KR100909397B1 - Terminal structure of transformer bobbin for inverter - Google Patents

Abstract

The present invention is to reduce the size of the bobbin by winding the connection terminal in the upward direction and withdraw the connected coil to the upper side of the coil winding portion of the inverter transformer of the inverter bobbin to realize the cost reduction by easy wiring The present invention relates to a terminal structure, and in accordance with the present invention, a coil winding portion configured by being divided into a first coil winding portion 121 and a second coil winding portion 122 having a plurality of slits around the coil partition wall 120a. Terminal boards 140 having coil terminals 150 respectively formed on both sides of the 120 and the coil winding 120 are integrally formed and penetrated in the longitudinal direction between the terminal boards 140 on both sides. In the transformer bobbin for an inverter composed of a hollow portion 102, the coil terminal 150 is formed integrally with the buried terminal 151 and the buried terminal 151 embedded in the terminal substrate 140, and the terminal In the substrate unit 140 And a connection terminal 153 which is formed integrally with the buried terminal 151 and is exposed from the terminal board unit 140 and connected to the coil by being mounted and mounted on the printed circuit board. In the terminal structure of the transformer bobbin for the inverter, the connection terminal 153 is formed integrally extending from the buried terminal 151 in the longitudinal direction of the bobbin 100 and exposed from the terminal board 150, and then the terminal board portion 140 It is characterized in that the upper surface 140a is formed by bending in the upward direction. According to the above, there is an advantage in that the size of the bobbin can be reduced and the wiring can be quickly and easily implemented to reduce the cost.

Description

A terminal structure of transformer bobbin for inverter

The present invention relates to a transformer for inverters, in particular, by forming a connection terminal bent upwards, and by winding the connected coil to the upper side of the coil winding unit, it is possible to reduce the size of the bobbin and to facilitate the cost reduction by quick connection. The terminal structure of the transformer bobbin for an inverter suited to be able to make it possible.

Recently, with the development of display devices, LCD monitors and LCD TVs are widely used. LCDs have fluorescent tubes driven at high voltages for a back light system, typically an inverter with a drive circuit is used to drive the fluorescent tube and the inverter has a high voltage transformer. Therefore, the transformer used to minimize the size needs to have a thin plate type structure.

A transformer is a device that increases or decreases the voltage of an alternating current, in which the primary and secondary coils of the low and high voltage sides are wound around a bobbin whose core is inserted into the hollow portion of the bobbin. Is produced. One low voltage coil called the primary coil is connected to the input circuit to which the voltage is to be changed, and the other high pressure coil called the secondary coil is connected to the output circuit to which the changed (converted) voltage is used. As the current passes through the primary coil, a magnetic field is generated in which the strength and direction change in response to the alternating current. The change in magnetic flux induces an alternating voltage in the secondary coil and the winding ratio in each coil determines the transformer ratio.

In the case of such a thin plate type high voltage transformer, the number of windings of the high voltage coil is much larger than that of the low voltage coil, so the current flowing in the high voltage coil is very small compared to the current flowing in the low voltage coil. Much thinner than low pressure coils. In addition, the high-voltage coil winding portion of the bobbin is wound in one continuous coil is spatially separated by a number of slits to facilitate the heat dissipation generated from the coil, so that both ends of the coil are spaced to some extent When the coil is connected to the high voltage terminal of the transformer formed on one side of the bobbin, one end of the coil is connected to one terminal of the high voltage terminal by a lead wire extending from the first end of the coil. . At this time, the leader line is spaced apart from the high voltage coil by a length of the terminal board to prevent a short circuit with a part of the high voltage coil.

Referring to Figures 1 to 3 the terminal structure of the transformer transformer bobbin according to the prior art as follows.

1 is an exploded perspective view of an inverter transformer bobbin according to the prior art, FIG. 2 is a front view of an inverter transformer bobbin according to FIG. 1, and FIG. 3 is a view of another transformer transformer bobbin according to the prior art. A terminal perspective view of the back of the terminal structure is shown.

