KR102137318B1 - Pump for Circulating Water - Google Patents

Abstract

The hot water circulation pump according to the present invention includes a housing cover 10 having an inlet 11 and an outlet 12 for fluid; A housing 20 coupled to the housing cover 10 and including a stator core 21 therein; An impeller housing 30 installed inside the housing 20 and having an impeller receiving portion 31; An impeller 40 located in the impeller accommodating part 31 and having a central hole 41A in which a sleeve bearing 50 is installed in the center; A shaft 60 installed through the sleeve bearing 50; And a ring-shaped anti-vibration member 80 installed between the bottom surface of the central space 20A inside the housing 20 and the bottom surface outside the impeller housing 30.

Description

Hot water circulation pump {Pump for Circulating Water}

The present invention relates to a hot water circulation pump. More specifically, the present invention relates to a hot water circulation pump capable of preventing vibration and noise generated from an impeller during operation of the pump from being transmitted to a set in which the pump is installed.

In general, a low pressure boiler or a hot water mat is provided with a hot water circulation pump for circulating heated hot water. The same principle as the motor is applied to the hot water circulation pump, and the impeller including a rotor functions to discharge hot water flowing into the inlet through the outlet while rotating by electromagnetic interaction with the stator.

As a prior art for a hot water circulation pump, there is Korean Patent No. 10-1204344. In this prior art, hot water flowing into the inlet side formed on the top of the hot water circulation pump is discharged to the outlet formed on the side by the rotation of the impeller. On the other hand, the hot water flowing between the lower portion of the impeller and the inner housing moves upwards through a flow path formed vertically through the inner side of the impeller to be discharged from the inner side of the impeller blades together with the hot water flowing from the upper side to the outlet. Through these discharge holes, it is intended to ensure a stable rotation of the impeller and prevent the impeller from rising.

Meanwhile, in Korean Patent No. 10-1826600, a horizontal discharge hole communicating with the flow path is formed on the side of the impeller to achieve a more stable operation of the impeller.

In such a conventional hot water circulation pump, noise and vibration generated while the pump is operating are transmitted to a set in which the hot water circulation pump is installed. Since the hot water circulation pump is mainly used for a hot water mat, noise and vibration generated during sleep can be very sensitive to the user, and a problem occurs in that the quality of the hot water mat is deteriorated because it interferes with sound sleep.

Further, in the above-mentioned two prior arts, the impeller has a structure that is installed and rotates on a fixed shaft, and the impeller moves in the vertical direction by the pressure of the inflowing fluid. Due to this movement, noise and vibration may occur while the impeller hits the housing.

In order to solve this problem, the present inventors propose a new structure hot water circulation pump that can prevent vibrations generated from the hot water circulation pump from being transmitted to the set and prevent noise and vibration generated when the impeller moves up and down. .

An object of the present invention is to provide a hot water circulation pump that can prevent the noise and vibration generated during the operation of the impeller from being transmitted to the set.

Another object of the present invention is to provide a hot water circulation pump that can prevent noise and vibration caused by the movement of the impeller in the vertical direction.

The above object and other intrinsic objects of the present invention can be easily achieved by the present invention described below.

The hot water circulation pump according to the present invention

A housing cover 10 having an inlet 11 and an outlet 12 for fluid;

A housing 20 coupled to the housing cover 10 and including a stator core 21 therein;

An impeller housing 30 installed inside the housing 20 and having an impeller receiving portion 31;

An impeller 40 located in the impeller accommodating part 31 and having a central hole 41A in which a sleeve bearing 50 is installed in the center;

A shaft 60 installed through the sleeve bearing 50; And

A ring-shaped anti-vibration member 80 installed between the bottom surface of the central space 20A inside the housing 20 and the bottom surface outside the impeller housing 30;

It characterized in that it comprises a.

In the present invention, the anti-vibration member 80 may be installed in the insertion groove 20B formed on the bottom surface of the central space 20A inside the housing 20.

In the present invention, the anti-vibration member 80 is preferably installed in the seating groove 33 formed on the bottom surface outside the impeller housing 30.

In the present invention, the upper damper receiving portion (41B) formed on the upper portion of the central hole (41A) of the impeller (40) is located the upper damper (71), the lower damper formed in the center of the lower end of the impeller (40) It is preferable that the lower damper 72 is located in the receiving portion 41C.

In the present invention, the outer circumferential surface of the upper damper 71 is press-fitted to the inner circumferential surface of the upper damper receiving portion 41B, and the center hole of the upper damper 71 is press-fitted to the shaft 60 to be coupled. It is good.

