JP6116314B2 - Seal unit, unit structure, and gas stopper - Google Patents

Description

  The present invention provides a gas stopper tip member having a gas outlet end and having a valve body inside which closes or opens the gas outlet end, and a gas outlet passage connected to the gas outlet end on the upstream side. The present invention relates to a seal unit, a unit structure, and a gas stopper that can be attached to a gas stopper including a main body.

Conventionally, as a gas stopper, a slide valve that moves between an open position for opening the gas flow passage and a closed position for closing the gas flow passage is provided inside the gas flow passage, and allows gas to flow out from the gas flow passage. One that switches between a state and a stopped state is known (see Patent Document 1).
In the gas stopper, the state of stopping the outflow of gas from the gas flow passage is realized by a seal between the inner peripheral surface of the gas flow passage and the outer peripheral surface of the slide valve.

  In addition, as another structure of the gas plug, as shown in FIG. 6 of the said patent document 1, it does not open and close a gas plug by mounting | wearing / non-wearing of the gas connection tool 100, but the operation part provided in the gas plug The gas stopper is opened and closed by pressing B. There is a so-called push-push type gas stopper.

JP 2012-207780 A

In the technology disclosed in Patent Document 1, since the outflow of gas from the gas flow passage is stopped only by the seal between the inner peripheral surface of the gas flow passage and the outer peripheral surface of the slide valve, for example, the slide valve Is moving from the open position to the closed position, and if foreign matter is caught between the inner peripheral surface of the gas flow passage and the outer peripheral surface of the slide valve, the gas may leak from the gas flow passage. there were.
For this reason, there has been a demand for a technique that can improve the closure of the gas flow passage more reliably in the existing gas stoppers.
Furthermore, it has been desired to obtain a unit structure capable of easily and simply constructing such a gas stopper.

  The present invention has been made in view of the above-described problems, and an object of the present invention is to provide a sealing unit and a unit structure that can more reliably prevent the outflow of gas from a gas stopper in a closed state in a conventional gas stopper. The point is to provide a body and a gas stopper.

The seal unit for achieving the above object is:
A gas stopper front end member having a gas outlet end and a valve body inside which closes or opens the gas outlet end; and a gas stopper base end member having a gas flow passage connected to the gas outlet end on the upstream side; A seal unit that can be attached to a gas stopper comprising :
An opening connecting the upstream side and the downstream side of the gas flow path in the partition wall provided with a upstream side and a downstream side and the partition wall separating the pre SL gas flow path provided,
A cylindrical housing that can be attached to the gas plug distal end member or the gas plug proximal end member and that disposes the partition wall in the gas flow passage ,
In response to the movement of the valve body between a closed position for closing the gas outflow end and an open position for opening, a switching member for switching between a closed state for closing the opening and an open state for opening is provided. is there.

According to the above characteristic configuration, the opening connecting the upstream side and the downstream side of the gas flow passage is in a closed state and an open state corresponding to the movement of the valve body between the closed position and the open position of the gas outflow end. Since the seal unit including the switching member to be switched to is configured to be attachable to the gas stopper tip member or the gas stopper base end member, by attaching the seal unit, in addition to closing the gas outlet end by the plug body, By closing the opening by the switching member, it is possible to prevent the gas from flowing through the gas flow passage.
As a result, it is possible to more reliably prevent the gas from flowing out from the gas stopper in the closed state by attaching the seal unit to the existing gas stopper.

Further features of the seal unit of the present invention are as follows:
The partition wall has an upstream gas inflow portion on the outer peripheral surface as the opening located on the upstream side of the gas flow passage and a downstream gas outflow portion located on the downstream side of the gas flow passage. Is a member,
The cylindrical member has the cylindrical axis aligned in the gas flow direction of the gas flow passage, and all of the gas flowing through the gas flow passage flows from the upstream gas inflow portion and the downstream. Prepare in a state of flowing out from the side gas outflow part,
The switching member is slidable along the outer peripheral surface of the cylindrical member, and corresponds to the movement of the valve body between a closed position for closing the gas outflow end and an open position for opening the gas outlet end. Te is that a can exchange off the upstream gas inlet in the closed state and the open state.
Here, the outer peripheral surface of the cylindrical member means an outer surface excluding both end surfaces of the cylindrical member.

