KR102430825B1 - Canned motor device - Google Patents

Abstract

The cand motor device includes a base unit 10 , a motor 30 , and front and rear covers 60 , 40 . The base unit 10 includes a side 111 comprising inner and outer annular portions 115 , 116 . The motor 30 is mounted to the base unit 10 and includes a flange 312. A rear cover 40 is mounted to the base unit 10 and sealably between the flange 312 and the inner annular portion 115. It includes a disk 42 to be clamped.The front cover 60 has an end 61 adjacent to a side surface 111 and includes inner and outer surrounding portions 611, 612. The disk 42 and The flange 312 is sealably clamped between the inner annular portion 115 and the inner surrounding portion 611. To form a hermetic seal between the base unit 10 and the front cover 60, the first A sealing element 71 is interposed between the base unit 10 and the disk 42. A second sealing element 72 is interposed between the outer annular portion 116 and the outer surrounding portion 612.

Description

Canned Motor Device {CANNED MOTOR DEVICE}

The present invention relates to a motor device, and more particularly, to a can motor device capable of preventing leakage.

A conventional magnetically driven CANNED MOTOR DEVICE disclosed in Taiwan Patent No. I424661 includes a front cover, a support frame, an impeller, a cup-shaped rear cover, an inner rotor, an outer rotor, a fixed shaft, and a bracket. . The front cover has an inlet and an outlet. The back cover has a double-layer structure, and has an inner lining made of a fluoroplastic material and a reinforcing layer.

During operation of a conventional magnetically driven pump, a chemical fluid is introduced and guided by an impeller to an inlet to dissipate the heat generated by the internal rotor, and then exits from the outlet.

The inner lining and the reinforcing layer are in contact with each other to form a double-layer structure of the back cover, but the diameter of the reinforcing layer is smaller than the diameter of the inner lining. As such, if the inner lining is damaged, the chemical fluid easily leaks through the cracks in the inner lining into the gap between the inner lining and the reinforcing layer, and then flows along the perimeter of the reinforcing layer towards the outer rotor, which will corrode the motor unit. can

Accordingly, it is an object of the present invention to provide a canned motor device capable of alleviating the disadvantages of the prior art.

According to the present invention, the can motor apparatus includes a base unit, a positioning seat, a motor unit, a rear cover, an impeller, a front cover, a first sealing element and a second sealing element. The base unit includes a side cover portion and a main plate portion. The main plate portion circumscribes the shaft, is connected to the side cover portion, and has a first side surface, a second side surface and an inner surface. The first side surface has a stepped profile in a radial direction transverse to the axis and includes an inner annular segment, an outer annular segment, and a first shoulder segment. The outer annular segment surrounds the inner annular segment and is closer to the side cover portion than the inner annular segment. The first shoulder connects the inner annular segment and the outer annular segment to each other. The second side surface is opposite the first side surface along the axis and is disposed closer to the side cover portion than the first side surface. The inner surface is disposed between the inner annular segment of the first side surface and the second side surface. The motor unit is mounted on the base unit and includes a casing body, a stator, and a rotor. The casing body includes a tubular main portion and a flange portion extending radially outwardly from one end of the tubular main portion and positioned corresponding to the inner annular segment. The stator is sleeved to the casing body. The rotor is mounted on the tubular main part of the casing body and is rotatable about an axis. The rear cover is mounted on the base unit and includes a main cover portion and a disk portion. The main cover part is disposed between the tubular main part and the stator. The disk portion extends radially outward from one end of the main cover portion and is sealingly clamped between the flange portion of the motor unit and the inner annular segment of the base unit. The impeller is connected to and driven by the motor unit and extends along an axis into the main plate portion of the base unit. A front cover is located on the first side surface of the main plate portion, covers the impeller, and has an end surface. The end surface abuts the first side surface, has a stepped profile along a radial direction, and includes an inner perimeter segment, an outer perimeter segment, and a second shoulder. The inner peripheral segment abuts the inner annular segment of the base unit along the axis. The outer perimeter segment surrounds the inner perimeter segment and abuts the outer annular segment of the base unit. The second shoulder connects the inner perimeter segment and the outer perimeter segment to each other and abuts the first shoulder. The disc portion and the flange portion are sealingly clamped between the inner annular segment and the inner peripheral segment. The first sealing element is disposed between the main plate portion and the disc portion of the base unit to form a hermetic seal between the base unit and the back cover. A second sealing element is disposed between the outer annular segment and the outer peripheral segment to form a hermetic seal between the base unit and the front cover.

