KR200402040Y1 - Temperature controller for mat - Google Patents

Abstract

The present invention relates to a temperature controller for the mat, in particular, the AC power supply for supplying the power voltage sine wave of the (+) half wave and (-) half wave, and is lit by the voltage applied from the AC power supply to indicate whether or not the power supply The power display unit, a reference voltage generator for dividing the AC power supplied from the AC power supply unit to provide a reference voltage, and receives the AC power from the AC power supply unit, generates heat, senses the temperature, and changes the resistance value according to the temperature. The variable heating unit, the sensor voltage charging and discharging unit for charging and discharging the voltage applied through the heating unit, and comparing the charging voltage of the sensor voltage charging and discharging unit with the reference voltage generator reference voltage switching when the charging voltage is higher than the reference voltage And a comparison / trigger section for supplying and cutting off the trigger voltage, and a variable resistor. A trigger voltage provided from the comparison / trigger unit, including a sensor voltage setting unit for varying an AC resistance value according to a positive value, and a switching voltage level of the sensor voltage charging / discharging unit to switch the comparison / trigger unit, and an SCR. Wherein the comparison / trigger part has a base at an output terminal of the sensor voltage setting part such that the comparison / trigger part is switched by a voltage output from the sensor voltage setting part. An NPN type switching transistor connected to the emitter at an output terminal of the reference voltage generator; A base is connected to the collector of the switching transistor to amplify the output current of the switching transistor, a collector is commonly connected to the emitter of the switching transistor, the emitter is connected to the output terminal of the AC power supply type PNP type Amplifying transistor; And a noise removing capacitor connected between the base of the switching transistor and the emitter so as to remove noise in the form of pulse input to the base of the switching transistor.

According to the present invention as described above, by using a single transistor of the NPN type in the comparison / trigger unit, by connecting the base of the PNP type transistor to the collector of the NPN type transistor through on-state current amplification of the NPN type transistor By triggering the SCR, the variation of the threshold voltage during switching can be reduced.

Description

TEMPERATURE CONTROLLER FOR MAT}

The present invention relates to a temperature controller for a mat, and more particularly, to a temperature controller for a mat for minimizing operation deviation and preventing malfunction due to pulsed noise.

Increasingly, our lifestyle is shifting from traditional ondol heating system to Western style residential style, and in this situation, the trend is to prefer heating type using bed. It is inconvenient to be hot in the summer and cold in the winter, and it is true that people who are familiar with the existing ondol room have a fatal effect on health and are interested in health due to the increase of the elderly population due to the aging of the current life span.

Therefore, the heating mat is used to keep the cold floor surface of the room without warmth at a certain temperature. In this heating mat, a heat generating member that generates heat by an input voltage is used. A temperature controller for preventing the temperature from rising above a predetermined temperature is used.

1 and 2, the conventional temperature controller includes an AC power supply 10, a power display 20, a reference voltage generator 30, a heat generator 40, and a sensor voltage charge. The whole 50, the comparison / trigger part 60, the sensor voltage setting part 70, and the output part 80 are comprised. Here, reference numeral D8 in the figure is a diode for the purpose of generating an overcurrent at the time of SCR short and shorting the fuse F1.

The AC power supply 10 includes a fuse F1 and a power switch PSW1, and according to the switching of the power switch PSW1, a power voltage sine wave of positive and negative half waves, that is, an AC power source. Supply power (110 / 220V).

The power display unit 20 is composed of a diode D1, a plurality of LEDs D2 and D3, and a resistor R1, and is turned on by a voltage applied from the AC power supply unit 10 to indicate whether power is supplied.

The reference voltage generator 30 includes the divided resistors R2 and R3 to divide the AC power supplied from the AC power supply 10 to provide a reference voltage V _R.

