KR19980057152U - Connection structure of pumping pipe for groundwater - Google Patents

Abstract

The present invention relates to a connection structure of the groundwater pumping pipe, in particular, in the connection structure of the groundwater pumping pipe connecting the upper pipe 10 and the lower pipe 20 continuously, even if the groundwater development depth is increased, the conventional flange Compared to the connection, it is possible to reduce the cross section of the casing (C) and the excavation hole (H), and to reduce the thickness of the pumping pipe, which is convenient for the excavation work, the casing work, and the pumping pipe connection, and reduces the cost. As such, the upper and lower ends of the upper pipe 10 and the lower pipe 20 are integrally formed at the ends of each of the fastening contact ends 14 and 24 and the upper and lower ends of the upper and lower ends 10 and 24. And a pair of fasteners 12 and 22 fitted to the pipe 20, and a connector 30 screwed at both ends of the fasteners 12 and 22, and the outer surface of the connector 30. Electrical wiring 40 is inserted into the Groundwater pumping to facilitate the protection of the electric wiring 40 connected to the submersible pump 50 by extending underground to the ground along the outer surface of the pump pipe by using the connector 30, the line protection end 34 protrudes The connection structure of the pipe.

Description

Connection structure of pumping pipe for groundwater

The present invention relates to a connection structure of the groundwater pumping pipe, in particular, in the connection structure of the groundwater pumping pipe for connecting the upper pipe and the lower pipe continuously, the lower portion of the upper pipe so as to reduce the cross section of the pumping pipe Inserting a pair of fasteners to be engaged with the close contact end formed integrally at one end of the pipe, and screwing the fasteners at both ends of the connector to connect the upper pipe and the lower pipe, and also to the outer side of the connector The present invention relates to a connection structure of pumping pipes for groundwater, which protrudes a wiring protection end into which electrical wiring is inserted and extends underground along the outer surface of the pumping pipe to facilitate the protection of electrical wiring connected to an underwater pump.

In general, the underground water reservoir is formed through a groundwater exploration process to secure groundwater for securing living water, agricultural water, industrial water, or hot spring water, such as drinking water, as shown in FIG. 1. Excavation hole (H) to the bottom to form (R) and pumping pipe (P) is installed inside the excavation hole (H) and pumping the groundwater from the underground reservoir (R) using a pump.

In general, the underground reservoir layer (R) has a geological structure to provide a passageway through which water flowing from the surface can be gathered a predetermined amount or more. The underground layers of various structures such as sandstone layers or granite layers formed with cracks are underground. If present in the lower part of the water table (Water Table) they may be the underground reservoir (R).

And when drilling holes (H) are formed from the surface to the underground reservoir layer (R) to pump the groundwater, casings on the inner surface of the drilling holes (H) to a predetermined depth to prevent depression of the drilling holes (H). (C) is provided, and the surface layer (S) adjacent to the excavation hole (H) is usually a soft ground in the usual case, so that a separate grouting (G) between the ground layer (S) and the casing (C) to strengthen the ground This may be done. And the casing (C) serves to prevent the surface water of the surface layer (S) adjacent to the excavation hole (H) to be hydraulic pressure in the excavation hole (H), the surface water is generally contaminated by the ground or ground pollution source In many cases, the contaminated surface water is introduced into the excavation hole (H) to prevent the groundwater below the excavation hole (H) from being contaminated.

In addition, the casing (C) is provided with a pumping pipe (P) for pumping the groundwater of the underground reservoir layer (R) to the ground, the pumping pipe (P) is connected to a plurality of predetermined length in succession from the ground Since it is installed in the casing (C) while descending to the underground reservoir (R), there is a connection means between the pump pipes (P) to support the connection force required according to the weight of the pump pipe (P) connection It is necessary.

In the related art, as shown in the accompanying drawings, FIGS. 1 and 2, and FIGS. 3A and 3B, flanges protruding outward from one end of the upper and lower pump pipes P as a connecting means of the pump pipes P are formed. The structure which fastens (F) using the bolt B and the nut N has been used.

However, according to the conventional connection structure described above, when the connection length of the positive pipe P increases from several hundred meters to several thousand meters underground depending on the depth of the underground reservoir layer R, In order to form a pipe connection with sufficient bearing capacity, the cross section of the flange (F) is required to be quite large. In a typical case, the diameter of the flange (F) is about 2.5 to 3 times the diameter of the positive pipe (P). Since the casing (C) and the excavation hole (H) whose cross sections are determined according to the size of the cross section of the flange (F) are also required, a large cross section is required, so that the casing (C) installation work and the excavation hole (H) Difficulties in carrying out the excavation work and its cost increase, as well as the rigidity of the bolt (B) and nut (N) is increased and the thickness of the flange (F) in order to support the increased weight of the pump pipe (P) Is also increased And therefore, so the flange (F) to the thickness of the pumping pipe (P) are formed integrally with even be increased more than is necessary there is a problem in that the economical losses.

