KR101472040B1 - Motor-integrated pump - Google Patents

Abstract

The present invention relates to a motor integrated pump, in which the pump is integrated to a motor to simplify the configuration and decrease the volume, so that it can be easily manufactured, and the cooling has an advantage. A stator wound by a coil is fixed to a fixed hollow shaft, and the outside of the stator is enclosed by an inner capsule to be waterproof. A rotor is installed on the outside of the inner capsule to generate a magnetic field. The rotor is engaged to the shaft by a bearing so as to be rotated. An impeller is installed on the outside of the rotor, and the impeller is enclosed by an outer capsule. An intake casing and an outlet casing are engaged to both sides of the outer capsule, and the shaft is fixed to the intake casing and the outlet casing. The outlet casing is provided with a check valve to prevent a counter flow.

Description

MOTOR-INTEGRATED PUMP [0002]

The present invention relates to a pump, and more particularly, to a motor-integrated pump which is simple in structure by integrating a pump into a motor, has a small volume, is easy to manufacture, and is advantageous in cooling.

Conventionally, a pump used for water supply or drainage is provided separately from a motor and a pump. The pump and the motor are connected to each other to transfer the fluid from the pump by using the rotational power of the motor. Depending on the method of transferring to the pump, a direct coupling method in which the pump is directly connected to the rotation shaft of the motor, and a method in which power is transmitted using a belt or the like is used.

Depending on the place of use, the pump can not be used separately for land use and water use. In case of land use, the size of the product is uneven, the weight is large, the installation space is wide, There is a problem that maintenance cost is high because it is not easy to assemble. Also, in the case of a submerged pump used underwater, a bulky installation space is required, and in the case of a submerged pump used at a deep water depth, There is a problem of lengthening and an increase in the unit price of the product.

That is, in the case of the motor pump, since the motor and the pump are used in combination, the volume becomes large, the mechanical structure is complicated, the maintenance is not easy, and the overheating can not be effectively lowered.

Korean Patent Registration 10-0986474 (Registered on October 1, 2010) Korean Patent Publication No. 10-2009-0069466 (published on July 1, 2009) Korean Patent Publication No. 10-1997-0006916 (published Feb. 21, 1997) Korea Patent Registration No. 10-1258091 (Registered on April 19, 2013)

In the case where the motor pump is used as a motor pump by combining the motor and the pump after the motor and the pump are separately manufactured, the structure for transferring the rotational force of the motor to the pump is complicated. Since the motor and the pump are connected to each other, In order to solve the problem that deterioration due to the heat of the motor occurs when the rotation of the motor is continued, there is a problem in that a motor pump which is structurally simple and small in volume by making the pump integrally with the motor, .

The present invention provides a rotor rotor for fixing a stator wound with a coil to a hollow fixed shaft, the outer side of the stator is covered with an inner capsule to be waterproof, and a magnetic field is generated outside the inner capsule, The impeller is mounted on the outer side of the rotor rotor, and an outer capsule is disposed on the outer side of the impeller. The suction casing and the discharge casing are provided on both sides of the outer capsule, And a check valve for preventing the back flow is provided in the discharge casing. The impeller fixed to the rotor rotor is rotated so that the fluid flows from the suction casing through the impeller and the guide And discharged to the post-discharge casing through the vane. At the same time, And flows between the stator and the rotor rotor.

The impeller is fixed to the outside of the rotor rotor after the rotor rotor of the motor is rotated from the outside of the stator without manufacturing the motor pump by separately coupling the motor and the pump, When the rotor is rotated, the impeller is rotated so that the fluid passes between the rotor rotor and the outer capsule, thereby pumping the rotor.

In the present invention, a fluid flows through a hollow shaft while passing between a stator and a rotor rotor, and flows between a rotor and an external capsule. A check valve is provided in the discharge casing to prevent backflow.

According to the present invention, it is possible to manufacture the motor and the pump as a one-piece type, thereby reducing the production cost, reducing the installation area, enabling economical facilities, and being used for various purposes depending on the application.

The present invention is characterized in that the fluid is flowed to the hollow of the shaft and to the outside of the stator and is installed in the water (it can be installed inside the pipe and used for water supply or hot water circulation) It is possible to save the energy, and even when used for land use, it can prevent the condensation which occurs in the stator through water cooling inside and external air cooling (same as under water installation or land installation).

