JP2022112221A - Armature insulator for outer rotor generator - Google Patents

Abstract

To facilitate automation of an armature coil winding work and to prevent contact with crossover wires of other phases.SOLUTION: On the front side of an armature insulator that covers both sides of an armature core of an outer rotor generator and the periphery of the salient pole, on the front side where a crossover wire is arranged, on the front side in the coil winding direction of a root portion of the salient pole, guide projections 12V to 12W2 protruding from the front side surface are provided. The guide projections guide crossover wires 17U to 17W at the shortest distance from the winding end portion of the armature coil wound around the immediately preceding salient pole of each phase to the winding start portion of the salient pole. In addition, stepped portions 13U1 to 13W2 are provided at the locations where the crossover wire passes between the winding start portion and the winding end portion of each phase coil, and the stepped portion at the winding end portion is higher than the winding start portion, and the height of the stepped portion of each phase is increased in order of the first phase, the second phase, and the third phase.SELECTED DRAWING: Figure 5

Description

The present invention relates to an armature insulator for an outer rotor generator that insulates armature coils of the outer rotor generator from salient poles.

The outer rotor generator has an armature core having a large number of salient poles protruding radially from the outer periphery, and is fixed on the axial center side. A magnet rotor is disposed so as to surround the in a ring shape, and power is generated by rotating the magnet rotor. In order to insulate the armature coil from the armature core, the core is covered with an armature insulator, and the armature coil is wound around the armature insulator.

Armature coils generally have a three-phase configuration, and the coils of each phase are connected in series with each other via a crossover wire. The crossover wires are arranged so as to extend in the circumferential direction while intersecting each other, but there is a possibility that the crossover parts rub against each other and deteriorate the insulation. In particular, in the case of a generator driven by an engine, the vibration is intense and there is a high risk of insulation deterioration. In addition, since there is a risk that the crossover wire may get caught in the drive shaft that is arranged through the center of the armature core, it is necessary to hold the position of the crossover wire so that it does not shift toward the center. There is

Conventionally, in the armature insulator for an outer rotor generator disclosed in Patent Document 1, a protrusion extending in the circumferential direction is provided at the base of the salient pole of a bobbin for insulating the armature coil from the salient pole of the armature core. A guide groove is provided on the outer surface of the protrusion so that the wire is accommodated and held in the guide groove. By doing so, the crossover wires between the different phases are reliably held insulated from each other, and entanglement into the drive shaft can be reliably prevented.

Microfilm of Japanese Utility Model Application No. 61-145471 (Japanese Utility Model Application No. 63-51544)

The work of winding the armature coils of an outer rotor generator is being automated for the purpose of improving work efficiency. Since each phase is different, a special jig is required to guide the crossover wire of each phase and store it in the groove. Moreover, in the above conventional armature insulator, the crossover wire in the portion continuing to the coil winding start and the crossover wire in the portion extending from the winding end of each phase intersect between the ribs or beyond the ribs. There is also a problem that there is a possibility that the two parts may come into contact with each other.

SUMMARY OF THE INVENTION In view of such problems, it is an object of the present invention to facilitate the automation of the winding work and to completely prevent contact between crossover wires of armature coils.

In order to solve the above-mentioned problems, the invention according to claim 1 of the present application fixes and arranges an annular armature core having a large number of salient poles projecting radially from an outer peripheral portion, and armature coils are attached to the salient poles. The armature coil has a three-phase configuration, the coils of each phase are connected in series via a crossover wire, and the rotor is disposed so as to concentrically surround the outer circumference of the armature core, An armature insulator that covers both side surfaces of the armature core and the periphery of the salient poles of an outer rotor generator that generates power by rotating the rotor in the circumferential direction, the armature insulator covering the gap. On the front side where the wire is arranged, a guide projection projecting from the front side surface is provided on the front side of the root portion of the salient pole in the coil winding direction, and the guide projection guides the crossover wire to the projection immediately before the phase. The armature coil on the front side of the armature insulator is guided so as to be arranged in the shortest distance from the winding end portion of the armature coil wound on the pole to the winding start portion of the armature coil on the salient pole. A stepped portion is provided at the root portion of the salient pole where the crossover wires of the winding start portion and winding end portion of each phase coil pass, and the height of the stepped portion of the winding end portion is greater than the height of the stepped portion of the winding start portion. Further, the steps are provided so that the step portions of the respective phases become higher in order of the first phase, the second phase and the third phase.