  According to the above characteristic configuration, the partition wall is configured by the cylindrical member having the upstream gas inflow portion on the outer peripheral surface thereof, and the cylindrical axis of the cylindrical member is aligned with the gas flow direction of the gas flow path. By moving the switching member to slide between the outer peripheral surface of the cylindrical member and switch the upstream gas inflow portion between the closed state and the open state, the gas flow direction of the gas flow passage is changed. Can be along. Then, by connecting the switching member to a valve body that moves in a direction along the gas flow direction of the gas flow passage, the switching member can be switched between the closed state and the open state of the upstream gas inflow portion. It can be made to correspond to a closed state and an open state.

Further features of the seal unit of the present invention are as follows:
The tubular member is provided with either an excessive outflow prevention valve for preventing excessive outflow of gas or a pressure detecting plug for detecting gas pressure.

  According to the above characteristic configuration, since the overflow prevention valve or the pressure detection plug can be provided inside the cylindrical member having the function of opening and closing the gas flow passage, the tubular member is connected to the overflow prevention valve or the pressure detection pressure. It can also be used as a plug housing.

Further features of the seal unit of the present invention are as follows:
It exists in the point which can be connected with the said gas stopper base end member via the said gas stopper front end member.

  That is, the seal unit of the present invention is configured to be connectable to the gas plug base end member via the gas plug front end member, so that the seal unit is provided in the gas flow passage formed inside the gas plug base end member. Can be easily arranged.

  The seal unit of the present invention may be configured such that the gas plug tip member and the gas plug base end member can be connected to each other via itself.

  The gas stopper provided with the seal unit described so far can be effectively used as a gas stopper that can more reliably prevent the outflow of gas in the closed state.

  Further, if the sealing unit described so far is a unit structure in which a gas plug tip member is connected, the unit structure is attached to a gas plug base end member of a gas plug that has been conventionally provided. Gas leakage in the closed state can be prevented more reliably.

Sectional drawing which shows the state which has removed the gas connector from the gas stopper which concerns on 1st Embodiment Sectional drawing which shows the state which has mounted | wore the gas connector which concerns on 1st Embodiment with the gas connector The perspective view of each member provided in a gas flow passage Sectional drawing which shows the state which has removed the gas connector from the gas stopper which concerns on 2nd Embodiment Sectional drawing which shows the state which has mounted | wore the gas connector which concerns on 2nd Embodiment with the gas connector Transition diagram showing operation of gas plug according to second embodiment Sectional drawing which shows the state which has removed the gas connector from the gas stopper which concerns on another embodiment Sectional drawing which shows the state which has equipped the gas stopper which concerns on another embodiment with the gas connector

  The seal mechanism S (an example of a seal unit), a unit structure, and a gas stopper 200 according to the present invention relate to a gas stopper 200 that can more reliably prevent outflow of gas in the closed state of the gas stopper 200 shown in FIG.

As shown in FIGS. 1 and 2, the gas stopper 200 has a first gas flow path part 1 a having the gas outflow end 3 as a tip part, and closes and opens the first gas flow path part 1 a ( A gas plug tip member 4 having an example of a valve body therein and a gas plug main body 2 having a second gas flow path portion 1b communicating with the first gas flow path portion 1a on the upstream side are provided.
Hereinafter, a flow path that is a combination of the first gas flow path part 1 a and the second gas flow path part 1 b is referred to as a gas flow path 1.
The gas plug 200 is connected to the gas connector 100 by opening the gas flow passage 1 by attaching the gas connection device 100 to the gas plug 200 (the state shown in FIG. 2), and flowing the gas through the gas flow passage 1. Gas is supplied to a gas appliance (not shown), and the gas connector 100 is removed from the gas plug 200 (in the state shown in FIG. 1), whereby the gas flow passage 1 is closed and the gas flow in the gas flow passage 1 is performed. This is configured as a so-called gas outlet that stops gas supply to the gas appliance.
Hereinafter, first, the gas connector 100 that can be attached to and detached from the gas stopper 200 will be described. Since the gas connector 100 has a known configuration, a detailed description thereof will be omitted and will be briefly described.

  In the gas connector 100, the positions of the protruding member 102, the locking ball 103, and the locking ball 103 urged forward by the first coil spring 101 (the base end side of the arrow X in FIGS. An inner diameter member 104 that regulates from the inner side of the direction and that is pressed against the gas stopper tip member 4 and retracts is provided, and a rod-like pressing portion 105 that presses the slide valve G when the gas stopper 200 is attached. ing.

