KR101220231B1 - Automatic discharge connector for underwater pump - Google Patents

Abstract

The present invention relates to an automatic desorption apparatus for a submersible pump, which is firmly fixed through a support structure of an underwater bottom, and elbow pipe for guiding the fluid discharged from the submersible pump to the outside; A guide bar installed vertically to extend life at both sides of the elbow pipe; A connection pipe that is fixed to communicate with a pump pipe on the discharge side of the submersible pump, and moves downward along the guide bar to be coupled to and fixed to the elbow pipe; And a rotary link inclined at an angle to the elbow pipe side in a longitudinal direction and rotatable about a hinge axis provided through the support structure, wherein the rotary link protrudes from an outlet flange of the connection pipe. Rotation by the pressing force of the guide bracket is characterized in that to perform the airtight for the connecting portion of the elbow pipe and the connection pipe.

Description

Automatic removal device for submersible pumps {AUTOMATIC DISCHARGE CONNECTOR FOR UNDERWATER PUMP}

The present invention relates to an automatic desorption apparatus for a submersible pump. More particularly, the coupling between the elbow pipe and the connection pipe of the submersible pump is made precisely, and at the same time, a solid bond is established at the connection site, thereby greatly improving the operation reliability of the pump. It relates to an automatic desorption apparatus for a submersible pump.

In general, an underwater pump is used as a means for transferring fluids to a sewage treatment plant or a drainage pumping plant. The submersible pump is divided into various types, such as a core, pressurized water, and drainage, depending on the purpose and purpose of use. .

Normally, the submersible pump uses an elbow piping method. However, when the elbow is used, it is difficult to maintain because it must be lifted after removing all the fluid in the pumping station to lift the pump when a pump failure occurs.

For this reason, the automatic discharge connector (Automatic Discharge Connector) has recently been used for various reasons, such as the convenience of pump maintenance and the demand of the company.

When using such an automatic desorption device, the pump can be lifted separately from the elbow for pump piping without the hassle of removing water, which has the advantage of effectively maintaining and managing the pump.

Republic of Korea Utility Model Registration No. 163069 "automatic removal device for submersible pump" discloses a configuration that can be accurately connected to or disassemble the pump in the water by using a guide frame and guide bracket.

The automatic desorption device for the submersible pump is fixed to a pair of guide frames arranged upright on the side of the elbows and bolts as fastening members on the flange face of the pump pipe side of the pump pipe, and descends along the guide frame by the pump's own weight when the pump is fastened. It is characterized by consisting of a guide bracket for guiding the pump fastening position in the water.

However, according to the related art, when the total head (pressure) of the pump is high, there is a problem that a gap occurs in the lower part of the joint of the pump and the elbow for discharge due to the lifting by the reaction force of the discharge pressure of the pump. Accordingly, about 20-30% of the pump discharge amount is leaked through the gap, causing a fatal problem in which the pump head efficiency is significantly lowered.

In addition, in the prior art, the pump may be detached from the elbow due to the lifting of the pump due to the reaction force, and the pump may be burned out. There is also a problem in serious situations.

Accordingly, the present invention has been made to solve the above problems, an object of the present invention is to completely prevent the leakage of fluid in the connection of the elbow pipe and the connection pipe of the submersible pump. .

In order to achieve the above object, the automatic desorption apparatus for a submersible pump according to the present invention is firmly fixed through a support structure of an underwater bottom, and elbow pipe for guiding the fluid discharged from the submersible pump to the outside; A guide bar installed vertically to extend life at both sides of the elbow pipe; A connection pipe that is fixed to communicate with a pump pipe on the discharge side of the submersible pump, and moves downward along the guide bar to be coupled to and fixed to the elbow pipe; And a rotary link inclined at an angle to the elbow pipe side in a longitudinal direction and rotatable about a hinge axis provided through the support structure, wherein the rotary link protrudes from an outlet flange of the connection pipe. Rotation by the pressing force of the guide bracket is characterized in that to perform the airtight for the connecting portion of the elbow pipe and the connection pipe.

