KR102398382B1 - Plug and plug structure - Google Patents

Abstract

A plug body portion (10) provided on the inner peripheral surface of the opening of the liquid storage container, and a siphon tube (20) connected to the plug body portion (10), wherein the plug body portion (10) is provided on the inner peripheral surface of the opening a first body portion 10a and a second body portion 10b integrally formed with the first body portion 10a and having a bottom surface portion 12 disposed on a plane intersecting the axis X1; , when the second body portion 10b is disposed in a state in which the sealing member is in contact with the bottom surface portion 12 , the inner space S1 of the liquid storage container and the inner space S2 of the plug 100 communicate with each other. To provide a plug (100) having a communicating portion (13).

Description

PLUG AND PLUG STRUCTURE {PLUG AND PLUG STRUCTURE}

The present invention relates to a plug installed in an opening of a liquid storage container and a plug structure having the same.

BACKGROUND ART There is known a conventional plug provided in a liquid storage container for containing a liquid such as a chemical used in semiconductor manufacturing (for example, refer to Patent Document 1).

In the plug disclosed in Patent Document 1, an outer plug is provided in an opening of a liquid storage container, a liquid discharge pipe is inserted in the outer plug, and an inner plug is provided in the outer plug.

In the plug disclosed in Patent Document 1, by arranging a packing between the flange portion of the outer plug and the lower end of the inner plug, the pipe is held and leakage is prevented. Therefore, when the inner plug is provided in the outer plug, the inner space of the liquid extraction pipe and the inner space of the liquid storage container do not communicate with each other.

However, when the gas accommodated in the liquid storage container increases due to a change in the environmental temperature of the liquid storage container accompanying transport or storage, the internal space of the liquid storage container is pressurized. In this case, when the inner plug is removed from the outer plug to use the liquid, there is a possibility that the liquid is ejected to the outside through the liquid ejection pipe.

JPH06-051200 U

The present invention has been made in view of such circumstances, and provides a plug and a plug structure having the same, which suppresses the problem that the liquid is ejected to the outside due to an increase in gas accommodated in the liquid storage container due to a change in the environmental temperature of the liquid storage container, etc. intended to provide

In order to solve the said subject, this invention employ|adopted the following means.

A plug according to one aspect of the present invention is a plug installed in a liquid storage container provided on an upper surface of a plug having an opening formed in a cylindrical shape along an axis, and a through hole extending along the axis while being provided on an inner circumferential surface of the opening is provided at the lower end a plug body formed thereon; and a siphon tube connected to the lower end of the plug body and extending along the axis to a bottom of the liquid container, wherein the plug body is provided on the inner circumferential surface of the opening and the a first body portion formed in a cylindrical shape along an axis, and a second body portion integrally formed with the first body portion and having a bottom surface disposed on a plane intersecting the axis, the second body portion; and a communicating portion for communicating the inner space of the liquid storage container and the inner space of the plug when the sealing member is disposed in contact with the bottom surface portion.

According to a plug according to one aspect of the present invention, in a state in which the plug body is provided on the inner circumferential surface of the opening of the liquid storage container, the sealing member is brought into contact with the bottom face of the second body of the plug body so that the flow path formed at the lower end of the plug body is closed. sealed By sealing the flow path, the liquid accommodated in the liquid storage container is prevented from being ejected to the outside through the siphon tube.

Further, according to the plug according to one embodiment of the present invention, since the second body portion has the communicating portion, the internal space of the liquid storage container communicates with the internal space of the plug even when the sealing member is placed in contact with the bottom surface portion. become in a state of being Therefore, even when the gas accommodated in the liquid storage container increases due to a change in the environmental temperature of the liquid storage container or the like, the pressure in the internal space of the liquid storage container and the pressure in the internal space of the plug are maintained at the same pressure. Thereby, the problem that the liquid accommodated in the liquid storage container is ejected to the outside through the siphon tube when the sealing of the flow path by the sealing member is canceled is suppressed.

In the plug according to one aspect of the present invention, the communicating portion includes a through hole extending along the axis, and extending on a plane intersecting the axis, one end communicating with the through hole, and the other end of the plug It is good also as a structure which has a communication groove|channel which communicated with the internal space.

