KR20220050595A - Reservoir tank - Google Patents

Abstract

Disclosed is a reservoir tank, comprising: a tank body in which a cooling water is stored; a partition wall formed inside the tank body, partitioning the tank body into a first chamber and a second chamber, and having an open hole through which the cooling water is exchanged between the first chamber and the second chamber; a conduit integrally formed with the tank body outside a lower part of the first chamber or the second chamber and providing an independent flow path through which the cooling water flows; and a connection unit formed to protrude from one side of the conduit, and supplementing the cooling water in the first or second chamber to the conduit by connecting the first chamber or the second chamber and the conduit. An objective of the present invention is to provide the reservoir tank in which heat exchange between the two chambers is minimized.

Description

Reservoir Tank {RESERVOIR TANK}

The present invention includes a tank body having two chambers in which cooling water is stored and a pipe line integrally formed with the tank body on the outside of the tank body, the cooling water flows along the pipe line, and the cooling water of the tank body is replenished to the pipe line. It relates to a reservoir tank in which heat exchange between chambers is minimized.

The reservoir tank is a tank in which the vehicle's coolant is stored, and is provided in the vehicle to cool the vehicle's engine, electric field, battery, etc. through the coolant. However, when each reservoir tank is provided to cool the engine, battery, electric field, etc., not only the space of the vehicle is limited, but also the vehicle configuration becomes complicated, and various problems such as the need to replenish coolant in each tank occur. To compensate for this problem, one integrated reservoir tank has been devised. The integrated reservoir tank divides the inside of one tank and supplies cooling water to the necessary parts, respectively, and the cooling water only needs to be replenished to one integrated reservoir tank.

However, in the existing integrated reservoir tank, each zone is divided only by the partition wall, and heat exchange is made between each zone through the partition wall, so that the temperature of the coolant inside the tank changes, and the cooling efficiency is reduced accordingly.

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

KR 10-0804551 B1

The present invention has been proposed to solve this problem, and includes a tank body having two chambers in which cooling water is stored, and a pipe line formed integrally with the tank body on the outside of the tank body, and cooling water along a pipe line independent of the tank body This is to provide a reservoir tank in which heat exchange between the two chambers is minimized by flowing, the coolant in the pipeline does not enter the tank body, and the coolant in the tank body is replenished to the pipeline through a connection formed in the pipeline.

A reservoir tank according to the present invention for achieving the above object includes a tank body in which coolant is stored; a partition wall formed inside the tank body, dividing the tank body into a first chamber and a second chamber, and having an open hole through which coolant is exchanged between the first chamber and the second chamber; and a conduit formed integrally with the tank body at the lower outer side of the first chamber or the second chamber and providing an independent flow path through which the coolant flows; It is formed to protrude from one side of the conduit, and connects the first or second chamber and the conduit to supplement the cooling water of the first or second chamber to the conduit; includes.

A through hole may be formed in the connection portion toward the inner space of the first chamber or the second chamber, and the coolant may be replenished through the conduit through the through hole.

By protruding in a branching shape from one side of the pipe, the connection part may be formed at a point deviating from the flow of the flow path formed by the pipe.

A slit hole is provided in the pipeline toward the inner space of the first or second chamber, the slit hole communicates with the first chamber or the second chamber, and the gas flowing in the pipeline passes through the slit hole to the first or second chamber may be discharged into the chamber.

One or more bent portions are provided in the pipeline, and the pipeline may include an in port through which the coolant flows in and an out port through which the coolant flows out around the bent portion.

The connection part is formed to protrude from the bent part to the opposite side of the outlet discharge part, and the cooling water may be replenished through a through hole formed at the upper end of the connection part.

One or more slit holes formed along the width direction of the conduit are provided at one point on the upper portion of the inlet, and the slit holes are connected to the first or second chamber, and the gas flowing in the conduit passes through the slit hole into the first chamber or may be discharged into the second chamber.

A subport integrally formed with the conduit is provided on one side of the conduit, and a valve is connected to the subport, and the valve is selectively opened and closed to control the flow rate of the coolant in the conduit.

The conduit includes a first conduit formed under the first chamber and a second conduit formed under the second chamber, and the connecting portion connects the first connecting portion connecting the first chamber and the first conduit and the second chamber and the second conduit. It may be composed of a second connection part.

At the lower outer side of the tank body, a coupling groove to which the pump is coupled is integrally formed with the tank body, one end of the pipe line is connected to the coupling recess, and when the pump is coupled to the coupling recess to operate, coolant may flow along the pipe line.

When the pump is coupled to the coupling groove, the impeller or the pump housing of the pump is positioned in the coupling groove, and a coolant flow nozzle may be formed on a sidewall of the coupling groove.