Further, the invention according to claim 2 of the present application is the invention according to claim 1, wherein a concave portion lower than the height of each step is provided between each of the two steps of the second phase and the third phase. Characterized by

Further, the invention according to claim 3 of the present application is characterized in that, in the invention according to claim 1 or 2, a shielding wall is provided on the inner peripheral edge of the armature insulator so as to protrude to the front side.

ADVANTAGE OF THE INVENTION This invention has the following effects.
That is, in the invention according to claim 1, on the front side of the armature insulator on which the crossover wires are arranged, the guide protrusion protrudes from the front side surface of the root portion of the salient pole toward the front side in the coil winding direction. is provided, and the crossover wire is arranged at the shortest distance from the winding end portion of the armature coil wound on the salient pole immediately before the phase to the winding start portion of the armature coil of the salient pole. In addition, stepped portions are provided at the roots of the salient poles on the front side of the armature insulator where the crossover wires at the winding start and winding end portions of each phase coil pass, and the step at the winding start portion is provided. The height of the stepped portion at the winding end portion is higher than that of the winding end portion, and the steps are provided so that the stepped portion of each phase becomes higher in the order of the first phase, the second phase, and the third phase. As a result, by providing the guide protrusion, automation of the winding work is facilitated, and by increasing the height of the stepped portion in order of the first phase, the second phase, and the third phase, the crossing wire of the first phase , the second-phase crossover wire, and the third-phase crossover wire. Gone.

Further, in the invention according to claim 2, in the armature insulator for the outer rotor generator according to claim 1, between the two stepped portions of the second phase and the third phase, the height of each stepped portion is higher than the height of each stepped portion. Since a low concave portion is provided at the winding start of each phase, a space is provided for the crossing wire to escape, making it easier to guide the armature coils to the bottom of the salient poles, and the winding start of the crossing wire for each phase becomes easier. The sections and the winding end sections can be crossed without contacting each other.

In the invention according to claim 3, in the armature insulator for the outer rotor generator according to claim 1 or 2, a shielding wall is provided on the inner peripheral edge of the armature insulator so as to protrude to the front side. Therefore, even if the connecting wire becomes loose, it can be prevented from slipping toward the shaft.

FIG. 2 illustrates an armature core and an armature insulator according to one embodiment of the present invention; FIG. 2 is an enlarged view of the portion indicated by X in FIG. 1; It is a figure which expands and shows a crossover wire guide part. FIG. 5 is a diagram showing a crossing wire installation path for each phase in a crossing wire guide section; FIG. 4 is a diagram showing a crossing wire arrangement state of each phase in a crossing wire guide portion; It is a figure which shows the state by which the U-interconnection wire was arrange|positioned. It is a figure which shows the state by which the V-interconnection wire was arrange|positioned. It is a figure which shows the state by which W interconnection wire was arrange|positioned. It is a figure which shows the connection of the winding start part of each phase coil, and the winding end part.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

FIG. 1 shows an armature core and an armature insulator according to one embodiment of the present invention. In FIG. 1, reference numeral 1 denotes the armature insulator front half, 2 the armature core, and 3 the armature insulator back half.

Here, of the two side surfaces of the armature core 2, the side on which the crossing wire is arranged is referred to as the "front side", and the opposite side is referred to as the "back side". The height is called "height". In addition, in the portion where the crossover wire is arranged, the side on which the rotating shaft of the generator is located is referred to as "inner side", and the opposite side is referred to as "outer side".

