KR102103446B1 - Fluid transferring device using magnetic levitation rotary fan - Google Patents

Abstract

The present invention relates to a fluid transfer apparatus using a magnetic levitation rotation fan, capable of preventing reduction of conveying force by reducing friction resistance. According to the present invention, the fluid transfer apparatus using a magnetic levitation rotation fan comprises: a housing (2); a rotation fan (3) mounted on a receiving unit (22) provided on a flow path (21) of the housing (2) to be rotated in a non-contact state; a first permanent magnet (4); a second permanent magnet (5); a third permanent magnet (6); and a motor (7) configured to provide wind power to a partition wall (33) and a receiving groove (34) of the rotation fan (3).

Description

Fluid transfer device using magnetic levitation rotary fan}

The present invention relates to a fluid transfer device that pressurizes a fluid flowing inside a pipe, and in particular, a rotating fan that provides a driving force to rotate and pressurize a fluid by being supplied in a state accommodated in the housing by the repulsive force of the permanent magnet. When it is injured and rotates, it does not come into contact with any other, thereby reducing frictional resistance to prevent deterioration of the pressure-transmitting force. Also, the body of the rotating fan is inserted into the receiving portion of the housing to block the flow of space in the flow path, thereby allowing fluid flow. It is possible to smoothly press the fluid without installing a motor inside the flow path, and furthermore, when the pressure is reduced due to the increase in the length of the pipe that discharges the fluid, the motor is installed inside the pipe where the differential pressure is generated. Fluid transfer device using magnetic levitation rotating fan that can compensate differential pressure simply by installing rotating fan without installation It relates.

In general, in the case of transferring fluid using a pipe, a rotating fan is installed at the inlet or outlet of the pipe. The reason is that it is very difficult to install a motor that drives a rotating fan inside the pipe, and even if it is installed, the motor flows most of the space inside the pipe, so fluid flow is not smooth inside the pipe.

For example, FIG. 1 is a conceptual diagram illustrating that waste gas used in a semiconductor manufacturing process is purified by using a scrubber (S) and then discharged into the atmosphere. The exhaust gas purified in each scrubber S is transferred to the main pipe M through a pipe P connected to the scrubber S, and then discharged into the atmosphere. To this end, an exhaust fan (F) is installed at the end of the main pipe (M) so as to pressurize the exhaust gas supplied from the pipe (P) to the atmosphere. Since this exhaust fan (F) is driven by a motor, the motor is not installed inside the main pipe (M) so as not to erode the main pipe (M), and is installed at an end that is easy to install as shown in the figure.

However, if the scrubber (S) is additionally installed during use, the pipe (P) of the added scrubber (S) must be connected to the main pipe (M), so the length of the main pipe (M) must be increased. When the main pipe (M) is extended for a long time, the exhaust fan (F) installed in the main pipe (M) is unable to discharge the exhaust gas at the initially designed exhaust pressure, resulting in a lower pressure, resulting in a differential pressure. To solve this problem, an exhaust fan having a large capacity must be installed in the main pipe (M), or an additional exhaust fan must be additionally installed in the pipe (P) connected to the scrubber (S).

In this case, since the main pipe M is already in use, the inner diameter cannot be greatly enlarged, so that even if an exhaust fan having a large capacity is installed, there is a problem that the exhaust pressure cannot be increased. In addition, when an additional exhaust fan is installed in the pipe (P), the motor driving the additional exhaust fan cannot be installed inside the pipe (P), so it must be installed at the outlet or inlet of the pipe (P). There is a problem that it is virtually impossible to add an exhaust fan.

This problem is caused by the inability to mount the motor driving the exhaust fan F inside the main pipe M or the pipe while being accommodated.

As described above, the conventional fan technology installed on the main pipe (M) or the pipe has been disclosed in the refrigerator of the refrigerator of the Utility Model No. 20-1999-0021526 (released on June 25, 1999). This technology is a fan in which a rotating shaft provided with a blower fan 220 on the other side is axially coupled with an inner box in which a coupling groove of a predetermined depth is formed inside, and a part of one side is coupled to a predetermined dustproof opening and accommodated inside the coupling groove. The motor 200, a cover having a center penetratingly coupled to the outer circumferential surface of the rotating shaft and having both ends fixedly coupled to the edge of the coupling groove, and a predetermined insulating material having a through hole that is accommodated so that the blowing fan 220 is rotatable It is provided with a louver coupled by a predetermined coupling means.

