. In addition to a clear limitation of the maximum pressure, a cooling circuit is to be created which has a high degree of efficiency over the entire working range of an internal combustion engine.

The invention solves this problem by dimensioning the pressure relief valve according to the characterizing part of claim 1. In this way it is ensured that the pressure on the suction side of the coolant pump does not drop to the boiling pressure of the coolant even when the pump delivery capacity changes, if at least approximately the maximum permissible coolant temperature is reached at this point, and that at the same time the pressure in the Flow range of the cooling circuit does not reach higher values than has previously been the case with known cooling circuits with a pressure relief valve controlled by the return range.

The features of claim 2 provide values of the pressure relief valve, which are adapted to the usual dimensions of cooling circuits. The arrangement of the pressure relief valve according to claim 3 gives in connection with the pressure drop at the outlet of the cooling jacket of the machine the advantage that during the operation of the machine the pressure course of the coolant is within normal limits, but after the machine has been switched off for the after-heating process the temperature compensation between the components and the coolant, an overpressure higher by the mentioned pressure drop is available to avoid re-boiling. Since only a static pressure load on the cooling circuit occurs, this is within the usual limits.

The features of claim 4 provide a lesson for coordinating the overall elasticity of the cooling circuit and the pressure changes of the coolant via its temperature changes by means of elastic hose lines, which means that when the coolant temperature drops below the boiling pressure, particularly on the suction side of the coolant pump, is ruled out without additional construction costs.

A coordination of the elasticity of the cooling circuit by means of an additional buffer vessel, which is expensive to construct, contains DE-Z-Technische Rundschau No. 46, October 29, 1971; however, only the pressure change of the coolant due to its temperature change is taken into account. The change in pressure course due to the change the pump delivery rate, however, is not included in the vote.

The invention is shown for example in the drawing. It shows a cooling circuit for internal combustion engines in a schematic representation with a pressure relief valve according to the invention in the flow water tank of a cooler.

An internal combustion engine 1 contains a cooling jacket indicated by an arrow 2, into which the coolant is conveyed under pressure by means of a coolant pump 3. At the outlet 4 of the cooling jacket 2, a flow 5 is connected as a line connection with a free passage to a cooler 6. The flow 5 opens into a cooler flow water tank 7. A short circuit 8 branches off from the flow 5 and opens into a mixing thermostat 9, this opening being controlled by a short circuit valve 10 of the mixing thermostat 9. From a cooler return water box 11, a line forming the return 12 from the cooler 6 likewise leads into the mixing thermostat 9, which contains a cooler valve 13 for controlling the mouth of the return 12. A suction line 15 opens from a mixing chamber 14 of the mixing thermostat 9 and opens into the suction side 16 of the coolant pump 3.

A pressure relief valve 17 is arranged on the cooler flow water tank 7 and is connected by means of an outflow line 18 to an expansion tank 19 which is open to the atmosphere and is equipped with a slotted sealing disk 19 'in its filling opening to prevent evaporation of the coolant. The pressure relief valve 17 can alternatively (17 'or 1711) be connected to the flow 5 or to the cooling jacket 2 of the machine 1. Via a suction line 20 and preferably as a return Impact valve depressurized vacuum valve 21, the expansion tank 19 is connected to the suction side 16 of the coolant pump 3. While the outflow line 18 can alternatively (18 ') also be connected to the upper area of the interior of the expansion tank 19, the suction line 20 opens out from the interior of the expansion tank 19 near the floor. Finally, the outflow line 18 can also open separately (18 ") near the bottom of the expansion tank 19. The vacuum valve 21 is combined with a filler neck 21 'to form a structural unit.

Parallel to the pressure relief valve 17, the outflow line 18 is connected to a vent valve 22, which is opened by its design as a sniffing, non-return or float valve or the like when air and a pressure-free cooling circuit are applied by the action of gravity. One or more relatively large-area fine screens 23 in the cooler 6 or in the expansion tank 19 prevent the valves from becoming leaky due to dirt particles entrained by the coolant.

