KR20150098864A - A cap of heat exchanger - Google Patents

Abstract

The present invention relates to a cap for a heat exchanger and, more specifically, relates to a cap for a heat exchanger which prevents damage to a component by pressure difference. A vacuum plate is eccentrically connected to a lower side of a pin valve to easily be opened and closed for cooling water to smoothly be discharged and supplemented.

Description

A CAP OF HEAT EXCHANGER

The present invention relates to a cap for a heat exchanger, and more particularly, a vacuum plate is eccentrically connected to a lower side of a pin valve so that a vacuum plate can be easily opened and closed to facilitate discharge and replenishment of cooling water, To a cap for a heat exchanger.

In recent years, interest in the environment and energy has been increasing worldwide in the automobile industry, and studies for improving fuel efficiency have been made. Research and development for lightening, miniaturization and high performance are continuously carried out in order to satisfy the needs of various consumers.

On the other hand, a heat exchanger is a component of an air conditioner, and is a device that absorbs one heat between two environments with a temperature difference and emits heat to the other.

Among the heat exchangers, the radiator has a structure for preventing the temperature of the engine from rising to a predetermined temperature or higher. The high temperature cooling water, which circulates in the engine and absorbs the heat generated by the combustion, is circulated by the water pump, This is a heat exchanger that dissipates heat to the outside to prevent overheating of the engine and maintain the optimum operating condition.

However, when gas is contained in the cooling water, the cooling water is repeatedly heated and cooled so that the gas dissolved therein occupies a certain volume on the cooling water circulation path, thereby deteriorating the heat exchange performance by the cooling water, Can not be properly cooled.

In addition, research and development for a hybrid vehicle using two power sources at the same time is increasing in accordance with research and development trends for high-performance. Especially, hybrid vehicles using both power and electric energy are increasing.

In this case, when a large-capacity battery is used as an electric energy source of the hybrid vehicle, the battery using nickel-metal hydride (Ni-MH) as the large capacity battery generates hydrogen gas in the chemical action of the charge- There is a high possibility that the hydrogen gas generated by the chemical action of the battery is mixed into the cooling water in the case of a vehicle using the water cooling type cooling method using the cooling water as described above.

When the hydrogen is mixed with the cooling water, the heat exchange performance by the cooling water as described above is lowered by the hydrogen gas, and when the pressure inside the heat exchanger is high, the pressure of the hydrogen gas High-temperature and high-pressure cooling water is blown out by the user, and the user may be injured such as an image.

In order to solve the above-described problems, a cap unit for a heat exchanger as shown in FIGS. 1 to 3 has been proposed.

As shown in FIG. 1, a cooling water injection unit 1 having a body 2 through which an opening 3 is opened is formed at one side of a heat exchanger, and the cooling water injection unit 1 And the reservoir tank 5 are connected to each other.

The conventional cap unit c for the heat exchanger is constructed such that the plate spring 20 is mounted and the first gasket 21 is fixed by the first gasket fixing unit 22 to seal the opening 3 of the body 2 A cap 10 is formed.

At this time, a link 31 having a through hole 32 is formed in a lower portion of the plug 10, and a first spring 33 is wound around the link 31 by a first spring fixing portion 34 And a lower plate 35 fixed to the lower side of the link 31 and formed with a communication hole 36 at the center thereof and provided with a second gasket for lowering the sealing force with respect to the body 2, 37) is fixed by the second gasket fixing portion (38).

The pressure valve 30 is provided with a pin valve 41 supported by a second spring 42 inside the lower plate 35 and protruding through a communication hole 36 at a lower fixed region, And a vacuum plate 41a connected to the second gasket 37 to seal the communication hole 36 in close contact with the second gasket 37.

When the pressure inside the heat exchanger is in a proper state, the pressure valve 30 closes the cooling water injection part 1 and the negative pressure valve 40 is also closed. However, when the temperature of the cooling water is increased by heat exchange, The pressure in the heat exchanger is increased by the pressure of the refrigerant, so that the pressure valve 30 is opened as shown in FIG. 2, and some cooling water is transferred to the reservoir tank 5 through the body 2.