Another conventional fan technology has been disclosed in the motor of Patent Publication No. 10-2018-0121179 (published Nov. 7, 2018). This technology comprises a motor housing made to open both ends in a cylindrical shape; A fan blade 120 radially installed in a fan hub formed along an extending direction of the motor housing, rotated inside the motor housing, and installed with a permanent magnet at an end; And a coil that is wound in a predetermined pattern with a flexible thin plate is disposed at a set interval, and is installed along the inner circumferential surface of the motor housing to be positioned to face the permanent magnet, and includes a printed circuit board (PCB).

It is characterized in that the rotation of the fan blade 120 is made by the rotational force formed by the interaction between the PCB and the permanent magnet. One

However, in the prior art, since the fans are driven by the motor, since the blowing fan 220 or the fan blade 120 is fixed to the shaft of the motor, the blowing fan 220 or the fan blade 120 is installed inside the pipe. In this case, since the motors that drive them must be mounted inside the pipe, the flow path inside the pipe has the conventional problem of being eroded by the motor.

Republic of Korea Utility Model No. 20-1999-0021526 Patent Publication No. 10-2018-0121179

Accordingly, the present invention is to solve all the problems of the conventional rotating fan device as described above, the purpose of which is a rotating fan that provides a driving force for rotating the fluid to be pushed by the wind supplied from the housing accommodated inside the housing An object of the present invention is to provide a fluid transfer device using a magnetic levitation rotating fan that prevents a drop in pressure due to frictional resistance by not contacting any of them when it is injured and rotated by the repulsive force of a permanent magnet.

Another object of the present invention is to insert the body of the rotating fan is inserted into the receiving portion of the housing to block the flow of the space of the flow path to facilitate the flow of the fluid, the magnetic force capable of feeding fluid without installing a motor inside the flow path It is to provide a fluid transfer device using a floating rotating fan.

In addition, another object of the present invention is to compensate the differential pressure simply by installing a rotating fan without installing a motor inside the pipe where the differential pressure is generated when the differential pressure is generated due to an increase in the length of the pipe for discharging the fluid. It is to provide a fluid transfer device using a magnetic levitation rotating fan.

A fluid transfer device using a magnetic levitation rotating fan according to the present invention for achieving the above object includes a housing through which a flow path passes through to allow fluid to pass therethrough;

It is rotatably mounted in a non-contact state in the receiving portion provided on the flow path of the housing, and when it rotates, the blade protrudes radially on the inner periphery of the body so as to pressurize the fluid inside the flow path, and is supplied from outside the housing A rotating fan in which partition walls and receiving grooves are alternately continuously arranged on the outer periphery of the body so that rotational force can be generated by the generated wind;

The vertical wall forming the receiving portion of the housing and the rotational fan accommodated in the receiving portion by the repulsive force acting therebetween fixed to each of the outer peripheral body of the rotating fan so as not to contact the vertical wall of the receiving portion Permanent magnets;

The upper horizontal wall forming the receiving portion of the housing and the upper end of the body of the rotating fan are fixed in correspondence with each other so that the rotating fan accommodated in the receiving portion is not in contact with the upper horizontal wall of the receiving portion by the repulsive force acting therebetween. 2 permanent magnets;

The lower horizontal wall forming the accommodating part of the housing and the lower part of the body of the rotating fan are fixed in correspondence with each other so that the rotating fan accommodated in the accommodating part does not contact the lower horizontal wall of the accommodating part by the repulsive force acting therebetween. 3 permanent magnets; And

It includes; a motor that passes through the vertical wall forming the receiving portion of the housing to provide wind power to the partition wall of the rotating fan and the receiving groove.

The housing of the present invention is composed of two sets of assemblies in which the receiving portions having larger inner diameters than the inner flow passages are accommodated with each other so as to accommodate the rotating fan, and an inlet for supplying wind power to a vertical wall forming the receiving portion Is penetrated.