In addition to the vacuum valve 21, a further pressure relief valve 24 is arranged in the filler neck 21 '. This further pressure relief valve 24 is effective via the suction line 20 directly on the suction side 16 of the coolant pump 3 and thus on its suction pressure. A vent line 25 opens into the interior of the filler neck 21 'and is located with a throttle 26 for reducing the pressure difference between its connections on the one hand on the supply water tank 7 and on the other hand via the suction line 20 on the suction side 16 of the coolant pump 3. A level float switch 21 "is installed in the filler neck 21 'or in the filler neck cover, which controls a display circuit when air accumulates in the filler neck 21', regardless of whether it is in compensation container 19 still contains an optically recognizable reserve amount or not.

The cooling circuit is filled with coolant in the filler neck 21 '. The machine 1 fills through the suction line 20 and the coolant pump 3, while at the same time the air contained therein through the supply line 5, the cooler supply water tank 7 and the ventilation line 25 into the filler neck 21 ′ as well as through the open ventilation valve 22 and the outflow line 18 escapes to the atmosphere in the expansion tank 19. As soon as the level of the flow 5 of the coolant is reached in the machine 1 and at the same time through the suction line 15, the mixing chamber 14 and the open short-circuit valve 10 of the mixing thermostat 9 in the short-circuit 8, the cooler 6 and the return line 12 also fill up to the cooler valve 13 , which can also be equipped with a conventional ventilation device. The vent valve 22 in the cooler 6 closes the filled cooler flow water tank 7 towards the outflow line 18, while the vent line 25 and the filler neck 21 fill completely. After the filler neck has been closed, the level float switch 21 "controls an electrical indicator lamp on the fittings of the machine or the vehicle. The expansion tank 19 can be partially filled with an additional reserve quantity. In the event of thermal expansion, this flows through the ambient and cooling circuit Temperature fluctuations and, in particular, due to the operational heating of the part of the coolant displaced from the cooling circuit by the pressure relief valves 17, 17 'or 17 "and 24.

During operation of the internal combustion engine 1, which usually begins with a cold start after a long cooling, in which the likewise cooled coolant content of the entire cooling circuit has a certain minimum volume has, the expansion tank 19 contains a corresponding criminal content. When the cooled machine starts, the first increase in speed immediately leads to the build-up of a delivery head of the coolant pump 3, which on the one hand causes the pump suction pressure to drop below the ambient pressure prevailing in the entire cooling circuit before starting and, on the other hand, builds up excess pressure in the cooling circuit sections downstream of the coolant pump 3, cooling jacket 2 , Flow 5, short circuit 8, cooler 6 and return 12 causes. While this overpressure does not reach the opening pressure value of the overpressure valve 17, the vacuum valve 21, which responds to the slightest pressure difference and the suction line 20 from the expansion tank 19, draws coolant into the cooling circuit until the ambient pressure is reached on the suction side 16 of the coolant pump 3. During this process, the overpressure in the parts of the cooling circuit downstream of the coolant pump 3 simultaneously increases further. The elastic hose lines and any residual air inclusions in this area allow an increase in the volume of coolant contained therein.

During further operation of the internal combustion engine 1, due to the heat transfer in the cooling jacket 2 to the coolant, its temperature rises steadily until the opening temperature value of the mixing thermostat 9 of approximately 80 ° C. is reached. This is followed by the control range of the mixing thermostat 9 with increasing opening of the cooler valve 13 and closing of the short-circuit valve 10 and also increasing flow through the cooler 6. A further rise in temperature to above approximately 95 ° C. leads beyond the control range of the mixing thermostat 9, with the bypass valve 10 closed, to the only flow through the cooler 6, with the flow rate, flow rate and heat dissipation thereby increased and also increased flow resistance and pressure build-up in the cooling jacket 2, flow 5 and cooler flow water tank 7. Depending on the volume and elasticity of the cooling circuit, in particular the hose lines of the flow 5, the short circuit 8, the return 12 and the suction line 15, and also depending After the starting temperature of the coolant during the starting process and depending on the instantaneous engine speed, the opening pressure value of the pressure relief valve 17 of approximately 2 bar or the pressure relief valve 24 of approximately 1.5 bar is reached more or less early before or after the opening of the cooling valve 13 of the mixing thermostat 9 . The engine speed is decisive because the low head of the coolant pump 3 that occurs at low to medium speeds first enables the pressure relief valve 24 to respond, which responds with an overpressure opening value that is just that pressure difference lower than the overpressure opening value of the pressure relief valve 17 which builds up between standstill or idling speed and maximum speed of the machine at the connection point of the pressure relief valve 17, 17 'or 17 ". At low engine speeds, the pressure relief valve 24 responds, which is connected to the suction side 16 of the coolant pump 3 via the suction line 20 The overpressure opening value of the pressure relief valve 17, 17 'or 17 "is decisive only in the area of the maximum speed of the machine. On the other hand, however, due to the flow resistances of the cooling circuit in the flow direction after the pressure relief valve 17, 17 'or 17 ", lower pressures occur. The pressure on the suction side 16 of the coolant pump 3 is even substantially below the upper pressure opening value of the overpressure effective there. valves 24. This is in the suction effect of the coolant pump 3 and in the elasticities distributed over the entire cooling circuit, especially of the hose lines justified. At the lowest idling speed of the machine, the pressure differences are very small and thus, as when the machine 1 is at a standstill, the entire cooling circuit assumes an overpressure corresponding to the opening value of the overpressure valve 24.

