JPH0458259B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION <Industrial Application Field> The present invention relates to a power supply protection device that protects a power supply circuit from overcurrents, inrush currents, and surge voltages such as those caused by lightning strikes.

<Prior art> Figure 5 shows an overcurrent protection circuit using a positive characteristic thermistor P, Figure 6 shows an in-rush current protection circuit using a negative characteristic thermistor N, and Figure 7 shows a surge voltage circuit using a varistor V. be. In each figure, reference numeral 1 indicates an AC power supply, 2 a rectifying diode bridge, 3 a smoothing capacitor, and SW a switch.

In the overcurrent protection circuit shown in FIG. 5, the positive temperature coefficient thermistor P maintains a low resistance value during normal operation. However, if some abnormality occurs in the smoothing capacitor 3 or a load (not shown) and the output side of the power supply circuit is short-circuited, causing an overcurrent to flow, the temperature of the PTC thermistor P will rise due to this overcurrent. Its resistance value rises rapidly. As a result, the overcurrent is suppressed and the power supply circuit is protected.

In addition, in the in-rush current protection circuit shown in Figure 6, the negative characteristic thermistor N is connected to the switch SW.
It shows a high low resistance value at the time of injection. Therefore, a large inrush current flowing through the smoothing capacitor 3 when the switch SW is turned on is suppressed. Then,
After a while after the switch SW is turned on,
Since the temperature of the negative characteristic thermistor N increases due to self-heating, its resistance value decreases, and the low resistance value is maintained during normal operation.

On the other hand, in the surge voltage protection circuit shown in FIG. 7, the varistor V is in a cut-off state during normal operation. However, when a surge voltage enters the AC power supply 1 from a lightning strike or other equipment, the varistor V absorbs this surge voltage and protects the power supply circuit.

<Problems to be Solved by the Invention> However, in conventional power supply protection devices, as mentioned above, the positive temperature coefficient thermistor, the negative coefficient thermistor, and the varistor are each individually attached to the power supply circuit, so it is difficult to use a printed circuit board. There were problems in that the space occupied increased and the installation work became complicated.

The present invention has been made in view of the above circumstances, and it is an object of the present invention to provide a power supply protection device that is space-saving, easy to install, and quick in protection operation.

<Means for Solving the Problems> In order to achieve the above object, the present invention has the following features.

That is, in the power protection device according to the present invention, a positive characteristic thermistor, a negative characteristic thermistor, and a varistor are housed in one case, and one terminal of each of the positive characteristic thermistor, negative characteristic thermistor, and varistor is The other terminal of the negative characteristic thermistor is connected to one end of the load circuit, the other terminal of the positive characteristic thermistor is connected to the power supply, and the other terminal of the varistor is connected to the other end of the load circuit and the power supply. The positive thermistor and the varistor are in a thermally close relationship, and the positive thermistor and the varistor are in a thermally sparse relationship with the negative thermistor. , each is characterized by being familiar.

<Function> As mentioned above, the positive characteristic thermistor, negative characteristic thermistor, and varistor are housed in one case, so when incorporating this power supply protection device into a power supply, the area occupied by the printed circuit board is reduced. Moreover, the installation work can be easily performed.

In addition, since the PTC thermistor and the varistor have a close thermal relationship, when a surge voltage is applied to the varistor for a long time and the varistor generates abnormal heat, this heat is quickly transferred to the PTC thermistor, causing the PTC thermistor to generate heat. By doing so, the resistance value increases rapidly and the circuit current is suppressed to a low level, thereby preventing thermal breakdown of the varistor. Furthermore, since the positive temperature coefficient thermistor and the negative temperature coefficient thermistor have a thermally sparse relationship, the inconvenience that the resistance value of the positive temperature coefficient thermistor increases due to the heat generated from the negative temperature coefficient thermistor during normal operation is avoided. be done.

<Embodiment> FIG. 1 is a circuit diagram of a power supply device using an embodiment of the present invention. In this figure, the same parts as in FIGS. 5 to 7 are indicated by the same reference numerals. The positive characteristic thermistor P, the negative characteristic thermistor N, and the varistor V are housed in one insulating case to constitute the power protection device 10 according to this embodiment. Hereinafter, the structure of the power protection device 10 will be explained with reference to FIGS. 2 to 4.

The common terminal 11 is a thin rectangular metal plate,
There is a long and narrow slit 12 along the short side in the central part.
is formed. A positive temperature coefficient thermistor P and a varistor V are fixed to one side of the common terminal 11 divided by the slit 12 so as to face each other. Also,
A negative characteristic thermistor N is fixed to the other side of the common terminal 11. Contact pieces of terminals 13 to 15 are connected to each surface electrode of the positive characteristic thermistor P, varistor V, and negative characteristic thermistor N fixed to the common terminal 11. The positive temperature coefficient thermistor P and the like to which the terminals 13 to 15 are connected are housed in one insulating case 16, and the terminals 13 to 15 are housed in one insulating case 16.
One end of the insulating case 16 is led out from the lower surface of the insulating case 16.

Next, the operation of the above-described embodiment will be explained.

