KR20100050986A - A underwater pump - Google Patents

Abstract

PURPOSE: An underwater pump is provided to expect a lubricating and a cooling effect by water film which is formed between a casing and a rotor while fluid is inhaled. CONSTITUTION: An underwater pump(100) comprises: a motor unit(110) which generates power to inhale fluid inside; and an impeller unit(210) which inhales and discharges by the power from the motor. The motor unit comprises a casing(112) wherein a space is formed, a stator(120) which is fixed on the outer circumference of the casing, and a rotor(130) which rotates in the casing.

Description

Submersible motor pump {A underwater pump}

The present invention relates to an submersible motor pump, and more particularly, to a rotor exposed to a fluid when the impeller is rotated while the impeller is formed in a cylindrical shape and is fixed to a rotor made of a steel plate made of silicon. The present invention relates to an underwater motor pump coated with a rotor to prevent cyan from being generated.

In general, the submersible motor pump is used in various fields for draining or pumping the entire pump in water or using a separate pipe.

The submersible motor pump is configured to suck or discharge fluid while the impeller of the pump unit rotates by the operation of the motor unit.

However, since they are provided with the rotor and stator of the motor unit together inside the motor casing, and the motor unit and the pump are hermetically separated from each other, the fluid pumped from the pump unit cannot be introduced into the motor unit. Lubricant should be applied in between, and repairing the motor part had a problem that the lubricant is leaked to the outside to contaminate the fluid flowing into the pump.

In addition, the rotor is supported only by the concentricity of the bearing, so when used for a long time, the bearing is worn out can not achieve the concentricity accurately, there was a problem that vibration and noise occurs.

In addition, the heat generated during operation of the motor unit is transferred to the motor casing and indirectly cooled by the fluid in contact with the outside of the motor case, resulting in low cooling efficiency. And there was a problem that the function is lowered to lower the efficiency of the pump.

On the other hand, the conventional submersible motor pump has a problem such as a high failure rate due to the complicated structure, the assembly cost increases.

The present invention has been made in order to solve the above problems, having a rotor formed in a cylindrical shape, the rotor and the impeller is fastened and fixed to connect the impeller by the rotation of the rotor while rotating the inside of the rotor When the fluid is sucked through the water film is formed between the casing and the rotor to be lubricating and cooling by this water film.

In addition, the coating is provided on the surface of the rotor made of a silicon material to provide a coating member to prevent the rotor of the silicon material from being exposed to the fluid to prevent cyan and corrosion caused by the fluid.

On the other hand, by cooling the heat generated during the operation of the pump by itself, there is no need for a separate coolant, the structure is simple and easy to assemble, at the same time the production price is low and the failure rate to provide an underwater motor pump There is this.

In addition, the fixing ring of the ceramic material is provided without the need of a bearing for guiding the same when the rotor is rotated, and the liquid does not need a separate cooling lubricant to cool the heat generated by the friction between the fixing ring and the rotor. The purpose is to allow the fluid to cool.

The present invention for achieving the above object is characterized by consisting of a motor unit for generating power so that the fluid is sucked into the inside, and an impeller unit for forcibly sucking and discharging the fluid by the power of the motor unit.

Here, the motor unit is characterized in that the casing is formed in the inner space, the stator is fixed to the outer peripheral surface of the casing, and the rotor provided inside the casing to perform a rotation operation.

Further, the casing is formed in a cylindrical shape, the inlet is formed so that the fluid flows into one side, characterized in that the impeller is fastened and fixed to the other side.

In addition, the rotor is formed in a cylindrical shape, the flow path is formed on the inner side, each side of the flow path is formed with a stepped surface, each of the stepped surface is characterized in that the rotary ring is fastened and fixed.

And, each of the outer circumferential surface of the rotating ring is fixed to the inner circumferential surface of the casing, characterized in that the fixing ring for guiding the rotation of the rotor is further provided.

In addition, the coating member for covering the surface of the rotor to be sealed is characterized in that it is provided.

Here, the coating member is characterized in that the synthetic resin material.

And, the coating member is characterized in that the natural rubber material.

In addition, the coating member is characterized in that any one of copper, aluminum, tin, zinc, copper, brass, white iron, stainless.

On the other hand, the rotor flow path is characterized in that the blade wing further provided.

Here, the screw blade is provided with a fixed tube that is fitted into the rotor flow path, characterized in that a plurality of screw wings are provided on the inner peripheral surface of the fixed tube.

