KR102029998B1 - Pipe connecting apparatus with cam - Google Patents

Abstract

The present invention relates to a rotation joint and an air conditioning device. According to an embodiment of the present invention, a pipe connecting device including a cam includes a first unit and a second unit separably connected to each other. The first unit includes: a first body including a cam hole penetrated to a first through hole of the inside on one side of the circumference; a control cam including a cam shaft penetrating the cam hole and the cam formed on the circumference of the camshaft in the first through hole; a first guide including a first guide hole and fixed into the first through hole; a first valve body penetrating the first guide hole and moving forward and backward in the first through hole; and a slider elastically supported in the first through hole, wherein the slider opens and closes a front flow path formed around the first valve body moving forward in accordance with the rotation of the cam while sliding along the inner circumference of the first through hole. The second unit includes: a second body having a second through hole inside and inserted into the first through hole of the first body to be separated, wherein the second body opens the front flow path by pushing the slider when the first valve body moves forward; and a second valve body elastically supported in the second through hole and blocking the second through hole by being attached to the inner circumference of the second through hole when the second body is separated, wherein the second valve body also opens a flow path of the second through hole by being in contact with and being pushed to the first valve body moving forward in accordance with the rotation of the cam when the second body is inserted.

Description

Piping connecting device with cam {PIPE CONNECTING APPARATUS WITH CAM}

The present invention relates to a pipe connecting device. More specifically, the present invention relates to a pipe connecting device having a cam that can separate a pipe without substantial loss of fluid flowing into the pipe.

In general, a pipe is a passage through which a fluid flows. Piping is used in various devices using fluids such as air conditioning and heating, and various equipment or systems in which fluids are used. The pipe is for flowing a fluid, and the fluid flowing through the inside of the pipe is usually a gas or a liquid.

Various appliances, devices, installations or systems with piping may require the removal and reinstallation of pipes or the connection of separation pipes. Piping applications include air conditioning, heating and cooling, water supply and drainage, ventilation / ventilation, city gas, factories or industrial facilities. In the case of installing pipes according to these uses, it is necessary to connect two or more pipes due to the shape of the installation site, the length of the pipes, the disassembly and assembly. Pipe joints include flanged joints, fitting joints, threaded joints, welded joints, adhesive joints, and the like, but the joints are inevitably leaking fluid in the pipe during re-separation.

Quick connectors are used to quickly connect or disconnect pipes in a way of pipe joints to solve the problem of fluid leakage during pipe separation. Pipe quick connectors are used when pipe separation is required. At this time, it is necessary to minimize the leakage of fluid flowing through the pipe. In addition, it should be possible to simply detach and combine while minimizing the leakage of fluid during separation.

On the other hand, it is necessary to prevent the fluid from leaking by accidentally pressing on the separated pipe side as well as during the separation of the pipe connected by the pipe quick connector. In particular, it is necessary to prevent the fluid from leaking from the side to which the fluid is supplied in the separated pipe or the side separation pipe having high fluid pressure by mistake.

Republic of Korea Patent Publication No. 10-2009-0056148 (2009. 06. 03. published) Republic of Korea Utility Model Publication No. 20-2017-0001449 (published Apr. 24, 2017)

The present invention is to solve the above-mentioned problems, the cam structure can be separated simply and conveniently without substantial loss of fluid flowing into the pipe when the pipe is separated, as well as having a cam structure to block the flow path after the cam structure On one side is provided with a pipe connecting device having a cam that can prevent the fluid leakage by mistake.

In order to solve the above-mentioned problem, according to one aspect of the present invention, in a pipe connecting apparatus including a first unit and a second unit and detachably coupled to each other, the first unit comprises: A first body having a cam hole penetrating through the first through hole; An operation cam including a cam shaft penetrating the cam hole and a cam formed around the cam shaft in the first through hole; A first guide formed in the first through hole and having a first guide hole; A first valve body penetrating through the first guide hole and moving forward and backward in the first through hole as the cam rotates; And a slider which is elastically supported in the first through hole, slides along the inner circumferential surface of the first through hole, and opens and closes a front flow path formed around the first valve body advanced according to the rotation of the cam. A second body having a second through hole formed therein and detachably fitted to the first through hole of the first body, and opening the front flow path by pushing the slider in a forward state of the first valve body; And a first valve body elastically supported in the second through hole and in close contact with the inner circumferential surface of the second through hole when the second body is separated, and blocking the second through hole and advancing according to the rotation of the cam when the second body is fitted. A piping connecting device with a cam is proposed, comprising a second valve body which abuts and opens a flow path of a second through hole.

At this time, in one example, the flow path communication of the first and second through holes is to the front side of the cam projection in the case where the second body is fitted in the advancing state of the first valve body and in the engaged state of the first and second bodies. When the first valve body is advanced by the rotation and the front part is separated from the slider, the internal flow path of the slider and the front flow path are connected, and the blocking of the connection flow path of the first and second through holes is performed in the second state in the forward state of the first valve body. When the body is separated, the slider blocks the front flow path, the second valve body blocks the second through hole, and when the first and second bodies are engaged, the first valve body retreats according to rotation of the cam protrusion. The front portion of the first valve body is in close contact with the slider to block the internal flow path of the slider.

At this time, in another example, the first guide is fixedly installed in the first through hole, and the first unit has one end supported by the slider and the other end supported by the first guide or the inner surface of the first through hole. In the forward state of the sieve, when the fitting of the second body is engaged, the slider contracts with the retraction of the slider, and when the second body is separated, the front flow path is provided to the slider so that the slider is closed. Further comprising a first spring that contracts with the retraction of the slider with the retraction, the second unit: a second guide having a second guide hole for guiding the sliding of the second valve body and fixed in the second through hole ; And one end supported by the second valve body and the other end supported by the second guide or the inner surface of the second through hole, the second through body being separated by the second valve body when the second body is separated. It may further include a second spring for providing an elastic force to the second valve body so that the flow path of the hole is blocked.

Further, in this case, in one example, the second body has a valve seat formed in the front side is smaller than the rear side on the inner circumferential surface of the second through hole, the second guide is the rear side of the second through hole in the outermost circumference The flow path is formed around the second guide hole by screwing with the inner circumferential surface, and the second valve body is formed in front of the second shaft part and the second shaft part, the rear side of which is inserted into the second guide hole and slides. A second valve portion that forms a front portion of the second valve body that abuts the first valve body during flow passage of the second through hole, and is enlarged larger than the minimum inner diameter of the valve seating portion in the direction of the inner circumferential surface of the second through hole, and around the second valve portion; And a second sealing portion for maintaining the airtightness between the valve seat and the second valve portion when the second body is separated, wherein the second spring is installed around the circumference of the second shaft portion, and one end thereof is the rear side of the second valve portion. It can be supported. In addition, the second unit may further include a tube connector fastened to the rear side of the second body and connected to the pipe.

Further, in one example, the first unit is installed around the circumference of the first valve body, one end of which is supported at the rear of the first valve body, the other end of which is supported on the first guide or the inner surface of the first through hole, and the cam It may further include a third spring for providing the resilient force for the retraction of the first valve body in accordance with the rotation to the rear side of the protrusion.

Further, in one example, the rear portion of the first valve body forms a cam engaging portion that is engaged with the cam, and the opposite side of the cam protrusion is fastened to the cam engaging portion when the cam projection rotates to the rear side, and in accordance with the rotation to the rear side. The cam may retract by pulling the first valve element.

At this time, in one example, the cam has a hook portion projecting up and down on the opposite side of the cam projection, the cam engaging portion is projected vertically at the arc-shaped end and arc-shaped end concave to the horizontal rear side and is pulled by the hook portion A pair of plates having a may be formed to be vertically symmetrical.

At this time, in another example, the cam hole is formed so as to penetrate into the first through hole at a portion protruding from the peripheral outer circumferential surface around the first body, the operation cam is a locking pin protruding around the upper end of the cam shaft protruding from the cam hole Further, the first body is formed on the inner circumferential surface of the first through hole facing the cam hole is a support groove for supporting the lower end of the cam shaft, protruding from the top of the cam hole and the stopper and cam hole limiting the rotation range of the locking pin is It may further include a cam stopper fastened to the formed protruding portion to cover the operation cam.