1 is a cross-sectional view of a state where a stator is fixed to a shaft of the present invention
Fig. 2 is a cross-sectional view of the stator of the present invention with its inner capsule covered
3 is a cross-sectional view of a state in which a rotor rotor and an outer capsule are covered with an outer side of the inner capsule of the present invention
Figure 4 is a cross-
5 is a cross-sectional view showing the discharge state of the present invention
FIG. 6 is a plan view of the assembled state of the present invention

In the present invention, a motor is combined with a pump to form a motor pump, and a pump is integrally formed with the motor. In this system, a rotor rotor constituting a conventional motor is used as a stator, By using the rotor as an electronic rotor, the rotor rotor surrounding the stator is rotated when the motor is operated, the impeller is fixed to the outside of the rotor rotor, and the outer capsule is provided outside the rotor rotor, So that the fluid can be discharged by the impeller.

In the present invention, a hollow shaft is fixedly installed, a cylindrical stator having a coil wound thereon is fixed, and a cylindrical inner capsule of nonmagnetic material is placed on the outer side of the stator, and a capsule housing is placed on both sides of the inner capsule, And a cylindrical rotor rotor for generating a magnetic field outside the inner capsule is provided. The rotor rotor is coupled to the shaft by a bearing to be rotated, and an impeller is installed on the outer side of the rotor, And the suction casing and the discharge casing are fitted to both sides of the outer capsule. The shaft is fixed to the center of the suction casing and the discharge casing, and the fluid is sucked and discharged through the outer side of the shaft.

In the present invention, water tightness is ensured between the inner capsule and the capsule housing and between the shaft and the capsule housing, while water tightness is ensured between the outer capsule and the suction casing and the discharge casing, and the space between the outer side of the inner capsule and the rotor, So that the fluid can be discharged through the rotation of the impeller.

A check valve is provided between the suction casing and the discharge casing to fix the fixing bolt therebetween while preventing the back flow in the discharge casing. The check valve is resiliently biased by the check spring, So that fluid flow can be made.

The coil of the stator is connected to the wire drawn to the inside of the rotor through the hollow of the shaft. The wire passing through the capsule housing is covered with a waterproof cap to be waterproofed.

In the present invention, when power is supplied for the operation of the motor pump, the rotor rotates on the outer side of the stator and is rotated by the rotation of the rotor, And at the same time, the fluid flows through the hollow of the shaft and flows through the space between the inner capsule and the rotor surrounding the stator, so that effective cooling is achieved.

Particularly, the present invention can provide a motor pump that is simple in construction, has a small volume, and can be effectively cooled by rotating the impeller using a rotor rotor of a motor without a separate pump.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The shaft 10 of the present invention has a hollow 11 formed therein and is fixed to the center of the suction casing 60 and the discharge casing 70 so as not to be rotated by using a polygonal key or a fixed key, The fluid is sucked and discharged through the inside of the discharge casing 70 while the stator 20 fixed to the shaft 10 is fixed so as not to rotate.

A cylindrical stator 20 having a coil wound thereon is fixed to the shaft 10 so as not to move left and right using E-rings or the like on both sides of the stator 20 and the outer diameter of the shaft 10 is polygonal The stator 20 is not rotated while being coupled to the shaft 10.

A coil is wound around the stator 20 and a current is supplied to the coil through a wire 21. The wire 21 passes through the capsule housing 31 and then flows through the hollow 11 of the shaft 10, And the electric wire 21 is inserted into the capsule housing 31 by using a waterproof cap to prevent water from flowing into the stator 20 through the electric wire 21.

A cylindrical inner capsule 30 made of a nonmagnetic material is placed on the outside of the stator 20 at predetermined intervals. Both sides of the inner capsule 30 are covered with a capsule housing 31, The housing 31 is fixed to the shaft 10 so that the inner capsule 30 remains fixed with the shaft 10. [

The inner capsule 30 in which the capsule housing 31 is inserted and fixed is inserted through an O-ring to ensure watertightness and an O-ring is inserted between the capsule 10 and the shaft 10 to which the capsule housing 31 is fixed The watertightness is ensured so that the internal space of the inner capsule 30 provided with the stator 20 is surely waterproofed.