The rotary link is made of a link contact member in contact with the guide bracket, and a flange pressing member corresponding to the outlet flange of the connection pipe located on the opposite side of the link contact member about the hinge axis, characterized in that do.

The flange pressing member is made to be in close contact with the front surface of the lower end of the flange of the connection pipe, characterized in that the 'L' shape made to be in close contact with the flange to restrain the horizontal movement of the connection pipe.

The flange pressing member is characterized in that the gap adjusting member for adjusting the interval in the vertical direction with respect to the outlet side flange of the connecting pipe.

The gap adjusting member is characterized in that the thread is formed on the fastening portion with the outlet flange so as to adjust the gap between the outlet flange and the flange pressing member of the connecting pipe by the rotation operation.

The elbow pipe is characterized in that it further comprises a fixing part for coupling and fixing the connection pipe to the inlet flange.

The fixing portion, the first element formed on the upper side of the inlet flange of the elbow pipe; And a second element formed at an outlet flange of the connection pipe and interacting with the first element to generate a coupling force.

The fixing part may further include a third element formed below the outlet side of the connection pipe.

The first element is a projection, and the second element is a groove.

The third element is characterized in that the engaging portion for generating a coupling force in close contact with the upper end of the inlet flange of the elbow pipe.

A sealing ring for sealing the gap is installed between the flange of the elbow pipe and the outlet flange of the connection pipe.

As described above, according to the automatic desorption apparatus for submersible pumps according to the present invention, the elbow pipe and the connection portion on the connection pipe side of the submersible pump are made correctly, and the airtightness of the connection portion is maintained firmly, It is possible to completely block the occurrence of fluid leakage in the connecting portion between the pipe side and the pump side to greatly improve the reliability of the pump operation.

1 is a side cross-sectional view showing a state before coupling of the elbow pipe side and the pump pipe side of the automatic desorption apparatus for submersible pump according to the present invention.
2 is a plan view schematically showing an automatic desorption apparatus for a submersible pump according to the present invention.
Figure 3 is a detailed view showing a coupling state of the elbow pipe side and the pump pipe side of the automatic desorption apparatus for submersible pump according to the present invention.
Figure 4 is a side cross-sectional view schematically showing a state after the coupling of the elbow pipe side and the pump pipe side of the automatic desorption apparatus for submersible pump according to the present invention.

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

1 is a side cross-sectional view showing a state before coupling of the elbow pipe side and the pump pipe side of the automatic desorption apparatus for submersible pump according to the present invention, Figure 2 schematically shows an automatic desorption apparatus for submersible pump according to the present invention. 3 is a plan view illustrating a coupling state between the elbow pipe side and the pump pipe side of the automatic desorption apparatus for an underwater pump according to the present invention.

In addition, Figure 4 is a side cross-sectional view schematically showing a state after the coupling of the elbow pipe side and the pump pipe side of the automatic desorption apparatus for submersible pump according to the present invention.

As shown in FIG. 1 and FIG. 2, according to an embodiment of the present invention, the submersible pump 10 operates by being directly disposed in the water, and a submersible pump 10 having various general configurations may be used. The impeller (not shown) is driven to rotate by a motor (not shown), and the fluid is sucked into the casing by the rotation of the impeller and the sucked fluid is discharged through the pump pipe 40.

The elbow pipe 20 made of an 'L' shaped pipe for guiding the fluid discharged from the submersible pump 10 to the outside is fixedly mounted in the water in the water tank 1 and connected to a separate discharge pipe (not shown). And fluid is conveyed to the outside.

At this time, the elbow pipe 20 has a structure that is firmly fixed while being spaced a certain height from the bottom of the water through the support structure (2) of the lower.

Automatic desorption apparatus for submersible pump according to an embodiment of the present invention is a device for connecting the connection pipe 30 and the elbow pipe 20 of such a submersible pump 10, the submersible pump 10 to the traction rope (mido Move downward, and is easily connected to the elbow pipe 20 fixedly mounted in the water through the connection pipe (30).

