KR20230055704A - Valve apparatus having air extracting structure - Google Patents

Abstract

Disclosed is a valve device having an air discharge structure securing cooling performance by a cooling medium by maintaining a flow amount of the cooling medium by selectively discharging air according to whether the cooling medium circulates according to an opening direction of a valve. The present invention relates to the valve device having an air discharge structure, which comprises: a valve body; an elastic body provided inside a storage groove; a seal member inserted into the storage groove to be supported by the elastic body, coming in contact with a flow passage valve, and formed to seal a gap between a flow passage and the storage groove; and a check member discharging air when opening an opening hole.

Description

Valve device having an air discharge structure {VALVE APPARATUS HAVING AIR EXTRACTING STRUCTURE}

The present invention relates to a valve device having an air discharge structure, and relates to a valve device having an air discharge structure through which air containing a cooling medium is discharged.

Vehicles are equipped with various electrical parts, and recently, various driving systems using electric energy are increasing.

A drive system using such electric energy may include an inverter, an LDC for converting DC power into AC power, and a charger, and a cooling system capable of maintaining an appropriate temperature is essential due to the heating characteristics of electric components including these. do.

To this end, a water pump is provided in the cooling system to circulate the cooling medium, and the cooling medium discharged from the water pump is circulated through various electrical components and then through a heat source, thereby protecting various electrical components having heat generating characteristics from overtemperature. .

However, conventional valves only focus on technology development to secure smooth distribution performance and sealing performance of cooling medium, and do not have an air bleeding function through the valve.

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 10-1558394 B1 (2015.10.01)

The present invention has been proposed to solve this problem, and an object of the present invention is to provide a valve device having an air discharge structure in which cooling performance by a cooling medium is secured by discharging air contained in a cooling medium.

In order to achieve the above object, a valve device having an air discharge structure according to the present invention has a flow path through which a cooling medium flows, and an accommodation groove formed outside the flow path, and an opening hole communicating with the flow path or the outside in the receiving groove. a valve body formed therein and having a flow valve for selectively controlling the circulation of the cooling medium in the circulation passage; An elastic body provided inside the receiving groove; a seal member inserted into the receiving groove, supported by the elastic body, in contact with the flow valve, and formed to seal between the flow passage and the receiving groove; and a check member provided to be movable in the accommodating groove and selectively opening and closing the through hole by the air and the cooling medium filled in the accommodating groove according to whether or not the cooling medium flows through the flow passage, thereby allowing air to be discharged when the through hole is opened. includes;

The valve body includes a port portion formed with a flow path and an accommodation groove, and an opening portion opened to an inside where a flow valve is provided is formed, and the port portion is inserted into the opening portion and coupled thereto.

A support rib for supporting the elastic body is formed in the accommodation groove of the valve body, and the elastic body is positioned between the support rib and the seal member.

The accommodating groove is divided into an upper space in which the check member is provided and a lower space in which the elastic body is provided around the support rib, and in the case of the upper space, the check member is formed to be extended to be movable.

A guide rib protruding adjacent to the check member and extending in a straight line is formed in the upper space of the receiving groove, so that the check member moves along the guide rib.

The valve body is formed with a partition wall partitioning the flow path and the receiving groove, and the seal member has one end inserted into the receiving groove and supported by an elastic body, the other end being in contact with the flow valve, and one end having a lip protruding into the partition wall. to be characterized

The lip is characterized in that it extends obliquely in the direction in which the through hole is formed at one end.

The seal member further includes a retainer interposed between one end and the elastic body, and the retainer is formed to surround an outer surface of the seal member.

The check member is characterized in that it consists of a body portion extending along the receiving groove and moving in the receiving groove, and a sealing portion protruding from the body portion to face the opening hole and closing the opening hole when contacting the opening hole.

The body portion is formed smaller than the receiving groove to form a microgap with the receiving groove, and is characterized in that the circumferential surface is formed to extend in a straight line.

