KR200260504Y1 - The motor pump - Google Patents

Abstract

The present invention mainly relates to the structure of a condenser starting type induction motor which can be used in water. More specifically, epoxy molding of a stator maintains a waterproof state and separates and shields both of the rotor and stator from each other. The sealing structure and the cover to seal the surface of the rotor prevent the water from penetrating into the stator and the rotor even when water enters the electric part side. Between the bearing holder and the clamps installed on the cover, the cover, and the rotating shaft of the rotor, respectively, there is a passage through which external fluid can flow, and actively induces the flow of water, thereby cooling the heat generated by the electric part by the inflow fluid. It is possible to improve the power efficiency and extend the service life by preventing overheating. In addition to filter the foreign objects were to be in the fluid flowing through the filter screen is to block the degradation of components of the failure factors and transmission efficiency.

Description

Capacitor Start Induction Motor {THE MOTOR PUMP}

The present invention mainly relates to the structure of a condenser starting type induction motor which can be used in water. More specifically, epoxy molding of a stator maintains a waterproof state and separates and shields both of the rotor and stator from each other. The sealing structure and the cover to seal the surface of the rotor prevent the water from penetrating into the stator and the rotor even when water enters the electric part side. Between the bearing holder and the clamp is installed in the cover and the rotating shaft of the rotor, there is a passage for the flow of external fluid, respectively, through which actively induces the flow of water to cool the heat generated from the electric drive by the flow fluid It is possible to improve the power efficiency and extend the service life by preventing overheating. In addition, it is possible to filter the foreign matter of the fluid flowing through the filter network to block the failure factors and deterioration of the transmission efficiency.

In general, a pump is a device that transports a liquid or gas fluid through a pipe by a pressure action, or pumps a fluid in a low pressure container into a high pressure container through a pipe, and is used in rural, mining, civil engineering, factory, Pumps are usually used where fluids are used up to the home.

In addition, pumps are widely used for transportation of special fluids such as petroleum, various chemicals or pulp, viscose, sludge, etc., and pumps have many types depending on the head, flow rate, and type of liquid to be handled. There are rotary (rotary) pump, centrifugal pump, axial pump, friction pump, etc., depending on the purpose, it can be called water feed pump, deep well pump, etc. Also, it is a vacuum pump that draws air or other gas in the container and makes a vacuum. There is.

On the other hand, it is known that a condenser start type induction motor pump, which receives electrical input from various pumps as described above, generates mechanical output by electromagnetic force, and rotates an impeller to transfer fluid.

It includes a pump unit consisting of an impeller housing in which an inlet and an outlet are formed and an impeller installed therein, a stator fixedly installed in the housing, and a rotatable shaft rotatably installed in the stator and coupled with an impeller. It is composed of a transmission unit consisting of a rotating rotor and the like, and the rotating shaft exposed to the outside of the motor housing is provided with a sealing sealing member for preventing the penetration of moisture into the interior of the housing.

On the other hand, induction motors have electrical and mechanical losses that occur during power conversion.

Since the heat generated by these losses has a great influence on the lifespan and characteristics of the induction motor, the induction motor must be cooled through an appropriate cooling system.

In other words, the induction motor is cooled by heat conduction from the heat source to the atmosphere and convective heat transfer through the vents, which are influenced by various factors such as material, cooling area, ventilation structure, flow rate and pressure of each component. In particular, as the size of the induction motor increases, the problem caused by the temperature increase becomes larger, and the efficient design and configuration of the cooling system becomes important.

However, the conventional pump as described above, the stator and the rotor is configured in a non-waterproof state, and also does not have a sealing structure that can accommodate the isolation of both, so that the housing in order to prevent the penetration of the water to the electric drive when used in water It has a structure that completely seals the part, so that the heat generated by the electric part during pump operation is made only through the motor housing surface, resulting in inadequate cooling and heat dissipation, resulting in frequent overheating. Causes such problems,

In addition, when the sealing member installed at the contact portion between the rotating shaft and the housing is worn out, the sealing state is released, and moisture penetrates into the stator and the rotor of the electric section, causing a short, which is a direct cause of failure and shortening of the life, or the stator and rotation. Insulation oil, which is filled between electrons, leaks to the outside and contaminates water quality.

