KR101445163B1 - Magnetic pump using bonded magnetic - Google Patents

Abstract

[0001] The present invention relates to a magnetic pump using an injection magnet, and more particularly to a magnetic pump using an injection magnet. A pump bracket that is opposed to the motor bracket and has a suction port for receiving fluid from the outside and a discharge port for discharging the sucked fluid; A blocking housing disposed between the motor bracket and the pump bracket and blocking a flow of fluid introduced into the pump bracket into the motor bracket and having a cylindrical receiving portion at the center; And an inner circumferential surface of the motor bracket rotatably connected to the inner circumferential surface of the motor bracket. The inner circumferential surface of the outer circumferential surface of the motor bracket is rotatably connected to the inner circumferential surface of the motor, A driven side rotator formed; A driven side rotator housed in the receiving portion of the blocking housing and formed in a hollow cylindrical shape and having N poles and S poles alternately repeated on the outer peripheral surface along the circumferential direction; And an impeller rotatably coupled to the driven side rotator and having a plurality of blades, wherein at least one of the drive side rotator and the driven side rotator is formed of an ejection magnet using a magnetic powder and a binder . According to the present invention, since at least one of the driving-side rotor and the driven-side rotor is provided with an ejecting magnet using a magnetic powder and a binder, manufacturing of the driving-side rotor and the driven-side rotor is facilitated, .

Description

MAGNETIC PUMP USING BONDED MAGNETIC USING INJECTION MAGNET

Disclosure of the Invention The present invention relates generally to a magnetic pump, and more particularly, to a magnetic pump using an injection magnet having a drive assembly formed of an injection magnet formed by using a magnetic body powder and a binder.

Herein, the background art relating to the present invention is provided, and they are not necessarily referred to as known arts.

1 is a view showing a structure of a conventional magnetic motor disclosed in Korean Patent Application Publication No. 2007-0053183.

1, Korean Unexamined Patent Application Publication No. 2007-0053183 discloses a structure in which a ring-shaped magnet 6 is inserted into an inner peripheral surface of a driving magnet housing 5 and a magnet 6 of a driving circuit body 4 is provided inside the impeller body 18, The magnet motor 20 has a structure in which the magnets 20 corresponding to the magnets 6 and 20 are embedded in the impeller body 18 and the driving magnet housing 5 and the impeller body 18 in which the magnets 6 and 20 are embedded, It is necessary to carry out a post-process of embedding the magnets corresponding to each other after the injection molding, which complicates the work process. Further, since the completed parts are assembled separately, the reliability of the products depends on the precision of the parts, It is difficult to manufacture and disassemble the magnets 6 and 20 embedded in the driving magnet housing 5 and the impeller body 18, and at the same time, The housing (5) Multiple body 18 and the confidence is less for each of the magnet 6 is not 20, coupling is loose or separated idle has the configuration not provided for preventing the product were also associated with problems.

An object of the present invention is to provide a magnetic pump using an injection magnet which can reduce the number of components by eliminating unnecessary components and simplify parts to simplify the manufacturing of components and the overall assembly process.

A drive assembly connected to a drive shaft of the motor and a driven assembly connected to the impeller are provided with a magnetic pump using an injection magnet that transmits power in a noncontact state by magnetic force and originally resolves the magnet from the drive assembly and the driven assembly .

In order to solve the above problems, according to an aspect of a magnetic pump using an injection magnet according to the present invention, there is provided a motor comprising: a motor bracket having a rotation shaft of a motor penetrated inwardly and opened at one side; A pump bracket that is opposed to the motor bracket and has a suction port for receiving fluid from the outside and a discharge port for discharging the sucked fluid; A blocking housing disposed between the motor bracket and the pump bracket and blocking a flow of fluid introduced into the pump bracket into the motor bracket and having a cylindrical receiving portion at the center; And an inner circumferential surface of the motor bracket rotatably connected to the inner circumferential surface of the motor bracket. The inner circumferential surface of the outer circumferential surface of the motor bracket is rotatably connected to the inner circumferential surface of the motor, A driven side rotator formed; A driven side rotator housed in the receiving portion of the blocking housing and formed in a hollow cylindrical shape and having N poles and S poles alternately repeated on the outer peripheral surface along the circumferential direction; And an impeller rotatably coupled to the driven side rotator and having a plurality of blades, wherein at least one of the drive side rotator and the driven side rotator is formed of an ejection magnet using a magnetic powder and a binder A magnetic pump using an injection magnet is provided.