The accommodating groove is characterized in that the periphery of the opening hole is formed to extend obliquely or linearly, and the sealing portion is formed to be curved in a spherical shape.

The receiving groove is characterized in that the periphery of the opening hole is curvedly depressed in a spherical shape, and the sealing portion is formed curvedly in a spherical shape to match the periphery of the receiving groove.

The valve body is characterized in that the flow path in which the receiving groove is formed is disposed at the upper portion, so that when the receiving groove is filled with air, the check member is moved downward to open the through hole.

The circulation path is characterized in that it is an outlet side through which the cooling medium is discharged.

The valve device having the air discharge structure configured as described above allows the air contained in the cooling medium to be discharged, so that the flow rate of the cooling medium is maintained and the cooling performance by the cooling medium is secured.

1 is a view showing a valve device having an air discharge structure according to the present invention.
Figure 2 is a view showing the inside of the valve device having an air discharge structure shown in Figure 1;
3 is a view showing a state in which the check member closes the opening hole.
4 is a view showing a state in which the check member opens the through hole.
5 is a cross-sectional view of a valve device having an air discharge structure shown in FIG. 1;
6 is a view showing a check member according to the present invention.
Figure 7 is a view showing another embodiment of the receiving groove according to the present invention.

Hereinafter, a valve device having an air discharge structure according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

1 is a view showing a valve device having an air discharge structure according to the present invention, FIG. 2 is a view showing the inside of the valve device having an air discharge structure shown in FIG. 1, and FIG. It is a view showing a closed state, Figure 4 is a view showing a state in which the check member opens the through hole, Figure 5 is a view showing a cross-sectional view of the valve device having the air discharge structure shown in Figure 1, Figure 6 is This is a view showing the check member according to the present invention, and FIG. 7 is a view showing another embodiment of the receiving groove according to the present invention.

As shown in FIGS. 1 and 2 , the valve device having an air discharge structure according to the present invention includes a flow path 110 through which a cooling medium flows, and an accommodation groove 120 formed outside the flow path 110. An opening hole 121 communicating with the flow path 110 is formed in the receiving groove 120, and a valve body equipped with a flow valve 200 for selectively controlling the flow of the cooling medium of the flow path 110 therein ( 100); An elastic body 300 provided inside the receiving groove 120; A seal member 400 inserted into the receiving groove 120, supported by the elastic body 300, in contact with the flow valve 200, and airtight between the flow passage 110 and the receiving groove 120; And it is provided to be movable in the accommodation groove 120 and selectively opens and closes the through hole 121 by the air and cooling medium filled in the accommodation groove 120 according to whether the cooling medium flows through the passage 110. , a check member 500 that allows air to be discharged when the opening hole 121 is opened.

Here, the flow path 110 may be an outlet side through which the cooling medium is discharged. Through this, the present invention, according to the position of the flow valve 200, the flow passage 110 is opened and the cooling medium is circulated, the receiving groove 120 is filled with the cooling medium, and the check member 500 is filled by the filled cooling medium. ) may be pushed to close the opening hole 121. In addition, the seal member 400 is deformed by the pressure of the cooling medium filled in the receiving groove 120 to ensure sealing performance.

In addition, when air is collected in the accommodating groove 120 together with the cooling medium, the opening hole 121 is opened as the check member 500 moves as much as the air is filled in the accommodating groove 120. Due to this, air passes through the check member 500 and is discharged through the opening hole 121 of the receiving groove 120, and the discharged air is separated from the cooling medium and passes through the distribution passage 110 to a radiator or an air venting device. It goes through the process of being discharged from the outside.

Accordingly, in the valve body 100, the flow path 110 in which the receiving groove 120 is formed is disposed at an upper portion, so that when the receiving groove 120 is filled with air, the check member 500 is moved downward and the opening hole (121) may be configured to be open.

