KR100901076B1 - High viscosity fluid filtering unit - Google Patents

Abstract

A high viscosity fluid filtering unit is provided to prevent breakage of a mesh filter by high pressure and to minimize leakage of fluid. A high viscosity fluid filtering unit(30) installed between a fluid storage tank and a fluid exhaust pipe includes an upper socket(31), a mesh net filter(32), a stainless steel perforated net(33) and a lower socket. The upper socket is s installed to be connected in the fluid storage tank. The mesh net filter is installed to be adhered on the bottom of the upper socket. The stainless steel perforated net attached on the bottom of the mesh net filter includes a plurality of penetration holes(33a). The stainless steel perforated net is settled on a perforated part of an inner circumference of the upper socket.

Description

High viscosity fluid filtering unit

The present invention relates to a highly viscous fluid filtering unit, and more particularly, to a highly viscous fluid filtering unit capable of preventing breakage of a mesh network filter for filtering high viscous fluids such as honey, ink paint and grease.

In general, highly viscous fluids such as honey, ink, paint, various oils and grease have to remove these foreign substances because they are mixed during the manufacturing or use process.

For this purpose, a conventional method of simply passing a high viscosity fluid through a mesh network filter is used. However, the highly viscous fluid is difficult to pass through the mesh network filter by gravity alone because of its high cohesive force. Therefore, pressure must be applied to the mesh filter by various means so that the highly viscous fluid can be filtered through the mesh filter.

However, when the pressure is applied to the highly viscous fluid, a large external force acts on the mesh network filter, and the mesh network filter does not tolerate such external force, causing a problem of tearing.

The present invention has been made to solve the above-mentioned problems of the prior art, by placing a stainless perforated network on the lower side of the mesh network filter used to filter high-viscosity fluid, the mesh network filter is a vertical pressure by the strong pressure It is an object of the present invention to provide a highly viscous fluid filtering unit that can prevent its breakage even if it is received.

The high viscosity fluid filtering unit according to the present invention for solving the above problems is a fluid storage tank 10 for pressurizing the high viscosity fluid stored therein by injecting air and a high viscosity fluid of the fluid storage tank (10) In the high viscosity fluid filtering unit having a discharge pipe 20 for discharging,
The fluid storage tank 10 has a cover 11 is installed on the upper surface, the cover 11 is provided with an air injection means 12, the air injection means 12 to the air from the outside the fluid storage tank (10) is connected to the air injection pipe 13 for inflow,
The fluid storage tank 10 has an outlet pipe 14 formed at the bottom thereof to discharge the high viscosity fluid stored in the fluid storage tank 10 to the outside,
One side of the fluid discharge pipe 20 is provided with a valve 21,
Here, an upper socket 31 installed in communication with the fluid storage tank 10, a mesh net filter 32 installed in close contact with the bottom of the upper socket 31, and a bottom of the mesh net filter 32. And a lower socket 34 into which a lower periphery of the outer circumferential surface of the upper socket 31 is inserted.
The upper socket 31 is made of a metal material, and the fluid flow hole 31a in the vertical direction is formed at the center thereof, and a spiral is formed at the upper end of the inner circumferential surface of the fluid flow hole 31a, and the spiral of the upper socket 31 is Spirally coupled to the outer circumferential surface of the outlet pipe 14 of the fluid storage tank 10, a groove portion 31b of a predetermined depth is formed along the outer circumferential surface,
The upper socket 31 has an annular fitting groove 31c formed at a bottom thereof around the fluid flow hole 31a, and the fitting groove 31c has a first packing P1 made of silicon. Installed,
The mesh network filter 32 is installed in close contact with the lower side of the first packing (P1) installed in the fitting groove 31c of the upper socket 31,
The stainless perforated network 33 is installed on the lower side of the mesh network filter 32, a plurality of through holes 33a is formed radially, wherein, between the mesh network filter 32 and the stainless perforated network 33 The second packing (P2) made of silicon is installed,
A third packing (P3) made of double synthetic rubber (EPDM, Ethylene Propylene Diene M-class) is installed on the bottom of the stainless perforated network 33.
The lower socket 34 is connected to the fluid discharge pipe 20, the stepped portion 34a is formed on the inner peripheral surface,
Through holes 34b are formed at both sides of the lower socket 34, and fixing pieces 34c are provided at both sides of the through hole 34b, and fixing pieces 34c are provided at the fixing pieces 34c. Rotating lever (34d) is rotated around the installed,
The rotary lever 34d is rotatably connected to the fixed piece 34c by a pin at its upper end, and when the rotary lever 34d rotates in a specific direction, the upper end thereof is a recessed portion of the upper socket 31. 31b), the upper socket 31 and the lower socket 34 is firmly coupled, and when rotated in the other direction, the upper end is separated from the recess 31b of the upper socket 31, the upper socket 31 and It is configured to include the lower socket 34 can be easily removed.