Other features and advantages of the present invention will become apparent from the following detailed description of embodiments with reference to the accompanying drawings:
1 is a partially exploded perspective view of a can motor device of an embodiment according to the present invention;
2 is a schematic cross-sectional view of an embodiment; and
3 is a partial cross-sectional view of an embodiment;

1 to 3 , an embodiment of the canned motor device according to the present invention includes a base unit 10, a positioning sheet 20, a motor unit 30, a rear cover 40, an impeller 50, It includes a front cover 60 , a first sealing member 71 , a second sealing member 72 , and a third sealing member 73 .

In this embodiment, the base unit 10 is made of a plastic material, polypropylene (PP), glass fiber reinforced polypropylene (GFRPP), polyvinylidene fluoride (PVDF), and carbon-filled ethylene tetrafluoroethylene ( CFRETFE) can be made of engineering plastic materials that are resistant to acid and alkali. The base unit 10 includes a main plate portion 11 and a side cover portion 12 . The main plate portion 11 surrounds the axis L, is connected to the side cover portion 12, and has a chamfered surface 110 , a first side surface 111 , a second side surface 112 , and an inner surface ( 114). The first side surface 111 has a stepped profile in a radial direction transverse to the axis L and includes an inner annular segment 115 , an outer annular segment 116 , and a first shoulder 117 . The outer annular segment 116 surrounds the inner annular segment 115 and is closer to the side cover portion 12 than the inner annular segment 115 . The first shoulder 117 connects the inner annular segment 115 and the outer annular segment 116 to each other. The second side surface 112 is opposite the first side surface 111 along the axis L and is disposed closer to the side cover portion 12 than the first side surface 111 . The inner surface 114 is disposed between the inner annular segments 115 of the first side surface 111 and has an end connected to the second side surface 112 . The chamfered surface 110 is connected between the first side surface 111 and the inner surface 114 .

The main plate portion 11 of the base unit 10 comprises a first annular groove 118 formed in the inner annular segment 115 and surrounding the axis L, and a first annular groove 118 formed in the outer annular segment 116 and surrounding the axis L A second annular groove 119 surrounding L) is defined. In particular, the first annular groove 118 abuts the inner surface 114 of the main plate portion 11 . In this embodiment, the first annular groove 118 is formed in the chamfered surface 110 , and the second annular groove 119 abuts the first shoulder 117 of the main plate portion 11 .

The positioning sheet 20 is made of a metal material and is tubular, and is disposed on the side cover portion 12 of the base unit 10 .

The motor unit 30 is mounted on the base unit 10 and the positioning seat 20 , and includes a casing body 31 , a stator 32 , and a rotor 33 . The casing body 31 includes a tubular main portion 311 and a flange portion 312 extending radially outward from one end of the tubular main portion 311 and positioned corresponding to the inner annular segment 115 . The stator 32 is sleeve-connected to the casing body 31 . The rotor 33 is mounted on the tubular main part 311 of the casing body 31 and is rotatable about an axis L.

The rear cover 40 is mounted on the base unit 10 , and includes a main cover portion 41 and a disk portion 42 . The main cover part 41 is disposed between the tubular main part 311 and the stator 32 . The disk portion 42 extends radially outward from one end of the main cover portion 41 , and seals between the flange portion 312 of the motor unit 3 and the inner annular segment 115 of the base unit 10 . clamped in this way.

The impeller 50 is connected to and driven by the motor unit 30 and extends along the axis L into the main plate portion 11 of the base unit 10 .

The front cover 60 is located on the first side surface 111 of the main plate portion 11 , covers the impeller 50 , defines a third annular groove 614 , and has an end surface 61 . . The end surface 61 abuts the first side surface 111 , has a stepped profile along the radial direction, and includes an inner perimeter segment 611 , an outer perimeter segment 612 , and a second shoulder 613 . do. The inner peripheral segment 611 abuts the inner annular segment 115 of the base unit 10 along the axis L. The outer perimeter segment 612 surrounds the inner perimeter segment 611 and abuts the outer annular segment 116 of the base unit 10 . The second shoulder 613 connects the inner peripheral segment 611 and the outer peripheral segment 612 to each other and abuts the first shoulder 117 .