The wing protruding on the inner periphery of the body of the rotating fan according to the present invention is formed with a bent portion in a curved shape at the bottom so that a propulsive force for feeding the fluid can be generated, and a straight portion is formed on the bent portion in parallel with the fluid flow.

In addition, the first, second, and third permanent magnets of the present invention may be composed of a plurality of block shapes and disposed radially, or may have a ring shape having a single shape.

The present invention configured as described above has an advantage of increasing frictional force by reducing frictional resistance by not contacting any of them when rotating because the rotating fan providing the propulsive force for feeding the fluid is floated by the repulsive force of the permanent magnet. .

In addition, the present invention has the advantage that the body of the rotating fan is inserted into the receiving portion of the housing to block the flow of the space of the flow path to facilitate fluid flow.

In addition, the present invention has the advantage of being able to compensate for the differential pressure simply by installing a rotating fan without installing a motor inside the pipe where the differential pressure is generated when the differential pressure is generated due to an increase in the length of the pipe discharging the fluid. have.

1 is a conceptual diagram showing that the waste gas used in the semiconductor manufacturing process is purified by using a scrubber and then discharged into the atmosphere.
2 is a conceptual diagram showing that the waste gas used in the semiconductor manufacturing process according to the present invention is purified by using a scrubber and then discharged into the atmosphere.
Figure 3 is a front sectional view showing the interior of the fluid transfer device using a magnetic levitation rotating fan according to the present invention
4 is a perspective view of a rotating fan according to the present invention
5 is an enlarged detail view of a blade of a rotating fan according to the present invention
Figure 6 is an enlarged detail view of a state in which a rotating fan is mounted on an accommodating portion of a housing according to the present invention.
7 is a plan view showing a state in which the rotating fan according to the present invention is separated from the housing by the repulsive force of the permanent magnet.
8 is a plan view showing a state in which the rotating fan of FIG. 7 rotates;

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration of the fluid transfer device using a magnetic levitation rotating fan according to the present invention.

As shown in the figure, the fluid conveying device 1 using the magnetic levitation rotating fan of the present invention can be widely used in the industrial field for conveying fluid, for example, as shown in FIG. 2, the main pipe (M) and the scrubber (S) The exhaust pressure discharged from the scrubber (S) to the main pipe (M) installed on the path connecting the pipes (P) is lower than the original exhaust pressure designed to compensate for this differential pressure when the differential pressure occurs to compensate for the normal exhaust pressure. Can be used to maintain.

As shown in the figure, the fluid transfer device 1 using the magnetic levitation rotating fan of the present invention is a rotating fan mounted in a magnetically injured state while being rotatably mounted in the housing 2 and the housing 2 in a non-contact state (3), a first permanent magnet (4) that prevents the rotating fan (3) housed in the housing (2) from contact with the side wall of the housing (2) by repulsive force, and a rotating fan stored in the housing (2) by repulsive force ( 3) The second permanent magnet (5) to prevent the upper horizontal wall (231) from contacting the housing (2), and the rotating fan (3) accommodated in the housing (2) with repulsive force, the lower horizontal wall of the housing (2) It includes a third permanent magnet (6) to prevent contact with the motor 7 to provide a wind to the rotating fan (3) through the housing (2) to rotate the rotating fan (3).

The flow path 21 is penetrated inside the housing 2 so that the fluid can pass therethrough. In addition, the housing 2 is composed of two sets of assemblies in which the receiving portions 22 having a larger inner diameter than the inner flow path 21 are fitted to each other to accommodate the rotating fan 3 as shown in FIG. 6. , The inlet 24 is penetrated to supply wind power to the vertical wall 23 forming the receiving portion 22. The housing 2 composed of two sets is assembled integrally with fixing means such as bolts and nuts of FIG. 3. And the upper and lower ends of the housing 2 are formed with a flange 25 through which a fastening hole is penetrated so as to be connected to the pipe.

