KR101210969B1 - T-shaped strainer for pump suction - Google Patents

Abstract

PURPOSE: A T-shaped strainer for pump suction is provided to reduce costs and time for maintenance as the inside of the strainer can be directly checked. CONSTITUTION: A T-shaped strainer for pump suction comprises an integral body(100) and a lid(200). The integral body comprises a suction hole(110), an ejection hole(120), a filter unit(130), and an insertion port(140). Fluid is inhaled through the suction hole. The fluid inhaled through the suction hole is discharged through the ejection hole. The filter unit filters foreign matters in the fluid. The insertion port is formed between the suction hole and the ejection hole. A filtering net(300) is assembled or disassembled to the filter unit. The lid is coupled to the insertion port with bolts.

Description

T-shaped strainer for pump suction

The present invention relates to a strainer installed on the fluid suction side of the inline pressurized pump horizontally installed in the water supply pipe for moving the fluid, in particular because the elbow (elbow) and the strainer is formed in a combined form, the installation area is reduced, The present invention relates to a T-shaped strainer for pump suction, which is easy to maintain and can be reused semi-permanently, by changing its structure into a T-shape so as to dismantle, clean, and assemble the filtering net that filters foreign substances contained in the fluid.

In general, in a field where fluid transfer is inevitably required, such as in a water supply plant or an oil refining and petrochemical plant, the fluid moves through a pipe, and the fluid flowing inside the pipe contains impurities by itself or is generated from the pipe. There are foreign substances generated when welding dirt or rust such as rust.

When the pipes are blocked by various foreign substances, the fluid cannot flow smoothly into the pipes.

In particular, due to various foreign substances mixed in the fluid flowing in the pipe, the pump for forcibly transferring the fluid, the temperature control valve for controlling the temperature of the fluid to be transferred, and the pressure reducing valve to cause failures such as the entire pipe, pump and There is a problem that the various valves themselves need to be replaced.

In order to prevent this from happening, a strainer equipped with a filter to filter foreign substances in the pipe was installed, and a method of periodically cleaning the strainer or replacing the filter was used.

Therefore, a strainer is used as a means of removing these various foreign substances through a connecting tube.

In other words, the strainer is attached to the front of the pump, various regulating valves, steam traps, and the like, and serves to protect the equipment in advance to prevent equipment failure due to impurities in the pipe.

1 is a cross-sectional view showing a conventional strainer, Figure 2 is an exemplary view showing a state in which the strainer of Figure 1 is mounted on the front end of the inline pressure pump.

1 and 2, the conventional strainer is installed on the fluid intake side of the horizontal in-line pressurized pump P installed horizontally in the water supply pipe.

In the structure in which the conventional strainer is installed in the inline pressurized pump P, one end of the flexible joint F is first coupled to the front end of the inline pressurized pump P, that is, the fluid suction side through which the fluid is sucked. Then, the conventional strainer is connected to the other end of the flexible joint F, and finally, an elbow E for changing the moving direction of the fluid is connected to one end of the strainer.

Here, the flexible joint (F) is located between the inline pressure pump (P) and the strainer to facilitate the repair or removal of the inline pressure pump (P) installed in the water supply pipe.

In general, when the water supply pipeline construction is carried out, the constant pipeline consisting of the above-described structure is buried in the basement of the road. In the case of the constant pipeline having the above-described structure, the structure is complicated and the flexible joint (F) and the elbow are The connection structure like (E) requires a large installation area.

In this way, if the installation area in the water supply pipeline construction is large, more digging work is required, which increases the cost of civil engineering and lengthens the construction period. As such, the longer the construction period causes the traffic jam on the road, there is a problem that further complaints occur.

On the other hand, the conventional strainer is formed in the shape of the Y-shape, looking specifically at the structure of the strainer body 10, the inlet port 11, the fluid flows inlet 11 and the discharge port 12 is formed integrally formed In the lower portion between the inlet port 11 and the outlet port 12, an insertion hole 13 through which the filter 20 is inserted into the main body 10 of the strainer is formed. In addition, the cover 30 is fastened to the insertion hole 13.