By doing so, when the sealing member is placed in contact with the bottom face of the second body portion, it is possible to communicate the internal space of the liquid storage container with the internal space of the plug via the through hole and the communication groove. Thereby, the problem that the liquid accommodated in the liquid storage container is ejected to the outside through the siphon tube when the sealing of the flow path by the sealing member is canceled is suppressed. In addition, the communication portion can be formed by a relatively simple configuration of forming a through hole and a communication groove intersecting the through hole in the second body portion.

In the plug having the above configuration, the bottom face portion may have an endless annular protrusion extending around the axis line on an outer peripheral side of the through hole with respect to the axis line.

By doing so, when the sealing member is placed in contact with the bottom surface of the second body portion, an endless portion-shaped sealing region is formed on the outer peripheral side of the through hole communicating with the internal space of the liquid storage container. Accordingly, it is possible to reliably suppress the problem that the liquid flows out from the siphon tube or the liquid storage container.

In the plug according to one aspect of the present invention, the plug body portion and the siphon tube may be formed of a resin material, and the plug body portion and the siphon tube may be connected by welding the resin material. .

In this way, compared to the case where the plug body and the siphon tube are connected as separate members without welding through a sealing member or the like, the problem caused by the inflow and outflow of liquid or gas from the connecting portion of the plug body and the siphon tube is suppressed. can do.

A plug structure according to one aspect of the present invention includes the plug according to any one of the above, and a sealing portion having the sealing member provided on the inner peripheral surface of the first body portion and contacting the bottom surface portion to form a sealing region. .

According to the plug structure according to one aspect of the present invention, by providing the sealing portion on the inner peripheral surface of the first body portion of the plug, the sealing member and the bottom surface portion come into contact with each other to form a sealing region. By this sealing area, the problem that liquid flows out from a liquid storage container and a siphon tube to the outside is suppressed.

Further, in the state in which the seal region is formed, the internal space of the liquid storage container and the internal space of the plug are brought into communication. Therefore, even when the gas accommodated in the liquid storage container increases due to a change in the environmental temperature of the liquid storage container or the like, the pressure in the internal space of the liquid storage container and the pressure in the internal space of the plug are maintained at the same pressure. Thereby, the problem that the liquid accommodated in the liquid storage container is ejected to the outside through the siphon tube when the sealing of the flow path by the sealing member is canceled is suppressed.

In the plug structure according to one aspect of the present invention, a female screw is formed on an inner peripheral surface of the first body part, and an external thread is formed on an outer peripheral surface of the sealing part, and the first body part and the sealing part connect the male screw to the It may be connected by coupling with a female screw.

By doing in this way, the sealing part can be provided in the 1st body part by a comparatively simple operation of attaching the male thread formed in the outer peripheral surface of the sealing part to the female thread formed in the inner peripheral surface of the 1st main body part.

Advantageous Effects of Invention According to the present invention, it is possible to provide a plug and a plug structure having the same, which suppresses the problem that the liquid is ejected to the outside due to an increase in gas accommodated in the liquid storage container due to a change in the environmental temperature of the liquid storage container or the like.

1 is a block diagram showing a liquid supply system according to an embodiment of the present invention.
Fig. 2 is a partial longitudinal sectional view showing an opening of a liquid storage container in which a plug is installed;
Fig. 3 is a longitudinal sectional view of the plug shown in Fig. 2;
Fig. 4 is a plan view of the plug shown in Fig. 2 viewed from above.
FIG. 5 is a longitudinal sectional view of the sealing part of FIG. 2 .
Fig. 6 is a partial longitudinal sectional view showing the opening of the liquid storage container in which the socket is installed;
Fig. 7 is a longitudinal sectional view showing the plug and socket;
Fig. 8 is a longitudinal sectional view showing a plug and a socket;
Fig. 9 is a longitudinal sectional view showing a plug and a socket;
Fig. 10 is a partial longitudinal sectional view showing an opening of a liquid storage container provided with a plug in a modified example;

Hereinafter, a liquid supply system according to an embodiment of the present invention will be described with reference to the drawings.