In addition, unlike the case where the pump is installed on the ground, when using the water pump (WP), the electric wiring including a power line for driving the motor of the water pump (WP) connected to the bottom of the pump pipe (P) ( E) is sent down the excavation hole (H) along the side of the positive pipe (P), wherein the electrical wiring (E) passing through the flange (F) due to the narrow gap with the casing (C), etc. In order to prevent disconnection or short circuit due to the impact of the wire (F1) to the one side of the wiring passing portion (F1) to cut separately formed, there is a hassle, the pipe passing portion (F1) is connected to the positive pipe ( There was also a problem in that the connection force between P) is weakened, resulting in an uneven connection force.

The present invention was devised to solve the problems of the conventional pump connection structure using the flange connection, the technical problem of the present invention is, firstly, despite the increase in the depth of groundwater development in the connection structure of the pump It provides a connection structure between pump pipes so that the transverse cross section of the pump pipe connection does not need to be greatly enlarged. Second, it prevents the connection force of the pump pipe connections from being uneven and connects underground along the pump pipe. The present invention provides a means for fixing / protecting electrical wiring.

The first of the above technical problems is a fastening contact end formed integrally at each end of the upper pipe and the lower pipe, a pair of fasteners respectively fitted to the upper pipe and the lower pipe so as to be caught by the locking contact end, and packed on the inner side. It is achieved by the connection structure of the groundwater pumping pipe consisting of a connector fitted with a member and screwed to the fastener.

In addition, the second object is achieved by the connection structure of the groundwater pumping pipe is formed so that the wiring protection end protrudes outward so that the electric wiring is inserted into the outer surface of the connector in the longitudinal direction.

1 is a longitudinal sectional view of a groundwater well according to a conventional pumping pipe connection structure.

2 is a cross-sectional view of FIG. 1.

3A is a cross-sectional view taken along line AA ′ of FIG. 2, and FIG. 3B is a cross-sectional view taken along line BB ′ of FIG. 2.

Figure 4 is a perspective view showing a positive pipe connection structure according to the present invention.

Figure 5 is a longitudinal cross-sectional view showing a positive pipe connection structure according to the present invention.

Figure 6 is a longitudinal cross-sectional view of the groundwater wells used with the present invention pump pipe connection structure.

Figure 7 is a longitudinal sectional view showing another embodiment of the connector of the present invention.

* Description of the symbols for the main parts of the drawings *

10: upper pipe 20: lower pipe

12, 22: fasteners 14, 24: close contact

30: connector 30a: seating end

32: packing member 34: wiring protection end

40: electric wiring

The connection structure of the groundwater pumping pipe of the present invention will be described with reference to FIGS. 4 to 7 as follows.

Figure 4 is an exploded perspective view showing the pumping pipe connection structure according to the present invention, Figure 5 is a longitudinal cross-sectional view showing a pumping pipe connection structure according to the present invention, Figure 6 is groundwater using the pumping pipe connection structure of the present invention This is a longitudinal section of the well. And Figure 7 is a longitudinal cross-sectional view showing another embodiment of the connector of the present invention.

The connection structure of the groundwater pumping pipe of the present invention is hooked to the close contact ends 14 and 24 formed integrally at the ends of each of the upper pipe 10 and the lower pipe 20, and the locking close ends 14 and 24. It consists of a pair of fasteners 12 and 22 fitted to the upper pipe 10 and the lower pipe 20, respectively, and a connector 30 screwed to the fasteners 12 and 22.

In more detail, the pair of fasteners 12 and 22 are formed in a polygonal column shape so that one end thereof is formed in a cylindrical shape, the outer circumferential surface thereof is screwed, and the other end is easily connected by a tool. It is formed to have an inner diameter that can be fitted to the outer diameter of the lower pipe and the lower pipe 20 of the upper pipe 10, respectively.

At the ends of the upper pipe 10 and the lower pipe 20 in which the fasteners 12 and 22 are fitted, the locking contact ends 14 and 24 are integrally formed to protrude in the outer diameter direction, respectively. 14 and 24 are integrally formed by being fixed to the ends of the upper pipe 10 and the lower pipe 20 by welding or the like.