Further, in one example, the first body has a stepped portion whose diameter of the first through hole is smaller than the outer diameter of the slider but which defines the retreat of the slider or supports the elastic support of the slider, wherein the first guide has the outermost portion. The circumference is screwed with the inner circumferential surface of the stepped portion of the first through hole to form a flow path around the first guide hole, and the first valve body is provided in front of the first shaft portion and the first shaft portion that penetrate the first guide hole. And a front portion of the first valve body which is formed to contact the second valve body when the first and second through holes communicate with each other, and is smaller than the diameter of the inner circumferential surface in the direction of the inner circumferential surface of the first through hole from the front side of the first guide and is an internal flow path of the slider. A first valve portion enlarged larger than a diameter, and a first valve portion installed around the first valve portion and maintaining airtightness between the slider and the first valve portion when the front flow passage or the internal flow passage is blocked. It may include a sealing unit.

At this time, in one example, the slider has a seating portion which is inclined to the curved surface toward the rear on the inner circumferential surface of the inner flow passage and is in close contact with the first sealing portion, and one end of the elastic support for elastically supporting the slider has an inner protrusion of the seating portion. Supported by grooves formed in the rear to rear surfaces of the seating portion formed by, the size of each of the front end of the slider and the front end of the second body, the size of each of the front surface of the first valve portion and the front surface of the second valve body And a protruding length of the front face of the first valve portion protruding from the front end of the slider when the internal flow path of the slider is blocked, and a retracting length of the front face of the second valve body retracted from the front end of the second body when the second through hole is blocked. Each size may match each other.

In addition, in one example, the first unit is installed in a plurality of ring grooves formed on the inner peripheral surface of the front engagement side of the first through hole, and is fitted between the inner circumferential surface of the first through hole and the outer circumferential surface of the slider and when the second body is fitted into the first through hole. Through hole sealing rings for maintaining the airtightness between the inner circumferential surface and the outer circumferential surface of the second body and at least one ring groove formed in the inner circumferential surface of the cam hole and at least one cam hole sealing ring for maintaining the airtightness between the inner circumferential surface of the cam hole and the outer circumferential surface of the cam shaft. It may further include.

In another example, the second unit may further include a connecting nut having one end supported around the second body and being screwed to the outer circumferential surface of the first body to which the second body is fitted.

According to one embodiment of the present invention, by using a pipe connecting device having a cam, the pipe can be separated simply and conveniently without substantial loss of fluid flowing into the pipe when the pipe is separated, and a cam structure is provided to block the flow path. By making it possible to prevent the accidental fluid leakage on one side with the cam structure even after separation.

Even if the effects are not directly mentioned in the specification of the present invention, various characteristic effects are within the understanding of those skilled in the art from the features included in the various embodiments and modifications of the present invention. It is obvious that it can be derived.

1 is a view schematically showing an operating state of a pipe connecting apparatus having a cam according to an embodiment of the present invention.
FIG. 2 is a view schematically showing a disconnected state of a pipe connecting device having a cam according to FIG. 1.
FIG. 3 is a view schematically showing a disconnected state of a pipe connecting device having a cam according to FIG. 1.
4 is a view schematically showing an exploded state of a pipe connecting apparatus with a cam according to an embodiment of the present invention.
5 is a view schematically showing a cam operating state of a pipe connecting device having a cam according to an embodiment of the present invention.
6 is an outline view schematically illustrating a pipe connecting apparatus having a cam according to an embodiment of the present invention.

Embodiments of the present invention for achieving the above object will be described with reference to the accompanying drawings. In the present description, the same reference numerals refer to the same configuration, and additional descriptions may be omitted for the purpose of understanding the present invention to those skilled in the art.

In the present specification, when one component forms a coupling relationship such as connection or coupling in a relationship with another component, unless there is a limitation of 'direct', not only a form of 'direct' coupling relationship or the like, As other components are related, they may also exist in the form of a coupling relationship by a medium. In addition, the same is true when terms that include the meaning of 'contact' such as 'up', 'up', 'lower', and 'lower' are included. In addition, terms indicating positions such as 'end' and 'other', 'one side' and 'other side' indicate different positions, and terms indicating directions such as 'front' and 'backward' are used as reference elements. It should be interpreted as a relative concept.

In addition, it should be noted that even if the configuration is expressed in the singular, it can be used as a concept representing the entirety of the plurality of configurations, unless they contradict or contradict the concept of the invention.

In addition, the description of the words "comprise", "comprises", and the like, and terms derived therefrom, herein refers to the possibility of adding, combining, or combining one or more other components to the original components or elements. Not exclusively, furthermore, descriptions of words having the meaning of 'comprise', 'consist of', etc. and terms derived therefrom are also indicative of additions, combinations, or combinations of one or more other elements to the original elements or elements. If the original elements or elements do not lose their features, functions and / or properties, then the possibility of addition or combination of such one or more other elements should not be excluded.

The drawings referred to in this specification are examples for describing embodiments of the present invention, and shapes, sizes, thicknesses, and the like may be exaggerated or reduced for effective description of technical features. In addition, some of the components of the embodiment in the drawings illustrating the embodiments of the present invention may be omitted or represented by description only to help the understanding of the entire invention to the remaining configuration.

The pipe connecting apparatus according to one aspect of the present invention will be described in detail with reference to the accompanying drawings. In this case, reference numerals not described in the accompanying drawings may be reference numerals in other drawings showing the same configuration. At this time, it should be noted that the components disclosed in each drawing may be partially omitted or modified according to the modification of the embodiments, and in each of the drawings, even the essential configuration of the invention may be omitted so as to assist in understanding other configurations. .

1 is a view schematically showing an operating state of a pipe connecting device having a cam according to an embodiment of the present invention, and FIGS. 2 and 3 each show a detached state of the pipe connecting device having a cam according to FIG. 1. It is a schematic drawing. In FIG. 2, the cam protrusion 122a of the cam 122 advances the first valve body 130 in the separated state. In FIG. 3, the cam protrusion 122a of the cam 122 moves forward to the rear side of the cam protrusion 122a in the separated state. 1 shows that the valve body 130 is retracted. 4 is a view schematically showing an exploded state of a pipe connecting apparatus with a cam according to an embodiment of the present invention, and FIG. 5 is a cam of a pipe connecting apparatus with a cam according to an embodiment of the present invention. 6 is a view schematically showing an operating state, and FIG. 6 is an outline view schematically illustrating a pipe connecting apparatus having a cam according to an embodiment of the present invention.

1 to 6, the pipe connecting apparatus according to one example includes a first unit 100 and a second unit 200 and is detachably coupled to each other. In this case, the pipe connecting device according to one of the present invention includes a cam 122. When the first unit 100 and the second unit 200 are separated, each of them blocks the flow path. For example, one side of each of the first and second units 100 and 200 is coupled to the pipe side, and the pipes are connected according to the coupling of the first and second units 100 and 200. If the pipe is to be separated, the first and second units 100 and 200 are separated to separate the pipe and the flow path of the separated pipe is blocked. In addition, referring to FIGS. 1 to 6, in another example, the pipe connecting device may further include a connecting nut 270. For example, the first unit 100 includes a first body 110, a manipulation cam 120, a first guide 150, a first valve body 130, and a slider 140, and the second unit 200. ) Includes a second body 210 and a second valve body 230. When the pipe is connected by the coupling of the first and second units 100 and 200, the first through hole 110a in the first body 110 and the second through hole 210a in the second body 210 are connected. Euros are communicated. In addition, in one example, the first unit 100 may further include a first spring 160. In addition, the second unit 200 may further include a second guide 250 and a second spring 260. For example, the first unit 100 may further include a third spring 170. In one example, the first unit 100 may further include through hole sealing rings 181 and one or more cam hole sealing rings 182. In another example, the second unit 200 may further include a connecting nut 270.

