KR101213023B1 - Hydro test apparatus - Google Patents

Abstract

Disclosed is a hydraulic test apparatus. The disclosed hydraulic test apparatus includes: a lower frame member; An upper frame member spaced apart by a connection member on an upper side of the lower frame member; A moving member installed on the lower frame member and configured to convey the bellows assembly; And an elevating member installed on the upper frame member to pressurize and seal to test the hydraulic pressure of the bellows assembly placed in the movable member.

Hydraulic test apparatus according to the present invention can provide the convenience of the inspection work because the hydraulic test is made in a state in which the bellows assembly is placed horizontally on the moving plate, and the bellows assembly is pressed and sealed by a lifting plate. .

Bellows Assembly, Test, Hydraulic Pressure, Moving Member, Lifting Member

Description

Hydraulic Test Equipment {HYDRO TEST APPARATUS}

The present invention relates to a hydraulic pressure testing apparatus, and more particularly, to a hydraulic pressure testing apparatus which provides convenience of inspection work by making the hydraulic pressure test convenient because the hydraulic pressure is measured while the bellows assembly is pressurized from the top and sealed. It is about.

In general, the bellows-type expansion pipe is a pipe member used for the purpose of buffering and absorbing vibration shock in precision equipment requiring high vacuum, elasticity, stability, and vibration absorption in various fields such as aerospace, semiconductor manufacturing, and nuclear facilities. It is a kind of.

Bellows type expansion tube (hereinafter referred to as expansion tube) is a bellows assembly to withstand the expansion and contraction of each section of the pipe member in order to prevent the pipe member from being expanded and damaged by the high temperature fluid moving therein. Equipped with.

1 is a view showing the configuration of a typical expansion pipe.

Both sides of the bellows assembly 10 are provided with a pipe member 16 spaced apart from each other at regular intervals.

The bellows assembly 10 includes a bellows 12 for extending or contracting when the pipe member 16 is expanded, a pair of flange members 18 positioned at both ends of the bellows 12, and a flange member ( 18, there is provided a connection joint 14 connecting each other to restrain excessive expansion of the bellows 12.

The bellows 12 is configured to be expanded or folded by giving a corrugated metal tube of different diameters.

The connecting joint 14 forms a threaded portion at both ends of the connecting shaft which is inserted into the hole of the flange member 18, and the bellows 12 is expanded by the temperature of the fluid moving inside by tightening the nut on the screwed portion. The expansion of the bellows 12 is limited by the support of the connecting shaft.

The technical structure described above is a background technique for assisting the understanding of the present invention, and does not mean the prior art widely known in the technical field to which the present invention belongs.

However, since the bellows of the bellows assembly is corrugated, it is very vulnerable to the hydraulic pressure, so the hydraulic pressure must be tested before manufacturing and selling, but in the past, the hydraulic pressure must be checked manually, and thus the test work is very cumbersome. There was a problem that the productivity is significantly reduced.

Thus, there is a need for improvement.

The present invention has been created by the necessity as described above, by placing the bellows assembly on the moving plate to move horizontally, pressurized the bellows assembly with a lifting plate, the pressure test is made in a convenient state, so the convenience of inspection work It is an object of the present invention to provide a hydraulic test apparatus to obtain a.

Hydraulic test apparatus according to an embodiment of the present invention to achieve the above object is: a lower frame member is placed bellows assembly; An upper frame member spaced apart from each other by a connection member on an upper side of the lower frame member; And it is installed on the upper frame member, characterized in that it comprises a lifting member for sealing by pressing to test the hydraulic pressure of the bellows assembly placed in the lower frame member.

Hydraulic test apparatus according to an embodiment of the present invention includes: a lower frame member; An upper frame member spaced apart from each other by a connection member on an upper side of the lower frame member; A movable member installed on the lower frame member and configured to convey the bellows assembly; And an elevating member installed on the upper frame member to pressurize and seal to test the hydraulic pressure of the bellows assembly placed in the movable member.

In addition, the lower frame member is formed to be long to one side, characterized in that the bellows assembly placed in the movable member is configured to move horizontally from the outside to be disposed below the lifting member.

In addition, the movable member is a movable plate installed to be movable on the lower frame member; And a power member connected to the moving plate to provide power for horizontal movement.

In addition, the power member is a power generating member for generating power; A bracket member connecting the power generating member and the moving plate to each other; And it characterized in that it comprises a guide member for guiding the movement of the moving plate.

