KR200422563Y1 - Inverter transformer - Google Patents

Abstract

The present invention provides an inverter transformer, which includes the following, wherein the first coil is wound around the secondary coil, and the hollow part is formed inside the main body, and the second coil is wound around the primary coil. The frame is vertically extended on both outer ends of the main body, and is separately installed and wound around a partial coil of the primary coil, and the hollow part is installed inside the main body, and the second coil and the first coil are also installed. The frame is installed to correspond in parallel. Iron cores are joined to correspond to each other and correspondingly penetrate into the hollows of the first and second coils, and are further composed of main paths, whereby the frames are first coiled through the second coils. Primary coil and its partial coil lead wire are leaded to correspond to both ends of ie, that is, indirect and direct connection is made to the side and both ends of secondary coil to improve overall connection voltage ratio and at the same time, first and second coil Under this corresponding spacing, the leakage inductance of the transformer can be relatively increased to effectively reduce the area material of the winding line of the primary and secondary coils.

Inverter, transformer, coil, coil frame, iron core, frame

Description

Inverter transformer

1 is a schematic perspective view illustrating an exploded first embodiment of the present invention;

Figure 2 is a schematic plan view of assembling the first embodiment of the present invention.

Figure 3 is a schematic perspective exploded view of a second embodiment of the present invention.

Figure 4 is a schematic plan view of assembling a second embodiment of the present invention.

5 is a schematic perspective view illustrating an exploded third embodiment of the present invention;

Figure 6 is a schematic perspective exploded view of a fourth embodiment of the present invention.

Figure 7 is a schematic plan view of assembling a fourth embodiment of the present invention.

8 is a schematic perspective view of the fifth embodiment of the present invention assembled.

** Explanation of symbols for main parts of drawings **

1: First coil 11: Interval sharing part

12: Hollow department 13: Cover joint

14: lead wire terminal 15: groove groove part

16: Frame 2: Second coil

21: Frame 211: Winding line groove

212: Heavy department 22: Heavy department

23: Lead wire terminal 3: Iron core

31 core 1 core 32 core 2 core

4: Primary coil 41: Coil lead wire

5: secondary coil 6: cover

61: The first entrance 62: The second entrance

63 ： Going out

The present invention relates to an inverter transformer, and in particular, to increase the leakage inductance (relative inductance), and at the same time to increase the connection voltage ratio to reduce the winding line area and material of the primary and secondary coils.

In Taiwan Patent Publication No. M269553, "Structural Improvement of Inverter Transformer" is installed by winding the primary coil and the secondary coil to correspond to the winding coil frame. A transformer having a structure is formed so that the primary and secondary coils are completely connected to each other on the same coil frame to have a relatively good induction effect, and at the same time, an effect of increasing the connection voltage ratio.

However, the above-described structure, although the transformer obtains a relatively good response effect, but because the use method is installed in the coil frame winding the primary and secondary coils, leakage inductance is indispensable due to the application demand of the transformer When increasing, this winding necessarily increases the number of installations of the primary and secondary coils relative to the coil frame, which leads to the leakage inductance required for the increase, in which case the primary and secondary coils have an increased winding area and material. Is made essential.

In addition, in Taiwan Patent Publication No. 507224, "Transformers for Inverters," it was found that the primary coil and the secondary coil were respectively installed in two independent winding coil frames, and the two coil frames were not directly contacted. By arranging them in parallel, the gap between the primary and secondary coils is increased to increase the required leakage inductance without increasing the number of windings of the primary and secondary coils.

However, this structure, although the transformer can obtain a relatively good leakage inductance, but because the magnetic flux is often released in the air when these primary and secondary coils are interconnected in practical applications, the induction effect ) Is a disadvantage that the relative voltage ratio of the transformer is not good, the transformer connection voltage ratio is lowered.

Therefore, the technical problem to be solved by the present inventor is to overcome the above-mentioned drawbacks and to relatively increase the leakage inductance and increase the connection voltage ratio. Therefore, the present inventors came up with this inverter transformer.

An object of the present invention is to provide an inverter transformer, which includes the following, the first coil is wound around the secondary coil is installed, the hollow portion is formed inside the main body, the second coil is the primary coil It is wound and installed on both ends of the main body, and the frame is vertically extended, respectively, and a partial coil of the primary coil is wound and installed, and the hollow part is installed inside the main body, and the second coil and the second One coil is installed to correspond in parallel.