In addition, since the core of the stator and the rotor are installed without a separate cover, it is difficult to precisely maintain the gap between them, resulting in a reduction in transmission efficiency and excessive heat generation.

In addition, the head and the flow rate for the maintenance of the sealing function is limited to a small range will have a structural problem that is limited to the use of small capacity.

The present invention is intended to solve the problems caused by the conventional electric pump as described above, the object of the present invention is to prevent the water from penetrating the inside of the stator and the rotor even when the water flows into the electric motor side, such as a short Not only prevents faults, but also actively induces the flow of water so that the heat generated by the electric part can be cooled and discharged by the inflow fluid to improve the electric efficiency and prolong the service life by preventing overheating. It is possible to filter foreign substances in the incoming fluid to provide a condenser start type induction motor pump that can block failure factors and deterioration of electric efficiency.

In order to achieve the above object, the present invention maintains a waterproof state by epoxy molding a stator.

The present invention also proposes a multiple or monolithic sealing structure that isolates and shields both between the rotor and the stator.

The present invention also proposes a thin metal cover that seals the surface of the rotor to prevent moisture penetration into the rotor.

In addition, the present invention proposes a passage through which external fluid can flow between the bearing holder and the clamp installed in front of the rotor and the cover and the rotating shaft of the rotor, respectively.

In addition, the present invention proposes a filter net fixedly installed between the bearing holder and the clamp to filter foreign matter contained in the water flowing into the electric drive.

In addition, the present invention proposes a vortex generating groove for assisting the circulation movement by vortexing the fluid flowing in the rear end of the rotating shaft.

Hereinafter, the configuration of the present invention with reference to the accompanying drawings in detail.

1 is a cross-sectional view showing the overall configuration of the present invention.

Figure 2 is an enlarged view of the main part for explaining the operation of the present invention.

Figure 3 is an exploded perspective view showing the sealing means of the rotor applied to the present invention.

Figure 4 is an exploded perspective view showing a filter structure applied to the bearing holder of the present invention.

Figure 5 is a perspective view of the main part showing the vortex generating structure configured on the rotating shaft of the rotor of the present invention.

Figure 6 is a side view of the main part showing a cooling fluid distribution hole formed in the cover of the present invention.

※ Explanation of code about main part of drawing ※

10 pump portion 11: impeller housing

12 inlet port 13 outlet port

14: impeller 20: electric drive

21: stator 22: rotor

23: rotating shaft 24: motor housing

30: cover 40: bearing holder

41 clamp 50 molding part

60: sealing structure 61: front seal

62: intermediate seal 63: rear seal

70: metal cover 80: filter net

81: support plate 82: fluid distribution hole

90: fluid movement passage 100: cooling passage

110: cooling hole 120: vortex generating groove

1 is an exemplary cross-sectional view showing the overall configuration of the present invention, Figure 2 is an enlarged view of the main portion for explaining the operation of the present invention,

The impeller housing 11 and the impeller 14 installed inside the impeller housing 11, the inlet 12 and the outlet 13 of the fluid are formed at right angles to each other, and the impeller The transmission unit is configured to be coupled to the housing 11 and the motor housing 24 and the like is installed a rotor 22 having a stator 21 and a rotating shaft 23 fixedly coupled to the impeller 14 therein. 20, a cover 30 fixedly coupled to the motor housing 24, a bearing holder 40 supporting the bearing B1 coupled to the rotating shaft 23, and the bearing holder 40. In the known condenser starting type induction motor pump structure including a clamp 41 coupled with

A molding part (50) for maintaining the waterproof state by epoxy molding the stator (21);

