KR200212011Y1 - Degaussing Circuit - Google Patents

Abstract

The present invention relates to a degaussing circuit of a water pipe, and the circuit of the present invention is a degaussing coil (a L _D ) And; A photoresist (P) which is a thermosensitive resistance element; A microcomputer 10 for outputting a first control signal of a predetermined level to degauss the water pipe magnetization generated by a geomagnetism or an external magnetism, and outputting a second control signal of a predetermined level at the beginning of degaussing; The degaussing coil may receive a commercial AC current input from the outside by the first control signal. L _D A first switching unit 20 for supplying the; And switching the on / off by the second control signal to degas the coil at the initial stage of degaussing. L _D ) And in parallel with the degaussing coil (P) after the initial degaussing. L _D It is composed of a second switching unit 30 connected in series), so that the degaussing is initially connected in parallel to the degaussing coil, and after the initial connection in series, sufficient degaussing at the beginning of degaussing. By supplying the degaussing coil to the degaussing coil, the number and diameter of the degaussing coil can be reduced, thereby reducing the cost of the degaussing coil.

Description

A degaussing circuit in a CRT

The present invention relates to a degaussing circuit of a water tube. In particular, in the early stage of degaussing, the de-singing current is connected in parallel to the degaussing coil, and afterwards, the degaussing current is connected in series to provide sufficient degaussing current. It relates to a degaussing circuit of a water pipe adapted to reduce the number of turns and diameter of a degaussing coil by supplying it to a degaussing coil.

In general, when the shadow mask or the attachment tool of the water pipe is magnetized due to the influence of geomagnetism or external magnetism, staining may occur on the screen. As described above, when any part of the water pipe is magnetized, color purity may appear. Falls out.

In addition, even if the color purity is well adjusted in the magnetized state, if the direction of the water pipe is changed, the color purity deteriorates due to the influence of residual magnetism. Therefore, the magnetized part of the shadow mask must be demagnetized.

At this time, removing the magnetism in the magnetized part is called degaussing (消磁).

In general, a degaussing element is used to demagnetize a water pipe. The degaussing coil is a coil group installed around the water pipe, and a degaussing coil is connected to a power circuit and a power switch or degaussing switch is used. Each time the same switching means is turned on / off, an alternating current flows through the degaussing coil so as to apply an alternating magnetic field on the shadow mask, thereby automatically demagnetizing the element.

FIG. 1 is a circuit diagram illustrating an example of a general degaussing circuit using a positive temperature characteristic thermistor (Posistor). Referring to FIG. 1, the operation of a general degaussing circuit will be described below.

When the user turns on the power switch or the degaussing switch, the microcomputer 10 detects this and outputs a high level degaussing control signal.

The high level degaussing control signal is applied to the base terminal of the NPN transistor Q20 through a resistor R21 to turn on the transistor Q20.

As the transistor Q20 is turned on, an effect of grounding one side of the relay RL20 coil is generated. Thus, a predetermined voltage 12V connected to the other side of the relay RL20 coil is applied to the relay RL20 coil L21. Is applied to form a magnetic field, and the relay RL20 switch SW21 is turned on by the magnetic field.

As the relay RL20 is switched on, a commercial alternating current is degassed through a pore P. L _D ), And an element is applied by applying an alternating magnetic field on the shadow mask.

Here, since the resistor is a thermosensitive resistor and has a characteristic that the resistance value gradually increases as the temperature increases, the resistor P has a small initial resistance value when the power switch is turned on, thus degaussing. coil( L _D ), But a lot of current flows, but as time passes, the temperature increases due to the current, so that the resistance value of the transistor P increases gradually. L _D The current flowing in the 감소 gradually decreases and eventually becomes zero.

Therefore, the degaussing coil ( L _D ), The attenuation current (degaussing current) is supplied for a certain time (typically 1 second), and the device is automatically formed.

A degaussing coil typically has a diameter of 0.4 °, a number of turns of 100T, and a resistance of 16Ω. L _D ), And a resistor (P) with an initial resistance of 14Ω is used.

Accordingly, assuming that 110V commercial AC voltage is input, the degaussing coil ( L _D The current flowing in) is as shown in Equation 1 below.

Accordingly, the degaussing coil ( L _D The force applied to the electrons moving by the magnetic field formed in) is MMF (Magnetic Moment Force) as shown in Equation 2 below.

MMF = NI = 100T × 5.18A = 518AT

Degaussing coils typically used for water pipes ( L _D ) MMF should be 500AT or more in specification.

At this time, the degaussing coil used in the water pipe ( L _D ) Is priced according to the weight of the degaussing coil ( L _D Weight of the degaussing coil ( L _D ) Is determined by the number of turns (ie, length) and diameter. That is, the gauging coil ( L _D ) And the larger the diameter, the heavier the weight, the greater the degaussing coil ( L _D ), The price of the degaussing coil (0.4T in diameter and 100T turns) L _D ), There is a problem that the price is too expensive.