In the magnetic pump using the injection magnet, the drive-side rotor or the driven-side rotator provided as an ejecting magnet may be provided as being magnetized simultaneously with the injection molding.

In the magnetic pump using the injection magnet, the driving-side rotator or the driven-side rotator provided as an ejecting magnet may be provided by being injection-molded under a magnetic field.

In the magnetic pump using the injection magnet, the driving-side rotator or the driven-side rotator provided as an ejecting magnet may be provided by being injection-molded under a magnetic field having a magnetic flux density equal to or greater than 1600G.

In the magnetic pump using the injection magnet, the magnetic powder may be a ferrite powder, and the binder may be one of nylon 12, nylon 6, nylon 66, and PPS (polyphenylene sulfide) resin.

In the magnetic pump using the injection magnet, the driving-side rotator further includes a fixing piece of a metal material fixed to the rotation axis of the motor, and the fixing piece is formed integrally with the driving-side rotator by insert injection molding ≪ / RTI >

In the magnetic pump using the injection magnet, the impeller may be provided such that one end of the impeller is supported by the shielding housing, and the other end of the impeller is supported by a support shaft supported by the pump bracket.

Wherein the support shaft is circular in cross section along the axial direction and is extrapolated to the support shaft to be positioned between the impeller and the shield housing, and the rotation shaft is inserted into the shield housing, A bushing housing side bushing connected to the bushing housing side bushing; And a pump bracket side bushing disposed between the impeller and the pump bracket and extruded to the support shaft to be connected to the pump bracket so as to lock the rotation in the circumferential direction.

Wherein the shield housing side bushing includes a through hole through which the support shaft rod penetrates, and an insertion hole extending from the through hole and having at least one flat surface in a part of an inner circumferential surface, The blocking housing may be provided with a fixing part formed at the center thereof with at least one flat fixing surface on a part of the outer circumferential surface corresponding to a plane formed in the insertion hole of the blocking housing side bushing.

In the magnetic pump using the injection magnet, the support shaft may be formed integrally with the shielding housing by insert injection molding, and a fixing groove may be formed on an outer circumferential surface of one end of the support shaft.

According to an embodiment of the magnetic pump using the injection magnet according to the present invention, at least one of the driving-side rotor and the driven-side rotor is provided with an ejecting magnet using a magnetic powder and a binder, And the manufacturing process is simplified as a whole.

In addition, it has an advantage of increasing price competitiveness by simplifying the manufacturing process.

Further, the blocking housing side bushing and the pump bracket side bushing have a configuration in which the rotation in the circumferential direction is locked with respect to the blocking housing and the pump bracket, respectively. This configuration simplifies the outer shape of the support shaft rod, and further, the assembly process can be simplified because the assembly can be completed by simply extrapolating the components extrapolated to the support shaft in sequence.

1 is a view showing a structure of a conventional magnetic motor disclosed in Korean Patent Publication No. 2007-0053183,
FIG. 2 is an exploded view of an example of a magnetic pump using an injection magnet according to the present invention,
FIG. 3 is an exploded view of an example of a magnetic pump using an injection magnet according to the present invention,
4 is a sectional view of an example of a magnetic pump using an injection magnet according to the present invention and FIG.
Fig. 5 is a photograph showing the external shape and magnetic force distribution of the driving-side rotors which are injection-molded and magnetized in Fig.