That is, the strainer has a structure that is fastened to each other in three directions, the predetermined filter 20 is inserted into the lower insertion opening 13, the filter 20 is inserted into close contact with the cover 30.

Therefore, the strainer is the fluid sucked into the pump at a predetermined pressure is filtered through the strainer in the middle, then discharged through the side outlet 12 is introduced into the inline pressure pump (P).

Here, the strainer must block a valve installed in the pipe in order to periodically remove the foreign matter accumulated in the inner side of the cylindrical filter (20).

That is, to check whether the strainer is clogged by foreign matter or when it is time to clean the strainer, the operating equipment should be shut down and the strainer should be disassembled directly.

As described above, in the conventional strainer, since the insertion hole 13 into which the filter 20 is inserted is located at the bottom of the strainer main body 10, in the case of the pipe installed at the bottom of the work space, when the foreign matter is accumulated in the filter, the bottom direction To dismantle the filter 20 to be cleaned or replaced.

That is, the operator is not easy to disassemble and assemble the filter 20 because the strainer is installed between the pipe and the floor of the work space is very close. If the assembly and disassembly is not easy and the maintenance time is unnecessarily long, the down time of the equipment becomes long, so the progress of the smooth working process cannot be expected.

Then, after disassembling the structural filter 20, the internal state of the strainer through the insertion hole 13 can not be observed with the naked eye, there is a problem that is very vulnerable to the maintenance of the strainer.

On the other hand, conventional strainers are made of cast iron, so the rust is generated inside the fluid over time.

When rust occurs in the strainer in this manner, the fluid passing through the strainer is contaminated by the rust, and the rusted fluid may be sucked into the pump P to damage the pump P.

In addition, since such rust accumulates in the filter and the filter 20 is blocked, the period for cleaning the filter 20 is shortened because it inhibits the smooth flow of the fluid.

In addition, when the cleaning of the filter is not performed in a state where excessive foreign substances generated by rust are accumulated in the filter 20, the rust water flows into the pump P, and the filter 20 is damaged due to corrosion. If it is lost, since the filter 20 cannot be reused, the cost of maintenance increases because the filter 20 cannot be reused.

The problem of the present invention devised to solve the above-mentioned problems, by applying to the in-line pressure pump installed in the water supply pipe, to simplify the structure by replacing the existing separate elbow, the overall installation area of the water supply pipe It is to provide a T-shaped strainer for pump suction which can be greatly reduced.

In addition, an additional object of the present invention is to provide a T-shaped strainer for pump suction which can dismantle, clean and assemble the strainer in the upper direction of the work space.

In addition, another object of the present invention is to provide a T-shaped strainer for pump suction which can be semi-permanently reused without being corroded by a fluid.

In addition, an additional object of the present invention is to provide a T-shaped strainer for pump suction which can discharge the air moving inside the pipe together with the fluid to the outside.

The present invention devised to achieve the above object is a strainer provided on the fluid intake side of a horizontal in-line pressurized pump installed horizontally in a constant water pipe for moving a fluid, the inlet for the fluid is sucked in, and the fluid sucked from the inlet Is formed on an upper surface between the discharge port through which the gas is discharged, the foreign matter contained in the fluid sucked through the suction port, and the suction port and the discharge port, so that a predetermined sieve is assembled or disassembled in the filter part. It includes an integrated body having an insertion hole to be bolted to the insertion hole.

The filter unit is positioned to face the suction port, and is horizontally positioned between the first partition wall, the first partition wall and the second partition wall, which are formed to form an inclined surface by a predetermined height, and the top of the first partition wall and the second partition wall. Both ends are connected to the lower end of the mesh-type filter surface with a central portion open so that the strainer rests in the inner space of the body and is supported in the vertical direction, and is located behind the first partition wall and faces the suction port. It is located, and formed in the rear of the second partition wall and the first partition forming an inclined surface, and includes an outflow passage for guiding the fluid introduced into the filter surface to the discharge port.

The sieve is seated on the bottom of the inside of the body, it characterized in that it has a first manure portion of the open top shape and a second manure of the hemispherical shape formed vertically along the upper outer diameter of the first manure.

