KR20230108585A - Cooling water circulating controll device - Google Patents

Abstract

The present invention introduces a coolant distribution control device that selectively circulates coolant through a plurality of coolant flow paths through a single valve and secures efficient cooling performance through temperature management of the coolant by individually or mixedly distributing the coolant for each situation. do.

Description

Cooling water distribution control device {COOLING WATER CIRCULATING CONTROLL DEVICE}

The present invention relates to a cooling water flow control device that selectively circulates cooling water through a plurality of cooling water flow paths through a single valve.

An electric vehicle is a vehicle that obtains driving energy from electric energy, not from burning fossil fuels like conventional vehicles. Electric vehicles have the advantage of no exhaust gas and very little noise, but they have not been put into practical use due to problems such as the heavy weight of the battery and the time it takes to charge. Its development is accelerating again.

In general, an electric vehicle driven by a motor is equipped with an inverter, an LDC for converting DC power to AC power, a charger, etc., and a cooling system capable of always maintaining an appropriate temperature is required due to their heating characteristics.

To this end, the cooling system is provided with a water pump for circulation of cooling water, and the cooling water discharged from the water pump passes through the motor and electrical devices related thereto and then circulates through a heat source, thereby protecting various electrical devices having heat generating characteristics from overheating. .

Conventional internal combustion engines use waste heat generated by combustion to heat the interior, so there is little increase in fuel consumption by heating. and maintain indoor heating and battery temperature. To this end, a heat pump system using a refrigerant as a medium and a device for appropriately adjusting the flow of cooling water circulating around a battery and a motor are required.

That is, as each electronic device must be managed for the highest efficiency of the vehicle under various conditions, a complex flow path and a plurality of valves are required, and a structure for cooling water distribution becomes excessive.

The matters described as the background art above are only for improving understanding of the background of the present invention, and should not be taken as an admission that they correspond to prior art already known to those skilled in the art.

KR 10-2018-0099007 A (2018.09.05)

The present invention has been proposed to solve these problems, and the cooling water is selectively circulated through a plurality of cooling water flow paths through a single valve, and the efficiency of temperature management of the cooling water is improved by individually or mixedly distributing the cooling water according to the situation. It is an object of the present invention to provide a cooling water distribution control device.

An apparatus for controlling the distribution of cooling water according to the present invention for achieving the above object includes a first cooling water line through which cooling water is distributed to a first pump, a battery, and a first heat exchanger; a second coolant line through which the coolant flows through the second pump, the electrical module, the second heat exchanger, and the radiator; a housing provided with a cooling water sharing space and formed with a plurality of passages allowing the first cooling water line and the second cooling water line to communicate with the cooling water sharing space; and a plurality of circulation portions provided to be rotated in the cooling water sharing space of the housing and selectively matched to the first cooling water line and the second cooling water line according to the rotational position, so that the cooling water is separated into the first cooling water line and the second cooling water line. It includes a valve for distributing or being mixed in the first coolant line and the second coolant line.

The outer surface of the valve is characterized in that the first circulation portion and the second circulation portion are formed to be spaced apart from each other, and each of the first circulation portion and the second circulation portion extends in a circumferential direction so that at least two flow paths of the housing are connected.

The passage of the housing is a circulation passage that communicates singularly with the first or second coolant line and the first or second circulation part of the valve, and the first or second coolant line is connected to the first circulation part of the valve. And it is characterized by consisting of a shared flow path to selectively distribute to the second distribution unit.

The flow path of the housing consists of a first sharing flow path selectively matched to the first distribution part and the second distribution part of the first pump and the valve, and a second circulation passage selectively matched to the first distribution part of the first heat exchanger and the valve. It is characterized in that the cooling water is circulated through the first cooling water line.

The flow path of the housing includes a second circulation flow path selectively matched to the second circulation part of the radiator and the valve, a second sharing flow path selectively matched to the first circulation part and the second flow part of the second pump and the valve, and a second heat exchange flow path. It is characterized in that the third circulation flow path selectively matched with the second circulation part of the roof tile and the valve is configured so that the cooling water is circulated through the second cooling water line.

