KR102335350B1 - Cooling system having integrated reservoir - Google Patents

Abstract

A cooling system having an integrated reservoir is disclosed.
A cooling system having an integrated reservoir according to an embodiment of the present invention includes an engine coolant line through which engine coolant for cooling an engine flows, an electrical coolant line through which electrical coolant for cooling electrical components flows, and engine coolant from one side of the engine coolant line. and an integrated reservoir arranged to receive the supply and supply engine coolant to the other side, to receive the electrical coolant from one side of the electrical coolant line, and to supply the electrical coolant to the other side, wherein the integrated reservoir includes: A reservoir tank containing coolant, a bulkhead dividing the internal space of the reservoir tank into an engine coolant chamber and an automotive coolant chamber, and one-way installed in the partition so that coolant flows in one direction between the engine coolant chamber and the automotive coolant chamber It may include a valve.

Description

Cooling system with integrated reservoir {COOLING SYSTEM HAVING INTEGRATED RESERVOIR}

The present invention relates to a cooling system having an integrated reservoir that reduces a layout space and facilitates maintenance by integrating the reservoir tanks into one in a system using two or more coolant reservoir tanks.

In general, an HEV or PHEV is provided with an engine cooling system and an electric vehicle cooling system, and each cooling system is provided with a separate reservoir.

As mentioned above, by configuring the reservoir in each cooling water circuit, the layout space is insufficient, the production and manufacturing cost increases, and maintenance is difficult because the cooling water must be replenished in each reservoir at different intervals.

Comparing the engine coolant flowing through the engine cooling system and the electrical coolant flowing through the electric vehicle cooling system, the engine coolant has a relatively high temperature and a high flow rate, and the electric vehicle coolant has a relatively low temperature and a slow flow rate.

The electric vehicle coolant mainly cools an electric device, an actuator, or a hybrid start and generator (HSG), and the engine coolant has a structure for cooling/heating an engine and a heater.

On the other hand, it is possible to more secure the layout space of the engine, to separate the engine coolant and the electronic coolant within a certain range to control the coolant temperature differently, and to minimize the heat transfer between the engine coolant and the electronic coolant. and a cooling system having the same is being studied.

Matters described in this background section are prepared to improve understanding of the background of the invention, and may include matters that are not already known to those of ordinary skill in the art to which this technology belongs.

Republic of Korea Publication Number: 10/2017/0032712 Japanese Unexamined Patent Publication 2012-002496

An object of the present invention is to be able to simultaneously fill engine coolant and electric coolant by using one integrated reservoir, to secure more layout space, and to separate engine coolant and electric coolant in a certain range to control their coolant temperatures differently. It is possible to provide a cooling system having an integrated reservoir that minimizes heat transfer between engine coolant and electric vehicle coolant.

A cooling system having an integrated reservoir according to an embodiment of the present invention includes an engine coolant line through which engine coolant for cooling an engine flows, an electrical coolant line through which electrical coolant for cooling electrical components flows, and engine coolant from one side of the engine coolant line. and an integrated reservoir arranged to receive the supply and supply engine coolant to the other side, to receive the electrical coolant from one side of the electrical coolant line, and to supply the electrical coolant to the other side, wherein the integrated reservoir includes: A reservoir tank containing coolant, a bulkhead dividing the internal space of the reservoir tank into an engine coolant chamber and an electric vehicle coolant chamber, and one-way installed in the bulkhead so that coolant flows in one direction between the engine coolant chamber and the electric vehicle coolant chamber It may include a valve.

A pressure cap may be installed on the upper side of the reservoir tank to control the pressure of the internal space to a set value or less.

The partition wall may extend to a set height from the bottom surface of the reservoir tank.

A height of the bulkhead may be lower than a ceiling height of the reservoir tank so that the engine coolant or electric vehicle coolant passes over the bulkhead.

The one-way valve may allow the engine coolant of the engine coolant chamber to flow toward the automotive coolant chamber and prevent the engine coolant chamber from flowing into the automotive coolant chamber.

The partition wall may include a first partition wall disposed on the engine coolant chamber side, and a second partition wall disposed on the electric vehicle coolant chamber side and forming an air gap between the first partition wall.

