KR101783204B1 - Double-acting water pump casing assembly - Google Patents

Abstract

The present invention relates to a double-acting water pump casing assembly. According to the present invention, a double-acting water pump casing assembly is configured for a flow path which is a moving path of a fluid to communicate by mutually coupling a main pipe, a first connection pipe, and upper pipes which are components to form a water lift structure in a state in which the main pipe, the first connection pipe, and the upper pipes are placed in the same axis. Therefore, composition can be simplified without a request to form an additional structure for forming a flow path. Moreover, mass production capability of products can be improved.

Description

A double-acting water pump casing assembly for a double-

The present invention relates to a casing assembly of a double-acting type amphibious pump, and more particularly to a casing assembly of a double-acting type amphoteric pump improved in structure so that a flow path structure for a fluid pump can be formed in a process of assembling components will be.

Generally, the amphibious pump is installed underground so that the groundwater can be pumped, as shown in Fig.

One of these pumping pumps, several electric sampling devices in the form of an inertial pump have been developed to pump deeper groundwater from a small borehole. Typical examples are an inertial ball (Korean Patent No. 10-0770051) or an opening / closing unit (Patent Registration No. 10-1124075) have been used mainly for the purpose of pumping groundwater by up and down movement.

However, since the above-mentioned devices are unable to insert the iron core in the electromagnet due to the fact that the groundwater intake pipe is located at the center of the pump, the strength of the electromagnet is restricted. Therefore, There is a problem that sufficient power can not be provided.

In addition, since an inertial ball or an opening / closing unit is used, there is a problem that the amount of pumped water is very small.

In order to solve such a problem, 10-2015-0075889 (name: double acting electromagnetic pump) was applied as shown in FIG. 9, but this double acting electromagnetic pump has a pair of electromagnets 12 And the case 11 which closes the piston 13 disposed therebetween, it is impossible to simplify the structure, thereby hindering the mass productivity of the product.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide a fluid flow structure for a fluid pump, And to provide a casing assembly of a double-acting type positive displacement pump capable of improving the mass productivity of the pump.

In order to accomplish the above object, the casing assembly of the double-acting type amphibious pumping apparatus according to the present invention is driven to pump groundwater, and has a tubular shape having an outer circumferential surface formed in a circular shape, A pair of central flow paths formed between the inner circumferential surface defining the hole and the outer circumferential surface so as not to communicate with each other with the through hole interposed therebetween, and a pair of inflow flow paths connected to the respective central flow paths, ; A cylinder having a piston portion disposed in the through-hole of the main tube and a pair of rod portions extending from both ends of the piston portion; A first connection pipe having a communication space in which a magnetic body that is power-coupled to any one of the rod portions is disposed, the first connection pipe being coupled to the main pipe so that the communication space and the discharge flow paths of the main pipe communicate with each other; And an upper tube having an installation space in which an electromagnet generating an attraction or a repulsive force is installed on the magnetic body and connected to the first connection tube so that the installation space and the communication space of the first connection tube communicate with each other, .

The present invention relates to a bearing for rotationally connecting the magnetic body and a rod portion for supporting the rod portion in a rotatable manner, A first support on which the bearing is installed; And a second support body coupled to the first support body in a state of being in surface contact with the rod portion through the first support body and to which the magnetic body is attached.

 The main tube has a tubular shape having an outer circumferential surface formed in a circular shape and has a through hole formed at the center thereof. The main tube communicates with an inner circumferential surface defining the through hole and the outer circumferential surface, A center tube having a pair of central flow paths formed so as not to overlap with each other; A guide hole which is coupled to one end of the center pipe and in which one of the rod portions of the cylinder is installed so as to be movable relative to each other and which is formed so as not to communicate with each other on both sides of the guide hole, An inflow pipe having the pair of inflow passages communicating with each other; A guide hole which is coupled to the other end of the center pipe and in which the other one of the rod portions of the cylinder is installed to be movable relative to each other, And a discharge pipe having the pair of discharge flow paths communicating correspondingly.

The present invention is characterized in that it comprises a communication space in which a magnetic body to be magnetically connected to the other one of the rod portions is disposed, and a second connection, which is coupled to the main tube so that each of the inflow channels of the main tube and the communication space communicate with each other, tube; And a lower tube coupled to the second connection tube so that the installation space and the communication space of the second connection tube communicate with each other, wherein the installation space includes an electromagnet for generating attraction or repulsion force to the magnetic body, .

