KR20160058548A - Pipe connector of space launch vehicle - Google Patents

Abstract

The pipe connector of the projectile according to the embodiment of the present invention is fastened to and fixed to the gas skin and has a fluid inlet port formed at one side thereof to be connected to an external pipe exposed to the outside when the gasket is fastened with the gasket, A fluid inflow portion extending from the inner surface to a central axis direction and having a fluid pipe portion in which a fluid flow path is formed, the fluid inflow portion being disposed in front of the fluid inflow portion and being connected to the fluid inflow portion, And a fluid discharge port connected to the inner pipe of the projectile at a front side to form a fluid discharge port through which the fluid stored in the accommodation space is formed, And the fluid passing through the flow path through sliding movement when the fluid is introduced A spool for discharging the fluid into the receiving space and pushing the fluid received in the receiving space to the inner pipe side of the projectile, and an elastic member disposed in the receiving space for elastically supporting the spool.

Description

Pipe connector of space launch vehicle < RTI ID = 0.0 >

The present invention relates to a pipe connector of a space launch vehicle installed at an end of a pipe connected to a gas skin of a pipe of a projectile.

Generally, projectiles installed at the launch site are connected to umbilical towers through piping to supply electrical signals, high or low pressure gas, air conditioning, fuel, cooling, and hydraulic related fluids from an umbilical tower Receive.

Specifically, the projectile is provided with a plurality of pipelines, and the umbilical tower is provided with an umbilical device connected to the plurality of pipelines to transmit electric signals, high or low pressure gas, air conditioning, fuel, cooling , And fluid related to hydraulic pressure.

In addition, there are a plurality of pipes connected to the above-described umbilical device and a separate pipe connected to the gas skin so as to receive fluid from the outside without being connected to the umbilical device.

At this time, the separate pipe is provided with a bulkhead union having a through-hole structure so that the pipe can communicate with the outside.

The bulkhead union is installed through the gas skin with a tubular structure having a flow path formed on the inner side. One side of the bulkhead union is located on the inner side of the base and is coupled to the end of the pipe, and the other side is exposed to the outside.

Therefore, conventionally, in order to supply the fluid to the inside of the projectile, the cap is separated from the body of the bulkhead union, and fluid is supplied to the inside of the projectile by coupling fluid supply means capable of supplying fluid from the outside to the other end .

However, even after the fluid is supplied to the inside of the projectile, the bulkhead union continuously maintains the state where the cap is separated from the body of the bulkhead union, that is, the flow path is opened, There was a problem.

Therefore, foreign substances in the air flow into the flow path, and foreign matter introduced into the flow path flows into the interior of the projectile through a pipe connected to the flow path, thereby deteriorating the performance of the projectile.

Further, the bulkhead union is fixed to the base skin through fixing bolts arranged on the outside and inside of the base skin to face each other.

Accordingly, the fixing force of the fixing bolt gradually weakens due to the flow generated in the air during the flight, and the bulkhead union is disengaged from the gas.

Korea Public Utility Model Bulletin 20-2012-0003267

 KSLV-I Small Satellite Launch Vehicle Launching System Design (I) - Young-ho Lee, Jin-Bo Jin, Seo Jin Ho, Hong Ilhee, Cho Kwang-rae - Aerospace Technology Vol.3 No.2 (2004.11, p98 ~ 103)

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to solve the above-mentioned problems, and it is an object of the present invention to provide an air- And to prevent a foreign matter from flowing into the inside of the projectile.

According to an aspect of the present invention, there is provided a piping connector for a projectile, the pipeline connector being fixedly coupled to a gas skin and having at one side thereof a fluid that can be connected to an external pipe, A fluid inlet formed on the other side of the fluid inlet portion, a fluid inlet portion extending from the inner surface of the fluid inlet portion along the direction of the central axis to form a fluid pipe portion in which the fluid flow path is formed, A fluid discharging portion formed in a receiving space for receiving the fluid discharged to the outside of the tubular portion on the inner side and formed with a fluid discharge port connected to the inner pipe of the projectile at a front side to discharge the fluid contained in the receiving space, The fluid is introduced into the fluid passage and the accommodation space at the same time, A spool for discharging the fluid passing through the furnace to the accommodating space and pushing the fluid to the inner pipe side of the projectile by applying pressure to the fluid accommodated in the accommodating space, As shown in Fig.

