TWM539995U - Rotor short circuit ring casting die - Google Patents

Description

Rotor short circuit ring casting mold

The present invention relates to a technical field related to a casting process, in particular to a rotor short-circuit ring casting mold for casting a rotor short-circuit ring structure.

In the design of the motor, in addition to utilizing the change of the phase of the alternating current to generate a varying magnetic field, it is also possible to utilize the varying surrounding magnetic field to induce the intermediate rotor to generate a magnetic field, so that the rotor can be wound without the need for a carbon brush or the like. The structure of the rotor can be simplified, as shown in Figures 10 and 11, such as the squirrel-cage rotor of the induction motor (single-phase and three-phase), in which the conductive copper piece 92 (or rod) is inserted in the stacked silicon steel core 91 The both ends of the short-circuit ring 93 are squirrel-cage type, and are excited by the surrounding magnetic field to generate eddy current and magnetic force to rotate.

Conventionally, the short-circuit ring 93 is formed by arranging a plurality of short-circuit ring copper pieces 931 on the end of the conductive copper piece 92 protruding from the end surface of the core 91, and passing through the insertion holes on the short-circuit ring copper piece 931 to make each short-circuit ring. The copper sheets 931 can be stacked and welded to each other to a certain thickness.

The manufacturing method of the short-circuit ring 93 has a great disadvantage, because the middle of the short-circuit ring copper piece 931 does not necessarily have a dense fit, and there must be a gap, and each short-circuit ring copper piece 931 is welded once, and the process is performed. It is quite slow, and it is unfavorable for the production of the industry, and the quality cannot be stabilized, and the yield and efficiency are not good.

In view of the above problems and deficiencies of the prior art, the main purpose of the present invention is to provide a rotor short-circuit ring casting mold, which overcomes the trouble and inconvenience of the conventional short-circuit ring manufacturing by the innovation of the casting mold structure.

According to the above object of the present invention, a rotor short-circuiting ring casting mold is proposed for sheathing one end of a core of a squirrel cage rotor to surround a plurality of conductive copper sheets protruding from the end face of the iron core to facilitate the casting process. The utility model comprises: an upper mold cover, a lower mold cover, an outer ring seat, an inner ring seat, a porous ring piece, and a bundle of ring sets. Fixing the outer ring of the core through the bundle of bundles, supporting the porous ring piece, the inner ring seat, the outer ring seat, the lower mold cover, and the upper mold cover which are sequentially nested on the end face of the core A plastic chamber is defined at the free ends of the conductive copper sheets to provide a copper casting solution, and an integrally formed short-circuit ring is cast at the free ends of the conductive copper sheets.

1‧‧‧Upper mold cover

12‧‧‧Upper mold slot

14‧‧‧Secondary runner

16‧‧‧Positioning bumps

18‧‧‧ injection hole

2‧‧‧ Lower mold cover

22‧‧‧ lower mold slot

24‧‧‧Sewer runner

26‧‧‧ positioning groove

242‧‧‧Channel hole

3‧‧‧ outer ring seat

4‧‧‧ Inner Ring Block

5‧‧‧porous ring

52‧‧‧copper perforation

6‧‧‧Bundle ring group

62‧‧‧ half ring

64‧‧‧Impressive bolts

66‧‧‧Adjusting bolts

621‧‧‧Lock block

622‧‧‧Keyhole

623‧‧‧Adjust keyhole

624‧‧‧Class end face

71‧‧‧Lock column

72‧‧‧ shaft seat

73‧‧‧ Screw components

91‧‧‧鐡芯

911‧‧‧ shaft hole

92‧‧‧ Conductive copper sheet

93‧‧‧short ring

931‧‧‧ Short circuit copper

101~107‧‧‧Steps

922‧‧‧through hole

S‧‧‧Shaping room

C‧‧‧short ring

Figure 1 is a schematic diagram of the decomposition of the local components of the rotor short-circuit ring casting mold (1).

Figure 2 is a schematic diagram of the decomposition of the local components of the rotor short-circuit ring casting mold (2).

Fig. 3 is a schematic view showing the centrifugal casting method of the rotor short-circuit ring casting mold of the present invention.

Figure 4 is a schematic diagram of the decomposition of the core of the rotor.

Figure 5 is a schematic diagram of the combination of casting short-circuit ring casting molds (1).

Figure 6 is a schematic diagram of the combination of casting short-circuit ring casting molds (2).