The present invention is devised to solve the above problems, the device of the present invention, in order to reduce the number of turns and diameter of the degaussing coil to reduce the price in the initial stage of the degaussing to the degaussing coil The purpose of this is to provide a degaussing circuit of the water tube adapted to supply sufficient degaussing current to the degaussing coil at the beginning of degaussing by connecting in parallel and subsequently in series.

Degaussing circuit of the water pipe according to the present invention for achieving the above object,

Degaussing coils installed around the water pipe;

A thermosensitive resistor;

A microcomputer outputting a first control signal of a predetermined level to degauss the magnetization of the water pipe generated by a geomagnetism or an external magnetism, and outputting a second control signal of a predetermined level at the beginning of degaussing;

A first switching unit for supplying a commercial AC current input from the outside to the degaussing coil by the first control signal; And

Switching on / off by the second control signal to connect the transistors in parallel to the degaussing coil at the beginning of degaussing, and to connect the transistors in series to the degaussing coil after the degaussing at the beginning. It is comprised by the 2nd switching part.

1 is a circuit diagram showing a degaussing circuit of a general water pipe;

2 is a circuit diagram showing a degaussing circuit of the water pipe according to the present invention;

3 is a timing diagram and waveform diagrams of respective parts of FIG. 2.

* Description of the symbols for the main parts of the drawings *

10: micom 20: first switching unit

30: second switching unit L _D Degaussing Coil

P: resistor R 21,22,31,32: resistor

RL20: first relay RL30: second relay

Q20: first transistor Q30: third transistor

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

2 is a circuit diagram showing a degaussing circuit of the water pipe according to the present invention.

As shown in FIG. 2, the circuit of the present invention includes a degaussing coil installed around a water pipe ( L _D ) And; A photoresist (P) which is a thermosensitive resistance element; A microcomputer 10 for outputting a first control signal of a predetermined level to degauss the water pipe magnetization generated by a geomagnetism or an external magnetism, and outputting a second control signal of a predetermined level at the beginning of degaussing; The degaussing coil may receive a commercial AC current input from the outside by the first control signal. L _D A first switching unit 20 for supplying the; And a degaussing coil for switching the on / off by the second control signal to initially degaussing. L _D ) In parallel, and after the initial degaussing the resistor is connected to a degaussing coil ( L _D ) Is composed of a second switching unit 30 connected in series.

Here, the first switching unit 20, the base terminal is supplied with the first control signal (S1) from the microcomputer 10, the collector terminal is supplied with a predetermined voltage (12V), the emitter terminal is grounded, the first An NPN type first transistor Q20 turned on / off by the control signal S1; The coil L21 is connected in series to the collector current supply line of the first transistor Q20, the switch S21 is connected in series to a commercial AC current supply line, and is switched on when the first transistor Q20 is turned on. On to the degaussing coil ( L _D It is composed of a first relay (RL20) for supplying a commercial AC current.

In addition, the second switching unit 30, the base terminal is supplied with the second control signal (S2) from the microcomputer 10, the collector terminal is supplied with a predetermined voltage (12V), the emitter terminal is grounded, the second An NPN type second transistor Q30 turned on / off by a control signal S2; A coil L31 is connected in series to the collector current supply line of the second transistor Q30, and when the second transistor Q30 is turned on, the switch 1 SW31 and the switch 3 SW33 are turned on so that the degaussing is performed. Singh coil ( L _D The degaussing coil (P) is connected in parallel to the L _D Supply a commercial AC current, and when the second transistor Q30 is turned off, the switch 2 (SW32) is turned on so that the degaussing coil ( L _D To the degaussing coil (P) in series. L _D ) Is configured as a second relay RL30 for supplying a commercial AC current.

Next, a circuit operation of the apparatus according to the present invention configured as described above will be described with reference to FIG. 3.

3 is a timing diagram and a waveform diagram of each part of FIG. 2.

When the user turns on the power switch or the degaussing switch, the microcomputer 10 detects this and performs the degaussing, as shown in FIG. ) Is output for the T1 time period, and the degaussing is stopped by outputting the low level first control signal S1 after the T1 time.

In addition, as shown in FIG. 3 (b), during the degaussing initial T2 time, the degaussing coil ( L _D The microcomputer 10 outputs the second control signal S2 having a high level in order to connect the transistors P in parallel with each other, and after the time T2, the degaussing coil ( L _D Outputs the second control signal S2 of low level in order to connect the transistors P in parallel.

1. During T2 time during T1 time

When the microcomputer 10 outputs the high level first control signal for the time T1 to demagnetize the water tube magnetization, the high level degaussing control signal S1 is transmitted through the resistor R21 to the first transistor Q20. Is applied to the base end of the transistor) to turn on the first transistor Q20. As the first transistor Q20 is turned on, an effect of grounding one side of the first relay RL20 coil L21 may occur, and thus, a predetermined voltage may be connected to the other side of the first relay RL20 coil L21. 12V is applied to the first relay RL20 coil L21 to form a magnetic field, and the first relay RL20 switch SW21 is turned on by the magnetic field.