Conversely, when negative pressure is generated in the heat exchanger, as shown in FIG. 3, the negative pressure valve 40 is opened and the cooling water, which has been moved from the reservoir tank 5 through the communicating portion 4, 32 to the heat exchanger.

However, in the conventional cap unit for a heat exchanger, there is a possibility that the vacuum plate 41a and the second gasket 37 are fixed to each other due to other foreign substances contained in the cooling water, and the vacuum plate 41a is not opened, There is a problem in that it is difficult to be performed smoothly.

If the discharge and replenishment of the cooling water is not smooth, there is a high possibility that the components such as the communication passage 4 are deformed due to the difference between the pressure inside the heat exchanger and the external pressure, thereby lowering the safety and increasing the repair cost There is a problem that can not be solved.

Korean Patent No. 10-1330989 (entitled "Radiator Cap")

SUMMARY OF THE INVENTION The present invention has been conceived in order to solve the problems as described above, and it is an object of the present invention to provide a vacuum cleaner which is eccentrically connected to a lower side of a pin valve to easily open and close a vacuum plate, And a cap for a heat exchanger that can prevent breakage of the component by the cap.

It is another object of the present invention to provide a vacuum valve which can easily open and close a vacuum plate by easily compressing a second spring region on a side where the vacuum plate is eccentrically formed, And an upper surface of the second portion is projected upward so as to prevent the second spring from coming off.

The cap 1000 for a heat exchanger according to the present invention includes a body 111 formed with protrusions formed in the header tanks 100 and 200 of the heat exchanger 1000 and having an opening 112 for injecting cooling water, For opening and closing a cooling water injection part 110 including a communication part 113 connecting the outer circumferential surface and the reservoir tank 700 and for controlling the flow of cooling water between the heat exchanger 1000 and the reservoir tank 700 In the cap 600, the cap 600 for the heat exchanger is formed to enclose the opening 112 of the body 111, closes the opened region and is fastened to the outer surface of the body 111, (610); A leaf spring 620 provided to abut the sealing member under the cap 610; A first spring 633 disposed on an outer circumferential surface of the link 631 and a second spring 633 disposed on an outer circumferential surface of the link 631. The first spring 633, A lower plate 635 having a communicating hole 636 formed in a central region thereof and a gasket 637 abutting the lower side of the body 111 of the cooling water injecting unit 110, Pressure valve 630; A pin valve 641 passing through the communication hole 636 of the lower plate 635, a second spring 642 supported by the pin valve 641 and the lower plate 635, And a negative pressure valve 640 including a vacuum plate 643 eccentrically connected to the lower side of the communication hole 631 to open and close the communication hole 636.

The vacuum plate 643 has a first area A1 in which the communication hole 636 can be closed around the pin valve 641 and a second area A1 extending from a certain area around the first area A1, And a region A2.

The pin valve 641 has a stepped portion 641-1 protruding from the upper outer circumferential surface of the pin valve 641 corresponding to a region where the second region A2 is not formed and supporting the second spring 642 Is formed.

In addition, the pin valve 641 is further formed with a separation preventing portion 641-2 in which the upper surface of the portion where the step portion 641-1 is not formed protrudes upward.

Accordingly, the cap for the heat exchanger of the present invention is eccentrically connected to the lower side of the vacuum plate pin valve so that the vacuum plate can be easily opened and closed, thereby facilitating the discharge and replenishment of the cooling water and preventing the component from being damaged by the pressure difference have.

In addition, the cap for the heat exchanger of the present invention can easily open and close the vacuum plate by easily compressing the second spring region on the eccentric side of the vacuum plate by forming the step portion only in a certain region, The upper surface of the unformed portion is protruded upward, and the second spring can be prevented from coming off.

