KR200443345Y1 - Rotary bearing device for a magnetic drive pump - Google Patents

Abstract

The rotary bearing device is for rotatably mounting the rotor 90 on the support shaft 91 of the magnetic drive pump 9 and includes a sleeve tube 3 rotatably surrounding the support shaft 91. . The sleeve tube 3 has a tubular outer face 32 fixed to the magnet mounting member 92 of the rotor 90 and front and rear ends adjacent to the impeller 95 and the rear thrust ring 93, respectively. 31,33). The tubular outer face 32 extends inwardly and rearwardly up to the trailing wall 33 and extends forwardly so as to be confined to the front edge 322 not reaching the front wall 31 and the front wall 31. Together with a heat dissipation groove 321 defining the hole (5). The heat dissipation groove 321 forms a convection cooling passage on the outer side of the sleeve tube 3.

Magnetic drive pump, rotary bearing, heat resistant groove

Description

ROTARY BEARING DEVICE FOR A MAGNETIC DRIVE PUMP}

The present invention relates to a magnetic drive pump, and more particularly to a rotary bearing device for rotatably mounting the rotor on the support shaft of the magnetic drive pump.

In general, a conventional magnetic drive sealless pump is supported by a support shaft fixed in a housing, a drive magnet disposed radially outward of the support shaft and rotated by a drive motor, and supported by a rotating bearing. A rotor rotatably supported on the shaft. The rotor includes a magnet mounting member radially spaced from the support shaft and receiving a driven magnet therein, and an impeller disposed in front of the magnet mounting member. The magnet mounting member is rotated by the rotation of the drive magnet. The impeller pumps the fluid into the housing through the inlet port in front of the housing and discharges the fluid through the outlet port.

The rotating bearing is movable in the thrust direction along the support axis. In normal operation, where the fluid is pumped, the rotor is moved forward by the negative pressure inside the suction port. In idling runs where no fluid is present and in abnormal driving such as an air involving run, the rotor is moved backwards by magnetic attraction, so that the rear end of the rotating bearing is mounted on the support shaft. Contact the rear thrust ring. Heat is generated as a result of the frictional contact. As a result, the temperatures of the rotary bearing and the support shaft rise rapidly, and the rotary bearing and the support shaft wear. Although the rotating bearing has a plurality of grooves formed on the outer side such that a plurality of channels are defined between the magnet mounting member, the heat generated between the rear end of the rotating bearing and the rear thrust ring is trapped in the channel, Damage the rotating bearing during operation.

It is an object of the present invention to provide a rotary bearing device having an improved heat dissipation groove structure for obtaining an optimal convection effect, in order to prevent damage to a magnetic drive pump caused by heat during dry running. .

According to the present invention, a rotary bearing device is for rotatably mounting a rotor on a support shaft of a magnetic drive pump. The rotary bearing device includes a sleeve tube. The sleeve tube has a tubular inner surface rotatably surrounding the support shaft, a tubular outer surface secured to the magnet mounting member of the rotor, and front and rear walls adjacent the impeller and rear thrust ring, respectively. The rear wall is protected by a rear thrust ring. The tubular outer face has at least one heat dissipation groove. The groove extends inwardly toward Axis and extends rearwardly to reach the trailing wall. The groove then extends forward to be confined to the front edge that does not reach the shear wall, thereby defining a hole between the shear wall. The hole extends inwardly through the tubular inner face. The hole then extends outward of the shear wall in communication with the channel so that the channel between the support shaft and the magnet mounting member is disposed upstream of the inner duct of the impeller.

According to the present invention, an optimal convection effect can be obtained to prevent damage to the magnetic drive pump caused by heat during dry running.

