KR102130158B1 - Gas charging valve unit with enhanced hermeticity and gas spring using the same - Google Patents

Abstract

The present invention relates to a gas charging valve unit with enhanced hermeticity and a gas spring using the same, and to a gas charging valve unit stably ensuring a close contact area for closing a gas chamber filled with a gas to have enhanced hermeticity, and to a gas spring using the same. The gas charging valve unit with enhanced hermeticity and the gas spring using the same according to the present invention can provide stable hermeticity by integrally coupling a hermetic member to a slide-moving main body movable within a valve body to regularly ensure an area in contact with a cylinder or an end cap which forms the valve body or a valve cavity in order to close the gas chamber. In addition, the gas charging valve unit with enhanced hermeticity and the gas spring using the same according to the present invention can enhance hermeticity by forming the hermetic member corresponding to an outer diameter extension unit of the slide-moving main body to ensure a regular close contact area in the circumferential direction around the slide-moving main body.

Description

Gas charging valve unit with enhanced hermeticity and gas spring using the same}

The present invention relates to a gas filling valve unit having improved airtightness and a gas spring using the same, wherein a gas-filled valve unit and an airtightness improved unit are secured by stably securing a close contact area of a check valve member for closing a gas chamber filled with gas. It is about gas spring.

Typically, a gas spring is installed in a press mold for forming a sheet metal part and can be used to prevent movement of parts such as fastening rings for metal semi-finished products. The gas spring is operated by an external gas source or by gas filled in a cylinder that is its own container.

The gas spring is composed of a cylinder having a gas chamber filled with nitrogen at a predetermined pressure through a filling valve, a sliding piston or head accommodated in the cylinder, and a rod connected thereto. This gas spring provides a cushion that allows the rod to flexibly move to its retracted position when the force applied to the rod from outside is greater than the gas repelling force in the gas chamber applied to the piston.

The gas chamber of the gas spring is filled with nitrogen having a pressure of 2,000 psi or more, and the pressure during use may be increased to 3,000 to 5,000 psi. Examples of such gas springs are disclosed in United States Patent Nos. 4,792,128 and 4,838,527.

And, as disclosed in Korean Patent Publication No. 10-1129044, the gas spring is provided with a gas filling valve for filling the gas.

In general, the gas filling valve is a valve body formed of a ring-shaped valve seat corresponding to a pressure direction acting inside the gas chamber of the gas spring, and is slidably installed on the valve body, and is installed on the valve seat under the action of gas pressure in the gas chamber. It is provided with a check valve member in close contact with a spring installed in the valve body to elastically bias the check valve member toward the valve seat.

The check valve member retreats away from the valve seat by the gas pressure supplied when filling the gas chamber, and when the gas filling is completed, the gas chamber is closed to the ring-shaped valve seat again by a spring so as to be closed.

However, the contact area between the check valve member and the valve seat is small, and when the check valve member is in close contact with the valve seat after gas chamber filling is completed, there is a problem in that gas may leak because contact is not uniformly made along the circumferential direction. .

Republic of Korea Registered Patent Publication No. 10-1129044: Gas spring

The present invention is to solve the above problems, the valve seat is integrally formed on the check valve member to ensure a uniform contact area for sealing the gas chamber, thereby improving the airtightness that the gas chamber is always stably sealed. It is intended to provide a gas filling valve unit and a gas spring using the same.

In order to achieve the above object, the gas filling valve unit having improved gas tightness of the present invention is mounted in a valve cavity formed in a cylinder or end cap of the gas spring in communication with the gas chamber of the gas spring, and gas is injected from the valve cavity. A valve body having an internal space communicating with the gas injection part and the gas chamber; A check valve member slidably installed in the inner space of the valve body and moved to close one end of the valve body or the valve cavity on the side of the gas injection part under the action of gas pressure in the gas chamber; And a pressurizing member elastically pressing the check valve member toward the gas injection part in the valve body, wherein the check valve member is slidably mounted in the valve body and is provided with the gas injection part by the pressurizing member. A sliding movable body having an outer diameter extension portion elastically pressed to the side; It is formed of a material that is elastically deformable by the pressure in the pressurizing member or the gas chamber, and is integrally coupled to the sliding movable body so as to face the gas injection part, but the valve body or the valve cavity to close the gas chamber. It is characterized in that it comprises a; airtight member that is in close contact with one end of the gas injection portion or the valve body covering the entire surface of the outer diameter expansion portion toward the gas injection portion to ensure a constant contact area in contact with.

