JP2017208895A - Improved structure for motors with internally installed capacitor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an improved simple structure for a motor in which a capacitor is installed within the motor to keep the electromagnetic field of the motor relatively free from interference.SOLUTION: A motor comprises a casing, a stator, an insulative element and a rotor. The casing accommodates the stator including its front and rear lids, and the stator has an iron core frame provided with an annular insulating frame body for connection to the insulative element. On one side periphery of the insulating frame body, annularly arranged plural pin parts are extended, and on the periphery of the bottom part of the insulative element, plural slot parts are disposed. Each of these slot parts is connected to one or another of the pin parts, and the rotor is housed in the stator. In this way, the capacitor is combined in a pair of housing spaces in the insulative element communicating with outside, resulting a structure in a simple structure in which the capacitor is fitted to the motor and the electromagnetic field of the motor is relatively free from interference.SELECTED DRAWING: Figure 2

Description

  The present invention is an improved structure of an internal capacitor motor, in particular, a structure of an internal capacitor motor in which a capacitor is mounted inside the motor, the structure is simple, and the electromagnetic field of the motor is not relatively interfered.

  As seen from the characteristics of a motor that rotates by a single-phase induction capacitor, it is necessary to connect a capacitor to the motor, and the capacitor is mainly mounted on the motor housing surface. As a result, the housing of the capacitor is damaged or cracked, the inside of the capacitor is expanded, and the property of the electrolytic substance is changed.

  Therefore, a structure in which a capacitor is installed inside the motor has been developed by the engineer. Referring to FIG. 1 which is a perspective view of the structure of a commonly used capacitor motor, the motor 1 includes an iron frame 12 therein. The iron frame 12 has two casings 11, and a plurality of coils 13 (that is, winding resistances) arranged in an annular shape and arranged at intervals are wound around each other so as to correspond on the arcuate circuit board 14. By vertically installing a plurality of capacitors 15 arranged at intervals, the capacitors 15 are inserted between the coils 13 until the arcuate circuit board 14 is engaged with the core frame 12. However, in the structure described above, although these capacitors 15 are installed inside the motor 1, as can be seen from the principle, the motor 1 When rotating, an electromagnetic field is generated, the electromagnetic field is operated around the coil 13, and the capacitor 15 belongs to an energy storage element, and generates an electromagnetic field after being energized. Therefore, the electromagnetic field when the motor 1 is operated is Although the electromagnetic field generated by the capacitor 15 causes interference, an extra electromagnetic energy loss occurs in the motor 1, and the final operation function of the motor 1 is not significantly affected. Will increase.

  In addition, these capacitors 15 are energized only when the motor 1 is driven, and are immediately turned off after the operation, but as is understood from the principle and the characteristics of the capacitors 15, they are generated between the coils 13. The electromagnetic field is affected by the interference of the capacitor 15 and extra electromagnetic energy loss occurs in the motor 1, but the final operation function of the motor 1 is not significantly affected, but the consumption of electromagnetic energy is relatively increased. Furthermore, the capacitors 15 have a conductive material capable of storing energy, such as an electrolyte, and the coils 13 are made of a metal material such as copper, for example. A so-called stray capacitance is generated due to the limitation that the distance between the capacitor 15 and the capacitor 15 is short, and extra electromagnetic energy is generated in the motor 1. Which leads to the occurrence of Girosu.

  Further, since heat energy is always generated during the operation of the motor 1, the space used for heat dissipation between these coils 13 is occupied by these capacitors 15, and it is difficult for heat energy to be dissipated. Therefore, the thermal energy accumulated by continuous operation for a long time is likely to change the property of the conductive material capable of storing energy such as an electrolyte in the capacitor 15, and further, the capacitor 15 May expand or crack and damage the motor 1.