The fluid inlet portion is formed in a cylindrical shape to form a thread on the outer circumferential surface, and a plurality of fastening holes are formed between the fluid inlet port and the oil duct portion, and a flange portion to be riveted to the body skin through the plurality of fastening holes is formed .

And a fluid discharge hole communicating the flow path with the accommodation space may be formed at one point of the oil pipe portion.

Wherein a part of the elastic member is seated on an inner side of the fluid discharge part and a seating groove is formed to surround an outer surface of a part of the elastic member that is seated on the fluid discharge part, A radially protruding locking protrusion of the fluid discharge portion may be formed.

And a binding member that is fastened to the fluid inflow portion and integrally fixes the fluid inflow portion and the fluid discharge portion may be provided outside the connection portion where the fluid inflow portion and the fluid discharge portion are in contact with each other.

The inner circumferential surface of the coupling member may be formed with another thread that can be coupled with a screw thread formed on the outer circumferential surface of the fluid inlet. A hook may be formed on the other inner circumferential surface of the coupling member.

The spool may include a head disposed in the accommodation space and supported on one side of the elastic member, and a rod extending from the head and disposed in the flow path.

The head portion may be formed with a through hole communicating the front space of the head portion where the elastic member is disposed and the rear space of the head portion where the fluid discharged to the outside of the oil pipe portion is received.

And a cap connected to the fluid inlet port to open and close the flow channel.

According to the present invention, when the fluid is supplied through the sliding movement of the spool in the pipe section, the flow path is opened, and when the supply of the fluid is interrupted, the flow path is automatically closed through the elastic restoring force of the elastic member, It is possible to protect the flow path from the outside at all times and prevent the foreign matter from flowing into the projectile.

Further, by integrally fixing the fluid inflow portion to the base skin by riveting, it is possible to maintain a uniform clamping force even when vibrations or tremor generated in the gas are generated, thereby preventing breakage of the component and detachment from the gas.

1 is a cross-sectional view schematically showing a piping connector of a projectile according to an embodiment of the present invention.
2 is a cross-sectional view schematically showing a state in which a piping connector of a projectile according to an embodiment of the present invention is installed on a gas skin.
3 is a schematic view illustrating a process of opening and closing a channel of a piping connector of a projectile according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a cross-sectional view schematically showing a piping connector of a projectile according to an embodiment of the present invention, FIG. 2 is a cross-sectional view schematically showing a state where a piping connector of a projectile according to an embodiment of the present invention is installed on a gas skin, Is a schematic view illustrating a process of opening and closing a channel of a piping connector of a projectile according to an embodiment of the present invention.

1 and 2, a piping connector 100 (hereinafter, referred to as a piping connector 100 of a projectile) of a projectile according to an embodiment of the present invention is connected to a gas skin 200 in a piping of a projectile The present invention relates to a piping connector for a space launch vehicle installed at an end of a piping, and includes a fluid inflow portion 10 fastened to a gas skin 200.

More specifically, the piping connector 100 of the present projectile is fastened to and fixed to the gas skin 200, and is connected to an external pipe 400, which is exposed to the outside when the gasket 200 is fastened to the gas skin 200, And a fluid inlet portion 10 in which a fluid pipe portion 13 is formed on the other side of which a fluid channel 133 is formed extending from the inner surface in the direction of the central axis, do.

The fluid inlet portion 10 is formed in a cylindrical shape and the fluid inlet port 11 is formed on one side and the tubular portion 13 is formed on the other side and a thread 17 is formed on the outer circumferential surface . Illustratively, the threads 17 may be formed as male threads for engagement with a binding member 50, which will be described below.

Further, the fluid inflow section 10 may have the flange section 15.