Figure 7 is a cross-sectional view of the embodiment 7-7 shown in Figure 6.

Fig. 8 is a schematic view showing the operation of the section line 8-8 shown in Fig. 6.

Fig. 9 is a schematic view showing the structure of the rotor in which the short circuit is integrally formed.

Figure 10 is a partial cross-sectional view of the embodiment shown in Figure 9.

Figure 11 is a schematic view of a rotor structure with a short-circuit ring.

Figure 12 is a partial schematic view of the embodiment shown in Figure 11.

Hereinafter, the embodiment of the rotor short-circuit ring casting mold of the present invention will be further described with reference to the related drawings. In order to facilitate the understanding of the present embodiment, the same components are denoted by the same reference numerals. However, the examples provided are not intended to limit the scope of the present invention, and the description of the structure operation is not intended to limit the order in which they are performed. Any device that is recombined by components will produce equal devices. The scope covered by the creation.

The drawings are for illustrative purposes only and are not drawn to the original dimensions. On the other hand, well-known components and steps are not described in the embodiments to avoid unnecessarily limiting the present invention.

Referring to Figures 1 to 2 and 11, the rotor short-circuiting ring casting mold of the present invention is used to be sleeved on one end of a core 91 of a squirrel-cage rotor to surround each conductive copper piece of the end face of the protruding iron core 91. 92. The enriching casting process comprises: an upper mold cover 1, a lower mold cover 2, an outer ring seat 3, an inner ring seat 4, a porous ring piece 5, and a bundle of ring sets 6.

The upper mold cover 1 has an upper die groove 12, a plurality of upper split channels 14, a plurality of positioning bumps 16, and at least one liquid injection hole 18 integrally formed. The upper mold groove 12 is formed with an open recess facing downward to form the upper mold cover 1 facing the lower end surface. Each of the upper split runners 14 is formed with a downwardly open recess to form a bottom surface of the upper mold groove 12, and each of the upper split runners 14 is closed at one end thereof in the extending direction. Each of the positioning bumps 16 is formed on the bottom surface of the upper mold groove 12. The liquid injection hole 18 is formed by the top and bottom of the upper mold cover 1 . And communicating with each of the upper shunt passages 14 with respect to the other end of the closed end. When implemented, the contour of the liquid injection hole 18 is tapered, and each positioning bump 16 can be selectively omitted.

The lower mold cover 2 has a peripheral contour which is formed to match the upper mold groove 12, so that the lower mold cover 2 is inserted into the upper mold cavity 1 with the top end surface. The lower mold cover 2 has an integral lower die groove 22, a plurality of lower split channels 24, a plurality of positioning grooves 26, and a plurality of flow passage holes 242. The lower mold groove 22 is formed in a downwardly open recess and formed on the lower end surface of the lower mold cover 2. Each of the lower split runners 24 is recessed and formed on the top end surface of the lower mold cover 2, and is open upwardly to match the upper split runners 14, and one end of each of the lower split runners 24 extends in communication with each other, and the liquid injection hole 18 The position corresponds, and the other end is closed. Each of the positioning grooves 26 corresponds to each of the positioning bumps 16 , and the recess is formed on the top end surface of the lower mold cover 2 . Each of the flow passage holes 242 is formed at the closed end of each of the lower bypass passages 24 through the lower mold cover 2 .

The outer ring seat 3 is a hollow annular body, and the outer peripheral edge thereof is matched with the lower mold cavity 22 of the lower mold cover 2, so that the outer ring seat 3 is inserted into the lower mold cover 2 under the cavity 22 by the top end surface. . When implemented, the inner diameter of the outer ring seat 3 matches the outer diameter of the porous ring piece 5.

The inner ring seat 4 is a hollow annular body. The top end surface of the inner ring seat 4 abuts against the lower mold cavity 22 of the lower mold cover 2, and the bottom end surface of the inner ring seat 4 abuts against the iron core 91. Axial end face.

The porous ring piece 5 is a hollow annular piece whose inner diameter matches the outer circumference of the inner ring seat 4 to provide the inner ring seat 4 to extend. The porous ring piece 5 has a plurality of copper plate perforations 52. The copper plate perforations 52 are formed in a top and a bottom through the porous ring piece 5. The conductive copper sheets 92 at one end of the iron core 91 are correspondingly stretched. In practice, each of the copper plate perforations 52 is sized to selectively provide a single piece or a plurality of pieces of conductive copper piece 92 for penetration.

