JP5730237B2 - Integrated cooling system - Google Patents

Description

  The present invention relates to an integrated cooling system that uses a plurality of cooling devices each using a different cooling medium, and can cool the cooling medium of the other cooling device with the cooling medium of one of the cooling devices.

As a conventional integrated cooling system, the one described in Patent Document 1 is known.
This conventional integrated cooling system includes a first air-cooling heat exchanger (sub-radiator) that cools a heating element other than an engine such as an electric motor of an automobile with cooling water, and a second air-cooling heat that cools a cooling medium for vehicle air conditioning. An exchanger (capacitor). A water-cooled heat exchanger is arranged in the sub-radiator outflow side tank, and the cooling medium circulating in the sub-radiator is cooled with water and then flows to the condenser.

As another conventional integrated cooling system, the one described in Patent Document 2 is known.
This conventional integrated cooling system is used in a hybrid vehicle, and an air-cooled condenser (air-cooled condenser) that exchanges heat between the cooling medium and the cooling air is used between the cooling medium and the low-temperature fluid. And a water-cooled condenser for heat exchange. This low-temperature fluid is an electric system cooling water that exchanges heat with cooling air by an electric system cooler, and exchanges heat with the air conditioning medium, and is supplied to a water-cooled condenser.
On the other hand, a control valve is provided in the flow path connecting the air-cooled condenser and the water-cooled condenser. Then, based on the coolant temperature detected by the first temperature sensor provided in the electric system cooler and the refrigerant temperature detected by the second temperature sensor provided in the air-cooled condenser by the controller, the air conditioning refrigerant The control valve is controlled to switch to one of the flow path that allows the air-cooled condenser to flow from the water-cooled condenser to the air-cooled condenser, and the flow path that bypasses the water-cooled condenser and flows the air-conditioning refrigerant to the air-cooled condenser. Is done.

JP 2010-127508 A JP 2006-199206 A

However, the conventional integrated cooling system has problems as described below.
First, in the former conventional integrated cooling system, a water-cooled heat exchanger is arranged inside the sub-radiator, and a high-pressure cooling medium flows inside the water-cooled heat exchanger. If refrigerant liquid leaks from the radiator into the sub-radiator, the heat exchange efficiency of the sub-radiator decreases, or the internal pressure of the cooling circuit on the sub-radiator side increases and damages the sub-radiator and the components of this cooling circuit. It will be.

  To take this measure, it is necessary to increase the liquid-tightness of the water-cooled heat exchanger and to increase the pressure resistance of the cooling circuit components on the sub-radiator side, which is very expensive and has a large weight and size. Become.

  On the other hand, in the latter conventional integrated cooling system, the controller controls the control valve to switch the flow path based on the coolant temperature for the electric system cooler and the refrigerant temperature for the air-cooled condenser. Although there is a merit that it can be reduced, if the cooling medium leaks from the water-cooled condenser and flows into the circuit of the electric cooling water, it is unavoidable that the same problem as the former integrated cooling system occurs.

  The present invention has been made paying attention to the above-mentioned problems, and the object is to cool the cooling medium and the cooling water with two heat exchangers provided in different cooling circuits, respectively, and cool with the cooling water. In a cooling system that allows the medium to be cooled, while taking the best possible measures against leakage of the cooling medium into the cooling water, all leakage is completely avoided during the period of use. From the standpoint that it is impossible, even if the cooling medium leaks and flows into the cooling water, the cooling circuit components that use the cooling water may be damaged, or the heat in the cooling circuit An object of the present invention is to provide an integrated cooling system in which exchange efficiency is not greatly reduced.

