KR20230055705A - Valve apparatus - Google Patents

Abstract

The present invention relates to a valve apparatus in which a port seal is closely adhered to a valve due to a support provided by a lip seal. The bearing capacity and airtightness of the lip seal are secured by using the pressure generated by the flow of cooling medium. In addition, the valve apparatus is introduced that simplifies the structure and reduces manufacturing costs by eliminating the spring structure supporting the port seal.

Description

Valve Apparatus {VALVE APPARATUS}

The present invention relates to a valve device that secures airtight performance by using the pressure of a cooling medium and has a simplified structure by removing a spring.

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. .

Accordingly, recently, a valve structure for controlling the flow of the cooling medium has been developed. In the case of the valve structure, a sealing structure is essentially applied for smooth flow of the cooling medium and stable operation of the valve body.

However, a conventional valve has a structure in which a seal for sealing is in contact with the valve, and a spring structure for bringing the seal and the valve into close contact with each other is applied. In addition, as the spring and the sealing body must also be applied with a retainer for a stable connection structure, there is a problem in that configurations for airtight performance of the valve increase and the connection structure becomes complicated.

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 these problems, and an object of the present invention is to provide a valve device in which a contact structure between a sealing body and a valve is simplified while ensuring airtight performance of the sealing body.

The valve device according to the present invention for achieving the above object is provided with a valve therein, a flow passage through which a cooling medium is circulated, and a valve body formed with a recessed portion facing the valve; A port seal provided in the recessed portion and formed to surround the flow path to contact the valve; And a plurality of lips are provided between the depression and the port seal, seated on the port seal, and extending to contact the depression to create a supporting force for the port seal. The plurality of lips are spaced apart to form a space between each lip. It includes a lip seal made so that each lip part is in close contact with the recessed part by the pressure of the cooling medium introduced into the space.

The valve body includes a port portion formed with a flow passage and a recessed portion, and an opening portion opened to an inside where a valve is provided is formed so that the port portion is inserted into the opening portion and coupled thereto.

The port seal is characterized in that one end is recessed so that the lip seal is seated, and a seating portion open toward the recessed portion 130 is formed, and the other end is formed to match the outer circumferential surface of the valve.

One end of the port seal is characterized in that it is formed to be spaced apart from the depression in a state where the lip seal is in contact with the depression and the other end is in contact with the valve.

The depression portion is composed of a horizontal end portion in a direction perpendicular to the flow path and a vertical end portion in a direction perpendicular to the horizontal end portion, and the lip seal is composed of a first lip portion contacting the horizontal end portion and a second lip portion contacting the vertical end portion, and the first lip portion It is characterized in that a space is formed between the and the second lip portion.

It is characterized in that a plurality of opening holes are formed along the circumference of the first lip portion so that the circulation passage and the space are opened.

The second lip part is characterized in that it extends obliquely in a direction opposite to the port seal and comes into close contact with the vertical end when the cooling medium introduced into the space acts under pressure.

The first lip part is characterized in that it extends curvedly toward the flow passage and presses the port seal toward the valve side while unfolding when the cooling medium flowing into the space acts as a pressure.

The first lip is characterized in that it extends by branching into a plurality of prongs toward the horizontal end.

The prongs extend to branch into two prongs, and in the case of one prong, it extends obliquely toward the space, and in the case of the other prong, it is characterized in that it extends obliquely toward the distribution path.

One side prong and the other prong are formed to be curved in mutually facing directions, so that the pressure of the cooling medium deforms the one prong and the other prong to collapse and presses the port seal toward the valve side.

The lip seal is characterized in that a third lip is spaced apart from the second lip and contacts the vertical end.

The third lip is characterized in that it extends obliquely in the port seal direction and contacts the vertical end.

The passage of the valve body is characterized in that it is an outlet side through which the cooling medium is discharged.

In the valve device having the structure as described above, the port seal is closely attached to the valve by the support force of the lip seal, and the support force and airtight performance of the lip seal are secured by using the pressure generated by the flow of the cooling medium. In addition, as the spring structure supporting the port seal is deleted, the structure is simplified and the manufacturing cost is reduced.

1 is a view showing a valve device according to the present invention.
Figure 2 is an internal cross-sectional view of the valve device shown in Figure 1;
3 is a view for explaining a lip seal according to a first embodiment;
4 is a view showing a lip seal according to the first embodiment shown in FIG. 3;
5 is a view for explaining a lip seal according to a second embodiment.
6 is a view showing a lip seal according to the second embodiment shown in FIG. 5;
7 is a view for explaining a lip seal according to a third embodiment.
8 is a view showing a lip seal according to the third embodiment shown in FIG. 7;
9 is a view for explaining a lip seal according to a fourth embodiment.

