JPH029369Y2 - - Google Patents

Description

[Detailed description of the invention] (Field of industrial application) The present invention uses a reed switch, a permanent magnet, and a temperature-sensitive magnet as a control means for a three-pole bidirectional thyristor (hereinafter referred to as a TRIAT) that controls current supply to a load. The present invention relates to a band-operated temperature control device that uses a normally open temperature switch in combination with a temperature-sensitive inductor using a magnetic core made of a temperature-sensitive magnetic material to bring a triac into conduction in a constant temperature range.

(Prior Art) FIG. 1 shows an example of a conventional band-operated temperature control device using a triac. A combination of a commercial AC power supply 1, a triax 3, a voltage dividing resistor 4, and a temperature-sensitive inductor 5 in order to supply power to the temperature-controlled load 2 only in a certain temperature range;
A transformer T is combined with a combination of a commercial AC power supply 1', a triax 3', a voltage dividing resistor 4', and a temperature sensitive inductor 5'.

Regarding one combination, the first primary winding T11 of the transformer T and the triax 3 are connected in series to the commercial AC power supply 1. Further, a series circuit of a voltage dividing resistor 4 and a temperature-sensitive inductor 5 is connected in parallel to the series circuit of the first primary winding T11 and the triac 3, and the temperature-sensitive inductor 5 transfers the induced voltage to the gate of the triac 3. connected to supply. The temperature-sensitive inductor 5 uses a magnetic core made of a temperature-sensitive magnetic material having a rectangular hysteresis characteristic and a low Curie point _Tc1 , and is disposed close to a temperature-detected portion heated or cooled by the load 2.

The difference from the above description in the other combination is that the triax 3' is connected to the first primary winding T11.
is connected to the second primary winding T12 of opposite phase to
The Curie point of the magnetic core of the temperature sensitive inductor 5' is T _c2 which is higher than T _c1 .

The load 2 may be a heater, a cooler, etc. of an air conditioner, and is connected to the secondary winding T22 of the transformer T. First and second primary windings T11, T
12 and the number of windings of the secondary winding T22 are equal.

The band operation will be briefly explained with reference to FIG. 7 as well.

If the temperature of the detected part is below the Curie point T _c1 ,
When switches 6, 6' are closed, voltage dividing resistor 4,
4' and the temperature-sensitive inductor 5, 5', the magnetic flux generated by the current flowing through the R-L circuit of the temperature-sensitive inductor 5, 5'
Since the magnetic core 5' has a rectangular hysteresis characteristic and saturates quickly, it becomes a trapezoidal wave that almost corresponds to the current waveform, and positive and negative voltage pulses are induced in the temperature-sensitive inductors 5 and 5' corresponding to the parts where the magnetic flux changes rapidly. be done. By setting this voltage pulse to be greater than or equal to the voltage pulse _Vpp required to fire the gates of the triacs 3, 3', the triacs 3, 3' are rendered conductive. In this state, the first
Since the primary winding T11 and the second primary winding T12 have opposite phases, the induced voltages of the two are canceled out, and no power is supplied to the load 2.

When the temperature of the detected part rises and reaches near the Curie point _Tc1 , the magnetic core of the temperature-sensitive inductor 5 becomes paramagnetic, so the temperature-sensitive inductor 5 receives the required voltage pulse.
_Vpp is not induced and therefore triax 3 is turned off (Figure 7a). In this state, power is supplied to the load 2 by the second primary winding T12.

When the temperature of the detected part further increases and reaches the Curie point _Tc2 , the magnetic core of the temperature-sensitive inductor 5' also becomes paramagnetic, and the triax 3' is also turned off (FIG. 7b).

In this way, as shown in FIG. 7c, the load 2
Power is supplied to the temperature range between the Curie points _Tc1 and _Tc2 . Such a function is required when, for example, battery charging, power is supplied within a certain temperature range and power supply is stopped outside the temperature range.

(Problem to be solved by the invention) By the way, in order to make such a temperature control device a band-operated type, in addition to the transformer T, two sets of temperature-sensitive inductors and triaxes are required, resulting in problems such as an increase in size and cost. There is.

In view of these problems, the technical problem of the present invention is to realize a band-operated temperature control device with a simple configuration.

(Means for Solving the Problems) The present invention consists of a temperature-controlled load driven by an AC power supply, a triax for controlling energization to the load, and a temperature-sensitive core having a predetermined first Curie point. an inductor, which is disposed in the temperature-detected section, and is connected in parallel to the triac and the load via a voltage dividing resistor so as to apply the voltage induced in the temperature-sensitive inductor to the gate of the triac. In the temperature control device equipped with a temperature-sensitive inductor, the gate circuit of the triax includes a reed switch, a permanent magnet, and a temperature-sensitive magnetic material having a second Curie point lower than the first Curie point, and the temperature to be detected is The feature is that a normally open temperature switch located in the section is inserted and connected.

(Embodiment) The present invention is characterized by the combination of a temperature-sensitive inductor and a normally open type temperature switch. Before describing the embodiments of the present invention, the normally open type temperature switch will be explained.