Disc portion 42 and flange portion 312 are sealingly clamped between inner annular segment 115 and inner peripheral segment 611 . The flange portion 312 of the casing body 31 and the disk portion 42 of the rear cover 40 abut against the second shoulder portion 613 .

A third annular groove 614 is formed in the inner peripheral segment 611 adjacent the second shoulder 613 and surrounds the axis L.

The first sealing element 71 is disposed between the main plate portion 11 and the disk portion 42 of the base unit 10 to form an airtight seal between the base unit 10 and the back cover 40 . In this embodiment, the first sealing element 71 is received in the first annular groove 118 .

A second sealing element 72 is disposed between the outer annular segment 116 and the outer peripheral segment 611 to form a hermetic seal between the base unit 10 and the front cover 60 . In this embodiment, the second sealing element 72 is received in the second annular groove 119 to form a hermetic seal between the base unit 10 and the front cover 60 .

The third sealing element 73 is received in the third annular groove 614 to form an airtight seal between the flange portion 312 of the motor unit 30 and the front cover 60 .

In general, the chemical fluid is introduced into a space defined in the casing body 31 to dissipate the heat generated in the rotor 33 . However, when the casing body 31 is damaged or broken, the chemical fluid may leak out of the space and damage the stator 32 of the motor unit 30 .

In the following description, the advantages provided by the structure of an embodiment of the canned motor apparatus of the present invention are described. As shown in FIG. 2 , the front cover 60 is positioned on the main plate portion 11 of the base unit 10 by a plurality of screws. The end surface 61 of the front cover 60 and the first side surface 111 of the main plate part 11, each of which has a stepped profile, are interposed between the flange part 312 of the casing body 31 . and the disc portion 42 of the back cover 40 face each other and cooperate with each other to clamp. In particular, the disc portion 42 and the flange portion 312 are sealingly clamped between the inner annular segment 115 and the inner peripheral segment 611 . Further, the disc portion 42 and the flange portion 312 abut the second shoulder portion 613 . Therefore, the disc portion 42 and the flange portion 312 are securely and sealingly positioned between the front cover 60 and the casing body 31 .

When the chemical fluid leaks out from the space defined by the casing body 31 and flows between the casing body 31 and the rear cover 40, the disk portion 42 of the main plate portion 11 and the rear cover 40 The first sealing element 71 mounted therebetween and received in the first annular groove 118 serves as a first line of defense to prevent the chemical fluid from leaking out from the back cover 40 , and therefore of the stator 32 . prevent damage; Additionally, the second sealing element 72 disposed between the outer annular segment 116 and the outer peripheral segment 611 and accommodated in the second annular groove 119 is coupled to the first side surface 111 of the base unit 10 and An airtight seal is formed between the outer peripheral segments 611 of the front cover 60 . Therefore, the second sealing element 72 serves as a second line of defense.

Further, the flange portion 312 of the casing body 31 and the disk portion 42 of the rear cover 40 are the inner annular segment 115 of the base unit 10 and the outer peripheral segment 611 of the front cover 60 . ) are sealed in between. Therefore, the disc portion 42 and the flange portion 313 are securely and sealingly positioned between the base unit 10 and the front cover 60 .

The third sealing member 73 is formed to form an airtight seal between the flange portion 312 of the motor unit 30, the front cover 60, and the base unit 10 to prevent the chemical fluid from leaking out. 3 is accommodated in the annular groove 614 .

Further, the configuration of the first side surface 111 and the end surface 61 , each having a stepped profile, is such that when the chemical fluid leaks out of the casing body 31 , the flow rate of the chemical fluid is reduced to the first side surface 11 . ) and the end surface 61 cooperate to form a plurality of turns that can be reduced in each turn. In this way, a relatively good leak-proof function can be provided, and therefore the life of the motor unit 30 can be increased.

In summary, according to the present invention, when the casing body 31 is damaged or broken so that the chemical fluid flows out from the space defined by the casing body 31, the first, second and The third sealing elements 71 , 72 , 73 and the above structure prevent the chemical fluid from leaking and damaging the stator 32 , thereby prolonging the life of the motor unit 3 .