The liquid supply system of this embodiment shown in FIG. 1 is a system that sucks the liquid accommodated in the liquid storage container 400 by a pump (not shown) and supplies it to a plurality of supply destination devices (not shown).

Here, the liquid in this embodiment is, for example, pure water and various chemical liquids used in the semiconductor manufacturing process of a semiconductor manufacturing apparatus.

When the liquid storage container 400 is transported to or stored in a factory where the semiconductor manufacturing apparatus is installed, there is a possibility that the environmental temperature becomes higher than when the liquid is contained therein. In this case, the gas accommodated in the liquid storage container 400 increases due to evaporation of the internal liquid or the like, and the internal space is pressurized. In addition, hydrogen peroxide water used as a chemical|medical solution is decomposed|disassembled into water and oxygen according to environmental temperature etc., for example. Therefore, when the liquid storage container 400 is sealed, the gas region of the internal space of the liquid storage container 400 is in a state pressurized by oxygen. In addition, even in a volatile chemical liquid or the like, the gas region of the internal space of the liquid storage container 400 is in a state pressurized by oxygen.

The liquid supply system of the present embodiment suppresses the liquid from being ejected from the liquid storage container 400 to the outside even when the internal space of the liquid storage container 400 is in a pressurized state.

As shown in FIG. 1 , a liquid storage container 400 included in the liquid supply system of the present embodiment includes a container body 410 formed in a cylindrical shape around an axis X2 and a container body 410 . It is provided on the upper surface (ceiling plate) and has an opening 420 and an opening 430 formed in a cylindrical shape around the axis X1.

As shown in FIG. 1 , the liquid supply system of the present embodiment includes a plug 100 and a sealing portion 200 provided in an opening 420 of a liquid storage container 400 . Further, the liquid supply system of the present embodiment includes a sealing stopper 300 provided in the opening 430 of the liquid storage container 400 .

In the liquid supply system of the present embodiment, when the liquid contained in the liquid storage container 400 is sucked and supplied to the supply destination device, the socket 500 is provided instead of the sealing part 200 . In addition, instead of the sealing stopper 300, another stopper (not shown) capable of supplying gas into the interior of the liquid storage container 400 is installed.

Hereinafter, the plug structure of this embodiment is demonstrated with reference to drawings.

2 and 3 , in the plug structure of the present embodiment, the plug 100 provided in the opening 420 of the liquid storage container 400 and the sealing part 200 provided in the plug 100 . ) is provided.

The plug 100 includes a plug body portion 10 installed on the inner circumferential surface of the opening 420 and a bottom portion 440 of the liquid storage container 400 (refer to FIG. 1 ) while being connected to the plug body portion 10 . It has an extended siphon tube (20). A flow path 11 extending along the axis X1 is formed inside the plug main body 10 , and is connected to a flow path 20a formed inside the siphon tube 20 .

The plug body portion 10 and the siphon tube 20 are each formed of a fluororesin material such as PFA (tetrafluoroethylene/perfluoroalkylvinyl ether copolymer) or a crystalline thermoplastic resin material such as HDPE (high density polyethylene). is formed by The plug body portion 10 and the siphon tube 20 are welded by melting the resin material of these connecting portions by ultrasonic waves. In addition, instead of melting the resin material by ultrasonic waves, the connecting portion of the plug body portion 10 and the siphon tube 20 may be welded by melting a welding rod formed of a resin material.

As shown in FIG. 3 , the plug body portion 10 includes a first body portion 10a formed in a cylindrical shape along an axis X1 and a bottom portion disposed on a plane orthogonal to the axis X1 . and a second body portion 10b having (12). The first body portion 10a and the second body portion 10b are integrally formed of a fluororesin material such as PFA or a crystalline thermoplastic resin material such as HDPE.

Male threads are formed on the outer peripheral surface of the first body portion 10a, and female threads are formed on the inner peripheral surface of the opening 420 . By fastening the male screw of the first body part 10a to the female screw of the opening part 420 , the first body part 10a is installed on the inner circumferential surface of the opening part 420 .

A female screw is formed on the inner circumferential surface of the first body portion 10a, and a male screw is formed on the outer circumferential surface of the sealing unit 200 . By fastening the male screw of the sealing part 200 to the female screw of the first body part 10a, the sealing part 200 and the first body part 10a are connected.