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The highly viscous fluid filtering unit of the present invention configured as described above is provided with a stainless perforated network having a plurality of through holes formed on the bottom surface of the mesh network filter without interfering with the flow of the highly viscous fluid filtered by the mesh network filter. Due to the high pressure generated by air, there is an advantage of preventing the mesh mesh filter from being torn.

In addition, by installing a plurality of packings (first packing, second packing, third packing) on the upper side and the lower side of the mesh network filter, there is an advantage of minimizing the leaking fluid.

Hereinafter, with reference to the accompanying drawings an embodiment of a high viscosity fluid filtering unit according to the present invention will be described in detail.

1 is a perspective view of a high viscosity fluid filtering unit according to the present invention, Figure 2 is a partial cutaway view of a high viscosity fluid filtering unit according to the present invention, Figure 3 is an exploded perspective view of the high viscosity fluid filtering unit according to the present invention. .

And, Figure 4 is a cross-sectional view of a high viscosity fluid filtering unit according to the present invention, Figure 5 is a cross-sectional view showing a state in which the upper and lower sockets of the high viscosity fluid filtering unit according to the present invention, Figure 6 This is a state diagram of the use of the high viscosity fluid filtering unit.

The high viscosity fluid filtering unit 30 according to the present invention is a fluid storage tank 10 for pressurizing the high viscosity fluid stored therein by injecting air, and a fluid discharge pipe for discharging the high viscosity fluid of the fluid storage tank 10 It is installed between the (20) is a device for filtering the high viscosity fluid stored in the fluid storage tank (10).

The fluid storage tank 10 has a cover 11 is installed on the upper surface, the cover 11 is provided with an air injection means 12, the air injection means 12 to the air from the outside the fluid storage tank An air injection pipe 13 for introducing into the 10 is connected. The air pressure is introduced into the fluid storage tank 10 through the air injection means 12, whereby high viscosity fluids such as honey, ink paint and grease stored in the fluid storage tank 10 are air pressure. By the strong pressure to the lower side.

In addition, the fluid storage tank 10 has an outlet pipe 14 connected to the high viscosity fluid filtering unit 30 according to the present invention at a lower end thereof to externally store the high viscosity fluid stored in the fluid storage tank 10. To be discharged.

The fluid discharge pipe 20 is connected to the lower side of the high-viscosity fluid filtering unit according to the present invention to discharge the filtered high-viscosity fluid to the outside, and the valve 21 is installed on the pipeline to filter the high-viscosity as necessary. Shut off the fluid.

The high viscosity fluid filtering unit 30 is the upper socket 31 is installed in communication with the fluid storage tank 10, the mesh network filter 32 is installed in close contact with the bottom surface of the upper socket 31, and It comprises a stainless perforated network 33 in close contact with the bottom surface of the mesh network filter 32, and the lower socket 34 is inserted into the lower outer peripheral surface of the upper socket 31.

The upper socket 31 is made of a metal material, and a fluid flow hole 31a in the vertical direction is formed at the center thereof, and a spiral is formed at an upper end of the inner circumferential surface of the fluid flow hole 31a. The spiral of the upper socket 31 formed as described above is coupled to the outer circumferential surface of the outlet pipe 14 of the fluid storage tank 10.

The upper socket 31 is provided with a recess 31b having a predetermined depth along its outer circumferential surface.

On the other hand, the upper socket 31 has an annular fitting groove 31c formed around the fluid flow hole 31a at the bottom thereof. The fitting groove 31c is provided with a first packing P1 made of a silicon material. Thus, the first packing (P1) is made of a silicon material to strongly press the upper edge portion of the mesh network filter 32 so that high viscosity fluid does not leak.

The mesh network filter 32 is installed in close contact with a lower surface of the upper socket 31, in more detail, below the first packing P1 installed in the fitting groove 31c of the upper socket 31.

The stainless perforated network 33 is installed below the mesh network filter 32, and a plurality of through holes 33a are radially formed. As the stainless perforated net 33 is installed, the mesh perforated net 33 provides a strong support force under the mesh net filter 32 even though the mesh net filter 32 is subjected to strong pressure from the upper side to the lower side. Can be torn off.

Meanwhile, a second packing P2 may be further installed between the mesh network filter 32 and the stainless perforated network 33. It is preferable that this second packing P2 is also made of a silicon material. Accordingly, the first packing P1 and the second packing P2 press the edges of the mesh network filter 32 strongly on the upper side and the lower side of the mesh network filter 32 so that high-viscosity fluids do not leak. do.

In addition, a third packing (P3) made of double synthetic rubber (EPDM, Ethylene Propylene Diene M-class) may be further installed on the bottom of the stainless perforated network. The reason for installing a plurality of packings such as the first packing (P1), the second packing (P2) and the third packing (P3) is a mesh having a certain portion of elastic packing when high viscosity fluid is pushed out by air pressure By supporting the edges of the filter 32 and the stainless perforated network 33 to prevent the breakage of each and prevent the breakage of high viscosity fluid.

