KR20200027385A - Water pump - Google Patents

Abstract

According to the present invention, a water pump comprises: an upper housing in which a suction port and a discharge port of a fluid are formed; a lower housing coupled to the lower side of the upper housing; an impeller assembly installed to be rotatable in a vertical direction as an axial direction in an inner space formed by coupling the upper and lower housings to each other, and including an impeller for suctioning the fluid to the suction port and discharging the fluid to the discharge port and a rotor; a stator assembly coupled to the lower side of the lower housing, configured to provide an accommodation space in which at least a portion of the lower housing is accommodated, and including a stator corresponding to the rotor; and a vibration absorbing pad disposed between the lower housing and the stator assembly to reduce vibration generated by at least one of the lower housing and the stator assembly.

Description

Water pump {WATER PUMP}

The present invention relates to a water pump, and more particularly, to a water pump with reduced vibration and noise.

In general, centrifugal pumps are frequently used as a water pump that sucks water through an inlet and discharges water through an outlet.

An example of using such a water pump is a hot water mat. A heating apparatus such as a hot water mat is equipped with a small hot water boiler that generates and supplies hot water, and a water pump for circulating the generated hot water onto a pipe.

The water pump is configured to rotate the impeller provided with a rotor by electromagnetic induction of the stator and the rotor to suck the fluid through the suction port and discharge the fluid through the centrifugal force.

However, when the water pump is driven, the impeller rotates to generate vibration, and noise is generated along with the vibration. Particularly, in the case of a water pump used in a hot water mat, it is used at a short distance from a user, and thus, inconvenience caused by generated vibration and noise is large.

Prior art related to this has disclosed a technique for reducing the occurrence of vibration by reducing the occurrence of cavitation when the impeller in the water pump rotates.

Nevertheless, vibration and noise of the water pump are inevitably generated, and an improved structure is needed to reduce this.

An object of the present invention is to effectively reduce vibration and noise generated in a water pump.

The problems of the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, the water pump according to an embodiment of the present invention, the upper housing is formed with a fluid inlet and outlet; A lower housing coupled to a lower side of the upper housing; In the inner space formed by the combination of the upper and lower housings, the impeller assembly including a rotor and an impeller for rotatable installation in the vertical direction in the axial direction to suck fluid into the suction port and discharge it to the discharge port Wow; A stator assembly coupled to a lower side of the lower housing, providing an accommodation space in which at least a portion of the lower housing is accommodated, and including a stator corresponding to the rotor; In order to reduce vibration generated by at least one of the lower housing and the stator assembly, an anti-vibration pad is disposed between the lower housing and the stator assembly.

In order to achieve the above object, the water pump according to an embodiment of the present invention, the upper housing is formed with a fluid inlet and outlet; A lower housing assembly coupled to a lower side of the upper housing and including a stator; The inner space formed by the combination of the upper housing and the lower housing assembly is rotatably installed in the up and down direction in the axial direction, the impeller for sucking fluid through the suction port and discharging it to the discharge port, and corresponding to the stator An impeller assembly including a rotor; A shaft which is installed in the inner space to penetrate the impeller assembly in a direction corresponding to the axial direction, and has upper and lower ends supported by the upper and lower housing assemblies; And a shaft cap provided to reduce vibration generated by at least one of the shaft and the upper housing.

The upper housing includes a cup-shaped upper housing body and a shaft upper support portion provided inside the upper housing body to support the upper end of the shaft, and the shaft cap is between the shaft upper support portion and the shaft. Is intervened in.

In order to achieve the above object, the water pump according to an embodiment of the present invention, the upper housing is formed with a fluid inlet and outlet; A lower housing assembly coupled to a lower side of the upper housing and including a stator; The inner space formed by the combination of the upper housing and the lower housing assembly is rotatably installed in the up and down direction in the axial direction, the impeller for sucking fluid through the suction port and discharging it to the discharge port, and corresponding to the stator An impeller assembly including a rotor; A shaft which is installed in the inner space to penetrate the impeller assembly in a direction corresponding to the axial direction, and has upper and lower ends supported by the upper and lower housing assemblies; Vibration generated by at least one of the impeller assembly and the lower housing is reduced by the lower anti-vibration packing, including a lower anti-vibration packing disposed between the impeller assembly and the lower housing and through which the shaft passes.

In order to achieve the above object, the water pump according to an embodiment of the present invention, the upper housing is formed with a fluid inlet and outlet; A lower housing assembly coupled to a lower side of the upper housing and including a stator; The inner space formed by the combination of the upper housing and the lower housing assembly is rotatably installed in the up and down direction in the axial direction, the impeller for sucking fluid through the suction port and discharging it to the discharge port, and corresponding to the stator An impeller assembly including a rotor; A shaft which is installed in the inner space to penetrate the impeller assembly in a direction corresponding to the axial direction, and has upper and lower ends supported by the upper and lower housing assemblies; In order to reduce vibration generated by at least one of the impeller assembly and the upper housing, an upper dustproof packing is provided.