For this purpose, an integrated cooling system according to the present invention as set forth in claim 1 is an integrated cooling system for a vehicle, wherein an air- conditioning cooling circuit for flowing an air- cooled cooling medium with an air- cooled condenser and an air-cooled cooling with a sub-radiator. a high-power system component cooling circuit flowing water, and water cooled condenser coolable cooling medium in cooling water having the air-cooled prior to being cooled by the air cooling condenser, and a downstream side of the air-cooled condenser in the air-conditioning cooling circuit a compressor is provided between the upstream side of the water-cooled condenser, a first switching valve provided between the upstream side of the downstream side to the water-cooled condenser of the compressor in the air conditioning cooling circuit, the water-cooled a second switching valve provided between the downstream side of the condenser and upstream of the air cooling condenser, is provided in the high-power system component for cooling circuit, the water-cooled co A leak detection means for detecting leakage of the cooling medium from capacitor, the cooling medium, by bypassing the water-cooled condenser, and a bi-path channel to flow upstream of the air cooling condenser, the compressor and the first A refrigerant temperature sensor that is provided between the switching valve and that detects the temperature of the cooling medium; a water temperature sensor that is provided between the sub-radiator and the water-cooling condenser and that detects the temperature of the cooling water; and And a controller for controlling switching of the first switching valve and the second switching valve in accordance with a detection result of a leak detection means, wherein the first switching valve has a downstream side of the air- cooled condenser connected to the water-cooled condenser . a first position for blocking from said bypass passage communicates with the upstream side, a downstream side of the air-cooled condenser of the water-cooled condenser And a second position in communication with the bypass passage while blocking the flow side, is switchable between said second switching valve, the connecting an upstream side of the air-cooled condenser on the downstream side of the water-cooled condenser 1 Position, a second position where the upstream side of the air-cooled condenser is blocked from the downstream side of the water-cooled condenser , and a third position where the cooling medium bypasses the air-cooled condenser and circulates through the cooling circuit for air conditioning. And the controller controls to switch both the first switching valve and the second switching valve to the second position when the leak detecting means detects the leak, and the refrigerant. Based on the temperature of the cooling medium detected by the temperature sensor and the temperature of the cooling water detected by the water temperature sensor, the first switching valve and the second The switching position of the switching valve was controlled.
It is characterized by that.

In the integrated cooling system of the present invention described in claim 1, even if the cooling medium leaks and flows into the cooling water, parts of the cooling circuit on the side using the cooling water may be damaged or the cooling It is possible to prevent the heat exchange efficiency in the circuit from greatly decreasing. In addition, it is most suitable for application to cooling circuits for air conditioning and heavy electrical parts of hybrid vehicles and electric vehicles. Furthermore, since the switching position of the first switching valve and the second switching valve is controlled according to the temperature of the cooling medium and the temperature of the cooling water, the cooling medium can be changed according to the use environment such as normal time, high water temperature, and winter. It becomes possible to perform the degree of cooling optimally.

It is a block diagram which shows the whole structure of the integrated cooling system of Example 1 of this invention. 1 is a perspective view showing a main part of Example 1. FIG. It is a figure which shows the flowchart of the switching control of a switching valve performed with the controller used with the integrated cooling system of Example 1. FIG.

  Hereinafter, embodiments of the present invention will be described in detail based on examples shown in the drawings.

  The integrated cooling system of the first embodiment is used for a hybrid vehicle equipped with an internal combustion engine and an electric motor and capable of being driven by either one or both.

  FIG. 1 is a block diagram showing the overall configuration of the integrated cooling system of the first embodiment, and FIG. 2 is a perspective view showing the main part of the integrated cooling system of the first embodiment.

  As shown in FIGS. 1 and 2, the integrated cooling system according to the first embodiment is a cooling system AC for cooling medium of an air conditioning system, and cooling of high-power components for cooling water for cooling high-power components such as an electric motor and an inverter. And a circuit EC. The cooling circuit AC for air conditioning and the high-power component cooling circuit EC are integrated by the water-cooled condenser 5 so that heat can be exchanged between the cooling media.

The cooling circuit AC for air conditioning connects the air cooling condenser 1, the expansion valve 2, the evaporator 3, the compressor 4, the water cooling condenser 5, the first switching valve V1, and the second switching valve V2. And flow paths 12 to 19 such as pipes.
For example, HFC-134a (chemical formula: CH ₂ FCF ₃ ) is used as a cooling medium flowing between these parts. The flow direction of the cooling medium is indicated by arrows in FIG.
The air-cooled condenser 1 corresponds to the first heat exchanger of the present invention. The water-cooled condenser 5 also constitutes a part of the high-power system part cooling circuit EC and corresponds to the third heat exchanger of the present invention.

The air-cooling condenser 1 includes a core portion 1c having an inflow side tank 1a and an outflow side tank 1b that are separated from each other, and a plurality of tubes (or alternately arranged tubes and cooling fins) that connect the tanks 1b and 1c. And having. The cooling medium flowing in from the inflow side tank 1a is cooled by the heat exchange between the cooling medium and the traveling wind or forced air generated by the motor / fan while flowing through the core part 1c toward the outflow side tank 1b. The
Here, the air-cooled cooling medium flows to the expansion valve 2 through the flow path 12.