1 and 2, a first embodiment of a rotary bearing device according to the present invention is a rotor on a support shaft 91 of a magnetic drive pump 9. (Rotator, 90) is adopted to rotatably mount. The support axis 9 defines an axis Axis, X. The pump 9 includes a housing having a front chamber 94 and a rear chamber 96 connected to each other along an axis X. The front chamber 94 has an inlet 941 and an outlet 942 extending radially with respect to the axis X. As shown in FIG. The pump 9 further includes an annular drive magnet 98 disposed on the radially outer side of the rear chamber 96 and rotating about an axis X by a drive motor (not shown). . The rotor 90 has an annular magnet mounting member 92 and an impeller 95. The magnet mounting member 92 is disposed in the rear chamber 96 so as to be rotatable about the axis X, and is spaced radially away from the support shaft 91 by the channel Channel 1. The magnet mounting member 92 accommodates therein an annular driven magnet 99 that is driven to rotate by the rotation of the drive magnet 98. The impeller 95 is disposed in front of the magnet mounting member 92. The impeller 95 has an internal duct 2. The impeller 95 has an inner duct 2 upstream of the outlet 942 and a downstream of the inlet 941 for forming a first flow path, and an inner duct 2 for forming a second flow path. It is arranged in the front chamber 94 to be located upstream of the outlet 942 and downstream of the channel 1, respectively. The pump 9 further includes a rear thrust ring 93 mounted to the support shaft 91 and surrounding the axis X.

The rotating bearing device of the present invention has a tubular inner surface (Inner Tubular Surface, 37), a tubular outer surface (Outer Tubular Surface, 32), and front and rear end walls (31, 33) Sleeve tube 3). The tubular inner face 37 rotatably surrounds the support shaft 91, and the tubular outer face 32 is fixed to the magnet mounting member 92. The front and rear walls 31, 33 are arranged adjacent to the impeller 95 and the rear thrust ring 93, respectively. In particular, the tubular outer surface 32 is splined with the magnet mounting member 92 in order to facilitate fitting the sleeve tube 3 to the magnet mounting member 92 along the axis X. It has a planar surface segment 36, which is Engagement. The shear wall 31 is disposed in contact with the inner flange of the magnet mounting member 92 to form a dead end of the channel 1. The rear wall 33 is arranged to be protected by the rear thrust ring 93 to make limited axial movement, ie a longitudinal thrust movement parallel to the axis X.

The tubular outer face 32 has a plurality of heat dissipating grooves 321 spaced apart from each other along the circumferential direction. Each heat dissipation groove 321 extends inward toward the axis Axis and extends rearward to reach the trailing wall 33. The heat dissipation groove 321 extends forward to be confined to the front edge 322 not reaching the shear wall 31, whereby a hole 5 is defined between the shear wall 31. The hole 5 extends inwardly through the tubular inner face 37. And the hole 5 extends outward of the shear wall 31 in communication with the channel 1 so that the channel 1 is arranged upstream of the inner duct 2 in view of the second flow path.

The trailing wall 33 has a rear circumferential surface 331. The trailing circumferential surface 331 is arranged to face the rear thrust ring 93 and is interrupted by a plurality of rear cutout portions 6 spaced apart from each other along the circumferential direction. Each rear cut out portion 6 extends along the lengthwise direction such that the respective heat dissipation grooves 321 communicate with the tubular inner surface 37.

The tubular inner face 37 has a spirally extending groove 371. The groove 371 extends through the holes 5 and the trailing circumferential surface 331 to facilitate heat convection inside the sleeve tube 3.

In this embodiment, the tubular outer face 32 further has a surrounding groove 34. The surrounding groove 34 extends circumferentially about the axis X and extends radially inward. The surrounding groove 34 turns the flow of fluid from the back of the trailing circumferential surface 331 to the surrounding groove 34 before the fluid flow enters the heat dissipation grooves 321.

In dry running, where liquid does not enter the pump 9, the trailing circumferential surface 331 is in frictional contact with the rear thrust ring 93 and air is spiraled to release heat inside the sleeve tube 3. It flows through the groove 371 extending to. In addition, the rear cut out portion 6, the surrounding groove 314, the heat dissipation grooves 321, and the holes 5 together form a convection cooling passage in the sleeve tube 3. As such, sufficient ventilation for cooling is provided even during long dry runs, whereby the sleeve tube 3 is kept at a low temperature. Furthermore, by providing the planar portion 36 to spline engagement with the magnet mounting member 92, rotation of the sleeve tube 3 can be prevented.

Referring to FIG. 3, the second embodiment of the rotary bearing device according to the present invention is similar to the first embodiment in its configuration, except that the rear cutout parts 6 are omitted. Thus, the surrounding groove 34, the heat dissipation grooves 321, and the holes 5 together form a convective cooling passage.

4, the third embodiment of the rotary bearing device according to the present invention is similar to the first embodiment in its configuration, except that the surrounding groove 34 is omitted. Thus, the rear cut out portions 6, the heat dissipation grooves 321, and the holes 5 together form a convective cooling passage.