Hereinafter, a valve device 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 according to the present invention, FIG. 2 is an internal cross-sectional view of the valve device shown in FIG. 1, FIG. 3 is a view for explaining a lip seal according to a first embodiment, and FIG. 3 is a view showing the lip seal according to the first embodiment, FIG. 5 is a view for explaining the lip seal according to the second embodiment, and FIG. 6 shows the lip seal according to the second embodiment shown in FIG. FIG. 7 is a view for explaining a lip seal according to the third embodiment, FIG. 8 is a view showing a lip seal according to the third embodiment shown in FIG. 7, and FIG. 9 is a lip seal according to the fourth embodiment It is a drawing for explaining.

As shown in FIGS. 1 and 2, the valve device according to the present invention has a valve 110 inside, a flow path 120 through which a cooling medium is circulated, and a portion facing the valve 110. A valve body 100 having a recessed portion 130; A port seal 200 provided in the depression 130 and formed to surround the flow path 120 to contact the valve 110; And a plurality of lip portions 310 are formed between the recessed portion 130 and the port seal 200, seated on the port seal 200, and extending to contact the recessed portion 130, so that the port seal 200 The plurality of lip parts 310 are spaced apart to form a space between each lip part 310 so that each lip part 310 adheres to the recessed part 130 by the pressure of the cooling medium flowing into the space. Lip seal 300; includes.

Here, the passage 120 of the valve body 100 may be an outlet side where the cooling medium is discharged, and the airtightness of the lip part 310 and the port seal 200 is achieved by using the pressure generated during the circulation of the cooling medium. This can be secured.

In the valve body 100, a flow path 120 through which a cooling medium flows is formed, and a recessed portion 130 is formed at a portion facing the valve 110 outside the flow path 120. Here, the valve body 100 may include a plurality of passages 120, and the flow direction of the cooling medium through the passages 120 is determined according to the rotational position of the valve 110 provided therein. The rotational position of the valve 110 may be controlled through a driving motor M installed in the valve body 100 .

Here, the valve body 100 includes a port portion 140 in which a flow passage 120 and a recessed portion 130 are formed, and an opening portion 150 open to the inside where the valve 110 is provided is formed to form a port Part 140 is inserted into and coupled to opening part 150 . That is, an opening 150 open to the inside is formed in the valve body 100, and the port portion 140 is coupled to the opening portion 150 so that the flow of the cooling medium by the valve 110 is controlled by the port portion 140. ) can be circulated to other parts through the distribution passage 120. In this way, the valve body 100 and the port portion 140 are individually configured and have a mutual coupling structure, so that the valve body 100 and the port portion 140 are easily manufactured.

A port seal 200 is provided in the recessed portion 130 of the valve body 100, and the port seal 200 is formed to surround the flow path 120 and comes into contact with the valve 110 to form a valve 110. performing sealing on

In addition, the lip seal 300 is seated on the port seal 200 . Here, the lip seal 300 is provided between the recessed portion 130 and the port seal 200, and a plurality of lip portions 310 extending to contact the recessed portion 130 are formed to provide support for the port seal 200. generate That is, the lip seal 300 is made elastically deformable, and the plurality of lip parts 310 contact and support the recessed part 130, so that the force of the port seal 200 in close contact with the valve 110 is assisted. do.

In addition, in the lip seal 300, a plurality of lip parts 310 are spaced apart from each other so that a space is formed between each lip part 310. In this way, as the plurality of lip portions 310 come into contact with the recessed portion 130, the lip seal 300 secures airtightness with respect to the recessed portion 130 and is stably fixed in position. In particular, in the case of the lip seal 300, since a space is formed between the plurality of lip parts 310, each lip part 310 is deformed by the pressure of the cooling medium flowing into the space and comes into close contact with the recessed part 130.

That is, the lip seal 300 forms a space as the plurality of lip parts 310 contact the recessed part 130, and each lip part 310 is deformed so that each lip part 310 is widened by the pressure of the cooling medium present in the space, Each of the lip portions 310 is in close contact with the recessed portion 130 to improve airtight performance.

In addition, since the elastic deformation of the lip portion 310 generates force in the direction of the port seal 200 toward the valve 110, the airtight performance of the port seal 200 and the valve 110 is also secured.

In detail, referring to FIG. 3, the port seal 200 is recessed so that the lip seal 300 is seated at one end 210, but a seating portion 211 open to the recessed portion 130 is formed, and the other end 220 is formed to match the outer circumferential surface of the valve 110.