In the present invention, the center hole of the lower damper 72 is press-fitted and coupled to the shaft 60, and the outer circumferential surface of the lower damper 72 is press-fit to the inner circumferential surface of the lower damper accommodating portion 41C. It is good.

The present invention can prevent the noise and vibration generated during the operation of the impeller from being transmitted to the set, and can prevent the noise and vibration generated as the impeller moves in the vertical direction, thereby increasing durability. It has the effect of the invention to provide a hot water circulation pump.

1 is a perspective view showing a hot water circulation pump according to the present invention.
2 is an exploded perspective view showing a hot water circulation pump according to the present invention.
3 is an exploded perspective view of the housing and the impeller cover of the hot water circulation pump according to the present invention.
4 is an exploded perspective view of the housing and the impeller cover of the hot water circulation pump according to the present invention.
5 is a cross-sectional view showing a hot water circulation pump according to the present invention.
6 is an exploded perspective view of a part of the configuration coupled to the impeller of the hot water circulation pump according to the present invention.
7 is an exploded perspective view of a part of a configuration coupled to the impeller of the hot water circulation pump according to the present invention.
Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing a hot water circulation pump 100 according to the present invention, and FIG. 2 is a perspective view showing a disassembled hot water circulation pump 100 according to the present invention. 1 and 2, the hot water circulation pump 100 according to the present invention includes a housing cover 10, a housing 20, an impeller housing 30, an impeller 40, a sleeve bearing 50 and a shaft. (60).

The housing cover 10 is coupled to the upper portion of the impeller housing 30 coupled to the housing 20. The inlet 11 through which the fluid flows is formed at the center and the top of the housing cover 10, and the outlet 12 is formed on the side of the housing cover 10. The fluid introduced into the inlet 11 is discharged to the outlet 12 by the operation of the impeller 40. The fluid flowing into the inlet 11 is installed symmetrically inside the inlet 11 and flows into the impeller 40 through a plurality of partitions 11A partitioning the interior space of the inlet 11. The partition wall 11A is formed in plural in the longitudinal direction to allow fluid to flow into the inlet 11, and an upper shaft coupling portion 11B is formed under the partition wall 11A.

The housing 20 has a stator core 21 installed therein. The upper insulator 22 and the lower insulator 23 are coupled to the upper and lower portions of the stator core 21. A coil (not shown) is wound on the stator core 21 and is electrically connected to the printed circuit board 24 coupled to the lower portion of the lower insulator 23. Power from the outside is applied to the printed circuit board 24 from the lead wire 26 connected to the external power through the connector 25. Preferably, the housing 20 of the present invention is a plastic resin by insert injection molding in a state where the stator core 21, the upper insulator 22, the lower insulator 23 and the printed circuit board 24 are placed in an injection mold. It is good to produce. The inner space of the housing 20 is the central space 20A, and the lower portion of the impeller housing 30 is located in the central space 20A.

The impeller housing 30 is coupled between the housing cover 10 and the housing 20. The impeller housing 30 has an impeller receiving portion 31 that is a space in which the impeller 40 is located. The lower shaft coupling portion 32 is formed in the center of the bottom surface of the impeller receiving portion 31 which is the inner space of the impeller housing 30. The lower end of the shaft 60 is coupled to the lower shaft coupling portion 32. In the present invention, the role of the impeller housing 30 may be performed by the housing 20 according to design needs. That is, the impeller housing 30 is not provided and the impeller 40 may be located inside the housing 20.

The impeller 40 is located in the impeller receiving portion 31 inside the impeller housing 30. The impeller 40 has an impeller body 41 accommodating the rotor 45 inside, and a plurality of impeller wings 42 formed on the upper part of the impeller 40. An impeller upper cover 43 is coupled to an upper portion of the impeller blades 42, and an impeller lower cover 44 is coupled to a bottom surface of the impeller body 41. The rotor 45 is preferably a ring-shaped magnet, fixed inside the impeller body 41, located inside the stator core 21, and rotated by interaction with a changing magnetic field when power is applied to the impeller 40 ).

A central hole 44A through which the shaft 60 penetrates is formed in the center of the lower cover 44 of the impeller, and a plurality of flow path holes 44B are formed in a symmetrical position around the central hole 44A. The flow path hole 44B flows fluid impregnated inside the impeller housing 30 into the impeller body 41 through the lower portion of the impeller 40, thereby causing the impeller 40 to flow in the vertical direction by the pressure of the fluid. It prevents.

The shaft 60 is installed through the impeller 40, and the upper and lower portions of the shaft 60 are fixed to the housing cover 10 and the impeller housing 30, respectively. A sleeve bearing 50 is press-fitted and coupled to the central hole 41A of the impeller 40. The sleeve bearing 50 is coupled to the fixed shaft 60 to support rotation of the impeller 40.