An upper end of the first barrier rib and an upper end of the second barrier rib may be connected to each other.

The air gap may be opened to a lower portion of the reservoir tank.

The one-way valve may selectively connect the engine coolant chamber and the electric vehicle coolant chamber through the first partition wall and the second partition wall.

An appropriate maximum height and an appropriate minimum height of the electric vehicle cooling water filled in the electric vehicle cooling water chamber may be set, and the installation height of the one-way valve may be lower than the appropriate minimum height.

A supply pipe for supplying coolant to the engine coolant chamber and the electrical coolant chamber and a discharge pipe for draining coolant from the engine coolant chamber and the electrical coolant chamber to the outside are connected to the reservoir tank, and the supply pipe is the reservoir tank is connected to the upper side of the , and the discharge pipe may be connected to the lower side of the reservoir tank.

According to an embodiment of the present invention, the first cooling water is supplied through the upper side of one side, the first cooling water is supplied through the lower side of the one side, the second cooling water is supplied through the upper side of the other side, and the second cooling water is supplied through the lower side of the other side. The integrated reservoir arranged to supply the reservoir includes a reservoir tank containing coolant therein, a partition wall dividing an internal space of the reservoir tank into a first coolant chamber and a second coolant chamber, and installed on the partition wall to form the first coolant chamber and the first coolant chamber and the second coolant chamber It may include a one-way valve configured to flow the coolant in one direction between the second coolant chambers.

A pressure cap may be installed on the upper side of the reservoir tank to control the pressure of the internal space to a set value or less.

The partition wall may extend to a set height from the bottom surface of the reservoir tank.

A height of the partition wall may be lower than a ceiling height of the reservoir tank so that the first coolant or the second coolant flows over the partition wall.

The one-way valve may allow the first coolant of the first coolant chamber to flow toward the second coolant chamber and prevent the first coolant chamber from flowing into the second coolant chamber.

The partition wall may include a first partition wall disposed on the side of the first coolant chamber and a second partition wall disposed on the side of the second coolant chamber and forming an air gap between the first partition wall.

An upper end of the first barrier rib and an upper end of the second barrier rib may be connected to each other, and the air gap may be opened to a lower portion of the reservoir tank.

The one-way valve may selectively connect the first coolant chamber and the second coolant chamber through the first partition wall and the second partition wall.

According to the present invention for achieving this object, it is possible to fill the engine coolant and the electric coolant at the same time using one integrated reservoir, and it is possible to secure more layout space.

In addition, by forming a bulkhead inside the reservoir tank of the integrated reservoir, it is possible to separate the engine coolant and the electric coolant in a certain range to control their coolant temperatures differently. The electric coolant can be easily replenished to the engine coolant side by the one-way valve.

In addition, by dividing the partition into first and second partition walls and forming an air gap between them, heat transfer between the engine coolant and the electric vehicle coolant can be minimized and the heat dissipation efficiency of the overall coolant can be improved.

1 is a schematic configuration diagram of a cooling system related to the present invention.
2 is a block diagram of a cooling system having an integrated reservoir according to an embodiment of the present invention.
3 is a cross-sectional view of an integrated reservoir according to an embodiment of the present invention.
4A is a cross-sectional view showing the state of the integrated reservoir before the engine is started according to an embodiment of the present invention.
4B is a cross-sectional view showing the state of the integrated reservoir after the engine is started according to an embodiment of the present invention.
4C is a cross-sectional view showing the state of the integrated reservoir after the engine is stopped according to an embodiment of the present invention.
4D is a cross-sectional view illustrating the state of the integrated reservoir after the engine is stopped and the engine coolant is cooled according to an embodiment of the present invention.
5 is a cross-sectional view of an integrated reservoir according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

However, since the size and thickness of each component shown in the drawings are arbitrarily indicated for convenience of explanation, the present invention is not necessarily limited to the bar shown in the drawings, and the thickness is enlarged to clearly express various parts and regions. it was

However, in order to clearly explain the embodiment of the present invention, parts irrelevant to the description are omitted, and the same or similar components are given the same reference numerals throughout the specification.

In the following description, the names of the components are divided into the first, the second, and the like to distinguish them because the names of the components are the same, and the order is not necessarily limited thereto.

