KR100884265B1 - Improved noiseless motor pump - Google Patents

Abstract

A noiseless motor pump improved to discharge the air is provided to prevent the generation of operating noise of a motor which pumps and circulates hot water and flux noise of the hot water when a user takes a rest on a hot water mat. A noiseless motor pump(1) includes a pump housing(20) having a pumping room(21). The pumping room includes a bubble discharging path(50) in a flow guide(27) formed in a round shape between an inner small diameter part(24) corresponding to the end of an inlet(22) and an inner large diameter part(26) adjacent to a packing groove in order to discharge bubbles.

Description

Improved noiseless motor pump

The present invention relates to a motor pump used for pumping and supplying fluids such as cold and hot water. In particular, the present invention is directly mounted on a heating hot mat using hot water as a heat source or installed in a hot water supply device for circulating hot water to a hot water mat. This prevents the operation noise of the motor or the flow rate noise of the hot water when pumping and supplying the hot water, so that the operation noise of the motor pump that pumps and circulates the hot water when the user sleeps or rests on the heating hot water mat, and the flow rate noise of the hot water is not generated. It relates to a noiseless motor pump improved.

As a conventional noiseless motor pump, a LAING (trade name) pump of a German company is known, which will be described with reference to the city of FIGS. 4 to 6, and the noiseless motor pump of the prior art includes a motor main body 10 and a pump housing 20. ) And the rotor 30 can be divided.

The motor body 10 is equipped with a plurality of iron core cores 12, each of which is wound around the coil 11, one end of the iron core core 12, the motor body 10 is the pump housing 20 is screwed Is connected to an electromagnet 13 having a hemispherical cross section at one side thereof, and at one side of the motor body 10 of the motor shaft 14 protruding toward the rotor 30 from the center of the electromagnet 13. The ceramic ball bearing 15 is formed at the end.

And the other side of the motor main body 10 has a structure in which a cover 17 for covering the condenser 16 is mounted, inside the cover 17 to the coil 11 mounted on the motor main body 10. The terminal block 18 for supplying electric current is formed.

The pump housing 20 of the pump housing 20 in a state in communication with the pumping chamber 21 formed in the inner side and the suction port 22 protruding outward from the center and one side of the pumping chamber 21. A discharge port 23 protruding to one side is provided.

The inner surface of the pump housing 20, which forms the pumping chamber 21, includes an inner small diameter portion 24 protruding toward the pumping chamber 21 from the inner end of the suction port 22, and around the inner small diameter portion. In the flow guide portion 25 is formed in an annular shape of a larger diameter and the inner diameter portion 26 of a larger diameter is formed around the flow guide, one side of the inner diameter portion 26 The discharge guide passage 27 is formed in communication with the discharge port 23, the packing groove 29 is formed on the outer periphery of the inner large diameter portion 26, the packing 28 is seated.

The rotor 30 is formed in a hemispherical cross section and is spaced apart from the inner surface of the electromagnet 13 of the motor body 10 at minute intervals, and at the center thereof, the motor shaft of the motor body 10 ( 14 is provided with a bearing hole rotatably supported by the ceramic ball bearing 15 formed at the end of the motor shaft 14, and the suction port 22 is provided at one side of the rotor 30. An impeller 31 for sucking water into the pumping chamber 21 and a cover plate 33 having a suction hole 32 through which water is sucked into the center of the impeller are formed.

The impeller 31 has a structure in which water is sucked into the center through the suction hole 32 and discharged to all sides.

The noiseless motor pump of the prior art configured as described above, when the power is applied to the motor main body 10, the rotor 30 is rotated, wherein the rotor 30 is the end of the motor shaft 14 of the motor main body 10 Since it rotates in a state of being supported in a very small size ceramic ball bearing 15 installed in the point contact state, the friction noise can be almost ignored, thereby providing an advantage of preventing the rotation noise of the rotor 30 from occurring. do.

The water sucked into the suction port 22 by the impeller 31 rotating together with the rotor 30 is sucked into the center of the impeller 31 through the suction hole 32, and then, in all directions by the rotational force of the impeller. The discharged water is discharged to the discharge port 23 through the discharge guide passage 27 formed on one side of the pumping chamber in a state in which the discharged water is collected throughout the pumping chamber 21.

However, as described above, bubbles (air) are generated in the water sucked into the pumping chamber 21 by the rotation operation of the impeller 31, and the bubbles are not discharged to the outlet 23 together with the water, and water is sucked in. The phenomenon of staying in the flow guide portion 25 formed between the inner small diameter portion 24, which is the end of the suction port 22, and the inner large diameter portion 26 adjacent to the packing groove 29 appears, Bubbles staying in the flow guide portion 25 acts as a resistance to block the flow of water sucked into the pumping chamber 21 toward the discharge guide passage 27 to slow the suction and discharge of water. In addition, when bubbles interfere with the flow of water, they generate noise (similar to the sound of an object hitting or rubbing), and the noise generated gradually increases over time. .

