KR102639855B1 - Fluid pressure pump capable of pumping fluid by rotation of rollers - Google Patents

Abstract

The present invention relates to a fluid pressure pump capable of pumping fluid by pressurizing the hose through which the fluid is transported. More specifically, rollers provided in three directions at regular intervals pressurize the hose through which the fluid is transported and rotate. The fluid inside the hose can be smoothly pumped, and a guide roller is provided between the rollers transporting the fluid to support the hose, preventing deformation and damage to the hose. The fluid can be pumped by the rotation of the roller. It's about pressure pumps.
For this purpose, a fluid pressure pump capable of pumping fluid by rotating a roller according to an embodiment of the present invention includes a casing that forms a space through which fluid is pumped, a fluid that is installed inside the casing, and a fluid that is filled inside the casing. It includes a fluid transfer hose to be transferred, and a pressure feed wheel rotatably provided inside the casing to the inside of the fluid transfer hose to pressurize the fluid transfer hose by rotation and pressurize the fluid.

Description

A fluid pressure pump capable of pumping fluid by rotation of rollers}

The present invention relates to a fluid pressure pump capable of pumping fluid by pressurizing the hose through which the fluid is transported. More specifically, rollers provided in three directions at regular intervals pressurize the hose through which the fluid is transported and rotate. The fluid inside the hose can be smoothly pumped, and a guide roller is provided between the rollers transporting the fluid to support the hose, preventing deformation and damage to the hose. The fluid can be pumped by the rotation of the roller. It's about pressure pumps.

Generally, pumps are used to transport fluids for construction sites, construction sites, agricultural water, etc.

Pumps can forcibly transport fluids, and various types of pumps are used, such as centrifugal pumps, gear pumps, screw pumps, and hose pumps.

Centrifugal pumps can transport fluids using centrifugal force, and gear pumps can transport fluids by rotating gears. Gear pumps are mainly used for fluids with high viscosity.

The hose pump is installed inside the hose in a circular shape and filled with fluid, and can continuously transfer the fluid inside the hose as it rotates by pressurizing the hose.

As these hose pumps transfer fluid by directly pressurizing the hose, friction may occur with the hose, and the hose may be damaged due to friction.

In addition, when the hose is pressurized, the hose moves due to the flow of fluid, which prevents smooth transfer of the fluid and causes problems in which damage may occur due to the flow of the hose.

In relation to this, prior literature 1 (Patent No. 10-1012550 Hose Pump Equipped with a Hose Guide Bar) discloses a configuration in which a hose compression shoe compresses the hose and rotates to transfer fluid, and a guide bar supports both sides of the hose.

However, in Prior Literature 1, heat is generated due to friction of the hose compression shoe that rotates while pressurizing the hose, and the guide bar also rotates on both sides of the hose to generate friction, causing a problem in which the hose is quickly damaged.

Prior Document 1 (Registered Patent 10-1012550 Hose pump equipped with hose guide bar)

The present invention was devised to solve the above-described problem. In a pump for pumping fluid, the pump wheel presses the hose and rotates to continuously move the fluid inside the hose in the direction of rotation, thereby making it possible to pump fluid. In addition, three pressure rollers are formed on the pressure wheel at regular intervals to minimize friction when pressurizing the hose, and a guide roller is provided in the space between the pressure rollers to prevent the flow of the hose. The purpose is to provide a fluid pressure pump that can pump fluid by rotating a roller that can support a hose while minimizing friction.

A fluid pressure pump capable of pumping fluid by rotating a roller according to an embodiment of the present invention to solve the above problems includes a casing that forms a space through which fluid is pumped, and is installed inside the casing. Characterized by comprising a fluid transfer hose in which fluid is filled and transferred, and a pressure feed wheel rotatably provided inside the casing toward the inside of the fluid transfer hose to pressurize the fluid transfer hose by rotation and pressurize the fluid. do.

Here, the pressure feed wheel extends in three directions at regular intervals, rotates while pressing the fluid transfer hose, and is capable of pumping the fluid inside the fluid transfer hose in the direction of rotation, and the space between the pressure rollers. A guide roller is provided with a smaller diameter than the pressure conveying roller, rotates with the pressure conveying roller without pressurizing the fluid conveying hose, and supports the fluid conveying hose to prevent it from flowing. The pressure conveying roller and the guide roller are installed so as to be rotatable. It is characterized by including a rotation support arm that can simultaneously rotate inside the fluid transfer hose.

At this time, the pressure conveying roller is formed with a pressure surface whose outer diameter is wider than the width of the fluid conveying hose in a pressurized state, and the guide roller is accurately positioned to prevent the fluid conveying hose from flowing without pressurizing the fluid conveying hose. It is characterized by a hose guide groove that can be supported in position.