  The expansion valve 2 lowers the pressure of the cooling medium cooled by the air-cooled condenser 1 and becomes a supercooled liquid, and squeezes the cooling medium to make it easier to vaporize as a low-temperature and low-pressure mist-like cooling medium. The vaporized cooling medium thus formed is sent to the evaporator 3 through the flow path 13.

The evaporator 3 is disposed in a ventilation duct of an air conditioner unit (not shown) disposed in the passenger compartment, and a low-temperature and low-pressure cooling medium that has been decompressed and expanded after passing through the expansion valve 2 is supplied to the air flow of the blower. It receives and evaporates, and cools the airflow which flows inside the air duct toward the passenger compartment.
The cooling medium exited from the evaporator 3 is sent out to the inlet of the compressor 4 through the flow path 14.

The compressor 4 compresses the cooling medium sent from the evaporator 3 to a high pressure. For example, the compressor 4 is composed of a variable discharge compressor, and the capacity control output from the controller 11 to a solenoid valve for capacity control (not shown). The discharge capacity changes (several% to 100%) in response to the signal. The compressor 4 is belt-driven by an electric motor (not shown) via an electromagnetic clutch or a direct pulley (no electromagnetic clutch) (not shown).
The cooling medium discharged from the outlet of the compressor 4 is sent to the air-cooled condenser 1 through the flow path 15 and bypassing the water-cooled condenser 5 or the flow path 18.

In the water-cooled condenser 5, the cooling medium flows through the internal flow path, and the cooling water of the high-voltage circuit EC flows through the flow path further inside the flow path, so that the cooling medium and the cooling water are between Heat exchange is performed so that the cooling medium can be cooled.
The cooling medium flowing out of the water-cooled condenser 5 is returned to the expansion valve 2 through the flow path 17 and bypassing the air-cooled condenser 1 or the flow path 19.

  Although not explicitly shown in the figure, a liquid tank is provided between the air-cooled condenser 1 and the expansion valve 2 to remove moisture and dust contained in the high-pressure medium-temperature liquefied cooling medium liquefied by the air-cooled condenser 1. It may be removed by the filter unit, and an excessive cooling medium may be temporarily stored so that the cooling medium can be sufficiently supplied at the time of rapid cooling or the like.

On the other hand, the high-power circuit EC has a water-cooled condenser 5, a sub-radiator 6, a high-power component cooling section 7, and flow paths 20-22 such as pipes connecting them, and cooling water is interposed between them. Is flowing.
In addition, the flow direction of the cooling water is indicated by arrows in FIG. The sub radiator 6 corresponds to the second heat exchanger of the present invention.

As described above, the water-cooled condenser 5 can cool the cooling medium flowing through the air conditioning cooling circuit AC with the cooling water.
The cooling water that has flowed out of the water-cooled condenser 5 passes through the flow path 20 and is sent to the high-power system part cooling unit 7.

The sub-radiator 6 is a core having a separated inflow tank 6a and outflow tank 6b, a plurality of tubes connecting the tanks 6a and 6b, and cooling fins disposed between adjacent tubes. Part 6c.
The cooling water warmed by the heavy electrical system component cooling unit 7 flows from the inflow side tank 6a and flows through the core unit 6c toward the outflow side tank 6b. Heat is exchanged between the two and the cooling water is cooled and sent to the water-cooled condenser 5 through the flow path 22.
The sub radiator 6 corresponds to the second heat exchanger of the present invention.

The high-power system part cooling unit 7 is a cooling passage formed inside the case of the electric motor, a cooling passage formed at the bottom of the case of the inverter, or the like, and the cooling water cooled by the sub-radiator 6 is allowed to flow through them. These are cooled by taking away the heat generated by high-power components such as electric motors and inverters.
The cooling water warmed by cooling the high-power components is sent to the sub-radiator 6 through the flow path 21.

FIG. 2 shows an arrangement example of the air-cooled condenser 1, the sub condenser 6, the water-cooled condenser 5, and the radiator R that cools the internal combustion engine.
In this arrangement, the air-cooling capacitor 1 is arranged adjacent to the upstream side of the radiator R, and the sub capacitor 6 is arranged on the radiator R. The water-cooled condenser 5 is disposed on the downstream side of the radiator R.
These arrangements are not limited to the above, and may be any of the variations described in the above-mentioned Patent Document 2. The water-cooled condenser 5 is placed inside the outflow side tank 6b of the sub condenser 6. You may arrange.

