KR100492926B1 - Hydraulic coupler combined use of gas injector - Google Patents

Abstract

The present invention relates to a hydraulic coupler for supplying hydraulic pressure to various equipment by connecting a socket serving as a supply valve and a plug serving as an inlet valve. More particularly, the hydraulic coupler is screwed into a socket and a plug. The hydraulic coupler can be easily fixed to various equipments, and the connecting portion of the hydraulic coupler is double sealed and supported by the sleeve installed with the plug pin. It is very easy to perform, and it completely blocks leakage of fluid and breakage of the connection part due to vibration or shock applied to the hydraulic coupler, and thus it can be easily applied to not only liquid working fluid but also gas working fluid. The present invention relates to a gas coupler combined hydraulic coupler.

The gas injector-coupled hydraulic coupler according to the present invention is composed of a socket 30 and a plug 40 serving as a supply valve and an inlet valve, and the socket 30 has an interior of a socket cap 31 forming a body. The socket pin 32 for opening and closing the front discharge port is elastically installed in the state with the coil spring 34 interposed therebetween, and the plug 40 has a coil for opening and closing the front inlet hole in the plug cap 41 forming the body. A spring 44 is installed, and a ring fitting portion 314 is formed on the inner circumferential surface of the front end of the socket cap 31 to insert a sealing ring 313 in contact with the front end of the plug cap 41. On the outer circumferential surface of the plug cap 41, a socket nut 47 fastened to the male thread portion 311 of the socket cap 31 is installed to be movable along the plug cap 41, and the tip end of the plug cap 41 is provided. The stopper 48 is fitted to block the movement of the socket nut 47, the plug A cylindrical sleeve 50 is inserted between the inner surface of the lug cap 41 to the front side of the coil spring 44 to be elastically movable along the inner surface of the plug cap 41. A male screw portion 311 is formed on the outer circumferential surface of the 31 and a support hole 33 and a pressure bolt 35 for opening and closing the front discharge port are installed therein, and the front inlet opening and closing is opened inside the plug cap 41. The support 43 and the pressure bolt 45 are installed with the plug pin 42 interposed therebetween, and the plate spring 38 and the fixing nut 37 are provided on the outer circumferential surface of the socket cap 31 with a male screw part ( It is inserted into the 311, characterized in that the front and rear outer peripheral surface of the sleeve 50 is inserted into the sealing ring 51 having a rectangular cross section and the O-ring 52 having a circular cross section.

Description

Hydraulic Coupler combined use of gas injector}

The present invention relates to a hydraulic coupler for supplying hydraulic pressure to various equipment by connecting a socket serving as a supply valve and a plug serving as an inlet valve. More particularly, the hydraulic coupler is screwed into a socket and a plug. The hydraulic coupler can be easily fixed to various equipments, and the connecting portion of the hydraulic coupler is double sealed and supported by the sleeve installed with the plug pin. It is very easy to perform, and it completely blocks leakage of fluid and breakage of the connection part due to vibration or shock applied to the hydraulic coupler, and thus it can be easily applied to not only liquid working fluid but also gas working fluid. The present invention relates to a gas coupler combined hydraulic coupler.

In general, the hydraulic coupler is used to supply hydraulic pressure from a hydraulic source such as a hydraulic pump, a hydraulic motor, or a hydraulic cylinder to various hydraulic devices or driving units of the hydraulic device, and as shown in FIGS. 1 and 2. It is composed of a combination of the socket 10 is connected to the output shaft to serve as a hydraulic supply valve, and the plug 20 is connected to the input shaft of various hydraulic devices or hydraulic equipment to serve as a hydraulic inlet valve.

The socket 10 constituting the conventional hydraulic coupler as described above, the socket pin 11 for opening and closing the front outlet 10a is provided in the interior of the body forming the hydraulic passage 16, the socket pin 11 At the rear of the), the tricycle-shaped support 13 to which the socket pin 11 is movably inserted through the guide hole 13a is fixedly installed in the socket 10 by the fixing ring 14, and the socket A coil spring 12 is inserted between the pin 11 and the support 13 to press the socket pin 11 toward the discharge port 10a side.