The heating unit 40 receives heating wires H1 and H2 that generate heat by receiving AC power from the AC power supply unit 10, and sensing lines S1 and S2 that detect a specific temperature by detecting AC power and between the heating line and the sensing line. It consists of a temperature sensor layer coated on. Here, the heating unit 40 further includes an LED (D4) for displaying whether or not the heating. Here, the heat generating unit 40 is a means for generating heat by sensing a power voltage of (-) half wave from the AC power supply unit 10 as shown in FIG. 2, and generating a heating wire spirally wound around the core ( H1, H2, the temperature sensor layer (nylon thermistor) coated between the sensing lines S1, S2 and the heating lines H1, H2, and the sensing lines S1, S2 spirally wound on the temperature sensor layer. Heating line (H1, H2) is a device for generating heat by receiving an AC power supply voltage, the sensing line (S1, S2) is a device for detecting a specific temperature from the outside by detecting a signal of the AC power, the temperature The sensor layer (nylon thermistor) relates to a sensing device in which an AC resistance value changes extremely large according to temperature change by covering between heating lines H1 and H2 and sensing lines S1 and S2. Heating wire, sensing wire and temperature sensor layer Typically referred to as a sense that the PVC coated heating wire (HEATER).

The sensor voltage charge / discharge unit 50 includes a capacitor C1, a resistor R4, and a diode D5 to charge the capacitor C1 with a voltage applied through the sensing lines S1 and S2 of the heat generator 40. Discharge, but the sensing voltage (Vs) is charged in the capacitor (C1) during the (+) half wave of the AC power applied from the AC2 terminal of the AC power supply 10, AC applied to the AC2 terminal of the AC power supply 10 During the negative half of the power supply, the sensing voltage Vs is discharged from the capacitor C1. Here, the level of the sensing voltage Vs of the capacitor C1 is proportional to the temperature of the heat generating unit 40 and inversely proportional to the AC resistance value.

The comparison / trigger part 60 is composed of an NPN type first and second transistors Q1 and Q2 connected to a ring of Arlingtons, a trigger voltage capacitor C2, a resistor R9 and a diode D7. During the (+) half wave of the AC power applied from the AC2 terminal of (10), the voltage is divided by the reference voltage generator 30 so that the voltage at both ends of the resistor R3 is charged to the trigger voltage capacitor C2 as the trigger voltage. The trigger current is discharged from the trigger voltage capacitor C2 during the negative half wave of the AC power applied from the AC2 terminal of the power supply unit 10, and the sensing voltage Vs and the reference voltage of the sensor voltage charge / discharge unit 50 are generated. is compared to a reference voltage (V _R) of the portion (30) sensing the voltage (Vs) is higher than the reference voltage (V _R), the first transistor (Q1) and second transistors (Q2) are turned on.

The sensor voltage setting unit 70 includes a variable resistor VR1, a plurality of resistors R5 to R8, and a diode D7, and varies the resistance value of the variable resistor VR1 according to a user's setting to fill the sensor voltage. The sensing voltage levels of the entirety 50 are varied to control the operations of the first transistor Q1 and the second transistor Q2 of the comparison / trigger unit 60.

The output unit 80 is composed of SCR (TH1). When the comparison / trigger unit 60 is turned on, the SCR (TH1) is triggered by the trigger current provided from the trigger voltage capacitor C2, and the AC power supply unit 10 is provided. The negative half-wave power supply voltage of is supplied to the heating lines H1 and H2 of the heat generating unit 40 to be heated.

Hereinafter, the operation of the conventional temperature controller will be described in detail with reference to the accompanying drawings.

First, when the power switch PSW1 is turned on by a user, an AC voltage having a sine wave is supplied from the AC power supply unit 10. The AC1 terminal of the power supply unit 10 is negative and the AC2 terminal is positive. It is the sensor charging cycle, and the AC1 stage of the power supply unit 10 is positive, and the AC2 stage is a conduction cycle of the SCR TH1 of the output unit 80 while negative.