The bundle ring set 6 includes two half rings 62, two pressing bolts 64, and at least one adjusting bolt 66. The semi-rings 62 are matched to the outer circumference of the core 91 The same member is formed and selectively fixed to the outer periphery of the core 91 by means of a mirror. Each of the half rings 62 has two locking blocks 621, two locking holes 622, at least one adjusting locking hole 623 and a class end surface 624. Each of the locking blocks 621 is formed from a free end of the semicircular ring and extends radially outwardly, and each of the locking blocks 621 is formed with a locking hole 622, and the pressing bolt 64 is provided to extend the screw to lock the two half rings 62. The outer periphery of the core 91. The adjustment lock hole 623 is formed through the half ring 62, and the adjustment bolt 66 is screwed and extended to adjust the half ring 62 to be properly abutted against the outer peripheral side of the core 91. The class end surface 624 is formed on the top end surface of the half ring 62.

Therefore, the above description is a preferred embodiment of the rotor short-circuit ring casting mold, the introduction of various components and assembly methods, and then the centrifugal casting method of the rotor short-circuit casting mold of the present invention, please refer to Figure 3, I introduce the following, which includes:

Step 101: Locking a lock cylinder through the iron core; as shown in Figures 4 and 5, after the lock cylinder 71 is inserted into the shaft hole 911 of the iron core 91, the sleeve is locked and locked to the lock cylinder 71. The shaft seat 72 and the screwing member 73 are configured to restrain the core 91 from undesired deformation due to heat.

Step 102: Fixing the bundle of bundles to the radially outer periphery of the core; as shown in FIG. 5, the half ring 62 is correspondingly placed on the outer periphery of the core 91 at a predetermined position, and then the tension bolt 64 is extended. The keyhole 622 is locked.

Step 103: The porous ring piece is sleeved on the outer periphery of the conductive copper piece; as shown in FIG. 7, the copper plate perforation 52 on the porous ring piece 5 respectively corresponds to the respective conductive portions of the end face of the core 91. Copper sheet 92.

Step 104: Concentrically enclose the inner and outer ring seats in the inner and outer diameter sides of the porous ring piece; as shown in Figures 6 and 7, the inner ring seat 4 is stacked on the end face of the core 91 and the porous ring piece 5 The inner diameter surface abuts, and the outer ring seat 3 is superposed on the bundle ring group 6 and abuts against the outer diameter surface of the porous ring piece 5.

Step 105: stacking the lower mold cover on the top surface of the inner and outer ring seats; as shown in Fig. 7, the lower mold cover 2 is placed against the inner and outer ring seats through the lower mold cavity 21 of the lower mold cover 2. 4, 3 top.

Step 106: stacking the upper mold cover on the lower mold cover; as shown in FIG. 7, the upper mold cover 1 is overlaid on the top end of the lower mold cover 2, and the positioning bump 16 of the upper mold cover 1 is matched. The positioning recess 26 of the lower mold cover 2 facilitates alignment of the upper and lower mold covers 1, 2 and the lower divided flow paths 14, 24.

Step 107: Centrifugally cast a short-circuit ring; as shown in FIGS. 8 to 10, inject the copper liquid casting liquid into the liquid injection hole 18 of the upper mold cover 1, and mix the split flow of the upper and lower split flow passages 14, 24 to make copper The casting fluid flows into the shaping chamber S defined by the porous ring piece 5, the inner ring seat 4 (outer diameter surface) and the outer ring seat 3 (inner diameter surface) from the respective flow path holes 242, so that the copper casting liquid can be The conductive copper sheet 92 covering the porous ring sheet 5 is further rotated, so that the high-quality copper material in the copper casting liquid in the molding chamber S can be covered with the outer periphery of the conductive copper sheet 92, and the bubbles and impurities can be The inner ring seat 4 (outer diameter surface) is concentrated, and the cutting or grinding after demolding can further remove the impurities.

In addition, as shown in Figures 9 and 10, the copper casting solution and the conductive copper sheet 92 are provided with a hook device, and the hook device can be a through hole 922 or a recess for penetrating each conductive copper sheet 92. The short circuit ring C formed by cooling the copper casting liquid can surely hook the conductive copper sheets 92 so that the conductive copper sheets 92 cannot be easily detached.