1 is a cross-sectional view of a conventional heat exchanger cap;
2 and 3 are views for explaining the operation of the cap for the heat exchanger shown in Fig.
4 is a perspective view of a heat exchanger equipped with a cap for a heat exchanger according to the present invention;
5 is a mounting cross-sectional view of a cap for a heat exchanger according to the present invention.
6 is a bottom perspective view of a cap for a heat exchanger according to the present invention.
7 is a plan view of vacuum plates of a cap for a heat exchanger according to the present invention.
8 and 9 are cross-sectional views illustrating the operation of a cap for a heat exchanger in accordance with the present invention.
(Fig. 8 shows the case where the cooling water in the heat exchanger moves to the reservoir tank, and Fig. 9 shows that the cooling water in the reservoir tank moves into the heat exchanger)
10 is another mounting cross-sectional view of a cap for a heat exchanger according to the present invention.

Hereinafter, a cap 600 for a heat exchanger of the present invention having the above-described features will be described in detail with reference to the accompanying drawings.

4 is a perspective view showing a heat exchanger 1000 equipped with a cap 600 for a heat exchanger according to the present invention. The cap 600 for a heat exchanger according to the present invention is installed in the cooling water of the heat exchanger 1000 The injection unit 110 is opened and closed.

The heat exchanger 1000 includes a first header tank 100, a second header tank 200, an inlet pipe 310, an outlet pipe 310, A coolant injection unit 110, a tube 400, a fin 500, and a cap 600 for a heat exchanger according to the present invention.

The first header tank 100 and the second header tank 200 are formed by joining the header 101 and the tank 102 and are spaced apart from each other by a predetermined distance.

The first header tank 100 and the second header tank 200 are portions where the inlet pipe 310, the outlet pipe 320, and the cooling water injecting unit 110 are formed.

The heat exchanger 1000 shown in FIG. 4 includes a cooling water injection unit 110 and an outlet pipe 320 (more specifically, the cooling water injection unit 110 is connected to the first header tank 100) The outlet pipe 320 is formed on the upper side of the first header tank 100 and the inlet pipe 310 is formed on the upper side of the second header tank 200, .

The inlet pipe 310 is formed in the first header tank 100 or the second header tank 200 to receive cooling water and the outlet pipe 320 is connected to the first header tank 100 or the second header tank 200, 2 header tank 200 to discharge the cooling water.

The cooling water injection unit 110 is formed in the first header tank 100 and includes a body 111, a sealing member 114, and a communication unit 113.

The body 111 is protruded from the first header tank 100 and has an opening 112 opened upward to inject cooling water.

The communicating part 113 connects the outer circumferential surface of the body 111 and the reservoir tank 700.

The tube 400 is a part where both ends are fixed to the first header tank 100 and the second header tank 200 to form a cooling water flow path and the fin 500 is interposed between the tubes 400 .

The cap 600 for a heat exchanger of the present invention is formed in the cooling water injection unit 110 to close the opening 112 and to cool the cooling water to the reservoir tank 700 so as to control the pressure inside the heat exchanger 1000 And regulates the replenishment of the cooling water into the heat exchanger 1000.

6 is a bottom perspective view of a cap 600 for a heat exchanger according to the present invention, and FIG. 7 is a cross-sectional view of a cap 600 for a heat exchanger according to the present invention. And vacuum plates 643, respectively.

More specifically, the heat exchanger cap 600 is formed to include a cap 610, a pressure valve 630, and a negative pressure valve 640.

The stopper 610 is formed to enclose the opening 112 of the body 111 and closes the open region of the opening 112 and is fixed to the outer surface of the body 111.

That is, the cap 610 is fastened to the upper portion of the body 111 to close the opening 112, or the fastening is released to open the opening 112.

A leaf spring 620 may be provided under the cap 610.

The leaf spring 620 is brought into close contact with the opening 112 of the cooling water injecting unit 110 to further increase the closing force.

The pressure valve 630 is provided below the plug 610 and closes the lower portion of the body 111 of the cooling water injecting unit 110. The pressure valve 630 includes a link 631, a first spring 633, One spring fixing portion 634, a lower plate 635 and a gasket 637. [

The link 631 is provided below the leaf spring 620 and has a through hole 632 through which the cooling water is moved so that the cooling water flowing into the body 111 through the connection part 113 flows into the inside of the link 631 .