Therefore, when the conventional motor pump as described above is applied to the hot water mat for heating, it is difficult to expect a smooth circulation of hot water, and in particular, it is not possible to rest due to the noise generated in the pump housing 20 as well as to sleep comfortably. The inconvenience of not achieving this is followed.

Therefore, the present invention, even when the bubble is included in the water pumped into the pump housing by the impeller formed integrally with the rotor when applied to the heating hot water mat, etc. using the motor pump of the prior art as described above the bubble of the pump housing Improving the internal structure of the pump housing so that it can be discharged by moving to the outlet port according to the flow rate of the discharged water without being stagnated inside the pumping chamber, so that the water flows smoothly when the hot water is pumped and circulated by operating the motor pump. At the same time, the invention has been made for the purpose of providing a noiseless motor pump that does not generate water flow noise in the pump housing.

The present invention as a means for achieving the above object,

A plurality of iron core cores disposed at an isometric angle, a coil wound around each of the iron core cores, a capacitor formed by overlapping a plurality of iron plates, and a hemispherical cross section electrically connected to one end of the plurality of iron core cores. A motor body having a formed electromagnet, a motor shaft protruding toward the center of the electromagnet, and a ceramic ball bearing formed at an end of the motor shaft;

A rotor formed on one side of the motor body in a hemispherical cross section such as an electromagnet so as to be rotatably supported by the ceramic ball bearing while being spaced at a minute interval from the electromagnet;

An impeller formed integrally with the rotor and pumping water while rotating together when the rotor rotates;

A suction port for guiding suction of water to the central portion of the impeller, a pumping chamber rotatably receiving the impeller, a discharge guide passage formed at one side of the pumping chamber, and the suction port connected to the discharge guide passage; A motor pump having a discharge port protruding in a direction perpendicular to each other, the pump housing being detachably coupled to one side of the motor main body to cover the rotor and the impeller.

An inner surface of the pumping chamber of the pump housing is formed by forming a bubble discharge passage in an annular flow guide portion formed between the inner small diameter portion, which is the end of the suction port, and the inner large diameter portion adjacent to the packing groove, in order to discharge the bubbles. It features.

In addition, the bubble discharge passage is characterized by consisting of a plurality of linear guide passages formed at regular intervals between the inner small diameter portion and the inner large diameter portion, and the annular guide passage connecting the middle portion of the plurality of linear guide passages. .

In addition, the plurality of linear guide passages formed in the bubble discharge passage is formed in a tangential direction from the inner small diameter portion to the inner large diameter portion, the tangential direction is formed to have a slope toward the rotation direction of the impeller. .

In addition, the inner large diameter portion is characterized in that the starting point in the direction in which the impeller is rotated relative to the discharge guide passage is formed as a spiral passage gradually lowered toward the end point.

In addition, the impeller on one side of the rotor is characterized in that it is formed in an open state in the pumping chamber.

The present invention is configured to rotate in a state in which the rotor is supported by a ceramic ball bearing formed at the end of the motor shaft of the motor body, as in the conventional motor pump, so that noise caused by the rotation operation of the rotor is not generated. When the pumped water is sucked into the pumping chamber by the impeller rotating together with the rotor, even if bubbles are sucked together or newly formed, the air bubbles can be discharged quickly, thereby preventing the flow velocity of water caused by the air bubbles in the pump housing. Provided is a noiseless motor pump having the effect of pumping and supplying hot water without generating rotation noise of the rotor and pumping noise of the impeller.

Specific embodiments of the noiseless motor pump according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view of a motor pump for explaining the present invention, Figure 2 is a cross-sectional view of the pump housing of the present invention, Figure 3 is a front view of the pumping chamber for showing the bubble discharge passage formed on the inner surface of the pump housing of the present invention. It is.

Reference numeral 1 denotes a motor pump, and in describing each component of the motor pump 1, the same components as those of the conventional motor pump will be described using the same names and the same reference numerals.

The motor pump 1 is divided into a motor body 10, a pump housing 20, and a rotor 30, and each component thereof will be briefly described.

The motor body 10 is formed in a hemispherical shape is connected to one end of each of the iron core cores, and a plurality of iron core core 12, each coil coil 11 is wound as in the prior art, and one side of the motor body 10 A plurality of electromagnets 13 and a motor shaft 14 protruding toward the rotor 30 and a ceramic ball bearing 15 formed at the end thereof.

In addition, the cover 17 for covering the condenser 16 is mounted on the other side of the motor main body 10, and the terminal block 18 mounted inside the cover 17 has an electric wire for supplying power from the outside. Connected.