The upper housing includes a cup-shaped upper housing body and a shaft top support provided inside the upper housing body to support the upper end of the shaft.

The upper anti-vibration packing is disposed between the impeller assembly and the upper housing body and the shaft is penetrated.

According to an embodiment of the present invention, there are one or more of the following effects.

First, by including an anti-vibration pad between the lower housing and the stator assembly, vibration and noise generated by at least one of the lower housing and the stator assembly are reduced.

Second, by including a shaft cap interposed between the shaft top support and the shaft, there is an effect of reducing vibration and noise generated by at least one of the shaft and the upper housing.

Third, the vibration generated by at least one of the impeller assembly and the upper housing is reduced by the upper anti-vibration packing, and the vibration generated by at least one of the impeller assembly and the lower housing is reduced by the lower anti-vibration packing. .

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will become apparent to those skilled in the art from the description of the claims.

1 is a perspective view of a water pump according to an embodiment of the present invention.
FIG. 2 is an exploded perspective view of the water pump of FIG. 1.
3 is a longitudinal sectional view of the water pump of FIG. 1.
4 is an exploded perspective view of a part of the configuration of the water pump of FIG. 1.
5 is an exploded perspective view of a water pump according to another embodiment of the present invention.
6 is a longitudinal sectional view of the water pump of FIG. 5.

Hereinafter, some embodiments of the present invention will be described in detail through exemplary drawings. In adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are assigned to the same components as much as possible even though they are shown in different drawings. In addition, in describing the embodiments of the present invention, when it is determined that the detailed description of the related well-known configuration or function interferes with the understanding of the embodiments of the present invention, the detailed description thereof will be omitted.

In the following, "up / down" is defined as indicated in the figure. However, this is only for convenience of description, and unlike this, “up / down” may be defined.

1 is a perspective view of a pump according to an embodiment of the present invention, Figure 2 is an exploded perspective view of the pump of Figure 1, Figure 3 is a longitudinal sectional view of the pump of Figure 1, Figure 4 is in the configuration of the pump of Figure 1 Here is a partial exploded perspective view.

The water pump 100 according to the present embodiment includes an upper housing 10, a lower housing 20, an impeller assembly 30, a stator assembly 40, and a dustproof member 70.

The water pump 100 according to this embodiment is provided in a hot water mat and can be used to circulate hot water. However, the present invention is not limited thereto, and the water pump 100 according to the present exemplary embodiment may be used to inhale and discharge a liquid or gas, which may be applied to various fields that a person skilled in the art can think of.

It is preferable that the water pump has low vibration or noise. However, in the conventional pump, when the impeller is rotated and driven at high speed, the rotation of the impeller is disturbed due to a pressure difference inside the pump, and the flow of the flow is not smooth, resulting in noise or vibration.

The present invention relates to a water pump that can further reduce noise and vibration. More specifically, the water pump according to the present embodiment includes a rotating body (impeller assembly 30, bushing 35, etc.) and a fixed body (upper and lower housing 10, 20), stator assembly 40, shaft ( 50), etc., in order to reduce vibration generated by at least one of the basic features of including the anti-vibration member (70). That is, the water water pump 100 according to the present embodiment has a basic feature in that it includes an anti-vibration member 70 to reduce vibration transmitted between the rotating body and the fixed body.

The characteristics of the water pump 100 according to this embodiment will be described in more detail below.

The upper housing 10 is formed with a fluid inlet 11 and outlet 12. The upper housing 10 includes a cup-shaped upper housing body 13 and an upper housing edge portion 14 extending from the edge of the upper housing body 13.

The intake port 11 may be formed to extend outwardly in the center of the upper housing body 13. The inlet 11 may be formed to protrude upward in the form of a pipe in the center of the upper housing body 13.

The outlet 12 may be formed to extend outwardly on the side surface of the upper housing body 13. The outlet 12 may be formed to protrude in the form of a pipe on the side of the upper housing body 13. The outlet 12 may be formed to extend in a direction corresponding to a tangential direction contacting a side surface of the upper housing body 13 to guide the fluid discharged by the impeller 31 to the outside of the water pump 100. .

The upper housing 10 has a shaft top support 15 provided in the inner space S of the upper housing body 13 and a flange portion (not shown) connecting the shaft top support 15 and the upper housing body 13 ).

The shaft top support 15 may be provided at a position overlapping the suction port 11 vertically. That is, the shaft top support 15 may be provided at a position where fluid flowing into the suction port 11 meets when it flows into the upper housing 10. In other words, when the water pump 100 is viewed from the upper side, the shaft top support 15 may be located at a position visible when the inside of the water pump 100 is viewed through the suction port 11.