A fluid pressure pump capable of pumping fluid by rotating a roller according to an embodiment of the present invention can increase fluid pumping efficiency while minimizing friction with the hose by pressurizing a hose with a pressure roller extending in three directions. There is an effect.

Additionally, a guide roller is provided to prevent the flow of the hose, which has the effect of stably supporting the flow of the hose by minimizing friction.

In addition, a groove corresponding to the outer diameter of the hose is formed on the guide roller, which has the effect of allowing the pressure conveying roller to pressurize the fluid transport hose in a fixed position while supporting the outside of the hose without moving through the groove.

1 is an overall perspective view of a fluid pump capable of pumping fluid by rotating a roller according to an embodiment of the present invention.
Figure 2 is an exploded perspective view of a fluid pump that can pump fluid by rotating a roller according to an embodiment of the present invention.
Figure 3 is an operating state diagram showing a state in which a pressure roller pressurizes a hose in a fluid pressure pump capable of pumping fluid by rotation of the roller according to an embodiment of the present invention.
Figure 4 is an operating state diagram showing a state in which a guide roller supports a hose in a fluid pumping pump capable of pumping fluid by rotation of the roller according to an embodiment of the present invention.
Figure 5 is a state diagram showing a state in which a cooling unit is provided in a fluid pump that can pump fluid by rotating a roller according to an embodiment of the present invention.
Figure 6 is an embodiment showing a state in which a hose support ball is provided inside the casing to support the outside of the hose by minimizing friction in a fluid pump that can pump fluid by rotating a roller according to another embodiment of the present invention.

The present invention relates to a pump capable of pumping fluid. In particular, a fluid transfer hose is built into the casing, and a press wheel rotating inside the fluid transfer hose pressurizes the hose and rotates to transfer the fluid. The wheel is equipped with a pressure roller and a guide roller, allowing fluid to be transported uniformly while minimizing friction with the fluid transfer hose during pressure transport.

Hereinafter, a fluid pump that can pump fluid by rotating a roller according to an embodiment of the present invention will be described in detail with reference to the attached drawings.

Figure 1 is an overall perspective view of a fluid pump capable of pumping fluid by rotation of a roller according to an embodiment of the present invention, and Figure 2 is a schematic diagram of a fluid pump capable of pumping fluid by rotation of a roller according to an embodiment of the present invention. This is an exploded perspective view of a fluid pressure pump.

Referring to Figures 1 and 2, the present invention includes a casing 100 that forms a space through which fluid is pumped, a fluid transfer hose 200 installed inside the casing 100 and filled with fluid for transport, and It is configured to include a pressure feed wheel 300 that is rotatably provided inside the casing 100 to the inside of the fluid transfer hose 200 and can pressurize the fluid transfer hose 200 by rotation and pump fluid. do.

Here, the casing 100 has a hose insertion hole 110 into which the fluid transfer hose 200 is inserted, and the fluid transfer hose 200 inserted into the hose insertion hole 110 is located along the inner circumference of the casing 100. It is configured to include a hose outlet 120 that is closely attached and then discharged in the transport direction.

At this time, the fluid transfer hose 200 has its own elasticity, so it is not folded inside the casing 100, but is installed in close contact with the inner circumference of the casing 100 due to its own elasticity.

And on the outside of the casing 100, an internal confirmation window 130 is provided made of a transparent material through which the inside of the casing 100 can be visually checked.

The fluid transfer hose 200 includes an inlet 210 through which fluid flows in, and an outlet 220 through which the inflow fluid is pumped and discharged by the pressure feed wheel 300.

The pressure feed wheel 300 rotates inside the casing 100 and pressurizes the fluid transfer hose 200, thereby forming a pressure feed roller 310 that can pressurize the fluid inside the fluid transfer hose 200 toward the outlet 220. is provided.

The pressure feeding roller 310 is formed with a pressure feeding surface 311 made of a flat surface along the outer circumference.

This pressure conveying roller 310 extends in three directions from the center of the pressure conveying wheel 300 and is installed to pressurize the fluid conveying hose 200.

And, in the space between the pressure feeding rollers 310 where the pressure feeding rollers 310 are installed, there is a space that can prevent the fluid conveying hose 200 from flowing due to the pressure feeding of the fluid when the pressure conveying roller 310 rotates while pressing the fluid conveying hose 200. Guide rollers 320 are provided in three directions.

Here, the guide roller 320 has a hose guide groove 321 formed on the outer periphery of a shape corresponding to the outer diameter of the fluid transfer hose 200.

The hose guide groove 321 is provided to surround the outer side of the fluid transfer hose 200 when the pressure transfer wheel 300 is rotated, thereby preventing the fluid transfer hose 200 from flowing.