The connecting pipe 30 is formed in a hollow cylindrical shape fixed to the discharge side of the submersible pump 10, the flow path formed therein is in communication with the pump pipe 40 of the submersible pump 10 and at the same time elbow pipe 20 One side is coupled to the pump side, the other side is coupled to the elbow pipe 20 side so as to communicate with the flow path of the).

At this time, the elbow pipe 20, the connection pipe 30 and the pump pipe 40 is preferably formed to have an internal flow path of the same shape.

As it has such an internal flow path, the flow of the fluid from the pump pipe 40 of the submersible pump 10 through the connection pipe 30 to the elbow pipe 20 can proceed smoothly without resistance.

The connecting pipe 30 for connecting the elbow pipe 20 and the submersible pump 10 is inserted into the elbow pipe 20 and the pump pipe 40 by using the inlet and outlet surfaces, and then is closely assembled. Is mounted.

For example, the connecting pipe 30 is concentrically assembled to the elbow pipe 20 via the flange 32 on the outlet side and at the same time the pump pipe 40 on the pump side through the pump flange 34 on the inlet side. Assembled by assembly.

The configuration of the connecting pipe 30 will be described in more detail. A hollow cylindrical body 31, a flange 32 formed to protrude along the circumferential direction at the outlet side end of the body 31, and the flange The guide bracket 33 is formed to protrude forward at the outer circumferential surface exit side end of the (32).

In addition, a pump flange 34 is formed at the other end opposite to the outer circumferential surface on which the flange 32 is formed at the other end of the body 31, and the submersible pump 10 is formed by the pump flange 34. The flange 41 of the pump pipe 40 of the side may be coupled via a fastening means, such a coupling method may be variously changed according to various pipe connection methods.

The connecting pipe 30 is coupled to the pump pipe 40 on the pump side in advance before connecting to the elbow pipe 20.

On the other hand, the support structure 2, the elbow pipe 20 is installed is equipped with a separate guide bar 50 that can guide the movement of the submersible pump 10 connected to the elbow pipe 20, In the guide bracket 33 provided on the outer circumferential surface of the outlet flange 32 of the connection pipe 30 coupled to the submersible pump 10, a guide ring 35 for guiding downward movement by the guide bar 50 is provided. It is provided.

Accordingly, when the submersible pump 10 is moved to the elbow pipe 20 in the water by the traction rope, the guide formed integrally in the connection pipe 30 in a state in which the connection pipe 30 is coupled to the submersible pump 10. The ring 35 is lowered along the guide bar 50 toward the elbow pipe 20.

The guide bar 50 is vertically installed to extend to the water surface from both sides of the elbow pipe 20, consisting of a pair of stable of the submersible pump 10 by a guide ring 35 formed integrally in the connection pipe 30 Enable movement

3 is a view illustrating a coupling structure of the elbow pipe 20 and the connection pipe 30 according to the present invention, wherein the coupling of the elbow pipe 20 and the connection pipe 30 is mediated through the fixing part 60. Will be made.

The fixing part 60 is formed on the first element formed on the inlet flange 21 of the elbow pipe 20 and the outlet flange 32 of the connecting pipe 30 and is formed on the first element. It consists of a second element that interacts to generate a bonding force.

The first element may be a protrusion 61, and the second element may be a groove 62. On the contrary, the first element may be a groove 62, and the second element may be a protrusion 61.

The protrusion 61 is formed in a vertical tapered shape and protrudes to a predetermined height. The groove 62 has a width approximately similar to the diameter of the protrusion 61, and the protrusion 61 is a groove 62. It can be inserted into the to keep it fixed.

According to this configuration, when the submersible pump 10 is pulled toward the elbow pipe 20 installed in the water while the connecting pipe 30 is coupled to the guide bar 50 via the guide ring 35, the submersible pump 10 moves downward along the guide bar 50 to approach the elbow pipe 20, and as the protrusion 61 is inserted into the space formed by the groove 62, the elbow pipe 20 and The coupling of the pump side is made.