As shown in FIG. 1, the conventional transformer 1 has a low voltage terminal board 13 having a low voltage coil terminal 14 and a high voltage coil terminal 12 formed on both sides thereof, and a high voltage terminal board 11 integrally formed. And a bobbin body portion having a core insertion hollow portion 17 formed therebetween so as to insert the "E" type core 5 having the same width as the horizontal length of the terminal substrate in both directions between the terminal substrates 11 and 13. And a plurality of slits 16 for dividing the outer circumferential surface of the bobbin body portion into the low pressure coil winding portion 19 and the high pressure coil winding portion 18 and the high pressure coil winding portion 18 at regular intervals. ) Is composed of a combination of a bobbin 10 consisting of a core and the "E" type core (5) formed of an outer core integrally formed on the core and the core inserted into the core insertion hollow 17 of the bobbin 10. .

Referring to FIG. 2, the bobbin 10 has a high pressure coil 2 and a low pressure coil 3 below the terminal boards 11 and 13 on both sides of the low pressure coil terminal 14 and the high pressure coil terminal 12. The lead-out path 20 to which each of the high-pressure coil lead-out line 2-1 and the low-pressure coil lead-out line 3-1 is guided so as to be electrically connected to each other is connected to the terminal boards 11 and 13 at a predetermined depth. It is formed in the rear part.

The low voltage coil terminal 14 and the high voltage coil terminal 12 may be divided into terminal parts 12a and 14a for soldering and terminal parts 12b and 14b for surface mounted devices (SMDs) on a printed circuit board. The terminal portions 12a and 14a for soldering protrude in a straight shape having a predetermined length.

Therefore, since the soldering terminal portion 12a of the high voltage coil terminal 12 to which the high pressure coil is connected has a straight end, there is a problem of winding out after soldering the high pressure coil 2-1 drawn out before soldering, and further, the high pressure coil 2 Since 1) is a thin coil, there is a fear that the high pressure coil (2-1) is disconnected due to the heating temperature generated when soldering by soldering.

Accordingly, these problems must always be taken into account in the manufacture of the transformer 1, thus reducing the efficiency of the process and taking more time for the process.

In order to solve this problem, the proposed technique is to bend a soldering terminal part which is soldered by binding with the high voltage coil drawn out of the high voltage coil terminals formed on both terminal boards in the bobbin structure of the transformer used in the inverter at a predetermined angle. It is a technique as described in the Republic of Korea Utility Model Registration Application No. 20-2005-0020647 to change the shape so that the high-pressure coil can be tightly bound without falling out. However, since the bobbin terminal structure of the prior art has a three-dimensional shape, the winding operation of the winding machine needs to be large, and the height of the vicinity of the final terminal of the bobbin is increased.

Thus, the proposed technique to solve this problem is shown in Fig. 3 as the 'bobbin terminal structure for transformers' filed by the applicant of the present invention as a patent 2006-48171.

Briefly describing the technique of the above Patent No. 2006-48171, as shown in FIG. 3, the coil winding part 52 in which the first coil winding part and the second coil winding part are formed around the coil partition wall, and the coil The terminal board 55 is formed integrally with the winding part 52, and the lead path 56 of the coil is formed on the bottom thereof, and has a protrusion 570 protruding from the lead path 560. In the terminal structure of the transformer bobbin configured to be formed, the buried terminal portion 51c made of metal embedded in the terminal substrate 550, and integrally formed in the axial direction of the bobbin from the embedded terminal portion 51c, The bobbin is exposed from the surface mounting terminal 51a and the buried terminal portion 51c exposed to the terminal board 55 and bent to the bottom of the bobbin, and then contacting the printed circuit board in a shape where the end is bent in the axial direction of the bobbin again. In the axial direction of Formed in the exposed portion of the terminal substrate 55, first bent in the transverse direction of the bobbin and then bent second to the bottom of the bobbin, the end of which is bent three times in the axial direction of the bobbin (so-called, The soldering terminal (51b), characterized in that the third bending of the connection terminal (51b) is characterized in that it is formed in the axial direction of the bobbin on a straight line in the same plane with the protrusion (57).

However, the terminal structure of the transformer bobbin for inverters according to the prior art as described above has the following problems.

First, since the connection terminal 51b is bent in the horizontal direction, the distance from the surface mounting terminal 51a is inevitably widened, and as a result, the volume of the product is large.

In the case of the primary coil, the thickness thereof is large (diameter is large), and therefore, when soldering to the connection terminal 51b, the space between the surface mounting terminal 51a has to be further widened because it occupies much connection space.

Second, when the connection terminal 51b is bent in the horizontal direction, it is not easy to connect in the relationship with the surface mounting terminal 51a. Therefore, the manufacturing process is complicated because the post-processing process must be performed again, such as bending in the vertical direction. There was a costly problem.