As such, the port seal 200 has a seating portion 211 formed at one end 210, and the lip seal 300 is seated through the seating portion 211, so that the lip seal 300 is positioned in the port seal 200 It is fixed. In particular, the seating portion 211 is formed to open toward the recessed portion 130, so that the lip seal 300 is seated on the seating portion 211 of the port seal 200 in a direction opposite to the formation direction of the lip portion 310. As the lip seal 300 is supported in the direction, the position of the lip seal 300 is stabilized. In addition, a state in which each lip portion 310 of the lip seal 300 is in contact with the recessed portion 130 may be maintained.

Accordingly, the port seal 200 may be made of Teflon, which is a rigid material, compared to the lip seal 300, and the lip seal 300 may be made of a rubber material.

For this reason, as the port seal 200 wraps the lip seal 300 through the mounting portion 211, the shape of the lip seal 300 is maintained, and thus the elastic force of the lip seal 300 may be generated.

On the other hand, one end 210 of the port seal 200 is spaced apart from the recessed part 130 in a state where the lip seal 300 is in contact with the recessed part 130 and the other end 220 is in contact with the valve 110 formed to be In this way, the port seal 200 is formed such that one end 210 is spaced apart from the recessed portion 130, so that the cooling medium flows through the spaced gap between the port seal 200 and the recessed portion 130 to form a lip seal ( A cooling medium may be filled in the space formed by the lip portion 310 of 300 .

As such, the port seal 200 has one end 210 spaced apart from the depression 130 in a state where the lip seal 300 is in contact with the depression 130 and the other end 220 is in contact with the valve 110 By doing so, a portion of the cooling medium circulating through the distribution path 120 is circulated into the spaced gap between the one end 210 and the recessed portion 130 of the port seal 200 to fill the space of the lip seal 300 Accordingly, the lip portion 310 may be deformed by the pressure of the cooling fluid and adhered to the recessed portion 130 side.

In addition, the cooling medium passing through the flow path 120 presses the one end 210 of the port seal 200 during circulation, so that the port seal 200 is strongly adhered to the valve 110 and the port seal 200 and The air tightness between the valves 110 is improved.

Meanwhile, the lip seal 300 according to the present invention may be applied in various embodiments.

Specifically, the depression 130 is composed of a horizontal end 131 in a direction orthogonal to the flow path 120 and a vertical end 132 in a direction orthogonal to the horizontal end 131, lip seal ( 300) is composed of a first lip portion 311 in contact with the horizontal end portion 131 and a second lip portion 312 in contact with the vertical end portion 132, and a space between the first lip portion 311 and the second lip portion 312 can be formed.

That is, it consists of a first lip portion 311 and a second lip portion 312 formed on the lip seal 300, and in the case of the first lip portion 311, it contacts the horizontal end portion 131 of the recessed portion 130 to form a port seal 200 is generated, and in the case of the second lip 312, it contacts the vertical end 132 of the recessed part 130, so that the recessed part 130 and the port seal 200 are airtight.

In addition, the first lip portion 311 and the second lip portion 312 of the lip seal 300 are spaced apart as they come into contact with the horizontal end portion 131 and the vertical end portion 132, respectively, so that the first lip portion 311 and the second lip portion 312 A space is formed between the two lip parts 312 together with the recessed part 130 . In this way, the lip seal 300 has a space by the first lip part 311 and the second lip part 312, and the cooling medium is filled in the space and pressure is generated by the cooling medium, so that the first lip part 311 ) and the second lip portion 312 are deformed to ensure airtightness and bearing capacity of each lip portion 310 .

To this end, a plurality of opening holes 311a may be formed along the circumference of the first lip portion 311 to open the space to the flow path 120 . These opening holes 311a may be spaced apart at regular intervals along the circumference of the first lip portion 311, and the first lip portion 311 and the second lip portion 312 are formed by the pressure of the cooling medium filled in the space. The size and number of the opening holes 311a may be determined according to the interaction of.

In particular, the pressure caused by the cooling medium in the space between the first lip portion 311 and the second lip portion 312 must be greater than the pressure of the cooling medium flowing through the port seal 200 inside the valve body 100. Bar, the size and number of the opening holes 311a are determined so that the pressure of the cooling medium in the space between the first lip portion 311 and the second lip portion 312 is greater.

Accordingly, the lip seal 300 of the present invention can be applied in various embodiments.