The casing assembly of the double-acting type amphibious pump according to the present invention having the above-described structure has a main pipe, a first connecting pipe and an upper pipe corresponding to parts for forming a positive number structure, The flow path of the fluid is communicated so that no separate structure for forming the flow path is required, thereby simplifying the structure and improving the mass productivity of the product Derive an advantage.

1 is a perspective view of a casing assembly of a double-acting water pump according to an embodiment of the present invention;
2 is a sectional view taken along the line II-II in Fig.
3 is an enlarged view of a portion III in Fig.
4 is an enlarged view of a portion IV in Fig.
5 is an enlarged view of a portion V in Fig.
6 and 7 are views for explaining a positive number principle according to an embodiment of the present invention.
8 is a view for explaining the concept of a general amphibious pump;
9 is a view for explaining a problem of a double-acting pump according to the prior art.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a casing assembly of a double-action type amphibious pump according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 is a cross-sectional view taken along a line II-II in FIG. 1, FIG. 3 is an enlarged view of a portion III in FIG. 2, and FIG. 4 is a cross- 2 is an enlarged view of part IV of FIG. 2, FIG. 5 is an enlarged view of part V of FIG. 2, and FIGS. 6 and 7 are views for explaining a positive number principle according to an embodiment of the present invention.

1 to 3, the casing assembly of the double-acting type amphibious pump according to the present invention is driven to pump groundwater. The casing assembly includes a main pipe 100, a cylinder 4, (110) and an upper tube (120).

The main pipe 100 has a cylindrical shape with an outer peripheral surface formed in a circular shape and a through hole 11 in which the piston portion 41 of the cylinder 4 is located is formed at the center of the main pipe 100. The through hole 11 A pair of inflow channels 22 and a pair of discharge channels 32 formed between the inner circumferential surface defining the inner circumferential surface and the outer circumferential surface.

The respective central flow paths 12 are formed so as not to communicate with each other with the through holes 11 therebetween and the respective inflow flow paths 22 and the discharge flow paths 32 are formed in the respective central flow paths 12, Respectively.

The cylinder 4 includes a piston portion 41 disposed in the through hole 11 of the main pipe 100 and a pair of rod portions 42 extending from both ends of the piston portion 41 6 and 7, a force for moving fluid relative to the main tube 100 is applied to the fluid.

The first connection pipe 110 includes a communication space disposed coaxially with the main pipe 100 and having a magnetic body 118 that is connected to one of the rod portions 42 And is coupled to the main pipe 100 so that the communication space and the discharge passage 32 of the main pipe 100 communicate with each other.

The upper tube 120 is provided with an installation space in which the electromagnets 5 for generating attractive force or repulsive force are installed on the magnetic bodies 118 and 138 and the communication space between the installation space and the first connection tube 110 And is coupled to the first connection pipe 110 so that the spaces communicate with each other.

The casing assembly of the double-acting type positive displacement pump according to an embodiment of the present invention having the above-described structure includes a main pipe 100, a first connecting pipe 110, By forming the tubes 120 by cooperating with each other in a state where the tubes 120 are positioned on the same axis, it is possible to simplify the constitution since the flow path of the fluid is communicated, And to improve the mass productivity of the product.

The present embodiment includes a power connecting means for powerfully connecting the magnetic body 118 and the rod portion 42, as best shown in Fig.

That is, the power connection means includes a bearing 112, a first support 114, and a second support 116. The bearing 112 rotatably supports the rod 42 to allow smooth movement of the rod 42 and the first support 114 supports the bearing 112 securely And the second support body 116 can support the magnetic body 118 firmly.

The second support body 116 is configured such that the rod portion 42 passing through the first support body 114 is connected to the first support body 114 in a surface contact state.

The present embodiment having such a configuration can smoothly guide the movement of the rod portion 42 and firmly support the rod portion 42 without flowing, The advantage of doing so is derived.

4, the main pipe 100 employed in the present embodiment includes a central pipe 1, an inlet pipe 2, and a discharge pipe 3.

The center tube (1) has a tubular shape having an outer peripheral surface in a circular shape, and a through hole (11) is formed at the center. The center tube (1) is inserted between the inner peripheral surface defining the through hole (11) And a pair of central flow passages (12) formed on the opposite side with the hole (11) therebetween so as not to communicate with each other.

