KR20000003798A - Deflecting yoke - Google Patents

Abstract

PURPOSE: A deflecting yoke is provided to be formed with a thin film coil attached to the deflecting yoke. CONSTITUTION: The deflecting yoke comprises the thin film coil. the thin film coil is attached to the deflecting yoke by using a thin film method. Especially, copper wire line(2) is formed on a film(1), and the film including copper wire of pattern is piled up. the copper wire line(2) is electrically connected to be form the shape of the coil, and the film layer is mounted on the vertical and horizontal portion of the core to be connected together. Thereby, it is possible to save the loss of the product time.

Description

Deflection Yoke

The present invention relates to a deflection yoke of a television receiver (hereinafter referred to as a TV), and in particular, a thin film coil using a thin film technique without using a coil structure of a coil copper wire using a winding machine, etc., which is an essential component in constructing a deflection yoke. It relates to a deflection yoke for forming a coil by attaching using the same.

In general, a TV for receiving and watching a broadcast signal transmitted from a broadcasting station is briefly described with reference to FIG. 1. When a power cord is inserted into an outlet (not shown), a standby power (for example, 5V) is applied to the microcomputer 200. By operating the power "key" of the key input unit 220, a high voltage pulse is generated in the power unit 700 for applying the main power source AC110 / 220V to the FBT 800, and the main power source applied from the power source unit 700. FBT 800 for supplying B ⁺ power to the image processor 300 and the microcomputer 200 for controlling overall operation of the TV by the operation of the key input unit 220, and the microcomputer 200 to process the microcomputer 200. Memory 240 for storing the data to be received, the tuner 100 for receiving the broadcast signal of the channel selected by the tuner voltage output from the microcomputer 200 from the antenna ANT, and the tuner 100 received An image processor 300 for processing an image signal of a broadcast signal The image amplification unit 320 amplifies the image signal output from the image processor 300 and the image signal displayed on the screen of the CRT 400 by the vertical / horizontal synchronization signal processed by the image processor 300. A vertical / horizontal synchronization processor 340 for deflecting a vertical synchronization signal and a horizontal synchronization signal, a CRT 400 for receiving an image signal output from the image amplifier 320 and displaying it on a screen; and the tuner 100. A voice processor 500 for processing a voice signal of the broadcast signal received by the voice signal, a voice amplifier 520 for amplifying the voice signal processed by the voice processor 500 to a predetermined level, and the voice amplifier 520. The speaker 600 is largely configured to receive and output the audio signal output from (620).

2 is a schematic view showing an internal structure of a general CRT 400, and FIG. 3 is an exemplary view showing an internal configuration relationship of a general CRT 400, and generates heat by receiving an image amplified R, G, and B signals. The heater 410 to increase the temperature of the cathode 420, the cathode 420 to emit electrons when a negative voltage is supplied from the heater 410, and the amount of electrons emitted from the cathode 420. The control grid 430 modulates luminance (change in brightness) and a constant voltage (for example, +110 V to 400 V) so that electrons emitted from the cathode 420 can reach the fluorescent surface 492 of the glass tube 490. By supplying electrons with charges to accelerate them in the axial direction, and by supplying a constant voltage (for example, +10 mA or more) to electrons accelerated primarily in the acceleration grid 440 To the fluorescent surface 492 of the glass tube 490, which is emitted from the cathode 420, and the medium acceleration grid 450 to accelerate the Focusing grid 460 which makes the electrons moving to diffuse by the repulsive force between the electrons in the axial direction to form a thin electron beam, and emitted from the cathode 420 to the acceleration grid 440 medium acceleration grid ( Ultra-high acceleration grid 470 to supply a constant voltage (for example, +10 kHz or more) to the electron accelerated twice through 450 and collide with the fluorescent surface 492 of the glass tube 490, and a constant voltage An anode terminal 480 is provided to supply a high voltage (eg, +10 kV) or more to the aluminum film of the glass tube 490, the fluorescent surface 492, and discharge the high voltage when the power is "off".

The deflection yoke that controls the transmission direction of the electron beam to display an image of the CRT is a very important configuration.

This deflection yoke, as shown in the accompanying Figure 3, by using a single winding wire winding machine to form a horizontal side and vertical side deflection coil in the ferrite core. That is, a winding machine is used to wind the copper wire on the horizontal side a certain number of times to form a horizontal deflection coil, and then the copper wire is wound a certain number of times on the vertical side to form a horizontal deflection coil.