More specifically, between the fluid inlet port 11 formed at one side of the fluid inlet portion 10 and the oil duct portion 13 formed at the other side of the fluid inlet portion 10, A plurality of fastening holes 151 protruding in the radial direction are formed and a flange portion 15 fastened to the base skin 200 by the rivet 80 through the plurality of fastening holes 151 may be formed.

A fluid discharge hole 131 is formed at one point of the oil pipe portion 13 formed in the fluid inlet portion 10 to communicate the fluid passage 133 with the accommodation space 21 of the fluid discharge portion 20 to be described later .

That is, when the fluid is discharged from the external pipe 400 coupled to the fluid inlet port 11 by using the adapter 500, the fluid outlet hole 131 is formed at the predetermined position in the oil pipe section 13, 133 may be discharged to the receiving space 21 of the fluid discharging portion 20 through the fluid discharging hole 131. For example, the shape, size, and position of the fluid discharge hole 131 can be set according to the amount of the fluid flowing into the flow path 133, the pressure and the velocity of the fluid supplied from the external pipe 400, and the like. For example, the fluid discharge hole 131 formed in the pipe section 13 of the piping connector 100 of the present projectile may be formed in an orifice shape.

Next, the piping connector 100 of the present projectile includes a fluid discharge portion 20.

1 and 2, a piping connector 100 of the present projectile is disposed in front of a fluid inlet portion 10 and is connected to a fluid inlet portion 10, And a fluid discharge port (23) in which a fluid discharge port (23) for discharging a fluid accommodated in the accommodation space (21) is formed in front of the fluid discharge port 20).

The fluid discharge portion 20 is formed in the same cylindrical shape as the fluid inlet portion 10 so that one side of the fluid outlet portion 20 in contact with the fluid inlet portion 10 is open and the other side thereof is connected to the external pipe 400 A fluid discharge port 23 to be connected is formed. At this time, a part of the elastic member 40, which will be described later, is seated on the inner side of the fluid discharge part 20, and a seating groove 211 for covering the outer surface of a part of the seated elastic member 40 may be formed. In other words, a seating groove 211 having a diameter smaller than the diameter of the accommodation space 21 is formed at a predetermined depth on the inner front side of the fluid discharge portion 20. Therefore, the elastic member 40 is seated in the seating groove 211 and can be stably supported. A protrusion 25 protruding in the radial direction of the fluid discharge part 20 may be formed on one side of the fluid discharge part 20 in contact with the fluid inflow part 10 along the outer circumferential surface.

At this time, the fluid inlet 10 and the fluid outlet 20 are integrally fixed to the fluid inlet 10 on the outside of the connecting portion where the fluid inlet 10 and the fluid outlet 20 are in contact with each other, A binding member 50 may be provided.

The coupling member 50 is inserted into the front side of the fluid discharge portion 20 and is supported by the engagement projection 25 formed on one side of the fluid discharge portion 20 and is provided with a thread 17 The fluid inlet portion 10 and the fluid outlet portion 20 disposed on the same central axis can be moved in the directions opposite to each other and fixed integrally. The threaded portion 17 formed on the outer circumferential surface of the fluid inlet portion 10 is formed with another screw thread 53 which is fastenable to one side of the inner circumferential surface of the binding member 50. On the other side inner circumferential surface of the binding member 50, The latching jaw 51 can be formed so as to be hooked on the base 25.

Illustratively, a gasket 70 may be further provided between the fluid inlet 10 and the fluid outlet 20, and the type of material forming the gasket 70 may be varied according to the needs of the user .

Next, the piping connector 100 of the present projectile includes a spool 30 and an elastic member 40.

1 and 2, the piping connector 100 of the present projecting body is disposed at the same time in the flow path 133 and the accommodation space 21 so that the fluid passing through the flow path 133 through the slide movement, A spool 30 for discharging the fluid to the inner pipe 21 and pushing the fluid to the inner pipe 300 side of the projectile by applying pressure to the fluid accommodated in the accommodation space 21 and a spool 30 disposed in the accommodation space 21, And an elastic member 40 for supporting the elastic member 40 in an elastic manner.