For example, a pipe connecting device according to one example of the present invention can be used for joining and separating various pipes. The pipe connecting device according to one example can be used irrespective of the gas or the liquid in that the fluid is little leakage, in particular liquefied gas piping, refrigerant pipes and the like can be usefully used.

Hereinafter, the components of the first unit 100 and the components of the second unit 200 will be described. At this time, in the description of the configuration of the first unit 100 'forward' and 'rear' is the concept of the coupling side with the second unit 200 'forward', 'forward' and 'retreat' It means a case of moving toward the 'front' which is the coupling side with the second unit 200 and a case of retreating in the 'forward' opposite direction. On the other hand, in the description of the configuration of the second unit 200, the concept of 'forward', 'rear', 'forward', 'retreat', etc., the coupling side with the first unit 100 as 'forward' In this regard, relative to the concept in the first unit 100 and the direction is opposite to each other when the first and second units 100 and 200 are combined. That is, in describing the detailed configurations of the first and second units 100 and 200, 'forward' means a coupling side of the first and second units 100 and 200, and 'rear' means the first and second units. Means the direction away from the coupling side of the unit (100, 200).

[First Unit 100]

1 to 6, in one example, the first unit 100 includes a first body 110, a manipulation cam 120, a first guide 150, a first valve body 130, and a slider ( 140). For example, the first unit 100 may further include a first spring 160. In addition, in one example, the first unit 100 may further include a third spring 170. In another example, the first unit 100 may further include through hole sealing rings 181 and one or more cam hole sealing rings 182.

For example, in one example, the first unit 100 may be connected to the pipe side to which the fluid is supplied or the pipe side to which the fluid pressure becomes high after separation. At this time, according to the operation of the operation cam 120 included in the first unit 100, even after the pipe is removed, it may be possible to prevent the leakage of fluid due to a mistake or to significantly reduce the possibility of leakage. For example, although not shown, the first unit 100 may further include a cap capable of blocking the front side of the first body 110 after separation. Similarly, the second unit 200 to be described later, although not shown, may further include a cap that blocks the front side of the second body (210). In this case, the cap may be stored in connection with each of the first and second bodies 110 and 210, respectively, by a connection line.

The detailed configurations of the first unit 100 will be described in detail. In this case, various embodiments of the first unit 100 may be implemented through a combination of various implementation examples of detailed configurations of the first unit 100.

First body 110

1 to 4 and 6, the first body 110 has a first through hole 110a therein and a cam hole 110b penetrating into the first through hole 110a at one circumference thereof. do. The first through hole 110a is a flow path through which fluid flows, and the first guide 150, the first valve body 130, the slider 140, and the like are installed in the first through hole 110a. In addition, a part of the cam shaft 121 of the operation cam 120 and the cam 122 are positioned in the first through hole 110a. The cam hole 110b is penetrated by the cam shaft 121 of the operation cam 120.

1 to 3, the inner circumferential surface of the first through hole 110a is further described. For example, ring grooves may be formed on the front inner circumferential surface of the first through hole 110a. In this case, through hole sealing rings 181 may be installed in the ring grooves to maintain airtightness between the inner circumferential surface and the slider 140 or the outer circumferential surface of the second body 210. The position of the ring grooves is such that the outer circumferential surface of the second body 210 when the first and second bodies 110 and 210 are coupled is kept airtight by the foremost through-hole sealing ring 181 installed in the foremost ring groove and the slider ( The outer circumferential surface of the 140 may be kept airtight by the rearmost through hole sealing ring 181 installed in the rearmost ring groove.

In one example, the first body 110 may include a stepped portion 111 on the inner circumferential surface of the first through hole 110a. The stepped part 111 has a diameter of the first through hole 110a smaller than the outer diameter of the slider 140 and is formed stepped. The stepped portion 111 may limit the retraction of the slider 140 or may support the elastic support of the slider 140, for example, the first spring 160. For example, referring to FIGS. 1 and 3, the stepped portion 111 may define the retreat of the slider 140. For example, a screw thread coupled to the first guide 150 may be formed at the rear side of the stepped part 111. For example, a stepped portion is formed in the first guide 150 that is engaged with the inner circumferential surface of the first through hole 110a and forms the same surface as the stepped portion 111 so that the first spring 160 may be supported on the same surface. have.

In addition, in one example, the first body 110 may further include a support groove 112 on the inner circumferential surface of the first through hole 110a. The support groove 112 is formed on the inner circumferential surface of the first through hole 110a facing the cam hole 110b to support the lower end of the cam shaft 121 to be described later. That is, the lower end of the cam shaft 121 is inserted into and supported by the support groove 112 during the rotation operation of the operation cam 120, so that, for example, the cam hole by the cam hole sealing ring 182 described below installed in the cam hole 110 b ( 110b) it is possible to prevent the shaking of the operation cam 120 according to the gap between the inner circumferential surface and the cam shaft 121.

Next, the cam hole 110b will be further described with reference to FIGS. 1 to 3. For example, one or more ring grooves may be formed on the inner circumferential surface of the cam hole 110b. At this time, the airtightness between the cam shaft 121 and the inner circumferential surface of the cam hole 110b may be maintained by at least one cam hole sealing ring 182 installed in the ring groove formed in the cam hole 110b.

For example, the cam hole 110b may be formed to penetrate into the first through hole 110a at a portion protruding from the peripheral outer circumferential surface of the circumference of the first body 110. At this time, the cam stopper 115 to be described later may be fastened to a portion protruding from the peripheral outer circumferential surface.

In addition, the first body 110 may further include a stopper 113 protruding from the upper end of the cam hole 110b. The stopper 113 protrudes from the upper end of the cam hole 110b to limit the rotation range of the locking pin 123 of the operation cam 120 to be described later. For example, the stopper 113 may limit the locking pin 123 to rotate 180 degrees. As a result, the cam projection 122a of the cam 122 of the operation cam 120 rotates from the front side to the rear side and vice versa.

In addition, the first body 110 may further include a cam stopper 115. The cam stopper 115 is fastened to the protruding portion where the cam hole 110b is formed to cover the operation cam 120. The cam stopper 115 may be opened to rotate the upper end of the cam shaft 121 of the operation cam 120 so that the cam protrusion 122a of the cam 122 may face the front side or the rear side.

For example, in one example, a thread is formed around the front side of the first body 110 to be coupled with the connecting nut 270 described later. Alternatively, although not shown, one end of the connecting nut 270 may be supported around the first body 110, and the other end may be screwed around the second body 210.

For example, the rear portion of the first body 110 may be smaller in diameter to be connected to the pipe side. Although not shown, in one example, a configuration such as the tubular connector 280 of the second unit 200 may be fastened to the rear side of the first body 110. When the pipe connector 280 is fastened to the rear side of the first body 110, pipes having various diameters may be connected through the pipe connector 280.

Operation Cam (120)

1 to 6, the operation cam 120 is formed around the cam shaft 121 in the cam shaft 121 and the first through hole 110a that pass through the cam hole 110b of the first body 110. Cam 122. The operation cam 120 may include a cam 122 to move the first valve body 130 forward. In addition, the first valve body 130 may be retracted backward as the operation cam 120 rotates.

For example, in one example, flow path communication between the first through hole 110a in the first body 110 and the second through hole 210a in the second body 210 may be caused by rotation of the cam 122, such as the cam protrusion. When the second body 210 is fitted in the advanced state of the first valve body 130 in accordance with the rotation of the front side of the (122a) is made, and also, the first and second body (110, 210) When the first valve body 130 moves forward and the front portion of the first valve body 130 falls from the slider 140 after rotation, the rotation of the operation cam 120, that is, the front of the cam protrusion 122a. Can be done on.

On the contrary, the blocking of the connecting flow paths of the first and second through holes 110a and 210a is performed by separating the second body 210 in the advanced state of the first valve body 130 according to the rotation of the cam protrusion 122a toward the front side. And the slider 140 blocks the front flow path, and the first valve body (A) is rotated to the rear side of the cam protrusion 122a in the engaged state of the first and second bodies 110 and 210. 130 may be retracted and the front part of the first valve body 130 may be in close contact with the slider 140.