In addition, the impeller is fastened and fixed to the longitudinal side of the casing, the impeller housing is formed with a discharge port for discharging the fluid, it characterized in that the impeller is provided inside the impeller housing.

Here, the impeller is characterized in that the extension member is formed on the rotary ring provided on the inner side of the casing and fastened to the extension member.

In addition, the outlet of the impeller housing is characterized in that formed on the same line as the flow path of the rotor.

In addition, the outlet of the impeller housing is characterized in that formed on the outer peripheral surface of the impeller housing.

The present invention configured as described above has a rotor formed in a cylindrical shape, and the rotor and the impeller are fastened and fixed so that the casing and the fluid is sucked through the inside of the rotor while the impeller is rotated by the rotation of the rotor. The water film is formed between the rotors, so that the water film can be lubricated and cooled.

In addition, by coating the surface of the rotor made of silicon material is provided with a coating member has the effect that the rotor of the silicon material is exposed from the fluid to prevent cyan, corrosion and the like generated by this fluid.

On the other hand, by cooling the heat generated during the operation of the pump by itself, there is no need for a separate coolant, and the structure is simple, easy to assemble, low production cost, and has the effect of providing an underwater motor pump with low failure rate have.

In addition, the fixing ring of the ceramic material is provided without the need of a bearing for guiding the same when the rotor is rotated. There is an effect that can be cooled by using a fluid.

Hereinafter, described in detail with reference to the accompanying drawings for the submersible motor pump according to the present invention.

1 is a cross-sectional view showing an underwater motor pump according to the present invention, Figure 2 is an enlarged view showing a portion A of Figure 1, Figure 3 is a perspective view showing a rotor of the present invention, Figure 4 is a rotor of the present invention It is a cross section shown.

1 to 4, the submersible motor pump 100 according to the present invention is provided with a motor unit 110 for generating power so that the fluid is sucked inward to flow in one direction.

Here, the motor unit 110 is provided with a casing 112 having a space 114 formed therein, and is provided with a stator 120 fixed to an outer circumferential surface of the casing 112, and the casing 112. The inner space 114 of the rotor 130 is provided to be located inside the stator 120.

Further, the casing 112 is formed in a cylindrical shape is formed with a suction port 116, the fluid is sucked to one side, the end of the casing 112 is formed bent inward to be formed smaller than the diameter of the rotor 130 The other end of the suction port 116 is bent to face the outside.

The stator 120 is fixed to the outer circumferential surface of the casing 112 and fixed to the outer circumferential surface of the position where the rotor 1230 is provided.

At this time, the stator 120 is provided on the outer circumferential surface of the casing 112 to generate power by applying power, and is configured to maintain a closed state by the sealing means.

In addition, the rotor 130 is formed in a cylindrical shape, the flow path 132 is formed on the inner side, the rotor 130 is provided to be spaced apart from the inner peripheral surface of the casing 112 at a predetermined interval.

Here, stepped surfaces 134 and 134a are further formed at both sides of the flow path 132 of the rotor 130, and the rotary rings 136 and 136a protrude outwardly from the stepped surfaces 134 and 134a. ) Is fastened and fixed.

Furthermore, the inner circumferential surface of the casing 112 is positioned on the outer circumferential surface of the rotary rings 136 and 136a fastened to the stepped surfaces 134 and 134a of the rotor 130 to support the rotor 130. Fixed rings 138 and 138a are fixedly supported.

At this time, the rotary ring 136, 136a is preferably coated on the surface or made of ceramic.

In addition, a coating member 140 is provided to coat the surface of the rotor 130, that is, the outer circumferential surface, the side surface, and the entire inner circumferential surface thereof.

At this time, the coating member 140 is formed of a tube of a synthetic resin material having good heat shrinkability is coated.

Alternatively, the coating member 140 may use a natural rubber material, the corrosion of the fluid by using any one of copper, aluminum, tin, zinc, copper, brass, white iron, stainless steel of the rotor The surface may be coated, and any coating means that does not generate corrosion or cyan by foreign fluid may be applied.

Therefore, by covering the entire surface of the rotor 130 with the coating member 140, when the rotor 130 made of a steel sheet of silicon material is exposed to the fluid cyan and corrosion occurs in the rotor 130 Can be prevented.

In addition, an impeller 210 which operates by the power of the motor unit 110 to allow the fluid to be sucked into the motor unit 110 and discharges the fluid sucked into the motor unit 110 is provided.