That is, the valve body 100 is disposed at an upper portion of the flow path 110 in which the receiving groove 120 is formed, so that the check member 500 moves vertically in the receiving groove 120 . Due to this, when the cooling medium is filled in the receiving groove 120, the check member 500 is moved upward by the cooling medium to close the opening hole 121, and the receiving groove 120 is filled with air when collecting air. As the check member 500 is moved downward as much as possible, an operation of opening the through hole 121 is performed.

As such, the check member 500 according to the present invention is moved upward by the pressure of the cooling medium filled in the receiving groove 120 and moves downward when the pressure of the cooling medium is released to open and close the through hole 121 .

Accordingly, the valve body 100 is spaced apart from the flow path 110 through which the cooling medium is circulated and the flow path 110 to accommodate the elastic body 300, the seal member 400, and the check member 500 provided. A groove 120 is formed. The valve body 100 may include a plurality of flow passages 110, and the cooling medium is supplied to each flow passage 110 by the flow valve 200 whose rotational position is switched by the drive motor M. It can be distributed selectively.

Here, the valve body 100 includes a port portion 130 in which a flow passage 110 and an accommodation groove 120 are formed, and an opening portion 150 open to the inside where the flow valve 200 is provided is formed The port part 130 is inserted into the opening part 150 and coupled thereto. That is, an opening 150 open to the inside is formed in the valve body 100, and the port portion 130 is coupled to the opening portion 150 so that the circulation of the cooling medium by the flow valve 200 is controlled by the port portion ( 130) may be circulated to other parts through the distribution passage 110. In this way, by individually configuring the valve body 100 and the port portion 130 and having a mutual coupling structure, the valve body 100 and the port portion 130 are easily manufactured. In addition, as the flow path 110 and the accommodation groove 120 are formed in the port portion 130, the formation of the structure in which the flow path 110 and the accommodation groove 120 are partitioned is simplified.

In the receiving groove 120 of the valve body 100, the seal member 400 is elastically supported by the elastic body 300 and comes into contact with the flow valve 200, thereby ensuring the operability and airtight performance of the flow valve 200. . Here, the elastic body 300 may include a spring, and various configurations for generating force through length variation may be applied.

In addition, the receiving groove 120 of the valve body 100 is provided with a check member 500 to be movable. This check member 500 is made of a lightweight plastic material and can be moved by a cooling medium filled in the receiving groove 120 .

Through this, the present invention, as shown in FIG. 3, when the cooling medium is circulated in the flow path 110 as the flow valve 200 is positioned to open the flow path 110 in which the receiving groove 120 is formed, The cooling medium also flows into the receiving groove 120 side. That is, the cooling medium inside the valve body 100 passes through the seal member 400 and flows into the receiving groove 120, and the check member 500 is opened by the cooling medium filled in the receiving groove 120 through the opening hole ( 121) to close the opening hole 121.

Meanwhile, as shown in FIG. 4 , when air is collected in the receiving groove 120 , the check member 500 is exposed to the air and moved as much as the air is filled to open the through hole 121 . That is, the air collected in the receiving groove 120 is discharged to the distribution passage 110 through the opening hole 121, and is discharged to the outside through a radiator or an air vent device, so that the air contained in the cooling medium is removed and cooled. Cooling performance by the medium is secured.

In this way, when the discharge of air is completed, the check member 500 is moved by the cooling medium filled in the accommodation groove 120 to close the opening hole 121 .

In detail with respect to the present invention described above, the support rib 122 for supporting the elastic body 300 is formed in the receiving groove 120 of the valve body 100, and the elastic body 300 is formed with the support rib 122 It is located between the sealing member 400.

As shown in FIGS. 2 to 5 , the receiving groove 120 is formed with a support rib 122 in which the elastic body 300 is contacted and supported, thereby fixing the position of the elastic body 300 . That is, the support rib 122 protrudes from the inner surface constituting the receiving groove 120 and is formed to catch the elastic body 300, so that the elastic body 300 is in contact with the support rib 122 to form a seal member in a supported state ( 400) may provide elastic force in a direction toward the flow valve 200.