Hereinafter, an embodiment of a magnetic pump using an injection magnet according to the present invention will be described in detail with reference to the accompanying drawings.

Prior to this, the inventor could properly define the term concept to describe its invention in the best possible way, so that the terms and words used in the specification and claims are to be construed in an ordinary or preliminary sense And should be construed as meaning and concept consistent with the technical idea of the present invention.

FIG. 2 is an exploded view of an example of a magnetic pump using an ejecting magnet according to the present invention, FIG. 3 is an exploded view of an example of a magnetic pump using an ejecting magnet according to the present invention, Sectional view of an example of a magnetic pump using an injection magnet according to the invention, and Fig. 5 is a photograph showing external shapes and magnetic force distributions of the injection-molded and magnetized driving-side rotors in Fig.

2 to 4, a magnetic pump using an injection magnet according to the present invention includes a motor 100, a motor bracket 110 positioned in front of the motor 100, A blocking housing 150 interposed between the motor bracket 110 and the pump bracket 140 and a drive shaft 150 connected to the motor 100 to receive a rotational force from the motor 100. [ A rotor 120 and a driven side rotor 130 and a driven side rotor 130 which are coupled to the drive side rotor 120 by a magnetic force and rotate by rotation of the drive side rotor 120 And an impeller 132 that rotates and rotates together.

The motor 100 is provided with a rotating shaft 101 which is rotated by an external power source (not shown) in front of the motor 100. The rotating shaft 101 passes through the motor bracket 110, Side rotator 120 that is accommodated in the housing.

The motor bracket 110 is fixed to the motor 100 and has a hole 111 through which the rotation shaft 101 passes. The motor bracket 110 has an opening 112 at one side thereof. The opening 112 is formed at an outer side with a coupling hole 113 for coupling with the pump bracket 140 at regular intervals along the circumferential direction.

A coupling hole 141 corresponding to the coupling hole 113 of the motor bracket 110 is formed on the outer side of the pump bracket 140. Coupling means (not shown) passes through the coupling hole 141 The pump bracket 140 is coupled to the motor bracket 110.

The driving side rotator 120, the blocking housing 150 and the driven side rotator 130 are accommodated in the inner space formed by the motor bracket 110 and the pump bracket 140.

In addition, the pump bracket 140 is provided with a suction port 142 for introducing fluid into the center, and a discharge port 143 for discharging the sucked fluid is formed on the outer circumferential surface in a direction perpendicular to the suction port 142 have.

At the center of the suction port 142, there is provided a lock part 144 for engaging with a support shaft rod 160 to be described later.

The locking part 144 will be described in more detail with reference to the supporting shaft rod 160.

A blocking housing 150 is provided between the motor bracket 110 and the pump bracket 140 to divide an internal space formed by the motor bracket 110 and the pump bracket 140.

The blocking housing 150 blocks the fluid drawn into the pump bracket 140 from flowing into the motor 100 side.

The blocking housing 150 includes a cylindrical receiving portion 151 formed at the center and a planar portion 152 extending in the radial direction from the receiving portion 151.

The receiving portion 151 is received in the inside of the motor bracket 110 and a connection hole 153 is formed at an outer side of the flat portion 152 at regular intervals along the circumferential direction.

The connection hole 153 is in communication with the coupling hole 113 of the motor bracket 110 and the coupling hole 141 of the pump bracket 140. The motor bracket 110 and the pump bracket 140 are connected to each other by bolts The coupling means is pierced.

The connection hole 153 has a number corresponding to an integer multiple of the number of the coupling holes 113 and the coupling holes 141 to facilitate positioning of the blocking housing 150 at the time of coupling.

The driving side rotator 120 is accommodated inside the motor bracket 110 and one side is fixed to the rotating shaft 101 of the motor 100 and the other side is connected to the receiving portion 151 of the blocking housing 150 It is a hollow cylindrical member with one side open.

The driving-side rotator 120 includes a fixing piece 121 for fixing the rotating shaft 101 of the motor 100.