A tank cap is provided at the upper end of the tank body, and through the tank cap, coolant can be replenished to the tank body or the gas inside the tank body can be discharged.

According to the reservoir tank of the present invention, it includes a tank body having two chambers in which coolant is stored, and a pipeline formed integrally with the tank body on the outside of the tank body, and the coolant flows along a pipeline independent of the tank body, Heat exchange between the two chambers is minimized as the cooling water of the tank body does not enter the inside of the tank body, and the coolant of the tank body is replenished to the pipe line through the connection part formed in the pipe line.

1 is a side view of a reservoir tank according to an embodiment of the present invention.
2 is a view showing an internal space of a reservoir tank according to an embodiment of the present invention.
3 is a plan view of an internal space of a reservoir tank according to an embodiment of the present invention.
4 is a side view of an internal space of a reservoir tank according to an embodiment of the present invention.
5 is a view showing an outer lower portion of the reservoir tank according to an embodiment of the present invention.

1 is a side view of a reservoir tank according to an embodiment of the present invention. 2 is a view showing an internal space of a reservoir tank according to an embodiment of the present invention. 3 is a plan view of an internal space of a reservoir tank according to an embodiment of the present invention. 4 is a side view of an internal space of a reservoir tank according to an embodiment of the present invention. 5 is a view showing an outer lower portion of the reservoir tank according to an embodiment of the present invention.

1 is a side view of a reservoir tank according to an embodiment of the present invention. 2 is a view showing an internal space of a reservoir tank according to an embodiment of the present invention. 3 is a plan view of an internal space of a reservoir tank according to an embodiment of the present invention. 4 is a side view of an internal space of a reservoir tank according to an embodiment of the present invention. The reservoir tank according to an embodiment of the present invention includes a tank body 100 in which coolant is stored; It is formed inside the tank body 100 , and divides the tank body 100 into a first chamber 110 and a second chamber 120 , and a coolant between the first chamber 110 and the second chamber 120 . a partition wall 200 having an exchange open hole formed therein; and a conduit 300 formed integrally with the tank body 100 at the lower outer side of the first chamber 110 or the second chamber 120 and providing an independent flow path through which the coolant flows; It is formed to protrude from one side of the conduit 300 , and by connecting between the first chamber 110 or the second chamber 120 and the conduit 300 , the cooling water of the first chamber 110 or the second chamber 120 is discharged. It includes; a connection part 400 supplementing the pipeline 300 .

In the existing integrated reservoir tank, two tanks are simply partitioned through a thin plastic bulkhead, which has a fatal disadvantage in that cooling efficiency is lowered because the coolant stored in each tank is heat exchanged through the bulkhead. Therefore, in the reservoir tank according to an embodiment of the present invention, the circulating coolant is not directly introduced into the tank, but in a bypass method, that is, the conduit 300 is formed on the outside of the tank and the conduit is passed through the connection unit 400 . At 300 , insufficient cooling water is supplied from the tank body 100 , so that heat exchange between the first chamber 110 and the second chamber 120 inside the tank is minimized at the partition wall 200 . The open hole is formed in the upper part of the partition wall, so that when replenishing the coolant in the first chamber 110 or the second chamber 120, it can be replenished at once, and when the coolant in one side is excessive, the coolant can be sent to the other side to maintain the balance will be.

In addition, in the reservoir tank according to an embodiment of the present invention, a through hole is formed in the connection part 400 toward the inner space of the first chamber 110 or the second chamber 120 , and the pipe 300 has a through hole. Coolant can be replenished via In the reservoir tank according to an embodiment of the present invention, the connecting portion 400 protrudes in a branching shape from one side of the conduit 300 , so that it may be formed at a point deviating from the flow of the conduit 300 . Therefore, the coolant circulating in the pipe line 300 circulates outside the tank without directly entering the first chamber 110 or the second chamber 120 of the tank body 100, and the coolant in the tank body 100 is The pressure is applied downward by gravity, and the conduit 300 receives insufficient cooling water from the tank body 100 through a through-hole at the top of the connection part 400 provided on one side of the conduit 300 .

On the other hand, the connection part 400 is provided to protrude on one side of the conduit 300 , and a through hole is provided at the upper end of the protruding portion to supply cooling water to the conduit 300 . Due to this protruding structure, in the conduit 300 Without interfering with the flow of the circulating coolant, the coolant circulating in the conduit 300 inversely passes through the through hole of the connection part 400 to the first chamber 110 or the second chamber 120 of the tank body 100 . entry can be prevented.