1 to 5, the cam 122 will be described in more detail. For example, the cam 122 may be formed around the cam shaft 121 to be positioned on the central axis of the first through hole 110a. At this time, in accordance with the rotation of the cam 122 by the rotation of the cam shaft 121, the cam projection 122a, the so-called Cam Nose (Rom) is rotated to the front side and the first valve body 130 can be pushed forward. have. As the cam protrusion 122a rotates to the rear side, the first valve body 130 may retreat backward.

In addition, in one example, the cam 122 may include a hook portion 122b protruding up and down on the opposite side of the cam protrusion 122a. At this time, the hook portion 122b of the cam 122 is fastened to the cam coupling portion 135 forming the rear portion of the first valve body 130 as the front side rotates, and the first valve body 130 is formed by cam lift. The first valve body 130 can be retracted by pulling.

Next, the camshaft 121 will be further described with reference to FIGS. 1 to 5. The cam shaft 121 penetrates the cam hole 110b, and a cam 122 may be formed around the cam shaft 121 at a central axis portion of the first through hole 110a. For example, the cam shaft 121 may pass through the cam hole 110b and may have a lower end supported by a support groove 112 formed on an inner circumferential surface facing the cam hole 110b in the first through hole 110a. For example, the cam shaft 121 may have a polygonal cross section where a portion where the cam 122 is installed is matched with a fitting groove formed in the cam 122 so that the cam 122 does not rotate separately from the cam shaft 121. . The lower end of the cam shaft 121 below the fastening portion of the cam 122 of the cam shaft 121 has a cylindrical shape so as to be rotatable in the support groove 112. The cam 122 may be fixed to the lower end of the cam coupling part of the cam shaft 121, that is, the lower end of the cam 122 so that the cam 122 does not move up and down on the cam shaft 121.

For example, referring to FIGS. 1 to 5, in one example, the operation cam 120 may further include a locking pin 123 protruding around an upper end portion of the cam shaft 121 protruding from the cam hole 110b. . At this time, the locking pin 123 is formed around the cam shaft 121 protruding upward from the cam hole 110b, and the rotation is caught by the stopper 113 formed at the top of the cam hole 110b when the operation cam 120 is rotated. Can be limited. For example, the locking pin 123 itself can also be used as a handle for adjusting the rotation of the operation cam (120).

For example, a square or hexagonal structure may be formed at an upper end of the cam shaft 121 to rotate the operation cam 120 using a tool such as a wrench.

In one example of the present invention, in accordance with the operation of the operation cam 120, the opening and closing of the flow path in the coupled state of the first and second body (110, 210) is possible, the first and second body (110, 210) Retract the first valve body 130 in the first body 110 both before and after the separation to prevent the slider 140 from being pressed accidentally and to prevent leakage of fluid through the internal flow path of the slider 140. It can prevent. That is, as the retraction of the first valve body 130 into the first through hole 110a may not only significantly reduce the possibility of accidentally discharging the fluid, but also the slider 140 as described below in one example. This can block the possibility of substantial opening of the internal flow path. In one example, before and after the separation of the first and second bodies 110 and 210, the slider is retracted by retracting the first valve body 130 in the first body 110 according to the operation of the operation cam 120. By retracting the 140 to the stepped portion 111 of the first through hole 110a to the maximum, the slider 140 may not be retracted further, thereby blocking the possibility of substantially opening the internal flow path of the slider 140. Thereby, the fluid leakage can be reliably prevented in the piping of the 1st unit 100 side.

First guide 150

1 to 5, the first guide 150 is formed in the first through hole 110a and has a first guide hole 151. The first guide 150 guides forward and backward sliding of the first valve body 130 passing through the first guide hole 151. For example, the first guide 150 may be formed integrally with the inner circumferential surface of the first through hole 110a protruded inward, and may be separately manufactured in terms of convenience of fabrication of the pipe connecting device and screwed into the first through hole 110a. It can be fixed and fastened by a coupling method. In one example, the first guide 150 may be fixedly installed in the first through hole 110a.

For example, the first guide 150 may guide the sliding of the first valve body 130 and support the other end of the first spring 160 at the rear surface side of the first guide 150. For example, the first spring 160 may be supported at an engagement portion with the inner circumferential surface of the first through hole 110a of the first guide 150, or may not be illustrated, but the first spring may be formed at the stepped portion formed in the first guide 150. 160 may be supported.

In addition, for example, the first guide 150 may support the other end of the third spring 170 to be described later on the front surface side. In this case, the first spring 160 may be supported on the rear surface side of the first guide 150 and the third spring 170 may be supported on the front surface side. At this time, the front side and the rear side of the first guide 150 are not divided according to one reference line, but the plane side viewed from the front side becomes the front side and the plane side viewed from the rear side becomes the rear side. . For example, the third spring 170 may be supported on the front surface side formed as a stepped recess toward the front side of the first guide 150.

For example, referring to FIGS. 1 to 5, in one example, the first guide 150 is screwed with the inner circumferential surface of the rear side of the stepped portion 111 of the first through hole 110a at the outermost circumference and the first guide hole. A flow path can be formed around 151. For example, the first guide 150 has a structure in which a plurality of branches are formed radially around the first guide hole 151 such as a trivet, so that the ends of each branch portion are screwed with the inner circumferential surface of the first through hole 110a. Can be. In this case, the space between the branch portions is a flow path around the first guide hole 151. Alternatively, although not shown, the first guide 150 may have a planar disc structure, a first guide hole 151 formed at a central portion thereof, and a plurality of passage holes formed around the first guide hole 151.

First valve body 130

1 to 5, the first valve body 130 passes through the first guide hole 151 and moves forward and backward in the first through hole 110a according to the rotation of the cam 122. When the first and second bodies 110 and 210 are coupled, the first valve body 130 slides forward through the first guide hole 151 and is separated from the slider 140 and is formed of the first through hole 110a. The flow path may be opened, the first valve body 130 may slide backward and close to the slider 140, and the flow path of the first through hole 110a may be blocked.

For example, the rear portion of the first valve body 130 may be in contact with or coupled to the cam 122. For example, when the rear portion of the first valve body 130 contacts the cam 122, the rear portion of the first valve body 130 is pushed forward in accordance with the rotation of the cam protrusion 122a toward the front side, and the cam protrusion 122a is provided. The first valve body 130 may be retracted backward by, for example, the third spring 170 in accordance with the rotation to the rear side. Alternatively, when the rear portion of the first valve body 130 is coupled to the cam 122, the first valve body 130 is pushed forward according to the front side rotation of the cam protrusion 122a, and the cam protrusion 122a is provided. The first valve body 130 may be retracted backward by the rotation of the rear side.

1 to 5, in one example, the rear portion of the first valve body 130 may form a cam coupling portion 135 coupled to the cam 122. At this time, when the cam projection 122a is rotated to the rear side, the opposite side of the cam projection 122a is fastened to the cam engaging portion 135, and the cam 122 is moved by the cam 122 in accordance with the rotation to the rear side of the cam projection 122a. 1 The valve body 130 can be pulled back and retracted.

For example, in one example, the cam 122 may include a hook portion 122b protruding up and down on the opposite side of the cam protrusion 122a, wherein the cam coupling portion 135 is attached to the hook portion 122b. It can be retracted and pulled back by the cam 122 during the rotation to the rear side of the cam projection (122a). 1 to 5, for example, the cam engaging portion 135 vertically protrudes from the arc-shaped end portion 135a and the arc-shaped end portion 135a concave to the horizontal rear side and is pulled by the hook portion 122b. A pair of plates having a 135b may be formed to be vertically symmetrical. The locking jaw 135b of the cam coupling part 135 does not interfere with the rotation of the hook portion 122b of the cam 122 and the hook portion 122b is positioned on the hook portion 122b when the cam 122 hook portion 122b is positioned to the front side. It is formed to be caught by. For example, the pair of plates forming the cam coupling portion 135 may be coupled to the rear end of the first shaft portion 131 described later by the fastening pin 135c.