The first distribution part of the valve is characterized in that it extends so that the first sharing passage and the first circulation passage, and the first circulation passage and the second sharing passage selectively communicate with each other according to the rotational position.

Depending on the rotational position of the second distribution part of the valve, the first sharing flow path and the second circulation flow path, the second circulation flow path and the second sharing flow path, the first sharing flow path and the third circulation flow path, and the second sharing flow path and the third circulation flow path are It is characterized in that it is extended to selectively communicate.

The first cooling water line and the second cooling water line share a reservoir tank, and the cooling water is supplied through the reservoir tank.

A motor installed in the housing and connected to the valve to adjust the rotational position of the valve; and

Characterized in that it further comprises; a controller for determining the rotational position of the valve by controlling the motor according to a preset mode.

When the first mode is performed, the controller controls the valve so that the first circulation flow path of the housing communicates with the first shared flow path through the first circulation part of the valve and the second circulation flow path of the housing communicates with the second shared flow path through the second circulation part. It is characterized in that the cooling water is individually distributed to the first cooling water line and the second cooling water line by controlling the rotational position.

When the second mode is performed, the controller controls the valve so that the first circulation flow path of the housing communicates with the second sharing flow path through the first circulation part of the valve and the second circulation flow path of the housing communicates with the first sharing flow path through the second circulation part. It is characterized in that the cooling water is mixed and distributed in the first cooling water line and the second cooling water line by controlling the rotational position.

When the third mode is performed, the controller rotates the valve so that the first circulation passage of the housing and the second sharing passage communicate with each other through the first distribution part of the valve, and the first sharing passage and the third circulation passage communicate with each other through the second distribution part. By controlling, the cooling water is mixed and distributed in the first cooling water line and the second cooling water line.

When the fourth mode is performed, the controller rotates the valve so that the first circulation passage of the housing communicates with the first sharing passage through the first distribution part of the valve, and the second sharing passage and the third circulation passage communicate through the second distribution part. It is characterized in that the cooling water is individually distributed to the first cooling water line and the second cooling water line by controlling the.

The cooling water distribution control device configured as described above allows the cooling water to be selectively circulated through a plurality of cooling water flow paths through a single valve, and individually or mixedly distributes the cooling water according to the situation, thereby managing the temperature of the cooling water for efficient cooling performance. this is secured

1 is a block diagram of a cooling water distribution control device according to the present invention.
2 is a view showing a cooling water distribution control device according to the present invention.
3 is a view showing the housing of the present invention.
4 is a view showing an internal flow path of the housing shown in FIG. 3;
5 is a view showing the valve of the present invention.
6 is a view for explaining the control according to the first embodiment of the cooling water distribution control device according to the present invention.
7 is a view for explaining the control according to the second embodiment of the cooling water distribution control device according to the present invention.
8 is a view for explaining the control according to the third embodiment of the cooling water distribution control device according to the present invention.
9 is a view for explaining the control according to the fourth embodiment of the cooling water distribution control device according to the present invention.

Hereinafter, a cooling water distribution control device according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

Specific structural or functional descriptions of the embodiments of the present invention disclosed in this specification or application are merely exemplified for the purpose of explaining the embodiments according to the present invention, and the embodiments according to the present invention may be implemented in various forms. and should not be construed as being limited to the embodiments described in this specification or application.

Embodiments according to the present invention can apply various changes and can have various forms, so specific embodiments are illustrated in the drawings and described in detail in this specification or application. However, this is not intended to limit the embodiments according to the concept of the present invention to a specific disclosed form, and should be understood to include all modifications, equivalents, or substitutes included in the spirit and technical scope of the present invention.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined herein, they are not interpreted in an ideal or excessively formal meaning. .

Hereinafter, the present invention will be described in detail by describing preferred embodiments of the present invention with reference to the accompanying drawings. Like reference numerals in each figure indicate like elements.