In addition, the power generating member is a cylinder which is installed on the bottom of the lower frame member, one end of the bracket member is connected to the shaft of the power generating member, the other end is connected to the side of the moving plate of the lower frame member It is movably connected through the cut-out space, the guide member is characterized in that the LM guide.

In addition, the lifting member is a motor installed in the upper frame member; A chain for transmitting power by engaging a drive sprocket connected to the shaft of the motor; It is characterized in that it is rotatably installed in the center of the driven sprocket meshed with the chain, the screw member for elevating the lifting plate up and down.

In addition, the elevating plate to be elevated by the rotation of the screw member slides along the connecting member, the upper frame member is screwed to the screw member is characterized in that it comprises a female screw member to move the lifting plate up and down It is done.

In addition, the lifting plate is characterized in that it further comprises a bearing member for preventing friction with the connecting member.

In addition, it characterized in that it further comprises a buffer member for buffering the elevating member moving between the upper frame member and the lower frame member.

As described above, the hydraulic pressure test apparatus according to the present invention is placed horizontally by placing the bellows assembly on the moving plate, and the pressure test is easily performed in a state in which the bellows assembly is pressurized and sealed by a lifting plate, so that the inspection work is performed. It can provide convenience.

Hereinafter, with reference to the accompanying drawings will be described a hydraulic test apparatus according to an embodiment of the present invention. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

Figure 2 is a perspective view of a hydraulic test apparatus according to an embodiment of the present invention, Figure 3 is a side view of the hydraulic test device shown in Figure 2, Figure 4 is a front view of the hydraulic test device shown in Figure 2, Figure 5 2 is a view showing a state of testing the water pressure using the water pressure test apparatus shown in FIG.

2 to 5, the hydraulic test apparatus according to an embodiment of the present invention is the lower frame member 24, the upper frame member spaced apart by the connecting member 26 on the upper side of the lower frame member 24 (22), which is installed on the lower frame member 24, installed on the movable member 30 and the upper frame member 22 for placing and transporting the bellows assembly 10, and placed on the movable member 30. It comprises a lifting member 50 for sealing by pressing to test the hydraulic pressure of the bellows assembly (10).

As shown in FIG. 1, the bellows assembly 10 includes a pair of flange members positioned at both ends of the bellows 12 and the bellows 12, which allow the pipe member 16 to expand or contract when the pipe member 16 is expanded. 18) and a connection joint 14 connecting the flange member 18 with each other to restrain excessive expansion of the bellows 12.

At this time, both opening portions of the bellows assembly 10 are provided with a sealing member 82 which is plate-shaped and sealed for sealing.

The sealing member 82 is connected to a pneumatic flow path 92 for supplying high pressure compressed air.

The other end of the pneumatic flow path 92 is connected to a high pressure generating unit 90 for generating high pressure compressed air.

The sealing member 82 is provided with a pressure gauge 94 indicating the internal pressure of the bellows assembly 10 by the compressed air supplied through the pneumatic flow path 92.

The lower frame member 24 is formed to be long to one side, and the bellows assembly 10 placed in the movable member 30 is configured to move horizontally from the outside to be disposed below the elevating member 50.

The lower surface of the lower frame member 24 may be further provided with a leg member for maintaining a predetermined interval.

The movable member 30 includes a movable plate 32 movably installed on the lower frame member 24 and a power member 34 connected to the movable plate 32 to provide power for horizontal movement.

The power member 34 is a guide for guiding the movement of the power generating member 36 generating power, the bracket member 40 connecting the power generating member 36 and the moving plate 32 to each other, and the moving plate 32. It comprises a member 42.

The power generating member 36 is preferably a hydraulic or pneumatic cylinder installed on the bottom of the lower frame member 24.

The power generating member 36 is configured to transfer and operate hydraulic or pneumatic pressure generated by the pressure generating unit 38 installed on the upper frame member 24 through the connecting pipe.

In the drawings of the present invention, the pressure generating unit 38 and the high pressure generating unit 90 are shown to have different configurations, but the pressure generating unit 38 and the high pressure generating unit 90 may be applied in the same configuration. have.

One end of the bracket member 40 is connected to the shaft of the cylinder that is the power generating member 36, the other end is connected to the side of the moving plate 32 through the cut-out space 28 of the lower frame member 24 It is movably connected.

The guide member 42 is preferably an LM guide.

The guide member 42 slides along the guide rail 44 and the guide rail 44 which are installed in a pair to have a predetermined interval in the longitudinal direction on the upper side of the lower frame member 24, It includes a guide groove 46 installed on the bottom.

In this case, the guide member 42 may be a roller installed on the bottom surface of the moving plate 32.