These support ribs 122 may protrude to extend along the circumference of the receiving groove 120 or may be configured to protrude at regular intervals. The elastic body 300 provides elastic force to the seal member 400 in a state located between the support rib 122 and the seal member 400 so that the seal member 400 is maintained in contact with the flow valve 200 can do.

On the other hand, the receiving groove 120 is divided into an upper space S1 in which the check member 500 is provided and a lower space S2 in which the elastic body 300 is provided around the support rib 122, and the upper space S1 ) In the case of the check member 500 is formed to be extended to be movable.

In this way, the accommodating groove 120 is divided into an upper space S1 and a lower space S2 around the support rib 122, so that the check member 500 is moved in the upper space S1 to open the through hole 121. is opened and closed, and the elastic body 300 and the seal member 400 interlock in the lower space S2 so that the seal member 400 is in close contact with the flow valve 200.

In particular, in the case of the upper space (S1) is extended longer than the length of the check member 500 to secure a space in which the check member 500 can be moved. Through this, the check member 500 can selectively open and close the opening hole 121 as it is movable in the upper space S1 of the receiving groove 120, and the elastic body 300 and the seal member 400 are accommodated The position is fixed in the lower space (S2) of the groove 120, so that contact between the seal member 400 and the flow valve 200 can be stably maintained.

In addition, a guide rib 123 protruding adjacent to the check member 500 and extending in a straight line is formed in the upper space S1 of the receiving groove 120, so that the check member 500 is attached to the guide rib 123 is moved along

These guide ribs 123 may be composed of a plurality, and by protruding adjacent to the check member 500 in the upper space S1 of the receiving groove 120, the check member 500 is moved by the guide rib 123. position is fixed.

That is, the guide rib 123 is extended in a straight line along the extending direction of the receiving groove 120 in a state located adjacent to the check member 500, so that the check member 500 is accommodated along the guide rib 123. Only linear motion can be performed in groove 120 .

Due to this, the position of the check member 500 is fixed to match the opening hole 121 in the receiving groove 120, and the opening or closing operation of the opening hole 121 can be accurately performed as only a linear motion is performed. there is.

On the other hand, in the valve body 100, a partition wall 140 partitioning the flow path 110 and the receiving groove 120 is formed, and one end 410 of the seal member 400 is inserted into the receiving groove 120 It is supported by the elastic body 300 , the other end 420 is in contact with the flow valve 200 , and a lip 411 protruding to the partition wall 140 is formed at one end 410 .

That is, in the valve body 100, the partition wall 140 extends in a straight line between the flow passage 110 and the accommodation groove 120, thereby partitioning the flow passage 110 and the accommodation groove 120.

In particular, one end 410 of the seal member 400 is inserted into the receiving groove 120 and supported by the elastic body 300 so that the end surface is formed flat so that the elastic body 300 is stably seated, and the other end ( 420) may be formed to match the outer circumferential surface of the flow valve 200.

A lip 411 protrudes from one end 410 of the seal member 400, and the lip 411 contacts the partition wall 140 to block the receiving groove 120 and the flow path 110, thereby receiving The gap between the groove 120 and the distribution path 110 is airtight. In particular, the lip 411 of the seal member 400 is deformed by the pressure of the cooling medium filled in the receiving groove 120, thereby forming strong adhesion to the partition wall 140, thereby improving airtight performance.

Accordingly, the lip 411 may obliquely extend in the direction in which the through hole 121 is formed from the one end portion 410 .

In this way, the lip 411 protrudes toward the partition wall 140 but extends obliquely, so that the lip 411 is deformed to be pressed toward the partition wall 140 when pressure is applied as the cooling medium is filled in the receiving groove 120. It adheres to the partition wall 140. That is, the lip 411 is deformed to open by the pressure of the cooling medium and adheres to the partition wall 140, thereby improving airtightness between the lip 411 and the partition wall 140, thereby providing a 110) is blocked from flowing the cooling medium.