The iron core unit is connected to each other and correspondingly penetrates into the hollow portion of the first and second coils, and is composed of a main magnetic path, thereby forming the second coil. The frame is positioned to correspond to both ends of the first coil so that the primary coil and its partial coil are wired, that is, the indirect and direct connections are made to the sides and both ends of the secondary coil, thereby improving the overall connection voltage ratio and again. As the first and second coils advance under the corresponding spacing, the leakage inductance of the transformer can be relatively increased to effectively reduce the area material of the winding line of the first and second coils.

Other features and advantages of the present invention, and the effect reached to be described in more detail through the drawings below.

1 and 2 illustrate a first embodiment of the present invention, which provides an inverter transformer, which includes a first coil 1, a second coil 2, and an iron core 3. ,

The first coil 1 is installed by winding a pair or more than one pair of secondary coils 5 on the outside of the main body, a plurality of intervals at intervals corresponding to the range that is wound around the secondary coil (5) The secondary coil 5 is wound up and installed in order by installing the division part 11, and the hollow part 12 which can install an iron core is formed in the inside of the main body, and is provided in the both ends of the outside of the main body. An inlet fitting 13 having an inlet in at least one direction is provided, and a plurality of secondary coils 5 are wound around the outside of the main body, and lead wire terminals 14 are connected to the external circuit. At least one groove part 15 is installed on the outside of the groove 11 to correspond to the gap dividing part 11.

The second coil (2) is provided with a pair or more than one set of primary coils 4 wound on the outside of the main body, respectively corresponding to the first coil 1 vertically on both ends of the main body, In addition, the fitting seam 13 of the first coil frame 1 and the frame 21 which are connected to each other are installed, and each of the two frames 21 has at least one winding groove 211. On the other hand, the partial coil lead wire 41 of the primary coil 4 is wound up and installed. In addition, the second coil frame 2 is provided with a hollow portion 12 in which iron cores can be installed to correspond to each other to correspond to the inside of the main body and the winding line groove 211 of the frame 21, and the The second coil frame 2 allows a plurality of primary coils 4 to be wound and connected around the outside of the main body, and also has a lead wire terminal 23 connected to the external circuit, and the second coil frame 2 ) And the first coil 1 are installed in parallel correspondence.

The iron core (3) is composed of the first iron core portion 31 and the second iron core portion 32 are bonded to each other, there is at least a pair of parallel paths to each other, the joints are joined to each other, The first coil 1, the second coil 2, and the hollow parts 12, 22, 212 of the frame 21 are drilled and received in a mutually corresponding manner, and further constitute a main path, thereby forming the first path. The secondary coil 2 and the frame 21 are positioned relative to the sides and both ends of the first coil 1, and further, the primary coil 4 is positioned to correspond to the side of the secondary coil 5 Indirect interconnection is achieved, and the partial coil lead wire 41 of the primary coil 4 corresponds to both ends of the secondary coil 5 to form a direct interconnection. The inductance of both of the secondary coils 5 increases to further increase the connection voltage ratio of the entire transformer, and at the same time, the primary coil 4 and the secondary coil 5 Is disposed to correspond to each other has the primary coil 4 and the secondary coil (5) both relative to the desired properties that can be varied to control the leakage inductance of the transformer by a further demand to adjust the corresponding spacing distance.

This effectively reduces the winding line area and the material of the primary coil 4 and the secondary coil 5. In addition, the present invention relatively controls the leakage inductance required by the entire transformer by relatively increasing or decreasing the number of windings of the coil lead wire 41.

3 and 4 are schematic diagrams of a second embodiment of the present invention.

Here, the first coil 1 and the second coil 2 are integrally formed with another at least one first coil 1 and the second coil 2 so as to correspond to each other according to the demand of use. The first coil core 1 and the second coil core 2 in the form of a first coil core 1 and a second coil core 2, and are connected to each other through the first iron core portion 31 and the second iron core portion 32. The first iron core 31 and the second iron core 32 are drilled and extended to correspond to each other in the first coil 1 and the second coil 2 to constitute the main main path.

In this way, the second coil frame 2 and the frame 21 are positioned to correspond to the sides and both ends of the first coil frame 1 (and within the range in which the coil of the first coil frame 1 is wound and installed). Both ends of the primary coil 4 and its partial coil lead wire 41 are positioned to correspond to the sides and both ends of the secondary coil 5, and at the same time between the secondary coils 5 and the whole winding. Indirect and direct connections are made between the coils wound and installed so as to improve the overall connection voltage ratio, and at the same intervals through the first coil 1 and the second coil 2 and relatively to the transformer. To reach the effect and characteristics of increasing the leakage inductance.