The inlet 24 is a supply passage for supplying a fluid such as air, nitrogen gas, or argon gas supplied from the motor 7 at high speed. The blowing force of the fluid supplied from the inlet 24 impulses with the rotating fan 3 to rotate the rotating fan 3 at high speed. The injection hole 24 is disposed in a direction that is severely eccentric in the lateral direction without facing the center of the housing 2 as shown in FIGS. 7 to 8. Therefore, air, nitrogen gas, or argon gas discharged from the inlet 24 is supplied to the partition wall 33 and the receiving groove 34 formed on the outer periphery of the rotating fan 3, the supply direction of which is lateral. In the direction A of FIG. 4, the rotational force of the rotating fan 3 is proportional to the pressure and speed of the supplied air, nitrogen gas, or argon gas.

Considering that the first, second, and third permanent magnets 4, 5, and 6 are used as the material of the housing 2, a non-ferrous metal or synthetic resin material having no magnetism may be used.

The rotating fan 3 rotates by the wind power supplied from the motor 7 to transfer the fluid inside the housing 2. The rotating fan 3 is rotatably mounted in a non-contact state to the receiving portion 22 provided on the flow path 21 of the housing 2, and when rotating, the fluid inside the flow path 21 is pushed in the discharge direction. In order to make the body 31 radially protrude on the inner periphery of the body 31, the outer periphery of the body 31 so that rotational force can be generated by wind supplied from the outside through the inlet 24 of the housing 2 In the partition wall 33 and the receiving groove 34 are alternately arranged.

Here, the shape of the blade 32 should be configured in a shape that can press the stopped fluid when the rotating fan 3 rotates. More specifically, the wing 32 protruding from the inner periphery of the body 31 of the rotating fan 3 is formed with a bent portion 321 formed in a curved shape at the bottom so that a driving force for feeding the fluid can be generated, and this bending is performed. A straight portion 322 is formed above the portion 321 in parallel with the fluid flow.

Since the lower portion of the blade 32 is formed in a curved shape as shown in FIGS. 3 to 5, when the rotating fan 3 rotates, the bent portion 321 located at the lower portion collides with the stopped fluid, and the fluid is a straight portion. It is pushed in the direction of (322). Therefore, when the rotating fan 3 rotates at a high speed, the stationary fluid generates a strong upward air flow according to the induction of the bent portion 321, moves to the straight portion 322, and then leaves the housing 2 and is discharged to the outside. . 4 shows that one wing 32 is formed on both sides of the inner periphery of the body 31, but this indicates that the remaining wing 32 is omitted. In practice, as shown in FIG. 5, a plurality of bodies 31 are arranged at regular intervals around the inner periphery.

The partition wall 33 and the receiving groove 34 formed in the wing 32 are very important elements in the present invention. Air, nitrogen gas, or argon gas, etc. supplied through the inlet 24 of the housing 2 collide with the partition wall 33 and move to the receiving groove 34 at the same time as the partition wall 33. This is because the rotating fan 3 rotates by the force generated when it collides with the groove 34.

On the other hand, according to the present invention, since the body 31 of the rotating fan 3 is completely accommodated in the receiving groove 34 of the housing 2 as shown in FIG. 6, it does not erode the space area of the flow path 21, thereby preventing fluid flow. It does not disturb, and the inner diameter of the rotating fan 3 is also completely penetrated, so that the flow of the fluid is not disturbed.

The first permanent magnet (4), as shown in Figure 6, the vertical wall 23 forming the receiving portion (22) of the housing (2) and the rotating fan (3) of the body (31) outer periphery corresponding to each It is fixed so that the rotating fan 3 accommodated in the receiving portion 22 is not in contact with the vertical wall 23 of the receiving portion 22 by the repulsive force acting between them. The first permanent magnet 4 may be configured in a plurality of block shapes as shown in FIGS. 7 to 8 and disposed radially. Also, the first permanent magnet 4 may be configured in a ring shape having a single shape.