  When the gas connector 100 is attached to the gas stopper 200, as shown in FIGS. 1 and 2, the gas stopper tip member 4 abuts against the inner diameter member 104, and the inner diameter member 104 is resisted against the biasing force of the second coil spring 106. Retire. When the inner diameter member 104 is retracted, the locking ball 103 moves inward in the radial direction, the locking ball 103 is fitted into the fitting groove 2a formed in the gas plug tip member 4, and the protruding member 102 is the first coil spring. It protrudes to the front side (the base end side of the arrow X in FIGS. 1 and 2) by the urging force of 101. In this manner, the gas connector 100 is externally attached to the gas stopper 200. When the gas connector 100 is attached to the gas stopper 200, the slide valve G is pressed by the pressing portion 105 of the gas connector 100. The slide valve G is moved to the upstream side of the gas flow passage 1 (the base end side of the arrow X in FIGS. 1 and 2) along the gas flow direction of the gas flow passage 1 by the pressure on the slide valve G by the pressing portion 105. Then, it moves from the closed position (position shown in FIG. 1) to the open position (position shown in FIG. 2), and the gas flow passage 1 is opened to supply gas to the gas appliance.

  When removing the gas connector 100 from the gas stopper 200, the protruding member 102 is pushed against the urging force of the first coil spring 101 (pushing toward the tip side of the arrow X in FIGS. 1 and 2). Since the fitting of the locking ball 103 into the insertion groove 2 a is released, the gas connector 100 can be removed from the gas stopper 200. Then, when the gas connector 100 is removed from the gas stopper 200, the pressing by the pressing portion 105 against the slide valve G is released, and the slide valve G is caused to flow through the gas flow passage 1 by the biasing force of the first biasing member F1. It moves to the downstream side of the gas flow path 1 along the direction (the tip end side of the arrow X in FIG. 2), the slide valve G is returned from the open position to the closed position, and the gas flow path 1 is closed.

  In the gas flow passage 1 of the gas stopper 200, as shown in FIGS. 1, 2, and 3, a seal mechanism S for closing the gas flow passage 1 of the gas stopper 200 and the slide valve G described above are described from the upstream side. Are provided in this order.

  When the explanation is added, the unit U having the seal mechanism S inside is configured to be screwed to the inner peripheral surface of the upstream end (the base end side of the arrow X in FIGS. 1 and 2) of the gas plug tip member 4. The gas plug base end member 4 is disposed in the second gas flow path portion 1b of the gas plug base end member 5 with the unit U screwed and connected to the gas plug front end member 4 itself. 5 is screwed together.

The unit U has a downstream opening U1a that communicates with the first gas flow path portion 1a at the downstream end (the tip end side of the arrow X in FIGS. 1 and 2), and an upstream opening U1b on the outer peripheral surface thereof. The housing U1 has a shape.
The housing U1 includes a male screw portion U1c formed on the outer peripheral surface on the downstream side, and the male screw portion U1c is airtight to the female screw portion U1d formed on the inner peripheral surface of the upstream end of the gas plug tip member 4. Threaded onto. Thereby, all the gas which flows through the gas flow path 1 flows in from the upstream opening part U1b of the housing | casing U1, and flows out out of the downstream opening part U1a.

The casing U1 has an upstream gas inflow portion S1a (an example of an opening) located on the upstream side of the gas flow passage 1 on the outer peripheral surface and a downstream gas located on the downstream side of the gas flow passage 1. A cylindrical member S1 (an example of a wall) having an outflow part S1b (an example of an opening) is provided.
Here, the cylindrical member S1 has an upstream gas inflow portion S1a facing the upstream opening U1b on the outer peripheral surface of the casing U1, and a downstream gas outflow portion S1b of the casing U1. It is screwed and connected to the housing U1 in a state of facing the portion U1a. Thereby, the pressure loss of the gas flowing through the gas flow passage 1 is reduced. Here, the outer peripheral surface of the cylindrical member S1 means an outer surface excluding both end surfaces of the cylindrical member S1.
In addition, the cylindrical member S1 is provided in a direction in which the cylindrical axis is along the gas flow direction of the gas flow passage 1 (the arrow X direction in FIGS. 1 and 2).
On the outer side of the cylindrical member S1, a switching member S2 that slides along the outer peripheral surface is urged to the downstream side (the tip side of the arrow X in FIGS. 1 and 2) by the third urging member F3. And the downstream end of the slide valve G is in contact with the upstream end. As a result, the switching member S2 moves upstream of the cylindrical member S1 in response to the movement of the slide valve G between the closed position (position shown in FIG. 1) and the open position (position shown in FIG. 2). It is configured to be switchable between a closed state in which the inflow portion S1a is closed and an open state in which the inflow portion S1a is opened.
That is, the cylindrical member S1 and the switching member S2 function as a sealing mechanism S that more reliably prevents the outflow of gas when the gas flow passage 1 is closed.