In addition, the fixing part 60 is composed of a third element formed on the lower side of the outlet side of the connection pipe (30).

The third element is a locking portion 63, the locking portion 63 is in close contact with the front end of the upper end of the inlet flange 21 of the elbow pipe 20 is in close contact.

Therefore, since the coupling of the connection portion of the elbow pipe 20 side and the pump pipe 40 side is coupled and fixed in a double, more accurate and firm coupling is made.

In the above-described embodiment of the present invention, the fixing part 60 is described as consisting of the protrusion 61, the groove 62, and the locking portion 63, but the fixing part 60 is necessarily limited thereto. If not, the elbow pipe 20 and the connecting pipe 40 may be combined with any structure as long as the structure can be firmly fixed.

Meanwhile, reference numeral 36 is a sealing ring provided between the flange 21 of the elbow pipe 20 and the outlet flange 32 of the connection pipe 30 to seal the gap.

In addition, in a preferred embodiment of the present invention, as shown in Figures 1 and 2, both sides of the elbow pipe 20 is inclined at a predetermined angle extending in the longitudinal direction, to support the elbow pipe 20 The rotary link 70 is rotatable about a hinge shaft 71 provided through the support structure 2.

The rotary link 70 is a member to be contacted while the guide bracket 33 of the connection pipe 30 moves downward, and is in contact with the link contact member 72 and the hinge shaft ( 71 is located on the opposite side of the link contact member 72 to the flange flange member 73 facing the outlet flange 32 of the connecting pipe (30).

When the guide bracket 33 is moved downward to be contacted at a predetermined position, the contacting contact member 72 is rotated about the hinge shaft 71 in the opposite direction of the submersible pump 10, so that the flange pressure is applied. The member 73 is comprised so that the outlet side flange 32 of the connection pipe 30 which is a connection site of the elbow pipe 20 side and the pump pipe 40 side may be pressurized.

In other words, the flange pressing member 73 is formed in an 'L' shape to be in close contact with the front surface of the lower end of the outlet side flange 32 of the connecting pipe 30, while being in close contact with the flange 32, the connecting pipe 30 ) Can be constrained in the horizontal direction.

For this reason, the entire connecting pipe 30 is not separated from the elbow pipe 20 in the horizontal direction, that is, in the right direction in FIG. 4.

On the other hand, the flange pressing member 73 of the hinge link 70 is provided with a gap adjusting member 74 which is adjusted in the vertical direction with respect to the outlet flange 32 of the connecting pipe (30).

The gap adjusting member 74 has a different size of the outlet flange 32 of the connection pipe 30 or a gap error between the rotary link 70 and the outlet flange 32 of the connection pipe 30 occurs. If so, it is to adjust this gap.

It is possible to adjust the distance between the outlet flange 32 and the flange pressing member 73 of the connecting pipe 30 by the rotation operation by forming a screw thread in the fastening portion with the outlet flange 32, such as bolts, screws. It is desirable to. Here, the gap adjusting member 74 is described as a means for fastening by a screw thread, but the gap adjusting member 74 is not necessarily limited thereto, and the outlet flange 32 and the flange pressing member of the connection pipe 30 are not limited thereto. If the structure can be adjusted so as to be firmly in close contact with the outlet flange 32 of the connecting pipe 30 by adjusting the distance between the 73 may be made of any structure.

Hereinafter, the operation of the automatic desorption apparatus for a submersible pump according to the present invention, the connection pipe 30 is coupled to the submersible pump 10 is moved downward through the traction rope together with the submersible pump 10.

As such, when the submersible pump 10 is lowered, the submersible pump 10 is naturally guided to the elbow pipe 20, and when the submersible pump 10 reaches the target position, the elbow pipe 20 and the connecting pipe are provided. The fixing part 60 of the 30, that is, the protrusion 61, the groove part 62, and the locking part 63 are doubled to be firmly and easily coupled.