Here, in the lip seal 300 according to the present invention, in common, the second lip portion 312 extends obliquely in the opposite direction to the port seal 200, and adheres to the vertical end portion 132 when the pressure of the cooling medium introduced into the space is applied. do. That is, the lip seal 300 forms a space together with the recessed portion 130 between the first lip portion 311 and the second lip portion 312, and cools the space through the opening hole 311a of the first lip portion 311. When the medium is filled, the obliquely extending second lip portion 312 is deformed to open due to the pressure of the cooling medium. Due to this, the second lip portion 312 of the lip seal 300 is strongly adhered to the recessed portion 130 to secure airtight performance.

As one embodiment of the lip seal 300, as shown in FIGS. 3 and 4, the lip seal 300 has a first lip portion 311 extending linearly toward the horizontal end portion 131 and a vertical end portion 132 It may be composed of a second lip portion 312 extending obliquely toward the right.

Due to this, the first lip portion 311 of the lip seal 300 is in contact with the horizontal end portion 131 of the recessed portion 130 to generate the supporting force of the port seal 200, and in the case of the second lip portion 312, the recessed portion It is in contact with the vertical end portion 132 of 130 to seal between the recessed portion 130 and the port seal 200.

On the other hand, as a second embodiment of the lip seal 300, as shown in FIGS. 5 and 6, the first lip portion 311 bends and extends toward the passageway 120 when the pressure of the cooling medium introduced into the space acts. While unfolding, the port seal 200 may be pressed toward the valve 110.

That is, the first lip portion 311 of the lip seal 300 is in contact with the horizontal end portion 131 of the recessed portion 130 to generate a supporting force of the port seal 200 . Here, in the case of the first lip portion 311, since it extends curvedly toward the passageway 120, the first lip portion 311 is deformed to unfold when the cooling medium filled in the space through the opening hole 311a acts with pressure. Due to this, the first lip portion 311 generates a supporting force for the horizontal end portion 131 of the recessed portion 130 and a force according to the unfolding of the curved shape is added. Accordingly, the port seal 200 receives the supporting force by the first lip portion 311 of the lip seal 300 and strongly adheres to the valve 110, thereby improving airtight performance.

The second lip 312 is in contact with the vertical end 132 of the recessed portion 130 to form an airtight seal between the recessed portion 130 and the port seal 200, and is deformed so as to spread by the pressure filled in the space, thereby forming the recessed portion ( 130) is strongly adhered to.

Meanwhile, as a third embodiment, as shown in FIGS. 7 and 8 , the first lip portion 311 may branch and extend toward the horizontal end portion 131 into a plurality of prongs 311b. In this way, as the first lip portion 311 is branched into a plurality of prong portions 311b, the supporting force of the depression portion 130 with respect to the horizontal end portion 131 is increased.

In detail, the prongs 311b extend to branch into two prongs, and in the case of one prong 311b-1 extends obliquely toward the space, and in the case of the other prong 311b-2 the flow path 120. It may extend obliquely towards the

In this way, the first lip 311 is branched into one side prong 311b-1 and the other prong 311b-2, and the one prong 311b-1 and the other prong 311b-2 are opposite to each other. By extending obliquely in the direction to be, it is in contact with the recessed portion 130 can generate a bearing force. That is, the first lip portion 311 has a 'Y' shape as one side prong 311b-1 extends obliquely toward the space and the other prong portion 311b-2 obliquely extends toward the flow path 120. By being formed, the contact area with respect to the recessed portion 130 is increased to generate a solid supporting force.

In addition, one side prong 311b-1 and the other prong 311b-2 may be formed to be curved in mutually facing directions. As can be seen in FIG. 7 , as the one-side prongs 311b-1 and the other prongs 311b-2 are curved, their shapes are deformed by the pressure of the cooling medium to secure bearing capacity.

That is, in the case of one side prong 311b-1, when pressure is applied due to the cooling medium filling the space, the pressure of the cooling medium pushes the depression 130 while being deformed toward the other prong 311b-2. .

In addition, in the case of the other prong 311b-2, when the cooling medium flowing through the passage 120 acts under pressure, it is deformed toward the one prong 311b-1 and pushes the depression 130.

In this way, the one side prongs 311b-1 and the other prongs 311b-2 constituting the first lip 311 are deformed to be collapsed by the cooling medium and pressurize the depression 130 to open the valve 110. A bearing force is created in the direction in which it is directed. Due to this, as the port seal 200 on which the lip seal 300 is seated is pressed toward the valve 110, it is strongly adhered to the valve 110, thereby improving airtight performance.

Meanwhile, as the fourth embodiment, the lip seal 300 may further include a third lip portion 313 that is spaced apart from the second lip portion 312 and contacts the vertical end portion 132 .