The sliding movement body is supported through the other end of the valve body on the gas chamber side and is connected to the center of the other surface of the outer diameter expansion portion and the first stem portion, and the cylinder, the end cap or the same position on the first stem portion. It is supported at one end of the valve body and extends in a direction parallel to the first stem portion, and has a second stem portion connected to the center of one surface of the outer diameter expansion portion, and the hermetic member penetrates the stem through which the second stem portion is penetrated at the center. A ball is formed and is coupled to one surface of the outer diameter expansion unit, and the pressure in the pressurizing member or the gas chamber is uniformly transmitted from the outer diameter expansion unit, and the outer diameter expansion is fixed to the inner peripheral surface of one end of the valve body or the inner peripheral surface of the valve cavity. It is preferably formed to correspond to the negative.

The check valve member may be formed of a material that is elastically deformable by the pressure of the pressurizing member or the gas chamber, and may further include a cover layer surrounding the mutually-expanded outer diameter expanding portion and the hermetic member.

The hermetic member includes a hermetic member body having a stem through hole and corresponding to the outer diameter expanding portion; It protrudes along the circumferential direction on the outer circumferential surface of the hermetic member body, extends toward the other end side of the valve body, and extends in a direction away from the hermetic member body by the gas pressure of the gas chamber to contact the inner circumferential surface of the valve body. , It may be provided with an auxiliary machine mill that is in close contact with the airtight member body by the gas pressure introduced during gas filling through the gas injection unit.

And, the gas spring of the present invention includes a cylinder having a hollow portion for forming a gas chamber in the longitudinal direction; And the end cap is coupled to the lower end of the cylinder to seal the lower portion of the hollow; A piston inserted into the hollow portion of the cylinder and having a rod; And a gas filling valve unit coupled to a valve cavity communicating with a gas injection part formed in the end cap to open the gas chamber during gas filling and to close the gas chamber after gas filling is completed. It is mounted on the valve cavity, the valve body having an internal space communicating with the gas chamber and the gas injection portion, and is slidably installed in the interior space of the valve body, the gas injection by the action of the gas pressure in the gas chamber It has a check valve member that is moved to close one end of the valve body or the end of the valve body on the negative side, and a pressing member for elastically biasing the check valve member to the gas injection side in the valve body, the check The valve member is slidably mounted in the valve body and a sliding movable body formed with an outer diameter expansion portion elastically pressurized toward the gas injection portion by the pressing member; It is formed of a material that is elastically deformable by the pressure in the pressurizing member or the gas chamber, and is integrally coupled to the sliding movable body so as to face the gas injection part, but the valve body or the valve cavity to close the gas chamber. It is characterized in that it comprises a; airtight member that covers the entire surface of the outer diameter expansion portion toward the gas injection portion to ensure a constant contact area in contact with the gas injection portion or the valve body in close contact with one end.

The gas spring of the present invention includes a first groove extending radially away from the second stem portion on one surface of the hermetic member facing the inner circumferential surface of one end of the valve body or the inner circumferential surface of the valve cavity, and one end of the valve body It is formed on the inner circumferential surface or the inner circumferential surface of the valve cavity, or is formed on a surface facing the airtight member of the auxiliary hermetic member mounted between the airtight member and one side of the inner space of the valve body or one side of the valve cavity to the first groove A second groove that can be molded may be further provided.

Gas filling valve unit and gas spring using the improved gas tightness of the present invention is a cylinder or end forming a valve body or a valve cavity to close the gas chamber by the airtight member is integrally coupled to a sliding movable body movable within the valve body Since the area in contact with the cap is constantly secured, it is possible to provide stable airtightness.

In addition, the gas filling valve unit having improved airtightness of the present invention and the gas spring using the gastight member are formed so as to correspond to the outer diameter expansion portion of the sliding mobile body to ensure a uniform contact area in the circumferential direction around the sliding mobile body to ensure airtightness. This can be improved.

In addition, the gas filling valve unit having improved airtightness of the present invention and a gas spring using the same have an advantage that airtightness can be further improved by an auxiliary machine mill that is in close contact with the side of the valve body by the gas pressure of the gas chamber.