  The housing U1 is provided with a sliding ball U1f that fits into a recessed portion U1e formed on the inner periphery thereof. The sliding ball U1f abuts on the outer peripheral surface of the switching member S2, and functions to smoothly slide along the outer peripheral surface of the tubular member S1 of the switching member S2.

The slide valve G is a valve that is movable between a closed position (position shown in FIG. 1) for closing the first gas flow path portion 1a of the gas plug tip member 4 and an open position (position shown in FIG. 2). A body part G1 and an annular sliding part G2 that is connected to the valve body part G1 by a shaft part and is slidable along the inner peripheral surface of the first gas flow path part 1a are provided.
The sliding part G2 has a ring-shaped sealing member G4 along the outer peripheral surface thereof, and the flow of gas between the outer peripheral surface and the first gas flow path part 1a is prevented. Further, the sliding portion G2 is fitted into a gap 1c (shown in FIG. 2) formed between the casing U1 of the unit U and the cylindrical member S1 when the valve body portion G1 is located at the open position. The outflow of gas from the gap 1c to the downstream side is prevented.

Second Embodiment
The gas stopper 200 of the second embodiment includes an overflow prevention mechanism H that prevents gas flow when the gas flow rate flowing through the gas flow passage 1 exceeds a certain level, and an overflow prevention mechanism H that is in an operating state. A reset means R for resetting to a non-operating state is provided.
Hereinafter, the same reference numerals are given to the same configurations as those in the first embodiment, and the description thereof is omitted.

As shown in FIGS. 4, 5, and 6, the tubular member S <b> 1 has an inoperative state (a state shown in FIGS. 6 (a) and 6 (b)) that allows gas flow and an operational state that prevents the gas flow ( An overflow prevention valve H2 that is switchable between the state shown in FIG. 6C and a support portion H4 that slidably supports the overflow prevention valve H2 in the gas flow direction of the gas flow passage 1 are provided. ing.
The support portion H4 is formed in a cylindrical shape whose inside penetrates in the gas flow direction of the gas flow passage 1. The upstream portion of the support portion H4 is fitted on the shaft portion H2a of the overflow prevention valve H2, and supports the overflow prevention valve H2 so as to be movable in the gas flow direction of the gas flow passage 1.

The excessive outflow prevention valve H2 is in an inoperative state (FIGS. 6A and 6B) positioned upstream from the operating state (the state shown in FIG. 6C) positioned on the downstream side by the second urging member F2. The state shown in FIG. 2 is urged so as to return to the state, and is held in a non-operating state by abutting against the support portion H4. The overflow prevention valve H2 is provided so as to freely shift from the non-operating state to the operating state by the flow pressure of the gas flow rate when the gas flow rate becomes an overflow rate, and the overflow preventing valve that has shifted to the operating state is provided. The valve H2 is fitted in a fitting opening G3 provided on the upstream side of the slide valve G to prevent gas flow.
The overflow prevention valve H2 in the operating state is excessively discharged to the fitting opening G3 as the slide valve G moves from the open position to the closed position (movement from FIG. 6C to FIG. 6D). The fitting of the prevention valve H2 is released, and the second urging member F2 is urged to return to the upstream side, thereby resetting to the non-operating state (the state of FIG. 6D) located on the upstream side.
That is, in the present invention, the fitting opening G3 of the slide valve G and the first urging member F1 that urges the slide valve G from the open position to the closed position function as the reset means R.