Also, here, a case where the present invention is applied to a generator for an engine welder will be described. Armature insulator front side half 1 and armature insulator back side half 3 are applied from both sides of armature core 2, and the fitting portions of the two are fitted through salient poles 2a to form armature core 2. cover both the front and back sides of and the periphery of the salient pole 2a. Crossover wire guides for arranging crossover wires of respective phases are provided on the periphery of the portion of the armature insulator front side half 1 corresponding to the root portion of the salient pole 2a.

2 is an enlarged view of the portion indicated by X in FIG. 1, and FIG. 3 is an enlarged view of the crossover wire guide portion. 2 and 3, reference numeral 11 is a bobbin portion arranged so as to wrap the salient pole 2a and for winding a coil around its outer periphery, 11a is a separation wall for separating the auxiliary output coil and the welding output coil, and 11b. is a fitting portion for fitting and integrating with the armature insulator back side half portion 3, and 12 _V to 12 _W2 are the winding start portions of the next bobbin portion 11 from the winding end of each bobbin portion 11 when winding the coil. A guide projection for guiding the wire, which is provided on the front side of each salient pole 2a in the winding direction. 13 _U1 to 13 _W2 are the winding start and winding end portions of the coil of each salient pole 2a, and are step portions for providing a step so that the crossover wires do not contact each other. It is provided at the place where the crossing wire passes. 14 _V and 14 _W are the winding start and winding end portions of the coils of the V-phase and W-phase salient poles 2a, and recesses for softening bending of the crossing wire at the corner portions of the stepped portions 13 _V1 to 13 _W2 . , 15 are shielding walls for preventing the crossing wires from loosening and slipping toward the shaft.

The auxiliary output coil is for extracting AC power as an external output from the engine welder, and is wound around the inner portion of each bobbin portion 11. It has a three-phase configuration, and the coil of each phase is connected via a connecting wire. connected in series with each other. The welding output coil is for obtaining the welding output of the engine welder, is separated from the auxiliary output coil by the separation wall 11a, and is wound around the outer portion of the bobbin portion 11. Each coil is connected in parallel. be. Here, the connecting wire guide section is used to arrange the connecting wires of the auxiliary output coils.

The guide projections 12 _V to 12 _W2 , stepped portions 13 _U1 to 13 _W2 , and recessed portions 14 _V and 14 _W , which constitute the crossing wire guide portion, are blocked for each phase of U phase, V phase, and W phase. . That is, the steps _13U1 and _13U2 are U-phase blocks, the guide projections _12V , the steps _13V1 and _13V2 and the recesses 14V are _V -phase blocks, the guide projections _12W1 and _12W2 , the step portions _13W1 , _13W2 and recesses 14W form a _W -phase block. Three blocks of U-phase, V-phase, and W-phase constitute one set, and one set forms an angle of 45° around the central axis of the generator. placed.

Among the crossover wire guide portions, the guide protrusions 12 _V to 12 _W2 are the tallest, for example, 16.7 mm, and the heights of the stepped portions 13 _U1 and 13 _U2 of the U-phase block are equal to the height of the stepped portion 13 _U1 . The height of the steps _13U2 is set to be slightly larger than the thickness of the windings, for example 4 mm, so that the coils that cross each other do not come into contact with each other. The height of the stepped portion _13V1 of the _V -phase block is higher than the stepped portion _13U2 of the U-phase block, for example, 6 mm. Let the increased height be, for example, 8.4 mm. The height of the stepped portion _13W1 of the _W -phase block is higher than that of the stepped portion _13V2 of the V-phase block, for example, 10.5 mm. The height should be slightly larger than the height, for example 12.5 mm.