An O-ring 450 made of fluororubber or the like is provided on the inner peripheral surface of the opening 420 . When the first body portion 10a is installed on the inner circumferential surface of the opening 420 , the O-ring 450 and the first body portion 10a come into contact with each other, and a seal region extending in an endless shape around the axis X1 is formed. is formed Thereby, the problem that the liquid flows out from the gap between the plug body part 10 and the opening part 420 is suppressed.

As shown in Fig. 3, the second body portion 10b has a through hole 13a formed on the outer peripheral side of the flow path 11 with respect to the axis X1, and one end communicates with the through hole 13a and the other end The provisional plug 100 includes a communication portion 13 having a communication groove 13b that communicates with the internal space S2 of the plug 100 .

As shown in FIG. 3 , when the communication portion 13 is disposed in a state in which the sealing member 220 of the sealing portion 200 is in contact with the bottom surface portion 12 , the interior of the liquid storage container 400 . The space S1 communicates with the inner space S2 of the plug 100 .

3, the through hole 13a is formed so that it may extend along the axis line X1. In addition, as shown in the plan view of Fig. 4, the through-holes 13a are shaped to extend along the circumferential direction around the axis X1, and are formed in four places at intervals of 90 degrees around the axis X1. there is.

The communication groove 13b communicates with each of the through-holes 13a formed in the four places, and is formed in four places so as to extend in the radial direction centered on the axis X1 on a plane orthogonal to the axis X1. has been

In addition, although it is assumed that the through-hole 13a and the communication groove 13b are formed in 4 places in the circumferential direction around the axis line X1 in FIG. 3, even if it forms in arbitrary places, such as 2 places, 6 places, 8 places, good.

As shown in Fig. 3, in the bottom face portion 12 of the second body portion 10b, it has an endless portion shape extending around the axis X1 on the outer periphery side of the through hole 13a with respect to the axis X1. An annular projection 12a is formed. As shown in FIG. 2 , when the sealing member 220 of the sealing portion 200 is placed in contact with the bottom surface portion 12 , the axis line at the contact portion between the annular projection 12a and the sealing member 220 . (X1) An endless portion-shaped seal region extending around is formed. By this sealing area, the flow path 11 formed in the lower end of the plug body part 10 is sealed.

As shown in FIG. 5 , the sealing part 200 comes into contact with the body part 210 provided on the inner peripheral surface of the first body part 10a and the bottom surface part 12 of the plug body part 10 to seal it. A sealing member 220 defining an area is provided. The sealing member 220 is provided in the plug body part 10 so that the sealing surface 220a of an annular shape may be formed below.

The main body 210 has a protrusion 210a protruding downward from the sealing surface 220a of the sealing member 220 . The protrusion 210a is inserted into the recess 14 formed in the plug body 10 when the body 210 of the sealing part 200 is installed in the plug body 10 . By inserting the protrusion 210a into the concave portion 14 , the central axis of the body portion 210 of the sealing portion 200 can easily coincide with the central axis of the plug body portion 10 of the plug 100 .

In addition, even when the protrusion 210a of the sealing portion 200 is inserted into the concave portion 14 of the plug body portion 10 , a minute gap is provided between the outer peripheral surface of the protrusion 210a and the inner peripheral surface of the concave portion 14 . to be in a state Therefore, even when the sealing part 200 is installed in the plug 100 , the internal space S1 of the liquid storage container 400 and the internal space S2 of the siphon tube 20 of the plug 100 are , a state of communication through the communication unit 13 is maintained. Therefore, even when the internal space S1 of the liquid storage container 400 is pressurized due to a change in environmental temperature or the like, the pressure of the internal space S1 and the internal space S2 of the siphon tube 20 are at the same pressure. is maintained as

Next, a description will be given of the socket 500 provided in the opening 420 instead of the sealing portion 200 when the liquid contained in the liquid storage container 400 is sucked and supplied to the supply device.