The lower socket 34 is a portion connected to the fluid discharge pipe 20, and a stepped portion 34a is formed on an inner circumferential surface thereof. Therefore, when the third packing (P3) is not installed, the edge of the stainless perforated network 33 is seated on the stepped portion 34a, and when the third packing (P3) is installed, the edge of the third packing (P3) The part rests on the step part 34a.

The lower socket 34 has through holes 34b formed at both sides thereof, and fixing pieces 34c are provided at both sides of the through hole 34b. The fixed piece 34c is provided with a rotary lever 34d which rotates about the fixed piece 34c.

The rotary lever 34d is rotatably connected to the fixed piece 34c by a pin at its upper end. Thus, when the rotary lever 34d rotates in a specific direction, the upper end is fitted into the recess 31b of the upper socket 31 so that the upper socket 31 and the lower socket 34 are firmly coupled to each other, and rotate in another direction. At the time, the upper end is separated from the recess 31b of the upper socket 31 so that the upper socket 31 and the lower socket 34 can be easily separated.

1 is a perspective view of a high viscosity fluid filtering unit according to the present invention.

Figure 2 is a partial cutaway view of a high viscosity fluid filtering unit according to the present invention.

Figure 3 is an exploded perspective view of a high viscosity fluid filtering unit according to the present invention.

Figure 4 is a cross-sectional view of a high viscosity fluid filtering unit according to the present invention.

Figure 5 is a cross-sectional view showing a combination of the upper and lower sockets of the high viscosity fluid filtering unit according to the present invention.

Figure 6 is a state of use of the high viscosity fluid filtering unit according to the present invention.

<Explanation of symbols on main parts of the drawings>

10: Fluid Storage Tank 11: Cover

12: air injection means 13: air injection pipe

14: outlet pipe 20: fluid discharge pipe

21: valve 30: high viscosity fluid filtering unit

31: upper socket 31a: fluid flow hole

31b: groove 31c: fitting groove

32: mesh network filter 33: stainless perforated network

34: lower socket 34a: stepped portion

34b: through hole 34c: fixing piece

34d: rotating lever P1: first packing

P2: Second Packing P3: Third Packing

Claims (5)

In the high viscosity fluid filtering unit having a fluid storage tank 10 for injecting air to pressurize the high viscosity fluid stored therein, and a fluid discharge pipe 20 for discharging the high viscosity fluid of the fluid storage tank 10 , The fluid storage tank 10 has a cover 11 is installed on the upper surface, the cover 11 is provided with an air injection means 12, the air injection means 12 to the air from the outside the fluid storage tank (10) is connected to the air injection pipe 13 for inflow, The fluid storage tank 10 has an outlet pipe 14 formed at the bottom thereof to discharge the high viscosity fluid stored in the fluid storage tank 10 to the outside, One side of the fluid discharge pipe 20 is provided with a valve 21, Here, an upper socket 31 installed in communication with the fluid storage tank 10, a mesh net filter 32 installed in close contact with the bottom of the upper socket 31, and a bottom of the mesh net filter 32. And a lower socket 34 into which a lower periphery of the outer circumferential surface of the upper socket 31 is inserted. The upper socket 31 is made of a metal material, and the fluid flow hole 31a in the vertical direction is formed at the center thereof, and a spiral is formed at the upper end of the inner circumferential surface of the fluid flow hole 31a, and the spiral of the upper socket 31 is Spirally coupled to the outer circumferential surface of the outlet pipe 14 of the fluid storage tank 10, a groove portion 31b of a predetermined depth is formed along the outer circumferential surface, The upper socket 31 has an annular fitting groove 31c formed at a bottom thereof around the fluid flow hole 31a, and the fitting groove 31c has a first packing P1 made of silicon. Installed, The mesh network filter 32 is installed in close contact with the lower side of the first packing (P1) installed in the fitting groove 31c of the upper socket 31, The stainless perforated network 33 is installed on the lower side of the mesh network filter 32, a plurality of through holes 33a is formed radially, wherein, between the mesh network filter 32 and the stainless perforated network 33 The second packing (P2) made of silicon is installed, A third packing (P3) made of double synthetic rubber (EPDM, Ethylene Propylene Diene M-class) is installed on the bottom of the stainless perforated network 33. The lower socket 34 is connected to the fluid discharge pipe 20, the stepped portion 34a is formed on the inner peripheral surface, Through holes 34b are formed at both sides of the lower socket 34, and fixing pieces 34c are provided at both sides of the through hole 34b, and fixing pieces 34c are provided at the fixing pieces 34c. Rotating lever (34d) is rotated around the installed, The rotary lever 34d is rotatably connected to the fixed piece 34c by a pin at its upper end, and when the rotary lever 34d rotates in a specific direction, the upper end thereof is a recessed portion of the upper socket 31. 31b), the upper socket 31 and the lower socket 34 is firmly coupled, and when rotated in the other direction, the upper end is separated from the recess 31b of the upper socket 31, the upper socket 31 and High viscosity fluid filtering unit, characterized in that configured to include the lower socket 34 can be easily separated. delete delete delete delete

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