1 is a block diagram of a cooling water distribution control device according to the present invention, FIG. 2 is a view showing the cooling water distribution control device according to the present invention, FIG. 3 is a view showing a housing of the present invention, and FIG. It is a view showing the inner flow path of the illustrated housing, and FIG. 5 is a view showing the valve of the present invention.

6 is a view for explaining the control according to the first embodiment of the cooling water distribution control device according to the present invention, and FIG. 7 is a view for explaining the control according to the second embodiment of the cooling water distribution control device according to the present invention. FIG. 8 is a view for explaining the control according to the third embodiment of the cooling water distribution control device according to the present invention, and FIG. 9 is the control according to the fourth embodiment of the cooling water distribution control device according to the present invention. It is a drawing for explanation.

As shown in FIGS. 1 to 4 , the cooling water distribution control device according to the present invention is a first cooling water line 10 that allows cooling water to flow through the first pump 11 , the battery 12 , and the first heat exchanger 12 . ); and a second coolant line 20 through which the coolant flows through the second pump 21, the electrical module 22, the second heat exchanger 23, and the radiator 24; a housing 30 having a cooling water sharing space 36 and having a plurality of flow passages allowing the first cooling water line 10 and the second cooling water line 20 to communicate with the cooling water sharing space 36; and a plurality of circulation portions provided to be rotated in the cooling water sharing space 36 of the housing 30 and selectively matched to the first cooling water line 10 and the second cooling water line 20 according to the rotational position, and cooling water It includes a valve 40 for distributing individually to the first coolant line 10 and the second coolant line 20 or mixed and distributed to the first coolant line 10 and the second coolant line 20.

Here, the first coolant line 10 and the second coolant line 20 share the reservoir tank 50, and the first coolant line 10 and the second coolant line 20 are supplied through the reservoir tank 50. By supplying the cooling water, the cooling water is circulated to each part.

In addition, the motor 60 is installed in the housing 30, and the motor 60 is connected to the valve 40 so that the rotational position of the valve 40 can be adjusted according to the operation of the motor 60.

In the first cooling water line 10 , the cooling water is circulated to the battery 12 and the first heat exchanger 13 by the driving of the first pump 11 and exchanges heat. Here, the first heat exchanger 13 may be configured to adjust the temperature of the cooling water circulating in the first cooling water line 10 through heat exchange with a medium such as a refrigerant, outside air, or other cooling water.

In the second coolant line 20, the coolant is circulated to the electrical module 22, the second heat exchanger 23, and the radiator 24 by driving the second pump 21 to exchange heat. Here, the second heat exchanger 23 may be configured to adjust the temperature of the cooling water circulating in the second cooling water line 20 through heat exchange with a medium such as a refrigerant or outside air or other cooling water.

Through this, the battery 12 is cooled through heat exchange with the coolant in the first coolant line 10, and the electric module 22 is cooled through heat exchange with the coolant in the second coolant line 20, A heat pump may be realized through heat exchange of cooling water through the first heat exchanger 13 and the second heat exchanger 23 .

The first coolant line 10 and the second coolant line 20 are connected to the housing 30 in which the valve 40 is embedded, and the circulation path of the coolant is determined according to the rotational position of the valve 40.

That is, the housing 30 is provided with a cooling water sharing space 36 in which the valve 40 is provided, and a plurality of passages in which the first cooling water line 10 and the second cooling water line 20 are provided in the housing 30. It communicates with the cooling water sharing space 36 through and the distribution path of the cooling water is determined according to the rotational position of the valve 40. Here, a distribution part is formed in the valve 40 to be matched with each flow path of the housing 30 and selectively allow the coolant to flow through the first coolant line 10 and the second coolant line 20 .

For this reason, according to the present invention, the distribution path of the cooling water distributed in the first cooling water line 10 and the second cooling water line 20 is determined according to the rotational position of the valve 40, so that the cooling water is individually distributed in each cooling water line. It is distributed or mixed in each cooling water line. Through this, the present invention can secure cooling efficiency through the cooling water by adjusting the temperature of the cooling water for various situations such as indoor air conditioning, battery cooling, electric module cooling, and outdoor temperature.