In addition, the plug 20 constituting the conventional hydraulic coupler is provided with a plug pin 21 for opening and closing the front inlet port 20a inside the body forming the hydraulic passage 26, and the plug pin 21. At the rear of the tricycle-shaped support 23 is inserted into the plug pin 21 so as to be movable through the guide hole (23a) is fixed to the inside of the plug 20 by the fixing ring 24, the plug pin Between the 21 and the support 23, a coil spring 22 for pressing the plug pin 21 toward the inlet 20a side is inserted.

And, in the rear inner side of the socket 10 and the plug 20, threaded portions 15 and 25 for fastening the socket 10 and the plug 20, respectively, are formed at the output side of the hydraulic supply source and the input side of the hydraulic equipment. In order to connect the socket 10 and the plug 20 integrally, a groove portion 17 is formed in the front outer circumferential surface of the socket 10, and a ball bearing 27 inserted into the groove portion 17 at the tip portion of the plug 20. Socket cover 28 provided on the inner circumferential surface thereof.

In the state in which the socket 10 and the plug 20 formed as described above are faced to each other, the socket 10 until the ball bearing 27 of the socket cover 28 is caught by the groove 17 of the socket 10. ) And the plug 20 are pushed while pressing each other, the socket pin 11 and the plug pin 21 compresses the respective coil springs 12 and 22 while guiding holes of the supports 13 and 23. 13a and 23a, which moves backward, whereby the socket pin 11 and the plug pin 21 open the outlet 10a and the inlet 20a, respectively, as shown in FIG. The hydraulic passages 16 and 26 of the hydraulic coupler consisting of the socket 10 and the plug 20 are to be connected.

However, in the conventional hydraulic coupler as described above, the coil springs 12 and 22 provided at the rear of the socket pin 11 and the plug pin 21 have a constant width (a gap such that the ball bearing can be caught in the groove of the socket). Since it needs to be compressed as much as possible, a large amount of force is required to connect the socket 10 and the plug 20, and the socket 10 and the plug 20 are brought into contact with the socket pin 11 and the plug pin 21. If the socket pin 11 and the plug pin 21 are displaced from each other by the elasticity of the coil springs 12 and 22 during pressurization), the worker performing the connection work may be easily injured in the hand. There was a problem that the connection of the coupler is rather difficult to perform easily.

In addition, since the hydraulic coupler has a connection structure by the ball bearing 27, the flow of the socket 10 or the plug 20 easily occurs around the groove 17 into which the ball bearing 27 is inserted. As a result, when shock or vibration occurs in the hydraulic coupler in the process of supplying the working fluid using the conventional hydraulic coupler, the hydraulic coupler generates a lot of flow around the connection part, causing the hydraulic coupler to break down and leakage of the working fluid. It caused the same problem.

In particular, the contact surface of the socket pin 11 and the plug pin 21, which is elastically supported by the coil springs 12 and 22, is in line with the connection portion of the hydraulic coupler to further flow the hydraulic coupler as described above. Due to this, the conventional hydraulic couplers have no problem in the use of highly viscous fluids such as oil, but when used as a supply pipe for gas that is harmful or explosive to humans, There was a problem that always involved risk.

In order to solve the problems caused when using the conventional hydraulic coupler for the gas supply pipe as described above, the hydraulic passage of the supply coupler (socket) connected to the gas storage tank is formed in two stages and supplied inside Resilient installation of the first and second sealing members (socket pins) to seal the coupler, so that gas filled in the gas storage tank does not leak from the supply coupler even if the connection part, which is a weak part of the coupler, is broken. An injection coupler is known and described in Korean Laid-Open Patent Publication (Publication No. 1998-085236).

However, since the gas injection coupler also has the same ball bearing connection structure as the conventional hydraulic coupler, the leakage of gas due to breakage of the connection portion can be blocked as the second sealing member, but the coupler does not cause any damage. The gas leak from the connection part of the coupler could not be completely blocked while supplying gas from the gas storage tank in the state, and this problem is more likely to cause a dangerous situation such as a large accident than the former case. It became a factor.

The present invention has been made in order to solve the conventional problems as described above, the gas injector combined hydraulic coupler according to the present invention by connecting the hydraulic coupler by screwing the socket and the plug, and the various hydraulic couplers connected in this way It can be easily fixed on the plug, and the coupling part of the hydraulic coupler is double sealed and supported by the sleeve installed with the plug pin, so that the connection between the socket and the plug can be performed very easily, The technical problem is to completely block the leakage of the fluid due to vibration or shock, thereby allowing the hydraulic coupler of the present invention to be easily applied to the working fluid in the gas form as well as the working fluid in the liquid form.