The first spring 633 is disposed on the outer surface of the link 631 and is maintained in a state or pressed by the pressure change in the heat exchanger 1000. When the inside of the heat exchanger 1000 is in a high temperature state So that the cooling water in the heat exchanger 1000 is moved to the reservoir tank 700 through the communicating part 113. When the pressure is in a normal state or in a normal state, In the negative pressure state, the pressure valve 630 is lowered by the restoring force to seal the lower side of the body 111. [

At this time, the first spring 633 is fixed by the first spring fixing portion 634 connected to the link 631.

The lower plate 635 is formed to surround the outer circumferential surface of the first spring fixing portion 634 and a communication hole 636 is formed in a central region where the negative pressure valve 640 is provided.

The gasket 637 is fixed by the lower plate 635 and contacts the lower side of the body 111 to seal a portion of the heat exchange medium inside the heat exchanger 1000 moving to the communication part 113.

At this time, the gasket 637 may be fixed through a gasket fixing part 638 fixed to the lower plate 635.

The negative pressure valve 640 controls the movement of the cooling water in the reservoir tank 700 into the heat exchanger 1000. The negative pressure valve 640 includes a pin valve 641 and a second spring 642, 643).

The pin valve 641 passes through the communication hole 636 of the lower plate 635 and the vacuum plate 643 is connected to the lower side so that the vacuum plate 643 can communicate with the communication hole 636 Open and close.

The second spring 642 is supported by the pin valve 641 and the lower plate 635 so that the second spring 642 maintains the unstable basic shape when the pressure in the steady state or the heat exchanger 1000 is raised. The vacuum plate 643 closes the communication hole 636 of the lower plate 635 and the vacuum plate 643 is pressed to open the communication hole 636 of the lower plate 635 The cooling water in the reservoir tank 700 is moved into the heat exchanger 1000 through the communication portion 113, the through hole 632 of the link 631, and the communication hole 636.

6 and 7, the vacuum plate 643 is eccentrically connected to the lower side of the pin valve 641. In the cap 600 for a heat exchanger according to the present invention,

More specifically, the vacuum plate 643 has a first area A1 formed to be large enough to close the communication hole 636 with respect to the pin valve 641, and a second area A1 surrounding the first area A1 And a second area A2 extending from a certain area of the second area A2.

Various examples of the vacuum plate 643 are shown in Figs. 6 and 7. Fig.

The vacuum plate 643 shown in Figs. 6 and 7A is an example in which the vacuum plate 643 shown in Fig. 7B is a circular shape. The vacuum plate 643 shown in Fig. The vacuum plate 643 shown in FIG. 7 (c) has a structure in which the second region A2 is steeper than the first region A1 An example of connection is shown.

In FIG. 7, the distinction between the first area A1 and the second area A2 is indicated by a dotted line.

8 and 9 are cross-sectional views illustrating the operation of the cap 600 for a heat exchanger in accordance with the present invention (Fig. 8, when cooling water within the heat exchanger 1000 is moved to the reservoir tank 700) 700 when the cooling water inside the heat exchanger 1000 moves into the heat exchanger 1000)

8, when the pressure inside the heat exchanger 1000 is raised to discharge the cooling water, the cap 600 for the heat exchanger of the present invention is connected to the first spring of the pressure valve 630, The vacuum plate 634 is pressed against the gasket 637 while the second spring 642 is maintained in the basic state to close the communication hole 636 in a state where the vacuum plate 634 is pressed against the gasket 637, The cooling water in the heat exchanger 1000 is sequentially passed through the space between the body 111 and the gasket 637 and the communicating part 113 by the pressure valve 630 being raised to the reservoir tank 700 .

9, when the negative pressure is generated in the heat exchanger 1000 and the cooling water needs to be replenished, the cap 600 for a heat exchanger of the present invention has a basic state of the first spring 633 The second spring 642 is pressed and the negative pressure valve 640 is lowered so that the eccentric opposite side of the vacuum plate 634 is opened so that the cooling water in the reservoir tank 700 The through hole 632 of the link 631 and the communication hole 636 of the lower plate 635 are moved into the heat exchanger 1000.