The connector 30 is threaded from both ends to the seating end 30a of the center portion so as to be fastened to the fasteners 12 and 22, and the seating end 30a is formed to protrude in the inner diameter direction. Annular packing members 32 are fitted to both sides of the seating end 30a, respectively.

The outer surface of the connector 30 is formed in the shape of a polygonal column to facilitate the connection work using a tool.

In addition, according to one embodiment of the connector 30 according to the present invention shown in Figures 2 to 6 attached to one side of the outer surface of the connector 30, the power line 42 is connected to the submersible pump 50 And the wire protection end 34 protrudes outward in the longitudinal direction of the positive pipe so that the electric wire 40 including the signal line 44 connected to the high water level measuring instrument 52 and the low water level measuring instrument 54 is fitted therebetween. Is formed. At this time, the interval between the two protrusions of the wire protection end 34 is formed at a predetermined interval to which the electric wiring 40 can be fitted and fixed, and the height of the protrusion is directly connected to the casing C. It is formed slightly higher than the height of the electrical wiring 40 so as not to be rubbed.

Of course, the connector may be provided with a plurality of wiring protection ends, and as shown in another embodiment of the connector shown in FIG. 7, two wiring protection ends 34A and 34B may be formed from the outer surface of the connector 30. It is formed to be spaced apart and spaced apart, the power line 42 and high, low water level meter connected to the submersible pump 50 to supply power in the electrical wiring passing through the connection of the upper pipe 10 and the lower pipe 20 ( Fixing and protecting the wiring of the signal line 44 connected to the 52 and 54 may be made separately.

The upper pipe 10 so as to be caught by the upper pipe 10 and the lower pipe 20 and the locking close ends 14 and 24 formed integrally with the locking close ends 14 and 24 forming the pump pipe connection structure of the present invention. The coupling process of the pair of fasteners 12 and 22 fitted to the lower pipe 20 and the connector 30 screwed to the fasteners 12 and 22 will be described with reference to FIG. 5. Is as follows.

A connector in which the packing member 32 is fitted to both sides between the upper pipe 10 and the lower pipe 20 in which a pair of fasteners 12 and 22 are fitted and the locking contact ends 14 and 24 are integrally formed. 30 is connected to and coupled to the upper pipe 10 so that the engaging close ends 14 and 24 are in close contact with both sides of the packing member 32 supported by the seating end 30a of the connector 30. The upper pipe 10 and the lower pipe 20 are connected by screwing the fasteners 12 and 22 inserted into the lower pipe 20 in the direction of the packing member 32 at the center from both ends of the inner surface of the connector 30. Will be.

The operation according to the connection structure of the groundwater pumping pipe of the present invention will be described with reference to the accompanying drawings shown in Figures 4 to 6 as follows.

First, looking at the process of interconnecting the upper pipe 10 and the lower pipe 20 in the connecting body of the positive pipes, the fasteners 12, respectively at the lower end of the upper pipe 10 and the upper end of the lower pipe 20 22) respectively threaded parts are opposed to each other, and the locking contact ends 14 and 24 are fixed to the lower end of the upper pipe 10 and the upper end of the lower pipe 20 by welding or the like. When formed, the fastening fasteners 12 and 22 are engaged with the locking close ends 14 and 24 so that the fasteners 12 and 22 are separated from the ends of the upper pipe 10 and the lower pipe 20 so as not to be separated.

Then, when the threaded portions of the fasteners 12 and 22 fitted to the upper pipe 10 and the lower pipe 20 are screwed from both ends of the inner surface of the connector 30, the upper pipe 10 and the lower pipe ( Each of the engaging close ends 14 and 24 coupled to 20 are in close contact with the packing member 32 supported by the seating end 30a protruding in the inner diameter direction from the inner side of the connector 30 to perform watertight action. The connection of the pipe 10 and the lower pipe 20 is made, and this connection action is carried out along the positive pipe, that is, the threaded portion of the inner surface of the connector 30, the inner surface of the connector 30, and the outer peripheral surface of the fasteners 12 and 22. Happens in.

Therefore, even if the depth of development of the groundwater increases so that a stronger connection force is required between the pumping pipes, the diameter of the connector 30 does not need to be enlarged, and thus the cross section of the casing C and the excavation hole H is increased. Without causing the problem that the diameter is enlarged, simply extend the connector 30 and the fasteners 12 and 22 in the longitudinal direction to reduce the area of the screwed portion of the inner surface of the connector 30 and the outer peripheral surface of the fasteners 12 and 22. The problem of increasing the connecting force can be solved by increasing the lengthwise direction.