1 is a side cross-sectional view of a gas spring according to a first embodiment of the present invention,
Figure 2 is a perspective view of the check valve member of the gas charging valve unit of Figure 1,
3 is a perspective view of a check valve member according to a second embodiment of the present invention,
4 is a partially enlarged cross-sectional view of a gas spring according to a third embodiment of the present invention,
FIG. 5 is a view showing a state in which the auxiliary machine mill of the gas tight member is folded when filling the gas spring of FIG. 4;
Figure 6 is a perspective view of the check valve member of the gas charging valve unit of Figure 4,
7 is a partially enlarged cross-sectional view of a gas spring according to a fourth embodiment of the present invention,

Hereinafter, a gas filling valve unit having improved airtightness according to a preferred embodiment of the present invention and a gas spring using the same will be described in detail with reference to the accompanying drawings.

1 and 2 show a gas spring to which the gas filling valve unit 70 according to the first embodiment of the present invention is applied.

Before describing the gas filling valve unit 70 according to the first embodiment of the present invention, the gas spring shown in FIG. 1 will be described.

The gas spring according to the first embodiment of the present invention is a cylinder 12 having a hollow portion 11 for forming a gas chamber 90, and is coupled to a lower end side of the cylinder 12 to form a cylinder 12. Combined with the end cap (13) for sealing the lower side and the rod (20) inserted into the hollow (11) of the cylinder (12) to partition the gas chamber (90) and projecting outward from the cylinder (12) The piston 30 is provided. And, it is inserted into and fixed to the inner circumferential surface of the cylinder and is in close contact with the rod 20 to include a sealing unit 40 for sealing the upper end of the cylinder 12.

Cylinder 12 is made of a tubular having a hollow portion 11, an opening through which the rod 20 protrudes on the upper end side is formed, and the end cap 13 is coupled to the other end, thereby allowing the piston 30 and In addition, the gas chamber 90 is partitioned. Nitrogen is filled in the gas chamber 90 to press the rod 20 upward, that is, in a protruding direction, and may be moved to a contracted position in response to a force applied to the free end of the rod 20.

The sealing unit 40 is installed on the upper end side of the cylinder 12 to seal the gas chamber 90 and maintain airtightness with the rod 20 of the piston, and is provided on the inner circumferential surface of the end side of the cylinder 12. The bushing member 43 is installed in the hollow portion on the end side of the cylinder in which the first inlet groove 41 is formed and the first inlet groove 41 is formed. In addition, a through hole 42 through which the rod 20 penetrates is formed in the bushing member 43. On the outer circumferential surface of the bush member 43, a second inlet groove (not shown) is formed in a portion corresponding to the first inlet groove, and a snap ring (or O-ring) is inserted into the second inlet groove. In addition, a piston seal 31 for airtightness may be installed between the outer circumferential surface of the piston 30 and the inner circumferential surface of the cylinder 12.

An end cap sealing portion 50 may be formed between the lower outer peripheral surface of the end cap 13 and the inner peripheral surface of the cylinder 12. The end cap sealing portion 50 is formed with at least one packing insertion groove 51 that is drawn in and formed along the outer circumferential surface of the insertion portion 22, and a packing 52 is installed in the packing insertion groove 51.

And, the end cap 13 is formed with a valve cavity 60 in communication with the gas chamber 90 on the central side. The valve cavity 60 is in communication with the gas chamber 90 and is provided with a valve mounting portion 61 on which a gas filling valve unit to be described later is mounted, and a gas injection portion 63 for injecting gas into the valve mounting portion 61 side. . The upper end 64 side of the gas injection portion 63 communicating with the valve mounting portion 61 is formed to have a smaller inner diameter than the lower portion to support one side of the check valve member 100 or the valve body 71 to be described later. A thread is formed on the inner circumferential surface of the valve mounting portion 61 for screwing with the valve body 71 to be described later.

Unlike the illustrated valve cavity 60, the valve mounting portion 61 and the gas injection portion 63 may be formed to have the same diameter without a stepped configuration, or may be formed on the side of the cylinder 12. In addition, the valve cavity 60 is not limited to the above-described structure, and any structure can be used as long as the gas filling valve unit 70 can be mounted.

In addition, the structure of the gas spring 1 is limited to what is shown if the gas chamber 90 is formed therein, the gas chamber 90 communicates with the gas filling valve unit 70, and the valve cavity is formed. Does not work.

On the other hand, the gas filling valve unit 70 is installed in the valve mounting portion 61 of the valve cavity 60 to open the gas chamber 90 during gas filling, and check to close the gas chamber 90 when gas filling is completed As a valve structure, a valve body 71, a check valve member 100, and a pressing member 80 are provided.