Third, in the bobbin terminal structure according to the prior art, it is necessary to connect only to the bottom of the bobbin in order to connect the terminal, so there is a problem in that it takes a lot of time when wiring with a winding machine.

The present invention was created to solve the problems of the prior art as described above, and an object of the terminal structure of the transformer bobbin for an inverter according to the present invention is to form a connection terminal bent upward and connect the connected coil to the upper side of the coil winding part. The present invention provides a terminal structure of a transformer bobbin for an inverter that can be reduced in size by winding out and wound up, and is suitable for quick and easy wiring to realize cost reduction.

The terminal structure of the transformer bobbin for inverters according to the present invention for achieving the above object is the coil winding part and the coil winding part which is divided into a first coil winding part and a second coil winding part provided with a plurality of slits around the coil partition wall. In an inverter transformer bobbin composed of a hollow portion formed integrally with a terminal board portion having coil terminals on both sides of the coil winding portion and having a longitudinally penetrating shape formed therebetween between the terminal board portions on both sides, the coil terminal is formed of the terminal board portion. A buried terminal embedded therein, a surface mount terminal integrally formed in the buried terminal and exposed on the terminal board portion and mounted on the printed circuit board, and integrally formed with the buried terminal and exposed from the terminal board portion to be connected to the coil In the terminal structure of the inverter bobbin for inverter, characterized in that consisting of a connection terminal, The connection terminal may be formed by integrally extending from the buried terminal in the longitudinal direction of the bobbin to be bent from the terminal board and then bent upward in the upper surface of the terminal board.

The terminal structure of the transformer bobbin for inverters of the present invention having the above-described configuration is formed by bending the connecting terminal in the upward direction, and drawing the connected coil to the upper side of the coil winding unit to wind up, thereby reducing the size of the bobbin and making the connection quick. There is an effect that can be implemented to facilitate cost reduction.

The following describes in detail with reference to the accompanying drawings a preferred embodiment of the terminal structure of the transformer bobbin for inverters of the present invention.

Figure 4 is a perspective view of the main terminal structure of the transformer bobbin for an inverter according to an embodiment of the present invention.

As shown in FIG. 4, the terminal structure of the transformer bobbin for an inverter according to an embodiment of the present invention includes a first coil winding part 121 and a plurality of slits around the coil partition wall 120a. The coil winding unit 120 which is divided into the coil winding unit 122 and the terminal board unit 140 having the coil terminals 150 on both sides of the coil winding unit 120 are integrally formed and formed on both sides. In the transformer bobbin for an inverter consisting of a hollow portion 102 formed in the longitudinal direction between the terminal board portion 140, the coil terminal 150 is embedded in the terminal board portion 140 151, a surface mount terminal 152 formed integrally with the buried terminal 151 and exposed from the terminal board 140 to be mounted on the printed circuit board, and integrally formed with the buried terminal 151. Wiring terminal exposed from the terminal board 140 and connected to the coil (so-called In the terminal structure of the inverter bobbin for the inverter, characterized in that consisting of (153), the connection terminal 153 is formed integrally extending in the longitudinal direction of the bobbin 100 from the buried terminal 151 to the After being exposed from the terminal board 150, the upper surface 140a of the terminal board 140 is bent upward.

As described above, since the connection terminal 153 is not bent in the horizontal direction but is bent upward from the terminal board part 140, the connection terminal 153 can be formed without being limited to the distance W1 from the surface mounting terminal 152. There is this. As a result, the size of the product can be significantly reduced.

In particular, when the primary coil is connected to the connection terminal 153, since the conventional coil occupies much connection space for soldering the primary coil having a large diameter to the connection terminal 153, the distance from the surface mounting terminal 152 is increased. Although it should be widened, in the present invention, even when the thick primary coil is soldered to the connection terminal 153, the effect can be more remarkably exhibited because the distance W1 from the surface mounting terminal 152 is not limited.

In addition, in the terminal structure according to the present invention, since the connection terminal 153 is bent upward in the vertical direction, a problem in that the soldered coil is not removed does not occur, and thus the connection is made firm.

In one embodiment of the present invention, the withdrawal groove 142 is constant in order to draw the coil connected to the coil winding 120 on the upper surface 140a of the terminal board portion 140 where the connection terminal 153 is located. It is characterized by the fact that the recess is formed at a depth.

The withdrawal groove 142 is characterized in that located immediately after the connection terminal 153.