Although the present invention has been described in connection with embodiments that are considered to be the most useful and desirable, the invention is not limited to the disclosed embodiments, and includes various arrangements within the spirit and scope of the broadest interpretation and equivalent arrangements. It should be understood that it is intended to cover.

Other features and advantages of the present invention will become apparent from the following detailed description of the preferred embodiments of the present invention provided below with reference to the accompanying drawings.

1 is a schematic cross-sectional view of a first embodiment of a rotary bearing device according to the present invention when mounted to a magnetic drive pump,

2 is a perspective view of a first embodiment,

3 is a perspective view of a second embodiment of a rotary bearing device according to the present invention,

4 is a perspective view of a third embodiment of a rotary bearing device according to the present invention.

<Description of Symbols for Main Parts of Drawings>

3: sleeve tube 5: hole

6: rear cut-out part 9: magnetic drive pump

34: surrounding groove 90: rotor

91: support shaft 321: heat dissipation groove

371: Spiral Groove

Claims (5)

In the rotary bearing device suitable for rotatably mounting the rotor 90 on the support shaft 91 of the magnetic drive pump 9, The support shaft 91 defines the axis X, The magnetic drive pump 9, A housing having front and rear chambers 94 and 96 connected to each other along the axis X, wherein the front chamber 94 has a suction port 941 and an outlet port 942 extending radially with respect to the shaft X; ; A driving magnet (98) disposed on a radially outer side of the rear chamber (96) and being rotated about the axis (X) by a driving motor; Disposed in the rear chamber 96 so as to be rotatable about the axis X, spaced radially away from the support shaft 91 by the channel 1, and by rotation of the drive magnet 98. A rotor 90 having a magnet mounting member 92 configured to receive a driven magnet 99 rotated therein; Disposed in front of the magnet mounting member 92, having an inner duct 2, the inner duct 2 upstream of the outlet 942 and downstream of the suction port 941 to form a first flow path; Impellers 95 disposed in the front chamber 94, respectively located at and in the inner chamber 94 so that the inner duct 2 is located upstream of the outlet 942 and downstream of the channel 1 to form a second flow path. ); And And a rear thrust ring (93) mounted to the support shaft (91) and surrounding the shaft (X). The rotary bearing device, A tubular inner surface 37 rotatably surrounding the support shaft 91, a tubular outer surface 32 fixed to the magnet mounting member 92, and the impeller 95 and the rear A sleeve tube (3) having front and rear end walls (31, 33) adjacent to the thrust ring (93), respectively, The shear wall 31 forms a dead end of the channel 1, The rear wall 33 is arranged to be protected by the rear thrust ring 93, The tubular outer face 32 extends inwardly towards the axis X, extends rearward to reach the rear end wall 33, and does not reach the front end wall 31. Has at least one heat dissipation groove 321 extending forward to define a hole 5 together with the shear wall 31, The hole 5 is provided to be in communication with a space defined by the inner surface 37 of the tubular shape, and the hole 5 has the channel 1 in view of a second flow path and the inner duct 2. Rotary bearing device, characterized in that it is provided in communication with the outer side of the shear wall (31) to be connected with the channel (1) to be disposed upstream of the. The method of claim 1, The trailing wall 33 has a trailing circumferential surface 331 disposed to face the rear thrust ring 93 and interrupted by at least one rear cutout portion 6, And the rear cut out portion (6) extends in the longitudinal direction parallel to the axis (X) such that the heat dissipation groove (321) and the inner surface (37) of the tube shape pass through. The method of claim 2, The tubular inner face 37 is provided with a groove 371 extending spirally through the holes 5 and the trailing circumferential face 331 to facilitate thermal convection within the sleeve tube 3. Rotary bearing device characterized in that it has. The method of claim 1, The tubular outer surface 32 is a planar portion splined with the magnet mounting member 92 to facilitate fitting the sleeve tube 3 to the magnet mounting member 92 along the axis X. A rotary bearing device having (36). The method of claim 1, The trailing wall 33 has a trailing circumferential surface 331 disposed to face the rear thrust ring 93, wherein the tubular outer surface 32 extends circumferentially about the axis X. Have a surrounding groove 34 extending radially inward, The surrounding groove 34 is rotated to turn the flow of fluid from the rear of the rear end circumferential surface 331 to the surrounding groove 34 before the flow of fluid enters the heat dissipating grooves 321. Bearing device.

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