The vertical wall 23 forming the accommodating portion 22 of the housing 2 and the first permanent magnet 4 fixed to the outer periphery of the body 31 of the rotating fan 3 are arranged so that the same polarities face each other. This prevents the rotating fan 3 from coming into contact with the housing 2 by causing repulsion between them. Here, the repulsive force generated between the first permanent magnets 4 is satisfied as long as the rotating fan 3 does not contact the housing 2 when it is stopped or rotated. Therefore, the repulsive force is so strong that the rotational fan 3 is not disturbed when the rotating fan 3 is rotated by the blowing force of the fluid supplied from the inlet 24.

The spacing between the first permanent magnets 4 is repulsive between them even when the rotating fan 3 is rotated as shown in FIG. 8 to be mounted on the housing 2 and the rotating permanent fan 3 is located. Due to this action, the rotation fan 3 must maintain a gap such that it does not come into contact with the housing 2.

The second permanent magnet 5 is fixed to correspond to each of the upper horizontal wall 231 forming the receiving portion 22 of the housing 2 and the upper end of the body 31 of the rotating fan 3 between them. The rotating fan 3 accommodated in the receiving portion 22 by the repulsive force acting on it is to prevent contact with the upper horizontal wall 231 of the receiving portion 22. The second permanent magnet 5 may consist of a plurality of block shapes and be disposed radially. Also, the first permanent magnet 4 may be configured in a ring shape having a single shape.

The upper horizontal wall 231 forming the accommodating portion 22 of the housing 2 and the second permanent magnet 5 fixed to the upper end of the body 31 of the rotating fan 3 so that the same polarities face each other It is arranged so that a repulsive force is generated between them so that the rotating fan 3 does not contact the housing 2. Here, the repulsive force generated between the second permanent magnets 5 is satisfied as long as the rotating fan 3 does not contact the housing 2 when it is stopped or rotated. Therefore, the repulsive force is so strong that the rotational fan 3 is not disturbed when the rotating fan 3 is rotated by the blowing force of the fluid supplied from the inlet 24.

The spacing between the second permanent magnets 5 is rotated by the repulsive force acting between them even when the rotating fan 3 rotates and is mounted on the rotating fan 3 between the two mounted on the housing 2. The fan 3 should be kept at a distance so as not to contact the housing 2.

The third permanent magnet 6 is fixed to correspond to each of the lower horizontal wall 232 forming the receiving portion 22 of the housing 2 and the lower end of the body 31 of the rotating fan 3 between them. The rotating fan 3 accommodated in the receiving portion 22 by the repulsive force acting on is to prevent contact with the lower horizontal wall 232 of the receiving portion 22. The third permanent magnet 6 may consist of a plurality of block shapes and be disposed radially. Also, the first permanent magnet 4 may be configured in a ring shape having a single shape.

The lower horizontal wall 232 forming the receiving portion 22 of the housing 2 and the third permanent magnet 6 fixed to correspond to the lower end of the body 31 of the rotating fan 3 have the same polarity to face each other. It is arranged so that a repulsive force is generated between them so that the rotating fan 3 does not contact the housing 2. Here, the repulsive force generated between the third permanent magnets 6 is satisfied as long as the rotating fan 3 does not contact the housing 2 when it is stopped or rotated. Therefore, the repulsive force is so strong that the rotational fan 3 is not disturbed when the rotating fan 3 is rotated by the blowing force of the fluid supplied from the inlet 24.

The spacing between the third permanent magnets 6 is rotated by the repulsive force acting between them even when the rotating fan 3 rotates and is mounted on the rotating fan 3 between the two mounted on the housing 2. The fan 3 should be kept at a distance so as not to contact the housing 2.

The motor 7 penetrates the vertical wall 23 forming the receiving portion 22 of the housing 2, that is, the inlet 24 of the housing 2, and the partition wall 33 of the rotating fan 3 And to provide wind power to the receiving groove (34). Since the motor 7 is connected to a hose H connected to the inlet 24 of the housing 2, it is installed at an arbitrary place outside the housing 2. Since the motor 7 is installed outside the housing 2 as described above, the object of the present invention can be achieved without interfering with the flow of fluid flowing through the housing 2.

The shaft of the motor 7 is equipped with a blower fan (not shown) to supply strong wind power to the inlet 24, which is the first, second, and third permanent magnets 4, 5, 6 The rotating fan 3 is rotated while winning the repulsive force.