Further, as shown in FIG. 1, the air conditioning cooling circuit AC includes a first switching valve V1 in the middle of a flow path 15 connecting the compressor 4 and the water cooling condenser 5, and a water cooling condenser 5 and an air cooling condenser 1. A second switching valve V2 is provided in the middle of the flow path 17 connecting the two.
Further, a refrigerant temperature sensor 8 and a pressure sensor 9 are provided in the upstream portion of the flow path 15 connecting the compressor 4 and the first switching valve V1, and between the sub-radiator 6 and the water-cooled condenser 5 are provided. The water temperature sensor 10 is provided in the flow path 22 connecting the two.

  The first switching valve V1 connects the compressor 4, the air-cooled condenser 1 and the first switching valve V1, and connects the upstream portion of the flow path 15 and the first switching valve V1 and the water-cooled condenser 5 to the flow path 15. And a downstream side portion of the flow path 15 connecting the compressor 4, the air-cooled condenser 1 and the first switching valve V1, and an upstream side part of the flow path 15 connecting the first switching valve V1 and the air-cooled condenser 1 to each other. 18 (this part is shared with the downstream portion of the flow path 17 connecting the air-cooled condenser 1 and the second switching valve V2), and the upstream portion of the flow path 15 is connected to the flow path 15 It is possible to switch between the second position where the upstream portion of the flow path 15 and the flow path 18 communicate with each other while being blocked from the downstream portion.

  The second switching valve V2 is connected to the upstream side portion of the flow path 17 connecting the air-cooling condenser 1 and the second switching valve V2, and downstream of the flow path 17 connecting the second switching valve V2 and the air-cooling condenser 1 to each other. A first position where the upstream portion of the flow path 17 is blocked from the flow path 19 connecting the second switching valve V2 and the expansion valve 2, and the upstream portion of the flow path 17 Is blocked from the downstream portion of the flow channel 17, the second position where the upstream portion of the flow channel 17 communicates with the flow channel 19, and the third position where the downstream portion of the flow channel 17 is blocked from the upstream portion. It is possible to switch between positions.

These first and second switching valves V1, V2 are controlled to be switched by the controller 11.
It is desirable to arrange the first switching valve V1 as close as possible to the inlet of the water-cooled condenser 5, and the second switching valve V2 as close as possible to the outlet of the water-cooled condenser 5. It is drawn apart to do that.)

The refrigerant temperature sensor 8 detects the temperature Ta of the cooling medium flowing out of the compressor 4 and flowing in the upstream portion of the flow path 15, and sends the detection signal to the controller 11.
The pressure sensor 9 detects the pressure of the cooling medium flowing out of the compressor 4 and in the upstream portion of the flow path 15, and sends the detection signal to the controller 11. Note that the pressure sensor 9 corresponds to the leakage detection means of the present invention.
The water temperature sensor 10 detects the temperature Tb of the cooling water flowing out from the sub-radiator 6 and flowing through the flow path 22, and sends the detection signal to the controller 11.
The controller 11 is connected to an outside temperature sensor 23 for detecting the outside temperature Tc so as to receive the detection signal.

  The controller 11 is constituted by a microcomputer, and controls switching of the first switching valve V1 and the second switching valve V2 based on detection signals sent from the refrigerant temperature sensor 8, the pressure sensor 9, and the water temperature sensor 10, respectively. This valve switching control is executed according to the flowchart of FIG. Details of this will be described later.

Next, the operation of the cooling system of the present embodiment will be described with reference to FIGS.
In the cooling system configured as described above, both the first switching valve V1 and the second switching valve V2 are normally in the first position.
Accordingly, in the cooling circuit AC for air conditioning, the cooling medium is air-cooled by the air-cooling condenser 1 to be in a supercooled liquid state and sent to the expansion valve 2 through the flow path 12.