In order to minimize the flow resistance received by the fluid flowing into the inlet 11, the shaft top support 15 is connected to the upper housing body 13 by a plurality of flanges, and from the top to the bottom of the shaft top support 15 It may be formed in a shape that increases in cross-section.

The shaft top support 15 may be composed of an upper portion having a cross-sectional area and a lower portion formed in a cup shape.

The upper portion of the shaft upper support portion 15 is formed in a shape in which a cross-sectional area becomes larger from a side closer to a side farther away from the suction port 11, so that the flow resistance received by the fluid flowing through the suction port 11 can be minimized.

The lower portion of the shaft upper support portion 15 is formed in a cup shape opened downward, so that the shaft 50 and the shaft cap 72 to be described later can be inserted and coupled.

The lower housing 20 may be disposed to be coupled to the lower side of the upper housing 10 to be coupled. The lower housing 20 may be combined with the upper housing 10 to provide an inner space S in which the impeller assembly 30 is accommodated.

The lower housing 20 may include a lower housing body 21 and a lower housing edge portion 22 extending from an edge of the lower housing body 21.

The lower housing body 21 is formed in a cup shape opened upward, and may provide an accommodation space in which the impeller assembly 30 is accommodated.

The lower housing 20 may include a lower housing outer protrusion 23 protruding from the lower center of the lower housing body 21 to the outside (or lower side) of the lower housing body 21.

The lower housing 20 may include a shaft lower support 24 protruding from the lower center of the lower housing body 21 to the inside (or upper side) of the lower housing body 21.

The shaft lower support portion 24 may be provided in a shape in which a groove is formed in the center and the groove periphery protrudes toward the inner space of the lower housing 20.

The shaft lower support portion 24 is a shaft 50 is inserted a predetermined length to form a groove in the center to firmly support the shaft 50, the portion in which the groove is formed to maintain the rigidity of the lower housing 20 Even the thickness of the housing wall must be kept above a certain thickness. To this end, the lower housing 20 forms a lower housing outer protrusion 23 protruding downward from the lower center of the lower housing body 21, and is also lowered in a portion where a groove is formed in the center of the shaft lower support 24 The thickness of the housing 20 may be maintained above a predetermined thickness.

The lower housing 20 may include a guide rib 25 having a shape protruding downward from an edge of a lower end of the lower housing body 21. The guide rib 25 may guide the position where the anti-vibration pad 71 will be described later. In addition, the guide rib 25 can prevent the dust pad 71 from being displaced.

The length at which the guide rib 25 protrudes may be shorter than the vertical distance between the lower housing 20 and the stator assembly 40. That is, the length at which the guide rib 25 protrudes is formed to be shorter than the separation distance between the bottom surface of the stator assembly receiving portion 42 to be described later and the lower portion of the lower housing body 21, so that the lower housing body 21 is the stator assembly. Direct contact with the bottom surface of the receiving portion 42 and vibration can be prevented from being transmitted.

The impeller assembly 30 may be rotatably installed in the inner space S formed by the coupling of the upper and lower housings 10 and 20 in the axial direction. The impeller assembly 30 may be rotated in the axial direction with a direction extending in the vertical direction past the center of the shaft 50.

The impeller assembly 30 may include an impeller 31 and a rotor 32. The impeller assembly 30 includes a cylindrical impeller body 30a, an impeller 31 connected to the upper side of the impeller body 30a, and a rotor 32 installed on the side of the impeller body 30a. You can.

The impeller 31 may be arranged around a cylindrical space in the center, and a plurality of wing pieces may be arranged in a circumferential direction. When the impeller assembly 30 rotates, the blade pieces suck fluid through the suction port 11 and push the fluid through the discharge port 12 to discharge the fluid. To this end, the wing pieces may be formed with a curved side surface.

The upper cover of the impeller is connected to the upper surface of the plurality of wing pieces, so that the fluid flowing into the impeller 31 through the suction port 11 is not dispersed and can be effectively discharged to the discharge port 12.

The shaft upper support portion 15 may be partially accommodated in the central cylindrical space of the impeller 31. The lower portion of the shaft top support 15 is accommodated in a cylindrical space in the center of the impeller 31, and can be combined with the shaft 50 to be described later.

The impeller 31 may include a rotor 32 accommodated in a rotor accommodating portion connected to a side surface of the impeller body 30a. The rotor 32 may be formed of a permanent magnet, and by forming a magnetic field with the stator 41 to be described later, the driving force may be provided by electromagnetic induction to rotate the impeller assembly 30.

