KR200186574Y1 - Thermosentive temperature controller for thermal mat - Google Patents

Abstract

The present invention relates to a thermoelectric type electric swash plate temperature controller, comprising a thyristor (SCR) 9 for applying a current to a heating line 3, a gate bias resistor 10 connected in series with a gate of the thyristor 9, and Heating line heating unit consisting of a bypass diode 12 connected in series to the gate bias resistor 10, a capacitor 11 connected in parallel between the resistor 10 and the diode 12, and connected in series to each other. A variable resistor 16, a temperature sensor 5, a bypass diode 6, a gas discharge tube 7, one of an anode and a cathode are connected to the condenser 11, and a gate is connected to the gas discharge tube 7 Consisting of a thermostat consisting of a thyristor (8) connected to and a gate bias resistor (17) connected in parallel between the gas discharge tube (7) and the gate of the thyristor (8). Conventional As compared to the case of using a plurality of integrated circuits and constructing an auxiliary power circuit for supplying the operating power to the integrated circuits, the number of parts and the structure are simple, thereby minimizing the volume of the thermostat and reducing the manufacturing cost. I would have to.

Description

Thermoelectric Engraving Plate Temperature Controller

The present invention relates to a thermosensitive electric immersion plate temperature controller, and more particularly to a thermosensitive electric immersion plate temperature controller that can reduce the manufacturing cost by reducing the number of components.

Conventional thermoelectric wire plate thermostat is composed of a plurality of integrated circuits (IC) for sensing the temperature and adjusting the current value flowing in the heating line and an auxiliary power circuit for applying the operating power to these integrated circuits. It was.

Accordingly, the present invention has been made to solve the problems of the prior art as described above, by omitting the auxiliary power supply circuit, and by adjusting the temperature of the electric power only by a simple switching element rather than an integrated circuit, and by omitting the auxiliary power supply circuit, The goal is to provide a thermal wire immersion thermostat that can reduce the cost, simplify configuration, minimize size, and reduce manufacturing costs.

1 is a circuit diagram of a thermosensitive electric yoke plate temperature controller according to a preferred embodiment of the present invention.

2 is an operational waveform diagram of FIG. 1. <Explanation of symbols for main parts of the drawings> 1: power fuse 2: thermal wire 3: heating wire in thermal wire 4: temperature sensitive resin in thermal wire 5: Temperature sensor 6, 12, 14: diode 7: gas discharge neon tube 8,9: SCR 10,13,15,17: Resistor 11: Capacitor

16: variable resistor

The thermal wire type electric swash plate temperature controller according to the present invention for achieving the above object is a thyristor (SCR, 9) for applying a current to the heating line (3), and a gate bias resistor (series) connected in series to the gate of the thyristor (9) 10) a heating wire heating section including a bypass diode (12) connected in series with the gate bias resistor (10), and a capacitor (11) connected in parallel between the resistor (10) and the diode (12); A variable resistor 16, a temperature sensor 5, a bypass diode 6, a gas discharge tube 7, and one of an anode and a cathode connected in series with each other are connected to the capacitor 11 and the gate is A thyristor (8) connected to the gas discharge tube (7), and the temperature control unit consisting of a gate bias resistor (17) connected in parallel between the gas discharge tube (7) and the gate of the thyristor (8).

1 is a circuit configuration diagram of the thermosensitive wire immersion plate temperature controller of the present invention, as can be seen with reference to the same drawing, the thermosensitive wire immersion plate temperature controller of the present invention is composed of a heating line heating unit and a temperature control unit.

The heating line heating unit includes a heating line 3, a plurality of diodes 12 and 14, a gate bias resistor 10, a capacitor 11, and a SCR (Silicon Controlled Rectifier) 9, and the temperature control unit includes a variable resistor 16. ), Resistor (15), temperature sensor (5), diode (6), gas discharge neon tube (7), gate bias resistor (17), and SCR (8).

For reference, '1', which is not described in the above configuration, is an overcurrent protection power fuse that melts when an overcurrent flows through the heating line 3, and '2' represents a modularization of the heating line 3 and the temperature sensor 5. '4' is a temperature sensitive resin that electrically insulates the heating wire (2) and the temperature sensor (5), but transmits heat, and '13' prevents an overcurrent from flowing to the anode of the SCR (8). This is a resistor for overcurrent limit.

Effects of the present invention configured as described above will be described with reference to FIGS. 1 and 2.