Further, N-pole and S-pole are alternately and repeatedly formed on the inner peripheral surface of the driving-side rotor 120 along the circumferential direction.

To this end, the driving-side rotator 120 is provided with an ejecting magnet using a magnetic substance powder and a binder.

Specifically, the driving-side rotator 120 is formed by mixing the magnetic powder and the binder into a liquid phase, and then injecting the mixture into a mold corresponding to the shape of the driving-side rotator 120, The magnet is magnetized at the same time as the injection molding by injection molding under a magnetic field in the state where magnets for magnetization are arranged at regular intervals on the outer peripheral surface of the mold corresponding to the outer peripheral surface of the mold.

Alternatively, magnets may be installed at regular intervals along the circumferential direction so as to surround the outer side of the receiving portion 151 of the shielding housing 150 at the inner circumferential surface of the driving-side rotator 120, However, all of the magnets were subjected to great difficulty in accurately positioning them.

However, in the case of using the ejecting magnet as in the present example, it is possible to eliminate manufacturing problems in which the magnet must be accurately positioned.

Here, the driving-side rotator 120 is made of a ferrite-based powder as a magnetic material powder, and one or more of nylon 12, nylon 6, nylon 66 and PPS (polyphenylene sulfide) resin is used as the binder.

On the other hand, the driving-side rotator 120 must be magnetized so as to have the magnetic flux density necessary for transmitting the torque required by the motor 100. According to the experiment of the present inventor, when the magnetic flux density of the magnet for magnetization is 3500 G or more, It was confirmed that the magnetic flux density of the rotor 120 was 1600 G and that when the driven side rotator 130 was magnetized at the same magnetic flux density, it could transmit a torque of 20 kgf · m or more.

The fixing piece 121 is made of a metal material such as aluminum and the rotation axis 101 of the motor 100 is adhered and fixed to the fixing hole 123 formed in the fixing piece 121 by a metal adhesive.

The fixing piece 121 is formed by insert injection molding at the same time during manufacture of the driving-side rotator 120, that is, injection molding, so that the engagement of the fixing piece 121 is performed simultaneously with the formation of the driving- .

Referring to FIG. 5, (a) shows a driving side rotor, (b) shows a magnetized state of a driving side rotor, in which a magnet is not separately adhered to or embedded in a driving side rotor, It can be seen that it is magnetized by itself.

The driven side rotator 130 is accommodated in the pump bracket 140 on the opposite side of the drive side rotator 120 with respect to the blocking housing 150. The driven-side rotator 130 is provided in a hollow cylindrical shape accommodated in the receiving portion 151 of the blocking housing 150, and an impeller 132 having a plurality of vanes is provided on one side thereof.

The driven-side rotator 130 is formed by alternately repeating N poles and S poles on its outer circumferential surface along its circumferential direction.

To this end, the driven-side rotator 130 is provided with an ejecting magnet using a magnetic powder and a binder.

The specific details are the same as those of the drive-side rotator 120 described above, and thus the description thereof will be omitted here.

Meanwhile, the driven-side rotator 130 is positioned to face the drive-side rotator 120 with the receiving portion 151 of the shielding housing 150 interposed therebetween. Due to this arrangement, the driven-side rotator 130 is coupled to the drive-side rotator 120 by the magnetic force. As a result, when the driven-side rotator 120 rotates, the driven- As a result, the impeller 132 rotates and the pumping operation is performed.

The support shaft 160 is positioned between the blocking housing 150 and the pump bracket 140 so as to allow the driven side rotator 130 to rotate by penetrating the driven side rotator 130, do. Unlike the support shaft bar of the prior art, the support shaft rod 160 is made of a ceramic material having the same circular cross section. In other words, the support shaft bar of the prior art is D-cut at both ends thereof and a part of the outer circumferential surface is flat. In this example, however, the support shaft rod 160 has the same overall circular cross section along the axial direction. Therefore, in this example, the support shaft rod 160 itself has an advantage of being easier to process than the prior art support shaft rod.