The elevating member 50 is engaged with the motor 56 installed on the upper frame member 22, the drive sprocket 58 connected to the shaft of the motor 56, and the chain 60 and the chain 60 for transmitting power. It is rotatably installed in the center of the driven sprocket 62 is engaged with the power transmission, and includes a screw member 64 for elevating the lifting plate 52 up and down.

The lifting member 50 may be configured such that the drive gear and the driven gear are directly engaged with each other to transmit power without using a chain.

The elevating plate 52 which is elevated by the rotation of the screw member 64 slides along four connection members 26.

The upper frame member 22 includes a female screw member 66 screwed to the screw member 64 to move the lifting plate 52 up and down.

The lifting plate 72 further includes a bearing member 70 to prevent friction with the connection member 26.

A buffer member 80 is further provided to buffer the lifting member 50 moving between the upper frame member 22 and the lower frame member 24.

The shock absorbing member 80 is formed in a polygonal column or a cylindrical shape, and a plurality of shock absorbing members 80 are formed on the lower frame member 24 and the lifting plate 52, respectively, and the lifting plate 52 is upper and lower frame members 22 and 24. Avoid bumping into

The end of the screw member 64 further includes a fixing member 66 which is fixed to the lifting plate 52 and each other.

On the other hand, although not shown in the drawings, the hydraulic test apparatus according to another embodiment of the present invention, the lower frame member 24, the lower member (28) on which the bellows assembly 10 is placed, the connecting member 26 on the upper side of the lower frame member 24. The elevating member 50 installed in the upper frame member 22 and the upper frame member 22 spaced apart by the pressurizing member 50 to pressurize to test the hydraulic pressure of the bellows assembly 10 placed in the lower frame member 24. It can be made, including.

Almost the same as in the embodiment of this other embodiment, but because only the moving member 30 is not provided, the bellows assembly 10 is placed directly on the lower frame member 24 without moving horizontally, and the elevating member 50 ) Is operated in the same manner as in the embodiment to test the hydraulic pressure of the bellows assembly 10. Since the configuration thereof is the same as in the exemplary embodiment, detailed description thereof will be omitted.

Or less, on the basis of the accompanying drawings to look at the operation and action of the hydraulic test apparatus according to an embodiment of the present invention.

First, as shown in FIGS. 2 to 5, the moving plate 32 of the moving member 30 in a state in which the operator blocks the openings at both ends of the bellows assembly 10 to measure the water pressure with the sealing member 82. ) And operating the control unit (not shown), the hydraulic or pneumatic pressure is generated in the pressure generating unit 38 is moved through the connecting pipe to pull the shaft of the cylinder, which is the power generating member (36).

In this way, since the shaft of the cylinder is pulled, when the bracket member 40 coupled to the shaft horizontally moves the movable plate 32 connected through the space portion 23, the movable plate 32 is moved along the LM guide 42. Is moved.

Then, in a state in which the movable plate 32 moves to one side and is located on the bottom surface of the elevating plate 52, the driving sprocket may be driven by driving the motor 56, which is the power member 54, on the upper side of the bellows assembly 10. 58), the screw 60 is integrally coupled to the driven sprocket 62 via the chain 60 and the driven sprocket 62.

Subsequently, when the screw member 64 is rotated, the screw member 64 is moved downward by the screwing state to the female screw member 23 of the upper frame member 22, and at the end of the screw member 64 The lifting plate 52 is moved downward by the fixed member 66 coupled to press the upper end of the bellows assembly 10.

At this time, the lifting plate 52 is stably moved downward while receiving the guide of the bearing member 70 along the connection member 26 installed on the four corners.

Then, by attaching a plurality of pressing members 96 on the upper surface of the lifting plate 52 to press the upper sealing member 82 located on the upper surface of the bellows assembly 10 to seal both ends of the bellows assembly 10. The compressed air of the high pressure generated in the high pressure generating unit 90 from the outside through the pneumatic flow path 92 to replace the pressure applied to the inside of the bellows assembly 10 through the pressure gauge 94 located outside. The measurement makes it easy to complete the hydraulic test.

If leakage occurs in the bellows assembly 10, the scale of the pressure gauge 94 will not rise, so that the defective article is judged, discarded or repaired, and tested again.

After completing the measurement, the bellows assembly 10 moves the lifting plate 52 upward, returns the movable plate 32 to the initial state, and places the other bellows assembly on the movable plate 32. Repeat the process so that you can proceed with the continuous hydraulic test.

