KR101665296B1 - LED lamp used power separate relay - Google Patents

Abstract

The present invention relates to an LED lamp using a power separation relay. The LED lamp includes a first switch, a second switch, a third switch, a first relay unit, a first resistance, a third relay unit, a first SMPS for converting a current having AC voltage received from the first relay unit into a current having DC voltage, a second SMPS for converting a current having AC voltage received from the first relay unit into a current having DC voltage, and a third SMPS for converting a current having AC voltage received from the third relay unit into a current having DC voltage. Therefore, the present invention can improve the power factor and flicker of the LED lamp.

Description

{LED lamp used power separate relay}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an LED light using a power supply relay, and more particularly, to a method of supplying current to an LED device divided into three groups using a relay.

Generally, most of the lighting apparatuses use fluorescent lamps. Such fluorescent lamps have a drawback in that they experience a lot of fatigue in eyes during long use and increase the ambient temperature due to heat generated during illumination, resulting in high power loss.

In recent years, an LED illumination lamp capable of replacing a fluorescent lamp has been developed and widely used.

It is expected that the LED lighting will be used in the future because it has excellent efficiency of converting power into light, excellent efficiency of power versus lighting, and excellent economical efficiency.

Currently, in the case of an LED light, it is discussed how to divide the LED elements constituting the LED light into a plurality of groups and drive each LED element included in the divided groups.

In other words, when the dimming technique is applied to the LED illumination, the magnitude of the current supplied to the LED device is conventionally adjusted. However, when the intensity of the current supplied to the LED device is used, Flicker is a phenomenon of flickering, which causes flickering of the eyes, which can cause dizziness and headache.

In addition, the conventional LED dimming method is supplied by receiving a communication value signal with one power from the converter, and the power factor is lowered by giving stress to the LED converter, resulting in deterioration of the service life of the product.

Accordingly, there has been proposed a dimming technique of dividing the LED elements constituting the current LED light into a plurality of groups and supplying current to the divided groups.

In addition, the conventional LED lighting system has different communication control depending on the capacity, quantity and position of the LED lighting device, and when integrated control is performed, the price of products and equipment increases according to communication facilities, have.

Korea Patent Publication No. 2014-0123812 Korea Patent Publication No. 2014-0100572

A problem to be solved by the present invention is to provide a method of supplying current to an LED element divided into at least three groups using a relay.

Another problem to be solved by the present invention is to propose a method for improving the power factor and flicker of an LED light.

Another problem to be solved by the present invention is to propose a method of controlling LED devices by groups using relays.

Another problem to be solved by the present invention is to provide a method for preventing a relatively large amount of power from being consumed compared to a set power.

Another object of the present invention is to provide a method of turning on an LED element by receiving power from a power (energy) storage device when power supply from the outside is interrupted.

Another object of the present invention is to provide a method of recognizing an emergency state by lighting only a specific LED element in an emergency.

To this end, the LED illumination lamp using the relay of the present invention includes a first switch for turning on / off the current supplied from the first power source, a second switch for turning on / off the current supplied from the second power source, A first relay unit receiving a current from the first power source by on / off of the first switch, a first relay unit including first to third relays, A second relay for receiving a current from the second power supply by / off, a first resistor for driving the first relay, and a second resistor for driving the second relay, And a third resistor for receiving a current from the third power supply and driving a third relay, and a second relay connected to the first relay, A first SMPS connected to the first relay unit and configured to convert a current having an AC voltage received from the first relay unit into a current having a DC voltage, A second SMPS connected to the second relay unit for converting a current having an AC voltage received from the second relay unit into a current having a DC voltage and a second SMPS connected to the third relay unit and having an AC voltage transmitted from the third relay unit And a third SMPS for converting the current to a current having a DC voltage.

The LED illumination light using the power supply relay according to the present invention supplies current to at least three groups of LED elements using a relay. Therefore, the LED illumination lamp of the present invention has an advantage of improving power factor and flicker.

In addition, since the LED light according to the present invention can be turned on for each LED element that is divided into groups using a relay, the power can be prevented from being wasted unnecessarily.

In addition, when power supply from the outside is interrupted, the present invention can supply an electric power from an electric power (energy) storage device to light an LED element, and illuminate only a specific LED element in an emergency to recognize an emergency state.

1 illustrates an LED illumination lamp according to an embodiment of the present invention.
Figure 2 illustrates an LED lighting system in accordance with an embodiment of the present invention.
3 is a diagram illustrating a configuration of a relay unit according to an embodiment of the present invention.
4 is a diagram illustrating the configuration of an SMPS according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The foregoing and further aspects of the present invention will become more apparent from the following detailed description of preferred embodiments with reference to the accompanying drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

1 illustrates an LED illumination lamp according to an embodiment of the present invention. Hereinafter, a structure of an LED illumination lamp according to an embodiment of the present invention will be described in detail with reference to FIG.