Overall, an internal pressure in the cooling circuit from the ambient pressure to the opening pressure value of the pressure relief valve 17 and during operation of the machine 1 in the area between the coolant pump 3 and the pressure relief valve 17, 17 'or 17 ", that is, above all in the cooling jacket 2, can be one above it The unambiguous limitation of the maximum and minimum pressure values avoids, on the one hand, a pressure overload of the cooler 6 with corresponding oversizing in its strength and, on the other hand, a pressure drop with an increased risk of cavitation in the coolant pump 3. The safe function with a high level Efficiency of the cooling circuit up to the design limit is guaranteed.

The overpressure, which is uniformly available in the entire cooling circuit after the machine has been switched off due to the action of the pressure relief valve 24, counteracts the formation of steam during reheating or temperature compensation between the machine and the coolant. A pressure overload of the cooling circuit components does not exist due to this relatively low, exclusively statically effective overpressure. The higher overpressure determined by the pressure relief valve 17, 17 'or 17 "is limited to the operation of the machine 1 at relatively high engine speeds, at which the pressure difference between the suction side 16 of the coolant pump 3 and the connection point of the pressure relief valve 17, 17' or 17th "is greater than the difference between the overpressure opening values of the pressure relief valves 17, 17 'and 17 "on the one hand and 24 on the other hand. This higher overpressure is therefore limited to a relatively small proportion of the operating time of the machine, in particular when driving vehicles. The durability of the cooling circuit components, in particular the cooler and the hose lines is favored.

When the machine 1 and the coolant cool down due to a reduction in the engine load, the negative pressure in the coolant also causes the excess pressure in the cooling circuit to drop. So that the overpressure, especially on the suction side of the coolant pump 3, does not drop below the boiling pressure at the respective temperature of the coolant, the overall elasticity of the cooling circuit is adjusted accordingly, above all by means of the elasticity of the hose lines.