The valve body 71 is formed with a screw thread on the outer circumferential surface, is mounted on the valve mounting portion 61, one side communicates with the gas injection portion 63 through which gas is injected, and the other side communicates with the gas chamber 90 inside space 72 ). The inner space 72 of the valve body 71 is opened on both sides to the gas chamber 90 side and the gas injection portion 63, and the open side of the inner space is expanded to the outer diameter of the check valve member 100 to be described later. It has an inner diameter corresponding to the outer diameter of the portion 121 and the hermetic member 130, and the other side opened has an inner diameter capable of penetrating the first stem portion 111 of the check valve member 110. However, the valve body 71 is different from that shown, one side of the inner space supports the second stem portion 116 of the check valve member 110 and restrains the outer diameter expansion portion 121 and the hermetic member 130 In order to be able to do so, the outer diameter expansion portion 121 and the hermetic member 130 may be opened through a smaller diameter.

The check valve member 100 is slidably installed in the internal space 72 of the valve body 71, and is actuated by the gas pressure in the gas chamber 90 or by the pressurizing member 80 to the gas injection part 63 side. The valve cavity 60 is positioned to close.

The check valve member 100 includes a sliding movable body 110 and an airtight member 130.

The sliding movable body 110 is slidably movable within the valve body 71, and the first stem part 111 having a round bar shape supported through the other end of the valve body 71 communicating with the gas chamber 90 , The first stem portion 111 and the second stem portion 116 which is located on the same line with each other and supported by the end cam 13 and extends in a direction parallel to the first stem portion 111 and the first It connects the stem portion 111 and the second stem portion 116 and has an outer diameter larger than the first and second stem portions 111 and 116, and is pressurized toward the gas injection portion 63 by the pressing member 80. It is provided with an outer diameter expansion unit 121.

The first stem part 111 and the second stem part 116 extend in a direction away from the center of the other surface and one surface of the outer diameter expanding part 121. The second stem portion 116 is formed so that the end toward the gas injection portion 63 side is easily tapered into the upper portion 64 of the gas injection portion, and constrains the airtight member at a spaced apart position from the outer diameter expansion portion. For the restraint jaw 118 is formed.

The hermetic member 130 is formed of a material that can be elastically deformed by the pressure in the pressing member 80 or the gas chamber 90, and the outer diameter is extended to move with the sliding moving body 110 toward the gas injection part 63 side. It is integrally coupled to one surface of the part 121.

The hermetic member 130 is in close contact with the stepped portion formed between the valve mounting portion 61 of the valve cavity 60 and the upper end portion of the gas injection portion 63 to seal the gas chamber 90. Unlike the illustrated case, when one end of the valve body 71 is penetrated with an inner diameter smaller than the outer diameter extension, the hermetic member 130 is in close contact with the inner circumferential surface of the valve body 71 to seal the gas chamber 90. .

The hermetic member 130 is formed in a circular shape corresponding to the outer diameter expansion portion so as to cover one surface of the outer diameter expansion portion 121, and a stem through hole 132 through which the second stem portion 116 penetrates is formed.

The hermetic member 130 may be formed of a synthetic resin material such as rubber or urethane, which is stretchable by external force, and may be integrally combined with the outer diameter expansion unit 121 by being heat-sealed to the outer diameter expansion unit 121. Alternatively, although not shown, an engaging groove is formed in the outer diameter expanding portion 121 and an engaging projection (not shown) coupled to the engaging groove is formed on one surface of the hermetic member 130 facing the outer diameter expanding portion 121, The outer diameter expansion unit 121 and the hermetic member 130 may be coupled to each other.

On the other hand, the restraining jaw 118 of the second stem portion 116 is easy to move the restraining jaw 118 when the stem through hole 132 of the hermetic member 130 is expanded when the hermetic member 130 is mounted, A tapered portion 119 whose outer diameter extends from one end of the second stem portion 116 toward the first stem portion 111, and a constant outer diameter in the direction of the second stem portion 116 at one end of the tapered portion 119 It has a constraining portion 120 for constraining the hermetic member 130 coupled to the outer diameter expansion portion 121.

The pressing member 80 is accommodated in the valve body 71 to elastically press the check valve member 100 toward the gas injection portion 63 side. The pressing member 80 is applied with a spirally extended coil spring, and the first stem portion 111 penetrates inward. One side of the pressing member 80 is in contact with the other surface of the outer diameter expansion portion 121, and the other side is in contact with the other inner circumferential surface of the valve body 71.