The rotor 32 may be provided in a donut shape having a predetermined thickness in the radial direction of rotation and a predetermined length in the vertical direction.

The impeller assembly 30 may include a shaft hole 33 formed to penetrate the impeller assembly 30 up and down. The impeller assembly 30 is disposed coaxially with the shaft hole 33 and may include a bearing receiving groove formed with a larger diameter than the shaft hole 33. The impeller assembly 30 may include a bearing accommodated in a bearing receiving groove.

In this embodiment, the bearing is a bushing 35, and the bearing receiving groove will be described as an example of a bushing receiving groove 34. However, the present invention is not limited thereto, and various types of bearings may be used instead of the bushing 35.

The shaft hole 33 may be formed by penetrating the impeller body 30a of the impeller assembly 30 up and down. The shaft hole 33 may be formed to have a size corresponding to the diameter of the shaft 50 so that the shaft 50 to be described later passes through.

The bushing receiving groove 34 is formed coaxially with the shaft hole 33 but is formed with a larger diameter than the shaft hole 33 so that the bushing 35 can be inserted between the shaft 50 and the impeller body 30a. Can be prepared.

The bushing receiving groove 34 may be formed to have a length corresponding to the length of the bushing 35.

The bushing 35 may be inserted into the bushing receiving groove 34 and combined with the impeller body 30a. The bushing 35 may be pressed into the bushing receiving groove 34 and combined.

The weight of the rotor 32 among the total weight of the impeller assembly 30 is high. Since the rotor 32 is made of a permanent magnet, it can be made heavy compared to the rest of the impeller assembly 30 made of plastic or the like. Therefore, the center of gravity of the impeller assembly 30 is at the lower side where the rotor 32 is located, and the rotation moment generated by the rotor 32 when the impeller assembly 30 is rotated is the rest of the impeller assembly 30. It can be relatively large. Accordingly, in order to reduce the vibration of the impeller assembly 30, it is effective to reduce the vibration generated by the rotor 32.

To this end, in this embodiment, the position of the bushing 35 is formed to extend vertically based on the rotor 32. Specifically, by providing the bushing 35 to extend from the upper inlet end of the bushing receiving groove 34 to lower than the middle of the upper and lower ends of the rotor 32, vibration in the rotational radial direction of the impeller assembly 30 is provided. Can be reduced. Referring to FIG. 3, the bushing 35 extends from the upper inlet end of the bushing receiving groove 34 to the lower side of the lower end of the rotor 32, so that vibration of the impeller assembly 30 can be provided to be more effectively reduced. .

In one embodiment, the bushing 35 may be provided such that the upper end extends at least above the upper end of the rotor 32 and the lower end extends at least below the lower end of the rotor 32. The impeller assembly when the bushing 35 of the same length is positioned closer to the bottom of the impeller assembly 30 where the rotor 32 is located than when the bushing 35 of the same length is placed closer to the top of the impeller assembly 30 The occurrence of vibration due to 30 can be further reduced.

The stator assembly 40 is coupled to the lower side of the lower housing 20 and may provide an accommodation space in which at least a portion of the lower housing 20 is accommodated. The stator assembly 40 may include a cup-shaped stator assembly accommodating portion 42 opened upward.

Meanwhile, the stator assembly 40 and the lower housing 20 may also be defined as a lower housing assembly 20 and 30.

The stator assembly accommodating portion 42 has a side portion of the stator assembly accommodating portion 42 that contacts the side portion of the lower housing body 21, and a state assembly accommodating portion 42 having a surface facing each other with a lower end portion of the lower housing body 21. ).

The lower housing 20 and the stator assembly 40 may be coupled such that the lower end portion of the lower housing body 21 and the bottom surface of the stator assembly receiving portion 42 are spaced apart from each other. That is, the lower housing body 21 is formed when the length in the vertical direction is shorter than the length in the vertical direction of the stator assembly receiving portion 42, and when the lower housing body 21 is inserted into the receiving space of the stator assembly 40 for a certain length, the lower Housing edge portion 22 is seated on the top of the stator assembly 40, the lower surface of the lower housing body 21 and the bottom surface of the stator assembly receiving portion 42 may be coupled to be spaced apart from each other.

The stator assembly 40 may further include a stator assembly depression 43 in which at least a portion of the lower housing outer protrusion 23 is accommodated further from the bottom of the accommodation space.

A stator assembly depression 43 having a shape recessed downward may be formed at the center of the stator assembly receiving portion 42.

The stator 41 may be installed at a corresponding position for electromagnetic induction with the rotor 32. The stator 41 is supplied with power from the outside to form a magnetic field with the rotor 32, and serves to provide a driving force so that the impeller assembly 30 rotates in a certain direction.

The stator 41 may include a stator core and a core support member for supporting the stator core.