The sieve is characterized in that the handle is further installed.

The second manure portion is characterized in that the inner surface is located toward the suction port direction.

The strainer is characterized in that the mesh (Mesh) of stainless material.

The body is characterized in that the material is stainless.

The cover is characterized in that the air vent (Air hole) is further formed.

The present invention is installed on the fluid suction side, which is the front end of the inline pressurized pump installed in the water supply pipe, the elbow is not required to reduce the overall installation area of the water supply pipe, thereby reducing the cost and time required for water supply pipeline work It works.

In addition, the present invention can dismantle, clean and assemble the strainer through the upper part of the strainer, it is possible to directly check the state of the strainer, the maintenance is very easy to shorten the maintenance time, thereby the overall smooth work process There is an effect going on.

In addition, the present invention is because the strainer is not corroded by the fluid to prevent the generation of rust inherently, can expect a smooth flow of the fluid at all times, can be reused semi-permanently, because it does not damage equipment such as pumps and valves The cost of maintaining and repairing this is reduced.

In addition, the present invention is an air vent formed in the strainer can easily discharge the air moving inside the pipe with the fluid to the outside has the effect of preventing the reduction in pumping efficiency caused by the air is sucked into the pump in advance.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate preferred embodiments of the invention and, together with the description, serve to further the understanding of the technical idea of the invention, And shall not be construed as interpretation.
1 is a cross-sectional view showing a conventional strainer,
Figure 2 is an exemplary view showing a state in which the strainer of Figure 1 is mounted on the front end of the inline pressure pump,
3 is an exploded perspective view showing a pump suction T-shaped strainer according to an embodiment of the present invention,
4 is a cross-sectional view showing a T-shaped strainer for pump suction according to an embodiment of the present invention;
Figure 5 is an exemplary view showing a state in which the pump suction T-shaped strainer according to an embodiment of the present invention is mounted on the front end of the inline pressure pump.

Hereinafter, a preferred embodiment of the pump suction T-shaped strainer according to the present invention will be described in detail.

Figure 3 is an exploded perspective view showing a pump suction T-shaped strainer according to an embodiment of the present invention, Figure 4 is a cross-sectional view showing a pump suction T-shaped strainer according to an embodiment of the present invention, Figure 5 is an embodiment of the present invention It is an exemplary figure which shows the state in which the pump suction T-shaped strainer by the example was attached to the front end of the inline pressurization pump.

3 to 5, the T-shaped strainer for pump suction according to the preferred embodiment of the present invention is composed of a component including a body 100 and a cover 200, which will be described in detail as follows.

First, the body 100 is formed integrally with the suction port 110, the discharge port 120 and the insertion port 140. In addition, the filter unit 130 is installed inside the body 100.

The suction port 110 is connected to a predetermined pipe (not shown) through which the fluid is transferred, and the predetermined fluid is sucked through the pipe.

The discharge port 120 discharges the fluid sucked through the suction port 110, and is connected to a predetermined pipe (not shown) like the suction port 110, and the fluid discharged through the discharge port 120 is connected to the discharge port 120. It is sucked into the inline pump P through the pipe.

The insertion hole 140 is formed on the upper surface between the suction hole 110 and the discharge hole 120, the screen 300 is inserted through the insertion hole 140.

At this time, the filter unit 130 for filtering the foreign matter contained in the fluid sucked through the suction port 110 is installed inside the body 100.

That is, when the strainer 300 is inserted through the insertion hole 140 formed on the upper surface of the body 100, at the same time through the upper portion of the filter unit 130, the strainer 300 inside the filter unit 130 This will be seated.

Therefore, the sieve net 300 may be assembled through the insertion hole 140 formed on the upper surface of the body 100, and at the same time, the sieve 300 may be dismantled.

At this time, the insertion hole 140 is bolted by the cover 200, and optionally can be placed additionally O-ring of the rubber material between the insertion hole 140 and the cover 200, the body When the internal pressure of the 100 rises, the leakage of fluid around the insertion hole 140 can be prevented.

