KR100360922B1 - Transformer - Google Patents

Abstract

The present invention relates to a transformer used in electronics, etc. In particular, the electrical characteristics of the transformer by placing the shunt core and the heater side by side between the secondary coil and the primary coil to be coupled to the coupling passage formed in the "E" type core block Compact design is possible due to internal space while maintaining, and production cost can be lowered, and large capacity design is possible by adjusting the size of primary and secondary coils by using an expanded space than transformers of the same size. This provides a transformer that can maximize economic efficiency.

Description

Transformers {TRANSFORMER}

The present invention relates to a transformer used in electronics, etc. In particular, the electrical characteristics of the transformer by placing the shunt core and the heater side by side between the secondary coil and the primary coil to be coupled to the coupling passage formed in the "E" type core block Compact design is possible due to internal space while maintaining, and production cost can be lowered, and large capacity design is possible by adjusting the size of primary and secondary coils by using an expanded space than transformers of the same size. The present invention relates to a transformer capable of maximizing economic efficiency.

The configuration of a conventional transformer is shown in FIG.

"E" type core block 1 for inducing high voltage and generating electromotive force, and a secondary coil for driving the magnetron and boosting the voltage by being coupled to the coupling passage 2 of the "E" type core block 1 ( 3), a heater 4 stacked on an upper surface of the secondary coil 3 to drive a magnetron and a capacitor, and a shunt core 5 stacked on an upper surface of the heater 4 to induce high pressure and generate an electromotive force. ) And a primary coil 6 stacked on an upper surface of the shunt core 5 to drive a magnetron and boosting a voltage, and stacked on an upper surface of the primary coil 6 and an "E" core block 1. It is configured to have an "I" type core block 7 to induce high pressure and generate electromotive force.

The conventional transformer having the above configuration is a device that modulates the voltage by combining the silicon steel plate and the copper wire using the law of electromagnetic induction and is used to convert the magnitude of the AC voltage and the current. It is composed of two or more coils with), and when AC voltage is applied to one of them (INPUT), AC electromotive force is generated and the desired voltage (secondary coil) can be obtained from the other (OUTPUT).

However, the conventional transformer as described above is provided between the primary coil 6 and the secondary coil 3 coupled into the coupling passage 2 of the "E" type core block 1 as shown in FIG. Since the heater 4 and the shunt core 5 are stacked up and down, the coupling passage 2 should be as long as the laminated thickness of the heater 4 and the shunt core 5 and further, the "E" type core. As the height of the block 1 is also increased, the consumption of materials is high and the production cost is increased.

In addition, since the size of the primary coil 6 and the secondary coil 3 cannot be freely controlled by the stacking thickness of the heater 4 and the shunt core 5, the design of a large capacity is not free, thereby increasing the economic efficiency. There was also a problem that can not be.

The purpose of the present invention for solving and solving these conventional problems,

By maintaining the electrical characteristics of the transformer, it is possible to make a compact design due to the internal space and to reduce the production cost, and to control the size of the primary and secondary coils by using the expanded space than the transformer of the same size Its purpose is to enable high capacity design to maximize economic efficiency.

In order to achieve the above object, the present invention,

When the shunt core and the heater are placed side by side between the secondary coil and the primary coil to be coupled to the coupling passage formed in the "E" type core block, the object of the present invention can be achieved.

1 is a cross-sectional view showing a laminated configuration of a shunt coil and a heater of a conventional transformer

Figure 2 is an exploded perspective view showing the mounting configuration of the shunt coil and the heater of the present invention transformer

Figure 3 is a cross-sectional view showing the mounting configuration of the shunt coil and the vertical winding heater of the present invention transformer

Figure 4 is a front sectional view showing the mounting configuration of the shunt coil and the vertical winding heater of the present invention transformer

Figure 5 is a front sectional view showing a mounting configuration of the shunt coil and the horizontal winding type heater of the present invention transformer

Figure 6 is a perspective view showing a horizontal wound heater of the present invention transformer

<Code Description of Main Parts of Drawing>

101- "E" type core block 102-combined passage

103-2 Coil 104-Vertical Wound Heater

105-shuntcore 106-1 primary coil

107- "I" type core block 111-heater

114-Horizontal Wirewound Heaters

The configuration of the present invention will be described in detail with reference to the accompanying drawings.

The shunt core 105 and the heater 111 are mounted side by side between the secondary coil 103 and the primary coil 106 which are coupled to the coupling passageway 102 formed on the “E” type core block 101. .

In addition, the heater 111 is provided as a vertical winding type heater 104 seated while wrapping the outer portion of the shunt core 105.

In addition, the heater 111 is provided as a horizontal winding type heater 114 is seated while wrapping the outer portion of the shunt core 105.

The first embodiment of the present invention as described above will be described in detail with reference to Figs.

First, the heater 111 of the present invention serves to drive the magnetron and the capacitor and the shunt core 5 serves to induce high pressure and generate electromotive force as in the prior art.

In addition, the heater 111 of the first embodiment of the present invention actually mounts side by side between the secondary coil 103 and the primary coil 106 so as to surround the vertical winding heater 104 outside the shunt core 105. The space occupied by the heater is omitted.

Therefore, the coupling passage 102 of the secondary coil 103 does not have to be long, and as the length of the primary coil 103 is shortened, a compact design can be performed due to the internal space while maintaining the electrical characteristics of the transformer. And lower the production cost.

In addition, due to the wound heater 104 and the shunt core 105 seated side by side as described above, an expanded space portion is formed in the transformer having the same size as the conventional one.

At this time, by adjusting the size of the primary and secondary coils 103 and 106 by using the expanded space portion, it is possible to maximize the economic efficiency by enabling a large capacity design.

Meanwhile, a second embodiment of the present invention will be described in detail with reference to FIGS. 5 and 6.

The heater 111 of the second embodiment of the present invention employs the horizontal winding heater 114 instead of the vertical winding heater 104 of the first embodiment.

That is, even if the horizontal wound heater 114 is seated side by side between the secondary coil 103 and the primary coil 106 so as to be wrapped around the shunt core 105, the space occupied by the conventional heater is virtually eliminated. By lowering the size of the primary and secondary coils (103, 106) by using a space portion expanded on the same size, it is possible to design a large capacity to maximize the economic efficiency.

The present invention is to secure the internal space while maintaining the electrical characteristics of the transformer by seating the shunt core and the heater side by side between the secondary coil and the primary coil to be coupled to the coupling passage formed in the "E" type core block Due to the compact design, lower production cost, and the expansion of the primary and secondary coils by using the expanded space than the transformers of the same size, the large-capacity design is possible to maximize the economic efficiency. Has a useful effect.

Claims (3)

The side of the shunt core 105 and the heater 111 are placed side by side between the secondary coil 103 and the primary coil 106 to be coupled to the coupling passage 102 formed in the "E" type core block 101 A transformer characterized by the above-mentioned. The method of claim 1, The heater 111 is a transformer, characterized in that provided with a vertical winding heater 104 is seated while wrapping the outer portion of the shunt core (105). The method of claim 1, The heater 111 is a transformer, characterized in that provided with a horizontal winding heater 114 is seated while wrapping the outer portion of the shunt core (105).