  Further, even if the ratio allowed for the coil slot is different, it is difficult to actually carry out. When the power of the motor 1 is increased, the size of the coil 13 is increased along with this, and the capacitor capacity is also increased. However, when the coil 13 becomes large, that is, when the distance between the coils 13 becomes small, the capacitor 15 becomes more difficult to install between the coils 13, and the actual It becomes even more difficult to implement.

  SUMMARY OF THE INVENTION In view of the above-mentioned problems of the well-known technique, an object of the present invention is to provide an improved structure of an internal capacitor motor in which a capacitor is mounted inside the motor, the structure is simple, and the electromagnetic field of the motor is not relatively interfered. .

  In order to achieve the above-described object, the present invention provides a casing having a front lid and a rear lid, a stator accommodated in the casing, an insulating element combined with the stator, and a rotor provided in the stator. The stator has an iron core frame on which an annular insulating frame body is provided, and a plurality of pin portions arranged in an annular shape are provided around one side of the insulating frame body. A plurality of slot portions are provided on the edge of the bottom portion of the insulating element, and the insulating elements are installed on the insulating frame body by connecting to the pin portions of the insulating frame body, respectively.

  Based on the structure described above, the insulating element accommodates a capacitor therein.

  Based on the structure described above, these pin portions in the insulating frame body extend toward the front lid, and the insulating element is connected to the insulating frame body to connect the front lid and the stator. Or these pin portions in the insulating frame body extend toward the rear lid, and the insulating element is connected to the insulating frame body and is connected to the rear lid. It is located between the stators.

  Based on the structure described above, the wall surface of the insulating element is provided with one or more elastic hooks.

  Based on the structure described above, a plurality of the insulating elements each having an angular difference are further provided.

It is a perspective exploded view showing the structure of a known capacitor motor. It is a perspective exploded view showing the structure of the present invention. It is a perspective exploded view showing a local structure of the present invention. It is a perspective exploded view showing a local structure of another preferred embodiment according to the present invention. It is a perspective exploded view showing a local structure of still another preferred embodiment according to the present invention. It is a perspective exploded view showing a local structure of another preferred embodiment according to the present invention.

In order to more specifically understand the above-described objects, effects, and features of the present invention, the following description will be given with reference to the drawings.
Referring to FIG. 2 which is a perspective exploded view showing the structure of the present invention, and FIG. 3 which is a perspective exploded view showing the local structure of the present invention, the structure of the motor 2 according to the present invention includes a caging 21 and a stator. 22, the insulating element 23, and the rotor 24. Among these, the caging 21 includes a front lid 211 and a rear lid 212, and the space between the front lid 211 and the rear lid 212. In addition, a space used for accommodating the stator 22, the insulating element 23, and the rotor 24 is formed.

  The stator 22 has an iron core frame 221 provided in the casing 21 and provided with an insulating frame body 222, and a plurality of pin portions 223 extend around one side of the insulating frame body 222. Based on the structure of the iron core frame 221, the insulating frame body 222 is annularly installed inside the iron core frame 221, so that these pin portions 223 extend along the insulating frame body 222. The pin portions 223 are arranged in a ring shape and have a certain distance between them.

  The insulating element 23 has a pair of accommodating spaces 231 that communicate with the outside. The accommodating space 231 is coupled to a capacitor 25, and the coupled capacitor 25 is connected to the insulating element 23. In the drawings according to the present embodiment, the capacitor 25 is shown in the form of charging in the meaning of being put in, but the capacitor 25 is connected, connected, combined, assembled in the insulating element 23. Any technical means to be coupled to the motor 1 such as installation, etc., belongs to the category claimed by the present invention. Adhesive with adhesive material such as adhesive, strong instantaneous adhesive, PU adhesive, emulsion, epoxy resin, AB glue, treatment agent, curing agent, finishing agent, or, for example, Betting, screwed, fitted, likewise present invention also mechanically fixed such removable engagement or the like belongs to the category of claims.