The present invention for achieving the above technical problem, consisting of a socket and a plug serving as a supply valve and an inlet valve, the socket is a socket pin for opening and closing the front outlet in the interior of the socket cap forming the body coil spring It is installed elastically in the state, the plug is installed inside the plug cap to form the body of the front of the coil spring for opening and closing the front inlet, a ring fitting portion is formed on the inner peripheral surface of the front end of the socket cap of the plug cap A sealing ring contacting the distal end is inserted and installed, and a socket nut fastened to the male threaded portion of the socket cap is movable along the plug cap on the outer circumferential surface of the plug cap, and the socket nut is blocked at the distal end of the plug cap. A stopper is fitted, and a cylindrical sleeve is disposed between the inner side of the plug cap. Inserted in the direction to be elastically movable along the inner surface of the plug cap, the outer circumferential surface of the socket cap is formed with a male screw portion and a support and pressure bolt for opening and closing the front outlet is installed therein, A support and a pressure bolt are installed in a state where a plug pin for opening and closing a front inlet is interposed therebetween, and a plate spring and a fixing nut are inserted into an external thread part on an outer circumferential surface of the socket cap 31, and the front surface of the sleeve The rear outer circumferential surface is characterized in that the sealing ring having a rectangular cross section and the O-ring having a circular cross section is inserted.

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The present invention for achieving the above object will be described in detail with reference to the accompanying drawings.

Figure 3 (a) and (b) is a side cross-sectional view showing a socket and a plug of the hydraulic coupler according to the present invention, Figure 4 is an exploded perspective view showing the internal structure of the plug of the hydraulic coupler according to the present invention, reference numeral In the description of the reference numerals 31a and 41a are the tightening nut, 31b and 41b is the fastening portion, 35a and 45a is the pressing nut, 41c is a stopper groove portion.

The gas coupler combined hydraulic coupler according to the present invention is connected to the output side of various hydraulic supply sources such as a hydraulic pump, a hydraulic motor, or a hydraulic cylinder like a general hydraulic coupler, and serves as a hydraulic supply valve, and various hydraulic devices or It is made as a plug 40 connected to the input side of the hydraulic device to serve as an inlet valve of the hydraulic pressure.

The socket 30 constituting the hydraulic coupler of the present invention, as shown in (a) of Figure 3, and the opening and closing the front outlet in the socket cap 31 forming the body, and the socket cap 31 Socket pin 32, triangular support 33 is inserted into the transfer rod 321 of the socket pin 32 to be moved along the guide hole 331, the support 33 and the socket Coil springs 34 inserted between the pins 32 to press the socket pins 32 toward the outlet side, and press bolts 35 engaged to the rear ends of the socket caps 31 to press the support holes 33. O-ring 36 is inserted into the coupling portion 31b of the socket cap 31 and the pressure bolt 35 to seal the working fluid to advance the hydraulic passage 353 of the socket 30. Will be performed.

A male screw portion 311 is formed on the front outer circumferential surface of the socket cap 31 so that the fixing nut 37 is fastened to the male screw portion 311 with the plate spring 38 interposed therebetween, and the socket cap 31 is provided. Fastening nut 31a is integrally formed on the rear outer circumferential surface of the socket 30 so that the socket 30 can be easily fixed to various facilities by the fixing nut 37 and the disc spring 38. The locking jaw 312 protrudes on the inner circumferential surface thereof, and a ring fitting portion 314 into which the sealing ring 313 is inserted is formed at the front side thereof, and the head of the socket pin 32 is supported on the rear inclined surface side thereof.

The packing 322 for sealing the outlet of the socket 30 by the elastic force of the coil spring 34 is installed in close contact with the outer peripheral surface of the head of the socket pin 32 on the rear of the head of the socket pin 32, the coil In order to prevent damage to the packing 322 by the spring 34, the pin plate 323 is installed in close contact with the packing 322, the pressure bolt 35 is fastened to the rear end of the socket 30 is On the output side of the pressure end 351 is fastened to the inside of the socket cap 31 to press the support 33, the pressure nut 35a for easily tightening the pressure bolt 35 and the hydraulic supply source (not shown) Supply pipe fastening portion 352 to be connected is formed integrally with the body.