An upper damper receiving portion 41B is formed at the upper end of the central hole 41A. The upper damper accommodating portion 41B means a space at the upper end of the central hole 41A formed by penetrating in the vertical direction from the center of the impeller body 41. The upper damper 71 may be coupled to the upper damper receiving portion 41B to rotate around the shaft 60 or coupled to the shaft 60 to be fixed together with the shaft 60.

A lower damper accommodating portion 41C is formed in the lower end of the central hole 41A or the central hole 44A of the impeller lower cover 44. The lower damper accommodating portion 41C means a space at the lower end of the central hole 41A formed through a vertical direction from the center of the impeller body 41 or a space at the central hole 44A of the impeller lower cover 44. do. The lower damper 72 may be coupled to the lower damper receiving portion 41C to rotate around the shaft 60 or coupled to the shaft 60 to be fixed together with the shaft 60. More detailed configurations of the upper damper 71 and the lower damper 72 will be described again with reference to FIGS. 5 to 7.

The anti-vibration member 80 is inserted between the bottom surface of the central space 20A of the housing 20 and the bottom surface outside the impeller housing 30. The anti-vibration member 80 is installed to prevent noise and vibration generated when the impeller 40 is operated from being transmitted to the set in which the hot water circulation pump 100 is installed through the housing 20. The detailed configuration of the anti-vibration member 80 will be described with reference to FIGS. 3 to 5.

3 is an exploded perspective view of the housing 20 and the impeller housing 30 of the hot water circulation pump 100 according to the present invention, and FIG. 4 is a perspective view seen from below, and FIG. 5 is hot water according to the present invention It is a sectional view showing the circulation pump 100. 3 to 5, the anti-vibration member 80 is installed between the housing 20 and the impeller housing 30 of the hot water circulation pump 100 according to the present invention. The anti-vibration member 80 is not particularly limited as long as it is a member capable of absorbing vibration and noise, but it is preferable to use an elastic material such as rubber.

The anti-vibration member 80 may be inserted into the ring-shaped insertion groove 20B formed on the bottom surface of the central space 20A of the housing 20. Or it may be inserted into the ring-shaped seating groove 33 formed on the lower bottom surface of the outside of the impeller housing (30). The insertion groove 20B or the seating groove 33 may be formed of any one of them. That is, the dustproof member 80 may be provided by forming only the insertion groove 20B, or the dustproof member 80 may be provided by forming only the seating groove 33. FIG. 5 shows an embodiment in which there is no insertion groove 20B and only the seating groove 33 is formed.

6 is an exploded perspective view of the upper damper 71 and the lower damper 72 of the hot water circulation pump 100 according to the present invention, and FIG. 7 is a perspective view seen from below. 6 and 7, the upper damper 71 is located in the upper damper receiving portion 41B formed at the central upper side of the impeller body 41. The lower damper 72 is located in the lower damper receiving portion 41C formed at the central lower side of the impeller body 41.

The upper damper 71 and the lower damper 72 use an elastic material such as rubber, and the shapes of the upper damper 71 and the lower damper 72 have a ring shape having a circular through hole in the center. The upper damper 71 serves to absorb noise or vibration that may occur when the upper central portion of the impeller 40 collides with the upper shaft coupling portion 11B when the impeller 40 moves in the upper direction. The lower damper 72 serves to absorb noise or vibration that may occur when the lower central portion of the impeller 40 collides with the lower shaft coupling portion 32 when the impeller 40 moves in the lower direction.

The upper damper 71 may be coupled by a ring-shaped outer circumferential surface being pressed into the inner circumferential surface of the upper damper receiving portion 41B. At this time, the center hole portion of the ring shape is installed so as not to contact the shaft (60). Therefore, the upper damper 71 rotates with the impeller 40. In another embodiment, the upper damper 71 may be coupled by being pressed into the shaft 60. That is, the hole in the center of the upper damper 71 is pressed and fixed to the shaft 60, and the ring-shaped outer circumferential portion of the upper damper 71 is installed so as not to contact the inner circumferential surface of the upper damper receiving portion 41B. Therefore, even if the impeller 40 rotates, the upper damper 71 does not rotate.

Similarly, the lower damper 72 may be coupled by pressing the ring-shaped outer circumferential surface into the inner circumferential surface of the lower damper receiving portion 41C. At this time, the center hole portion of the ring shape is installed so as not to contact the shaft (60). Therefore, the lower damper 72 rotates with the impeller 40. In another embodiment, the lower damper 72 may be pressed into the shaft 60 and coupled. That is, the center hole of the lower damper 72 is press-fitted and fixed to the shaft 60, and the ring-shaped outer peripheral portion of the lower damper 72 is installed so as not to contact the inner circumferential surface of the lower damper receiving portion 41C. Therefore, even if the impeller 40 rotates, the lower damper 72 does not rotate.