The gas filling valve unit 70 with improved gas tightness according to the first embodiment of the present invention and the gas spring using the gas tight member 130 are integrally coupled to the sliding movable body 110 movable within the valve body 71 Since the area in contact with the valve body 71 or the valve cavity 60 is constantly secured to close the gas chamber 90, stable airtightness can be provided.

In addition, the gas filling valve unit 70 with improved airtightness according to the first embodiment of the present invention and the gas spring using the same are formed such that the airtight member 130 corresponds to the outer diameter expansion portion 121 of the sliding moving body 110. Since the uniform sliding area is secured in the circumferential direction around the sliding moving body 110, the airtightness can be stably maintained.

Meanwhile, FIG. 3 shows a check valve member 200 according to a second embodiment of the present invention. Components having the same function as in the above-described drawings are denoted by the same reference numerals.

The check valve member 200 according to the second embodiment of the present invention is formed of a material that can be elastically deformed by the gas pressure of the pressurizing member 80 or the gas chamber 90, and the outer diameter expansion unit 121 coupled with each other A cover layer 140 surrounding the hermetic member 130 is further provided.

In the check valve member 200 according to the second embodiment of the present invention, the coupling force between the outer diameter expanding portion 121 and the hermetic member 130 may be improved by the cover layer 140.

Meanwhile, FIGS. 4 to 6 illustrate a gas filling valve unit according to a third embodiment of the present invention and a gas spring using the same. Components having the same function as in the above-described drawings are denoted by the same reference numerals.

The gas filling valve unit according to the third embodiment of the present invention and the gas spring using the same are the same as the structure of the gas filling valve unit according to the first embodiment of the present invention and the gas spring using the gas spring except for the airtight member 330 Do.

The airtight member 330 is formed with a stem through hole 132 at the center and a ring-shaped airtight member body 331 formed to correspond to the outer diameter expansion unit 121; It is provided with an auxiliary machine mill (336) protruding from the side of the airtight member body (331) and extending along the circumferential direction.

The auxiliary machine mill 336 protrudes along the circumferential direction on the outer circumferential surface of the hermetic member body 331 and extends toward the other end side of the valve body 71.

The auxiliary machine mill 336 extends in the direction away from the gas-tight member 90 by the gas pressure of the gas chamber 90 to contact the inner circumferential surface of the valve body 71, and through the gas injection part 63 It is in close contact with the airtight member body 331 by the gas pressure introduced during gas filling.

While the auxiliary machine mill 336 is in contact with the inner circumferential surface of the valve body 71, between the hermetic member body 331 and the valve body 71 of the hermetic member 330, that is, the auxiliary hermetic space around the hermetic member body 331 It is formed. The auxiliary enclosed space is opened while the end of the auxiliary machine mill 336 is in contact with the main body 331 by the gas inlet pressure when filling the gas through the gas injection part 63.

The gas filling valve unit and the gas spring using the gas filling valve according to the third embodiment of the present invention further improve airtightness because a plurality of contact portions are formed on the valve body 71 by the airtight member body 331 and the auxiliary machine mill 336 It has the advantage of being.

Meanwhile, FIG. 7 shows a gas filling valve unit according to a fourth embodiment of the present invention and a gas spring using the same. Components having the same function as in the above-described drawings are denoted by the same reference numerals.

The gas filling valve unit and the gas spring using the gas filling valve according to the fourth embodiment of the present invention except that the first groove 231 is formed in the hermetic member and the auxiliary hermetic member 260 having the second groove is further provided. And the same as the structure of the gas filling valve unit and the gas spring using the same according to the first embodiment of the present invention.

The hermetic member 230 is formed with a first groove 231 extending in a radial direction away from the second stem portion 116 from the center side on one surface facing the gas injection portion 63.

The first groove 231 is drawn in the gas chamber 90 direction and extends in the circumferential direction with a first recess, and the gas injection portion 63 protrudes in the direction, and the first projection extending in the circumferential direction crosses and repeats radially. Is formed.

The auxiliary hermetic member 260 is formed in a ring shape having a central side through which the second stem portion 116 can be penetrated, and a second groove 261 is formed on a surface facing the hermetic member 230.

The auxiliary hermetic member 260 is formed of an elastic material such as elastic rubber and urethane while being in close contact with the hermetic member 230, and may be coupled to the end cap 13 by heat fusion.