For example, in one example, the first valve body 130 may include a first shaft portion 131, a first valve portion 132, and a first sealing portion 133. For example, at this time, the cam coupling portion 135 may be formed at the rear end of the first shaft portion 131. In some embodiments, the cam 122 may contact the rear end of the first shaft part 131. The first shaft part 131 penetrates through the first guide hole 151. For example, at this time, a third spring 170 may be installed around the circumference of the first shaft portion 131.

The first valve part 132 is formed in front of the first shaft part 131. For example, the first valve part 132 may be integrally connected to the front part of the first shaft part 131 or may be fastened and coupled to the fastening groove 131a formed at the front end of the first shaft. The first valve part 132 forms a front portion of the first valve body 130 which abuts on the second valve body 230 when the first and second through holes 110a and 210a communicate with each other. In addition, the first valve part 132 may be formed to be smaller than the diameter of the inner circumferential surface in the direction of the inner circumferential surface of the first through hole 110a on the front side of the first guide 150 and larger than the diameter of the inner flow path of the slider 140. Can be. For example, referring to FIGS. 1 to 4, as an example, the front surface of the first valve portion 132 and the front surface of the second valve body 230 may be planes in which their sizes are the same to substantially match. Can be. Although not shown, according to the embodiment, the front end of the first valve portion 132 in contact with the second valve body 230 protrudes more than the circumference of the first valve portion 132 in which the first sealing portion 133 is installed. It may be a structure.

The first sealing part 133 is installed around the first valve part 132. In this case, the first sealing part 133 maintains airtight between the slider 140 and the first valve part 132 when the front flow path or the internal flow path is blocked. In this case, the front flow path refers to a flow path around the circumference of the first valve part 132, and the internal flow path refers to an internal flow path of the slider 140. Therefore, the blocking of the front flow path is the slider 140 which is in contact with the front end of the second body 210 according to the separation of the second body 210 after the flow communication between the first and second through holes 110a and 210a. ) Is to slide forward by the elastic force of the first spring 160 to block the front flow path around the first valve portion 132, the blocking of the internal flow path between the first and second through holes (110a, 210a) After the flow passage of the first and second body (110, 210) in the engaged state of the cam projection (122a) in the combined state of the rear side, the first valve body 130 retreats backward and the first valve unit 132 Is in close contact with the slider 140 and blocks the internal flow path of the slider 140. For example, the first sealing part 133 may be a sealing ring installed in a ring groove formed around the first valve part 132. At this time, the circumference of the first valve portion 132 is inclined to the curved surface of the seating portion 141 so that the first sealing portion 133 can be in close contact with the inclined surface or the curved surface of the seating portion 141 formed on the slider 140. It may have an inclined surface or curved surface parallel to or facing. A ring groove may be formed on the inclined or curved surface forming the circumference of the first valve part 132, and a first sealing part 133, for example, a sealing ring may be installed in the ring groove.

Slider 140

1 to 5, the slider 140 is elastically supported in the first through hole 110a and slides along an inner circumferential surface of the first through hole 110a. The slider 140 slides and opens and closes a front flow path formed around the first valve body 130 advanced according to the rotation of the cam 122. For example, the front flow passage is formed around the circumference of the first valve portion 132 of the first valve body 130. The front flow path is formed between the circumference of the first valve part 132 and the inner circumferential surface of the second body 210 in the open state, and the circumference of the first valve part 132 and the first through hole 110a in the closed state. It is formed between the inner circumferential surface of the) but is blocked by the slider 140. For example, the front surface of the first valve portion 132 protrudes by a predetermined protruding length from the front end of the slider 140 in the blocked state. For example, the slider 140 has a cylindrical shape and has an inner flow path formed therein, and a seating portion 141 on which the first sealing part 133 of the first valve body 130 is seated protrudes inward on an inner circumferential surface thereof. Can be formed. In this case, the seating surface of the seating portion 141 on which the first sealing portion 133 of the first valve body 130 is seated may be an inclined surface or a curved surface.

For example, referring to FIGS. 1 to 4, in one example, the slider 140 may include a seating portion 141 on the inner circumferential surface of the inner channel. The seating portion 141 of the slider 140 forms an inner flow path, forming an inclined or curved tapered surface toward the rear on the inner flow path. In addition, the mounting portion 141 is in close contact with the first sealing portion 133 to form a tapered inclined surface or curved surface. The curved surface of the seating portion 141 may have a convex structure toward the inside rather than the outside.

For example, an elastic support for elastically supporting the slider 140, for example, a rear surface of the seating portion 141 to a rear surface of the seating portion 141, in which one end of the first spring 160 is formed by an inner protrusion of the seating portion 141. It can be supported in the groove formed in. The rear surface of the seating portion 141 forms a surface perpendicular to the inner circumferential surface of the inner flow path, and at this time, the first spring 160 is supported on the rear surface of the seating portion 141 or a groove is formed on the rear surface of the seating portion 141. The first spring 160 may be supported in the groove. For example, FIGS. 1 to 4 illustrate that the first spring 160 is supported in the groove formed on the rear surface of the seating part 141.

For example, referring to FIGS. 1 through 4, in one example, the size of each of the front end of the slider 140 and the front end of the second body 210 in contact therewith is equally or substantially matched with each other, and the slider ( Protruding length of the front surface of the first valve portion 132 protruding from the front end of the slider 140 when the internal flow path of the 140 is blocked, and from the front end of the second body 210 when the second through hole 210a is blocked. The sizes of the retracted lengths of the front surfaces of the retracted second valve bodies 230 may be the same or substantially match each other. At this time, when the second through hole 210a is blocked, the front surface of the second valve body 230 exposed to the front side and the front surface of the first valve portion 132 contacting with each other are identically or substantially identically matched in the plane. In the separation process of the second body 210, the front flow path is immediately before the front end of the second body 210 falls off from the front end of the slider 140, and the front end of the slider 140 and the second body 210. The first valve body 130 and the second valve body 230 may be blocked by the front portion of the c), and substantially no fluid remains between the first valve body 130 and the second valve body 230 so that there is almost no fluid leaking after separation.

First spring 160

1 to 4, another example of the present invention will be described. In this case, the first unit 100 may further include a first spring 160. 1 to 4, one end of the first spring 160 is supported by the slider 140 and the other end is supported by the first guide 150 or the inner surface of the first through hole 110a. In the forward state of the first valve body 130, the first spring 160 is contracted according to the retreat of the slider 140 when the second body 210 is fitted, the front when the second body 210 is separated An elastic force is provided to the slider 140 so that the flow path is blocked. In addition, the first spring 160 contracts with the retraction of the slider 140 in accordance with the retraction of the first valve body 130 due to the rotation of the cam protrusion 122a toward the rear side.

For example, the other end of the first spring 160 may be supported by the stepped portion 111 formed on the inner surface of the first through hole 110a. For the description of the stepped portion 111 of the first through hole 110a, refer to the above bar. Alternatively, the other end of the first spring 160 may be supported by a stepped or vertical surface formed in the first guide 150 that is fastened to the inner circumferential surface of the first through hole 110a. For example, the stepped or vertical surface of the first guide 150, on which the other end of the first spring 160 is supported, may form the same surface as the stepped portion 111 of the first through hole 110a or may be formed of the first through hole 110a. It may be formed in the rear, in this case, the stepped portion 111 of the first through hole (110a) may limit the retreat to the rear of the slider 140.

Third spring 170

1 to 4, in another example of the present invention, the first unit 100 may further include a third spring 170. The third spring 170 is installed around the periphery of the first valve body 130, one end of which is supported at the rear of the first valve body 130, and the other end of which is disposed in the first guide 150 or the first through hole ( It is supported on the inner surface of 110a). The third spring 170 may provide an elastic force for retraction of the first valve body 130 as the cam protrusion 122a rotates to the rear side.

The third spring 170 is supported on the front surface side with respect to the first guide 150, while the first spring 160 is supported on the rear surface side of the first guide 150, wherein the first guide The front side and the rear side of the 150 may refer to a vertical plane but may refer to a front side and a rear side view, for example, the front side face is concave and rear side side view. The face may be convex.