Describing the present invention in detail, as shown in Figure 5, the outer surface of the valve 40, the first distribution portion 41 and the second circulation portion 42 are formed to be spaced apart from each other, the first distribution portion The portion 41 and the second circulation portion 42 each extend in the circumferential direction so that at least two flow paths of the housing 30 are connected.

In this way, the valve 40 can switch the distribution path of the cooling water for the first cooling water line 10 and the second cooling water line 20 as the first distribution part 41 and the second distribution part 42 are formed. can The first distribution part 41 and the second distribution part 42 are formed so that at least two or more passages of the housing 30 to which the first coolant line 10 and the second coolant line 20 are connected are connected. , the circulation of cooling water can be selectively allowed for each cooling water line. Accordingly, the first distribution part 41 and the second distribution part 42 are axially spaced apart from the outer surface of the valve 40 and extend in the circumferential direction, so that two or more flow passages may be selected.

On the other hand, the flow path of the housing 30 communicates singularly with the first coolant line 10 or the second coolant line 20 and the first distribution part 41 or the second distribution part 42 of the valve 40. Composed of a circulation passage and a shared passage through which the first coolant line 10 or the second coolant line 20 selectively flows through the first distribution part 41 and the second distribution part 42 of the valve 40 It can be.

That is, the flow path of the housing 30 is composed of a circulation flow path and a shared flow path.

Here, in the case of the circulation passage, any one of the first distribution part 41 and the second distribution part 42 of the valve 40 communicates singly to the first cooling water line 10 or the second cooling water line 20. Let the coolant circulate. This circulation passage allows cooling water to flow only in one of the first cooling water line 10 and the second cooling water line 20, and is opened or closed according to the rotational position of the valve 40.

In the case of a shared flow path, the first and second distribution parts 41 and 42 of the valve 40 are in communication with each other so that the cooling water distributed in the first cooling water line 10 and the second cooling water line 20 is circulated. do. Such a shared passage allows the cooling water to be mixed and distributed in the first cooling water line 10 and the second cooling water line 20 or individually distributed in the first cooling water line 10 and the second cooling water line 20 .

In detail, the flow path of the housing 30 is a first shared flow path 31 selectively matched to the first flow path 41 and the second flow path 42 of the first pump 11 and the valve 40, A first circulation passage 32 selectively matched to the first heat exchanger 13 and the first circulation part 41 of the valve 40 is configured so that the cooling water is circulated through the first cooling water line 10 .

That is, the cooling water is circulated through the first pump 11 in the first shared flow passage 31, and the cooling water is circulated through the first distribution part 41 or the second distribution part 42 according to the rotational position of the valve 40. The coolant is allowed to flow through both the first coolant line 10 and the second coolant line 20 . In addition, the first circulation passage 32 distributes the cooling water heat-exchanged in the first heat exchanger 13, and the cooling water flowing through the first circulation part 41 according to the rotational position of the valve 40 is the first cooling water. It provides a pathway for circulation in the line (10).

On the other hand, the flow path of the housing 30 is a second circulation flow path 33 selectively matched to the second circulation part 42 of the radiator 24 and the valve 40, the second pump 21 and the valve 40 The second shared flow path 34 selectively matched to the first distribution part 41 and the second distribution part 42 of the second heat exchanger 23 and the second distribution part 42 of the valve 40 A selectively matched third circulation passage 35 is configured so that the coolant flows through the second coolant line 20 .

That is, in the second circulation passage 33, the cooling water can be heat-exchanged through the radiator 24, and according to the rotational position of the valve 40, the cooling water flows through the second circulation part 42 to the second cooling water line 20. It provides a distribution channel for Cooling water is circulated in the second sharing passage 34 by the second pump 21, and the first cooling water passes through the first distribution part 41 and the second distribution part 42 according to the rotational position of the valve 40. Cooling water is all circulated through the line 10 and the second cooling water line 20 . In the third circulation passage 35, the cooling water heat-exchanged through the second heat exchanger 23 is circulated, and according to the rotational position of the valve 40, the cooling water flows through the second circulation part 42 to the second cooling water line 20. ) to provide a distribution channel.