The pump housing 20 has a suction port 22 protruding outward from the center of the pumping chamber 21 so as to communicate with the center of the pumping chamber 21 formed therein so as to be perpendicular to the suction port. The protruding outlet 23 communicates with one side of the pumping chamber 21 by the discharge guide passage 27.

The inner surface of the pumping chamber 21 has a flow guide portion 25 and an inner side toward the packing groove 29 based on the inner small diameter portion 24 protruding toward the pumping chamber 21 from the inner end of the suction port 22. The large diameter part 26 is formed in order.

The pump housing 20 is detachably screwed to one side of the motor body 10 by the fastener 40.

The rotor 30 is rotatably supported by the ceramic ball bearing 15 so as to be spaced apart from the inner surface of the plurality of electromagnets 13 formed on one side of the motor body 10 at a minute interval, and each of the electromagnets It is configured to rotate by magnetic force having different polarity at.

An impeller 31 for sucking water into the pumping chamber 21 is formed at one side of the rotor 30, and the impeller 31 is pumped except for a part attached to the cross-sectional side of the rotor 30. The chamber 21 is formed in an open state.

The present invention is characterized in that air bubbles are sucked into the water sucked into the pumping chamber 21 of the pump housing 20 by the rotation operation of the impeller 31 integrally formed with the rotor 30 when the motor pump 1 is driven. Even if bubbles are generated in the water when they are included or pumped by the impeller 31, the bubbles contained in the mole do not appear to stay inside the pumping chamber 21 and are discharged quickly together with the water. 21) is to allow the flow rate of water to be quietly discharged without generating.

To this end, the bubble discharge passage 50 is formed on the inner surface of the pumping chamber 21 of the pump housing 20, the bubble discharge passage 50 is a straight line in the tangential direction around the outer circumference of the inner small diameter portion (24) It consists of a plurality of linear guide passages 51 formed in an upper shape, and an annular guide passage 52 connecting the middle portions of the linear guide passages 51 described above.

Further, since the plurality of linear guide passages 51 formed in the tangential direction around the outer circumference of the inner small diameter portion 24 are formed to have an inclination toward the rotational direction of the impeller 31, these linear guides By the passages 51, the bubble discharge passage 50 is shaped like a pinwheel.

On the other hand, the inner large diameter portion 26 formed in the pump chamber 21 of the pump housing 20 has a direction in which the impeller 31 rotates when viewed in the drawing (see FIG. 3) with reference to the discharge guide passage 27. The starting point S is high and the ending point F is formed spirally so as to be in a low state. That is, the impeller 31 is formed in a spiral that gradually decreases toward the end point F toward the direction in which the impeller 31 rotates in the state where the starting point S is formed high. When the water sucked by the rotational force of the discharged in all directions, the centrifugal force along the inner large diameter portion 26 formed in a spiral acts spirally so that the water is quickly discharged into the discharge guide passage 27.

In the motor pump 1 of the present invention configured as described above, when the power is supplied to the motor main body 10 as in the conventional motor pump, the electromagnet 13 has a magnetic force, and thus the rotor supported by the ceramic ball bearing 15. 30 is rotated, wherein the rotor 30 is rotated in a state that does not generate friction noise.

When the rotor 30 rotates, a suction force is generated at the center of the impeller 31 which rotates with the rotor 30. Accordingly, the water sucked from the suction port 22 is sucked into the center of the impeller 31 and is provided through four sides. The flow guide part 25 around the inner small diameter part 24 which is discharged into the pumping chamber 21 and the air bubbles contained in the water pumped into the pumping chamber 21 as described above is the inner end of the suction port 22. In this case, the bubbles collected in the flow guide portion 25 are moved toward the inner diameter portion 26 formed in a spiral shape by the bubble discharge passage 50. That is, since the plurality of linear guide passages 51 constituting the bubble discharge passage 50 are formed in a tangential direction having a slope toward the rotational direction of the impeller 31 from the circumferential portion of the inner small diameter portion 24, When bubbles scattered in one flow guide portion 25 are located in the plurality of linear guide passages 51 or the annular guide passages 52, the bubbles located in each of the guide passages 51 and 52 described above. They are quickly moved toward the inner large diameter portion 26 by the action of swirling the water clockwise by the rotation operation of the impeller 31, the inner large diameter portion 26 is the direction in which the impeller 31 rotates Since it is formed in a spiral toward the air bubbles moved to the inner large diameter portion 26 is introduced into the discharge guide passage 27 along the flow rate flowing in the spiral from the inner large diameter portion 26, the discharge guide passage 27 in this way ) Yu Bubbles is discharged through the outlet 23.