  Further, a plurality of slot portions 232 are provided at the edge of the bottom of the insulating element 23, and when the insulating element 23 is provided corresponding to the insulating frame body 22, the slot portion 232 is in the insulating frame body 222. These pin portions 223 respectively correspond to each other, and more specifically, one or more elastic hooks 233 are further provided on the wall surface of the insulating element 23 in order to further fix the capacitor 25. Thus, the capacitor 25 can be firmly fixed inside the insulating element 23. The rotor 24 is accommodated in the stator 22.

  When assembled, the stator 22 includes the iron core frame 221 provided with the annular insulating frame body 222, and the plurality of pin portions 223 arranged in an annular shape are extended around one side of the insulating frame body 222. The plurality of slot portions 232 are provided at the edge of the bottom of the accommodating space 231 in the insulating element 23, and the slot portions 232 are formed on the pin portion 223 in the insulating frame body 222. By corresponding to each, the insulating element 23 is continuously provided on the insulating frame body 222.

  More specifically, the plurality of pin portions 223 extending around one side of the insulating frame 222 described in the description of the present invention described above may be the front lid 211 or the One of the insulating frame bodies 222 facing the rear lid 212 is pointed, that is, the pin portions 223 of the insulating frame body 222 extend toward the front lid 211, so that the insulating element 23 is connected to the insulating frame body 222, the insulating element 23 is positioned between the front lid 211 and the stator 22, or the pin portions 223 of the insulating frame body 222 are connected to the rear frame body 222. By extending toward the lid 212, the insulating element 23 is positioned between the rear lid 212 and the stator 22 after the insulating element 23 is connected to the insulating frame body 222. Therefore, these pin portions 223 according to the present invention may be installed only on one side of the insulating frame 222 or simultaneously on both sides of the insulating frame 222 according to actual production or manufacturing demand. Since these pin portions 223 extend simultaneously from both sides of the insulating frame 222, one, two or a plurality of the insulating elements 23 are installed according to the actual demand. 222 is connected.

  Accordingly, the motor 1 can reliably install the capacitor 25 inside the casing 21, and at the same time, after the capacitor 25 is installed inside the motor 1, the position of the capacitor 25 is set to the stator 22. As described in the well-known technique, the problem that the magnetic field generated inside the motor 1 is easily interfered by the electromagnetic field is eliminated, and the capacitor 25 is inserted. The method of attaching the insulating frame body 222 provided on the stator 22 after first installing the insulating element 23 on the insulating element 23 has the advantage that it is easy to install and can be performed quickly. 1, it is only necessary to install one capacitor 25, which is a well-known technique illustrated in FIG. 1. As such, compared with a method of installing a plurality of small capacitors 15, the present invention further cost can be suppressed, maintenance has the advantage of easy to perform.

  Next, referring to FIG. 4, which is a perspective exploded view showing a local structure of another preferred embodiment according to the present invention, the present invention is arranged on the insulating frame 222 according to demand during actual use. A plurality of insulating elements 23 are provided, and there is an angle difference between the plurality of insulating elements 23 to match the shape of the annular insulating frame 222. In the drawing according to the present embodiment, the insulating elements 23 are installed in two, preferably in an arrangement that approximates a curved shape, and may be installed in parallel on the insulating frame 222. When three or a plurality of the insulating elements 23 are installed, The insulating elements 23 may be arranged on the insulating frame 222 after being connected to each other, or may be arranged independently of each other. In this embodiment, the method of connecting each other is described. However, it is also within the scope of the present invention to independently install each of the insulating frames 222. ing.