The slide valve G is a valve that is movable between a closed position (position shown in FIG. 4) for closing the first gas flow path portion 1a of the gas plug tip member 4 and an open position (position shown in FIG. 5) for opening. In addition to the body part G1 and the annular sliding part G2 which is connected to the valve body part G1 by a shaft part and is slidably movable along the inner peripheral surface of the first gas flow path part 1a, the sliding part And a fitting opening G3 that is formed at the inner diameter portion of the portion G2 and into which the overflow prevention valve H2 is fitted.
Thereby, when the valve body G1 is located at the open position (position shown in FIG. 4), all of the gas flowing through the gas flow passage 1 passes through the fitting opening G3. In this state, when the gas flow rate exceeds a certain level, as shown in FIG. 5, the overflow prevention valve H2 is fitted into the fitting opening G3, and the gas from the fitting opening G3 to the downstream side is fitted. Is prevented from flowing out.

Hereinafter, the operation of the slide valve G, the excessive outflow prevention mechanism H, and the reset means R will be described with reference to FIG.
6A shows a state in which the gas connector 100 is removed from the gas stopper 200, and FIG. 6B shows a state in which the gas connector 100 is attached to the gas stopper 200. FIG. FIG. 6D shows a state in which the overflow prevention valve H2 has shifted from the non-operating state to the operating state when the gas connector 100 is attached to the gas stopper 200. FIG. This is a state where a reset operation is performed when the stopper 200 is removed.

As shown in FIG. 6A, when the gas connector 100 is removed from the gas stopper 200, the valve body G1 of the slide valve G is located at the closed position, and the gas flow passage 1 is connected to the valve body G1. It is closed by. Further, the switching member S2 closes the upstream gas inflow portion S1a formed on the outer peripheral surface of the cylindrical member S1 by the inner peripheral surface thereof.
That is, in the state shown in FIG. 6A, the gas flow passage 1 is located on the inner peripheral surface of the gas flow passage 1 of the valve body G1 and the outer side of the cylindrical member S1 by the inner peripheral surface of the switching member S2. It is securely closed by both the peripheral surface seal and the seal.
At this time, the excessive outflow prevention valve H2 is in an inoperative state separated from the fitting opening G3 of the slide valve G.

  As shown in FIG. 6 (b), when the gas connector 100 is attached to the gas stopper 200, the pressing portion 105 of the gas connector 100 presses the valve body G 1 of the slide valve G to the upstream side of the gas flow passage 1. Thus, the valve body G1 of the slide valve G moves from the closed position to the open position, and the gas flow passage 1 is opened. Accordingly, the sliding portion G2 of the slide valve G presses the switching member S2 to the upstream side of the gas flow passage 1, and the upstream gas inflow portion S1a is opened.

  As shown in FIG. 6 (c), when a certain amount or more of gas flows through the gas flow passage 1, the overflow prevention valve H2 that has been in an inoperative state is fitted into the fitting opening G3 of the slide valve G. Thus, the fitting opening G3 is closed, and an excessive outflow of gas is prevented.

In the state shown in FIG. 6C, when the gas connector 100 is removed from the gas stopper 200, as shown in FIG. 6D, the pressing portion 105 moves to the upstream side of the valve body G1 of the slide valve G. The pressure is released, and the valve body G1 of the slide valve G moves from the open position to the closed position.
Along with this, the pressure on the upstream side of the switching member S2 by the sliding portion G2 of the slide valve G is released, and the switching member S2 moves to a closing position where the upstream side gas inflow portion S1a of the cylindrical member S1 is closed.
Further, when the fitting opening G3 of the slide valve G moves to the downstream side (the tip end side of the arrow X in FIG. 6D), the fitting of the overflow prevention valve H2 to the fitting opening G3 is released. Then, the fitting opening G3 is opened, and a reset operation is performed to shift the overflow prevention valve H2 in the operating state to the non-operating state.

[Another embodiment]
(1)
As shown in FIGS. 7 and 8, the unit U including the seal mechanism S of the present invention includes a cylindrical axis of the gas plug tip member 4 (axis along the arrow X in FIGS. 7 and 8) and a gas plug base end member. 5 is configured to be attachable to the gas stopper 200 integrally formed with the cylinder axis (the axis along the arrow X in FIGS. 7 and 8) orthogonal to each other.
The unit U communicates the downstream opening U1a of the housing U1 with the first gas flow path portion 1a of the gas plug tip member 4 and the upstream opening U1b of the housing U1 of the gas plug proximal end member 5. 2 It is screwed and connected to the gas plug tip member 4 in a state of being opposed to and communicated with the gas flow path portion 1b.
Note that the internal structure of the unit U is not different from that of the first embodiment.