In addition, since the impeller 31 is formed in an open state toward the inner surface of the pumping chamber 21 in which the bubble discharge passage 50 is formed, the impeller 31 and the pumping chamber 21 by the rotation operation of the impeller 31. ) Bubbles in the flow guide portion 25 are rapidly moved along the straight guide passage 51 due to the phenomenon that water existing between the inner surfaces is spirally diffused from the inner small diameter portion 24 side toward the inner large diameter portion 26. The large diameter portion 26 is moved, and thus the bubbles moving toward the inner large diameter portion 26 are discharged through the discharge guide passage 27 along with the water flowing spirally from the inner large diameter portion 26. To be discharged.

As described above, bubbles that are present in the water pumped into the pumping chamber 21 of the pump housing 20 by the impeller 31 do not stay in the flow guide 25 of the inner surface of the pumping chamber 21. The bubble discharge passage 50 formed in the guide portion 25 moves toward the inner large diameter portion 26 and flows into the flow rate and the discharge guide passage 27 in a spiral manner to the inner large diameter portion 26. By being discharged to 23, bubbles are not present in the pumping chamber 21.

Therefore, the motor pump 1 has no rotational noise of the rotor 30 when the motor body 10 is driven, and the water sucked in the inlet by the impeller 31 is discharged to the outlet 23 without generating the flow velocity noise. When the motor pump (1) of the present invention is applied to a heating hot water mat for circulating hot water, the operation noise of the motor and the flow rate noise of the hot water are not generated when the hot water is circulated on the hot water mat, so that the user sleeps in a quiet atmosphere. Ask for help or take a break.

1 is a cross-sectional view of a motor pump for explaining the present invention.

2 is a cross-sectional view of the pump housing of the present invention.

Figure 3 is a front view of the pumping chamber for showing the bubble discharge passage formed on the inner surface of the pump housing of the present invention.

Figure 4 is a cross-sectional view of the motor pump assembled state of the prior art.

5 and 6 are a front view showing the pump housing cross-sectional view and the inner surface of the pumping chamber of the conventional motor pump.

※ Explanation of code for main part of drawing

1: motor pump 10: motor body

11: coil 12: iron core

13: electromagnet 14: motor shaft

15 ceramic ball bearing 20 pump housing

21: pumping chamber 22: suction port

23: outlet 24: inner small diameter portion

25: flow guide portion 26: the inner large diameter portion

27: discharge guide passage 30: rotor

31 impeller 40 fastener

50: bubble discharge passage 51: straight guide passage

52: annular guide passage

Claims (5)

A plurality of iron core cores disposed at an isometric angle, a coil wound around each of the iron core cores, a capacitor formed by overlapping a plurality of iron plates, and a hemispherical cross section electrically connected to one end of the plurality of iron core cores. A motor body having a formed electromagnet, a motor shaft protruding toward the center of the electromagnet, and a ceramic ball bearing formed at an end of the motor shaft; A rotor formed on one side of the motor body in a hemispherical cross section such as an electromagnet so as to be rotatably supported by the ceramic ball bearing while being spaced at a minute interval from the electromagnet; An impeller formed integrally with the rotor and pumping water while rotating together when the rotor rotates; A suction port for guiding suction of water to the central portion of the impeller, a pumping chamber rotatably receiving the impeller, a discharge guide passage formed at one side of the pumping chamber, and the suction port connected to the discharge guide passage; A motor pump having a discharge port protruding in a direction perpendicular to each other, the pump housing being detachably coupled to one side of the motor main body to cover the rotor and the impeller. An inner surface of the pumping chamber of the pump housing is formed by forming a bubble discharge passage in an annular flow guide portion formed between the inner small diameter portion, which is the end of the suction port, and the inner large diameter portion adjacent to the packing groove, in order to discharge the bubbles. Noiseless motor pump, improved to release the air features. The method of claim 1, The air bubble passage comprises a plurality of linear guide passages formed at regular intervals between the inner small diameter portion and the inner large diameter portion, and the annular guide passage connecting the middle portions of the plurality of linear guide passages. Noiseless motor pump modified to drain. The method according to claim 1 or 2, The plurality of linear guide passages formed in the bubble discharge passage are formed in a tangential direction from the inner small diameter portion to the inner large diameter portion, and the tangential direction is formed to have an inclination toward the rotation direction of the impeller. Noiseless motor pump modified to drain. The method of claim 1, The inner large diameter portion is a noiseless motor pump improved to discharge the air characterized in that the starting point in the direction in which the impeller is rotated relative to the discharge guide passage is formed as a spiral passage gradually lowered toward the end point. The method of claim 1, An improved noiseless motor pump capable of discharging air, wherein the impeller on one side of the rotor is formed in an open state in the pumping chamber.

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