The pressure feeding roller 310 and the guide roller 320 are each installed on a rotating support arm 330 extending from the center of the casing 100, and the pressure feeding roller 310 transfers fluid by rotation of the rotating support arm 330. The hose 200 is continuously pressurized to transport the fluid, and the guide roller 320 rotates together with the pressure transport roller 310 to prevent the fluid transfer hose 200 from flowing in the space between the pressure transport rollers 310. You can do it.

The rotation support arm 330 is rotated at a constant speed by a pressure feed wheel drive motor 340 installed and connected to the outside of the casing 100.

For this reason, as the fluid is filled with the fluid transfer hose 200 installed inside the casing 100 and the pressure feed wheel 300 is rotated, the pressure feed roller 310 pressurizes the fluid transfer hose 200 with minimal friction. As the fluid transfer hose 200 is pressurized by the press roller 310, the fluid contained therein can be transferred and transferred in the rotational direction of the transfer wheel 300.

In addition, as the guide roller 320 supports and rotates the fluid transfer hose 200, it prevents the fluid transfer hose 200 from being damaged by friction generated as the fluid transfer hose 200 flows, thereby improving durability. It becomes possible.

Figure 3 is an operating state diagram showing a state in which a pressure feeding roller pressurizes a hose in a fluid pumping pump capable of pumping fluid by rotation of the roller according to an embodiment of the present invention.

Referring to FIG. 3, the fluid transfer hose 200 containing the fluid is deformed as it is pressed by the pressure feeding roller 310, and the fluid contained therein is separated at the position of the pressure feeding roller 310.

When the pressure conveying roller 310 is rotated in this state, the fluid separated by the pressure conveying roller 310 is conveyed along the rotation direction of the pressure conveying roller 310.

As the pressure conveying roller 310 rotates while pressurizing the fluid conveying hose 200 as described above, the fluid contained in the fluid conveying hose 200 is conveyed in the direction of rotation of the conveying roller 310 and toward the discharge port 220. As a result, fluid can be continuously pumped in the rotation direction of the pressure feed roller 310 by the continuous rotation of the pressure feed roller 310.

Figure 4 is an operating state diagram showing a state in which a guide roller supports a hose in a fluid pump that can pump fluid by rotating the roller according to an embodiment of the present invention.

Referring to FIG. 4, when fluid is pumped through the fluid transfer hose 200, the guide roller 320 supports the inside of the fluid transfer hose 200 installed in the casing 100 between the pressure transfer rollers 310. .

This guide roller 320 has a hose guide groove 321 formed along its outer circumference in a curved shape corresponding to the fluid transfer hose.

The hose guide groove 321 rotates while surrounding the outside of the fluid transfer hose 200 to minimize friction while the pressure feed wheel 300 rotates and to support the fluid transfer hose 200 so that it does not flow.

Figure 5 is a state diagram showing a state in which a cooling unit is provided in a fluid pump that can pump fluid by rotating a roller according to an embodiment of the present invention.

Referring to FIG. 5, the casing 100 may be provided with a cooling unit 140.

The cooling unit 140 is capable of preventing excessive heat from being generated during long-term operation due to friction or external temperature between the pressure feed wheel 300 and the fluid transfer hose 200 inside the casing 100. First, the casing 100 ) It can be operated with refrigerant filled inside.

Refrigerant oil may be used as the refrigerant, and it is filled into the entire space where the fluid transfer hose 200 and the pressure transfer wheel 300 operate within the casing 100 to ensure the overall operation of the pressure transfer wheel 300 and the fluid transfer hose 200. The range can be cooled.

It is preferable that the refrigerant oil is continuously cooled and circulated by the cooling unit 140 to maintain long-term performance.

The cooling unit 140 includes a refrigerant inlet 141 that introduces refrigerant into the casing 100, a refrigerant recovery port 142 that is filled in the casing 100 and can recover the refrigerant used for cooling, and a refrigerant It is configured to include a refrigerant circulation pipe 143 that circulates continuously.

The refrigerant circulation pipe 143 is provided with several overlapping thin plate-shaped cooling fins.

Additionally, a refrigerant circulation pump 145 is provided to recover the refrigerant inside the casing 100 and circulate it so that it can be re-introduced.

The cooling fins 144 enable heat exchange in the refrigerant circulation pipe 143 by air, thereby lowering the temperature of the refrigerant and allowing it to circulate.

At this time, a cooling fan 146 capable of blowing air toward the cooling fin 144 is further provided on one side of the cooling fin 144.

The cooling fan 146 blows air toward the refrigerant circulation pipe 143 and the cooling fins 144, thereby increasing cooling efficiency.