The piston portion 41 of the cylinder 4 is disposed in the through hole 11 of the center pipe 1 and the pair of central flow paths 12 are connected to the inlet flow path 22 and the discharge flow path 22, (32).

The cylinder 4 includes a piston portion 41 disposed in the through hole 11 of the center pipe 1 and a pair of rod portions 42 extending from both ends of the piston portion 41 So that a force for moving the fluid relative to the center tube 1 is applied to the fluid as shown in Figs. 6 (b) and 7 (b).

The inlet pipe 2 is connected to one end of the center pipe 1 so as to be disposed at a position coaxial with the center pipe 1 and has a guide hole 21 and a pair of inlet channels 22 .

One of the rod portions (42) of the cylinder (4) is movably installed in the guide hole (21), and the pair of inflow passages (22) are arranged around the guide hole And are formed so as not to communicate with each other on both sides and communicate with each other in a one-to-one correspondence with the respective central flow paths (12).

The discharge pipe 3 is coupled to the other end of the central pipe 1 so as to be disposed coaxially with the center pipe 1 and includes a guide hole 31 and a pair of discharge flow paths 32 .

The other one of the rod portions 42 of the cylinder 4 is installed in the guide hole 31 so as to be movable relative to the guide hole 31, And are formed so as not to communicate with each other on both sides and communicate with each other in a one-to-one correspondence with the respective central flow paths (12).

The present embodiment having the above-described configuration is characterized in that the flow path which is a path for pumping groundwater is connected to the center pipe 1, the inflow pipe 2 and the discharge pipe 3, The inflow passage 22 and the discharge passage 32 to prevent interference between the component and the underground material due to the external exposure of the flow passage and to provide a separate structure for flow passage formation So that it is possible to connect the flow path due to the structure of the pipe itself, thereby making it possible to expect a merit that a simple and compact structure can be realized.

The present embodiment is for moving the piston portion 41 of the cylinder 4 and is provided at a position spaced apart from the rod portions 42 so as to generate a pulling force or a repulsive force to the rod portions 42 Pair of electromagnets 5.

This embodiment having such a configuration has an advantage that a relatively large force can be applied even by a simple structure by exerting the force for pumping groundwater by the electromagnet 5. [

The present embodiment is provided with a pair of damping chambers formed between the central passage 12 and the inflow passage 22 and between the central passage 12 and the discharge passage 32, (12a).

The present embodiment having such a configuration can smoothly maintain the flow of the fluid in the central flow path 12 of the center tube 1, thereby suppressing the precision and malfunction of the product operation due to sudden inflow of the fluid I will.

The present embodiment includes fastening holes 13 and 23 formed in the center pipe 1 and the inflow pipe 2 and formed in positions coaxial with each other.

Each of the fastening holes 13 and 23 is formed between the inner circumferential surface and the outer circumferential surface of the center tube 1 and is fastened to each other by one fastening means to thereby connect the center tube 1 and the inflow tube 2 So that the central flow path 12 and the inflow path 22 can communicate with each other.

The discharge pipe 3 also includes a fastening hole 33 formed coaxially with the fastening hole 13 of the center pipe 1 like the inflow pipe 2. The coupling pipe 33 of the discharge pipe 3 and the coupling hole 13 of the central pipe 1 are fastened to each other by fastening means so that the center pipe 1 and the discharge pipe 3 are connected to each other, And the flow path 12 and the discharge flow path 32 are communicably connected to each other.

The present embodiment having such a configuration is configured to simultaneously realize connection between parts and channel connection in a process of assembling a product, thereby deriving an advantage that the mass productivity of the product can be further improved.

On the other hand, the present embodiment is provided with an inlet check valve 6 for opening and closing a pair of inlet passages 22 of the inlet pipe 2, a pair of outlet passages 32 Side check valves 7 for opening and closing them.

6, when the piston portion 41 of the cylinder 4 moves upward to press the fluid by the action of the electromagnet 5, The valve is opened and the fluid is discharged into the discharge passage 32. At the same time, the inlet check valves 6 are opened and the fluid flows into the central passage 12 via the inflow passage 22. [

7, when the piston 41 of the cylinder 4 moves downward under the action of the electromagnet 5 to pressurize the fluid, the discharge-side check valves 7 The left check valve is opened and the fluid is discharged to the discharge flow path 32. At the same time, the inlet check valves 6 are opened and the fluid flows into the center flow path 12 via the inflow path 22.