The guide projections 12 _V to 12 _W2 are provided so as to be positioned on the front side in the winding direction of each salient pole 2a _. It faces along the path, hooks the crossing wire of the V-phase coil, and guides the crossing wire so that the crossing wire is arranged at the shortest distance from the winding end portion to the winding start portion. One guide projection _12W1 of the W-phase block has one surface of its peripheral wall facing along the route of the W-phase crossover wire, and hooks the W-phase coil crossover wire to the crossover wire. is arranged at the shortest distance from the winding end portion to the winding start portion. The other guide projection 12 _W2 of the W-phase block has its corners facing along the route of the U-phase crossover wire, and hooks the U-phase coil crossover wire to the crossover wire. is arranged at the shortest distance from the winding end portion to the winding start portion. One surface of the peripheral wall of the guide projection 12 _W2 faces along the path of the crossover wire drawn out from the winding end portion of the W-phase coil. It also guides the lines.

In addition, the stepped portions 13 _U1 to 13 _W2 not only regulate the height position of each crossing wire, but also the peripheral wall surface is angled along the path through which each crossing wire passes. Each crossing line is guided.

FIG. 4 is a diagram showing a connecting wire route for each phase in the connecting wire guide section, and FIG. 5 is a diagram showing a connecting wire arrangement state for each phase in the connecting wire guide section. 4 and 5, the solid line 16 _U is the U-phase crossover wire route, the broken line 16 _V is the V-phase crossover wire route, the dotted line 16 _W is the W-phase crossover wire route, and 17 _U to 17 _W is a crossover wire. 5, the _U -phase transition line 17U is indicated by a solid line, the _V -phase transition line 17V is indicated by a broken line, and the _W -phase transition line 17W is indicated by a dotted line. The coils shown are omitted, and only the crossover wires 17 _U to 17 _W are shown.

As is clear from FIGS. 4 and 5, the height of the stepped portion of each phase is set as described above, so that the crossing wire for each phase is the lowest for the U phase, the middle for the V phase, and the middle for the V phase. The W phase is positioned at the top. Therefore, the armature coils are wound in the order of the U-phase, V-phase and W-phase. Therefore, first, the U-phase coil is wound.

As indicated by a solid line 16U in FIG. 4, the _U -phase crossover line extends from the winding end portion of the U-phase bobbin portion not shown in FIG. 4 to the winding start portion of the U-phase bobbin portion 11. and wound around the bobbin portion 11 of the U phase, from the winding end portion to the upper surface of the stepped portion _13U2 , the peripheral wall surfaces of the stepped portions _13V1 , _13V2 , _13W2 , and the corners of the guide projection _12W2 . , the upper surface of the stepped portion _13U1 and the peripheral wall surface of the stepped portion _13U2 . As a result, the _U interconnection wire 17U is arranged as shown in FIG.

Next, regarding the V-phase coil, the V-phase crossover line extends from the winding end portion of the _V -phase bobbin portion (not shown in FIG. 4) to the step portion _13W1 , as indicated by the dashed line 16V. , 13 _W2 , 13 _U2 , guide protrusion 12 _V , the upper surface of stepped portion 13 _V1 and the peripheral wall surface of stepped portion 13 _V2 . be killed. After being wound on the V-phase bobbin portion 11, the arrangement position is restricted by the upper surface of the stepped portion _{13V2 and the peripheral wall surfaces of the stepped portions 13W1 , 13W2} , and _13U2 from the winding end portion, while the V-phase is led to the winding start portion of the bobbin portion 11 at the next stage. As a result, the _V -interconnection line 17V is arranged as indicated by the dashed line in FIG.

As indicated by a dotted line 16W, the _W -phase crossing line extends from the winding end portion of the W-phase bobbin portion 11 in the preceding stage to the upper surface of the stepped portion _13W2 , the peripheral wall surface of the guide projection _12W2 , the stepped portion _13U2 , . _13V2 , the peripheral wall surface of the guide projection _12W1 , and the upper surface of the stepped portion _13W1 . After being wound on the W-phase bobbin portion 11, the arrangement position is restricted by the upper surface of the stepped portion _13W2 , the peripheral wall surface of the guide projection _12W2 , and the peripheral wall surface of the stepped portion _13U2 from the winding end portion. It is guided to the winding start portion of the next bobbin portion 11 of the W phase. As a result, the _W crossover wire 17W is arranged as indicated by the dotted line in FIG.