For example, one end of the third spring 170 may be supported by the rear surface side of the cam coupling portion 135, which is a rear portion of the first valve body 130. For example, the rear surface of the cam engaging portion 135 is the side of a pair of plates that have an arc-shaped end 135a and a latching jaw 135b and is symmetrically supported or supports such a pair of plates and the first shaft portion. It may be a vertical plate through which 131 passes.

For example, referring to FIGS. 1 to 4, the other end of the third spring 170 may be supported on the front surface side of the first guide 150 or may be provided on the stepped portion protruding inwardly of the first through hole 110a. Can be supported.

For example, the elastic modulus of the third spring 170 may be greater than the elastic modulus of the first spring 160.

Through-hole sealing ring 181 and cam hole sealing ring 182

1 to 4, in another example of the present invention, the first unit 100 may further include through hole sealing rings 181 and one or more cam hole sealing rings 182. The through hole sealing rings 181 are installed in a plurality of ring grooves formed on the inner circumferential surface of the front coupling side of the first through hole 110a. The through hole sealing rings 181 may be disposed between the inner circumferential surface of the first through hole 110a and the outer circumferential surface of the slider 140 and the inner circumferential surface of the first through hole 110a and the second body when the second body 210 is fitted. The airtightness between the outer circumferential surfaces of 210 is maintained. For example, the arrangement of the through hole sealing rings 181 and the ring grooves is hermetically sealed by the foremost sealing ring in which the outer circumferential surface of the second body 210 is installed in the foremost ring groove when the first and second bodies 110 and 210 are coupled. This can be maintained and the airtightness can be maintained by the rearmost sealing ring is installed in the outermost ring groove of the outer peripheral surface of the slider 140. In this case, at least one of the through hole sealing rings 181 may always maintain airtightness between the inner circumferential surface of the first through hole 110a and the outer circumferential surface of the slider 140. For example, when the advance of the first valve body 130 and the separation of the first body 110 according to the rotation toward the front side of the cam protrusion 122a are made, the slider 140 is elastically beyond the foremost through hole sealing ring 181. The airtightness may be maintained between the inner circumferential surface of the first through hole 110a and the outer circumferential surface of the slider 140 by the foremost through hole sealing ring 181. For example, two ring grooves and through hole sealing rings 181 on the inner circumferential surface of the first through hole 110a may be formed in two.

The one or more cam hole sealing rings 182 may be installed in one or more ring grooves formed in the inner circumferential surface of the cam hole 110b and may maintain airtightness between the inner circumferential surface of the cam hole 110b and the outer circumferential surface of the cam shaft 121. For example, two ring grooves and cam hole sealing rings 182 formed on the inner circumferential surface of the cam hole 110b may be formed.

For example, the through hole sealing rings 181 and the cam hole sealing ring 182 may be rubber or other resin material.

For example, although not shown, the connecting nut 270 may be provided in the first unit 100 instead of the second unit 200 as shown in FIGS. 1 to 6. That is, although not shown, one end is supported around the first body 110 and may be screwed to the outer circumferential surface of the second body 210 that is fitted to the first body 110. For example, a front stepped portion of the bending nut of the connecting nut 270 may be formed on the circumferential front side of the first body 110 to define a range in which the connecting nut 270 is engaged with the outer circumferential surface of the second body 210. have.

1 to 4 and 6, in one example, the first unit 100 may further include a fixing stand 190. Fixture 190 is coupled to one side of the circumference of the first body 110 and may allow the first unit 100 to be fixed to a fixture, such as a wall, column, floor, frame, other device or device, such as a building, equipment, etc. have. For example, the fixture 190 may be coupled to the circumference of the second body 210 of the second unit 200 to be described later, not the first unit 100.

[Second unit 200]

Next, the second unit 200 will be described with reference to FIGS. 1 to 6. For example, a part of the second unit 200 may be inserted into the first unit 100 and may be combined with the first unit 100. In one example, the second unit 200 includes a second body 210 and a second valve body 230. Also, in one example, the second unit 200 may further include a second guide 250 and a second spring 260. In another example, the second unit 200 may further include a connecting nut 270. In one example, the second unit 200 can further include a tubular connector 280. The detailed configurations of the second unit 200 will be described in detail. In this case, various embodiments of the second unit 200 may be implemented through a combination of various implementation examples of detailed configurations of the second unit 200.

Second body 210

1 to 6, the second body 210 is detachably fitted to the first body 110. 1 to 4, the second body 210 has a second through hole 210a formed therein and is detachably fitted to the first through hole 110a of the first body 110. When the second body 210 is fitted to the first body 110, the front body is opened by pushing the slider 140 in the advanced state of the first valve body 130. For example, the first valve body 130 in the forward state pushes the second valve body 230 together with the operation of pushing the slider 140 and opening the front flow path according to the fitting of the second body 210. The flow path of the second through hole 210a may be opened. In the pushing direction of the slider 140 of the second body 210 and in the pushing direction of the second valve body 230 of the first valve body 130, they are opposite to each other. The front flow path means a flow path outside the circumference of the first valve body 130, and the flow path of the second through-hole 210a opened by the second valve body 230 is opposite to the circumference outside of the second valve body 230. Means a flow path between the inner peripheral surface of the second through hole (210a).

For example, in one example, the flow passage of the first through hole 110a in the first body 110 and the second through hole 210a in the second body 210 may be in a forward state of the first valve body 130. In the case where the second body 210 is fitted and the first and the second body (110, 210) in the combined state of the cam projection (122a) in front of the rotation of the first valve body 130 is advanced The front part is separated from the slider 140 so that the inner flow path of the slider 140 and the front flow path are connected to each other. In addition, blocking of the flow path of the first and second through holes 110a and 210a is performed by separating the second body 210 in the advanced state of the first valve body 130 and the slider 140 blocking the front flow path. The first valve when the second valve body 230 blocks the second through hole 210a and rotates to the rear side of the cam protrusion 122a in the combined state of the first and second bodies 110 and 210. When the sieve 130 retreats and the front part of the first valve body 130 comes into close contact with the slider 140, the internal flow path of the slider 140 is blocked.

For example, in one example, the second body 210 may include a valve seat 211 formed with a smaller inner diameter of the front side than the rear side on the inner circumferential surface of the second through hole 210a. The valve seating portion 211 may be seated with a second valve body 230 advanced forward, for example, a second sealing portion 233 of the second valve body 230. For example, the valve seat 211 may be formed on the front inner circumferential surface of the second through hole 210a. The valve seating portion 211 may be gradually formed in the inner circumferential surface of the second through hole 210a from the rear side to the front side, or may form a stepped step with a smaller inner diameter or a smaller inner diameter of the front side than the rear side. For example, when the inner circumferential surface of the second through hole 210a forms a step and the valve seat 211 is formed, the second sealing part 233 of the second valve body 230 may be formed of, for example, the second valve part 232. It is formed on the front surface and may be seated on the valve seat 211 according to the movement forward. Alternatively, referring to FIGS. 1 to 3, when the inner circumferential surface of the second through hole 210a is gradually reduced from the rear side to the front side, the inner diameter of the second through hole 210a forms a valve seat 211, and the valve seat 211 is one. It may be provided with a plurality of inclined surfaces or curved structures formed stepped in order or inclined. At this time, the second valve portion 232 of the second valve body 230 forms a ring groove around the at least partly matched to the structure of the valve seat 211 and the second sealing portion 233 is installed in the ring groove. Can be.

For example, in one example, a screw thread coupled to the second guide 250 may be formed on the rear inner circumferential surface of the second through hole 210a of the second body 210.

For example, the second body 210 may have a stepped protrusion protruding outward from the front circumference thereof to define a fitting to an insertion length of the second body 210 into the first body 110. For example, the protruding stepped portion formed around the front side of the second body 210 is formed in the shape of a protrusion in the cross section, and the front stepped portion of the protrusion defines the insertion or insertion length of the second body 210, and the rear stepped portion of the protrusion is the connecting nut. One end of the 270 may be formed. For example, the locking protrusion 213 is formed around the front side of the second body 210 so that the front surface of the locking protrusion 213 serves to limit the fitting to the insertion length of the second body 210, and the locking protrusion The rear surface of 213 may serve to limit the fastening range of the connecting nut 270. Alternatively, although not shown, a thread is formed on the outer circumferential surface formed by a protruding step defining, for example, fitting or insertion of the second body 210 around the front side of the second body 210. The other end of the connecting nut 270 having one end supported around the 110 may be screwed with the outer circumferential thread of the second body 210.