On the other hand, the discharge port 120 is smaller than the diameter of the suction port 110, the suction port 110 and the discharge port 120 formed in the body 100 is horizontal to face each other in the body 100 It is characteristic that it is not formed in the direction, but is formed in mutually perpendicular direction.

That is, the fluid sucked through the suction port 110 is discharged to the side of the body 100 through the discharge port 120 formed on one side of the body 100, the function of the elbow and the strainer is coupled It is made of a structure.

This is a combination of elbows and strainers, which has the advantage that the overall installation area of the water conduit is reduced because a separate elbow is no longer needed.

On the other hand, when the filter unit 130 is composed of a component having a first partition 131, a second partition 132, the filtering surface 133 and the outlet passage 134, it will be described in detail as follows. .

The first partition 131 is positioned to face the suction port 110, and is installed while forming an inclined surface by a predetermined height.

That is, the bottom surface of the first partition wall 131 is in contact with the lower surface of the inner diameter of the body 100 is installed to form an inclined surface by a predetermined height.

The second partition 132 is located behind the first partition 131 and is positioned to face the suction port 110 similarly to the first partition 131. That is, the upper end of the second partition wall 132 is installed in contact with the upper surface of the inner diameter of the body 100.

The filtering surface 133 is horizontally positioned between the first partition wall 131 and the second partition wall 132. At this time, both ends of the filtering surface 133 are coupled to an upper end of the first partition 131 and a lower end of the second partition 132.

At this time, the filtering surface 133 is formed in the form of a mesh (Mesh Type) so that the fluid can be passed through, so that the strainer 300 is supported in the vertical direction by seating in the inner space of the body 100 The central part has a circular open structure.

In addition, the outlet passage 134 guides the fluid introduced into the filtering surface 133 to the discharge port 120 so that the fluid flows out.

On the other hand, the strainer 300 is inserted through the insertion hole 140 in order to filter the foreign matter contained in the fluid sucked through the suction port 110, that is, inside the body 100, that is, the filter unit 130 It is preferably located in a cylindrical shape, the outer diameter surface is a mesh type having a plurality of through-holes.

At this time, the sieve 300 is seated on the bottom of the inside of the body 100, the upper portion of the first manure portion 310 of the open shape, and vertically along the upper outer diameter of the first manure portion 310. The formed hemispherical second fertilizer 320 is formed, the second fertilizer 320 is the inner curved surface is located toward the suction port 110 direction.

That is, looking at the movement of the fluid flowing in the interior of the body 100 in detail, the fluid sucked through the inlet 110 is blocked by the first partition 131 and the second partition 132, The flow is naturally changed along the inclined surface in the direction of the filtering net 300 and the filtering surface 133, the fluid filtered by the filtering net 300 and the filtering surface 133 is guided to the outlet passage 134 to the body ( It flows out in the direction of the discharge port 120 formed on the side of 100.

At this time, the size of the inner diameter of the discharge port 120 is smaller than the size of the inner diameter of the suction port 110.

Here, the second filter part 320 in the filter net 300 is located in the vertical direction in the direction of the insertion hole 140, along with the filtering of the fluid, the filter net when dismantling, cleaning and assembly of the filter net (300) The handle 330 may be further installed at 300 to be easily gripped by an operator.

In addition, the material of the sieve 300 is made of stainless steel, which is light in weight, easy to handle, less damage due to high pressure of the fluid, and since corrosion does not occur by the fluid, there is an advantage that it can be used semi-permanently.

That is, the strainer 300 is installed through the insertion hole 140 formed in the upper direction of the body 100, and when dismantling or replacing the strainer 300 in the upper direction of the body 100, Compared with the conventional method of dismantling and assembling the sieve 300 in the lower direction of the body 100, the work space can be sufficiently secured, so that the dismantling, cleaning and assembly work of the sieve 300 is easy.

In addition, since after dismantling the sieve 300, the inside of the body 100 is easy to observe with the naked eye, there is an advantage of easy inspection and cleaning of the internal state of the body 100.

In addition, the body 100 may also be made of stainless steel, as in the sieve 300, to prevent rust caused by the fluid in advance.