The spool 30 includes a head portion 31 disposed in the accommodation space 21 and supported on one side of the elastic member 40 and a rod 33 extending from the head portion 31 and disposed in the flow path 133 ).

The head portion 31 of the spool 30 has an outer shape corresponding to the inside of the fluid discharge portion 20 and is recessed at a certain depth along the axial direction inside the head portion 31 of the spool 30, Another seating groove 313 may be formed in which a part of one side of the elastic member 40, on which a part of the other side is supported, is seated and supported in the seating groove of the portion 20.

The rod 33 extending from the head portion 31 of the shrub has an outer shape corresponding to the inside of the oil pipe portion 13 forming the oil path 133. In the state where it is disposed in the oil path 133, And may be formed to have a length that can block the fluid discharge hole 131 formed in the discharge port 13. That is, the rod 33 may have a length that can block the fluid discharge hole 131 through the outer surface when the fluid is not supplied from the outside. In contrast, when the fluid is supplied from the outside, the rod 33 may be formed to have a length that allows the fluid discharge hole 131 to be exposed to the flow path 133 by moving to the front side by the introduced fluid. Illustratively, in order to prevent a gap between the inner surface of the fluid inlet portion 10 in which the flow path 133 is formed and the rod 33 disposed in the flow path 133 from being generated in the outer peripheral surface on the rear side of the rod 33, (331) can be further installed.

At this time, in the head part 31, the front space of the head part 31 in which the elastic member 40 is disposed and the rear space of the head part 31 in which the fluid discharged to the outside of the oil pipe part 13 is received, A through hole 311 may be formed.

The fluid introduced into the flow path 133 through the fluid inlet port 11 is discharged to the rear side accommodation space 21 of the head part 31 through the fluid discharge hole 131 formed in the tubular section 13 Through the through hole 311 formed in the head 31 of the spool 30 to the front side accommodation space 21 of the head 31. [

Meanwhile, the piping connector 100 of the present projectile may further include a cap 60.

1 and 2, the piping connector 100 of the present projectile may further include a cap 60 which is fastened to the fluid inlet port 11 and opens and closes the flow passage 133.

The cap 60 includes a coupling portion 61 to be coupled to the outer circumferential surface of the fluid inlet port 11 in which a thread 611 is formed and another thread 111 corresponding thereto is formed, And a blocking portion 63 protruding in the axial direction from the fluid inlet port 11 and having a size corresponding to the inner circumferential surface and the length of the fluid inlet port 11 and contacting the end of the fluid inlet portion 10 in which the flow channel 133 is formed. Illustratively, a gasket 70 may be further provided between the end of the fluid inlet 10 in which the flow path 133 is formed and the blocking portion 63 of the cap 60 in contact therewith.

Hereinafter, the opening and closing process of the flow path 133 of the piping connector 100 of the present projectile will be described.

For the sake of explanation, the same reference numerals are used for explaining the piping connector 100 of the projectile and for explaining the opening and closing process of the flow passage 133 of the pipeline connector 100 of the present projectile And redundant description will be omitted.

3 (a), after the external piping 400 is coupled to the fluid inlet port 11 from which the cap 60 is removed, the fluid F is supplied to the flow channel 133. The spool 30 is pushed forward by the pressure of the fluid F and the fluid discharge hole 131 formed in the oil pipe portion 13 is moved And is exposed to the flow path 133. The fluid F that has flowed into the flow path 133 is discharged to the rear side accommodation space 21 of the head portion 31 of the spool 30 and then passes through the through hole 311 formed in the head portion 31 of the spool 30 To the front side accommodation space 21 of the head part 31. [0050] The head 31 of the spool 30 is moved forward by the pressure of the fluid F to pressurize the fluid F contained in the front side accommodation space 21 of the head 31, And is pushed toward the internal piping 300 side of the projectile and discharged.