The shaft 50 is installed in the inner space S to penetrate the impeller assembly 30 in a direction corresponding to the axial direction, and upper and lower ends may be supported by the upper and lower housings 10 and 20. The shaft 50 may be supported by being inserted into the shaft upper support portion 15 and supported by being inserted into the shaft lower support portion 24.

In this embodiment, the upper and lower ends of the shaft 50 are fixed to the upper and lower housings 10 and 20, and the impeller assembly 30 is rotatably provided around the shaft 50.

The anti-vibration member 70 may include an anti-vibration pad 71, a shaft cap 72, and upper and lower anti-vibration packings 73 and 74.

The anti-vibration pad 71 may be disposed between the lower housing 20 and the stator assembly 40 to reduce vibration generated by at least one of the lower housing 20 and the stator assembly 40. For example, the anti-vibration pad 71 may reduce the vibration generated in the lower housing 20 to the stator assembly 40 as the impeller assembly 30 rotates. In addition, the anti-vibration pad 71 has an effect of reducing noise by removing a space in which noise is amplified by filling the upper and lower separation spaces between the lower housing body 21 and the stator assembly receiving portion 42.

The anti-vibration pad 71 is disposed in the space between the lower end of the lower housing body 21 and the bottom surface of the stator assembly accommodating portion 42 without any gap in the vertical direction, thereby reducing vibration generated in the lower housing body 21. I can do it.

The anti-vibration pad 71 is formed in a donut shape, and may be disposed to surround the lower housing outer protrusion 23. In addition, the anti-vibration pad 71 can be prevented from deviating from the position arranged by the guide rib 25.

That is, the anti-vibration pad 71 may be provided in a shape that is supported radially outward from the center by the lower housing outer protrusion 23 and radially inward from the edge by the guide rib 25. In addition, the position of the anti-vibration pad 71 may be guided by the lower housing outer protrusion 23 and the guide rib 25 during manufacture. In addition, prior to the main coupling of the lower housing 20 and the stator assembly 40, in the state where the anti-vibration pad 71 is disposed on the lower housing 20, it is prevented from being displaced from the position where the anti-vibration pad 71 is disposed. Can be.

The shaft cap 72 may be interposed between the upper end of the shaft 50 and the upper shaft support 15 to reduce vibration generated by at least one of the shaft 50 and the upper housing 10.

The shaft cap 72 is provided in a cup shape opened downward to allow the upper portion of the shaft 50 to be inserted, and similarly, the shaft cap 72 may be inserted into the shaft upper support 15 which is a cup shape opened downward.

Through this, the shaft 50 is buffered by the shaft cap 72 and coupled with the upper housing 10, so that the vibration of the shaft 50 can be reduced while the vibration of the shaft 50 is upper housing 10 ) Can be reduced.

The upper anti-vibration packing 73 is disposed between the impeller assembly 30 and the shaft top support 15 to reduce vibration generated by at least one of the impeller assembly 30 and the upper housing 10, and the shaft It may be provided to penetrate.

The upper anti-vibration packing 73 may be provided so that the upper end can contact the lower end of the shaft top support 15 and the lower end can contact the upper end of the impeller body 30a of the impeller assembly 30. Alternatively, the upper anti-vibration packing 73 may be provided so that the lower end is in contact with the upper end of the bushing 35 of the impeller assembly 30.

The upper anti-vibration packing 73 prevents the impeller assembly 30 from moving toward the shaft top support 15, thereby reducing vibration of the impeller assembly 30. In addition, the upper anti-vibration packing 73 prevents the impeller assembly 30 from colliding with or directly contacting the shaft top support 15, thereby reducing the occurrence of vibration and noise.

The lower anti-vibration packing 74 is disposed between the impeller assembly 30 and the lower housing 20 to reduce vibration generated by at least one of the impeller assembly 30 and the lower housing 20, and the shaft ( 50) may be provided to penetrate.

The lower anti-vibration packing 74 may be provided so that the upper end can contact the lower end of the impeller assembly 30 and the lower end can contact the shaft lower support 24.

The lower anti-vibration packing 74 can reduce the vibration of the impeller assembly 30 by preventing the impeller assembly 30 from moving toward the shaft lower support 24. In addition, the lower anti-vibration packing 74 prevents the impeller assembly 30 from colliding with or directly contacting the shaft lower support 24 to reduce vibration and noise.

In addition, the upper and lower anti-vibration packings 73 and 74 are provided together to support the impeller assembly 30 from the upper and lower sides, thereby effectively reducing vibrations in the vertical direction of the impeller assembly 30.

To this end, the upper and lower anti-vibration packings 73 and 74 have elasticity, but are preferably provided to minimize frictional force with the impeller assembly 30 when in contact with the impeller assembly 30. For example, the upper and lower anti-vibration packings 73 and 74 are formed of a rubber material, and the surface may be smoothly treated (for example, coated).