1 is a schematic configuration diagram of a cooling system related to the present invention.

Referring to FIG. 1 , the cooling system includes an engine cooling system 100 and an electric field cooling system 150 . The engine cooling system 100 includes an engine coolant line 198 , a thermostat 135 , an engine radiator 130 , a first pressure cap 127 , a first reservoir 125 , and a first water pump as main components. 120 , an engine 110 , a water temperature control valve 115 , and a heater 105 .

In addition, the electric coolant system 150 includes an electric coolant line 199, a second reservoir 160, a second pressure cap 157, an electric part 165, a second water pump 175 as main components; a clutch actuator 170 , an HSG 155 , and a full-length radiator 152 .

In the embodiment of the present invention, reference is made to the known technology for the structure and function of each of the components, a detailed description thereof will be omitted, and only the parts related to the present invention will be mainly described.

As shown, the engine cooling system 100 includes a first reservoir 125 in which coolant is contained and filled, and a first pressure cap 127 for maintaining the internal pressure of the first reservoir 125 within a set value. ) is provided.

In addition, the electric coolant system 150 includes a second reservoir 160 in which coolant is contained and filled, and a second pressure cap 157 for maintaining the internal pressure of the second reservoir 160 within a set value is provided. do.

2 is a block diagram of a cooling system having an integrated reservoir according to an embodiment of the present invention.

Referring to FIG. 2 , one integrated reservoir 200 and a pressure cap 210 are disposed in the engine cooling system 100 and the electric vehicle cooling system 150 .

A first line 211 is branched from the coolant line between the water temperature control valve 115 and the engine radiator 130 and is connected to an upper portion of one side of the integrated reservoir 200 , and a lower portion of one side of the integrated reservoir 200 . A second line 212 is branched from and is connected to a coolant line between the engine radiator 130 and the thermostat 135 .

In addition, a third line 213 is connected from the electric radiator 152 to the upper portion of the other side of the integrated reservoir 200 , and a fourth line 214 is branched from the lower portion of the other side of the integrated reservoir 200 , and the electric length It is connected to a coolant line between the component 165 and the second water pump 175 .

3 is a cross-sectional view of an integrated reservoir according to an embodiment of the present invention.

Referring to FIG. 3 , the integrated reservoir 200 includes a reservoir tank 201 , a bulkhead 321 , a one-way valve 330 , and a pressure cap 210 as main components, and the bulkhead 321 is the center As a result, an engine coolant chamber 320 is formed on one inner side of the reservoir tank 201 , and an electric length coolant chamber 310 is formed on the other inner side of the reservoir tank 201 .

The upper portion of the engine coolant chamber 320 is connected to the first line 211 , the lower portion is connected to the second line 212 , and the upper portion of the electric vehicle coolant chamber 310 is connected to the third line 213 . and the lower portion is connected to the fourth line 214 .

The partition wall 321 may extend a set distance upward from the inner bottom surface of the reservoir tank 201 , and coolant may overflow into a space between the upper end of the partition wall 321 and the pressure cap 210 .

In addition, a one-way valve 330 selectively connecting the electric vehicle coolant chamber 310 and the engine coolant chamber 320 is disposed on the partition wall 321 . The one-way valve 330 may have a flap valve structure. For the detailed structure of the one-way valve 330 , reference is made to known techniques, and detailed description thereof will be omitted.

In an embodiment of the present invention, in the one-way valve 330 , the coolant of the electric vehicle coolant chamber 310 may move toward the engine coolant chamber 320 , and the coolant in the engine coolant chamber 320 is supplied to the electric vehicle coolant chamber You cannot move to (310).

Here, for convenience of description, the coolant contained in the electric vehicle coolant chamber 310 may be referred to as an electric vehicle coolant, and the coolant contained in the engine coolant chamber 320 may be referred to as an engine coolant.

4A is a cross-sectional view showing the state of the integrated reservoir before the engine is started according to an embodiment of the present invention.

Referring to FIG. 4A , before starting, the coolant chamber 310 and the engine coolant chamber 320 are each filled with coolant at substantially the same level. Here, before starting, the engine 110 is turned off, and the motor of the electric component 165 is not operated.