When the switch SW is turned on, each element is at room temperature, so the positive characteristic thermistor P exhibits a low resistance value, while the negative characteristic thermistor N exhibits a high resistance value. Therefore, the inrush current flowing into the smoothing capacitor 3 when the switch SW is turned on is suppressed by the negative characteristic thermistor N exhibiting high and low resistance values. During normal operation, both the negative characteristic thermistor N and the positive characteristic thermistor P exhibit a low resistance value, and the varistor V has a large resistance value and is in a current cutoff state. Here, when the output side is short-circuited and an overcurrent flows in the power supply circuit, the positive temperature coefficient thermistor P generates heat and its low resistance value increases rapidly. the result,
The overcurrent is suppressed. On the other hand, when a surge voltage is superimposed on the AC power supply 1, this surge voltage is short-circuited to ground via the varistor V, thereby protecting the power supply circuit.

By the way, the respective operating temperatures T _P , T _N , and TV of the above-mentioned positive characteristic thermistor P, negative characteristic thermistor N, and varistor _V are as follows: T _P =50°C to 100°C T _N =100°C to 200°C T _V = The temperature is 0°C to 50°C, and the negative temperature thermistor N generates the highest amount of heat under normal operating conditions. Alternatively, if the negative thermistor N, positive thermistor P, and varistor V are not thermally isolated, the heat generated from the thermistor N is conducted to the thermistor P, P, and the varistor V. Characteristic thermistor P
and increase the temperature of the varistor V. As a result, the low resistance value of the positive temperature coefficient thermistor P increases, and even though no overcurrent is flowing, the current flowing in the power supply circuit is suppressed, which is inconvenient. Therefore, as described above, the positive temperature thermistor P and the negative temperature thermistor N fixed to the common terminal 11 are made to have a more sparse thermal relationship through the slit 12, so that the positive temperature thermistor P becomes the negative temperature thermistor. This made it less susceptible to thermal effects from N.

On the other hand, if the temperature of the varistor V increases due to the heat generated by the negative characteristic thermistor N, the surge resistance of the varistor V may decrease, so it is desirable to thermally isolate the two. Therefore, in the embodiment described above, the slit 12 is used to further establish a thermally sparse relationship between the negative characteristic thermistor N and the varistor V.

In addition, the positive temperature coefficient thermistor P and the varistor V are in a close thermal relationship, and if a surge voltage is applied to the varistor V for a long time, the varistor V will instantly reach a high temperature and be thermally destroyed. prevent that. Therefore, if the varistor V and the positive temperature coefficient thermistor P are fixed to face each other on the front and back surfaces of the common terminal 11 as in the above embodiment, and the thermal coupling is made tight,
The heat generated by the varistor V is conducted to the PTC thermistor P, and the low resistance value of the PTC thermistor P increases. As a result, the surge current flowing through the varistor V is suppressed by the positive temperature coefficient thermistor P, and thermal destruction of the varistor V is prevented.

Note that in the above embodiment, the negative characteristic thermistor N
A slit 12 is formed in the common terminal 11 in order to create a thermally sparse relationship between the positive temperature coefficient thermistor P and the varistor V. However, the present invention is not limited to this, and various modifications can be made, such as cutting off the common terminal 11 at the center, for example.
Further, it goes without saying that the means for bringing the positive temperature coefficient thermistor P and the varistor V into a close thermal relationship are not limited to those described in the embodiments.

<Effects of the Invention> As is clear from the above explanation, the power supply protection device according to the present invention has a positive characteristic thermistor, a negative characteristic thermistor, and a varistor that are housed in one case and are integrated. When the inventive device is incorporated into a power supply circuit, the area occupied by the printed circuit board is reduced, and the installation work can be performed more easily than in the conventional case where individual parts are attached.

Further, in the device of the present invention, since the positive temperature coefficient thermistor and varistor and the negative coefficient thermistor are configured in a thermally sparse relationship, the heat generated from the negative coefficient thermistor during normal operation causes the temperature of the positive coefficient thermistor to rise. As a result of the increase in the low resistance value, the inconvenience that the current flowing in the power supply circuit is suppressed even though no overcurrent is flowing does not occur.

Furthermore, in the device of the present invention, since the positive temperature coefficient thermistor and the varistor are configured in a close thermal relationship,
When a surge voltage is input for a long time and the varistor overheats, the temperature of the positive temperature coefficient thermistor also rises quickly, its low resistance value increases, and the circuit current is kept low, preventing thermal breakdown of the varistor. It can also be prevented.

[Brief explanation of drawings]

FIG. 1 is a circuit diagram of a power supply device using an embodiment of the present invention, FIG. 2 is a schematic diagram of the configuration of a power protection device according to the embodiment shown in FIG. 4 is an exploded perspective view, FIG. 4 is an external perspective view of the above embodiment, FIG. 5 is a conventional overcurrent protection circuit using a positive characteristic thermistor P, and FIG. 6 is a negative characteristic thermistor N.
FIG. 7 shows a conventional pulse high voltage protection circuit using a varistor V. P...Positive characteristic thermistor, N...Negative characteristic thermistor, V...Varistor, 10...Power protection device,
11...Common terminal, 12...Slit, 13-1
5...terminal, 16...insulation case.

Claims (1)

[Claims] 1 A positive characteristic thermistor, a negative characteristic thermistor, and a varistor are housed in one case, and one terminal of each of the positive characteristic thermistor, negative characteristic thermistor, and varistor is connected within the case, and the negative The other terminal of the characteristic thermistor is led out of the case so that it is connected to one end of the load circuit, the other terminal of the positive characteristic thermistor is connected to the power supply, and the other terminal of the varistor is connected to the other end of the load circuit and the power supply. The positive thermistor and the varistor are in a close thermal relationship, and the positive thermistor and the varistor are in a sparse thermal relationship with the negative thermistor. Power protection device.