The expansion valve 2 makes it easy to vaporize as a low-temperature and low-pressure mist-like cooling medium by reducing the pressure of the cooling medium in the supercooled liquid state to a low pressure. The cooling medium thus vaporized is sent to the evaporator 3 through the flow path 13, where the low-temperature and low-pressure cooling medium that has passed through the expansion valve 2 and expanded under reduced pressure is subjected to the air flow of the blower. The cooling medium, which has been evaporated to a low temperature, cools the air flow that flows in the air duct toward the passenger compartment and cools the passenger compartment.
The cooling medium heated by exchanging heat with the evaporator 3 is sent to the compressor 4 through the flow path 14.

In the compressor 4, the cooling medium is compressed to a high pressure (and therefore the temperature also rises), and then sent to the water-cooled condenser 5 through the flow path 15 and the first switching valve V1.
When the cooling medium passes through the water-cooled condenser 5, it is cooled by exchanging heat with the cooling water of the high-power system component cooling circuit EC, further cooled by the air-cooled condenser 1 through the flow path 17, and then passed through the flow path 12. Sent to expansion valve 2.
In this way, the cooling medium circulates through the air conditioning cooling circuit AC.

On the other hand, in the high-power component circuit EC, the cooling water heated by cooling the high-power components in the high-power component cooling unit 7 is sent to the sub-radiator 6 through the flow path 21. The cooling water is air-cooled by the sub-radiator 6 and sent to the water-cooled condenser 5 through the flow path 22.
In the water-cooled condenser 5, heat exchange is performed between the low-temperature cooling water cooled by the sub-radiator 6 and the cooling medium flowing into the water-cooled condenser 5 from the compressor 4 of the air conditioning cooling circuit AC. After being cooled with the cooling water, it passes through the flow path 20 and is sent to the high-power system part cooling unit 7.
Although the cooling water is slightly warmed by the water-cooled condenser 5, it is sufficiently low to cool the high-power components, so the high-power components are cooled and returned to the sub-radiator 6 through the flow path 21. In this way, the cooling water circulates through the high-power component cooling circuit EC.

In addition, when the load of the high-power components is large and the heat generation amount is large, the temperature of the cooling water becomes high. In such a case, since the cooling medium discharged from the compressor 4 cannot be cooled with the cooling water in the water-cooled condenser 5, the first switching valve V1 and the second switching valve V2 are both set to the second position. The cooling medium is cooled only by the air-cooled condenser 1.
That is, the cooling medium is cooled by the air-cooling condenser 1 and flows through the expansion valve 2, the evaporator 3, and the compressor 4 in this order in the same manner as in the normal state, and cools the passenger compartment, but is discharged from the compressor 4. The cooling medium is returned to the air-cooled condenser 1 through the upstream portion of the flow path 15, the first switching valve V 1, and the flow path 18. At this time, the cooling medium cannot flow to the downstream portion of the flow path 15 and the upstream portion of the flow path 17.
As a result, the cooling medium does not exchange heat with the high-temperature cooling water in the water-cooled condenser 5.
In the high-power component cooling circuit EC, the cooling water flows in the same way as in the normal case, except that the water cooling condenser 5 does not exchange heat with the cooling medium as described above.

  Although the passenger compartment is not cooled unlike the winter season, the air conditioning system may be operated to remove the fog on the front window. At this time, if the cooling medium is cooled too much, the stability of the air conditioning cycle is hindered. In such a case, the first switching valve V1 is in the second position and the second switching valve V2 is in the second position. Thus, the cooling medium bypasses the air-cooled condenser 1.

That is, the cooling medium discharged from the compressor 4 is sent to the water-cooled condenser 5 through the flow path 15, where it is cooled by exchanging heat with the cooling water flowing through the high-power component cooling circuit EC. The cooling capacity here is considerably lower than the cooling capacity of the air-cooled condenser 1.
The cooling medium cooled by the water-cooled condenser 5 passes through the upstream portion of the flow path 17, the second switching valve V 2, and the flow path 19, bypasses the air-cooled condenser 1, and is sent to the expansion valve 3. Thereafter, it is returned to the compressor 4 via the evaporator 13.
The cooling water flowing through the high-power system parts cooling circuit EC is the same as that in the normal time.

  For air conditioning when there is no engine in an electric vehicle or when the engine is cold without being operated in a hybrid vehicle, the heat pump system is combined with the cooling system of this embodiment to effectively use the exhaust heat. In order to avoid overcooling the cooling medium, the air-cooled condenser 1 does not perform heat exchange, but only the water-cooled condenser 5 performs heat exchange. The switching valves V1 and V2 are switched and controlled.