In the foregoing description, for purposes of explanation, numerous specific details have been set forth in order to provide a thorough understanding of the embodiments. However, it will be apparent to one skilled in the art that one or more other embodiments may be practiced without some of these specific details. It should also be understood that references throughout the specification to “one embodiment,” “an embodiment,” an embodiment having an ordinal designation, etc., mean that a particular feature, structure, or characteristic may be included in an embodiment of the invention. do. In the detailed description, various features are sometimes grouped together in a single embodiment, drawing, or description thereof, for the purpose of streamlining the disclosure and assisting in understanding various aspects of the invention, one or more features from one embodiment or It should be understood that specific details may be practiced in conjunction with one or more features or specific details from other embodiments in the practice of the invention, where appropriate.

Claims (9)

A can motor device comprising:
A base unit comprising a side cover portion, and a main plate portion, wherein the main plate portion surrounds an axis and is connected to the side cover portion,
an inner annular segment having a stepped profile in a radial direction transverse to the axis, an outer annular segment surrounding the inner annular segment and closer to the side cover portion than the inner annular segment, and interconnecting the inner annular segment and the outer annular segment a first side surface having a first shoulder to
a second side surface opposite the first side surface along the axis and disposed closer to the side cover portion than the first side surface; and
the base unit having an inner surface disposed between the inner annular segment of the first side surface and the second side surface;
A motor unit mounted to the base unit, the casing body including a tubular main portion and a flange portion extending radially outward from one end of the tubular main portion and positioned corresponding to the inner annular segment; the motor unit comprising a stator sleeve-connected and a rotor mounted to the tubular main portion of the casing body and rotatable about the axis;
a rear cover mounted to the base unit, a main cover portion disposed between the tubular main portion and the stator, and radially outwardly extending from one end of the main cover portion, the flange portion of the motor unit and the base the back cover comprising a disk portion sealingly clamped between the inner annular segments of the unit;
an impeller connected to and driven by the motor unit and extending along the axis into the main plate portion of the base unit;
a front cover located on the first side surface of the main plate portion and covering the impeller, the inner annular segment of the base unit abutting the first side surface and having a stepped profile along the radial direction and along the axis an end surface comprising an inner perimeter segment tangent to, an outer perimeter segment surrounding the inner perimeter segment and abutting the outer annular segment of the base unit, and an outer perimeter segment interconnecting the inner perimeter segment and the outer perimeter segment and connecting the outer perimeter segment to the first shoulder the front cover having a second shoulder abutting to the front cover, wherein the disk portion and the flange portion are sealingly clamped between the inner annular segment and the inner peripheral segment;
a first sealing element disposed between the main plate portion and the disk portion of the base unit to form an hermetic seal between the base unit and the back cover; and
and a second sealing element disposed between the outer annular segment and the outer peripheral segment to form a hermetic seal between the base unit and the front cover. 2. The base unit of claim 1, wherein the main plate portion of the base unit defines a first annular groove formed in the inner annular segment and surrounding the axis, the first sealing element being disposed between the base unit and the back cover. and received within the first annular groove to form a hermetic seal. The can motor device according to claim 2, wherein the first annular groove is adjacent to the inner surface of the main plate portion. The can motor apparatus according to claim 3, wherein the main plate portion further has a chamfered surface between the first side surface and the inner surface, and the first annular groove is formed in the chamfered surface. 5. The device of claim 4, wherein the main plate portion of the base unit defines a second annular groove formed in the outer annular segment and surrounding the axis, the second sealing element being disposed between the base unit and the front cover. received within the second annular groove to form an airtight seal. The can motor device according to claim 5, wherein the second annular groove is formed adjacent to the first shoulder portion of the main plate portion. 7. The motor unit of claim 6, further comprising a third sealing element, wherein the front cover defines a third annular groove formed in the inner peripheral segment and surrounding the axis, the third sealing element of the motor unit. and received in the third annular groove to form an airtight seal between the flange portion and the front cover. 8. The can motor device according to claim 7, wherein said third annular groove is adjacent to said second shoulder portion. The can motor device according to any one of claims 1 to 8, wherein the flange portion of the casing body of the motor unit and the disk portion of the rear cover abut the second shoulder portion.

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