Through this, the present invention changes the circulation path of the cooling water through the first sharing flow path 31 and the second sharing flow path 34 according to the rotational position of the valve 40, so that the first cooling water line 10 and the second sharing flow path 34 are switched. Cooling water in the cooling water line 20 may be circulated separately for each cooling water line or mixed with the first cooling water line 10 and the second cooling water line 20 .

Through this, the present invention can efficiently adjust the temperature of the cooling water according to the cooling temperature required by the battery 12 and the electric module 22, and through the first heat exchanger 13 and the second heat exchanger 23 A heat pump may be implemented through heat exchange of cooling water.

On the other hand, the first distribution part 41 of the valve 40 has a first sharing passage 31, a first circulation passage 32, a first circulation passage 32, and a second sharing passage 34 according to the rotational position. is selectively extended to communicate. That is, even if the rotational position of the valve 40 is switched, the extended length of the first distribution part 41 is the first sharing flow path 31 and the first circulation path 32, the first circulation path 32 and the second circulation path 32, and the second circulation path 32. Formed to include a shared passage 34, the coolant is circulated only in the first coolant line 10 through the first distribution part 41 or distributed in both the first coolant line 10 and the second coolant line 20. can be made

In addition, the second distribution part 42 of the valve 40 has a first sharing passage 31, a second circulation passage 33, a second circulation passage 33, and a second sharing passage 34 according to the rotational position. , The first sharing passage 31 and the third circulation passage 35, and the second sharing passage 34 and the third circulation passage 35 are extended to selectively communicate with each other. That is, even if the rotational position of the valve 40 is switched, the extended length of the second distribution part 42 is the first sharing flow path 31 and the second circulation flow path 33, the second circulation flow path 33 and the second circulation flow path 33, and the second circulation flow path 33. It is formed to include the sharing passage 34, the first sharing passage 31, the third circulation passage 35, the second sharing passage 34, and the third circulation passage 35, so that the cooling water flows through the second distribution part ( 42), it can be circulated only to the second coolant line 20 or to both the first coolant line 10 and the second coolant line 20.

The first distribution part 41 and the second distribution part 42 of the valve 40 are formed to include respective passages, and when the respective passages cannot be matched only by the shape of the distribution part, the passages are branched to form the housing 30. It may be configured to communicate with the cooling water sharing space 36. For example, in the drawing according to the present invention, the third circulation passage 35 is branched to selectively match the second circulation part 42 of the valve 40.

As described above, in the present invention, the temperature of the cooling water can be efficiently adjusted according to the cooling temperature required by the battery 12 and the electric module 22, and the first heat exchanger 13 and the second heat exchanger 23 A heat pump may be implemented through heat exchange of cooling water through the cooling water.

To this end, in the present invention, the controller 70 controls the motor 60 according to a predetermined mode to determine the rotational position of the valve 40; is configured. Through the control of the controller 70, indoor air conditioning and heat pump implementation may be performed.

That is, the controller 70 determines the temperature of the cooling water according to various situations such as the battery 12, the electrical module 22, air conditioning, and the like, and determines the rotational position of the valve 40 according to the determined temperature of the cooling water. Cooling performance can be ensured through circulation and heat exchange.

For example, when the controller 70 performs the first mode, the first circulation passage 32 of the housing 30 and the first sharing passage 31 communicate with each other through the first distribution part 41 of the valve 40. The first coolant line 10 ) and the second cooling water line 20, respectively, so that the cooling water is individually circulated.

The first mode of the controller 70 is to manage the battery 12 and the electric module 22 under different temperature conditions, and the external temperature is high or the battery 12 needs to be cooled due to high-speed charging. can include

That is, as shown in FIG. 6, in the case of the first mode, the rotational position of the valve 40 is adjusted so that the cooling water flows through the first circulation passage 32 and the first sharing passage 31 of the housing 30. As a result, the cooling water is distributed to the first pump 11, the battery 12, the first heat exchanger 13, and the valve 40. In addition, in the first mode, cooling water flows through the second circulation passage 33 and the second sharing passage 34 of the housing 30, so that the cooling water flows through the second pump 21, the electrical module 22, the second It is distributed to the heat exchanger 23, the radiator 24, and the valve 40.