Reference is now made to FIG. 5, which is an exploded perspective view showing the local structure of still another preferred embodiment of the present invention. This embodiment is equivalent to and similar to FIGS. 1 to 4 described above. To point out, the insulating element 23 can be directly formed and coupled to the outside of the capacitor 25 by directly forming the insulating element 23 outside the capacitor 25 in this embodiment. The technical means are as follows.
For example, by applying or adhering a curable adhesive to the surface of the capacitor 25 with a liquid, soft or flexible adhesive, and performing a local coating or a full coating, the surface of the capacitor 25 is The insulating element 23 is combined and formed. Note that the curable adhesive referred to here is a liquid, soft or flexible form of the curable adhesive when it is not applied or attached to the capacitor 25, and applied to the capacitor 25. Alternatively, when attached, for example, photocuring by irradiation with light of a specific wavelength such as ultraviolet light, for example, heat curing such as thermal adhesive, softening after heating or remolding with a liquid, or for example, broad AB glue or epoxy putty After passing through a curing process such as a volatile type in which a specific gas is volatilized and cured, the capacitor 25 is installed inside the motor 2 by directly forming the insulating element 23 outside the capacitor 25. Any combination means that does not interfere with the stator or the rotor belongs to the scope claimed by the present invention.

  Finally, referring to FIG. 6, which is a perspective exploded view showing the local structure of another preferred embodiment of the present invention, this embodiment is equivalent to and similar to FIGS. 1 to 5 described above. In point, in this embodiment, when the inside of the insulating element 23 is coupled to the capacitor 25, the adhesive 26 is further filled in the gap between the insulating element 23 and the capacitor 25, and the motor is operated. Since a vibration and an electromagnetic field are generated during the process, the capacitor 25 can be reliably coupled to the inside of the insulating element 23 by means of filling the adhesive 26, and the component of the adhesive 26 When an additive for shielding an electromagnetic field is included, the electromagnetic shielding effect between the capacitor 25 and the motor 2 can be further improved.

  From the above, the improved structure of the internal capacitor motor according to the present invention surely achieves a structure in which the electromagnetic field of the motor is not easily interfered, and the content of the above description is the preferred embodiment of the present invention. Any change, modification, change or equivalent substitution developed by the technical means and scope of the present invention shall fall within the scope claimed by the present invention.

2 Motor 21 Caging 22 Stator 23 Insulating Element 24 Rotor 25 Capacitor 26 Adhesive 211 Front Lid 212 Rear Lid 221 Iron Core Frame 222 Insulating Frame 223 Pin Portion 231 Housing Space 232 Slot Portion

Claims (8)

Caging including front and back lids;
A stator frame housed in the casing and provided with an annular insulating frame body; around one side of the insulating frame body, a stator extending a plurality of pin portions arranged in an annular shape; and
An insulating element that is connected to the insulating frame body and has a pair of accommodating spaces that communicate with the outside;
An improved structure of an internal capacitor motor that includes at least a rotor housed in the stator,
The stator includes an iron core frame on which an annular insulating frame body is provided, and a plurality of pin portions arranged in an annular shape are provided on one side periphery of the insulating frame body so as to extend from the insulating element. A plurality of slot portions are provided at an edge of the housing space bottom portion, and the plurality of slot portions are respectively connected to the pin portions in the insulating frame body so that the insulating element is installed on the insulating frame body. An improved structure of an internal capacitor motor characterized by   The improved structure of an internal capacitor motor according to claim 1, wherein a capacitor is coupled to the accommodation space in the insulating element.   These pin portions in the insulating frame body extend toward the front lid, and the insulating element is installed so as to correspond to the insulating frame body and is interposed between the front lid and the stator. The improved structure of the internal capacitor motor according to claim 1, wherein the improved structure is located.   These pin portions in the insulating frame body extend toward the rear lid, and the insulating element is installed so as to correspond to the insulating frame body, and between the rear lid and the stator. The improved structure of the internal capacitor motor according to claim 1, wherein the improved structure is located.   The improved structure of an internal capacitor motor according to claim 1, wherein the wall surface of the insulating element is provided with one or more elastic hooks.   The improved structure of an internal capacitor motor according to claim 1, further comprising a plurality of insulating elements each having an angular difference.   The improved structure of an internal capacitor motor according to claim 2, wherein the insulating element is formed outside the capacitor.   The improved structure of an internal capacitor motor according to claim 2, wherein the insulating element is locally or entirely covered outside the capacitor.