When power is supplied from the AC power supply unit 10, the plurality of LEDs D2 and D3 of the power display unit 20 are turned on to indicate whether power is supplied to the outside, and the voltage dividing resistor of the reference voltage generator 30 is supplied during the sensor charging cycle. The upper end of the resistor R2 is negative and the lower end is positive by R2 and R3 to provide a reference voltage.

Since a negative voltage is applied to the AC1 terminal of the power supply unit 10 and a positive voltage is applied to the AC2 terminal, the sensing voltage Vs is charged to the capacitor C1, and the trigger voltage is supplied to the trigger voltage capacitor C2. The sensing current flows from AC2 stage → heating line (H2, H1) → nylon thermistor → sensing line (S2, S1) → R5 → C1 → AC2 stage and the top of capacitor (C1) The positive polarity charges the sensing voltage Vs to the capacitor C1.

At this time, since the nitro thermistor has a negative temperature characteristic, the electrical resistance decreases as the temperature increases, and the sensing current rises to charge the capacitor C1 with a voltage proportional to the temperature.

In addition, the trigger voltage flows from the AC2 stage → H2 → H1 → R3 → R2 → AC1 stage, and the AC2 stage → H2 → H1 → R10 → C2 → D6 → R2 → AC1 stage, and the divided voltage of the divided resistors R2 and R3. Among the voltages, the voltage across the R3 is charged in the trigger voltage capacitor C2 to prepare the trigger voltage, and the reference voltage V _R is generated with the polarity of (+) and (-) at the lower end of R2.

And, the sensed voltage (Vs) is R5 → S2 → S1 → R6 → VR1 → R8 → through D7 are applied to the base of the first transistor (Q1), a reference voltage (V _R) charged in the capacitor (C1) ( The voltage is applied to the emitter of the first transistor Q1 through D6 and compared at the first transistor Q1 during the sensor charging period so that the sensing voltage Vs is greater than the reference voltage V _R. The transistors Q1 and Q2 are turned on, the capacitor C2 for the trigger voltage is discharged, and the heating of the heating lines H1 and H2 is stopped because the SCR (TH1) cannot be triggered in the conduction period.

On the contrary, when the sensing voltage Vs is less than or equal to the reference voltage V _R , the first and second transistors Q1 and Q2 are not conducting, and thus the trigger voltage capacitor C2 is not discharged, and the SCR ( TH1) sensor voltage charging and discharging unit 50 → R5 → S1 → S2 → R6 → VR1 → R8 → D7 → Q1 base → Q1 emitter → C2 (−) → C2 (+) → SCR gate H1 → H2 → AC2 The current flows through the first and second transistors Q1 and Q2, and the trigger voltage capacitor C2 is discharged to generate current at the gate of the SCR TH1, thereby triggering the SCR TH1. Heating wires H1 and H2 are heated.

However, since the conventional temperature controller switches two NPN-type transistors by Darlington connection in the comparison / trigger part, the threshold voltage becomes a sum (1.2V) of the two transistors, causing a large variation in the threshold voltage. There is a problem that accurate switching is not achieved.

In addition, when the noise in the form of a pulse is introduced into the conventional comparison / trigger unit there is another problem that is recognized as a switching signal to malfunction.

In addition, since the error of the variable resistor used in the sensor voltage setting unit has a ± 20%, there is another problem that a serious deviation between the actual temperature and the sensing temperature occurs.

The present invention is to solve the above problems, the NPN type transistor by connecting the base of the PNP type transistor to the collector of the NPN type transistor by switching using one NPN type transistor in the comparison / trigger section It is an object of the present invention to provide a temperature controller for a mat to reduce the deviation of the threshold voltage during switching by triggering the SCR through the current amplification at the time of.

In addition, the present invention by connecting a capacitor to the conventional comparison / trigger unit to remove the noise in the form of a pulse when the noise is introduced in the capacitor to prevent the comparison / trigger unit malfunction due to the pulse-shaped noise The purpose is to provide.