As described above, the coil is directly drawn out and wound up to the upper surface 140a of the terminal board 140 through the drawing groove 142 formed on the upper surface 140a of the terminal board 140. .

That is, since the coil connected to the connection terminal 153 is directly connected through the withdrawal groove 142 located immediately afterwards, the connection distance is shortened, so that the connection is more easily facilitated.

In addition, the drawing groove 142 is preferably formed to be recessed to a predetermined depth so as to form the same plane as the upper surface of the coil winding unit 120.

By the above configuration, there is an advantage that the coil drawn out through the drawing groove 142 may be more easily wound on the coil winding part 120.

In addition, the connection terminal 153 is characterized in that the vertical bending immediately after being exposed in the longitudinal direction from the terminal board 140.

5 is a perspective view of the main portion of the terminal structure of the transformer bobbin for an inverter according to another embodiment of the present invention.

As shown in FIG. 5, in the terminal structure of the transformer bobbin for an inverter according to another embodiment of the present invention, the connection terminal 153 is in contact with the front surface 140b of the terminal board 140 to bend vertically. It is characterized by.

Since the connection terminal 153 is vertically bent upward by contacting the front surface 140b of the terminal board part 140 as described above, the gap with the withdrawal groove 142 is closer to the connection terminal 153 after the connection. There is an advantage that the process of winding the coil winding 120 is faster and easier.

The above embodiments of the present invention are merely one embodiment of the technical idea of the present invention, and of course, other modifications are possible within the technical idea of the present invention.

1 is an exploded perspective view of a transformer bobbin for an inverter according to the prior art.

FIG. 2 is a front view of the transformer bobbin for an inverter shown in FIG. 1.

3 is a perspective view of the terminal structure main part rear side of the transformer bobbin for inverters by another prior art.

4 is a perspective view of the main portion of the terminal structure of the transformer bobbin for an inverter according to an embodiment of the present invention.

Fig. 5 is a perspective view of the main part of a terminal structure of an inverter transformer bobbin according to another embodiment of the present invention.

          Explanation of symbols on the main parts of the drawings

120a; Coil partition 121; Coil winding part 1

122; Second coil winding 120; Coil winding

150; Coil terminal 140; Terminal board part

102; Hollow part 151; Buried terminal

152; Surface mount terminal 153; Final terminal

100; Bobbin 140a; Top surface of terminal board

142; Withdrawal groove 140b; Front side of the terminal board

Claims (6)

The coil winding part 120 and the coil winding part 120 which are divided into a first coil winding part 121 and a second coil winding part 122 provided with a plurality of slits around the coil partition wall 120a. Inverter terminal unit 140 having a coil terminal 150 on each side of the side is formed integrally and the hollow portion 102 formed in the longitudinal direction through the interior between the terminal substrate portion 140 on both sides In the transformer bobbin, the coil terminal 150 is formed by being embedded in the terminal 151 embedded in the terminal board 140 and the embedded terminal 151 and exposed from the terminal board 140 to be printed. Surface mounting terminal 152 to be mounted on the circuit board, and the connection terminal 153 is formed integrally with the buried terminal 151 and exposed from the terminal board unit 140, and connected to the coil, for the inverter In the terminal structure of the transformer bobbin: The connection terminal 153 is formed integrally extending from the buried terminal 151 in the longitudinal direction of the bobbin 100 and is exposed from the terminal board 150 to have an upper surface 140a of the terminal board part 140. A terminal structure of a transformer bobbin for an inverter, which is formed by bending upward. The method according to claim 1, The upper surface 140a of the terminal board unit 140 on which the connection terminal 153 is located is provided with a drawing groove 142 for drawing the coil connected to the coil winding unit 120. Terminal structure of transformer bobbin. The method according to claim 2, The withdrawal groove 142 is a terminal structure of the transformer bobbin for an inverter, characterized in that the groove is formed so as to form the same plane and the upper surface of the coil winding 120. The method according to claim 3, The above-mentioned bending of the connection terminal 153 in the upward direction is a terminal structure of the transformer bobbin for inverter, characterized in that the vertical bending. The method according to any one of claims 2 to 4, The outlet groove 142 is a terminal structure of a transformer bobbin for an inverter, characterized in that located immediately after the connection terminal 153. The method according to claim 5, The connection terminal 153 is in contact with the front surface (140b) of the terminal board 140, the terminal structure of the transformer bobbin for the inverter, characterized in that the bending.

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