As a result, the cooling water circulated by driving the first pump 11 in the first cooling water line 10 cools the battery 12, and the cooling water that cools the battery 12 cools the battery 12 in the first heat exchanger 13. As the temperature is controlled through heat exchange, the battery 12 can be continuously cooled through recirculation. Here, in the case of the first heat exchanger 13, as the air conditioner is driven, heat exchange with the refrigerant may be performed and cooled.

In addition, the cooling water circulated by the driving of the second pump 21 in the second cooling water line 20 cools the electrical module 22, and the cooling water that cools the electrical module 22 cools the second heat exchanger 23. And heat is exchanged through the radiator 24 to adjust the temperature, so that the electric module 22 can be continuously cooled through recirculation of cooling water. Here, in the case of the second heat exchanger 23, heat exchange with the refrigerant may be performed, and in the case of the radiator 24, heat exchange may be performed with outside air.

On the other hand, when the controller 70 performs the second mode, the first circulation passage 32 of the housing 30 and the second sharing passage 34 communicate with each other through the first circulation part 41 of the valve 40. By controlling the rotational position of the valve 40 so that the second circulation passage 33 of the housing 30 and the first sharing passage 31 communicate with each other through the second distribution part 42, the first cooling water line 10 and the second coolant line 20 so that the coolant is mixed and distributed.

The second mode of the controller 70 manages the temperature of the coolant by sharing the coolant flowing through the first coolant line 10 and the second coolant line 20, and the external temperature, the battery 12, and the electric module. Depending on the temperature of (22), the corresponding mode may be performed.

That is, as shown in FIG. 7 , in the case of the second mode, the rotational position of the valve 40 is adjusted to share the first circulation passage 32 of the housing 30 and the second through the first distribution part 41. As the coolant flows through the flow path 34, the coolant distributed in the first coolant line 10 flows through the second pump 21 of the second coolant line 20, the electrical module 22, and the second heat exchanger 23. ), distributed to the radiator 24. In addition, the coolant flowing through the second circulation passage 42 of the valve 40 flows through the second circulation passage 33 and the first sharing passage 31, so that the coolant distributed in the second coolant line 20 is It is distributed to the first pump 11, the battery 12, and the first heat exchanger 13 of the first cooling water line 10.

Through this, in the second mode, when the external temperature is low, the cooling water is circulated and heat exchanged with the battery 12 and the electric module 22, and the recovered waste heat is transferred to the first heat exchanger 13 and the second heat exchanger 23. By exchanging heat, the first heat exchanger 13 and the second heat exchanger 23 each exchange heat with a refrigerant or other cooling water to realize a heat pump that performs heating. In addition, as the cooling water is cooled through the radiator 24, the cooling of the battery 12 and the electrical module 22 can be maintained.

In addition, in the second mode, when the external temperature is high, the heat of the refrigerant according to the operation of the air conditioner is recovered through the first heat exchanger 13 and the second heat exchanger 23, and the battery 12 and the electric module 22 Waste heat from cooling may be recovered and cooled in the radiator 24 .

On the other hand, when the controller 70 performs the third mode, the first circulation passage 32 of the housing 30 and the second sharing passage 34 communicate with each other through the first distribution part 41 of the valve 40. The first cooling water line 10 and the second cooling water line are formed by controlling the rotational position of the valve 40 so that the first sharing flow path 31 and the third circulation flow path 35 communicate with each other through the second distribution part 42. Cooling water may be mixed and distributed in (20).

The third mode of the controller 70 is for managing the temperature of the cooling water by sharing the cooling water flowing through the first cooling water line 10 and the second cooling water line 20, and the external temperature, the battery 12 and the electric field. A corresponding mode may be performed according to the temperature of the module 22 .