For example, the tubular connector 280 may be coupled to the rear of the second body 210. In this case, a sealing ring is installed and a thread is formed around the outer circumferential surface of the second body 210 to form a thread. Screwed to 280 and can be kept airtight.

Second valve body 230

1 to 4, the second valve body 230 is elastically supported in the second through hole 210a of the second body. The second valve body 230 is in close contact with the inner circumferential surface of the second through hole 210a when the second body 210 is separated, and blocks the second through hole 210a. In addition, the second valve body 230 abuts against the first valve body 130 advanced according to the rotation of the cam 122 when the second body 210 is fitted and the flow path of the second through hole 210a. To open.

1 to 4, in one example, the second valve body 230 may include a second shaft portion 231, a second valve portion 232, and a second sealing portion 233. The rear side of the second shaft portion 231 is inserted into the second guide hole 251 and slides. The second valve portion 232 may be integrally formed or screwed in front of the second shaft, and the second valve portion 232 may be coupled.

The second valve part 232 is formed in front of the second shaft part 231 to contact the first valve body 130 when the first and second through holes 110a and 210a communicate with each other. Forming a front portion of 230. In addition, the second valve portion 232 is larger than the minimum inner diameter of the valve seat 211 in the direction of the inner circumferential surface of the second through hole 210a. For example, the valve seat 211 may be a single inclined plane, a sequential inclined plane to a curved structure, or a vertical plane perpendicular to the inner circumferential surface of the second through hole 210a, the diameter of which extends from the front side to the rear side, in each case. 2 The periphery of the valve portion 232 has an installation surface on which the second sealing portion 233 is installed so as to be parallel to or facing the seating surface of the valve seat 211, and the second sealing portion 233 on the installation surface. Ring groove is installed may be formed. For example, one end of the second spring 260 may be supported on the rear surface side of the second valve unit 232. For example, a groove structure may be formed on the rear surface of the second valve part 232 and one end of the second spring 260 may be supported by the groove structure. When the flow path of the second through hole 210a is blocked, the front face of the second valve part 232 exposed from the front side is flat and, for example, has the same size as or substantially matches the front face of the first valve part 132. Can have That is, just before the second body 210 falls from the front end of the slider 140 after the flow path communication, the front flow path outside the circumference of the first valve part 132 and the flow path outside the circumference of the second valve part 232. In addition, the front surface of the second valve portion 232 and the front surface of the first valve portion 132 abut so that the fluid space is not formed between the first valve body 130 and the second valve body 230. 2 When the separation of the body 210 can be minimized or no leakage of fluid.

The second sealing part 233 is installed around the second valve part 232 and maintains the airtightness between the valve seat 211 and the second valve part 232 when the second body 210 is separated. For example, the second sealing part 233 may be a rubber or resin sealing ring.

Second guide 250

1 to 4, in another example of the present invention, the second unit 200 may further include a second guide 250 and a second spring 260. The second spring 260 will be described later.

The second guide 250 includes a second guide hole 251 for guiding the sliding of the second valve body 230. For example, the second guide 250 is fixed in the second through hole 210a or is formed in the center by a plurality of branches protruding inward from the inner circumferential surface of the second through hole 210a. ) And the second guide 250 may be formed by a plurality of branches forming the second guide hole 251. In one example, the second guide 250 may be fixedly installed in the second through hole 210a. For example, the second guide 250 is inserted or screwed in the rear side of the second body 210 and fixedly installed or fixed on the rear inner circumferential surface of the second through hole 210a at the front side of the second body 210. Can be installed. For example, the second guide 250 may have the same or similar structure as the first guide 150.

In one example, the second guide 250 may be screwed with the rear inner circumferential surface of the second through hole 210a at the outermost circumference to form a flow path around the second guide hole 251. For example, the second guide 250 has a plurality of branches protruding radially around the second guide hole 251 to form a triangular shape, for example, and the outermost periphery is fixedly installed on the inner circumferential surface of the second through hole 210a, For example, it can be screwed and fastened. In this case, an empty space between the branches and the inner circumferential surface of the second through hole 210a may form induction. For example, alternatively, a plurality of through-holes may be formed in the disc plate around the second guide hole 251.

For example, the other end of the second spring 260 may be supported on the radial branches or the circular plate around the second guide hole 251 of the second guide 250.

Second spring 260

1 to 4, the second spring 260 is installed around the circumference of the second valve body 230, one end of which is supported by the second valve body 230, and the other end of which corresponds to the second guide 250 or It is supported by the inner surface of the second through hole 210a. The second spring 260 provides elastic force to the second valve body 230 so that the flow path of the second through hole 210a is blocked by the second valve body 230 when the second body 210 is separated. That is, when the second body 210 is inserted and fastened into the first through hole 110a of the first body 110, the front part of the first valve body 130, for example, by the first valve part 132. When the second valve body 230 is pushed and the second spring 260 contracts, the second body 210 is separated, and retracted backward, the second spring 260 provides an elastic force and the second valve body 230 ) To block the second through hole 210a, and the cam protrusion 122a rotates to the rear side (in the opposite direction to the rear side of the second body 210) while the second body 210 is engaged. Accordingly, the second spring 260 may provide an elastic force and allow the second valve body 230 to block the second through hole 210a.

For example, the second spring 260 may be installed around the circumference of the second shaft portion 231 and one end thereof may be supported on the rear side of the second valve portion 232.

Connecting nut (270)

1 to 6, in one example, the piping connecting device may further include a connecting nut 270. The connecting nut 270 may be screwed to the outer circumferential surface of the first body 110, one end of which is supported around the second body 210 and to which the second body 210 is fitted. When fitting the second body 210, the second body 210 may be fitted by turning the connecting nut 270. For example, around the second body 210 on which one end of the connecting nut 270 is supported, a step, for example, a protrusion is formed at the front side to define a range in which the connecting nut 270 is engaged with the outer circumferential surface of the first body 110. 213 may be formed. The locking protrusion 213 may limit the fitting to the insertion length of the second body 210 at the front side, and may limit the fastening range of the connecting nut 270 at the rear side. For example, the connecting nut 270 has one end bent inwardly and the bent portion is caught by the rear surface of the locking protrusion 213 formed around the front side of the second body 210 and is formed on the inner circumferential surface of the connecting nut 270. And a screw thread formed around the first body 110 may be fastened, and the first body 110 and the second body 210 may be coupled to each other.

Tubular connector (280)

1 to 6, in another example of the present invention, the second unit 200 may further include a tubular connector 280. The pipe connector 280 is fastened to the rear side of the second body 210 may be connected to the pipe. For example, at this time, a sealing ring for maintaining the airtightness of the connecting portion may be installed around the rear side of the second body 210, the tubular connector 280 is the nut side to the rear side of the second body 210 Can be fastened to. For example, the pipe connector 280 may form various diameters of portions connected to the pipe side so as to be selected and fastened according to various pipe diameters.

Although not shown, when the second unit 200 does not include the pipe connector 280, the rear side of the second body 210 may be directly connected to the pipe side.

In the foregoing description, the above-described embodiments and the accompanying drawings are not limited to the scope of the present invention, but are described by way of example to help those skilled in the art to understand the present invention. In this case, various modifications may be obviously implemented according to various combinations of the above-described components by those skilled in the art. That is, various embodiments of the present invention may be implemented in various modified forms according to various combinations of the above-described components without departing from the essential characteristics of the present invention. Therefore, the scope of the present invention should be interpreted according to the invention described in the claims and includes various modifications, alternatives, and equivalent embodiments by those skilled in the art as well as the above-described embodiments.