Referring to Fig. 1, the LED illumination lamp is composed of three groups. In other words, the LED illumination lamp is formed in a rectangular shape, and is formed of a plurality of columns, and an LED element is arranged in each column.

In the odd-numbered columns, the LED elements included in the first group and the LED elements included in the second group are arranged alternately, and the LED elements included in the third group are arranged in the even-numbered column.

In this way, the LED illumination lamp proposed in FIG. 1 divides the LED elements constituting the LED illumination lamp into three groups, and supplies the current to each of the LED elements included in the divided group.

Particularly, the LED elements included in each group of the LED illumination lamp of the present invention are formed uniformly throughout the LED illumination lamp. That is, the LED elements included in the first group are formed uniformly in the LED illumination lamp, the LED elements included in the second group are uniformly formed in the LED illumination, and the LED elements included in the third group are uniformly . In order to uniformly form the LED module included in each group in the LED illumination lamp, a part of the wiring for supplying current to the LED device is formed in a zigzag shape. Thus, by uniformly forming the LED element in the LED illumination lamp, the LED illumination lamp has a uniform illuminance in all areas.

Figure 2 illustrates an LED lighting system in accordance with an embodiment of the present invention. Hereinafter, an LED lighting system according to an embodiment of the present invention will be described in detail with reference to FIG.

2, the LED lighting system includes a switch unit, a relay unit, an SMPS, and an LED device. Of course, other configurations than the above-described configuration may be included in the LED lighting system proposed in the present invention.

The switch unit 110 includes a first switch 110-1 to a third switch 110-3 and transmits a current supplied from the outside to the relay unit 120. [ The first switch 110-1 supplies the current to the first relay unit 120-1 and the second switch 110-2 supplies the current to the second relay unit 120-2 And the third switch 110-3 supplies current to the third relay unit 120-3.

The relay unit 120 transmits the power supplied from the switch unit 110 to the SMPS 130. The detailed operation of the relay unit 120 will be described in detail with reference to FIG.

The SMPS 130 converts an alternating current supplied to the outside into a direct current, converts the alternating current into a voltage that meets the conditions of the LED device 140, and supplies the voltage to the LED device 140.

The SMPS 130 includes a battery for driving the SMPS 130. In particular, the SMPS of the present invention is composed of three modules including a first SMPS 130-1 to a third SMPS 130-3, and each SMPS 130 is connected to an LED element 140 included in a corresponding group do. The first SMPS 130-1 is connected to the LED element 140-1 included in the first group and the second SMPS 130-2 is connected to the LED element 140-2 included in the second group do. Also, the third SMPS 130-3 is connected to the LED element 140-3 included in the third group. Accordingly, when power is supplied to the first SMPS 130-1, the LED elements 140-1 included in the first group are turned on, and when power is supplied to the second SMPS 130-2, The LED element 140-2 included in the group is turned on. When power is supplied to the third SMPS 130-3, the LED elements 140-3 included in the third group are turned on.

3 is a diagram illustrating a configuration of a relay unit according to an embodiment of the present invention. Hereinafter, the configuration of the relay unit according to one embodiment of the present invention will be described in detail with reference to FIG.

3, the relay unit includes a first relay unit to a third relay unit. Of course, when the number of SMPS increases, the number of relays included in the relay part also increases.

The first relay unit 120-1 is connected to the first switch and the second relay unit 120-2 is connected to the second switch. And the third relay unit 120-3 is connected to the third switch.

The first relay unit 120-1 includes a first relay 120a to a third relay 120a. The first relay unit 120-1 receives current from the first switch, and the wiring supplied with the current is branched in a parallel form. The first wiring, which is one of the branched wirings, is connected to the first SMPS, Is connected to the second SMPS.

The third relay 120c is formed on the wiring before being branched in parallel, the first relay 120a is formed on the first wiring, and the second relay 120b is formed on the second wiring.

The second relay unit 120-2 receives the current from the second switch and includes a first converter 120d and a first resistor 120f and a second resistor 120g. The first resistor 120e and the second resistor 120f are connected in parallel and the first converter 120d and the resistor composed of the first resistor 120f and the second resistor 120g are connected in series.

The wiring connected to the second switch branches in parallel, and the branched third wiring is connected to the second relay 120b. In addition, the branched fourth wiring is connected to the first converter 120d, the first resistor 120f and the second resistor 120g.

The third relay unit 120-3 receives the current from the third switch, and the second converter 120e and the third resistor 120h are formed. The third resistor 120h and the second converter 120e are connected in series.

The wiring connected to the third switch branches in parallel, the branched fifth wiring is connected to the third SMPS, and the branched sixth wiring is connected to the second converter 120e and the third resistor 120h.

Hereinafter, a process of supplying current to the LED device using each switch will be described in detail.

When power is supplied to the first relay unit using the first switch, the first relay to the third relay are connected, and current is supplied to the first SMPS and the second SMPS. When current is supplied to the first SMPS and the second SMPS, the LED elements included in the first group connected to the first SMPS are turned on and the LED elements included in the second group connected to the second SMPS are turned on.