As described above, according to the embodiment of the present invention, the fluid can be pumped according to the angular movement of the cylinder 4, thereby making it possible to increase the amniotic efficiency of the fluid.

As best shown in FIG. 5, this embodiment includes a second connection pipe 130 and a lower pipe 140.

The second connection pipe (130) has a communication space in which a magnetic body (138), which is connected to the other one of the rod portions (42), is disposed, and the communication space And is connected to the main pipe 100 so that the respective inflow channels 22 communicate with each other.

The lower tube 140 is provided with an installation space in which the electromagnet 5 for generating attraction or repulsive force is installed in the magnetic body 138 and the communication space between the installation space and the second connection tube 130 And is coupled to the second connection pipe 130 so as to be communicated.

In this embodiment having such a configuration, the first connection pipe 110 and the upper pipe 120 located at the upper side with respect to the main pipe 100, the second connection pipe 130 positioned at the lower side and the lower pipe 140 are coupled to each other at positions coaxial with each other, and a positive flow path can be realized in the process of coupling between the components. Thus, a separate structure for forming the flow path is not required, And to improve the mass productivity of the product.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, It is obvious that all modifications and concrete examples which can easily be devised by those skilled in the art within the scope of technical thought are included in the scope of the present invention.

100: main pipe 110: first connection pipe
112: bearing 114: first support
116: second support body 118: magnetic body
120: upper tube 130: second connector
138: magnetic body 140: lower tube
1: center tube 11: through hole
12: central flow path 12a: damping space
13: fastening hole 2: inlet pipe
21: Guide ball 22: Inflow channel
23: fastening hole 3: discharge pipe
31: Guide ball 32: Discharge channel
33: fastening hole 4: cylinder
41: piston portion 42: rod portion
5: Electromagnet 6: Check valve on the inlet side
7: Check valve on discharge side

Claims (4)

Which is driven so that the groundwater can be pumped,
And a pair of inner circumferential surfaces defining a through hole and formed so as not to communicate with each other through the through hole between the inner circumferential surface defining the through hole and the outer circumferential surface, A main pipe having a pair of inflow channels and a discharge channel connected to the respective central channels;
A cylinder having a piston portion disposed in the through-hole of the main tube and a pair of rod portions extending from both ends of the piston portion;
A first connection pipe having a communication space in which a magnetic body that is power-coupled to any one of the rod portions is disposed, the first connection pipe being coupled to the main pipe so that the communication space and the discharge flow paths of the main pipe communicate with each other; And
And an upper tube having an installation space in which an electromagnet generating an attraction force or a repulsive force is installed on the magnetic body and connected to the first connection tube so that the installation space and the communication space of the first connection tube communicate with each other,
In the main pipe,
And a damping space capable of temporarily receiving the groundwater is provided between the central passage and the inflow passage or between the central passage and the discharge passage. The method according to claim 1,
And for connecting the magnetic body and the rod portion in a dynamic manner,
A bearing rotatably supporting the rod portion;
A first support on which the bearing is installed; And
And a second support body connected to the rod portion passing through the first support body so as to be in surface contact with the first support body and to which the magnetic body is attached. . The method according to claim 1,
The main pipe
And a pair of inner circumferential surfaces defining a through hole and formed so as not to communicate with each other through the through hole between the inner circumferential surface defining the through hole and the outer circumferential surface, A central tube having a central flow path of the gas;
A guide hole which is coupled to one end of the center pipe and in which one of the rod portions of the cylinder is installed so as to be movable relative to each other and which is formed so as not to communicate with each other on both sides of the guide hole, An inflow pipe having the pair of inflow passages communicating with each other; And
A guide hole which is coupled to the other end of the center pipe and in which the other one of the rod portions of the cylinder is installed so as to be movable relative to each other, And a discharge pipe having the pair of discharge channels communicated with the discharge pipe. The method according to claim 1,
A second connection pipe having a communication space in which a magnetic body that is mechanically connected to the other one of the rod portions is disposed, the second connection pipe being connected to the main pipe so that the communication spaces and the respective inflow channels of the main pipe communicate with each other; And
And a lower pipe coupled to the second connection pipe so that the installation space and the communication space of the second connection pipe communicate with each other, wherein the installation space includes an electromagnet for generating an attraction force or a repulsive force to the magnetic member, Wherein the pump assembly is a pump assembly.

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