FIG. 2 shows a cross-sectional view of the temperature switch used in the present invention. A ring-shaped paramagnetic material 8 is sandwiched around the outer periphery of the reed switch 7, and cylindrical permanent magnets 9, 9 and temperature-sensitive magnetic materials 10, 10 are fitted. Normally, the contacts of this switch are in an open state, and the temperature-sensitive magnetic material 10
It is a so-called normally open type temperature switch, in which the contact closes when the temperature of the switch exceeds its Curie point. This switch has features such as small size, low cost, high reliability, and long life, but because the contact capacity of the reed switch 7 is small, it cannot be used directly when the load is large.

However, according to the present invention, by combining a temperature-sensitive inductor and the above-mentioned temperature switch, it is possible to provide a band-operated temperature control device that is highly reliable and can be applied to large current loads.

Examples of the present invention will be described below.

FIG. 3 shows a circuit diagram of an embodiment of the present invention, in which a temperature switch 11 shown in FIG. 2 is inserted and connected between the temperature-sensitive inductor 5 and the gate of the triac 3 shown in FIG. Also, like the temperature-sensitive inductor 5, the temperature switch 11 is placed close to the temperature-detected section. Here, as the characteristics of each temperature-sensitive magnetic material are shown in _{FIG .} It is set lower. In FIG. 4, the solid line shows the magnetic permeability-temperature characteristic of the inductor 5, and the broken line shows the saturation magnetic flux density-temperature characteristic of the temperature switch 11, respectively.

A case where the load 2 has a heat generating effect will be explained.

In this device, when the switch 6 is turned on and the commercial power supply 1 is applied, a voltage pulse is applied to the temperature-sensitive inductor 5.
_Vpp is induced. However, while the temperature of the temperature-sensitive magnetic material 10 of the temperature switch 11 is below its Curie point _Tc1 (low temperature range), the reed switch contacts are in an open state, so no voltage pulse is applied to the gate of the triac 3. Triax 3 is in a non-conducting state.

The temperature detected part is in the medium temperature range, that is, the temperature switch 11
In the temperature range above the Curie point T _c1 of the temperature-sensitive magnetic material 10 and below the Curie point T _c2 of the magnetic core of the temperature-sensitive inductor 5, the contact of the temperature switch 11 is in a closed state, and the voltage induced in the temperature-sensitive inductor 5 is pulse
Since _Vpp is applied to the gate of the triac 3, the triac 3 becomes conductive and power is supplied to the load 2.

When the temperature of the magnetic core of the temperature-sensitive inductor 5 reaches the Curie point T _c2 (high temperature range) due to the heat generated by the load 2, the contact of the temperature switch 11 remains closed, but the temperature-sensitive inductor 5 receives the required voltage pulse V. _PP is not induced, triac 3 becomes non-conducting, and load 2
Power is cut off. After a certain period of time, when the magnetic core of the temperature-sensitive inductor 5 becomes magnetic due to a decrease in temperature,
A voltage pulse V _pp is induced, and the triac 3 becomes conductive again. For example, as shown in FIG. 5, if the Curie point T _c1 of the temperature-sensitive magnetic body 11 is 25°C and the Curie point T _c2 of the magnetic core of the temperature-sensitive inductor 5 is 80°C, this control device will control the temperature of the controlled part. 25℃ to 80℃
It has a temperature control function of supplying electric power P _w to the load during this period.

FIG. 6 shows an example of application to a battery charging control circuit. Operating temperature of temperature switch 11 T _c1
5℃, the Curie point T _c2 of temperature-sensitive inductor 5 is 48
℃, the temperature of the outer case of battery 12 is 5℃
It is possible to supply power for charging from the rectifier 13 in the temperature range of 48°C to 48°C, prevent overcharging in low temperature ranges, and by combining the temperature switch 11 with some kind of display means, the upper limit temperature can be set to 48°C. By detecting this, the charging end state can be detected.

(Effects of the invention) As described above, the band-operated temperature control device according to the invention can be realized in a small size and at a low cost by combining a temperature-sensitive inductor, a temperature switch, and a triax, and can be applied to large current loads.

[Brief explanation of the drawing]

Figure 1 is an example of a circuit diagram of a conventional temperature control device.
Fig. 2 is a sectional view of a temperature switch used in the present invention, Fig. 3 is a circuit diagram showing an embodiment of the invention, and Fig. 4 is a temperature characteristic diagram of a temperature-sensitive inductor and a temperature-sensitive material used in the temperature switch. , Fig. 5 is a diagram showing the relationship between detected temperature and power supply, Fig. 6 is a circuit diagram showing an example of application to a battery charge control circuit, and Fig. 7 is a diagram showing the temperature control device shown in Fig. 1. FIG. In the figure, 1... AC power supply, 2... Temperature-controlled load, 3... Triax, 5... Temperature-sensitive inductor, 6... Power switch, 7... Reed switch, 9... Permanent magnet, 10... Temperature-sensitive magnetic material, 11
...Temperature switch, 12...Battery, 13...
rectifier.

Claims (1)

[Scope of utility model registration request] a temperature-controlled load driven by an AC power source;
A bidirectional thyristor for controlling the supply of current to the load, and an inductor made of a magnetic core having a predetermined first Curie point, which is disposed at the temperature detection section and is connected to the thyristor and the load via a voltage dividing resistor. and an inductor connected in parallel to the gate circuit of the thyristor so as to apply a voltage induced in the inductor to the gate of the thyristor. 1. A temperature control device, characterized in that a normally open temperature switch made of a temperature-sensitive magnetic material having a second Curie point lower than the Curie point of the temperature detection section is inserted and connected.