In addition, the seal member 400 further includes a retainer 430 interposed between the one end portion 410 and the elastic body 300, and the retainer 430 may be formed to surround the outer surface of the seal member 400. there is.

In this way, since the retainer 430 is provided between the one end 410 of the seal member 400 and the elastic body 300, damage to the sealing member 400 due to direct contact of the elastic body 300 with the seal member 400 This is prevented and the shape of the seal member 400 is preserved.

This retainer 430 is disposed between the elastic body 300 and one end 410 of the seal member 400, and the end is bent to extend to cover the outer surface of the seal member 400, so as to have a '┏' shape. It may be formed in the form of a cap.

In this way, the retainer 430 is formed in a form surrounding the seal member 400, so that even when the elastic force of the elastic body 300 is applied to the one end 410 of the seal member 400, excessive shape deformation of the one end 410 is prevented. prevented In addition, the retainer 430 is in contact with one end 410 and the other end 420 as it wraps the outer surface of the seal member 400, so that the shape of the seal member 400 is maintained and the flow valve 200 contact performance is ensured.

On the other hand, as shown in FIGS. 2 and 6, the check member 500 is formed to extend along the receiving groove 120 and moves in the receiving groove 120 in the body portion 510 and the body portion 510. It consists of a sealing part 520 that protrudes to face the opening hole 121 and closes the opening hole 121 when in contact with the opening hole 121 .

In this way, the check member 500 is composed of a body portion 510 and a sealing portion 520, and the body portion 510 and the sealing portion 520 are integrally formed. Here, in the case of the body portion 510, it is formed to extend along the receiving groove 120, and stable linear movement is performed in the receiving groove 120, and the sealing portion 520 is formed through the opening hole when contacting the opening hole 121 ( 121) to ensure that the opening hole 121 is accurately closed.

In detail, the body portion 510 is formed smaller than the receiving groove 120 to form a micro gap with the receiving groove 120, and the circumferential surface is formed to extend in a straight line.

In this way, since the body portion 510 of the check member 500 is formed to extend in a straight line, movement is allowed only in a straight line along the receiving groove 120, and operation performance according to the movement is secured by preventing inclination. do.

In addition, as the body portion 510 forms a microgap with the accommodating groove 120, air can flow through the microgap. Due to this, when the check member 500 is moved to open the opening hole 121, the air remaining in the receiving groove 120 passes through the micro gap between the body portion 510 and the receiving groove 120 to open the opening hole 121. ) and can be discharged.

Meanwhile, as shown in FIG. 3 , the receiving groove 120 may be formed so that the periphery of the through hole 121 extends in an oblique or straight line, and the sealing portion 520 may be formed to be curved in a spherical shape.

In this way, the accommodation groove 120 extends obliquely or linearly around the opening hole 121, and the sealing portion 520 of the check member 500 is formed to protrude in a spherical shape, so that the check member 500 It is moved toward the opening hole 121, and when the sealing part 520 comes into contact with the receiving groove 120, it is in line contact. For this reason, the opening hole 121 is formed in an oblique or straight line to ensure ease of manufacture, and even if the opening hole 121 and the check member 500 do not match perfectly, the check member 500 and the through hole 121 are lined. Contact performance is ensured.

On the other hand, as shown in FIG. 7, the receiving groove 120 is recessed in a spherical shape around the opening hole 121, and the sealing portion 520 is spherical to match the periphery of the receiving groove 120. It is formed to be curved.

In this way, the receiving groove 120 is depressed in a spherical shape, and the sealing portion 520 of the check member 500 is formed to protrude in a spherical shape to match the receiving groove 120, so that the check member 500 is formed through the opening hole As it is moved to the (121) side and the sealing part 520 is mutually matched when in contact with the receiving groove 120, the contact area is secured and the airtight performance is improved. In addition, when the check member 500 is moved to open the opening hole 121, the air discharge becomes smooth due to the curved shape of the opening hole 121 and the sealing part 520.