In addition, the present invention reduces the error of the variable resistor by connecting the damping resistor in parallel to the variable resistor in order to reduce the error of the variable resistor used in the sensor voltage setting unit to minimize the deviation between the actual temperature and the sensing temperature The purpose is to provide a regulator.

Features of the present invention for achieving the above object,

An AC power supply for supplying a power voltage sine wave of positive and negative half-waves, a power display unit which is lit by a voltage applied from the AC power supply unit to indicate whether power is supplied, and an AC supplied from the AC power supply unit A reference voltage generator for dividing the power to provide a reference voltage, a heat generator that receives AC power from the AC power supply, generates heat, and detects a temperature to change a resistance value according to temperature, and is applied through the heat generator. A sensor voltage charging / discharging unit for charging and discharging a voltage, and a comparison / trigger unit for comparing the charging voltage of the sensor voltage charging and discharging unit with a reference voltage of the reference voltage generator to switch when the charging voltage is higher than the reference voltage to supply and cut off the trigger voltage. And a variable resistor, and varying the resistance value according to a user's setting to charge and discharge the sensor voltage. A sensor voltage setting unit for switching the comparison / trigger unit by varying a charge voltage level of the output unit, and an output unit including an SCR and switched by a trigger voltage provided from the comparison / trigger unit to supply power to the heat generating unit. In the temperature controller for the mat, the base unit is connected to the output terminal of the sensor voltage setting unit to be switched by the voltage output from the sensor voltage setting unit, the emitter is connected to the output terminal of the reference voltage generator NPN type switching transistors; The base is connected to the collector of the switching transistor to amplify the output voltage of the switching transistor, the emitter is commonly connected to the emitter of the switching transistor, the collector is connected to the output terminal of the AC power supply type PNP type Amplifying transistor; And a noise removing capacitor connected between the base of the switching transistor and the emitter so as to remove noise in the form of pulse input to the base of the switching transistor.

The sensor voltage setting unit may further include a damping resistor connected in parallel thereto to reduce the variation of the resistance value of the variable resistor.

Hereinafter, with reference to the accompanying drawings, the configuration of the temperature controller for the mat according to the present invention will be described in detail.

3 is a block circuit diagram showing the configuration of a temperature controller for a mat according to the present invention.

In the following description of the present invention, if it is determined that the detailed description of the related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. In addition, terms to be described below are terms defined in consideration of functions in the present invention, which may vary according to intention or custom of a user or an operator. Therefore, the definition should be made based on the contents throughout the specification.

Referring to FIG. 3, the mat temperature controller 100 according to the present invention includes an AC power supply unit 10, a power display unit 20, a reference voltage generator 30, a heating unit 40, The sensor voltage charge / discharge unit 50, the comparison / trigger unit 110, the sensor voltage setting unit 120, and the output unit 80 are configured.

First, the comparison / trigger unit 110 includes a switching transistor Q10, an amplifying transistor Q20, a trigger voltage capacitor C2, and a noise removing capacitor C10.

The switching transistor Q10 is of NPN type, the base of which is connected to the output terminal of the sensor voltage setting unit 120 to be switched by the voltage output from the sensor voltage setting unit 120, and the output terminal of the reference voltage generator 30. The emitter is connected.

The amplifying transistor Q20 is a PNP type, the base of which is connected to the collector of the switching transistor Q10 to amplify the output current of the switching transistor Q10, and the collector is common to the emitter of the switching transistor Q10. The emitter is connected to the output terminal of the AC power supply unit 10.

In the trigger voltage capacitor C2, the sensing voltage Vs is charged in the capacitor C1 during the positive half wave of the AC power applied from the AC1 terminal of the AC power supply 10, and the AC1 of the AC power supply 10 During the negative half-wave of the AC power applied from the stage, the sensing voltage Vs is discharged from the capacitor C1.