In addition, the support shaft rod 160 is inserted and fixed to the shielding housing 150, and a concave groove 161 is formed on the outer circumferential surface of the shaft rod 160 in order to ensure fixing after the injection shaft 160 is injected. When the cut-off housing 150 is injection-molded with a plastic material into the concave groove 161, the support shaft rod 160 can not be easily detached from the cut-off housing 150 after the injection.

The bushing 170 on the blocking housing side and the bushing 180 on the pump bracket side are extruded to both sides of the support shaft 160 about the driven rotor 130.

These bushings 170 and 180 prevent wear of the blocking housing 150 and the pump bracket 140 adjacent to the driven rotor 130 due to the rotation of the driven rotor 130, thereby improving the durability of the pump as a whole .

The blocking housing side bushing 170 and the pump bracket side bushing 180 are preferably made of a ceramic material having high abrasion resistance.

The blocking housing side bushing 170 is located between the driven side rotator 130 and the blocking housing 150 and is connected to the blocking housing 150 so that the rotation in the circumferential direction is locked.

The pump bracket side bushing 180 is located between the driven side rotator 130 and the pump bracket 140 and is connected to the pump bracket 140 so as to lock the rotation in the circumferential direction.

The rotation of the blocking housing side bushing 170 and the pump bracket side bushing 180 in the circumferential direction is locked to the blocking housing 150 and the pump bracket 140 instead of the supporting shaft rod 160 So that the assembly is simplified.

More specifically, referring to an enlarged portion of the blocking housing side bushing 170 in FIG. 2, the blocking housing side bushing 170 has a through hole 171 at the center thereof for extrapolation to the support shaft rod 160 And an insertion hole 172 extending from the through hole 171 is formed at one side of the through hole 171.

The blocking housing 150 is formed with a fixing portion 154 for fixing and supporting the supporting shaft 160. The insertion hole 172 of the blocking housing side bushing 170 is inserted into the fixing portion 154 .

At least one flat flat surface 172a is formed in a part of the inner circumferential surface of the insertion hole 172 and a flat portion 172a is formed in the fixing portion 154 of the blocking housing 150 into which the insertion hole 172 is inserted. At least one fixing surface 154a having a flat shape is formed on a part of the outer circumferential surface corresponding to the fixing surfaces 154a and 172a.

Therefore, even if the blocking housing side bushing 170 tries to rotate due to friction with the driven side rotator 130, the plane 172a and the fixing surface 154a are in contact with each other and can not rotate, The bushing 170 is locked in the circumferential direction.

In this embodiment, only one of the plane surface 172a and the fixing surface 154a may be provided, provided that they have the function of locking the rotation of the blocking housing side bushing 170 in the circumferential direction, have.

3, the pump bracket side bushing 180 has a through hole (not shown) at the center to be extrapolated to the support shaft 160, like the blocking housing side bushing 170, And an insertion hole 182 is formed at one side of the through hole 181 so as to extend from the through hole 181 and to be extruded into a locking portion 144 of a pump bracket 140 described later .

The support member 145 of the pump bracket 140 is formed with a lock portion 144 into which the end of the support shaft rod 160 is inserted and the insertion hole 182 is extruded outward. At least one flat surface 182a is formed in a part of the inner circumferential surface of the insertion hole 182. A locking portion 144 to which the insertion hole 182 is extruded is provided with an outer peripheral surface portion 182a corresponding to the flat surface 182a, At least one locking surface 144a having a flat shape is formed. Therefore, even if the pump bracket side bushing 180 tries to rotate due to friction with the driven side rotator 130, the plane 182a and the locking surface 144a are in contact with each other, The rotation of the bushing 180 is locked in the circumferential direction.

In this embodiment, only one of the plane 182a and the locking surface 144a is provided. However, if the structure has the function of locking the rotation of the pump bracket side bushing 180 in the circumferential direction while both structures are in contact with each other, can do.