The second groove 261 has a second protrusion protruding in the direction of the gas chamber 90 corresponding to the first recess, and a second concave groove introduced in the direction of the gas injection part 63 corresponding to the first protrusion. .

The gas filling valve unit according to the fourth embodiment of the present invention and the gas spring using the gas tight member 230, when the airtight member 230 is in close contact with the stepped portion formed by the valve mounting portion 61 and the gas injection upper portion 61, the first Since the groove 261 is molded to the second groove 261, the contact area can be secured more widely, and airtightness can be improved.

On the other hand, unlike the illustrated, the gas filling valve unit according to the fourth embodiment of the present invention and the gas spring using the same, without the auxiliary hermetic member 260, the second groove has a valve mounting portion 61 and a gas injection upper portion 61 It may be applied to be formed on the stepped portion formed by ). Alternatively, when one end of the valve body 71 is formed through an inner diameter smaller than the hermetic member 230, the second groove may be formed on one inner circumferential surface of the valve body 71.

The gas filling valve unit having improved airtightness according to an embodiment of the present invention and the gas spring using the gas airtight member are integrally coupled to the sliding movable body 110 movable within the valve body 71 so that the gas chamber 90 ), the area in contact with the valve body 71 or the valve cavity 60 is secured to close, thereby providing stable airtightness.

In addition, the gas filling valve unit having improved airtightness according to an embodiment of the present invention and a gas spring using the gas tightness member are formed such that the airtight member is formed to correspond to the outer diameter expansion portion 121 of the sliding mobile body 110, and thus the sliding mobile body 110 A uniform contact area is secured in the circumferential direction around the center, so that airtightness can be stably maintained.

The present invention has been described with reference to one embodiment shown in the drawings, but this is merely exemplary, and those skilled in the art will understand that various modifications and equivalent embodiments are possible therefrom.

Therefore, the true protection scope of the present invention should be defined only by the appended claims.

12: cylinder 13: end cap
30: piston 20: rod
60: valve cavity 70: gas filling valve unit
71: valve body 80: pressing member
100: check valve member 110: sliding mobile body
111: first stem part 116: second stem part
121: outer diameter extension 130: airtight member
140: cover layer

Claims (6)

delete delete delete delete A cylinder having a hollow portion for forming a gas chamber in the longitudinal direction;
And the end cap is coupled to the lower end of the cylinder to seal the lower portion of the hollow;
A piston inserted into the hollow portion of the cylinder and having a rod;
It is coupled to a valve cavity communicating with the gas injection portion formed in the end cap to open the gas chamber during gas filling, and a gas filling valve unit for closing the gas chamber after gas filling is completed.
The gas filling valve unit
It is mounted on the valve cavity, the valve body having an internal space communicating with the gas chamber and the gas injection part, and is slidably installed in the interior space of the valve body, the gas injection by the action of the gas pressure in the gas chamber A check valve member for moving the end of the valve body on one side or one side of the valve cavity to be closed, and a pressing member for elastically biasing the check valve member to the gas injection side in the valve body,
The check valve member
A sliding movable body mounted slidably within the valve body and having an outer diameter expansion portion elastically pressurized toward the gas injection portion by the pressing member;
It is formed of a material that is elastically deformable by the pressure in the pressurizing member or the gas chamber, and is integrally coupled to the sliding movable body so as to face the gas injection part, but the valve body or the valve cavity to close the gas chamber. It is provided with a gas-tight member that covers the entire surface of the outer diameter expansion portion toward the gas injection portion to ensure a constant contact area to be in contact with the gas injection portion or one end of the valve body;
The sliding mobile body
A first stem part supported through the other end of the valve body on the gas chamber side and connected to the center of the other surface of the outer diameter expansion part, and one end of the cylinder, the end cap, or the valve body at the same line position of the first stem part It is supported on the portion and extends in a direction parallel to the first stem portion and has a second stem portion connected to the center of one surface of the outer diameter expansion portion,
A first groove extending radially away from the second stem portion on one surface of the hermetic member facing the inner circumferential surface of one end of the valve body or the inner circumferential surface of the valve cavity;
It is formed on the inner circumferential surface of one end of the valve body or the inner circumferential surface of the valve cavity, or is formed on a surface facing the airtight member of the auxiliary hermetic member mounted between the airtight member and one side of the inner space of the valve body or one side of the valve cavity. Gas spring characterized in that it further comprises a second groove that can be molded to the first groove. delete

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