KR101392745B1 - Contactless type auxiliary power unit - Google Patents

Abstract

The present invention provides a contactless type emergency power transfer device capable of blocking the supply of commercial power to an emergency lamp, supplying the emergency power through a plurality of current paths, preventing a strain effect of a load current flowing through the current paths, and minimizing the temperature difference of a semiconductor switching element placed on the current paths. The contactless type emergency power transfer device according to the invention includes: a regular power detecting part outputting a detection signal by detecting whether regular power is applied; a control part outputting a control signal for emergency power crackdown and a control signal for regular power crackdown in response to the detection signal; a regular power crackdown part switched by being controlled by the control signal for regular power crackdown; an emergency power crackdown part switched by being controlled by the control signal for the emergency power crackdown and forming different current paths for a plurality of emergency loads; and a switching balancing part connected to the emergency power crackdown part.

Description

{CONTACTLESS TYPE AUXILIARY POWER UNIT}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an emergency power switching apparatus, and more particularly, to an emergency power switching apparatus operating in a contactless manner.

Generally, large buildings and factories are supplied with commercial power supply at normal times, and emergency power supplies such as power generation facilities installed inside in case of emergency are used. In other words, an emergency power switching device is provided to connect a commercial power supply to a load side of a large building or a factory to supply electric power, and to supply electric power by connecting the emergency power supply to the load when an abnormality occurs in the commercial power supply.

On the other hand, loads that are supplied with emergency power because of the limit of power generation are limited to essential load such as emergency lighting of living space, boiler facility, electric door. However, for the above-mentioned essential loads, a commercial power supply or an emergency power supply system supplies power without distinguishing between an emergency lighting circuit and a boiler facility circuit. In other words, the emergency light does not distinguish between normal and emergency, and always maintains the lighting state.

The emergency power switching apparatus according to the related art shown in FIG. 1 comprises: a first satellite (100) for connecting commercial power to a load; A second solar cell (200) for connecting the photovoltaic power supply to a load; A switch 1100 installed between the photovoltaic power supply and the commercial power supply to open and close the power supply at the same time; A video current transformer 900 for detecting a ground current or a leakage current generated in the load and transmitting a detection signal; A current transformer 1000 for detecting an overcurrent generated in a load and transmitting a detection signal; A commercial voltage detecting unit 300 for detecting a voltage and a phase by receiving commercial power; An inverter 400 for adjusting a voltage state of the photovoltaic power supply; And a photovoltaic generation voltage detector 500 for receiving the photovoltaic power supply through the inverter and detecting the voltage and phase.

In other words, even in accordance with the prior art shown in Fig. 1, since the emergency lighting load is not distinguished from the other load facilities, the emergency lighting lamp keeps the lighting state at all times without distinguishing between normal and emergency.

However, since there is no need for the emergency light to be turned on during the normal lighting of the surrounding lights, the power is continuously consumed.

Patent Document 1: JP-A-10-0955806 An automatic power switching device for selectively connecting a commercial power source and a solar power generation power source as a load while detecting a power state of a load

The present invention provides a non-contact type emergency power switching apparatus capable of cutting off the supply of commercial power to an emergency lighting lamp.

Further, the present invention provides a non-contact type emergency power switching apparatus for supplying an emergency power via a plurality of current paths in an emergency.

Further, the present invention provides a non-contact type emergency power switching apparatus capable of preventing a load current from flowing along a plurality of current paths formed in an emergency.

Further, the present invention provides a non-contact type emergency power switching device capable of minimizing a temperature difference of a semiconductor switching device disposed on a plurality of current paths.

The non-contact type emergency power switching apparatus according to the present invention includes: a constant power detection unit for detecting whether or not a constant power source is applied and outputting a detection signal; A control unit for outputting a control signal for intermittent power intermittence and a control signal for interrupting an emergency power supply in response to the detection signal; An intermittent power intermittent part controlled by the control signal for intermittent power intermittence switching; An emergency power interrupter configured to control and switch to the control signal for interrupting the emergency power supply, and to form a different current path for a plurality of emergency loads; And a switching equilibrium unit connected in series with the emergency power intermittent unit.

Preferably, the emergency light among the plurality of emergency loads is not supplied with power from the constant power source.

Preferably, the emergency power source intermittently includes: a first semiconductor switching element connected to the emergency light; And a second semiconductor switching element connected to at least any one of the plurality of emergency loads other than the emergency light.

Preferably, the switching equilibrium portion is a resistance connected in series with the first and second semiconductor switching elements, respectively.

Preferably, the first and second semiconductor switching elements are bi-directional switching elements or antiparallel coupled unidirectional switching elements.

Preferably, the resistance value of the resistance can be determined within a range of the sum of the thermal resistance value and the transient thermal impedance of the first and second semiconductor switching elements.