The water pump 100 may include a circuit board 80 for controlling the overall configuration of the water pump 100. The circuit board 80 may be installed in the stator assembly 40.

Although not shown, the water pump 100 may further include a power connector (not shown) for receiving power from the outside. The power connector may be electrically connected to the circuit board 80.

The water pump 100 may include one or more O-rings 91 so that the upper and lower housings 10 and 20 are hermetically coupled. For example, one of the upper housing edge portion 14 and the lower housing edge portion 22 is formed with an O-ring groove and an O-ring groove insertion protrusion is formed on the other side, and the O-ring 91 is inserted into the O-ring groove. In the O-ring groove insertion protrusion is inserted into the O-ring groove and the upper and lower housings 10 and 20 may be combined.

Through this, it is possible to effectively prevent the fluid in the upper and inner spaces S of the housings 10 and 20 from leaking out of the housing.

5 is an exploded perspective view of a pump according to another embodiment of the present invention, and FIG. 6 is a longitudinal sectional view of the pump of FIG. 5.

Hereinafter, the water water pump 200 according to another embodiment of the present invention will be mainly described with respect to the water water pump 100 according to an embodiment of the present invention.

The difference between the water pump 200 according to this embodiment and the water pump 100 in the previous embodiment is that the shaft 250 is provided to rotate with the impeller assembly 230. To this end, the water pump 200 according to the present embodiment includes members to enable rotation of the shaft 250.

The water pump 200 according to the present embodiment includes an upper housing 210, a lower housing 220, an impeller assembly 230, a stator assembly 240, and a dustproof member 270.

The upper housing 210 is formed with a fluid inlet 211 and an outlet 212. The upper housing 210 includes a cup-shaped upper housing body 213 and an upper housing edge 214 extending from an edge of the upper housing body 213.

The description in the previous embodiment may be applied to the intake 211 and the outlet 212.

The upper housing 210 is coupled to the upper end of the shaft 250 by being inserted into the shaft top support 215 of the cup-shaped shaft opened downward, and the shaft top support 215 to support the upper end of the shaft 250. Upper bearing 226 may be included.

The lower housing 220 may be disposed to be coupled to the lower side of the upper housing 210 to be coupled. The lower housing 220 may be combined with the upper housing 210 to provide an inner space S in which the impeller assembly 230 is accommodated.

The lower housing 220 may include a lower housing body 221 and a lower housing edge 222 extending from an edge of the lower housing body 221.

The lower housing 220 is coupled to the lower end of the shaft 250 by being inserted into the cup-shaped shaft lower support 224 and the shaft lower support 224 that are opened upward to support the lower end of the shaft 250. Lower bearing 227 may be included.

The impeller assembly 230 may have a shaft hole 233 through which the shaft 250 penetrates.

The shaft 250 penetrates the shaft hole 233 of the impeller assembly 230 and may be combined with the impeller assembly 230. For example, the shaft 250 may be pressed into and coupled to the shaft hole 233 of the impeller assembly 230.

The shaft 250 may have an upper end supported by the upper housing 210 and a lower end supported by the lower housing 220. The shaft 250 is coupled to the upper bearing 226, the upper end of which is inserted into the shaft upper support 215, the lower end is coupled to the lower bearing 227, which is inserted into the shaft lower support 224, the inner space (S) Can be installed rotatably on.

The anti-vibration member 270 may include an anti-vibration pad 271. As for the anti-vibration pad 271, the description in the previous embodiment may be applied.

The anti-vibration member 270 may include upper and lower anti-vibration packings 273 and 274.

The upper anti-vibration packing 273 is disposed between the impeller assembly 230 and the shaft top support 215 to reduce vibration generated by at least one of the impeller assembly 230 and the upper housing 210, and the shaft It may be provided to penetrate.

The upper anti-vibration packing 273 may be provided so that the upper end may contact the lower end of the shaft upper support 215 and the lower end may contact the upper end of the impeller body 230a of the impeller assembly 230. Alternatively, the upper anti-vibration packing 273 may be provided so that at least a portion thereof can contact the upper bearing 226.

The upper anti-vibration packing 273 can reduce the vibration of the impeller assembly 230 by preventing the impeller assembly 230 from moving toward the shaft top support 215. In addition, the upper anti-vibration packing 273 prevents the impeller assembly 230 from colliding or directly contacting the shaft upper support 215 or the upper bearing 226, thereby reducing vibration and noise.

The lower dust packing 274 is disposed between the impeller assembly 230 and the lower housing 220 to reduce vibration generated by at least one of the impeller assembly 230 and the lower housing 220, and the shaft ( 250) may be provided to penetrate.