In other words, the impeller 210 allows the fluid to be sucked into the motor unit 110 and flows in one direction to be discharged in the other direction.

Here, the impeller 210 is fastened and fixed to the longitudinal side of the casing 112, that is, the opposite direction in which the inlet 116 is formed, the discharge port 214 for discharging the fluid introduced into the motor unit 110 is The impeller housing 212 is formed to be fastened and fixed by the fixing means in the opposite direction in which the inlet 116 of the casing 112 is formed.

At this time, the fixing means for fastening and fixing the impeller housing 212 to the casing 112 is preferably fixed using a bolt and a nut, but any means capable of fastening and fastening is applicable.

Further, the outlet 214 formed in the impeller housing 212 is preferably formed on the side to be in line with the flow path 132 of the rotor 130, but is formed to protrude outward on the outer peripheral surface of the impeller housing 212 You may.

In addition, an impeller 220 is provided at an inner side of the impeller housing 212, and the impeller 220 extends to form a rotating ring 136a fastened and fixed to the stepped surface 134a of the rotor 130. A portion 136b is formed and fastened to this extension 136b.

Here, the rotating ring 136a fastened and fixed to the rotor 130 forms an extension portion 136b in the rotating ring 136a fastened and fixed in the opposite direction of the inlet 116 so that the impeller 220 is fastened and fastened. Will be.

At this time, the impeller 220 is fastening hole 222 is formed in the center portion to be fastened and fixed to the extension portion (136b) of the rotary ring (136a).

In addition, the impeller 220 may be used by installing one or two or more depending on the use and capacity.

In addition, when the outlet 214 is formed on the outer circumferential surface of the impeller housing 212, one or two outlets 214 may be formed.

Referring to the operational relationship for the submersible motor pump according to the present invention configured as described above are as follows.

5 is a cross-sectional view showing the operation of the submersible motor pump according to the present invention.

As shown in the submersible motor pump 100 according to the present invention, when the power is first applied to the stator 120, the rotor 130 is rotated by the power applied to the stator 120.

At this time, the rotor 130 is securely supported by the fixing ring 138, 138a and the rotating ring 136, 136a, and at the same time the fixed impeller fastened fixed to the extension (136b) of the rotating ring 136a While 220 rotates in the same manner as the rotor 130, the external fluid is forced into the space 114 of the casing 112 by force.

That is, after connecting a hose or pipe to each of the inlet 116 of the casing 112 and the outlet 214 of the impeller housing 212 and then rotating the rotor 130 is fastened and fixed to the rotor 130 As the impeller 220 rotates together with the rotation rings 136 and 136a, the fluid is forcibly sucked into the casing 112 through the inlet 116, and the fluid sucked into the casing 112 is rotated. The fluid flows to the impeller 210 through the inner passage 132 of the 130, and the fluid moved to the impeller 210 is forcedly discharged through the outlet 214 formed in the impeller housing 212.

As the impeller 220 rotates due to the rotation of the rotor 130, the fluid sucked into the inside of the casing 112 flows in one direction by sucking the external fluid into the casing 112. In order to prevent the heat and friction generated in the 130 and the like to penetrate between the inner circumferential surface of the casing 112 and the rotor 130 to form a water film, this water film prevents friction generated when the rotor is rotated by this water film. At the same time to cool the heat generated.

At this time, the fluid sucked into the casing 112 is circulated by the operation of the impeller 220 to cool the heat generated from the stator 120 and the rotor 130, thereby improving the internal cooling effect of the casing 112. It can be greatly improved.

Then, by coating the surface of the rotor 130 using the coating member 140, formed into a steel sheet of silicon material by a fluid penetrating between the casing 112 and the rotor 130 to form a water film Preventing cyan and corrosion from occurring on the rotor 130 and improving wear resistance and durability at the same time.

6 is a cross-sectional view of another embodiment of the submersible motor pump according to the present invention.

As shown therein, the rotor blade 130 inner channel 132 of the submersible motor pump 100 according to the present invention is further provided with a screw blade 310 for forcibly sucking the external fluid.

Here, the screw blade 310 is provided with a fixing tube 312 is fixed to the flow path 132 of the rotor 130 by interference fit, a plurality of screw blades 314 on the inner peripheral surface of the fixing tube 312 Is provided.

At this time, when the screw blade 310 is provided on the inside of the rotor 130, the fixed tube 312 extends in the direction of the impeller 210, the impeller on the outer peripheral surface of the fixed fixed tube 312 formed By fastening and fixing the 220, the impeller 220 may be fastened and fixed to rotate when the rotor 130 is rotated.