A rotor rotor 40 having a cylindrical shape and generating a magnetic field at a predetermined distance from the inner capsule 30 is installed. The rotor rotor fixing bracket 41 is fixed to both sides of the rotor 40, The electronic rotor fixing metal 41 is engaged with the shaft 10 via the bearing 45 so that the rotor rotor 40 is rotated.

In the present invention, the rotor rotor fixing metal (41) has a comb shape to allow fluid to flow into or out of the inner space of the rotor rotor (40) while the rotor rotor fixing metal (41) (10) so that the rotor rotor (40) is rotated about the bearing (45).

A known outer impeller 46 is installed on the outer side of the rotor rotor 40 and a cylindrical outer capsule 50 is installed at a predetermined distance from the impeller 46, A known guide vane is installed to allow fluid to be discharged during rotation of the impeller 46.

The outer capsule 50 of the present invention is fixed to both sides of the suction casing 60 and the discharge casing 70 by sandwiching the suction casing 60 and the discharge casing 70. The shaft 10 is fixed to the center of the suction casing 60 and the discharge casing 70 The suction casing (60) and the discharge casing (70) have a form of a flow path for allowing fluid to flow into the outer capsule (50).

An O-ring is interposed between the outer capsule 50 and the suction casing 60 and the discharge casing 70 so that water tightness is established between the outer casing 50 and the discharge casing 70 while fixing the fixing bolt 90 between the suction casing 60 and the discharge casing 70 .

In the present invention, the discharge casing 70 is provided with a check valve 80 that is biased by a check spring 81 so as to prevent reverse flow, and the inlet and outlet of the suction casing 60 and the discharge casing 70 are formed with a screw And a pipe 91 is formed at the bottom of the suction casing 60 and the discharge casing 70 so as to be fixed to a pedestal not shown.

According to the present invention having such a configuration, a stator for generating a magnetic field of a conventional motor is rotated to use the stator as a rotor rotor 40 by using a rotor of a conventional motor with a coiled rotor wound thereon as a stator 20, And a stator fixed to the casing in a conventional motor is formed into a rotatable cylindrical rotor rotor 40. In the present invention, when a current is supplied, a current The rotor rotor 40 is rotated in a state where the stator 20 is fixed by a force received in the magnetic field.

The shaft 10 is fixed to the stator 20 while being fixed to the center of the suction casing 60 and the discharge casing 70. The shaft 10 is fixed to the stator 20 and the suction casing 60 and the discharge casing 70 and the outer capsule 50 are kept in a fixed state without rotating.

The inner capsule 30 which is placed on the outer side of the stator 20 at a predetermined interval is fixed to the side surface by using the capsule housing 31 fixed to the shaft 10, And the capsule housing 31 and the capsule housing 31 and the shaft 10 so that water is sealed between the capsule housing 31 and the shaft 10 so that the fluid flows into the inner space of the inner capsule 30 So that it never flows.

The stator 20 does not move on the shaft 10 by using E-rings on both sides and the shaft 10 has a polygonal shape so as not to rotate. The shaft 10 has a hollow 11, So that the electric wire 21 is connected to the coil of the stator 20.

At this time, the electric wire 21 passing through the capsule housing 31 is connected through the waterproof cap, and the portion where the rotor rotor fixing metal 41 is installed can be connected to the electric wire 21 through the inside of the shaft 10 , The rotation of the rotor rotor (40) is ensured while the electric wire (21) is installed, and the watertightness at the portion where the electric wire (21) is connected is ensured.

The inner capsule 30 of the present invention is made of a non-magnetic material so as not to be influenced by the magnetic field or disturb the flow of the magnetic field.

The side surface of the rotor rotor 40 is fixed to the outside of the inner capsule 30 of the present invention at a predetermined interval by a rotor rotor fixing metal member 41. The rotor rotor fixing member 41 is fixed to a bearing 45, so that the rotor rotor 40 can freely rotate by the bearing 45. As shown in Fig.

The fluid is sucked into the suction casing 60 through the rotor fixing metal fitting 41 so as to support the rotor rotor 40. The fluid sucked into the suction casing 60 flows through the rotor fixing metal fitting 41, And is discharged to the discharge casing 70 after passing between the rotor 40 and the inner capsule 30.

The impeller 46 is installed on the outer side of the rotor rotor 40 while the outer capsule 50 is mounted on the outer side of the impeller 46. Both side surfaces of the outer capsule 50 are connected to the suction casing 60 And the discharge casing 70, as shown in Fig.