In this way, the lip seal 300 is further configured with a third lip portion 313 spaced apart from the second lip portion 312 and in contact with the vertical end portion 132, so that the port seal 200 passes through the inside of the valve body 100 to block the circulating cooling medium. That is, since the second lip portion 312 and the third lip portion 313 of the lip seal 300 come into contact with the vertical end portion 132, airtightness between the recessed portion 130 and the port seal 200 is secured.

The third lip portion 313 obliquely extends toward the port seal 200 and contacts the vertical end portion 132 .

That is, in the lip seal 300, the third lip portion 313 extends obliquely in the direction of the port seal 200 and passes through the port seal 200 inside the valve body 100. Adhere to (132).

As such, the third lip portion 313 is strongly attached to the vertical end portion 132 of the recessed portion 130 by being deformed to widen by the pressure of the cooling medium flowing through the port seal 200 inside the valve body 100. It is closely adhered and confidentiality performance is ensured. Due to this, the lip seal 300 has improved airtight performance with respect to the vertical end 132 of the recessed portion 130 by the second lip portion 312 and the third lip portion 313, thereby passing through the passageway 120. The flow loss of the cooling medium is minimized.

In the valve 110 device having the structure as described above, the port seal 200 is in close contact with the valve 110 by the support force of the lip seal 300, and the lip seal ( 300) to secure the bearing capacity and airtight performance. In addition, as the spring structure supporting the port seal 200 is deleted, the structure is simplified and the manufacturing cost is reduced.

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: valve
120: distribution path 130: depression
131: horizontal end 132: vertical end
140: port part 150: opening part
200: port seal 210: one end of the port seal
211: seating part 220: the other end of the port seal
300: lip seal 310: lip
311: first lip portion 311a: opening hole
311b: prong 312: second lip
313: third lip

Claims (14)

a valve body having a valve therein, having a passage through which a cooling medium flows, and having a recessed portion formed at a portion facing the valve;
A port seal provided in the recessed portion and formed to surround the flow path to contact the valve; and
It is provided between the recess and the port seal and is seated on the port seal, and a plurality of lips extending to contact the recess are formed to generate a supporting force for the port seal, and the plurality of lips are spaced apart to form a space between each lip. A valve device comprising: a lip seal configured such that each lip portion is brought into close contact with the recessed portion by the pressure of the cooling medium introduced into the space. The method of claim 1,
The valve body includes a flow path and a port portion formed with a recessed portion, and an opening portion is formed that is open to the inside where the valve is provided, and the port portion is inserted into the opening portion and coupled to the valve device. The method of claim 1,
The valve device is characterized in that the port seal is recessed so that the lip seal is seated at one end, and a seating portion open to the recessed portion 130 is formed, and the other end is formed to match the outer circumferential surface of the valve. The method of claim 1,
A valve device characterized in that one end of the port seal is formed to be spaced apart from the depression in a state where the lip seal is in contact with the depression and the other end is in contact with the valve. The method of claim 1,
The recessed portion is composed of a horizontal end portion in a direction orthogonal to the flow path and a vertical end portion in a direction orthogonal to the horizontal end portion,
The lip seal is composed of a first lip portion contacting the horizontal end portion and a second lip portion contacting the vertical end portion, and a valve device characterized in that a space is formed between the first lip portion and the second lip portion. The method of claim 5,
A valve device characterized in that a plurality of opening holes are formed along the circumference of the first lip portion to open the flow path and space. The method of claim 5,
The valve device, characterized in that the second lip extends obliquely in a direction opposite to the port seal and is in close contact with the vertical end when the cooling medium flowing into the space acts under pressure. The method of claim 5,
The valve device, characterized in that the first lip portion is bently extended toward the flow path and pressurizes the port seal toward the valve side while unfolding when the pressure of the cooling medium flowing into the space is applied. The method of claim 5,
The valve device characterized in that the first lip part extends by branching into a plurality of prongs toward the horizontal end. The method of claim 9,
The valve device, characterized in that the prongs extend to branch into two prongs, in the case of one prong, extending obliquely toward the space, and in the case of the other prong, extending obliquely toward the flow path. The method of claim 10,
One side prong and the other prong are formed to be curved in mutually facing directions, so that the pressure of the cooling medium deforms the one prong and the other prong to collapse, thereby pressing the port seal toward the valve device. The method of claim 5,
The valve device according to claim 1 , wherein the lip seal further comprises a third lip portion spaced apart from the second lip portion and contacting the vertical end portion. The method of claim 12,
The valve device characterized in that the third lip extends obliquely in the direction of the port seal and contacts the vertical end. The method of claim 1,
The valve device characterized in that the circulation path of the valve body is the outlet side through which the cooling medium is discharged.

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