As shown in FIG. 6 , the socket 500 includes a socket body 510 formed in a cylindrical shape extending along an axis X1 and a cylindrical shape extending along the axis X1 while simultaneously forming a socket. An installation nut 520 disposed to surround the main body 510, an O-ring 530 installed on the outer circumferential surface of the socket body 510, and a fastening bolt on the upper side of the socket body 510 are fastened. It includes flange portions 540 and 550 , a sealing member 560 , a lower end portion 570 , and an O-ring 580 .

A flow path 511 is formed inside the socket body 510, and in a state where the socket 500 is installed in the plug 100, the flow path 511 and the siphon tube 20 are formed inside The flow path 20a and the supply pipe 600 installed in the socket body part 510 are in communication with each other.

The mounting nut 520 is a member having an external thread formed on the lower outer circumferential surface, and is a member relatively movable with respect to the socket body 510 along the axis X1.

By relatively moving the installation nut 520 to the lower end of the socket body 510 , the male screw of the installation nut 520 may be fastened to the female screw formed on the inner circumferential surface of the plug body 10 . Thereby, as shown in FIG. 7, the socket body part 510 and the sealing member 560 are installed between the installation nut 520 and the plug body part 10 in the fitted state.

The O-ring 530 regulates excessive movement of the installation nut 520 with respect to the socket body 510 while making the installation nut 520 relatively movable with respect to the socket body 510 . The O-ring 530 functions as a stopper for fixing the installation nut 520 upward so that the operator can easily visually recognize the tip of the socket 500 when the socket 500 is installed on the plug 100 . .

The flange parts 540 and 550 are members fastened to the socket body part 510 by fastening bolts, respectively. The flange portions 540 and 550 are to determine an upper limit position where the installation nut 520 is relatively movable with respect to the socket body portion 510 .

7, the sealing member 560 is provided in the socket main body part 510 so that the annular-shaped sealing surface 560a may be formed below.

At the lower end of the socket body 510 , a lower end 570 protruding downward from the sealing surface 560a of the sealing member 560 is provided. The lower end 570 is inserted into the recess 14 formed in the plug body 10 when the socket body 510 is installed in the plug body 10 . By inserting the lower end 570 into the recess 14 , the central axis of the socket body 510 can easily coincide with the central axis of the plug body 10 of the plug 100 .

7, when the lower end 570 is inserted into the recess 14 of the plug body 10, the O-ring 580 installed on the outer circumferential surface of the socket body 510 is formed in the recess ( 14), an endless portion-shaped seal region extending around the axis X1 is formed. Therefore, when the socket 500 is installed in the plug 100, the internal space S1 of the liquid storage container 400 and the internal space S2 of the siphon tube 20 of the plug 100 are, remain unconnected. Therefore, when the internal space S2 of the siphon tube 20 is sucked by a pump (not shown), the internal space S1 of the liquid storage container 400 and the siphon tube 20 of the plug 100 The pressure difference generated between the inner spaces S2 is maintained.

Next, an operation for removing the socket 500 from the plug 100 will be described with reference to FIGS. 8 and 9 .

When the fastening of the mounting nut 520 and the plug body part 10 is gradually loosened from the state shown in FIG. 7, it will be in the state shown in FIG. In the state shown in Fig. 8, since the O-ring 580 is in contact with the inner circumferential surface of the concave portion 14, the inner space S1 of the liquid storage container 400 and the siphon tube of the plug 100 ( 20), the pressure difference generated between the internal spaces S2 is maintained. In this state, there is a possibility that the liquid inside the siphon tube 20 rises to the concave portion 14 of the plug 100 due to the pressure difference between the inner space S1 and the inner space S2 .

When the fastening of the mounting nut 520 and the plug body portion 10 is further loosened from the state shown in FIG. 8, the state shown in FIG. 9 is obtained. In the state shown in FIG. 9 , since the O-ring 580 is not in contact with the inner circumferential surface of the concave portion 14 , the inner space S1 of the liquid storage container 400 and the siphon tube of the plug 100 . It is in a state in which a pressure difference does not generate|occur|produce between the internal spaces S2 of (20). In this state, since there is no pressure difference between the internal space S1 and the internal space S2 , the liquid inside the siphon tube 20 does not rise to the recessed portion 14 of the plug 100 . In this state, the liquid level in the inner space S1 is equal to the liquid level in the inner space S2.