The noise removing capacitor C10 is connected between the emitter and the base of the switching transistor Q10 to remove noise in the form of pulse input to the base of the switching transistor Q10.

In addition, the sensor voltage setting unit 120 includes a variable resistor VR1, a plurality of resistors R5 to R8, and a diode D7, and is connected in parallel thereto so as to reduce variation in resistance values of the variable resistor VR1. It further comprises a damping resistor (DR10).

Hereinafter, the operation of the mat temperature controller according to the present invention in detail with reference to FIG.

First, when the power switch PSW1 is turned on by a user, an AC voltage having a sine wave is supplied from the AC power supply unit 10. The AC1 terminal of the power supply unit 10 is negative and the AC2 terminal is positive. It is the sensor charging cycle, and the AC1 stage of the power supply unit 10 is positive, and the AC2 stage is a conduction cycle of the SCR TH1 of the output unit 80 while negative.

When power is supplied from the AC power supply unit 10, the plurality of LEDs D2 and D3 of the power display unit 20 are turned on to indicate whether power is supplied to the outside, and the voltage dividing resistor of the reference voltage generator 30 is supplied during the sensor charging cycle. The upper end of the resistor R2 is negative and the lower end is positive by R2 and R3 to provide a reference voltage.

Since a negative voltage is applied to the AC1 terminal of the power supply unit 10 and a positive voltage is applied to the AC2 terminal, the sensing voltage Vs is charged to the capacitor C1, and the trigger voltage is supplied to the trigger voltage capacitor C2. The sensing current flows from AC2 stage → heating line (H2, H1) → nylon thermistor → sensing line (S2, S1) → R5 → C1 → AC2 stage and the top of capacitor (C1) The positive polarity charges the sensing voltage Vs to the capacitor C1.

At this time, since the nitro thermistor has a negative temperature characteristic, the electrical resistance decreases as the temperature increases, and the sensing current rises to charge the capacitor C1 with a voltage proportional to the temperature.

In addition, the trigger voltage flows from the AC2 stage → H2 → H1 → R3 → R2 → AC1 stage, and the AC2 stage → H2 → H1 → R10 → C2 → D6 → R2 → AC1 stage, and the divided voltage of the divided resistors R2 and R3. Among the voltages, the voltage across the R3 is charged in the trigger voltage capacitor C2 to prepare the trigger voltage, and the reference voltage V _R is generated with the polarity of (+) and (-) at the lower end of R2.

In addition, the sensing voltage Vs charged in the capacitor C1 passes through R5 → S2 → S1 → R6 → VR1 → R8 → D7 and R5 → S2 → S1 → R6 → DR10 → R8 → D7. ) is (+) voltage of the reference voltage (V _R is applied to the base) is compared in the switching emitter is applied to the emitter sensor charging cycle the switching transistor (Q10) for for the transistor (Q10) for through D6 sensing voltage (the When Vs) is greater than the reference voltage V _R , the switching transistor Q10 is turned on, the trigger voltage capacitor C2 is discharged, and SCR (TH1) cannot be triggered during the conduction period, thereby heating the heating lines H1 and H2. Is stopped. Here, the resistance error may be reduced by connecting the damping resistor DR10 in parallel with the variable resistor VR1 of the sensor voltage setting unit 120. That is, the error range of the variable resistor VR1 is reduced by the sum of the resistance values of the variable resistor VR1 and the damping resistor DR10.

On the contrary, if the sensing voltage Vs is less than or equal to the reference voltage V _R , the switching transistor Q10 is not conducting, and thus the trigger voltage capacitor C2 is not discharged. Voltage charging and discharging unit 50 → R5 → S1 → S2 → R6 → VR1 → R8 → D7 → Q10 Base → Q10 emitter → C2 (−) → C2 (+) → SCR gate H1 → H2 → AC2 stage and sensor voltage charging All (50) → R5 → S1 → S2 → R6 → DR1 → R8 → D7 → Q10 Base → Q10 Emitter → C2 (-) → C2 (+) → SCR Gate H1 → H2 → AC2 The switching transistor Q10 is turned on, the trigger voltage capacitor C2 is discharged, and a current is generated in the SCR (TH1) gate, which causes the SCR (TH1) to be triggered to heat the heating lines H1 and H2. At this time, since only one switching transistor Q10 is used and the threshold voltage is 0.6V, the operation deviation is minimized.