In the other embodiment, the excessive outflow prevention mechanism H is provided in the second gas flow path portion 1 b of the gas plug base end member 5. The reset member R that performs the reset operation of the excessive outflow prevention mechanism H is provided from the second gas flow path portion 1b to the upstream opening U1b of the housing U1.
As shown in FIG. 8, when the switching member S2 is not positioned while facing the upstream opening U1b of the housing U1, a part of the reset member R enters the upstream opening U1b. The excessive flow prevention valve H2 is separated.
On the other hand, as shown in FIG. 7, when the switching member S2 is positioned at a position facing the upstream opening U1b, the reset member R is pushed out of the upstream opening U1b by the switching member S2, and the overflow prevention valve H2 is pressed. Located in the position of the side. At this time, if the overflow prevention valve H2 is in an operating state, the overflow prevention valve H2 is reset to a non-operational state.

(3)
In the said embodiment, while showing the structure which equips the outer peripheral surface of cylindrical member S1 with upstream gas inflow part S1a, and equips the downstream end part of cylindrical member S1 with downstream gas outflow part S1b.
As another configuration of the cylindrical member S1, both the upstream gas inflow portion S1a and the downstream gas outflow portion S1b may be provided on the outer peripheral surface of the cylindrical member S1.

(4)
The gas plug distal end member 4 may be configured to be connected to the gas plug proximal end member 5 via the unit U.

(5)
Further, the gas stopper 200 of the present application can be applied to a push-push type gas stopper 200 as shown in FIG. 6 of Patent Document 1 shown in the related art.

(6)
The unit U having the seal mechanism S therein and the gas plug tip member 4 constituting the gas plug 200 may be configured as a unit structure.

  The gas plug of the present invention can be effectively used as a seal unit, a unit structure, and a gas plug that can more reliably close the gas flow passage in the existing gas plug.

1: Gas flow passage 3: Gas outflow end 4: Gas stopper tip member 5: Gas stopper base end member 200: Gas stopper G: Slide valve G3: Fitting opening H2: Overflow prevention valve R: Reset means S1: Cylinder -Shaped member S1a: upstream gas inflow portion S1b: downstream gas outflow portion S2: switching member U1: casing

Claims (7)

A gas stopper front end member having a gas outlet end and a valve body inside which closes or opens the gas outlet end; and a gas stopper base end member having a gas flow passage connected to the gas outlet end on the upstream side; A seal unit attachable to a gas stopper comprising :
An opening connecting the upstream side and the downstream side of the gas flow path in the partition wall provided with a upstream side and a downstream side and the partition wall separating the pre SL gas flow path provided,
A cylindrical housing that can be attached to the gas plug distal end member or the gas plug proximal end member and that disposes the partition wall in the gas flow passage ,
A seal unit comprising a switching member that switches between a closed state for closing the opening and an open state for opening corresponding to the movement of the valve body between a closed position for closing the gas outflow end and an open position for opening. . The partition wall has an upstream gas inflow portion on the outer peripheral surface as the opening located on the upstream side of the gas flow passage and a downstream gas outflow portion located on the downstream side of the gas flow passage. Is a member,
The cylindrical member has the cylindrical axis aligned in the gas flow direction of the gas flow passage, and all of the gas flowing through the gas flow passage flows from the upstream gas inflow portion and the downstream. Prepare in a state of flowing out from the side gas outflow part,
The switching member is slidable along the outer peripheral surface of the cylindrical member, and corresponds to the movement of the valve body between a closed position for closing the gas outflow end and an open position for opening the gas outlet end. Te, seal unit according to cut exchange El claim 1 wherein the upstream gas inlet in the closed state and the open state.   The seal unit according to claim 2, wherein either one of an excessive outflow prevention valve for preventing excessive outflow of gas and a pressure detecting plug for detecting gas pressure is provided inside the cylindrical member.   The seal unit according to claim 1, wherein the seal unit is configured to be connectable to the gas stopper base end member via the gas stopper tip member.   The seal unit as described in any one of Claims 1-3 comprised so that the said gas stopper front end member and the said gas stopper base end member can be connected via self.   A gas stopper comprising the seal unit according to any one of claims 1 to 5.   A unit structure in which the seal unit according to any one of claims 1 to 5 and the gas plug tip member are connected.

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