On the other hand, the present invention, the inner passage 21 of the housing 2, the rotating fan 3, and the first, second and third permanent magnets 4, 5 and 6 are coated with a corrosion inhibitor to transport waste gas It is good to extend the life when the pipe is installed inside the pipe. Corrosion inhibitors and methods for coating them are well-known techniques, and therefore detailed descriptions thereof will be omitted.

The present invention configured as described above prevents the pressure from being reduced by reducing the frictional resistance because the rotating fan 3, which provides the propulsive force for feeding fluid, is injured by the repulsive force of the permanent magnet and does not contact any of them when rotating. A point that can be made, the body 31 of the rotating fan 3 is inserted into the receiving portion 22 of the housing 2 to block the passage of the space of the flow path 21 to smooth the flow of fluid, When the pressure is reduced due to the fact that the fluid 7 can be compressed without installing the motor 7 inside the flow path 21 and the length of the pipe for discharging the fluid is reduced, the motor inside the pipe where the differential pressure is generated when the differential pressure is generated ( 7) It is an advantageous invention that can improve the use in the device for transferring fluid because it has the point of simply compensating for the differential pressure by installing only the rotating fan (3) without installation.

Claims (4)

A housing 2 through which a flow path 21 is penetrated to allow fluid to pass;
The housing (22) rotatably mounted in a non-contact state on the receiving portion (22) provided on the flow path (21) of the housing (2) when rotated, the body (31) is capable of feeding fluid inside the flow path (21) in the discharge direction. ) The wing 32 is projected radially on the inner periphery, and the partition wall 33 and the receiving groove 34 are crossed on the outer periphery of the body 31 so that rotational force can be generated by wind supplied from the outside of the housing 2. Rotating fan (3) are arranged successively;
The vertical wall 23 forming the accommodating portion 22 of the housing 2 and the body 31 of the rotating fan 3 are fixed in correspondence with each of the outer peripheries, and the accommodating portion by the repulsive force acting therebetween ( A first permanent magnet 4 that prevents the rotating fan 3 accommodated in the 22 from contacting the vertical wall 23 of the receiving portion 22;
The upper horizontal wall 231 forming the receiving portion 22 of the housing 2 and the upper end of the body 31 of the rotating fan 3 are fixed to correspond to each of the receiving portions by repulsive forces acting between them ( A second permanent magnet 5 that prevents the rotating fan 3 accommodated in the 22 from contacting the upper horizontal wall 231 of the receiving portion 22;
The lower horizontal wall 232 forming the receiving portion 22 of the housing 2 and the lower portion of the body 31 of the rotating fan 3 are fixed to correspond to each of the lower portions of the receiving portion 22 by a repulsive force acting therebetween. A third permanent magnet 6 that prevents the rotating fan 3 accommodated in the 22 from contacting the lower horizontal wall 232 of the receiving portion 22; And
A motor 7 that penetrates the vertical wall 23 forming the receiving portion 22 of the housing 2 and provides wind power to the partition wall 33 and the receiving groove 34 of the rotating fan 3; Fluid transfer device using a magnetic levitation rotating fan, characterized in that it comprises.
The method according to claim 1, wherein the housing (2) is composed of two sets of assembly in which the receiving portion (22) having a larger inner diameter than the inner flow passage (21) is fitted to each other to accommodate the rotating fan (3). And, the fluid transfer device using a magnetic levitation rotating fan, characterized in that the inlet 24 is passed through to supply the wind to the vertical wall 23 forming the receiving portion (22).
The method according to claim 1, Wings (32) protruding from the inner periphery of the body (31) of the rotating fan (3) is formed with a bent portion (321) in the form of a curved surface at the bottom so that a propulsive force for generating fluid can be generated. A fluid transfer device using a magnetic levitation rotating fan, characterized in that a straight portion 322 is formed in parallel to the fluid flow on the bent portion 321.
The method according to claim 1, The first, second, and third permanent magnets (4) (5) (6) are fixed to correspond to each other is composed of a plurality of block shapes are arranged radially, or composed of a ring shape having a single shape Fluid transfer device using a magnetic levitation rotating fan, characterized in that.

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