In this armature insulator, as shown in FIG. 5, the heights of stepped portions 13 _U1 to 13 _W2 are increased in the order of U-phase, V-phase, and W-phase. Since the two step portions are provided with a step, the winding start and winding end portions of the crossover wires 17 _U to 17 _W of each phase intersect each other without coming into contact with each other. The U-phase crossover wire 17 _U , the V-phase crossover wire 17 _V , and the W-phase crossover wire 17 _W increase in this order, and the crossover wires of the respective phases are arranged at different height positions. Therefore, the crossover wires do not come into contact with each other between the phases.

In addition, as shown in FIGS. 6 to 8, the crossing wires of each phase are separated from the winding end portion of the preceding bobbin portion 11 by the guide projections 12 _V to 12 _W2 and stepped portions 13 _U1 to 13 _W2 . It is linearly guided up to the winding start portion of 11 and arranged in the shortest distance.

In this way, the crossing wire of each phase is pulled straight from the winding end part of the previous stage and pushed against the stepped part from the front side, hooked on the guide projection in front of the winding start part to start winding the coil. Since it is sufficient to repeat this in the order of U phase, V phase, and W phase, automation of the work is facilitated.

In addition, since the recesses 14 _V and 14 _W are provided in the V-phase and W-phase blocks, the V-phase crossover wire 17 _V and the W-phase crossover wire 17 _W have large stepped portions 13 _V1 to 13 _W2 . can be arranged without being subjected to excessive bending even at the corners.

As shown in FIG. 9, the winding start portions of the respective phases of the auxiliary output coils are collectively connected by a connection tool 19 to form a neutral point, and the winding end portions are pulled out individually to form U and V coils, respectively. , W-phase leads.

Further, in the above embodiment, the present invention is applied to the generator of the engine welder and the connecting wire of the auxiliary output coil is treated. It can also be applied to armature coils individually wound around each salient pole of the machine armature core.

1 Armature insulator front side half 2 Armature core 2a Salient pole 3 Armature insulator back side half 11 Bobbin part 11a Separation wall 11b Fitting part 12 _V to 12 _W2 guide projection 13 _U1 to 13 _W2 stepped part 14 _V , 14 _W recess 15 Shielding wall 16 _U to 16 _W crossover wire installation path 17 _U to 17 _W crossover wire 18 _U to 18 _W coil 19 Connector

Claims (3)

An annular armature core having a large number of salient poles protruding radially from the outer periphery is fixedly arranged, and an armature coil is wound around the salient poles. coils are connected in series with each other via a crossing wire, a rotor is disposed so as to concentrically surround the outer circumference of the armature core, and the rotor is rotated in the circumferential direction to generate power. , an armature insulator covering both side surfaces of the armature core and the periphery of the salient pole,
On the front side of the armature insulator where the crossover wire is arranged, a guide projection protruding from the front side surface is provided on the front side in the coil winding direction of the base portion of the salient pole, and the crossover wire is moved by the guide projection. is arranged at the shortest distance from the winding end portion of the armature coil wound around the salient pole immediately before the phase to the winding start portion of the armature coil of the salient pole, A stepped portion is provided at the root portion of the salient pole on the front side of the armature insulator at a portion where the crossover wire passes at the winding start portion and the winding end portion of each phase coil, and the winding ends from the winding start portion at the stepped portion. An outer rotor power generation characterized in that the height of the stepped portion of each phase is increased, and the steps are provided so that the height of the stepped portion of each phase increases in the order of the first phase, the second phase, and the third phase. Machine armature insulator. 2. An armature insulator for an outer rotor generator according to claim 1, wherein a recess lower than the height of each step is provided between each of the two steps of the second and third phases. 3. An armature insulator for an outer rotor generator according to claim 1, wherein a shielding wall is provided on the inner peripheral edge of the armature insulator so as to protrude to the front side.

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