The plug 40 constituting the hydraulic coupler of the present invention, as shown in Fig. 3 (b), is installed exposed through the front inlet from the inside of the plug cap 41 and the plug cap 41 to form a body Inserted into the plug pin 42, the sleeve 50 inserted between the front inner surface of the plug cap 41 and the rear surface of the plug pin 42, and the fixing rod 421 of the plug pin 42 is inserted. The tricycle support 43 is inserted into the ball 431 to be supported by the closing portion 432, and is inserted between the sleeve 50 and the support 43 to the sleeve 50 Coil spring 44 for pressing to the head side of the plug pin 42 and the pressing bolt 45 is fastened to the rear end of the plug cap 41 to press the support 43, the plug cap O-ring 46 is inserted into the fastening portion 41b of the 41 and the pressure bolt 45 to drive the hydraulic passage 453 of the plug 40. The sealing function is performed.

On the outer circumferential surface of the plug cap 41, a socket nut 47 formed on the inner circumferential surface of the body with a female thread part 471 screwed to the male thread part 311 of the socket cap 31 moves along the plug cap 41. The groove 41c, which is installed to be possible and formed at the distal end of the plug cap 41, is fitted with an annular stopper 48 to prevent the socket nut 47 from being pulled out of the plug cap 41, and the plug cap 41 Fastening nut (41a) is integrally formed on the rear outer periphery of the) so that the pressure bolt 45 can be easily fastened.

The pressure bolt 45 is fastened to the inside of the plug cap 41 to press the support end 43 to press the support member 43, and the pressure bolt (tightening bolt 41a together with the tightening nut 41a of the plug cap 41) A press nut 45a for easy tightening 45 and an inlet pipe fastening portion 452 connected to the input side of various hydraulic equipment or hydraulic equipment (not shown) are integrally formed with the body.

Figure 4 shows in more detail the internal structure of the plug of the hydraulic coupler according to the present invention, as shown in the sleeve 50 having a cylindrical shape is inserted into the head of the plug pin 42, the sleeve The inner diameter of the 50 is smaller than the diameter of the head of the plug pin 42, so that the sleeve 50 is elastically supported at the head of the plug pin 42 by the coil spring 44 and the support 43. Since the outer diameter of the sleeve 50 is somewhat larger than the diameter of the head of the plug pin 42, the sleeve 50 is connected by the locking step 313 of the socket cap 31 when the socket 30 and the plug 40 are connected. ) Can be pushed back while compressing the coil spring (44).

In addition, the sealing ring 51 is inserted into the front surface of the sleeve 50 having a rectangular cross section, so that the sealing ring 51 is plug pin 42 in a state where the socket 30 and the plug 40 are not connected. Close the inlet of the plug 40, and when the socket 30 and the plug 40 is connected, the sealing ring 51 is in close contact with the engaging jaw 313 of the socket cap 31 The connection portion of the hydraulic coupler is sealed, and an O-ring 52 is inserted into the rear outer circumferential surface of the sleeve 50 to be in close contact with the inner surface of the plug cap 41 to seal the fluid flowing through the hydraulic passage 453. Will be performed.

The installation and working relationship of the gas injector-coupled hydraulic coupler according to the present invention having the above configuration will be described in detail with reference to FIGS. 5 and 6, and FIG. 5 shows an initial state of connecting the hydraulic coupler according to the present invention. 6 shows a state in which the connection of the hydraulic coupler according to the present invention is completed.

First, the support plate 60, into which the socket 30 of the present invention can be inserted, may be directly installed in a hydraulic source not shown, such as a hydraulic pump, a hydraulic motor, or a hydraulic cylinder, or the other equipment or apparatus around the hydraulic source may be used. After fixing the support plate 60, the socket 30 is inserted so that the support plate 60 is positioned between the plate spring 38 and the fixing nut 37, and the fixing nut 37 is attached to the plate spring 38. When tightened to the side, the socket 30 according to the present invention is firmly fixed to the support plate 60, thereby connecting the output side of the hydraulic supply source to the supply pipe fastening portion 352 of the fixed socket 30.

As described above, the socket 30 is first fixed to the support plate 60, and then the input shafts of various hydraulic devices or hydraulic devices face the socket 30 with the plug 40 connected to the inlet pipe fastening part 452. When the socket nut 47 installed on the plug 40 is fastened to the male thread portion 311 side of the socket cap 31, as shown in FIG. 5, the socket pin 32 and the plug pin 42 are formed. At the same time, the front surfaces face each other, and the front surface of the locking jaw 312 of the socket cap 31 comes into close contact with the sealing ring 51 of the sleeve 50. It will be in a state where sealing is performed.