As described above, the bellows assembly 10 is placed on the movable plate 32 to move horizontally, and the hydraulic test is simply performed while the bellows assembly 10 is pressed by the lifting plate 52. Can be provided.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand.

As described above, the bellows assembly 10 has been described as an example, but the hydraulic test apparatus of the present invention can be used to measure the water pressure of various pipe members.

Accordingly, the true scope of protection of the present invention should be defined by the following claims.

1 is a view showing the configuration of a typical expansion pipe.

2 is a perspective view of a hydraulic test apparatus according to an embodiment of the present invention.

3 is a side view of the hydraulic test apparatus shown in FIG.

4 is a front view of the hydraulic test apparatus shown in FIG.

5 is a view showing a state of testing the water pressure using the water pressure test apparatus shown in FIG.

Explanation of symbols on the main parts of the drawings

10: bellows assembly 22: upper frame member

24: lower frame member 26: connecting member

30: moving member 32: moving plate

34: power member 36: power generating member

40: bracket member 42: guide member

50: elevating member 52: elevating plate

54: power member 56: motor

60: chain 64: screw member

70: bearing member 80: buffer member

Claims (10)

A lower frame member on which the bellows assembly is placed; An upper frame member spaced apart from an upper side of the lower frame member; And A lifting member installed on the upper frame member and pressurizing the bellows assembly to test the hydraulic pressure of the bellows assembly placed in the lower frame member, And a shock absorbing member for buffering the lifting member moving between the upper frame member and the lower frame member. The lifting member, the motor is installed in the upper frame member; A chain for transmitting power by engaging a drive sprocket connected to the shaft of the motor; A screw member which is rotatably installed at the center of the driven sprocket which is engaged with the chain and receives power, and includes elevating a lifting plate up and down, Both open portions of the bellows assembly are provided with a plate-shaped sealing member for sealing, The other end of the pneumatic flow path for supplying high pressure compressed air to the sealing member is connected to a high pressure generating unit for generating high pressure compressed air, The sealing member is provided with a pressure gauge indicating the internal pressure of the bellows assembly by the compressed air supplied through the pneumatic flow path to confirm from the outside, When the leakage occurs in the bellows assembly, the pressure test device, characterized in that to determine the defective by checking that the scale of the pressure gauge does not rise. An upper frame member spaced apart from an upper side of the lower frame member; A movable member installed on the lower frame member and configured to convey the bellows assembly; And A lifting member installed on the upper frame member and pressurizing the bellows assembly to test the hydraulic pressure of the bellows assembly placed in the movable member; Further comprising a buffer member for buffering the lifting member to move between the upper frame member and the lower frame member, The lifting member, the motor is installed in the upper frame member; A chain for transmitting power by engaging a drive sprocket connected to the shaft of the motor; A screw member which is rotatably installed at the center of the driven sprocket which is engaged with the chain and receives power, and includes elevating a lifting plate up and down, Both open portions of the bellows assembly are provided with a plate-shaped sealing member for sealing, The other end of the pneumatic flow path for supplying high pressure compressed air to the sealing member is connected to a high pressure generating unit for generating high pressure compressed air, The sealing member is provided with a pressure gauge indicating the internal pressure of the bellows assembly by the compressed air supplied through the pneumatic flow path to confirm from the outside, When the leakage occurs in the bellows assembly, the pressure test device, characterized in that to determine the defective by checking that the scale of the pressure gauge does not rise. The method of claim 2, The lower frame member is formed long to one side, the hydraulic test apparatus, characterized in that the bellows assembly placed in the movable member is configured to move horizontally from the outside to be disposed below the lifting member. The method of claim 2, wherein the moving member A moving plate movably installed on the lower frame member; And And a power member connected to the movable plate to provide power for horizontal movement. The method of claim 4, wherein the power member is A power generating member for generating power; A bracket member connecting the power generating member and the moving plate to each other; And And a guide member for guiding the movement of the movable plate. 6. The method of claim 5, The power generating member is a cylinder installed on the bottom of the lower frame member, One end of the bracket member is connected to the shaft of the power generating member, the other end is connected to the side of the movable plate is movably connected through the cut space of the lower frame member, The guide member is a hydraulic test apparatus, characterized in that the LM guide. delete The method of claim 1, The elevating plate, which is lifted by the rotation of the screw member, slides along the connecting member, The upper frame member is a hydraulic test apparatus, characterized in that it comprises a female screw member which is screwed to the screw member to move the lifting plate up and down. 9. The method of claim 8, The lifting plate further comprises a bearing member for preventing friction with the connecting member. delete

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