Of course, the pump pipe formed separately from the connector 30 or the fasteners 12 and 22 also does not need to increase the diameter or thickness of the cross section.

In this case, the outer surfaces of the fasteners 12 and 22 and the connector 30 are formed in the shape of a polygonal column to facilitate the use of a tool for fastening such a screw and to apply a stronger connection force. .

As such, the casing of the excavation hole (H) in which the excavation work and the casing work are completed by connecting the submersible pump 50 to one end of the connecting pipe of the positive pipe in which the plurality of upper pipes 10 and the lower pipes 20 are sequentially interconnected. (C) is installed downward down toward the underground reservoir layer (R) in this case, in this case the power line 42 and the submersible pump 50 is connected to supply the power for driving the motor of the submersible pump (50) Electric wiring 40 also includes a signal line 44 connected to the high water level measuring instrument 52 and the low water level measuring instrument 54 installed at a specific position of the excavation hole (H) for controlling the water level of the groundwater level The electric wire 40 is casing (C) in the installation process of the positive pipe by being fitted and secured by being fitted to the wire protection end 34 protruding from the outer surface of the connector 30 according to the present invention while descending along one side of the positive pipe. Friction with) By the impact it will serve to prevent the disconnection or short circuit. In addition to this, it is possible to increase the fixing and protection action of the electrical wiring 40 fitted to the wiring protection end 34 by taping.

In addition, since the wire protection end 34 for fixing and protecting the electric wire 40 is formed on the outer surface of the connector 30, the inner surface and the fastener ( 12 and 22 and the connection force between the positive pipes connected regardless of the fastening force of the engaging close ends (14, 24) and the like does not occur.

Of course, in the case of another embodiment of the connector 30 according to the present invention shown in FIG. 7, the fixing and protection of the separated power line 42 and the signal line 44 are separately performed at the two wire protection ends 34A and 34B. The same operation as described above except that it is made.

According to the present invention, the connecting action of the upper pipe and the lower pipe occurs on the longitudinal surface along the positive pipe, that is, on the threaded portion of the inner surface of the connector and the outer circumferential surface of the fastener, so that the connecting action is performed in the transverse plane in the conventional flange connection structure. Unlike this case, even if the required connection force increases with the increase of the depth of groundwater development, the area of the connection can be enlarged only in the longitudinal direction to support the increased required connection force. The cross section of the pumped pipe connection including the connector can be greatly reduced and the cross section of the casing and the excavation hole can be reduced compared to the conventional flange connection without affecting the pumping capacity since the cross section does not need to be enlarged together. It is possible to improve the ease and economical efficiency of casing installation and excavation work.

And, according to the present invention in which the fastener and the connector are separated from the positive pipe, unlike the conventional flange connection formed integrally with the positive pipe, the thickness of the positive pipe does not need to be increased even when the required connecting force is increased. Self-weight reduction and cost reduction are provided, and when the submerged pump is used, electrical wiring including a power line connected to the submersible pump located at the bottom of the pump pipe from the ground is formed to protrude from the outer side of the connector of the present invention. When it is fixed to the protective end, it eliminates the trouble of separately cutting the wire passing part on one side of the flange in the conventional structure, and also does not cause the uneven connection force between the pumping pipes caused by the weakening in the cut wire passing part. The effect is not provided.

Claims (3)

In the connection structure of the pumping pipe for groundwater, the catching close ends 14 and 24 integrally formed at the ends of each of the upper pipe 10 and the lower pipe 20 and the catching close ends 14 and 24. And a pair of fasteners 12 and 22 fitted to the upper pipe 10 and the lower pipe 20, and a connector 30 to which both ends are screwed to the fasteners 12 and 22, respectively. Connection structure of pumping pipe for groundwater. The upper and lower pipes 10 and 22 of claim 1, wherein one end of the fasteners 12 and 22 is screwed on the outer circumferential surface thereof, and the fastening ends 14 and 24 are fitted with the upper and lower pipes 10 and 22 to which the fasteners 12 and 22 are fitted. It is integrally formed to protrude in the outer diameter direction at each end of the 20, the connector 30 is screwed on the inner surface to be screwed with the fasteners (12, 22) and the mounting end (30a) in the center of the inner surface This projecting structure is connected to the ground water pumping pipe, characterized in that the packing member 32 is fitted to both sides of the seating end (30a) is formed. According to claim 1 or claim 2, Ground protection pumping water characterized in that the wire protection end 34 is formed to protrude to the outside so that the electric wiring 40 is fitted to the outer surface of the connector 30 in the longitudinal direction Pipe connection structure.