At the same time, the guide bracket 33 of the connecting pipe 30 imparts a pressing force to the rotary link 70, and the link contact member 72, which rotates about the hinge shaft 71 by the pressing force, presses the flange. The member 73 is firmly brought into close contact with the outlet flange 32 of the connecting pipe 30, and as a result, the coupling force between the connecting part of the elbow pipe 20 side and the pump pipe 40 side is strengthened to generate a gap. Is prevented.

In addition, even if vibration occurs during operation of the submersible pump 10, the position change due to the vibration does not occur and the fixed state is maintained.

Therefore, the leakage of the fluid through the connection portion is prevented to improve the performance of the submersible pump 10.

In addition, through the spacing adjusting member 74 to give a more close contact to the connection portion it is possible to stably prevent the leakage of fluid even in the high pump submersible pump (10).

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Various modifications to the embodiments are also within the scope of the claims of the present invention.

10: submersible pump 20: elbow pipe
21 flange 30 connection pipe
31 body 32 flange
33: guide bracket 34: pump flange
35 guide ring 36 sealing ring
40: pump piping 41: flange
50: guide bar 60: fixed part
61: projection 62: groove
63: catching part 70: rotating link
71: hinge shaft 72: link contact member
73: flange pressing member 74: gap adjusting member

Claims (11)

An elbow pipe that is firmly fixed through the support structure of the underwater bottom and guides the fluid discharged from the underwater pump to the outside;
A guide bar installed vertically to extend from the both sides of the elbow pipe to the water surface;
A connection pipe that is fixed to communicate with a pump pipe on the discharge side of the submersible pump, and moves downward along the guide bar to be coupled to and fixed to the elbow pipe; And,
The elbow pipe side inclined at an angle to extend in the longitudinal direction, and includes a rotary link rotatable about a hinge axis provided through the support structure,
And the rotary link rotates by a pressing force of a guide bracket protruding from an outlet flange of the connection pipe to perform airtightness for a connection between the elbow pipe and the connection pipe.
The method of claim 1,
The rotary link is made of a link contact member in contact with the guide bracket, and a flange pressing member corresponding to the outlet flange of the connection pipe located on the opposite side of the link contact member about the hinge axis, characterized in that Automatic removal device for submersible pump.
The method of claim 2,
The flange pressing member is made to be in close contact with the front surface of the lower end of the flange of the connection pipe, the water pump, characterized in that the 'L' shape made to be in close contact with the flange to restrain the horizontal movement of the connection pipe Automatic removal device for
The method of claim 3,
The flange pressing member is an automatic desorption apparatus for a submersible pump, characterized in that the interval adjusting member for adjusting the interval in the vertical direction with respect to the outlet flange of the connecting pipe.
5. The method of claim 4,
The spacing adjusting member is an automatic removal device for an underwater pump, characterized in that a thread is formed at the fastening portion with the outlet flange to adjust the gap between the outlet flange and the flange pressing member of the connecting pipe by the rotation operation.
The method according to any one of claims 1 to 5,
The elbow pipe further comprises a fixing part for coupling and fixing the connection pipe to each other in the inlet flange thereof.
The method according to claim 6,
The fixing unit includes:
A first element formed above the inlet flange of the elbow pipe; And,
And a second element formed at an outlet flange of the connection pipe and configured to interact with the first element to generate a coupling force.
The method of claim 7, wherein
The fixing part further comprises a third element formed in the lower portion of the outlet side of the connection pipe for automatic pump removal.
The method of claim 7, wherein
And said first element is a projection and said second element is a groove.
9. The method of claim 8,
The third element is an automatic detachment device for an underwater pump, characterized in that the engaging portion for generating a coupling force in close contact with the rear of the upper end of the inlet flange of the elbow pipe.
9. The method of claim 8,
And a sealing ring for sealing the gap between the flange of the elbow pipe and the outlet flange of the connecting pipe.

Images