  In the unlikely event that the cooling medium leaks from the cooling circuit AC for air conditioning, the pressure in this circuit AC will drop, so if it drops more than normal, it will be detected by the pressure sensor 9 placed in the flow path 15 The controller 11 detects the leakage of the cooling medium based on the pressure, and the first switching valve V1 is set to the second position and the second so that the cooling circuit AC for air conditioning is disconnected from the high-power component cooling circuit EC and becomes independent. Switch the switching valve V2 to the third position.

As a result, the cooling medium discharged from the compressor 4 to the upstream portion of the flow path 15 is blocked from the downstream portion of the flow path 15 by the first switching valve V1, communicated with the flow path 18, and sent to the air cooling condenser 1. It is done. On the other hand, the downstream portion of the flow channel 17 is blocked from the upstream portion of the flow channel 17 by the second switching valve V2.
Therefore, the cooling medium does not flow into the water-cooled condenser 5 from the upstream side portion of the flow path 15 and from the downstream side portion of the flow path 17.

As a result, even if the coolant leaks in the water-cooled condenser 5 and flows into the cooling water of the high-power system cooling circuit EC, the first and second switching valves V1 and V2 are placed close to the water-cooled condenser 5. If it is placed, the amount of leakage will be slightly suppressed, so there will be almost no decline in the cooling efficiency of the high-power system cooling circuit EC required for vehicle travel, and the pressure in the high-power system cooling circuit EC will increase. Problems such as breakage of the lever parts, for example, the sub-radiator 6, can be eliminated.
On the other hand, if the leak is in a part other than the water-cooled condenser 5, the cooling circuit AC for air conditioning may become unusable, but there is no problem because the above-described malfunction of the high-power system parts cooling circuit EC does not occur.
Note that when the leakage of the cooling medium is detected in this way, the air conditioning cooling circuit AC is forcibly stopped.

In performing the above-described operation of the cooling system of the present embodiment, the controller 11 executes the flow chart of FIG.
Hereinafter, switching control of the first and second switching valves V1, V2 will be described according to a flow chart.

After initialization when the power is turned on, as shown in the flow chart of FIG. 3, the controller 11 first cools the pressure sensor 9 through the upstream portion of the flow path 15 of the air conditioning cooling circuit AC in step S1. A detection signal of the medium pressure P is received.
Then, it progresses to step S2.

In step S2, it is determined whether or not the read pressure P of the cooling medium is equal to or lower than a predetermined value Pc. If the determination result is NO, the process proceeds to step S3, and if the determination result is YES, the process proceeds to step S12.
The determination here is for detecting whether or not the cooling medium is leaking from the air conditioning cooling circuit AC. Therefore, the predetermined value Pc is set to a value that is slightly lower than the lowest pressure that can occur when the cooling medium does not leak from the air conditioning cooling circuit AC.

In step S3, the temperature Ta of the cooling medium discharged from the compressor 4 detected by the refrigerant temperature sensor 8, and the temperature Tb of the cooling water flowing out from the sub-radiator 6 detected by the water temperature sensor 10, Further, the controller 11 reads the outside air temperature Tc detected by the outside air temperature sensor 23.
Then, it progresses to step S4.

In step S4, it is determined whether or not the outside air temperature Tc is equal to or lower than a first predetermined temperature T1. If the determination result is YES, the process proceeds to step S11, and if the determination result is NO, the process proceeds to step S5.
Here, the first predetermined temperature T1 is set to a low temperature for determining whether or not it is winter.

In step S5, it is determined whether the temperature Tb of the cooling water is equal to or lower than a second predetermined temperature T2. If the determination result is YES, the process proceeds to step S6, and if the determination result is NO, the process proceeds to step S10.
The determination here is to determine whether or not the temperature Tc of the cooling water is higher than the predetermined temperature T2 due to an increase in load, and therefore the predetermined value T2 is set to 65 ° C., for example.

  In step S6, it is determined whether or not the temperature Tb of the cooling water is equal to or lower than the temperature Ta of the cooling medium. If the determination result is YES, the process proceeds to step S7 assuming that it is a normal state. If the determination result is NO, the process proceeds to step S10.