It is configured to be integrally coupled with the molding part 50 in a state located between the stator 21 and the rotor 22 and to isolate the stator 21 and the rotor 22 in a sealed state at the top. A front seal 61 having a base 61 'for supporting the O-ring 0, a tubular intermediate seal 62 integrally coupled to the front seal 61, and the intermediate seal A metal sealing structure (60) integrally coupled with the sieve (62) and composed of a rear seal (63) for holding and supporting the bearing (B2);

A metal cover 70 formed on the entire surface of the rotor 22 to seal the inside of the rotor 22 from the outside;

The filter net 80 is fixed to the front of the bearing holder 40 through the support plate 81 having a plurality of fluid flow holes 82 and for filtering foreign substances of the fluid flowing into the transmission unit 20 in advance and;

In order to guide the filtered water through the through hole 40 ′ of the filter net 80 and the bearing holder 40 to the transmission unit 20, a predetermined space is provided between the bearing holder 40 and the clamp 41. A fluid movement passage (90) configured;

A cooling passage (100) formed in the longitudinal direction in the rotation shaft (23);

A plurality of cooling holes are formed through the rear surface of the cover 30 so that external water or air can be circulated to the inside and outside of the cover 30, and a plurality of cooling holes for cooling and dissipating heat generated from the electric motor 20 ( 110);

The recess is formed at the rear end of the rotary shaft 23 and includes a vortex generating groove 120 for providing a circulation movement function by vortexing the fluid flowing through the cooling furnace 100.

※ Unexplained code in the drawing ※

(P) is the seal packing, (TP) is the overheat protection,

(C) shows a capacitor.

Referring to the operation of the subject innovation constituted as above in detail as follows.

Figure 2 is an enlarged view of the main part for explaining the operation of the present invention,

When the power switch (not shown) installed in the pump of the present invention 'on' the electric part 20 is operated as in the conventional pump, the rotor 22 is rotated and the impeller coupled to the rotating shaft 23 ( By rotating 14), the water is sucked through the inlet 12, and the sucked water is discharged and transferred through the discharge port 13.

Part of the water flowing into the impeller housing 11 by the operation of the impeller 14 in the pumping process through the fluid distribution hole 82 of the support plate 81 fixed to the front of the bearing holder 40 Foreign matter is introduced and filtered through the filter net 80, and the filtered water exits the through hole 40 'of the bearing holder 40 and is transferred through the fluid movement passage 90 provided between the clamp 41 and the clamp 41. It flows in the eastern part 20.

Therefore, foreign matter contained in the non-filtered water may be attached to the surface or other parts of the rotor 22 to fundamentally prevent the cause of rotational resistance and failure.

In addition, even if water is introduced into the transmission part 20, the penetration of moisture into the rotor 22 completely sealed by the metal cover 70 becomes impossible, so that there is no fear of failure due to moisture. In addition, the inflow of water to the stator 21 side by the molding part 50 surrounding the sealing structure 60 and the stator 21 is also impossible, so that the stator 21 is also not adversely affected by the water transmission part 20. ) Is secured.

Water flowing into the transmission unit 20 is rotated through a predetermined gap provided between the metal cover 70 of the rotor 22 and the intermediate seal 62 as shown by the arrow of FIG. 22) It is introduced into the rear sealing body 63 of the rear to function to cool the operating heat of the rotor (22).

In addition, the sucked water flows to the bearing B2 in the rear seal 63 through the cooling passage 100 formed in the longitudinal direction inside the center of the rotating shaft 23 by the rotor 22. Cooling the heat transferred to 23) to assist the cooling function.

On the other hand, the water in the bearing B2 in the rear seal 63 of the rotor 22 is in contact with the vortex generating groove 120 formed at the rear end of the rotating shaft 23, causing vortex phenomena. By allowing the fluid in the cooling path 100 of 23 to flow without stagnation, the cooling efficiency can be improved.

In addition, since the external water may flow into the cover 30 through the cooling hole 110 formed at the rear side of the cover 30, it is possible to cool the heat transferred to the molding part 50, thereby providing more perfect cooling. When it is used on the ground and not underwater, the air can be circulated inflow to have an air cooling effect.