According to the present invention, it is possible to save power unnecessarily consumed at normal times by supplying only the emergency power source without supplying commercial power to the emergency lighting lamp. In addition, when emergency power is supplied through a plurality of current paths in an emergency, it is possible to distinguish current paths for emergency lighting lamps from current paths for other essential loads. In addition, by minimizing the temperature difference of the semiconductor switching elements disposed on the plurality of current paths formed in the emergency, the load current flowing along the plurality of current paths can be prevented from leaning.

1 is an overall block diagram of an emergency power switching apparatus according to the prior art, and Fig.
2 is an overall circuit diagram of an emergency power switching apparatus according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined. Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

FIG. 2 is an overall circuit diagram of an emergency power switching apparatus according to an embodiment of the present invention. The emergency power switching unit 210 includes a constant power detection unit 210, a controller 220, an emergency power interrupter 230, an emergency power interrupter 240, (250), and a DC power generator (260).

The constant power detection unit 210 includes a photodiode PD for emitting light when the power is constantly applied and a phototransistor PT for turning on light emitted from the photodiode PD. Here, reference numeral D1 denotes light when the power is constantly applied as an LED.

The control unit 220 receives a control signal for turning on the constant power intermittence unit 230 (Q1, Q2) by receiving an "L" level signal in response to the turn-on of the phototransistor PT and a control signal for turning on the emergency power interrupter units 240, , And Q5, respectively. When the phototransistor PT is turned off, a control signal for turning off the constant power intermittent portion 230 and a control signal for turning on the emergency power intermittent portion 240 are received.

The semiconductor switching elements in the emergency power interrupter 240 are advantageous in that no mechanical noise is generated, no electrical noise is generated, and the lifetime is semi-permanent compared with the relays. However, the switching elements Q4 ) And the switching element (Q5) for the current path for the boiler are connected in parallel, so that the load current leaks out.

More specifically, even if a turn-on signal is applied to the switching element Q4 and the switching element Q5 at the same time, if any one of the two switching elements is turned on first, a smaller load current flows into the switching element that is turned on later. So that more heat is generated in the switching elements.

In particular, when the inductive load is increased, the triacs Q4 and Q5, which are connected in parallel, are damaged. This is caused by the current (dv / dt), the phase of the load current is lower than the phase of the applied voltage, the load current flowing through the semiconductor switching element is zero, while a high voltage is applied across the triac do.

That is, at the point when the triac is to be turned off, the instantaneous line voltage across the triac appears at a rate that limits the stray capacitance of the circuit and the capacity of the triac.

When the inductive load is intensified in this way, the current (dv / dt) time and the magnitude of the current appear at both ends of the triacs (Q4 and Q5). This means that the turn off points of the triac are different, which causes the temperature difference of the individual triacs. The temperature rise of the triac is caused by Turn-On Switching, Turn-Off or current (dv / dt) energization, especially turn-off or current (dv / dt) And the turn-off function becomes uncertain.

Therefore, it is necessary to control the turn-on time and temperature of the semiconductor switching element (triac). To this end, a resistor (250, R1, R2, R3) corresponding to the thermal resistance (thermal resistance) and the transient thermal impedance of the junction is connected in series to the triac, Can be minimized.

As a result, the temperature rise of the triac can be suppressed by keeping the turn-on time difference of the individual triac through the switching balancer 250 within 1 Hz. The values of the resistances R1, R2 and R3 of each phase in the switching balancing unit 250 are preferably designed according to the load type within the range of the sum of the thermal resistance value of the triac and the transient thermal impedance occurring in the transient state.

The DC power generator 260 includes a rectifier for receiving an emergency power source and converting the DC power into a DC voltage, and a DC voltage converter for converting a DC voltage of a predetermined level outputted from the rectifier to a power voltage to be used by the controller.

210:
220:
230: Constant power intermittent part
240: Emergency power supply interrupter
250: switching equilibrium part
260: DC power generator

Claims (6)

A normal power detection unit for detecting whether or not the normal power source is applied and outputting a detection signal;
A control unit for outputting a control signal for intermittent power intermittence and a control signal for interrupting an emergency power supply in response to the detection signal;
An intermittent power intermittent part controlled by the control signal for intermittent power intermittence switching;
An emergency power interrupter configured to control and switch to the control signal for interrupting the emergency power supply, and to form a different current path for a plurality of emergency loads; And
And a resistor in series with said emergency power interrupter for switching balancing,
Wherein the emergency power interrupter comprises:
A first semiconductor switching element connected to an emergency light among the plurality of emergency loads; And
And a second semiconductor switching element connected to at least one of the plurality of emergency loads other than the emergency light,
The emergency power switching device comprising:
The method according to claim 1,
Wherein the emergency light among the plurality of emergency loads does not receive power from the constant power source.
delete delete 3. The method of claim 2,
Wherein the first and second semiconductor switching elements are bidirectional switching elements or anti-parallel coupled unidirectional switching elements.
3. The method of claim 2,
Wherein the resistance value of the resistor is determined within a range of a sum of a thermal resistance value and an excessive thermal impedance of the first and second semiconductor switching elements.

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