That is, as shown in FIG. 8, in the case of the second mode, the rotational position of the valve 40 is adjusted to share the first circulation passage 32 of the housing 30 and the second through the first circulation part 41. As the coolant flows through the flow path 34, the coolant distributed in the first coolant line 10 flows through the second pump 21 of the second coolant line 20, the electrical module 22, and the second heat exchanger 23. ) is distributed to In addition, the cooling water is distributed to the first sharing flow path 31 and the third circulation flow path 35 through the second distribution part 42 of the valve 40, so that the second heat exchanger in the second cooling water line 20 ( As the cooling water passing through 23) flows through the first cooling water line 10, it is distributed to the first pump 11, battery 12, and first heat exchanger 13 of the first cooling water line 10. At this time, since the second circulation passage 33 is closed by the valve 40, the cooling water does not flow toward the radiator 24.

Through this, in a situation where the temperature of the battery 12 is low or the external temperature is low, waste heat from cooling the electric module 22 is recovered through the second heat exchanger 23 to perform indoor heating, and the battery The temperature of (12) can also be adjusted to rise.

On the other hand, when the controller 70 performs the fourth mode, the first circulation passage 32 of the housing 30 and the first sharing passage 31 communicate with each other through the first distribution part 41 of the valve 40. The first coolant line 10 and the second coolant line are formed by controlling the rotational position of the valve 40 so that the second shared flow path 34 and the third circulation flow path 35 communicate with each other through the second distribution unit 42. Cooling water may be individually circulated through (20).

The fourth mode of the controller 70 is to manage the battery 12 and the electric module 22 under different temperature conditions, and a situation where the external temperature is low or a heat pump using waste heat of the battery 12 is implemented. this may be included.

That is, as shown in FIG. 9 , in the case of the fourth mode, the rotational position of the valve 40 is adjusted so that the cooling water flows through the first circulation passage 32 and the first sharing passage 31 of the housing 30. As a result, the cooling water is distributed to the first pump 11, the battery 12, the first heat exchanger 13, and the valve 40. In addition, in the fourth mode, the second sharing flow path 34 of the housing 30 and the third circulation flow path 35 communicate with each other, so that the cooling water flows through the second pump 21, the electrical module 22, and the second heat exchanger ( 23), and is distributed to the valve 40. At this time, since the second circulation passage 33 is closed by the valve 40, the cooling water does not flow toward the radiator 24.

Through this, when the external temperature is low in the fourth mode, the temperature of the battery 12 can be increased by using the cooling water whose temperature has risen as the electric module 22 is cooled, and the electric module 22 and the battery 12 can be heated. Waste heat generated during cooling may be recovered through the first heat exchanger 13 and the second heat exchanger 23 to implement indoor heating and a heat pump.

Each mode preset in the above-described controller 70 is not limited to each mode described above, and controls indoor air conditioning, heat pump implementation, external temperature conditions, battery 12 cooling temperature, electric module 22 temperature, etc. Considering this, it is possible to implement various modes.

The cooling water distribution control device configured as described above allows the cooling water to be selectively circulated through a plurality of cooling water flow paths through a single valve, and individually or mixedly distributes the cooling water according to the situation, thereby managing the temperature of the cooling water for efficient cooling performance. this is secured

Although the present invention has been shown and described in relation to specific embodiments, it is known in the art that the present invention can be variously improved and changed without departing from the technical spirit of the present invention provided by the claims below. It will be self-evident to those skilled in the art.

10: first cooling water line 11: first pump
12: battery 13: first heat exchanger
20: second coolant line 21: second pump
22: electrical module 23: second heat exchanger
24: radiator 30: housing
31: first sharing flow path 32: first circulation flow path
33: second circulation passage 34: second sharing passage
35: third circulation passage 36: cooling water sharing space
40: valve 41: first distribution unit
42: second distribution unit 50: reservoir tank
60: motor 70: controller