4B is a cross-sectional view showing the state of the integrated reservoir after the engine is started according to an embodiment of the present invention.

Referring to FIG. 4B , after starting, the coolant level of the electric vehicle coolant chamber 310 is similar to the state before starting, and the coolant level of the engine coolant chamber 320 is constantly increased due to a rise in the temperature of the entire coolant.

4C is a cross-sectional view showing the state of the integrated reservoir after the engine is stopped according to an embodiment of the present invention.

4C, after starting off, the coolant level in the electric vehicle coolant chamber 310 slightly rises from that before starting, and the coolant level in the engine coolant chamber 320 rises as the temperature of the entire coolant rises, In a state in which the inflow of engine coolant is increased, the engine coolant flows over the bulkhead 321 and flows toward the electric coolant chamber 310 .

4D is a cross-sectional view illustrating the state of the integrated reservoir after the engine is stopped and the engine coolant is cooled according to an embodiment of the present invention.

Referring to FIG. 4D , when a certain time elapses after the engine is turned off, the coolant level in the electric vehicle coolant chamber 310 slightly rises from that before starting by the amount of engine coolant overflowing from the engine coolant chamber 320 , and the engine coolant The level of the engine coolant filled in the chamber 320 is decreased due to the decrease in coolant temperature and the amount of engine coolant flowing into the electric coolant chamber 310 .

In addition, when the level of the electric coolant contained in the electric coolant chamber 310 is higher than the level of the engine coolant contained in the engine coolant chamber 320, the one-way valve 330 is opened due to the difference in water head to open the electric coolant. flows toward the engine coolant chamber 320 .

Accordingly, the level of the electric vehicle coolant contained in the electric vehicle coolant chamber 310 and the engine coolant level contained in the engine coolant chamber 320 are substantially the same.

5 is a cross-sectional view of an integrated reservoir according to another embodiment of the present invention.

Referring to FIG. 5 , the integrated reservoir 200 includes a reservoir tank 201 , a bulkhead 321 , a one-way valve 330 , and a pressure cap 210 as main components.

The partition wall 321 includes a first partition wall 502 and a second partition wall 504, an air gap 510 is formed between the first and second partition walls 502 and 504, and the first and second partition walls Upper ends of the partition walls 502 and 504 are connected to each other, and the air gap 510 is opened to a lower portion of the reservoir tank 201 .

Through the structure of the air gap 510 , heat transfer between the engine coolant and the electric coolant in the reservoir tank 201 can be minimized and the heat dissipation efficiency of the coolant can be improved.

In addition, when the pressure cap 210 is removed and the coolant is filled, the engine coolant and the electric coolant can be simultaneously filled through a single operation, so that maintenance is easy and the production process is reduced.

In an embodiment of the present invention, the bulkhead 321 is set to be skewed to the left from the center of the reservoir tank 201 so that the volume of the electric coolant chamber 310 is set smaller than the volume of the engine coolant chamber 320 can

Although the preferred embodiment of the present invention has been described above, the present invention is not limited to the above embodiment, and it is easily changed by a person skilled in the art from the embodiment of the present invention to equivalent Including all changes to the extent recognized as being

100: engine cooling system 105: heater
110: engine 115: water temperature control valve
120: first water pump 125: first reservoir
127: first pressure cap 130: engine radiator
135: thermostat 150: battlefield cooling system
152: battlefield radiator 155: HSG
157: second pressure cap 160: second reservoir
165: electrical component 170: clutch actuator
175: second water pump 198: engine coolant line
199: electric coolant line 200: integrated reservoir
201: reservoir tank 210: pressure cap
211: first line 212: second line
213: third line 214: fourth line
310: automotive coolant chamber 320: engine coolant chamber
502: first partition 504: second partition
321: bulkhead 330: one-way valve
510: air gap