In addition, as illustrated in FIG. 5, this is a schematic diagram of a third embodiment of the present invention, in which the present invention simultaneously applies a pair or more than one pair of primary coils 4 of the same layer to the outside of the main body of the second coil 2. By installing the second coil 2, the primary coil 4 and the secondary coil 5, which are not divided by the partial pressure and the interval, are inducted to correspond to each other to reach the characteristic of dropping the voltage. In addition, the second coil 2 and the first coil 1 in such a way that the primary coil 4 and the divided secondary coil 5 are connected to each other so as to reach a characteristic of increasing voltage. do. Thus, the present invention not only has the above-described effects but also has the characteristics of voltage drop and voltage rise at the same time (However, the method of winding the layers in detail in the secondary coil 5 is the main technical characteristic of the present invention. No description is made here, as indicated by 5 in the drawing).

In addition, the iron core (3) is composed of the first iron core portion 31 and the second iron core portion 32 are bonded to each other, at least one pair of parallel intervals and substantially the first coil through the thickness of the same cutting area And second coils (e.g., multiply, round, oval, etc.) and up to different types of gyros, which are mutually bonded and connected to the first coil 1 and the second coil 2 and the frame ( 21, the hollow parts 12, 22, 212 are mutually penetrated and received, and further constitutes the main magnetic path, and the magnetic core of the iron core 3 is relatively inductively connected, thereby controlling and controlling the leakage inductance required for the entire transformer. .

6 and 7 are schematic diagrams of a fourth embodiment of the present invention.

Referring to the first and third embodiments as an example, the first coil frame 1 is installed by covering at least one cover 6, and the cover 6 has two second coils corresponding to one side thereof. One first inlet 61 is provided to correspond to the position of the frame 21 of the frame 2 so that the frame 21 of the second coil 2 penetrates and extends at the same time. And each other,

In addition, the second inlet 62 is formed to correspond to the positions of the hollow parts 12 and 212 of the frame 21 of the first coil 1 and the second coil 2 so as to correspond to both side surfaces of the cover 6. And the first iron core 31 and the second iron core 32 are formed to correspond to each other and extend to the second inlet 62 of the cover 6, and the first coil 1 and the first coil are relatively formed. It extends through the two coils (2) and the hollow portion (12, 22, 212) of the frame 21, the first coil by installing at least one protruding root (63) inside the cover (6) And the first coil 1 and the second coil 2 when the first coil 1 and the lid 6 are assembled and engaged with the groove groove 15 of (1). Corresponding to each other, the connection voltage ratio and leakage inductance increase, and at the same time, they have characteristics of insulation.

8 is a schematic diagram of a fifth embodiment of the present invention.

The first coil frame (1) is provided with a frame (16) for accommodating the iron core on both ends of the main body to extend vertically outward, respectively, the iron core (3) is the first iron core portion 31 and the second U (or C) and I-type iron cores are formed by joining each other in the form of the iron core portion 32, and when assembled, the first iron core portion 31 is connected to the frame 16 of the first coil frame 1. The second iron core 32 is accommodated to correspond to the hollow portion 12 of the first coil frame 1, and is joined to the first iron core 31, and the first iron core 31 is connected thereto. ), One or more sets of one or more sets of primary coils 4 are wound around the corresponding portions of the secondary coils 5 of the first coil 1, and the primary coils 4 are secondary At least one or more coil lead wires 41 are hooked and installed between the ranges or opposite ends of the coils 5 so that the primary coil 4 and the partial coil lead wires 41 are wound by the secondary coil ( 5) correspond to the sides and both ends of Directly and indirectly connected to improve the overall connection voltage ratio, and at the same time arranged again with a gap between the corresponding of the first and second lead wires, and further increase the leakage inductance of the transformer, effectively winding the primary and secondary coils Reduce the area and cost of materials and coil frame.

Therefore, the technical feature of the present invention is that the primary coil 4 is indirectly interconnected corresponding to the side edge of the secondary coil 5 to increase its required leakage inductance, and then again the primary coil 4 again. In the situation where the partial coil lead wire 41 of R2 is relatively located at both ends of the secondary coil 5 and is directly interconnected, thereby increasing the connection voltage ratio, the general transformer can improve the connection voltage ratio and the leakage inductance together. The winding line area and the material of the primary coil 4 and the secondary coil 5 are reduced by excluding the unacceptable properties.