It should be noted that the description of the present invention described above is merely an example for understanding the present invention, and is not intended to determine the scope of the present invention. The scope of the present invention is defined by the appended claims, and it should be understood that all simple modifications or changes within this range fall within the scope of the present invention.

10: housing cover 11: inlet
12: outlet 11A: bulkhead
11B: upper shaft coupling 20: housing
20A: center space 20B: insertion groove
21: stator core 22: upper insulator
23: lower insulator 24: printed circuit board
25: power connector 26: lead wire
30: impeller housing 31: impeller receiving portion
32: lower shaft engaging portion 33: seating groove
40: impeller 41: impeller body
41A: Central Hall 42: Impeller Wing
43: impeller upper cover 44: impeller lower cover
44A: Central Hall 44B: Euro Hall
45: rotor 50: sleeve bearing
60: shaft 71: upper damper
72: lower damper 80: anti-vibration member
100: hot water circulation pump

Claims (6)

delete A housing cover 10 having an inlet 11 and an outlet 12 for fluid;
A housing 20 coupled to the housing cover 10 and including a stator core 21 therein;
An impeller housing 30 installed inside the housing 20 and having an impeller receiving portion 31;
An impeller 40 located in the impeller accommodating part 31 and having a central hole 41A in which a sleeve bearing 50 is installed in the center;
A shaft 60 installed through the sleeve bearing 50; And
A ring-shaped anti-vibration member 80 installed between the bottom surface of the central space 20A inside the housing 20 and the bottom surface outside the impeller housing 30;
Including,
An upper damper 71 is located in the upper damper accommodating portion 41B, which is a space formed on the upper end side of the central hole 41A of the impeller 40, and a lower portion is a space formed in the center of the lower end of the impeller 40. The lower damper 72 is located in the damper receiving portion 41C,
The central hole of the upper damper 71 is press-fitted and fixed to the shaft 60, and the outer circumferential portion of the upper damper 71 is installed so as not to contact the inner circumferential surface of the upper damper accommodating portion 41B. 40) even if the upper damper 71 does not rotate,
The center hole of the lower damper 72 is press-fitted and fixed to the shaft 60, and the ring-shaped outer circumferential portion of the lower damper 72 is installed so as not to contact the inner circumferential surface of the lower damper receiving portion 41C. Even if the impeller 40 rotates, the lower damper 72 does not rotate,
In the center of the bottom surface of the impeller accommodating portion 31, a lower shaft coupling portion 32 to which the lower end of the shaft 60 is coupled is formed to protrude,
The anti-vibration member 80 is a hot water circulation pump, characterized in that installed in the insertion groove (20B) formed on the bottom surface of the central space (20A) inside the housing (20). A housing cover 10 having an inlet 11 and an outlet 12 for fluid;
A housing 20 coupled to the housing cover 10 and including a stator core 21 therein;
An impeller housing 30 installed inside the housing 20 and having an impeller receiving portion 31;
An impeller 40 located in the impeller accommodating part 31 and having a central hole 41A in which a sleeve bearing 50 is installed in the center;
A shaft 60 installed through the sleeve bearing 50; And
A ring-shaped anti-vibration member 80 installed between the bottom surface of the central space 20A inside the housing 20 and the bottom surface outside the impeller housing 30;
Including,
An upper damper 71 is located in the upper damper accommodating portion 41B, which is a space formed on the upper end side of the central hole 41A of the impeller 40, and a lower portion is a space formed in the center of the lower end of the impeller 40. The lower damper 72 is located in the damper receiving portion 41C,
The central hole of the upper damper 71 is press-fitted and fixed to the shaft 60, and the outer circumferential portion of the upper damper 71 is installed so as not to contact the inner circumferential surface of the upper damper accommodating portion 41B. 40) even if the upper damper 71 does not rotate,
The center hole of the lower damper 72 is press-fitted and fixed to the shaft 60, and the ring-shaped outer circumferential portion of the lower damper 72 is installed so as not to contact the inner circumferential surface of the lower damper receiving portion 41C. Even if the impeller 40 rotates, the lower damper 72 does not rotate,
In the center of the bottom surface of the impeller accommodating portion 31, a lower shaft coupling portion 32 to which the lower end of the shaft 60 is coupled is formed to protrude,
The anti-vibration member (80) is installed in a seating groove (33) formed on a bottom surface outside the impeller housing (30). delete delete delete

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