In step S7, it is determined whether or not the temperature Ta of the cooling medium is equal to or lower than a third predetermined temperature T3. If this determination result is NO, the process proceeds to step S8, and if the determination result is YES, the process proceeds to step S9.
In this determination, it is determined whether or not the cooling medium is at a low temperature equal to or lower than the third predetermined temperature T3 and is in a temperature region that does not need to be cooled by the air-cooled condenser 1.

In step S8, both the first switching valve V1 and the second switching valve V2 are set to the first position. As a result, the upstream portion and the downstream portion of the flow path 15 are communicated with the upstream portion of the flow path 17, respectively.
Therefore, the cooling medium flows to the water-cooled condenser 5 where it is cooled by the cooling water and then sent to the air-cooled condenser 1.
Subsequently, the process returns to step S1.

In step S9, the first switching valve V1 is set to the first position, and the second switching valve V2 is set to the third position. As a result, the upstream portion of the flow channel 15 communicates with the downstream portion, and the upstream portion of the flow channel 17 is blocked from the downstream portion and communicated with the flow channel 19.
Therefore, the cooling medium discharged from the compressor 4 is cooled by the water cooling condenser 5 and then circulates in the air conditioning cooling circuit AC bypassing the air cooling condenser 1, so that there is no concern that the cooling medium is excessively cooled. It is also possible to use the heat of the exhaust gas in combination with a heat pipe system.
Subsequently, the process returns to step S1.

In step S10, both the first switching valve V1 and the second switching valve V2 are set to the second position. As a result, the upstream portion of the flow channel 15 is blocked from the downstream portion and connected to the flow channel 18. Further, the downstream portion of the flow path 17 is blocked from this upstream portion.
Therefore, the cooling medium bypasses the water-cooled condenser 5 and is cooled by the air-cooled condenser 12, and circulates through the air-conditioning cooling circuit AC independently of the high-power system parts cooling circuit EC.
Subsequently, the process returns to step S1.

In step S11, the first switching valve V1 is set to the first position, and the second switching valve V2 is set to the third position. As a result, the first cooling medium discharged from the compressor 4 is cooled by the water cooling condenser 5 and then flows from the expansion valve 2 to the compressor 4 bypassing the water cooling condenser 1.
Subsequently, the process returns to step S1.

In step S12, both the first switching valve V1 and the second switching valve V2 are set to the second position. As a result, the upstream portion of the flow channel 15 is blocked from the downstream portion and communicated with the flow channel 18. Further, the downstream side of the flow path 17 is blocked from this upstream side.
Therefore, the water-cooled condenser 5 is disconnected from the air-conditioning cooling circuit AC and does not newly flow in other than the cooling medium that was not in the water-cooled condenser 5.

In addition, when the internal pressure of the high-power system cooling circuit EC on the sub-radiator 6 side becomes high and a pressure higher than the specified value is detected by the pressure sensor, that is, when leakage of the cooling medium is detected in the high-power system cooling circuit EC In this case, supply of the cooling medium to the high-power system cooling circuit EC is cut off, but if the cooling medium continues to leak until the pressure is equalized in the high-power system cooling circuit EC that has caused the leakage of the cooling medium, Parts may be damaged.
Therefore, when the pressure sensor 9 detects a pressure equal to or higher than a predetermined value, the compressor 4 is stopped to reduce the refrigerant pressure in the air conditioning cooling circuit AC. Alternatively, the fan for the air-cooling condenser 1 is rotated at a high speed to reduce the refrigerant pressure in the cooling circuit AC for air conditioning, thereby reducing the pressure in the water-cooling condenser 5 and reducing the circulation amount of the cooling medium in the refrigeration cycle.
As a detection means for detecting refrigerant leakage, a pressure sensor 9 is set in the vicinity of heat exchange between the water-cooled condenser 5 and the sub-radiator 6, and the pressure sensor 9 is preferably provided in the cooling water path of the water-cooled condenser 5. .

As described above, in the cooling system of the present embodiment, the following effects can be obtained.
When the leakage of the cooling medium from the air conditioning cooling circuit AC is detected by the pressure sensor 9, the first switching valve V1 shuts off the upstream portion of the flow path 15 between the compressor 4 and the water cooling condenser 5 from the downstream portion. At the same time, the second switching valve V2 blocks the downstream portion of the flow path 17 between the water-cooled condenser 5 and the air-cooled condenser 1 from the upstream portion.