The above description is only for the preferred embodiment of the present invention, and is intended to clarify the features of the present invention, and is not intended to limit the scope of the present embodiment, and the average variation made by those skilled in the art according to the present creation. Changes that are well known to those skilled in the art, and still fall within the scope of this creation.

1‧‧‧Upper mold cover

12‧‧‧Upper mold slot

14‧‧‧Secondary runner

16‧‧‧Positioning bumps

18‧‧‧ injection hole

2‧‧‧ Lower mold cover

22‧‧‧ lower mold slot

24‧‧‧Sewer runner

242‧‧‧Channel hole

26‧‧‧ positioning groove

3‧‧‧ outer ring seat

4‧‧‧ Inner Ring Block

5‧‧‧porous ring

52‧‧‧copper perforation

62‧‧‧ half ring

71‧‧‧Lock column

72‧‧‧ shaft seat

73‧‧‧ Screw components

91‧‧‧鐡芯

92‧‧‧ Conductive copper sheet

922‧‧‧through hole

S‧‧‧Shaping room

Claims (4)

The utility model relates to a rotor short-circuit ring casting mold, which is arranged on one end of a core of a squirrel cage rotor to surround a plurality of conductive copper sheets protruding from the end surface of the iron core to facilitate the casting process, comprising: an upper mold cover, Forming an upper die groove, a plurality of upper split channels, and at least one liquid injection hole; the upper die groove is formed by a downward opening recess formed on the lower end surface of the upper die cover; each of the upper split runners is open downwardly downwardly Forming a bottom surface of the upper mold groove, and each of the upper split flow passages is closed at one end of the extending direction; the liquid injection hole bottom is formed through the upper mold cover, and the other end of the upper split flow passage is opposite to the closed end Connecting the outer mold cover with the outer peripheral contour matching the upper mold groove, so that the lower mold cover is inserted into the upper mold groove with the top end surface, and the lower mold cover has an integral lower mold groove and a plurality of lower split runners. And a plurality of runner holes; the lower die groove is formed in a downwardly facing recessed end surface of the lower die cover; each of the lower split runners is recessed and formed on the top end face of the lower die cover, and is open upwardly to match Each of the upper split runners and each of the lower split runners Communicating with the end of the injection hole, while the other end is different from the closed form; each of the flow passage holes through the top and bottom lines of the lower mold formed in each of the cover at the closed end of the shunt; An outer ring seat is a hollow annular body, the outer periphery of which is matched with the lower die groove, so that the outer ring seat is inserted into the lower die groove with the top end face; an inner ring seat is a hollow An annular body, the top end of the inner ring seat abuts against the lower die groove, and the bottom end surface of the inner ring seat abuts against the axial end surface of the iron core; a porous ring piece is a hollow ring shape a sheet body having an inner diameter matching the outer circumference of the inner ring seat, providing the inner ring seat to extend, and the outer peripheral edge abutting the inner diameter surface of the outer ring seat, the porous ring piece having a plurality of copper plate perforations; The copper perforation top and bottom are formed through the porous ring sheet, and each of the conductive copper sheets is correspondingly stretched; a bundle of loops is fastened to the outer periphery of the core, supporting the bottom end of the outer ring seat, including two a semi-ring, two pressing bolts, and at least one adjusting bolt; each of the half rings has two locking blocks integrally formed, and two locking holes; the locking blocks extend radially outward from the free end of the half ring Forming, and each of the lock blocks is formed with a locking hole, and each of the pressing bolts is provided with a screw to lock each of the semi-rings on the outer circumference of the core Wherein, the porous ring piece, the inner ring seat (outer diameter face) and the outer ring seat (inner diameter face) jointly define a molding chamber, and the free ends of the conductive copper sheets of the porous ring piece are wound around Inject and shape the copper casting liquid. The rotor short-circuit ring casting mold according to claim 1, wherein the upper mold cover further has a plurality of positioning bumps, each of the positioning bumps being formed on a bottom surface of the upper mold groove; the lower mold cover matching each of the positioning positions The bump further has a plurality of positioning grooves, and each of the positioning grooves is formed on the top end surface of the lower mold cover. The rotor short circuit ring casting mold according to claim 1, wherein each of the half rings further has at least one adjusting key hole formed through each of the half rings, and an adjusting bolt is screwed through. Stretch. The rotor short-circuit ring casting mold according to claim 1, wherein each of the half rings further forms a class end surface on the top end surface.