According to the mat temperature controller of the present invention, which is configured as described above, the NPN type is connected by switching using one NPN type transistor in the comparison / trigger part, and connecting the base of the PNP type transistor to the collector of the NPN type transistor. By amplifying the SCR through on-state current amplification of the transistor, the threshold voltage can be reduced.

In addition, according to the present invention by connecting a capacitor to the conventional comparison / trigger unit when the noise in the form of pulse can be removed from the capacitor to prevent the comparison / trigger unit malfunction due to the noise of the pulse form.

In addition, according to the present invention it is possible to minimize the deviation of the actual temperature and the sensing temperature by reducing the error of the variable resistor by connecting the damping resistor in parallel to the variable resistor in order to reduce the error of the variable resistor used in the sensor voltage setting unit.

The present invention may be variously modified and may take various forms, and the detailed description of the present invention has been described only with respect to specific embodiments thereof. It is to be understood, however, that the present invention is not limited to the specific forms referred to in the description, but rather includes all modifications, equivalents, and substitutions within the spirit and scope of the invention as defined by the appended claims. Should be.

1 is a block circuit diagram showing the configuration of a conventional temperature controller;

2 is a perspective view showing the configuration of a heat generating unit of a conventional temperature controller;

Figure 3 is a block circuit diagram showing the configuration of the temperature controller for mat according to the present invention.

<Explanation of symbols on main parts of the drawings>

10: AC power supply 20: power display

30: reference voltage generator 40: heat generating unit

50: sensor voltage charge / discharge unit 60, 110: comparison / trigger rejection

70, 120: sensor voltage setting unit 80: output unit

Claims (2)

An AC power supply for supplying a power voltage sine wave of positive and negative half-waves, a power display unit which is lit by a voltage applied from the AC power supply unit to indicate whether power is supplied, and an AC supplied from the AC power supply unit A reference voltage generator for dividing the power to provide a reference voltage, a heat generator that receives AC power from the AC power supply, generates heat, and detects a temperature to change a resistance value according to temperature, and is applied through the heat generator. A sensor voltage charging / discharging unit for charging and discharging a voltage, and a comparison / trigger unit for comparing the charging voltage of the sensor voltage charging and discharging unit with a reference voltage of the reference voltage generator to switch when the charging voltage is higher than the reference voltage to supply and cut off the trigger voltage. And a variable resistor, and varying the AC resistance value according to a user's setting to charge the sensor voltage. A sensor voltage setting unit for switching the comparison / trigger unit by varying all charging voltage levels, and an output unit having an SCR and switched by a trigger voltage provided from the comparison / trigger unit to supply power to the heat generating unit. In the temperature controller for mat which consists of, The comparison / trigger unit, A NPN type switching transistor having a base connected to an output terminal of the sensor voltage setting unit so as to be switched by a voltage output from the sensor voltage setting unit, and an emitter connected to an output terminal of the reference voltage generator; A base is connected to the collector of the switching transistor to amplify the output current of the switching transistor, a collector is commonly connected to the emitter of the switching transistor, the emitter is connected to the output terminal of the AC power supply type PNP type Amplifying transistor; And And a noise removing capacitor connected between the base and the emitter of the switching transistor so as to remove noise in the form of pulse input to the base of the switching transistor. The method of claim 1, The sensor voltage setting unit, And a damping resistor connected in parallel thereto so as to reduce a variation in the resistance value of the variable resistor.