At this time, the suction casing 60 and the discharge casing 70 are configured to have a flow path in which the fluid flows when fixing the discharge casing 70 to the shaft 10, so that after the fluid is sucked through the suction casing 60, So that the fluid can be discharged.

The outer capsule 50 of the present invention allows water to be sealed by engaging an O-ring with the suction casing 60 and the discharge casing 70. The inside of the outer capsule 50 is filled with a fluid And the suction casing (60) and the discharge casing (70) are fixed by fixing the fixing bolt (90).

In the present invention, when the electric current is supplied through the electric wire 21, since the stator 20 is fixed to the shaft 10, the rotor rotor 40 rotates and the rotor rotor 40 Since the impeller 46 installed on the outer side rotates, the fluid is discharged by the guide vane provided inside the outer capsule 50.

That is, when the rotor rotor 40 rotates, the impeller 46 rotates and the fluid sucked into the suction casing 60 is discharged through the discharge casing 70, and the internal capsule 30 The fluid flows between the inner capsule 30 and the rotor 40 and the fluid flows through the hollow 11 of the shaft 10 while flowing the fluid between the rotor rotors 40 and between the inner capsule 30 and the rotor 40, The fluid flowing through the hollow 11 of the motor cools the heat generated by the rotation of the motor.

In the case of using for water, the outer side of the outer capsule 50 is submerged in water, so that cooling can be easily performed. In the case of being used for land use, however, So that the cooling fins are formed.

Since the fluid flowing between the inner space of the rotor rotor 40 and the inner capsule 30 and through the hollow 11 of the shaft 10 is cooled when the impeller 46 discharges the fluid, Overheating does not occur.

The discharge casing 70 is provided with a check valve 80 that is biased by a check spring 81. When the pressure of the discharged fluid compresses the check spring 81, normal discharge is performed, The discharge casing 70 is blocked by the elastic force of the check spring 81, thereby preventing the fluid from flowing backward.

The present invention can be applied to a case where the suction casing 60 and the discharge casing 70 are fixed to the pedestal by using a fixture 91 formed on the suction casing 60 and the discharge casing 70, In case of installation in water, only suction shaft can be fixed by pipe pipe or only discharge shaft can be fixed by pipe pipe, so that it can be used for a desired purpose.

10: shaft 20: stator
30: inner capsule 40: rotor rotor
45: Bearing 46: Impeller
50: outer capsule 60: suction casing
70: Discharge casing 80: Check valve
90: Fixing bolt

Claims (5)

A shaft (10) having a hollow polygonal shape is provided,
And a cylindrical stator (20) fixed to the shaft (10) and wound with a coil connected to the electric wire (21)
And an inner capsule 30 made of a non-magnetic material of cylindrical shape covering the outer side of the stator 20,
And a capsule housing (31) fixed to both sides of the inner capsule (30) while being fixed to the shaft (10)
And a cylindrical rotor rotor (40) covering the outer side of the inner capsule (30)
And a rotor rotor fixing metal (41) fixed to both sides of the rotor rotor (40) while being fixed to the shaft (10) via a bearing (45)
And an impeller (46) fixed to the outside of the rotor rotor (40)
And a cylindrical outer capsule (50) covering the outer side of the impeller (46)
And a suction casing (60) and a discharge casing (70) fixed on both sides of the outer capsule (50) and fixed to the shaft (10)
Wherein the discharge casing (70) is provided with a check valve (80) which is biased by a check spring (81) to prevent back flow. 2. The method according to claim 1, wherein the fluid introduced into the suction casing (60) is discharged through the discharge casing (70) by rotation of the impeller (46), while flowing through the hollow (11) 30) and the rotor (40) while flowing through the space between the rotor (30) and the rotor (40). The electric motor according to claim 1, wherein the electric wire (21) connected to the coil of the stator (20) is installed through a watertight cap provided in the capsule housing (31) Wherein the pump is connected to an external power source through a pump. The capsule endoscope according to claim 1, wherein an inner ring (30) and a capsule housing (31), a capsule housing (31) and a shaft (10), an outer capsule (50) And the watertightness of the motor is achieved. The motor-integrated type pump according to claim 1, wherein a radiating fin is provided outside the outer capsule (50), and a fixing hole (91) is formed in the suction casing (60) and the discharge casing (70).

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