100: first unit 110: first body
110a: first through hole 110b: cam hole
111: step portion 112: support groove
113: stopper 115: cam stopper
120: operation cam 121: cam shaft
122: cam 122a: cam protrusion
122b: hook portion 123: locking pin
130: first valve body 131: first shaft portion
131a: fastening groove 132: first valve portion
133: first sealing portion 135: cam coupling portion
135a: arc-shaped end of the plate 135b: locking jaw
135c: fastening pin 140: slider
141: seating portion 150: first guide
151: first guide hole 160: first spring
170: third spring 181: through hole sealing ring
182: cam hole sealing ring 190: fixed base
200: second unit 210: second body
210a: second through hole 211: valve seat
213: locking projection 230: second valve body
231: second shaft portion 232: second valve portion
233: second sealing portion 250: second guide
251: second guide hole 260: second spring
270: connecting nut 280: tubular connector

Claims (12)

A piping connecting device comprising a first unit and a second unit and detachably coupled to each other,
The first unit is:
A first body having a cam hole penetrating into an inner first through hole at one side of the circumference;
An operation cam including a cam shaft penetrating the cam hole and a cam formed around the cam shaft in the first through hole;
A first guide formed in the first through hole and having a first guide hole;
A first valve body penetrating the first guide hole and moving forward and backward in the first through hole as the cam rotates; And
And a slider that is elastically supported in the first through hole and slides along an inner circumferential surface of the first through hole and opens and closes a front flow path formed around the first valve body, which is advanced according to the rotation of the cam.
The second unit is:
A second body having a second through hole formed therein and detachably fitted to the first through hole of the first body, and opening the front flow path by pushing the slider in a forward state of the first valve body; And
It is elastically supported in the second through hole and is in close contact with the inner circumferential surface of the second through hole when the second body is separated, and is advanced according to the rotation of the cam when blocking the second through hole and engaging the second body. And a second valve body which abuts against the first valve body and opens a flow path of the second through hole.
Piping connecting device with cam.
In claim 1,
The flow passage of the first and second through-holes is based on the case where the second body is fitted in the forward state of the first valve body and when the first and second bodies are engaged, the rotation of the cam protrusion toward the front side. The first valve body is advanced and the front part is separated from the slider, and the internal flow path of the slider is connected to the front flow path,
Blocking the connection flow path of the first and second through holes is that the second body is separated in the advancing state of the first valve body, the slider blocks the front flow path, and the second valve body blocks the second through hole. And the first valve body is retracted in accordance with the rotation of the cam protrusion to the rear side in the engaged state of the first and second bodies, and the front part of the first valve body is in close contact with the slider to allow the internal flow path of the slider to be close. The piping connecting device provided with a cam characterized by the above-mentioned.
In claim 2,
The first guide is fixedly installed in the first through hole,
The first unit has one end supported by the slider and the other end supported by the first guide or the inner surface of the first through hole, and the slider is fitted when the second body is fitted in the forward state of the first valve body. With the retraction of the slider along with the retraction of the first valve body by providing a resilient force to the slider so as to retract with the retraction and the front flow path to be blocked when the second body is separated and to the rear side of the cam projection. Further comprising a contracting first spring,
The second unit may include: a second guide having a second guide hole for guiding sliding of the second valve body and fixedly installed in the second through hole; And one end supported by the second valve body and the other end supported by the second guide or the inner surface of the second through hole, the second valve being separated when the second body is detached. And a second spring for providing an elastic force to the second valve body so that the flow path of the second through hole is blocked by the sieve.
In claim 3,
The second body has a valve seat formed in the front side is smaller than the rear side on the inner circumferential surface of the second through hole is formed,
The second guide is screwed with the inner peripheral surface of the rear side of the second through hole in the outermost circumference to form a flow path around the second guide hole,
The second valve body may include a second shaft part having a rear side inserted into the second guide hole and sliding in front of the second shaft part to communicate with the first and second through holes in a flow path. A second valve portion which is formed in front of the second valve body which is in contact with the second valve hole and is enlarged in a direction of the inner circumferential surface of the second through hole to be larger than the minimum inner diameter of the valve seating portion, and the second valve portion; When the separation includes a second sealing portion for maintaining the airtight between the valve seat and the second valve,
The second spring is installed around the circumference of the second shaft portion and one end is supported on the rear side of the second valve portion,
And the second unit further comprises a pipe connector fastened to the rear side of the second body and connected to the pipe.
In claim 2,
The first unit is installed around the circumference of the first valve body, one end of which is supported by the rear portion of the first valve body, the other end of which is supported by the first guide or the inner surface of the first through hole, and the cam protrusion And a third spring for providing a resilient force for retraction of said first valve body in accordance with rotation to the rear side of said first valve body.
In claim 2,
The rear portion of the first valve body forms a cam engaging portion that is engaged with the cam,
When the cam projection is rotated to the rear side, the opposite side of the cam projection is fastened to the cam engaging portion, characterized in that the cam pulls back the first valve body in accordance with the rotation to the rear side, provided with a cam One plumbing connecting device.
In claim 6,
The cam has a hook portion protruding up and down on the opposite side of the cam projection,
The cam engaging portion is characterized in that the pair of plates having a concave arcuate end concave to the horizontal rear side and a locking jaw vertically protruding from the arc-shaped end is pulled by the hook portion is formed up and down symmetrical, Piping connecting device.
In claim 7,
The cam hole is formed so as to penetrate into the first through hole in a portion protruding from the peripheral peripheral surface around the first body,
The operation cam further comprises a locking pin protruding around the upper end of the cam shaft protruding from the cam hole,
The first body is formed on the inner circumferential surface of the first through hole facing the cam hole to support the lower end of the cam shaft, protruding from the upper end of the cam hole and the stopper for limiting the rotation range of the locking pin and And a cam stopper fastened to the protruding portion where the cam hole is formed to cover the operation cam.
In any one of claims 1 to 8,
The first body has a diameter of the first through hole is smaller than the outer diameter of the slider and stepped to define a step of limiting the retraction of the slider or to support the elastic support of the slider,
The first guide is screwed with the inner peripheral surface of the rear side of the stepped portion of the first through hole in the outermost circumference to form a flow path around the first guide hole,
The first valve body may include a first shaft portion penetrating the first guide hole and a front portion of the first shaft portion to contact the second valve body when the first and second through holes communicate with each other. A first valve portion which forms a front portion of the valve body and is larger than the diameter of the inner flow path of the slider and smaller than the diameter of the inner circumferential surface in the direction of the inner circumferential surface of the first through hole on the front side of the first guide, and the first valve portion And a first sealing part installed at a circumference and maintaining airtightness between the slider and the first valve part when the front flow path and the internal flow path are blocked.
In claim 9,
The slider has a seating portion that is in close contact with the first sealing portion to form a tapered inclined surface or curved surface toward the rear on the inner circumferential surface of the inner flow passage,
One end of the elastic support for elastically supporting the slider is supported by a groove formed in the rear surface to the rear surface of the seating portion formed by the inner protrusion of the seating portion,
The size of each of the front end of the slider and the front end of the second body, the size of each of the front surface of the first valve portion and the front surface of the second valve body, and the front end of the slider when the internal flow path of the slider is blocked. The size of each of the protruding length of the front surface of the first valve portion that protrudes more and the retracting length of the front surface of the second valve body that is retracted from the front end of the second body when the second through hole is blocked are matched with each other. The piping connecting device provided with a cam characterized by the above-mentioned.
In any one of claims 1 to 8,
The first unit is installed in a plurality of ring grooves formed on the inner peripheral surface of the front coupling side of the first through hole, and when the second body is fitted, the inner peripheral surface of the first through hole and the outer peripheral surface of the slider and the inner peripheral surface of the first through hole. At least one cam hole installed in the at least one ring groove formed in the inner circumferential surface of the cam hole and through hole sealing rings to maintain the airtightness between the outer circumferential surface of the second body and the at least one cam hole. A piping connecting device with a cam, further comprising a sealing ring.
In any one of claims 1 to 8,
The second unit is further provided with a cam, characterized in that the one end is supported around the second body and the second nut is screwed with the outer peripheral surface of the first body is coupled Piping connecting device.

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