KR950004454Y1 - Protective apparatus - Google Patents

Abstract

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Description

Burnout prevention device of electric equipment

1 is an exemplary view of the present invention implemented in a transformer.

2 is a structural diagram of a winding disconnected for heating by overcurrent in the present invention.

3 is a circuit diagram of another embodiment of the present invention.

4 is a circuit diagram when carried out in equipment not using a transformer.

* Explanation of symbols for main parts of the drawings

F: Thermal element M, M ': Insulator for thermal element

L: Protective induction winding LC: Center point of protective induction winding

T ₁ , T ₂ : Input terminal N ₁ : Primary winding of transformer

N ₂ : secondary winding of transformer t ₁ , t ₂ : lead-out terminal of transformer primary

SW: Circuit Breaker

The present invention is designed to prevent the loss of overheating or damage to the electrical equipment due to improper operation of the electrical equipment due to the input of a voltage exceeding the range of the rated voltage in the equipment using a single voltage or positive voltage It is.

The operating principle of an electric device can be roughly divided into a resistance load that emits light or heat, and an induction winding load that generates electric power by an electric action due to electric current flowing in a winding. In order to prevent accidents, a widely used method is a device that cuts off and cuts off a circuit at a current higher than the rated current, that is, a method that connects a normal fuse between a power supply and a load, and generates heat by overcurrent. A method of using an overcurrent circuit breaker that opens the circuit between the contacts and breaks the circuit has been widely used.

However, these methods may be effective when the overcurrent occurs relatively quickly, but the apparatus connected to the power source frequently overheats when the state is maintained for a long time slightly beyond the rated state.

In addition, when the starting current is significantly larger than the operating current, it is difficult to set a standard of the breaking current with a conventional overcurrent blocking device, so that it is difficult to effectively protect against overload. Therefore, even though the burnout protection device as described above is installed, In many cases, electrical equipment were burned out.

Therefore, the present invention is designed to facilitate the safe use of the device by properly blocking the load even when the load is operated with a current slightly larger than the rated current for a relatively long time.

FIG. 1 is a partially cutaway perspective view of the present invention implemented in a transformer, and FIG. 2 schematically shows only a protective induction winding wound on a transformer.

In general, in the structure of a transformer, the power line is connected to the input terminals T ₁ and T ₂ , and one side T ₁ of the input terminals is connected to the transformer winding (t ₁ ) through the switch SW and the other input terminal ( t ₂₎ is connected (t ₂₎ in the fuse (F) and the winding of a transformer for example and connected to the protective non-induction winding (L) of the same winding method shown in FIG. 2 (N _1).

The protective induction winding (L) is folded in half the insulated conductor twice the length to be wound, and is wound from the middle length of the conductor, that is, the folded portion (Lc), in a constant rotational direction, and is caused by the AC resistance (XL) of the conductor. There should be no voltage drop.

In this structure, the load-side winding (N ₂ ) and the power-side winding (N ₁ ) of the transformer are wound with conductors of the proper thickness according to the current capacity, and the load-side winding when the protective uninduced winding (L) is made with the conductors of slightly smaller thickness. If excessive current flows through (N ₂ ), the heat generated by Joule's LAW, that is, the current flowing through winding N _1, is called I, and the resistance of the protective induction winding (L) is defined as 0.24 I ² Rt. The heat generation (t is the time when the current flows), and the protective induction winding having a large resistance is disconnected before the windings N ₁ and N _{2 of the} transformer to prevent burnout of the transformer winding.

In this case, L is a reverse winding close to each other, i.e., no induction winding, and thus there is almost no voltage drop.

The induction winding (L) may be wound on the outer surface of the transformer or on a separate iron core.

The present invention has a structure that prevents burnout in the case where a little more than the current or the normal current flows for a relatively long time, and it starts more than the operating current because it delays time in comparison with a protection device using ordinary electronic parts. Ideal protection even for loads with much higher currents.

In addition, in order to more effectively protect the protective induction winding in the structure of the present invention, the element F, which is melted by heat to cut off the power line directly by the heating of the main winding, has the internal temperature of the transformer main winding N ₁ , N ₂ . It is sandwiched between insulations (M, M ') of higher grade than the one installed close to the winding and connected to the power supply terminal (T ₂ ).

Reference numeral SW is an open switch.

In the case of Figure 4 is a structure that is applied to equipment that does not use a transformer.

In this structure, the protective induction winding (L) and the thermal termination element (F) are connected in series, and the induction winding (L) and the thermal termination element (F) are installed to facilitate the transfer of heat flow in the same way as the electric method.

The present invention, as compared to the conventional burnout prevention device of the electric equipment used in the past, is gentle in time, so it can operate quickly and can eliminate the possibility that the power is cut off by the momentary surge of the power supply voltage, while overvoltage and overcurrent It is a useful design that can be used semi-permanently by repairing only the damaged non-inductive winding (L) and the melted element (F).

Claims (2)

As shown in the drawings and the description, the thermal insulation insulated from the winding (N ₁ , N ₂ ) is electrically connected to the outer side of the winding (N ₁ , N ₂ ) by connecting an induction-free winding (L) and a thermal breaker element (F) to the burnout side (t ₂ ) of the transformer. A burnout prevention device for an electric appliance, in which a device (F) is installed in close contact with the power supply terminal (T ₂ ). According to claim 1, The protective winding (L) and the thermal insulation element (F) is connected in series with the load Lo and electrically insulated thermal insulation element (F) is in close contact with the protective winding (L) Burnout prevention device.