That is, in the cap 600 for the heat exchanger of the present invention, since the vacuum plate 643 is eccentrically connected to the pin valve 641, when the cooling water needs to be replenished, the eccentric opposite side can be easily opened There are advantages.

FIG. 10 is another cross-sectional view of a cap 600 for a heat exchanger according to the present invention, in which a cap 600 for a heat exchanger of the present invention is formed such that the second region A2 is not formed on the upper outer circumferential surface of the pin valve 641 A stepped portion 641-1 for supporting the second spring 642 is formed.

The stepped portion 641-1 has an upper outer peripheral surface of the pin valve 641 protruded to support the second spring 642 and an outer peripheral surface of the pin valve 641, Only a certain region corresponding to the region for forming the first region A1 where the two regions A2 are not formed is protruded.

Accordingly, when the cooling water needs to be replenished, the cap 600 for a heat exchanger of the present invention can easily press the second spring 642 supported by the side where the stepped portion 641-1 is formed, The second gasket 637 can be easily opened by the portion of the vacuum plate 643 on which the second region A2 is not formed.

The cap 600 for a heat exchanger of the present invention further includes a release preventing portion 641-2 in which the upper surface of the portion of the pin valve 641 on which the stepped portion 641-1 is not formed protrudes upward, So as to prevent the second spring 642 from coming off the pin valve 641 when the second spring 642 is compressed.

Accordingly, the cap 600 for a heat exchanger of the present invention is eccentrically connected to the lower side of the vacuum valve 643 and is easily opened and closed by the vacuum plate 643 to smoothly discharge and replenish the cooling water, It is possible to prevent the components from being damaged due to the vibration.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

1000: heat exchanger
100: first header tank
101: header 102: tank
110: cooling water injection part 111: body
112:
113:
200: second header tank
310: inlet pipe 320: outlet pipe
400: tube
500: pin
600: Cap for heat exchanger
610: Plug
620: leaf spring
630: Pressure valve
631: Link 632: Through hole
633: first spring 634: first spring fixing portion
635: Lower plate 636:
637: gasket 638: gasket fixing portion
640: Negative pressure valve 641: Pin valve
641-1: step portion 641-2:
642: second spring 643: vacuum plate
A1: first region A2: second region
700: reservoir tank

Claims (4)

A body 111 formed to protrude from header tanks 100 and 200 of the heat exchanger 1000 and having an opening 112 for injecting cooling water and a reservoir tank 700 connecting the outer circumferential surface of the body 111 and the reservoir tank 700 In a cap 600 for a heat exchanger which opens and closes a cooling water injection part 110 including a communication part 113 and controls the flow of cooling water between the heat exchanger 1000 and the reservoir tank 700,
The heat exchanger cap (600)
A cap 610 formed to enclose the opening 112 of the body 111 and closing the opened region and being fixed to the outer surface of the body 111;
A leaf spring 620 provided to abut the sealing member under the cap 610;
A first spring 633 disposed on an outer circumferential surface of the link 631 and a second spring 633 disposed on an outer circumferential surface of the link 631. The first spring 633, A lower plate 635 having a communicating hole 636 formed in a central region thereof and a gasket 637 abutting the lower side of the body 111 of the cooling water injecting unit 110, Pressure valve 630;
A pin valve 641 passing through the communication hole 636 of the lower plate 635, a second spring 642 supported by the pin valve 641 and the lower plate 635, And a negative pressure valve (640) eccentrically connected to a lower side of the vacuum valve (641) to open and close the communication hole (636).
The method according to claim 1,
The vacuum plate 643 has a first area A1 capable of keeping the communication hole 636 in a closed state with respect to the pin valve 641 and a second area extending from a certain area around the first area A1 A2). ≪ / RTI >
3. The method of claim 2,
The pin valve 641 has a stepped portion 641-1 protruding from the upper outer circumferential surface of the pin valve 641 corresponding to a region where the second region A2 is not formed to support the second spring 642 Wherein the heat exchanger comprises a heat exchanger.
The method of claim 3,
The pin valve 641
And a separation preventing portion (641-2) formed on the upper surface of the portion where the stepped portion (641-1) is not formed is protruded upward.

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