The lower anti-vibration packing 274 may be provided such that the upper end can contact the lower end of the impeller assembly 230 and the lower end can contact the shaft lower support 224. Alternatively, at least a portion of the lower anti-vibration packing 274 may be provided to be in contact with the lower bearing 227.

The lower anti-vibration packing 274 may reduce vibration of the impeller assembly 230 by preventing the impeller assembly 230 from moving toward the shaft lower support 224. In addition, the lower anti-vibration packing 274 prevents the impeller assembly 230 from colliding or directly contacting the shaft lower support 224 or the lower bearing 227, thereby reducing vibration and noise.

In addition, the upper and lower anti-vibration packings 273 and 274 are provided together to support the impeller assembly 230 from the upper and lower sides, thereby effectively reducing vibrations in the vertical direction of the impeller assembly 230.

To this end, the upper and lower anti-vibration packings 273 and 274 have elasticity, but are preferably provided to minimize frictional force with the impeller assembly 230 when in contact with the impeller assembly 230. For example, the upper and lower anti-vibration packings 273 and 274 are formed of a rubber material, and the surface may be smoothly treated (for example, coated).

For a configuration that has not been described in detail elsewhere, a description of the configuration of the water pump 200 according to an embodiment described with reference to FIGS. 1 to 4 may be applied as it is.

Although the present invention has been described above by means of limited embodiments and drawings, the present invention is not limited thereto, and the technical concept of the present invention and the following will be described by those skilled in the art to which the present invention pertains. Various implementations are possible within the scope of equivalent claims.

10, 210: upper housing
11, 211: Intake
12, 212: outlet
13, 213: upper housing body
14, 214: upper housing edge
15, 215: shaft top support
20, 220: lower housing
21, 221: lower housing body
22, 222: lower housing edge
23, 223: Lower housing outer protrusion
24, 224: Shaft lower support
25, 225: Guide rib
30, 230: impeller assembly
30a, 230a: impeller body
31, 231: Impeller
32, 232: rotor
33, 233: shaft hole
34: Bushing accommodation home
35: bushing
40, 240: stator assembly
41, 241: stator
42, 242: stator assembly receiving portion
43, 243: stator assembly depression
50, 250: shaft
70, 270: Dustproof member
71, 271: anti-vibration pad
72: shaft cap
73, 273: Upper dust packing
74, 274: Lower dust packing
80, 280: Circuit board
91, 291: O-ring
100, 200: water pump
226: upper bearing
227: lower bearing
S: Internal space

Claims (17)