The inventive progress and practicality of the present invention will be described by comparing with the following.

[Conventional disadvantages]

1. At the same time, there is no characteristic to increase leakage inductance and connection voltage ratio.

2. The winding of primary and secondary coils leads to an increase in wire area and material.

3. Electromagnetic interference affects the original electrical characteristics of the inverter.

[Advantage of this invention]

1. At the same time, it has the effect of increasing the leakage inductance and the connection voltage ratio.

2. Effectively reduce the line area and material of primary and secondary coils.

3. The situation of electronic interference can be improved.

As mentioned above, the present invention has reached the effect to be surely achieved in the conventional technology structure, which is not easily devised by those skilled in the art, and the application of the present invention is unpublished, and the progress and practicality of the utility model I am applying for a utility model under the law because it meets the application requirements.

The above detailed descriptions are specific embodiments of the embodiments of the present invention, and are not intended to limit the claims of the present invention. It is to be understood that the same implementation or modifications as the spirit of the present invention fall within the claims of the present invention.

Claims (19)

Including the first coil, the second coil, iron core, The first coil is provided with at least one set of secondary coils wound around the outside of the main body, and a hollow part for installing an iron core is formed inside the main body. The second coil frame is installed to correspond in parallel with the first coil frame, at least one set of primary coils are wound on the outside of the main body, and both frames of the main body are vertically provided with frames arranged vertically. Corresponding positions on both ends of the coil frame, the frame is provided with a winding wire groove which is used to wind and install at least one partial coil lead wire of at least one primary coil, and the hollow portion for accommodating the iron core is installed in the main body and the frame, respectively. , The iron core is composed of a first iron core portion and a second iron core portion and is accommodated in the hollow portion of the first coil frame, the second coil frame and the frame to form a magnetic path corresponding to each other at least a pair of parallel intervals to each other in the mutual correspondence Inverter transformer, characterized in that bonded. The inverter transformer according to claim 1, wherein the first coil is provided with a plurality of interval dividers at intervals in a range in which secondary coils are wound to correspond to each other. The inverter transformer according to claim 1, wherein the first coil frame is provided with at least one direction of covering joints at both ends of the outer side of the main body. The inverter transformer of claim 1, wherein a plurality of lead wire terminals are installed around the outside of the main body of the first coil and the second coil. The inverter transformer of claim 1, wherein at least one groove groove is installed outside the main body of the first coil. The inverter transformer according to claim 5, wherein a partial coil lead wire of the primary coil is wound around the groove groove part, and at least one set of secondary coils is wound around the second coil in series or in parallel. The inverter transformer of claim 1, wherein the first coil and the second coil are integrally connected to at least one other first coil and the second coil so as to correspond to each other. The inverter transformer according to claim 1, wherein at least one set of secondary coils is wound around the second coil mold. The inverter transformer according to claim 1, wherein the second coil is provided with a plurality of interval dividers at intervals in a range in which the primary coils are wound in correspondence with each other. The inverter transformer according to claim 1, wherein at least one cover is provided at the first coil and the second coil to provide an assembly of the first coil and the second coil. The inverter transformer of claim 10, wherein a first inlet is provided at one side of the cover, and a second inlet is provided at both ends of the cover. 11. The inverter transformer of claim 10, wherein the cover is provided for assembly of at least one first coil and at least one second coil. 11. The inverter transformer according to claim 10, wherein a protruding root used to assemble at least one coil frame is installed in the cover. According to claim 1, wherein both ends of the main body of the second coil is wound in a line groove, the primary coil is wound in a frame extending vertically outward, respectively, and the second coil in series or in parallel from an external circuit Inverter transformer characterized in that at least one set of secondary coils are installed. The inverter transformer according to claim 1, wherein frames at both ends of the main body of the first coil frame are provided to accommodate iron cores vertically outward. The inverter transformer according to claim 1, wherein winding wire grooves of the coil lead wires of the primary coils are provided at both ends of the main body of the first coil. 2. The inverter transformer according to claim 1, wherein the iron cores installed in at least one pair of parallel intervals accommodated in the hollow portions of the first coil frame and the second coil frame have different shapes. The inverter transformer according to claim 1, wherein at least one pair of parallel cores accommodated in the hollow portion of the first coil frame and the second coil frame has the same shape. The inverter transformer according to claim 1, wherein the iron cores installed in at least one pair of parallel intervals accommodated in the hollow portions of the first coil frame and the second coil frame have the same height.

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