In addition, in the reservoir tank according to an embodiment of the present invention, a slit hole 500 is provided in the conduit 300 toward the inner space of the first chamber 110 or the second chamber 120 , and the slit hole 500 . is in communication with the first chamber 110 or the second chamber 120 , and the gas flowing in the pipeline 300 is discharged to the first chamber 110 or the second chamber 120 through the slit hole 500 . can In the conduit 300 through which the cooling water circulates, cavitation may occur due to an instantaneous pressure difference or vibration caused by the operation of the pump during cooling water circulation, and thus bubbles may be generated inside the conduit 300, and these bubbles may be cooled in the electrical components to be cooled. However, if the battery is locally accumulating on the cooling line, the heat cannot be cooled, resulting in malfunction and fire hazard. Therefore, a narrow slit hole 500 is provided at the upper end of the conduit 300 so as not to interfere with the flow of the coolant, so that air bubbles, air, etc. present in the conduit 300 are removed from the first chamber 110 of the tank body 100 or As it rises into the second chamber 120 , air bubbles, air, and the like inside the conduit 300 are removed.

On the other hand, in the reservoir tank according to an embodiment of the present invention, one or more bent parts are provided in the pipe line 300, and the pipe line 300 is composed of an in port through which cooling water is introduced and an out port through which cooling water flows out centering on the bent part. can In addition, in the reservoir tank according to an embodiment of the present invention, the connection part 400 is formed to protrude from the bent part to the opposite side of the outlet discharge part, and the conduit 300 is connected to the cooling water through a through hole formed at the top of the connection part 400 . can be supplemented. The in-port and out-port of the conduit 300 are formed on the outside of the tank body 100 so that the cooling water in the conduit 300 circulates without passing through the inside of the tank body 100, so that heat exchange between each conduit or tank is minimized. . In addition, the connection part 400 is formed to protrude from the bent part of the pipe line 300 in the opposite direction toward the outport, thereby preventing the flow of the cooling water circulating in the pipe line 300 or the cooling water flowing backward into the through hole of the connection unit 400 . you will be able to prevent

In addition, in the reservoir tank according to an embodiment of the present invention, one or more slit holes 500 formed along the width direction of the conduit 300 are provided at a point above the inlet, and the slit holes 500 are formed in the first chamber. Alternatively, the gas connected to the second chamber and flowing in the conduit 300 may be discharged to the first chamber 110 or the second chamber 120 through the slit hole 500 . The slit hole 500 is formed in a narrow shape in the width direction of the conduit 300, so that air bubbles or air present in the conduit 300 flow from the inlet of the conduit 300 in which the coolant flow is constant to the inside of the tank body 100. As it rises, air bubbles or air are removed from the pipe 300 .

On the other hand, in the reservoir tank according to an embodiment of the present invention, the conduit 300 is a first conduit 310 formed under the first chamber 110 and a second conduit 320 formed under the second chamber 120 . The connection unit 400 includes a first connection unit 410 connecting the first chamber 110 and the first conduit 310 and a second connection unit connecting the second chamber 120 and the second conduit 320 . (420). The cooling water circulating in the first conduit 310 and the second conduit 320 is discharged in opposite directions, respectively, and accordingly, the first connection part 410 and the second connection part 420 are disposed in the opposite direction of each discharge part, that is, the partition wall. is formed to protrude toward the Therefore, the first connection part 410 and the second connection part 420 minimize the heat exchange between the first pipe line 310 and the second pipe line 320, and the first pipe line 310 and the second pipe line 310 through the through hole provided at the top, respectively. Cooling water is replenished in the second conduit 320 .

5 is a view showing an outer lower portion of the reservoir tank according to an embodiment of the present invention. In the reservoir tank according to an embodiment of the present invention, a subport 600 integrally formed with the pipeline 300 is provided on one side of the pipeline 300, and a valve 610 is connected to the subport 600, The valve 610 may be selectively opened and closed to adjust the flow rate of the coolant in the conduit 300 . As the valve 610, a 3-way valve or a 2-way valve may be used, and the sub-port 600 may not be used without the valve 610 depending on the option of the vehicle. It is possible to selectively apply the input flow rate of the conduit 300 through the valve 610 and the sub-port 600 .

In addition, in the reservoir tank according to an embodiment of the present invention, a coupling groove 700 to which the pump is coupled is integrally formed with the tank body 100 at the lower outer side of the tank body 100 , and one end of the conduit 300 is coupled When connected to the groove 700 and the pump is coupled to the coupling groove 700 to operate, the coolant may flow along the conduit 300 . When the pump is coupled to the coupling groove 700 in the reservoir tank according to an embodiment of the present invention, the impeller or pump housing of the pump is located in the coupling groove 700, and a coolant flow nozzle is provided on the side wall of the coupling groove 700. can be formed. Each of the pipelines 300 is connected to the pump through a coolant flow nozzle formed on the side wall of the coupling groove 700 , and when the pump is coupled to the coupling groove 700 , the impeller or pump housing of the pump is located in the defective groove 700 . Accordingly, cooling water flows through the pump, and the coupling groove 700 in which the pump is defective is formed integrally with the tank body 100, thereby increasing the manufacturing efficiency of the reservoir tank.