Referring to FIG. 3 (b), when the supply of the fluid F from the outside is interrupted, the pressure applied to the spool 30 is released, and the compression force of the compressed elastic member 40 is released. The spool 30 which has been resiliently supported on the elastic member 40 is moved back to the rear side by the elastic restoring force of the elastic member 40 and the rod 33 of the spool 30 is again moved back to the oil pipe portion 13 And closes the fluid discharge hole 131 to completely block the outer space and the accommodation space 21. [

As described above, according to the present invention, when the fluid is supplied through the slide movement of the spool 30 in the pipe section 13, the flow path 133 is opened, and when the supply of the fluid is stopped, It is possible to protect the flow path 133 from the outside at all times regardless of the presence or absence of the cap 60 and to prevent foreign matter from flowing into the projectile.

Further, by fixing the fluid inflow part 10 to the base skin 200 by rivet fastening, it is possible to maintain a uniform clamping force even when vibrations or tremor generated in the base body are maintained, Can be prevented.

While the present invention has been particularly shown and described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, And all changes and modifications to the scope of the invention.

100. Piping connector of projectile
10. Fluid inlet
11. Fluid inlet port 111. Threaded
13. Oil pipe section
131. Fluid discharge hole 133. Flow
15. Flange 151. A plurality of fasteners
17. Threaded
20. Fluid outlet
21. The accommodation space 211. The seat groove
23. Fluid drain port
25. Strapping
30. Spool
31. Head
311. Through-hole 313. Placement groove
33. Load 331. O-ring
40. Elastic member
50. Member of binding
51. Jaws 53. Threaded
60. Cap
61. Coupling portion 611. Threaded
63. Blocking section
70. Gasket
80. Rivet
200. Gas Skin
300. Internal piping of projectile
400. External piping
500. Adapter
F. Fluid

Claims (9)

And a fluid inlet port which is connected to an external piping which is exposed to the outside and which is exposed to the outside when fastened to the gasket is formed on one side and a fluid inlet port extending from the inner side to the inside, A fluid inlet portion in which a fluid pipe portion through which the fluid flow path is formed is formed,
A housing space disposed in front of the fluid inlet portion and connected to the fluid inlet portion and accommodating the fluid discharged to the outside of the duct portion inside the housing portion; A fluid discharge portion in which a fluid discharge port through which the fluid is discharged is formed,
The fluid is simultaneously disposed in the flow path and the accommodation space, the fluid passing through the flow path is discharged to the accommodation space through slide movement when the fluid flows, and a pressure is applied to the fluid contained in the accommodation space, A spool which pushes the spool to the inner pipe side of the
An elastic member disposed in the accommodation space for elastically supporting the spool;
And a pipe connector for the projectile. The method of claim 1,
The fluid inlet
A cylindrical shape is formed, a thread is formed on the outer peripheral surface,
Wherein a plurality of fastening holes are formed between the fluid inlet port and the ducted portion to form a flange portion which is riveted to the base skin through the plurality of fastening holes. 3. The method of claim 2,
And a fluid discharge hole for communicating the flow path with the accommodation space is formed at one point of the pipe section. 4. The method of claim 3,
Wherein a part of the elastic member is seated on the inner side of the fluid discharge portion and a seating groove is formed to surround the outer surface of a part of the elastic member,
And a protrusion protruding in a radial direction of the fluid discharge portion is formed along one side of the fluid discharge portion which is in contact with the fluid inlet portion along the outer circumferential face. 5. The method of claim 4,
And a coupling member for coupling the fluid inlet and the fluid outlet are integrally formed on an outer side of a connection portion where the fluid inlet and the fluid outlet are in contact with each other. The method of claim 5,
Wherein the coupling member is formed with a threaded portion formed on an outer peripheral surface of the fluid inlet portion and formed with a threaded portion on an inner circumferential surface of one side of the coupling member and a hooked portion formed on an inner circumferential surface of the other side portion of the coupling member. The method of claim 1,
The spool
A head disposed in the accommodation space and supported on one side of the elastic member,
And a rod extending from the head portion and disposed in the flow path. 8. The method of claim 7,
Wherein a through hole is formed in the head portion for communicating the front space of the head portion where the elastic member is disposed and the rear space of the head portion where the fluid discharged to the outside of the oil pipe portion is received. The method of claim 1,
And a cap which is fastened to the fluid inlet port to open and close the flow path.

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