The valve device having the air discharge structure configured as described above allows the air contained in the cooling medium to be discharged, so that the flow rate of the cooling medium is maintained and the cooling performance by the cooling medium 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.

100: valve body 110: distribution path
120: receiving groove 121: opening hole
122: support rib 123: guide rib
130: port part 140: bulkhead
200: flow valve 300: elastic body
400: seal member 410: one end of the seal member
411: lip 420: the other end of the seal member
430: retainer 500: check member
510: body part 520: sealing part

Claims (14)

A flow passage through which the cooling medium is circulated, and an accommodating groove are formed outside the passage passage, and an opening hole communicating with the flow passage or the outside is formed in the accommodating groove. A valve body provided with;
An elastic body provided inside the receiving groove;
a seal member inserted into the receiving groove, supported by the elastic body, in contact with the flow valve, and formed to seal between the flow passage and the receiving groove; and
a check member provided to be movable in the accommodating groove and selectively opening and closing the through hole by the air and the cooling medium filled in the accommodating groove according to whether or not the cooling medium flows through the passage, so that air is discharged when the through hole is opened; Valve device having an air discharge structure comprising a. The method of claim 1,
A valve device having an air discharge structure, characterized in that the valve body includes a port portion in which a flow passage and an accommodation groove are formed, and an opening portion opened to an inside where a flow valve is provided is formed and the port portion is inserted into the opening portion and coupled. The method of claim 1,
A valve device having an air discharge structure, characterized in that a support rib is formed in the receiving groove of the valve body to support the elastic body, and the elastic body is positioned between the support rib and the seal member. The method of claim 3,
The accommodating groove is divided into an upper space where the check member is provided and a lower space where the elastic body is provided around the support rib, and in the case of the upper space, the valve device having an air discharge structure characterized in that the check member is formed to be extended to be movable. . The method of claim 4,
A valve device having an air discharge structure, characterized in that a guide rib protruding adjacent to the check member and extending in a straight line is formed in the upper space of the receiving groove, so that the check member moves along the guide rib. The method of claim 1,
The valve body is formed with a partition wall partitioning the flow path and the receiving groove,
The sealing member has an air discharge structure, characterized in that one end is inserted into the receiving groove and supported by the elastic body, the other end is in contact with the flow valve, and one end is formed with a lip protruding from the partition wall. The method of claim 6,
The valve device having an air discharge structure, characterized in that the lip extends obliquely in the direction in which the through hole is formed at one end. The method of claim 6,
The valve device having an air discharge structure, characterized in that the seal member further includes a retainer interposed between one end and the elastic body, and the retainer is formed to surround an outer surface of the seal member. The method of claim 1,
The check member is formed to extend along the receiving groove and is formed of a body portion moved in the receiving groove and a sealing portion protruding from the body portion to face the opening hole and closing the opening hole when in contact with the opening hole An air discharge structure characterized in that valve device with The method of claim 9,
A valve device having an air discharge structure, characterized in that the body portion is formed smaller than the accommodation groove to form a microgap with the accommodation groove, and the circumferential surface is formed to extend in a straight line. The method of claim 9,
The accommodation groove is formed so that the periphery of the through hole extends in an oblique or straight line,
The valve device having an air discharge structure, characterized in that the sealing portion is formed to be curved in a spherical shape. The method of claim 9,
The receiving groove is recessed in a spherical shape around the opening hole,
The valve device having an air discharge structure, characterized in that the sealing portion is formed curved in a spherical shape to match the periphery of the receiving groove. The method of claim 9,
The valve body has an air discharge structure, characterized in that the flow passage in which the receiving groove is formed is disposed on the upper side, so that the check member is moved downward to open the through hole when the receiving groove is filled with air. The method of claim 1,
A valve device having an air discharge structure, characterized in that the passage is an outlet side through which the cooling medium is discharged.

Images