With the start of operation of the machine 1 after the cooling circuit has been filled with coolant, the cooling circuit also begins to be vented automatically from residual air portions which have remained at various points during the filling or during operation, for example through the seals of which are briefly loaded with negative pressure during the cold start Coolant pump 3, get into the cooling circuit. These residual air fractions are flushed with the flow of the coolant from the machine 1 through the free continuous flow 5 into the cooler flow water tank 7, in which only the one determined by the throttle 26 relative to the thermostat 9 during the heating of the machine with the cooler valve 13 closed low ventilation flow. As a result, after the short-circuit 8 has branched off, a large part of the residual air can separate from the coolant in the remaining part of the flow 5 and in the cooler flow water tank 7 when the flow is calm and in the case of a larger accumulation, flow out through the then opening vent valve 22 via the outflow line 18 and possibly 18 "to the expansion tank 19. A corresponding volume of coolant can be sucked through the after-suction line 20 and the pressure relief valve 21 into the filler neck 21 'at the same time, which is due to the Effect of the pump suction pressure comes about via the suction line 20 leading to the suction side 16. Through the ventilation line 25 and the throttle 26, the ventilation flow flows to the filler neck 21 ', which directs the remaining small amounts of residual air into the filler neck and there upstream of the further pressure relief valve 24. As soon as it is heated the machine 1 and the coolant as well as the given thermal expansion and pressure increase of the coolant the upper pressure value of about 1.5 bar of this pressure relief valve 24 is reached, this opens and allows all the residual air to flow through the suction line 20 into the expansion tank 19. This process takes place s I continue or repeat myself until the heat steady state of the cooling circuit is reached. Venting also occurs when the upper pressure opening value of approximately 2.0 bar of the pressure relief valve 17 in the cooler flow water tank is reached. However, no upstream residual air fractions are removed, but only residual air fractions directly contained or dissolved in the emerging coolant are discharged into the expansion tank 19 and thus into the atmosphere. A further venting and pushing out of coolant with residual air from the filler neck 21 'into the expansion tank 19 through the pressure relief valve 24 also occurs whenever, after a warm-up operating time with a high engine speed of about 5000 to 6000 / min and a high pressure difference of about 1 bar between the cooler flow water tank 7 and the suction side 16 of the coolant pump 3, the engine speed drops considerably, in particular to the idling speed. The overpressure opening Value of about 2 bar of the pressure relief valve 17 is namely at least approximately reached at first, while the pressure opening value of about 1.5 bar of the further pressure relief valve 24 is significantly below. When the engine speed drops, the overpressure values then largely adjust to one another, so that the overpressure in the filler neck 21 ′ increases approximately to the overpressure opening value of the overpressure valve 24 there. During the subsequent subsequent subsequent heating of the coolant by the temperature compensation between the highly heated machine 1 and the coolant, the overpressure opening value of the pressure relief valve 24 is exceeded by the corresponding thermal expansion of the coolant. The residual air which may have been upstream in the filler neck 21 'is discharged into the expansion tank 19 together with a portion of coolant.

In the expansion tank 19 differs at atmospheric pressure and ambient temperature, for. B. engine compartment temperature of vehicles in the coolant as bubbles or air contained in solution from the atmosphere. A sealing washer 19 'slotted without waste allows air to enter and leave the expansion tank 19 for volume compensation, but prevents constant air movement due to convection flow. This largely prevents evaporation losses in the coolant.

Claims (4)

1. cooling circuit for internal combustion engines,
with a coolant pump (3) arranged on the inlet to the cooling jacket (2) of the machine (1), which has a cooling jacket (2), a cooler (6), a thermostat (9) and their connecting lines (flow 5, return 12 and short circuit 8 ) causes a coolant circulation with a pressure gradient that changes with the engine speed, and
with an overpressure valve (17, 17 'or 1711), which opens to the atmosphere and is controlled by the coolant pressure in the flow area (cooling jacket 2, flow 5 and cooler flow water tank 7) to limit the maximum coolant pressure, characterized in that
that the pressure relief valve (17) has an overpressure opening value which is at least approximately that pressure difference above the boiling pressure of the coolant at the maximum permissible coolant temperature on the suction side (16) of the coolant pump (3), which is between the suction side (16) of the coolant pump (3 ) and the connection point of the pressure relief valve (17, 17 ', 1711) occurs when essentially the highest delivery rate of the coolant pump (3) is given when the cooler valve (13) of the thermostat (9) is fully open. 2. Cooling circuit according to claim 1, characterized in that the pressure relief valve (17, 17 'or 17 ") has an overpressure opening value of approximately 1.5 to 2.2 bar at a maximum permissible coolant temperature on the pump suction side of approximately 90 to 120 ° C and at a pressure difference between the suction side (16) of the coolant pump (3) and the connection point of the pressure relief valve (17, 17 'or 17 ") of about 0.5 to 1.2 bar. 3. Cooling circuit according to claim 1 or 2, characterized in that
that the pressure relief valve (17 ") is connected to the cooling jacket (2) before it exits (4). 4. Cooling circuit according to one of claims 1 to 3, characterized by
elastic hose lines (for flow 5, short circuit 8, return 12, suction line 15, suction line 20 and vent line 25) in the flow and return areas between the cooling jacket (2), cooler (6), thermostat (9) and / or coolant pump (3), their elasticity together with the elasticity of the further coolant-containing cavities and / or the air or gas components contained in them with the temperature-change-related volume and pressure changes in the coolant, the pump delivery rate-related changes in pressure and the excess pressure Opening value of the overpressure valve (17, 17 'or 17 ") is matched,
that with changing coolant temperature and machine or coolant pump speed, the coolant pressure on the suction side (16) of the coolant pump (3) is always above the respective boiling pressure of the coolant.

Images