As a result, the water-cooled condenser 5, and thus the high-power component circuit EC, can be separated from the air conditioning cooling circuit AC. As a result, when the cooling medium leaks from the air conditioning cooling circuit AC, even if the above leakage occurs in the water-cooled condenser 5 and flows from the air conditioning cooling circuit AC to the high-voltage component circuit EC, the inflow amount thereof is Only a small amount corresponding to the downstream portion and the upstream portion of the flow path 17 (these portions are set short) and the amount corresponding to the water-cooled condenser 5 are included.
Therefore, there is almost no decrease in the cooling efficiency of the high-power component circuit EC, and there is no fear of damage to the high-power component circuit EC because there is no high voltage.

The switching of the first switching valve V1 and the second switching valve V2 is controlled according to the detected temperatures of the refrigerant temperature sensor 8 in the flow path 15 and the water temperature sensor 10 in the flow path 22.
Therefore, the first cooling refrigerant passes through both the air-cooled condenser 1 and the water-cooled condenser 5, depending on the usage environment such as normal time, high water temperature, and winter. Can exhibit a good cooling function. In addition, a heat pump system can be used in combination.

  The present invention has been described based on the above embodiments. However, the present invention is not limited to these embodiments, and is included in the present invention even when there is a design change or the like without departing from the gist of the present invention. .

For example, the integrated cooling system of the present embodiment is applied to a hybrid vehicle, but may be applied to an electric vehicle or other devices.
At that time, the switching control of the first switching valve V1 and the second switching valve V2 can be appropriately changed according to the purpose of use and the usage environment.

  Further, the detection of the leakage of the cooling medium is not limited to the pressure sensor of the embodiment, and other means may be used.

R radiator
1 Air-cooled condenser (first heat exchanger)
2 Expansion valve
3 Evaporator
4 Compressor
5 Water-cooled condenser (third heat exchanger)
6 Sub radiator (second heat exchanger)
7 Cooling part for heavy electrical parts
8 Refrigerant temperature sensor
9 Pressure sensor
10 Water temperature sensor
11 Controller
12-22 flow path
23 Outside temperature sensor

Claims (1)

An integrated cooling system for a vehicle,
An air- conditioning cooling circuit that flows an air- cooled cooling medium using an air-cooled condenser ;
A cooling circuit for high-power components that flows cooling water that is air-cooled by a sub-radiator ,
A water-cooled condenser capable of cooling the cooling medium before being cooled by the air-cooled condenser with the air-cooled cooling water;
A compressor provided between the downstream side of the air-cooled condenser and the upstream side of the water-cooled condenser in the cooling circuit for air conditioning;
A first switching valve provided between the downstream side of the compressor and the upstream side of the water-cooled condenser in the cooling circuit for air conditioning ;
A second switching valve provided between the downstream side of the water- cooled condenser and the upstream side of the air-cooled condenser ;
Leakage detecting means provided in the cooling circuit for the high-power components and detecting leakage of the cooling medium from the water-cooled condenser ;
Said cooling medium, said bypass the water-cooled condenser, and a bi-path channel to flow upstream of the air cooling condenser,
A refrigerant temperature sensor provided between the compressor and the first switching valve for detecting the temperature of the cooling medium;
A water temperature sensor that is provided between the sub-radiator and the water-cooling condenser and detects a temperature of the cooling water;
A controller for controlling switching of the first switching valve and the second switching valve according to a detection result of the leak detection means;
With
Wherein the first switching valve has a first position for blocking from the bypass flow passage communicated with the downstream side of the air-cooled condenser on the upstream side of the water-cooled condenser, a downstream side of the air-cooled condenser from the upstream side of the water-cooled condenser It is possible to switch between a second position that shuts off and communicates with the bypass flow path,
The second switching valve has a first position for connecting the upstream side of the air-cooled condenser on the downstream side of the water-cooled condenser, and a second position for blocking the upstream of the air cooling condenser from the downstream side of the water-cooled condenser, the cooling medium Can be switched between a third position for bypassing the air-cooling condenser and circulating the cooling circuit for air conditioning ,
The controller controls to switch both the first switching valve and the second switching valve to the second position when the leak detecting means detects the leak, and the controller detects the refrigerant temperature sensor. The switching positions of the first switching valve and the second switching valve are controlled based on the temperature of the cooling medium and the temperature of the cooling water detected by the water temperature sensor.
Integrated cooling system characterized by that.

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