The working relationship of the submersible motor pump according to the present invention configured as described above is made by the same method as in the former, and the description of the working relationship will be omitted here.

However, by further comprising a screw blade 310 in the inner flow path 132 of the rotor 130, the external fluid is forcibly sucked by the impeller 220 that rotates during the rotation of the rotor 130 At the same time, the screw blade 310 is rotated in the same manner as the rotor 130 to forcibly suck the external fluid by the screw blade 314 to force the external fluid to be sucked out more effectively It is possible to supply and drain the fluid.

In the above, a preferred embodiment of the submersible motor pump according to the present invention has been described, but the present invention is not limited thereto, and various modifications are made within the scope of the claims and the detailed description of the invention and the accompanying drawings. It is possible that this also belongs to the scope of the present invention

The present invention relates to an submersible motor pump, and more particularly, to a rotor exposed to a fluid when the impeller is rotated while the impeller is formed in a cylindrical shape and is fixed to a rotor made of a steel plate made of silicon. The present invention relates to an underwater motor pump coated with a rotor to prevent cyan from being generated.

1 is a cross-sectional view showing an underwater motor pump according to the present invention.

2 is an enlarged view of a portion A of FIG. 1;

Figure 3 is a perspective view of the rotor of the present invention.

4 is a cross-sectional view showing a rotor of the present invention.

Figure 5 is a cross-sectional view showing the operation of the underwater motor pump according to the present invention.

Figure 6 is a sectional view of another embodiment of the submersible motor pump according to the present invention.

[Description of Symbols for Main Parts of Drawing]

100: submersible motor pump 110: motor unit

112 casing 114 space part

116: suction port 120: stator

130: rotor 132: euro

134, 134a: stepped surface 136, 136a: rotating ring

136b: extension 138, 138a: retaining ring

140: coating member 210: impeller portion

212 impeller housing 214 outlet

220: impeller 310: screw wing

312: fixed tube 314: screw wing

Claims (15)

A motor unit generating power so that fluid is sucked inward; Underwater motor pump, characterized in that consisting of an impeller for forcibly suctioning and discharging the fluid by the power of the motor. The method of claim 1, The motor unit has a casing formed in the inner space, A stator fixed to an outer circumferential surface of the casing, Submersible motor pump, characterized in that the rotor is provided inside the casing to perform a rotation operation. The method of claim 2, The casing is formed in a cylindrical shape, the inlet is formed so that the fluid flows into one side, the other side motor pump, characterized in that the impeller is fastened and fixed. The method of claim 2, The rotor is formed in a cylindrical shape, the flow path is formed on the inside, the stepped surface is formed on each of both sides of the flow path, each of the stepped surface motor pump characterized in that the rotary ring is fastened and fixed. The method of claim 4, wherein Submersible motor pump, characterized in that each of the outer circumferential surface of the rotary ring is further fixed to the inner circumferential surface of the casing to guide the rotation of the rotor. The method of claim 4, wherein Submersible motor pump characterized in that the coating member is provided to cover the surface of the rotor to be sealed. The method of claim 6, The coating member is a submersible motor pump, characterized in that the synthetic resin material. The method of claim 6, Submersible motor pump, characterized in that the coating member is a natural rubber material. The method of claim 6, The coating member is an underwater motor pump, characterized in that any one of copper, aluminum, tin, zinc, copper, brass, white iron, stainless. The method of claim 4, wherein Submersible motor pump, characterized in that the screw blade portion is further provided in the flow path of the rotor. The method of claim 10, The screw blade portion is provided with a fixed tube is fixed to the flow path of the rotor, the inner motor surface of the water motor, characterized in that a plurality of screw blades are provided. The method of claim 1, The impeller portion is fastened and fixed to the longitudinal side of the casing, the impeller housing is provided with a discharge port for discharging the fluid, An underwater motor pump, characterized in that an impeller is provided inside the impeller housing. 13. The method of claim 12, The impeller is a motor submersible pump, characterized in that to form an extension member in the rotary ring provided on the inner side of the casing and fixed to the extension member. The method of claim 13, The outlet of the impeller housing is an underwater motor pump, characterized in that formed on the same line as the rotor flow path. The method of claim 13, The outlet of the impeller housing is an underwater motor pump, characterized in that formed on the outer peripheral surface of the impeller housing.

Images