Figure 6 is an embodiment showing a state in which a hose support ball is provided inside the casing to support the outside of the hose by minimizing friction in a fluid pump that can pump fluid by rotating a roller according to another embodiment of the present invention. am.

Referring to FIG. 6, a plurality of hose support balls 150 may be provided inside the casing 100 along a surface on which the fluid transfer hose 200 is installed.

The hose support ball 150 is rotatably provided in the casing 100, and rotates when the fluid transfer hose 200 flows on the surface where the fluid transfer hose 200 and the casing 100 are in contact. By reducing friction, damage to the fluid transfer hose 200 can be minimized.

In addition, the hose support ball 150 is supported by a plate-shaped rotating support plate 151 installed spaced apart from the inside of the casing 100 to prevent the refrigerant from leaking out, and the hose support ball 150 is attached to the rotating support plate 151. ) are formed with a plurality of rotation support holes 152 that rotatably support the hose support ball and are supported and rotated by the rotation support holes.

At this time, a support spring 153 is installed for each hose support ball 150 on the outside of the rotating support plate 151 on which the hose support ball 150 is supported, so that the hose support ball 150 is elastically applied by the support spring 153. I support it.

As a result, when the pressure feeding roller 310 rotates and pressurizes the fluid transfer hose 200, the hose support ball 150 is retracted, and the pressurization and pressure delivery efficiency is increased by the outer surface of the rotation support plate 151, and the fluid transfer hose 200 is pressed. When 200 flows, friction is reduced by the rotation of the hose support ball 150, thereby preventing overheating during operation and minimizing damage to the fluid transfer hose 200.

In the present invention made as described above, when pumping a fluid, the fluid transfer hose is pressed and rotated so that the fluid inside the fluid transfer hose is transferred in the direction of rotation, so that the fluid can be continuously pumped.

In addition, three pressure conveying rollers and three guide rollers are alternately arranged to prevent the fluid conveying hose from flowing in the space between the pressure conveying rollers and pressurizing the fluid conveying hose, thereby enabling continuous and stable conveying.

In addition, by filling the inside of the casing with refrigerant, overheating due to the refrigerant is prevented, and friction can be minimized by transporting and supporting with a roller structure, thereby increasing durability.

100: Casing 110: Hose insertion hole
120: Hose outlet 130: Internal confirmation window
140: cooling unit 141: refrigerant inlet
142: Refrigerant recovery port 143: Refrigerant circulation pipe
144: cooling fin 145: refrigerant circulation pump
146: cooling fan 150: hose support ball
151: Rotation support plate 152: Rotation support hole
153: support spring 200: fluid transfer hose
210: inlet 220: outlet
300: Pressure wheel 310: Pressure roller
311: Pressure surface 320: Guide roller
321: Hose guide groove 330: Rotating support arm
340: Pressure wheel drive motor

Claims (3)

A casing (100) forming a space through which fluid is pumped;
A fluid transfer hose 200 installed inside the casing 100 and filled with fluid therein and transferred thereto; and
A pressure feed wheel 300 is rotatably provided inside the casing 100 to the inside of the fluid transfer hose 200 and pressurizes the fluid transfer hose 200 by rotation and can pump fluid. Because,
The pressure feed wheel 300 is a pressure feed roller ( 310) and the pressure conveying roller 310, it is provided in the space between the pressure conveying roller 310 and has a smaller diameter than the pressure conveying roller 310, so that the fluid conveying hose 200 is rotated together with the conveying roller 310 without pressurizing the fluid. The guide roller 320, which supports the transfer hose 200 so that it does not flow, and the pressure transfer roller 310 and guide roller 320 are rotatably installed and can rotate simultaneously to the inside of the fluid transfer hose 200. Includes a support arm 330,
The pressure feeding roller 310 is formed with a pressure feeding surface 311 whose outer diameter is wider than the width of the fluid transport hose 200 in a pressurized state, and the guide roller 320 is formed with the fluid transport hose 200. A hose guide groove 321 is formed that can support the fluid transfer hose 200 in an accurate position so that it does not flow without pressurizing,
A plurality of hose support balls 150 are provided along the surface on which the fluid transfer hose 200 is installed inside the casing 100, and the hose support balls 150 are used to prevent refrigerant from leaking out from the inside of the casing 100. It is supported by a spaced apart plate-shaped rotation support plate 151, and a plurality of rotation support holes 152 are formed in the rotation support plate 151 to rotatably support the hose support ball 150, thereby forming a hose support ball. is supported and rotated by a rotation support hole, and a support spring 153 is installed for each hose support ball 150 on the outside of the rotation support plate 151 on which the hose support ball 150 is supported. A fluid pump that can pump fluid by rotating a roller, wherein the hose support ball (150) is elastically supported.
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