This may cause a failure of the pump when the fluid sucked into the pump through the discharge port 120 is contaminated with rusted water, and when the strainer 300 is blocked by the rusted water, the flow rate passing through the body 100 is significantly increased. This is because the pumping efficiency is reduced due to the reduction in the flow rate finally drawn into the pump.

On the other hand, the insertion hole 140 is bolted to the cover 200 covering the open top. The cover may further include an air vent 400.

The air vent 400 serves as an air purge valve, and when air is filled in the entire piping line, since the circulation of the fluid is not smooth, the air vent 400 is further formed to discharge the internal air to the outside. In this way, the pumping efficiency can be increased by smoothly flowing the fluid. In addition, it is possible to block the occurrence of the cavitation (cavitation) of the pump due to the inflow of air.

The cover 200 may further include an O-ring made of rubber. That is, when the cover 200 is fastened to the insertion hole 140 by the bolt, the O-ring is positioned between the insertion hole 140 and the cover 200 so that the pressurized fluid flowing inside the body is inserted into the insertion hole 140 and the cover. It is possible to prevent leakage to the contact portion of the (200).

In addition, the suction port 110 is connected to the pipe, the discharge port 120 is connected to the pump, the insertion hole 140 is formed of a structure that is fastened to each other in the form of a flange (Flange) and the cover 200, respectively.

At this time, when the O-ring is further installed in contact with each other and fastened, it is possible to prevent the leakage of fluid flowing at a high pressure inside the body (100).

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, And will fall within the scope of the appended claims.

100: body 110: suction port
120: discharge port 130: filter portion
131: first partition 132: second partition
133: manure cotton 134: outflow passage
140: insertion hole 200: cover
300: strainer 310: the first strainer
320: second filter 330: handle
400: air vent P: inline pressurized pump

Claims (8)

A strainer installed on the fluid intake side of a horizontal in-line pressurized pump horizontally installed in a water supply pipe for moving a fluid,
The suction port 110 through which the fluid is sucked, the discharge port 120 through which the fluid sucked from the suction port 110 is discharged, and the filter unit 130 through which foreign matter contained in the fluid sucked through the suction port 110 is filtered. And an insertion hole 140 formed on an upper surface between the suction port 110 and the discharge port 120 to enable a predetermined filter net 300 to be assembled or disassembled in the filter unit 130. Body 100; And
The cover 200 is bolted to the insertion hole 140,
The filter unit 130,
A first partition 131 positioned to face the suction port 110 and installed on an inclined surface by a predetermined height;
Located horizontally between the first partition 131 and the second partition 132, both ends are connected to the upper end of the first partition 131 and the lower end of the second partition 132, the strainer 300 A mesh type filtering surface 133 of which a central portion is opened so that) is seated in the inner space of the body 100 and supported in the vertical direction;
A second partition 132 positioned rearward from the first partition 131, facing the suction port 110, and installed to form an inclined surface; And
T-shaped strainer for pump suction, which is formed at the rear of the first partition 131, and includes an outlet passage 134 for introducing the fluid introduced into the filtering surface 133 to the discharge port 120. . delete The method of claim 1,
The filter net 300 is seated on the bottom of the inside of the body 100, the upper part of the first filter portion 310 of the open shape; And
T-shaped strainer for pump suction, characterized in that it comprises a hemispherical second filter portion 320 formed vertically along the upper outer diameter of the first filter portion (310). The method of claim 3,
The strainer 300 is a pump suction T-shaped strainer, characterized in that the handle 330 is further installed. The method of claim 3,
The second filter portion 320 is a T-shaped strainer for pump suction, characterized in that the inner curved surface is located toward the suction port (110) direction. The method of claim 1,
The strainer 300 is a T-shaped strainer for pump suction, characterized in that the mesh (Mesh) of stainless material. The method of claim 1,
The body 100 is a T-shaped strainer for pump suction, characterized in that the material is stainless. The method of claim 1,
The cover is a T-shaped strainer for pump suction, characterized in that the air vent (Air hole) 400 is further formed.

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