When the socket nut 47 which is fastened to the male thread part 311 of the socket cap 31 continues to be tightened in the above state, the socket pin 32 has its transfer rod 321 guided by the support 33. The plug pin 42 is installed to be movable along the hole 331, and the socket pin (42) is fixed because the fixing rod 421 is blocked by the sealing portion 432 of the support 43, thereby preventing movement. As the 47 is continuously tightened, only the socket pin 32 moves backwards (left side in the drawing) while compressing the coil spring 34 to open the outlet of the socket 30.

In addition, although the plug pin 42 itself is not movable by the support 43, the sleeve 50 installed on the back of the plug pin 42 is movable along the inner surface of the plug cap 41. Since the socket nut 47 is continuously tightened, the sleeve 50, which is in close contact with the engaging jaw 312 of the socket cap 31, compresses the coil spring 44 to the rear (right side in the drawing). Direction) to open the inlet of the plug 40.

When the socket nut 47 fastened to the male thread portion 311 of the socket cap 31 in this manner is completely tightened, as shown in FIG. 6, the socket pin 32 and the sleeve 50 are respectively rearward. When it is pushed out completely, the outlet of the socket 30 and the inlet of the plug 40 are opened to the maximum, and at the same time, the sealing ring 313 inserted into the front of the locking jaw 312 of the socket cap 31 is plugged. In close contact with the tip of the cap 41, a secondary sealing of the connection portion of the hydraulic coupler is made, and when the hydraulic source (not shown) connected to the socket 30 is operated in this state, the socket 30 and the plug Through the open hydraulic passages 353 and 453 of 40, it is possible to supply the hydraulic pressure to the driving units of various hydraulic equipment or hydraulic apparatus.

As described above, even if various shocks or vibrations occur in the hydraulic coupler in the process of supplying the hydraulic pressure using the hydraulic coupler comprising the socket 30 and the plug 40 according to the present invention, the connection portion of the hydraulic coupler according to the present invention is Since the screw-type fastening structure has almost no flow in the connection portion of the socket 30 and the plug 40, the socket 30 according to the present invention by using the plate spring 38 and the fixing nut 37 Since it can be firmly fixed to a variety of facilities it is possible to block the flow generated in the connection portion of the hydraulic coupler in advance, and thereby the leakage of the working fluid to proceed the hydraulic passage (353, 453) of the hydraulic coupler, It is possible to effectively prevent damage to the connection portion of the hydraulic coupler.

In particular, the contact pins of the socket pins 32 and the plug pins 42 are not placed in line with the connecting portion of the hydraulic coupler and are staggered from each other, so that the socket pins 32 and the plug pins 42 are coil springs 34. Even if it is slightly shaken by the elastic force of the), not only does not generate a flow in the connection portion of the hydraulic coupler, but also the end of the socket cap 31 and the end of the plug cap 41 with the sealing ring 313 interposed therebetween. It is in close contact with the hydraulic coupler and seals and supports the connection part of the hydraulic coupler first, and the inside of the locking jaw 312 of the socket cap 31 and the front surface of the sleeve 50 are interposed between the sealing ring 51. Strongly adhered in a state to seal and support the connecting portion of the hydraulic coupler secondly, the connecting portion of the hydraulic coupler is more tightly sealed and fixed, the leakage of working fluid through the connecting portion, the breakage of the connecting portion To be able to almost completely prevented.

As described above, since the hydraulic coupler according to the present invention has excellent fixation and sealing performance at the connection portion, the hydraulic coupler is very suitable for supplying harmful or explosive gas to the human body, including a highly viscous working fluid such as oil. It is easy and safe to use, and as shown in Figs. 1 and 2, only the male screw portion 311 and the socket nut 47 according to the present invention formed in the socket 10 and the plug 20 of the conventional hydraulic coupler Even if it is possible to achieve the performance of the above hydraulic coupler enough.