On the other hand, between the stator 21 and the rotor 22 of the present invention, the intermediate sealing body 62 of a thin thin sheet is located, so that it is easy to maintain the mutual gap precisely and at the time of operation of the rotor 22. Even if the microfluidic flow is caused, the stator 21 is not affected, so that the transmission efficiency is not lowered, or overheating and failure are not caused.

On the other hand, the sealing structure 60 is represented as three parts in the drawings, but may be configured as a single body, it can be advantageous in the function, effect, manufacturing process.

Rotating shaft 23 to be applied to the present invention is not limited to a specific material, but preferably is composed of a ceramic material that is excellent in heat resistance and wear resistance, and hardly axial deformation occurs.

The present invention as described above has a sealing structure to maintain the waterproof state by molding the stator, and the sealing structure to isolate and shield the rotor and the stator, and a metal cover to seal the surface of the rotor, so that the water stator even when the water inflows to the electric part side It can prevent the breakdown such as short by blocking the penetration into the inside of the rotor.

Furthermore, by actively inducing moisture into the electric drive, the heat generated can be cooled and discharged through the inflow fluid, thereby improving the electric efficiency and extending the service life by preventing overheating.

In addition, it is possible to filter the foreign matter of the fluid flowing through the filter network has the effect that can block the failure factors and degradation of the transmission efficiency.

Claims (4)

The impeller housing 11 and the impeller 14 installed inside the impeller housing 11, the inlet 12 and the outlet 13 of the fluid are formed at right angles to each other, and the impeller The transmission unit is configured to be coupled to the housing 11 and the motor housing 24 and the like is installed a rotor 22 having a stator 21 and a rotating shaft 23 fixedly coupled to the impeller 14 therein. 20, a cover 30 fixedly coupled to the motor housing 24, a bearing holder 40 supporting the bearing B1 coupled to the rotating shaft 23, and the bearing holder 40. In the known condenser starting type induction motor pump structure including a clamp 41 coupled with A molding part (50) for maintaining the waterproof state by epoxy molding the stator (21); A metal seal for integrally coupling the molding part 50 in a state located between the stator 21 and the rotor 22 to isolate the stator 21 and the rotor 22 in a hermetically sealed state. The structure 60; A metal cover 70 formed on the entire surface of the rotor 22 to seal the inside of the rotor 22 from the outside; The filter net 80 is fixed to the front of the bearing holder 40 through the support plate 81 having a plurality of fluid flow holes 82 and for filtering foreign substances of the fluid flowing into the transmission unit 20 in advance and; In order to guide the filtered water through the through hole 40 ′ of the filter net 80 and the bearing holder 40 to the transmission unit 20, a predetermined space is provided between the bearing holder 40 and the clamp 41. A fluid movement passage (90) configured; A cooling passage (100) formed in the longitudinal direction in the rotation shaft (23); A plurality of cooling holes are formed through the rear surface of the cover 30 so that external water or air can be circulated to the inside and outside of the cover 30, and a plurality of cooling holes for cooling and dissipating heat generated from the electric motor 20 ( 110); The condenser starting type induction motor is formed in the rear end of the rotary shaft 23 and includes a vortex generating groove 120 for providing a circulation movement function by vortexing a fluid flowing through the cooling furnace 100. Pump. The method of claim 1, The sealing structure 60, It is configured to be integrally coupled with the molding part 50 in a state located between the stator 21 and the rotor 22 and to isolate the stator 21 and the rotor 22 in a sealed state at the top. A front seal 61 having a base 61 'for supporting the O-ring 0, A tubular intermediate seal (62) integrally coupled with the front seal (61), Condenser starting type induction motor pump, characterized in that it is integrally coupled with the intermediate seal (62) and comprises a rear seal (63) for receiving and supporting a bearing (B2). The method according to claim 1 or 2, The sealing structure (60) is a condenser starting induction motor pump, characterized in that consisting of a single piece (one piece). The method of claim 1, The metal cover (70) of the rotor (22) is a condenser starting induction motor pump, characterized in that configured to maintain a predetermined distance from the intermediate seal 62 of the sealing structure (60).