On the other hand, in the reservoir tank according to an embodiment of the present invention, a tank cap 800 is provided on the upper end of the tank body 100 , and cooling water is replenished to the tank body 100 through the tank cap 800 or the tank body. (100) The gas inside can be discharged. In the tank body 100 in which two tanks are combined, gas or coolant is exchanged between the first chamber 110 and the second chamber 120 through an open hole at the top of the bulkhead 200, and the tank cap 800 ) is provided so that the cooling water to be supplied to the first chamber 110 and the second chamber 120 can be supplied at once, and gas such as air bubbles or air that has fallen through the slit hole 500 in each pipe line 300 is also a tank. Cap 800 may be used to pull it out of the tank.

The reservoir tank according to an embodiment of the present invention is a reservoir tank composed of a first chamber 110, a second chamber 120, and two chambers, and a conduit 310 for each chamber at the lower outside of the tank body 100; 320) is separately formed, and the coolant circulating in the pipeline 300 does not directly enter the tank body 100, but receives only insufficient coolant through the connection part 400, so that the first chamber 110 and the second chamber ( 120) or between each pipe line (310, 320) to minimize the heat exchange, it is possible to increase the cooling efficiency in the entire circuit.

Although shown and described with respect to specific embodiments of the present invention, it is within the art that the present invention can be variously improved and changed without departing from the spirit of the present invention provided by the following claims. It will be obvious to those of ordinary skill in the art.

100: tank body 200: bulkhead
300: pipeline 400: connection part

Claims (12)

a tank body in which coolant is stored;
a partition wall formed inside the tank body, dividing the tank body into a first chamber and a second chamber, and having an open hole through which coolant is exchanged between the first chamber and the second chamber; and
a conduit formed integrally with the tank body at the lower outer side of the first chamber or the second chamber and providing an independent flow path through which the coolant flows;
Reservoir tank comprising a; is formed to protrude from one side of the conduit, and connects the first or second chamber and the conduit to supplement the cooling water of the first or second chamber to the conduit. The method according to claim 1,
A reservoir tank, characterized in that the connection part has a through hole formed toward the inner space of the first chamber or the second chamber, and the coolant is replenished through the through hole. The method according to claim 1,
Reservoir tank, characterized in that the connection part is formed at a point deviating from the flow of the flow path formed by the pipe by protruding in a branching shape from one side of the pipe. The method according to claim 1,
A slit hole is provided in the pipeline toward the inner space of the first or second chamber, the slit hole communicates with the first chamber or the second chamber, and gas flowing in the pipeline passes through the slit hole into the first chamber or the second chamber Reservoir tank, characterized in that discharged into the chamber. The method according to claim 1,
One or more bent portions are provided in the pipeline, and the pipeline includes an in port through which coolant flows in and an out port through which coolant flows out around the bent portion. 6. The method of claim 5,
The connection part is formed to protrude from the bent part to the opposite side of the outlet discharge part, and the conduit is a reservoir tank, characterized in that the coolant is replenished through a through hole formed at the top of the connection part. 6. The method of claim 5,
One or more slit holes formed along the width direction of the conduit are provided at one point on the upper portion of the inlet, the slit holes are connected to the first chamber or the second chamber, and the gas flowing in the conduit passes through the slit hole into the first chamber or A reservoir tank, characterized in that discharged to the second chamber. The method according to claim 1,
A reservoir tank, characterized in that a subport integrally formed with the conduit is provided on one side of the conduit, and a valve is connected to the subport, and the valve is selectively opened and closed to control the flow rate of the coolant in the conduit. The method according to claim 1,
The conduit includes a first conduit formed under the first chamber and a second conduit formed under the second chamber, and the connecting portion connects the first connecting portion connecting the first chamber and the first conduit and the second chamber and the second conduit. Reservoir tank, characterized in that consisting of a second connection part. The method according to claim 1,
On the outer side of the lower part of the tank body, a coupling groove to which the pump is coupled is formed integrally with the tank body, and one end of the pipe is connected to the coupling groove, and when the pump is coupled to the coupling groove and operates, the coolant flows along the pipe. a reservoir tank. 11. The method of claim 10,
When the pump is coupled to the coupling groove, the impeller or the pump housing of the pump is located in the coupling groove, the reservoir tank, characterized in that the coolant flow nozzle is formed on the side wall of the coupling groove. The method according to claim 1,
A tank cap is provided at the upper end of the tank body, and the reservoir tank, characterized in that the coolant is replenished to the tank body or the gas inside the tank body is discharged through the tank cap.

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