First, when the waveform of the phase as shown in FIG. 2 (a) from the AC power source is applied to the thermosensitive wire type temperature regulator of the present invention, the variable resistor 16 → resistance 15 → temperature sensor 5 → diode ( 6)? Gas discharge neon tube 7? Resistance 17, a current is applied to the gate of SCR 8, and a trigger signal such as the waveform c of FIG. 2 is applied.

Here, the resistor 15 is an element protection resistor for preventing overcurrent from flowing through the gate of the SCR 8 and the variable resistor 16.

In addition, the gas discharge neon tube 7 is a kind of gas discharge tube, and performs the automatic temperature control function by maintaining the voltage level of the trigger signal at the electrostatic potential based on the negative resistance characteristic generated during discharge, that is, the temperature is inversely proportional to the resistance value. Is a device for generating a constant voltage trigger signal.

As described above, when a trigger signal as shown in FIG. 2C is applied from the gas discharge neon tube 7 to the gate of the SCR 8, the SCR 8 is conducted while the trigger signal is applied, and the SCR 8 is turned on. During the period of conduction, the current Ic flows through the diode 12 → capacitor 11 → resistor 13 → SCR 8, and the capacitor 11 is charged during the period in which this current flows.

Here, the diode 12 is provided to prevent reverse discharge.

The capacitor 11 is charged with a voltage for a half cycle of the half cycle forming the high level of the AC power, and the voltage charged in the capacitor 11 is discharged after being charged, and then the SCR from the capacitor 11 through the resistor 10. The gating current Ig flows to the gate of (9) so that the SCR 9 is conducted. At this time, the charge / discharge cycle of the capacitor 11 is as shown in FIG.

However, if the SCR 9 is not conducting while the capacitor 11 is charged before being discharged and the low cycle of the low level of the AC power supply starts, the fuse (1) → heating line (3) → SCR (9) → from zero potential A current Ih flows through the diode 14, and an AC half-wave voltage such as the waveform e of FIG. 2 is applied to both ends of the heating line 3 to generate heat.

As described above, when the heating line 3 generates heat, the impedance between the temperature sensor 5 and the heating line 3 is lowered, so that the potential of the gas discharge neon tube 7 becomes lower during the next half cycle (high level) of the AC power supply. In the gas discharge neon tube 7, no trigger signal is generated, and therefore, the SCR 8 is not conducted.

The trigger potential of the gas discharge neon tube 7 is determined by the resistance value of the variable resistor 16, so that when the user adjusts the resistance value of the variable resistor 16, the current value applied to the heating line 3 is changed to the electric potential. The temperature can be adjusted. For reference, the change in the internal impedance of the thermal line 2 will be described in more detail as follows. When heat is generated in the heating line 3, the insulation resistance value of the temperature sensitive resin 4 accumulated on the outer wall of the thermal line 3 changes, and the resistance value of the temperature sensitive resin 4 changes due to the change in the resistance value of the temperature sensitive resin 4. The capacitance value and resistance value between the temperature sensor 5 and the heating wire wound around the bar change, so that the combined impedance value between the temperature sensor 5 and the heating wire 3 changes.

Here, the temperature sensor 5 has a negative resistance characteristic in which temperature and resistance are inversely proportional. When the temperature increases, the impedance value decreases, and when the temperature is low, the impedance value increases.

As described above, according to the present invention, a trigger signal corresponding to the temperature of the heating wire and the temperature value of the variable resistor set by the user is generated in the temperature control unit every half cycle of the AC power, and the heating line heating unit according to the trigger signal for the remaining half cycle. It is configured to apply current to the heating line in the circuit, and the circuit is composed of simple elements, so the number of parts is small compared to the case of using a plurality of integrated circuits as in the prior art and constructing an auxiliary power circuit for supplying operating power to the integrated circuit Since the structure is simple, the volume of the thermostat can be minimized and the manufacturing cost can be reduced.

Claims (1)

In the thermosensitive wire type yoke board temperature controller for controlling the temperature of the electric yaw by adjusting the current value applied to the heating line (3), Thyristor (SCR) 9 for applying current to the heating line (3), a gate bias resistor (10) connected in series with the gate of the thyristor (9), and a bypass connected in series with the gate bias resistor (10) A heating line heating part composed of a diode 12 and a capacitor 11 connected in parallel between the resistor 10 and the diode 12, A variable resistor 16, a temperature sensor 5, a bypass diode 6, a gas discharge tube 7, a thyristor 8 anode connected in series with each other are connected in series with the resistor 13 and the capacitor 11 in series. And a temperature regulating part comprising a gate bias resistor (17) connected in parallel between the gas discharge tube (7) and the gate of the thyristor (8).