In addition, when the socket 30 and the plug 40 of the hydraulic coupler according to the present invention are connected, the socket pin 32 and the sleeve 50 of the socket nut 32 are fastened to the male screw portion 311. Since the coil springs 34 and 44 installed at the rear side are automatically compressed, the fastening operation of the hydraulic coupler can be easily performed with a small force, and the socket pins 31 and the socket pins 47 are fastened during the fastening of the socket nuts 47. Since the plug pins 41 are not displaced from each other due to the elasticity of the coil springs 34, there is almost no problem such as a worker being injured in the hand part during the fastening of the hydraulic coupler. It will not be.

As described above, the gas coupler-coupled hydraulic coupler according to the present invention connects a hydraulic coupler by screwing a socket and a plug in a threaded manner, so as to easily fix the connected hydraulic coupler to various facilities, and with a plug pin. The coupling part of the hydraulic coupler is double-sealed and supported by the sleeve to be installed, so that the connection work of the socket and plug can be performed very easily by screwing work, and the process of performing the coupling work of the hydraulic coupler. In the worker has an effect that can prevent problems such as hurting the hand area.

In addition, when the hydraulic coupler is used, there is an effect of almost completely preventing the leakage of the working fluid generated at the connection portion of the hydraulic coupler and damage to the connection portion of the hydraulic coupler due to vibration or shock applied to the hydraulic coupler. Due to this, it is possible to easily and safely apply the hydraulic coupler according to the present invention to the working fluid in the liquid form as well as the working fluid in the form of gas that is harmful or explosive to the human body.

1 is a side cross-sectional view showing a socket and a plug of a conventional hydraulic coupler.

Figure 2 is a side cross-sectional view showing a state in which a conventional hydraulic coupler is connected.

Figure 3 (a) and (b) is a side cross-sectional view showing a socket and a plug of the hydraulic coupler according to the present invention.

Figure 4 is an exploded perspective view showing the internal structure of the plug of the hydraulic coupler according to the present invention.

Figure 5 is a side cross-sectional view showing an initial state for connecting the hydraulic coupler according to the present invention.

Figure 6 is a side cross-sectional view showing a state in which the connection of the hydraulic coupler according to the present invention is completed.

<Explanation of symbols for main parts of drawing>

30 socket 31 socket cap 311 male thread portion

312: engaging jaw 313: sealing ring 314: ring fitting

32: socket pin 321: transfer rod 322: packing

323: pin plate 33: support 331: guide hole

34: coil spring 35: pressure bolt 351: pressure end

352: supply pipe joint 353: hydraulic passage 36: O-ring

37: fixing nut 38: dish spring 40: plug

41: plug cap 42: plug pin 421: fixed rod

43: support 431: insertion hole 432: sealing

44: coil spring 45: pressure bolt 451: pressure end

452: inlet pipe connecting portion 453: hydraulic passage 46: O-ring

47: socket nut 471: female thread 50: sleeve

51: sealing ring 52: O-ring 60: support plate

Claims (2)

(정정) consists of a socket 30 and a plug 40, which serves as a supply valve and an inlet valve, The socket 30 is installed in the socket cap 32 to open and close the front outlet in the socket cap 31 forming the body with the coil spring 34 interstitially installed, the plug 40 is the body A coil spring 44 for opening and closing the front inlet is installed in the plug cap 41 that forms a recess. A ring fitting portion 314 is formed on the inner circumferential surface of the tip end portion of the socket cap 31 to insert a sealing ring 313 in contact with the tip end of the plug cap 41 therein, and an outer circumferential surface of the plug cap 41 is inserted therein. The socket nut 47 is fastened to the male screw portion 311 of the socket cap 31 so as to be movable along the plug cap 41. A stopper 48 is inserted into the distal end of the plug cap 41 to block the movement of the socket nut 47. Between the inner surface of the plug cap 41 is a cylindrical sleeve 50 is inserted into the front side of the coil spring 44 is installed to be elastically movable along the inner surface of the plug cap 41, A male screw portion 311 is formed on an outer circumferential surface of the socket cap 31, and a supporter 33 and a pressure bolt 35 for opening and closing the front discharge port are installed therein. The support cap 43 and the pressure bolt 45 are installed in the plug cap 41 in a state where the plug pin 42 for opening and closing the front inlet is interposed therebetween. On the outer circumferential surface of the socket cap 31, a dish spring 38 and a fixing nut 37 are inserted into the male screw portion 311, Gas coupler combined hydraulic coupler, characterized in that the front and rear outer peripheral surface of the sleeve 50 is inserted into the sealing ring 51 having a rectangular cross section and the O-ring 52 having a circular cross section. ( delete )