Further, according to the plug 100 of this embodiment, since the communication groove 13b is further formed in addition to the through hole 13a, the O-ring 580 is compared with the case where the communication groove 13b is not formed. The state in which it does not contact with the inner peripheral surface of this recessed part 14 is implement|achieved at an early stage. Therefore, compared with the case where the communication groove 13b is not formed, the problem that the liquid inside the siphon tube 20 rises up to the recessed part 14 of the plug 100 and is ejected can be suppressed.

The action and effect exhibited by the plug 100 and the plug structure of the present embodiment described above will be described.

According to the plug 100 of the present embodiment, in a state in which the plug body 10 is installed on the inner circumferential surface of the opening 420 of the liquid storage container 400 , the second body 10b of the plug body 10 is included. ), by bringing the sealing member 220 into contact with the bottom portion 12 of the plug body portion 10, the flow passage 11 formed at the lower end of the plug body portion 10 is sealed. By sealing the flow path 11 , the liquid accommodated in the liquid storage container 400 is prevented from being ejected to the outside through the siphon tube 20 .

Further, according to the plug 100 of the present embodiment, since the second body portion 10b has the communication portion 13 , even when the sealing member 220 is placed in contact with the bottom surface portion 12 . , the internal space S1 of the liquid storage container 400 and the internal space S2 of the siphon tube 20 of the plug 100 are in communication with each other.

Therefore, even when the gas accommodated in the liquid storage container 400 increases due to a change in the environmental temperature of the liquid storage container 400 , the pressure in the internal space S1 of the liquid storage container 400 and the plug 100 The pressure in the inner space S2 of the is maintained at the same pressure. Thereby, when the sealing of the flow path by the sealing member 220 is released, the problem that the liquid accommodated in the liquid storage container 400 is ejected to the outside through the siphon tube 20 is suppressed.

In the plug 100 of the present embodiment, the communicating portion 13 extends on a plane intersecting the through hole 13a extending along the axis X1 and the axis X1, and at one end, the through hole The communication groove 13b communicates with the 13a and the other end communicates with the internal space S2 of the plug 100 .

By doing so, when the sealing member 220 is placed in contact with the bottom face 12 of the second body portion 10b, the liquid storage container ( The internal space S1 of the 400 and the internal space S2 of the plug 100 may be communicated. Thereby, when the sealing member 220 releases the sealing of the flow path 11 , the problem that the liquid accommodated in the liquid storage container 400 is ejected to the outside through the siphon tube 20 is suppressed. Moreover, the communicating part 13 can be formed by the comparatively simple structure of forming the 2nd main body part 10b with the through-hole 13a and the communicating groove|channel 13b orthogonal to this.

Further, in the plug 100 of the present embodiment, the bottom face portion 12 has an endless annular protrusion 12a extending around the axis X1 on the outer periphery side of the through hole 13a with respect to the axis X1. ) has

By doing so, when the sealing member 220 is placed in contact with the bottom surface portion 12 of the second body portion 10b, a through hole communicating with the internal space S1 of the liquid storage container 400 ( An endless portion-shaped seal region is formed on the outer peripheral side of 13a). Thereby, the problem that the liquid flows out from the siphon tube 20 or the liquid storage container 400 to the outside can be reliably suppressed.

In the plug 100 of the present embodiment, the plug body portion 10 and the siphon tube 20 are formed of a resin material, and the plug body portion 10 and the siphon tube 20 are formed of a resin material. They are connected by welding.

By doing so, the connection portion between the plug body portion 10 and the siphon tube 20 is compared with the case where the plug body portion 10 and the siphon tube 20 are not welded together and are connected as separate members through a seal member or the like. It is possible to suppress the problem caused by the inflow and outflow of liquid or gas from the

The plug structure of this embodiment has a plug 100 and a sealing portion ( 200) is provided.

According to the plug structure of this embodiment, by providing the sealing portion 200 on the inner peripheral surface of the first body portion 10a of the plug 100 , the sealing member 220 and the bottom surface portion 12 come into contact with each other to form a sealing area. is formed By this sealing area, the problem that the liquid flows out from the liquid storage container 400 and the siphon tube 20 to the outside is suppressed.