Claims (13)

a first cooling water line through which cooling water is circulated to the first pump, the battery, and the first heat exchanger;
a second coolant line through which the coolant flows through the second pump, the electrical module, the second heat exchanger, and the radiator;
a housing provided with a cooling water sharing space and formed with a plurality of passages allowing the first cooling water line and the second cooling water line to communicate with the cooling water sharing space; and
It is provided to be rotated in the cooling water sharing space of the housing, and a plurality of distribution parts are formed that are selectively matched to the first cooling water line and the second cooling water line according to the rotational position, so that the cooling water is individually distributed in the first cooling water line and the second cooling water line. A cooling water distribution control device comprising a valve that is mixed or distributed in the first cooling water line and the second cooling water line. The method of claim 1,
Cooling water characterized in that the first and second distribution parts are formed to be spaced apart from each other on the outer surface of the valve, and each of the first and second distribution parts extends in a circumferential direction so that at least two flow paths of the housing are connected. distribution control unit. The method of claim 2,
The passage of the housing is a circulation passage that communicates singly with the first or second coolant line and the first or second circulation part of the valve, and the first or second coolant line is the first distribution part of the valve. Cooling water distribution control device, characterized in that composed of a shared flow path for selectively circulating in the second distribution unit. The method of claim 3,
The flow path of the housing consists of a first sharing flow path selectively matched to the first distribution part and the second distribution part of the first pump and the valve, and a second circulation passage selectively matched to the first distribution part of the first heat exchanger and the valve. A cooling water distribution control device characterized in that the cooling water is distributed through the first cooling water line. The method of claim 4,
The flow path of the housing includes a second circulation flow path selectively matched to the second circulation part of the radiator and the valve, a second sharing flow path selectively matched to the first circulation part and the second flow part of the second pump and the valve, and a second heat exchange flow path. A cooling water distribution control device, characterized in that a third circulation passage selectively matched with the second circulation part of the tile and the valve is configured so that the cooling water is circulated through the second cooling water line. The method of claim 5,
Cooling water distribution control device, characterized in that the first flow passage of the valve extends so that the first sharing flow path and the first circulation flow path, and the first circulation flow path and the second sharing flow path selectively communicate with each other according to the rotational position. The method of claim 5,
Depending on the rotational position of the second distribution part of the valve, the first sharing flow path and the second circulation flow path, the second circulation flow path and the second sharing flow path, the first sharing flow path and the third circulation flow path, and the second sharing flow path and the third circulation flow path are A cooling water flow control device characterized in that it is extended to selectively communicate. The method of claim 1,
The first coolant line and the second coolant line share a reservoir tank, and the coolant distribution control device characterized in that the coolant is supplied through the reservoir tank. The method of any one of claims 1 to 5,
A motor installed in the housing and connected to the valve to adjust the rotational position of the valve; and
The cooling water distribution control device further comprising a controller configured to determine the rotational position of the valve by controlling the motor according to a preset mode. The method of claim 9,
When the first mode is performed, the controller controls the valve so that the first circulation flow path of the housing communicates with the first shared flow path through the first circulation part of the valve and the second circulation flow path of the housing communicates with the second shared flow path through the second circulation part. A cooling water distribution control device characterized in that cooling water is individually distributed to the first cooling water line and the second cooling water line by controlling the rotational position. The method of claim 9,
When the second mode is performed, the controller controls the valve so that the first circulation flow path of the housing communicates with the second sharing flow path through the first circulation part of the valve and the second circulation flow path of the housing communicates with the first sharing flow path through the second circulation part. A cooling water distribution control device characterized in that the cooling water is mixed and distributed in the first cooling water line and the second cooling water line by controlling the rotational position. The method of claim 9,
When the third mode is performed, the controller rotates the valve so that the first circulation passage of the housing and the second sharing passage communicate with each other through the first distribution part of the valve, and the first sharing passage and the third circulation passage communicate with each other through the second distribution part. Cooling water distribution control device characterized in that the cooling water is mixed and distributed in the first cooling water line and the second cooling water line by controlling the. The method of claim 9,
When the fourth mode is performed, the controller rotates the valve so that the first circulation passage of the housing communicates with the first sharing passage through the first distribution part of the valve, and the second sharing passage and the third circulation passage communicate through the second distribution part. Cooling water circulation control device characterized in that the cooling water is individually distributed to the first cooling water line and the second cooling water line by controlling the.

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