An upper housing where fluid inlets and outlets are formed;
A lower housing coupled to a lower side of the upper housing;
In the inner space formed by the combination of the upper and lower housings, the impeller assembly including a rotor and an impeller for rotatable installation in the vertical direction in the axial direction to suck fluid into the suction port and discharge it to the discharge port ;
A stator assembly coupled to a lower side of the lower housing, providing an accommodation space in which at least a portion of the lower housing is accommodated, and including a stator corresponding to the rotor; And
A water pump including an anti-vibration pad disposed between the lower housing and the stator assembly to reduce vibration generated by at least one of the lower housing and the stator assembly. The method according to claim 1,
The lower housing includes a cup-shaped lower housing body inserted into an accommodating space of the stator assembly, and a lower housing outer protrusion protruding toward the stator assembly from a lower center of the lower housing body,
The stator assembly further includes a stator assembly depression that is further recessed from the bottom of the accommodation space to accommodate at least a portion of the lower housing outer protrusion,
The anti-vibration pad is formed in a donut shape, and is disposed to surround the lower housing outer protrusion, a water pump. The method according to claim 1,
The lower housing includes a cup-shaped lower housing body that is inserted into the accommodation space of the stator assembly,
The lower housing and the stator assembly, the lower end of the lower housing body and the bottom surface of the receiving space are coupled to be spaced apart from each other,
The anti-vibration pad, the water pump is arranged so that there is no gap in the vertical direction in the space between the bottom of the lower housing body and the bottom of the receiving space. The method according to claim 3,
At least one of the lower housing and the stator assembly,
A water pump including a guide rib protruding into the space to guide the position where the anti-vibration pad is disposed. The method according to claim 4,
The length of the guide rib protruding is shorter than the vertical separation distance between the lower housing and the stator assembly, the water pump. The method according to claim 1,
The shaft is installed in the inner space to penetrate the impeller assembly in a direction corresponding to the axial direction, and further includes a shaft supported by the upper and lower housings.
The upper housing includes a cup-shaped upper housing body, a shaft upper support portion provided inside the upper housing body to support the upper end of the shaft, and a flange portion connecting the shaft upper support portion and the upper housing body. Included, water pump. The method according to claim 6,
To reduce vibration generated by at least one of the shaft and the upper housing, the water pump further comprises a shaft cap interposed between the upper end of the shaft and the upper shaft support. The method according to claim 7,
The shaft cap is provided in a cup shape that is opened downward to allow the upper portion of the shaft to be inserted,
The shaft top support is provided in a cup shape that opens downward to allow at least a portion of the shaft cap to be inserted. The method according to claim 6,
In order to reduce vibration generated by at least one of the impeller assembly and the upper housing, a water pump further comprising an upper vibration-proof packing disposed between the impeller assembly and the shaft upper support and through which the shaft penetrates. The method according to claim 1,
The shaft is installed in the inner space to penetrate the impeller assembly in a direction corresponding to the axial direction, and further includes a shaft supported by the upper and lower housings.
The impeller assembly,
A shaft hole provided to penetrate the shaft,
A bearing receiving groove disposed coaxially with the shaft hole and formed with a larger diameter than the shaft hole,
A water pump including a bearing accommodated in the bearing receiving groove. The method according to claim 10,
The bearing,
Based on the vertical direction, the water pump is provided to extend from the upper inlet end of the bearing receiving groove to a lower side than the middle of the top and bottom of the rotor. The method according to claim 10,
The bearing,
Based on the vertical direction, the upper end is extended to the upper side than the upper end of the rotor, the lower end is provided to extend to the lower side than the lower end of the rotor, the water pump. The method according to claim 1,
The shaft is installed in the inner space to penetrate the impeller assembly in a direction corresponding to the axial direction, and further includes a shaft supported by the upper and lower housings.
In order to reduce the vibration generated by at least one of the impeller assembly and the lower housing, the water pump further comprises a lower vibration packing disposed between the impeller assembly and the lower housing and through which the shaft passes. The method according to claim 1,
It is combined with the impeller assembly, and further includes a shaft installed in the inner space to enable relative rotation with the impeller assembly in the upper and lower housings,
The upper housing, to support the upper end of the shaft, includes a cup-shaped shaft upper support opened downward and an upper bearing inserted into the upper shaft support and coupled with the upper end of the shaft,
The lower housing, to support the lower end of the shaft, includes a cup-shaped shaft lower support opening upward and a lower bearing inserted into the lower shaft support and coupled with the lower end of the shaft. An upper housing where fluid inlets and outlets are formed;
A lower housing assembly coupled to a lower side of the upper housing and including a stator;
The inner space formed by the combination of the upper housing and the lower housing assembly is rotatably installed in the up and down direction in the axial direction, the impeller for sucking fluid through the suction port and discharging it to the discharge port, and corresponding to the stator An impeller assembly comprising a rotor;
A shaft installed in the internal space to penetrate the impeller assembly in a direction corresponding to the axial direction, and the upper and lower shafts supported by the upper and lower housing assemblies; And
And a shaft cap provided to reduce vibration generated by at least one of the shaft and the upper housing,
The upper housing includes a cup-shaped upper housing body and a shaft upper support portion provided inside the upper housing body to support the upper end of the shaft,
The shaft cap is interposed between the shaft top support and the shaft, the water pump. An upper housing where fluid inlets and outlets are formed;
A lower housing assembly coupled to a lower side of the upper housing and including a stator;
The inner space formed by the combination of the upper housing and the lower housing assembly is rotatably installed in the up and down direction in the axial direction, the impeller for sucking fluid through the suction port and discharging it to the discharge port, and corresponding to the stator An impeller assembly comprising a rotor;
A shaft installed in the inner space to penetrate the impeller assembly in a direction corresponding to the axial direction, and the upper and lower ends supported by the upper and lower housing assemblies; And
Including the lower dust-proof packing disposed between the impeller assembly and the lower housing and through which the shaft passes,
The water pump that reduces vibration generated by at least one of the impeller assembly and the lower housing by the lower anti-vibration packing. An upper housing where fluid inlets and outlets are formed;
A lower housing assembly coupled to a lower side of the upper housing and including a stator;
The inner space formed by the combination of the upper housing and the lower housing assembly is rotatably installed in the up and down direction in the axial direction, the impeller for sucking fluid through the suction port and discharging it to the discharge port, and corresponding to the stator An impeller assembly comprising a rotor;
A shaft installed in the inner space to penetrate the impeller assembly in a direction corresponding to the axial direction, and the upper and lower ends supported by the upper and lower housing assemblies; And
And an upper anti-vibration packing provided to reduce vibration generated by at least one of the impeller assembly and the upper housing.
The upper housing includes a cup-shaped upper housing body and a shaft top support provided inside the upper housing body to support the upper end of the shaft,
The upper anti-vibration packing is disposed between the impeller assembly and the upper housing body, and the shaft passes through the water pump.

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