Further, in the state in which the seal region is formed, the internal space S1 of the liquid storage container 400 and the internal space S2 of the siphon tube 20 of the plug 100 are in communication with each other. Therefore, even when the gas accommodated in the liquid storage container 400 increases due to a change in the environmental temperature of the liquid storage container 400 , the pressure in the internal space S1 of the liquid storage container 400 and the plug 100 The pressure of the inner space (S2) of the siphon tube 20 is maintained at the same pressure. Thereby, when the sealing member 220 releases the sealing of the flow path 11 , the problem that the liquid accommodated in the liquid storage container 400 is ejected to the outside through the siphon tube 20 is suppressed.

In the plug structure of the present embodiment, female threads are formed on the inner peripheral surface of the first body portion 10a, and male threads are formed on the outer peripheral surface of the sealing portion 200, and the first body portion 10a and the sealing portion ( 200) is connected by coupling the male screw to the female screw.

In this way, by a relatively simple operation of installing the male screw formed on the outer peripheral surface of the sealing part 200 to the female thread formed on the inner peripheral surface of the first body part 10a, the sealing part 200 is attached to the first body part 10a. can be installed on

<Other embodiment>

In the above description, the plug body portion 10 and the siphon tube 20 are welded by melting of a resin material by ultrasonic waves or welding by melting of a welding rod, however, other forms may be used.

For example, as shown in Fig. 10, the lower end of the plug body portion 10A may be formed in a cylindrical shape, and the lower end of the plug main body portion 10A may be inserted into the upper end portion of the siphon tube 20A. .

As shown in Fig. 10, the lower end of the plug body portion 10A according to another form (modified example) is formed in a cylindrical shape extending along the axis X1 and has an endless annular projection 15 on the outer peripheral surface. ) is installed. As shown in Fig. 10, the outer peripheral surface of the lower end of the plug body portion 10A is in contact with the inner peripheral surface of the upper end of the siphon tube 20A. In this state, between the annular projection 15 and the inner circumferential surface of the upper end of the siphon tube 20A, an endless portion-shaped seal region extending around the axis X1 is formed. Since this sealing area is formed, in this form, 10 A of plug body parts and the siphon tube 20 can be connected without work, such as welding or welding.

Claims (6)

A plug installed in a liquid storage container having an opening formed in a cylindrical shape along the axis and installed on the upper surface,
a plug body installed on the inner circumferential surface of the opening and having a flow path extending along the axis;
a siphon tube connected to the plug body and extending along the axis to the bottom of the liquid container;
The plug body part,
a first body portion installed on the inner circumferential surface of the opening and formed in a cylindrical shape along the axis;
a second body portion integrally formed with the first body portion and having a bottom portion disposed on a plane intersecting the axis line;
the second body portion has a communication portion for communicating the inner space of the liquid storage container and the inner space of the plug when the second body portion is disposed in a state in which the sealing member is in contact with the bottom surface portion;
The communication unit,
a through hole extending along the axis;
and a communication groove extending on a plane intersecting the axis and at the same time having one end communicating with the through hole and the other end communicating with the inner space of the plug. The method of claim 1,
the first body portion has an inner peripheral surface to which a sealing portion having a sealing member for sealing the flow passage formed in the plug body portion with respect to the outside of the liquid storage container can be mounted;
wherein the communicating portion communicates with the inner space of the liquid container and the inner space of the plug when an endless portion-shaped seal region extending around the axis is formed in contact with the sealing member on the bottom surface portion. . The method of claim 1,
The plug, wherein the bottom surface portion has an endless annular projection extending around the axis on an outer peripheral side of the through hole with respect to the axis. 4. The method according to any one of claims 1 to 3,
the plug body and the siphon tube are formed of a resin material,
The plug, wherein the plug body portion and the siphon tube are connected by welding of the resin material. The plug according to any one of claims 1 to 3,
and a sealing portion provided on the inner circumferential surface of the first body portion and having the sealing member in contact with the bottom surface portion to form a sealing area. 6. The method of claim 5,
A female screw is formed on the inner circumferential surface of the first body portion,
A male screw is formed on the outer peripheral surface of the sealing part,
and the first body portion and the sealing portion are connected by fastening the male screw to the female screw.

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