On the other hand, during the initial degaussing T2 time, the P is degassed. L _D When the microcomputer 10 outputs the high level second control signal S2 to be connected in parallel to the second transistor), the high level second control signal S2 is transmitted through the resistor R31 to the second transistor Q30. Is applied to the base end of the transistor) to turn on the second transistor Q30. As the second transistor Q30 is turned on, an effect of grounding one side of the second relay RL30 coil L31 may occur, and thus, a predetermined voltage may be connected to the other side of the second relay RL30 coil L31. 12V is applied to the second relay RL30 coil L31 to form a magnetic field, and the second relay RL30 switches 1, 3 (SW31, SW33) are turned on and the switch 2 (SW32) is turned on. Is off.

Accordingly, the degaussing coil ( L _D As the P is connected in parallel and the first relay RL20 switch SW21 is turned on, the commercial AC current is degaussed. L _D Element) by applying an alternating magnetic field on the shadow mask.

Accordingly, the degaussing coil ( L _D The degaussing coil ( L _D Sufficient degaussing current and MMF are supplied.

For example, the degaussing coil applied to the present invention ( L _D Assume that the number of turns is 55T and the resistance value is 16Ω (a degaussing coil having a diameter of 0.4 ø, a number of turns of 100T and a resistance value of 16Ω is usually used for the receiving tube).

Accordingly, the degaussing coil ( L _D ) Can be obtained as shown in Equation 3 below.

At this time, the resistance value of the conventional degaussing coil is R, the cross-sectional area is A, the length proportional to the number of turns is l, the resistance value of the degaussing coil applied to the present invention is R ', the cross-sectional area is A', the proportion is the number of turns The length is l '.

Since the resistance value R of the conventional degaussing coil and the resistance value R 'of the degaussing coil applied to the present invention are equal to 16 Ω,

Accordingly, the degaussing coil applied to the present invention ( L _D Can be reduced to 0.28 ° and the number of turns to 55T.

On the other hand, assuming that 110V commercial AC voltage is input, the degaussing coil ( L _D The current flowing in) is shown in Equation 4 below.

Accordingly, the degaussing coil applied to the present invention ( L _D MMF (Magnetic Moment Force) applied to the electrons moved by the magnetic field formed in Eq.

MMF = NI = 55T × 9.72A = 534AT

Degaussing coils typically used for water pipes ( L _D ) MMF should be at least 500AT in size, as shown in Equation 5 degaussing coil ( L _D ) MMF is satisfied with the specification.

Thus, during the initial degaussing T2 time, the degaussing coil ( L _D By connecting the transistors (P) in parallel to the degaussing coil ( L _D Currents flowing through the degaussing coil ( L _D Is determined only by the resistance value (16Ω).

Accordingly, as shown in FIG. 3 (d), the degaussing coil ( L _D ), Since the current flowing in () increases (see 9.72 A in Equation 4), the degaussing coil ( L _D In addition to reducing the number of turns and diameter, the MMF can be maintained at 500 AT or more to satisfy the water pipe specification.

2. After T2 time of T1 time

After the initial degaussing, i.e., after the T2 time, the microcomputer 10 moves the position P to the degaussing coil ( L _D Outputs a low level second control signal S2 to be connected in series to the circuit), the low level second control signal S2 is applied to the base terminal of the second transistor Q30 through the resistor R31. To turn off the second transistor Q30. Since the magnetic field is not formed in the second relay RL30 coil L31 as the second transistor Q30 is turned off, the switches 1 and 3 (SW31 and SW33) of the second relay RL30 are turned off. Switch 2 (SW2) is turned on.

Accordingly, the degaussing coil ( L _D (P) is connected in series, the commercial AC current is passed through the transistor (P) degaussing coil ( L _D Element) by applying an alternating magnetic field on the shadow mask.

At this time, the resistor (P) is a thermal resistance element, as shown in Figure 3 (c) has a characteristic that the resistance value gradually increases when the temperature increases, as shown in Figure 3 (d) Gaussing coil L _D The current flowing in the 감소 gradually decreases and eventually becomes zero. Therefore, the degaussing coil ( L _D ), The attenuation current is supplied for a predetermined time (T1 time).

As described above, the present invention provides a sufficient degaussing current to the degaussing coil at the beginning of degaussing by connecting the transistors in parallel to the degaussing coil at the beginning of degaussing and then in series after the initial degaussing. Thus, the number of turns and the diameter of the degaussing coil can be reduced, thereby reducing the cost of the degaussing coil.

Claims (1)

Degaussing coils installed around the water pipe ( L _D ) And; A photoresist (P) which is a thermosensitive resistance element; A microcomputer 10 for outputting a first control signal of a predetermined level to degauss the water pipe magnetization generated by a geomagnetism or an external magnetism, and outputting a second control signal of a predetermined level at the beginning of degaussing; The degaussing coil may receive a commercial AC current input from the outside by the first control signal. L _D A first switching unit 20 for supplying the; And Switching on / off by the second control signal, the degaussing coil at the initial stage of degaussing is degaussing coil ( L _D ) And in parallel with the degaussing coil (P) after the initial degaussing. L _D Degaussing circuit of the water pipe, characterized in that consisting of a second switching unit (30) connected in series.