As described above, the blocking housing side bushing 170 and the pump bracket side bushing 180 are not connected to the support shaft rod 160 so as to be locked with respect to the support shaft rod 160, 180 so that it is not necessary to form a flat surface with respect to the support shaft rod 160, which is advantageous in that it is easy to manufacture.

The blocking housing side bushing 170 enables insert injection molding of the supporting shaft rod 160 into the blocking housing 150 since the blocking shaft side bushing 170 can be assembled after the supporting shaft rod 160 is fixed to the blocking housing 150 .

The support shaft 160 is first fixed to the shielding housing 150 and then the support housing side bushing 170, the driven rotor 130, the pump bracket side bushing 180, and the pump bracket 140 are sequentially supported Since the assembly can be performed by inserting into the shaft rod 160, assembly is easy and the overall manufacturing process is simplified.

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, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (10)

A motor bracket through which the rotation axis of the motor penetrates inward and whose one side is open;
A pump bracket that is opposed to the motor bracket and has a suction port for receiving fluid from the outside and a discharge port for discharging the sucked fluid;
A blocking housing disposed between the motor bracket and the pump bracket and blocking a flow of fluid introduced into the pump bracket into the motor bracket and having a cylindrical receiving portion at the center;
And an inner circumferential surface of the motor bracket rotatably connected to the inner circumferential surface of the motor bracket. The inner circumferential surface of the outer circumferential surface of the motor bracket is rotatably connected to the inner circumferential surface of the motor. A driven side rotator formed;
A driven side rotator housed in the receiving portion of the blocking housing and formed in a hollow cylindrical shape and having N poles and S poles alternately repeated on the outer peripheral surface along the circumferential direction; And
An impeller rotatably coupled to the driven side rotator and having a plurality of blades,
At least one of the driving-side rotator and the driven-side rotator is formed of an ejecting magnet using a magnetic powder and a binder,
The driving-side rotator or the driven-side rotator provided as an ejecting magnet is injection-molded under a magnetic field,
Wherein the magnetic material powder is made of ferrite powder and the binder is made of any one of nylon 12, nylon 6, nylon 66, and PPS (polyphenylene sulfide) resin. The method according to claim 1,
Wherein the driving-side rotator or the driven-side rotator provided as an ejecting magnet is magnetized simultaneously with the injection molding. delete The method according to claim 1,
Wherein the driving-side rotator or the driven-side rotator provided as an ejecting magnet is injection-molded under a magnetic field having a magnetic flux density equal to or greater than 1600G. delete The method according to claim 1,
Wherein the driving-side rotator further comprises a fixing piece of a metal material fixed to a rotation axis of the motor,
Wherein the fixed piece is formed integrally with the drive-side rotor by insert injection molding. The method according to claim 1,
Wherein the impeller is supported at one end thereof by the cut-off housing and at the other end by a support shaft supported by the pump bracket. The method of claim 7,
The supporting shaft bar has a circular section in the axial direction,
A blocking housing side bushing disposed between the impeller and the blocking housing, the blocking housing side bushing being connected to the blocking housing so that rotation in the circumferential direction is locked; And
Further comprising a pump bracket side bushing disposed between the impeller and the pump bracket and extending outwardly from the support shaft to be connected to the pump bracket so that rotation in the circumferential direction is locked. The method of claim 8,
The blocking housing side bushing includes a through hole through which the supporting shaft rod penetrates, and an insertion hole extending from the through hole and having at least one flat surface in a part of an inner circumferential surface,
Wherein the blocking housing is provided at its center with a fixing part having at least one flat fixing surface on a part of an outer circumferential surface corresponding to a plane formed in the insertion hole of the blocking housing side bushing. The method of claim 7,
Wherein the support shaft rod is integrally formed by the cut-off housing and the insert injection molding,
Wherein a fixing groove is formed on an outer circumferential surface of one end of the support shaft rod.

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