Therefore, the conventional deflection coil is a winding machine for its production, and the time loss due to the winding is large. Moreover, the mechanical winding method using a winding machine has caused a problem that uniform manufacturing is not easy and considerable correction work is required.

An object of the present invention for solving the above problems is to form a coil by attaching a coil, which is an essential component in constructing a deflection yoke, by using a thin film coil using a thin film technique, without using a winding structure of a coil copper wire using a winding machine or the like. It is to provide a deflection yoke to be made.

1 is a block diagram schematically showing a typical TV receiver

Figure 2 is a schematic diagram showing the internal structure of a typical cathode ray tube (Cathode-Ray Tube: CRT)

3 is a configuration example of a conventional deflection yoke

4 is an exemplary view of a coil in a pattern method according to the present invention.

A feature of the present invention for achieving the above object is to form a copper copper wire by a pattern thin film of uniform thickness at a predetermined interval on the film, and then superimpose the films, and the upper copper film of the copper copper wire formed on the overlapping film The copper copper wire is connected to the copper copper wire of the lower layer, but one of the plurality of copper copper wires formed in one film is called a stage and the other end is referred to as b stage, and two films are connected to form a coil. (Where 1 ≦ k ≦ n), the a ends of the kth copper copper wires sequentially arranged on the first film are the kth copper copper wires sequentially arranged on the second film. The b ends of the k-th copper copper wire which are connected to a stage of the copper copper wires sequentially arranged on the first film are the k-1th copper copper wires of the copper copper wire which are sequentially arranged on the second film. It is connected to the b stage to form a coil to attach to the core as a horizontal side and vertical coil, and to connect them again to perform the role of a deflection coil consisting of one copper wire.

As an additional feature of the present invention for achieving the above object, the b end of the first copper copper wire of the first film and the b end of the nth copper copper wire positioned in the last arrangement of the second film are utilized as input / output terminals of electricity. There is.

Hereinafter, the configuration according to an embodiment of the present invention will be described in detail with the accompanying drawings.

4 is an exemplary view for explaining a coil forming method in the deflection yoke according to the present invention.

After the copper copper wire 2 by a pattern thin film is formed in the film 1, the film 1 in which such copper wire of a pattern is formed is superimposed. Subsequently, when the copper copper wires 2 formed on the overlapping film 1 are connected in the manner shown by the dotted lines in FIG. 4, the coils are formed as a whole.

The thus formed film layer is attached to the core as a horizontal side and a vertical side coil and connected again to serve as a deflection coil made of a conventional copper wire.

That is, when one end of the plurality of copper copper wires formed in one film is referred to as one end and the other end is referred to as b end, and two sheets of film are connected to each other to form one coil, the first film is sequentially arranged. A stages of the kth copper copper wires among the copper copper wires are connected to a stage of the kth copper copper wires of the copper copper wires sequentially arranged on the second film, and k of the copper copper wires sequentially arranged on the first film. The b ends of the first copper copper wire are connected to the b ends of the k-1th copper copper wire among the copper copper wires sequentially arranged on the second film (where 1 ≦ k ≦ n).

As it is connected in this way, the b end of the first copper copper wire of the first film and the b end of the nth copper copper wire located in the last arrangement of the second film are utilized as input / output terminals of electricity.

Providing the deflection yoke according to the present invention as described above has the effect of reducing the loss of production time and having a uniform characteristic, eliminating the need for maintenance / correction work.

Claims (2)

In the deflection yoke, After forming copper copper wire 2 by the pattern thin film of the uniform thickness in the film 1 at predetermined intervals, the said film 1 is overlapped and the copper copper wire 2 formed in the superimposed film 1 is carried out. Connect the copper copper wire of the upper layer film and the copper copper wire of the lower layer film, but one end of the plurality of copper copper wires formed in one film is called a end and the other end is called b end, and the two films are connected In the case of forming a coil (where 1 ≦ k ≦ n), the a stages of the kth copper copper wires sequentially arranged on the first film are the kth copper copper wires sequentially arranged on the second film. The k-th copper copper wire of the k-th copper copper wire which is connected to the a end of the copper copper wire of the copper copper wire which is sequentially arranged on the first film of Connected to b stage of single coil By attaching a horizontal side and a vertical side coil and the core, yoke and reconnect them, it characterized in that it acts as a deflection coil consisting of a copper wire. The method of claim 1, And a b end of the first copper copper wire of the first film and a b end of the nth copper copper wire positioned in the last arrangement of the second film are used as electrical input / output terminals.