Claims (19)

an engine coolant line through which engine coolant for cooling the engine flows;
an electrical coolant line through which electrical coolant for cooling electrical components flows; and
an integrated reservoir that receives engine coolant from one side of the engine coolant line and supplies engine coolant to the other side, receives electrical coolant from one side of the electrical coolant line, and supplies electrical coolant to the other side; including,
The integrated reservoir,
Reservoir tank with coolant inside;
a partition wall dividing the internal space of the reservoir tank into an engine coolant chamber and an electric vehicle coolant chamber; and
a one-way valve installed on the bulkhead to allow coolant to flow in one direction between the engine coolant chamber and the electric vehicle coolant chamber; and
and the one-way valve allows the engine coolant of the engine coolant chamber to flow toward the automotive coolant chamber and prevents it from flowing into the engine coolant chamber of the automotive coolant chamber. According to claim 1,
A cooling system with an integrated reservoir, characterized in that a pressure cap is installed on the upper side of the reservoir tank to control the pressure in the internal space to a set value or less. 3. The method of claim 2,
The bulkhead is a cooling system with an integrated reservoir, characterized in that extending from the bottom surface of the reservoir tank to a set height. 4. The method of claim 3,
A cooling system with an integrated reservoir, characterized in that the height of the bulkhead is lower than the height of the ceiling of the reservoir tank so that the engine coolant or electric vehicle coolant passes over the bulkhead. delete According to claim 1,
The partition wall is
a first partition wall disposed on the engine coolant chamber side; and
a second barrier rib disposed on a side of the electric coolant chamber and forming an air gap between the first barrier ribs;
A cooling system having an integrated reservoir comprising a. 7. The method of claim 6,
The cooling system with an integrated reservoir, characterized in that the upper end of the first bulkhead and the upper end of the second bulkhead are connected to each other. 7. The method of claim 6,
The air gap is a cooling system with an integrated reservoir, characterized in that open to the lower portion of the reservoir tank. 7. The method of claim 6,
The one-way valve is
The cooling system with an integrated reservoir, characterized in that selectively connecting the engine coolant chamber and the electric vehicle coolant chamber through the first partition wall and the second partition wall. According to claim 1,
A cooling system with an integrated reservoir, characterized in that an appropriate maximum height and an appropriate minimum height of the electrical coolant filled in the electrical coolant chamber are set, and the installation height of the one-way valve is lower than the appropriate minimum height. According to claim 1,
A supply pipe for supplying coolant to the engine coolant chamber and the electrical coolant chamber and a discharge pipe for draining coolant from the engine coolant chamber and the electrical coolant chamber to the outside are connected to the reservoir tank;
The supply pipe is connected to the upper side of the reservoir tank, and the discharge pipe is connected to the lower side of the reservoir tank. In the integrated reservoir that is arranged to receive the first cooling water through the upper part of one side, supply the first cooling water through the lower part of the one side, receive the second cooling water through the upper part of the other side, and supply the second cooling water through the lower part of the one side in
Reservoir tank with coolant inside;
a partition wall dividing the internal space of the reservoir tank into a first coolant chamber and a second coolant chamber; and
a one-way valve installed on the partition wall and configured to allow coolant to flow in one direction between the first coolant chamber and the second coolant chamber; and
and the one-way valve allows the first coolant of the first coolant chamber to flow toward the second coolant chamber and prevents the first coolant chamber from flowing into the second coolant chamber. 13. The method of claim 12,
An integrated reservoir, characterized in that a pressure cap is installed on the upper side of the reservoir tank to control the pressure in the internal space to a set value or less. 14. The method of claim 13,
The partition wall is an integrated reservoir, characterized in that extending from the bottom surface of the reservoir tank to a set height. 15. The method of claim 14,
The integrated reservoir, characterized in that the height of the partition wall is lower than the ceiling height of the reservoir tank so that the first coolant or the second coolant flows over the partition wall. delete 13. The method of claim 12,
The partition wall is
a first partition wall disposed on the first coolant chamber side; and
a second partition wall disposed on the second coolant chamber side and forming an air gap between the first partition wall;
An integrated reservoir comprising a. 18. The method of claim 17,
An upper end of the first barrier rib and an upper end of the second barrier rib are connected to each other, and the air gap is opened to a lower portion of the reservoir tank. 18. The method of claim 17,
The one-way valve is
The integrated reservoir of claim 1, wherein the first coolant chamber and the second coolant chamber are selectively connected through the first partition wall and the second partition wall.

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