KR850002828Y1 - Overcurrent breaking apparatus - Google Patents

Abstract

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Description

Overcurrent Breaker

1 is a circuit diagram of the over-current sensing device of the present invention single-phase no hue-bureka.

2 is an embodiment in which the copper overcurrent sensing device is applied to a three-phase bureka.

* Explanation of symbols for main parts of the drawings

1: power 2: power input terminal

3: contact point 4: phosphor bronze

5: Output terminal 6: Load

7: bimetal 8 ': current transformer

11: static thermistor or resistance heating element

12: Neon or LED lamp 13: Bolt nut for operation time setting

14: breaking device key 15: mechanical breaking device

16: old lady 17: return spring

18: sublocking diode 19: indicator protection resistor

This application attaches the overload detection method regarding the overload circuit breaker (patent application 83-4954) and the fast-type overload circuit breaker and the electronic relay relay single-phase induction lamp starting device (1982 Utility Model No. 10514) which I applied for. As a device used for the Reka switch, the overcurrent detection of the existing Nohugh-Bureka is caused by the heat generated when the heat generated by the resistance loss of the current flowing through the output terminal 5 is transmitted to the bimetal 7 or directly through the bimetal. As the bimetal was curved, the operating point setting bolt 13 pushed the breaking device key 14 to operate the breaking device 15 to turn off the breca.

The existing method described above has a lot of inconveniences such as unpredictable operation, influenced by the ambient temperature, power consumption is inevitable, time-consuming overload setting, inaccuracy and material cost. In the case of three phases, the output terminals suitable for bimetal and current capacity are manufactured and mounted, and the overload operation characteristic and the overcurrent operation setting have to be adjusted separately, which leads to a high labor cost.

In the present invention, in order to solve the above-mentioned drawback, the bending of the bimetal is not caused by heat transfer of the resistance loss of the load current, and there is no heat generation in the bimetal below the set current value. The bimetal is instantaneously turned off by the power to turn off the breca.

Hereinafter, the present invention will be described with reference to the accompanying drawings to understand the purpose or effect of the present invention. FIG. 1 is a circuit and structural diagram of an embodiment of the present invention in which the power source 1 rivets the contacts 3, the phosphor bronze laminate 4, the bimetals 7, and the load terminal 5 at the power supply terminal 2. The current connected to the other side of the power source 1 through the load 6 forms a current path, installs an operating time setting bolt 13 on the upper part of the bimetal, and installs a through-type current transformer 8 in the load terminal 5, The parallel connection of the variable resistor (9) for overload setting to the secondary side of 8) is connected to T ₁ and the gate G of the thyristor or TRIAC (10), respectively, and the light protection resistor (19) in parallel with the heating element (11). The indicator device (NEON or LED) 12 is installed through, and is connected to one terminal or the power supply terminal 2 of the indicator, and one side of the heating element 11 is connected to the bimetal and the breaker key installed in the mechanical shutoff device 15. The operation time adjusting bolt 13 bolted to the bimetal is pushed, and the brake is turned off.

In the above embodiment, when the power source 1 is supplied, the load current I flows through the power source terminal 2, the contact point 3, the phosphor bronze movable piece 4, the load terminal 5, and the load 6. However, by installing the through current transformer 8 between the load terminals 5, the load current is sensed and converted to a voltage by the overcurrent setting variable resistor 9 connected in parallel to the secondary side thereof to T ₁ of the TRIAC 10. If the current value exceeds the set value, the tree of the TRIAC 10 becomes over the voltage, and the TRIAC is energized.

When the TRIAC 10 is energized, the current I _H flows through the resistance heating element 11 attached to the bimetal to generate heat to operate the bimetal to adjust the distance between the bolt 13 installed on the top of the bimetal and the blocking device key 14. When the end of the adjusting bolt 13 pushes the breaker key 14 within a predetermined time, the breaker arch 15 is activated to operate the power supply terminal 2, the contact point 3 and the phosphor bronze piece 4 of the breca. Contact point (3) turns off to cut off the load current I. However, when the TRIAC 10 is energized, the indicator 12 (neon lamp or LED) installed through the protection resistor 19 in parallel with the resistance heating element 11 turns on to indicate that the overcurrent operation is started. The unique feature is that the indicator light is connected to T ₂ of the TRIAC (10) and the other side is connected to the power supply terminal (2), so it remains on even after the breca is turned off, indicating that the breca is operated. When the power source 1 is supplied, it is turned on, and thus has an important function of identifying the state of charge of the power supply, such as starting an overcurrent and identifying the state of charge of the power supply.

As described above, the method of detecting overcurrent must be specially manufactured to match the conductor cross-sectional area and length so that heat can be generated during overload operation, and it must be designed by adjusting the cross-sectional area and strength of bimetal and the position of spot welding. Since all the parts of the remarks need to be different, the biggest problem has been the lack of accuracy while having many problems such as difficulty in manufacturing, assembly, management, power consumption, and operation test during finished product inspection. However, in the present invention, the overcurrent is detected in the through-type current transformer 8, so there is no power consumption, the product is uniform, the price is low, the installation cost is small, and there is an advantage that it takes up a small place. The overcurrent set is made of variable resistor (9) and the operation check is made of indicator (12). If the variable resistor and indicator are exposed to the outside of the breca, the overload set can be correctly set not only in the manufacturer but also in the field. It is easy to inspect, and it is easy to inspect, and it is possible to mass-produce a uniform product. In the state of overload, voltage is applied to both ends of the heating element, and the magnitude of this voltage increases and decreases according to the degree of overload, so the more the overload is, the higher the voltage is, the faster it becomes hot and the bimetal operates quickly.

Therefore, it forms an operating characteristic curve similar to the precision induction type overcurrent relay, thereby providing an overcurrent blocking device that is inexpensive and has no power consumption.

2 is a three-phase example of the three-phase breaker switch, so two current transformers are installed in R phase and T phase, and in the center, S phase is installed with an overcurrent sensing device having the same structure as that of FIG. The dogs are installed in each, three overload setting resistors are installed, and negative locking diodes (18) and (18-1) are installed to avoid mutual interference of the current transformers, and the triac (10), the indicator lamp (12) and the resistance heating element ( 11) is an example of installation.

Since three-phase bureca is larger and larger than single phase, it can contribute to industrial development by producing and supplying more economical and precise products by applying the detection device of the present invention.

Claims (2)

In combination of a resistance heating element (heater or static thermistor) and a current transformer and triac electrically coupled to a bar bimetal, the operating time adjusting bolt 13 installed on the bimetal is replaced with a breca breaker key (14). ), And an overcurrent indicator (! 2) (neon lamp or LED) and a variable resistor (9) for overcurrent setting appear on the surface of the no-fuse brake car. In the overcurrent cut-out device according to claim 1, negative locking diodes (18) (18-1) and two variable resistors (9) (9-1) for overcurrent setting are provided on the secondary side of current transformers installed in R phase and T phase. And one indicator light (12) exposed on the surface of the breca.