When power is supplied to the second relay unit using the second switch, the first relay is short-circuited by the current flowing in the first resistor, and the current supply to the first SMPS is interrupted. When current supply to the first SMPS is interrupted, the LED elements included in the first group are turned off.

When power is supplied to the second relay unit using the second switch, the second relay connects the third wiring to the second SMPS by the current flowing through the second resistor. That is, the second SMPS receives a current from a power source connected to the first switch, but a power source connected to the second switch. Accordingly, the LED elements included in the second group connected to the second SMPS are turned on.

As described above, when the current is supplied to the power source connected to the second switch, the current supply from the power source connected to the first switch is automatically cut off. Also, when the current supply from the power supply connected to the second switch is interrupted, the current is automatically supplied from the power supply connected to the first switch.

When power is supplied to the third relay unit using the third switch, the third relay is short-circuited by the current flowing in the third resistor, and the current supply to the first SMPS and the second SMPS is cut off. When the current supply to the first SMPS and the second SMPS is interrupted, the LED elements included in the first group and the LED elements included in the second group are turned off. On the other hand, the LED elements included in the third group are turned on because the third relay unit supplies current to the third SMPS.

As described above, when the current is supplied to the power source connected to the third switch, the current supply from the power source connected to the first switch is automatically interrupted. Also, when the current supply from the power supply connected to the third switch is interrupted, the current is automatically supplied from the power supply connected to the first switch.

In other words, the present invention controls the operation of the second switch or the third switch in a state in which the current is supplied to the first relay unit through the power source connected to the first switch, The LED elements included in the LEDs are turned on or off. Further, the LED elements included in each group are supplied with current from one power source at a specific time. That is, the LED element included in the second group is supplied with current from any one of the power source connected to the first switch or the power source connected to the second switch at a specific time.

The power source connected to the third switch may be supplied in a manner different from the power source connected to the first switch or the power source connected to the second switch. When current is cut off from a power supply connected to the first switch or a power supply connected to the second switch due to fire or the like, current is supplied from a power supply connected to the third switch, The device is turned on. That is, the LED elements included in the third group can be controlled to be turned on in the event of an emergency such as a fire.

Although not explicitly shown in Fig. 3, a fuse can be connected to the front end of the first relay and the second relay. The fuse blocks the overload from being supplied to the first relay or the second relay. Further, a fuse may be connected to a point connecting the second relay part and the second switch, or a point connecting the third relay part and the third switch.

Hereinafter, an application method for an LED illumination using a relay according to the present invention will be described.

The LED illumination light using the relay according to the present invention can light the LED element through the first power source. As described above, when the LED elements are lit through the first power source, the LED elements included in the first group and the LED elements included in the second group are turned on. When the electric power consumed by the other electric appliances exceeds the set electric power in this state, the present invention turns on the second switch and lights the LED illumination lamp by using the second electric power. The LED elements included in the first LED group are turned off and only the LED elements included in the second LED group are turned on as described above in which the LED light is turned on through the second power source. In this way, when only the LED elements included in the second LED group are lit, the power consumed in the LED light is reduced, and the power consumed thereby can be reduced.

As described above, the present invention controls the power consumed in the LED illumination lamp by controlling the switch connected to the relay unit, so that the consumed power is less than the set power.

In addition, according to the present invention, power may not be supplied from the first power source and the second power source as described above. That is, the wiring for supplying the first power source and the second power source may be short-circuited, or the current supply may be interrupted. In this case, an LED element included in the third LED group can be turned on by using a third power source supplied with current from the emergency battery. As described above, according to the present invention, when the power is supplied in a different form, if the current is not supplied to any one of the power sources, the current is supplied to the other types of power sources to light the LED element.

In other words, the third power source receives a current from a battery disposed in the building so as to be able to receive power even in an emergency such as a fire, so that the LED device included in the third LED group It lights up. Of course, when the LED device included in the third LED group is turned on, people in the building can recognize that it is in an emergency.

 4 is a diagram illustrating the configuration of an SMPS according to an embodiment of the present invention. Hereinafter, the configuration of the SMPS according to an embodiment of the present invention will be described in detail with reference to FIG.

Referring to FIG. 4, the SMPS is composed of a noise filter, an input rectifying smoothing circuit, a DC-DC converter, an output rectifying smoothing circuit, a feedback control circuit, and a protection circuit. Of course, other configurations than the above-described configuration may be included in the SMPS proposed in the present invention.

The noise filter 130a removes the noise portion from the input current, and the noise-canceled current is transmitted to the input rectifying smoothing circuit 130b.

The input rectifying smoothing circuit 130b converts the noise-eliminated current (having an AC voltage) to a DC voltage.

The DC-DC converter 130c converts the DC voltage converted by the input rectifying smoothing circuit 130b to have a set voltage. In general, the DC-DC converter 130c is composed of a main switch, a reflux diode, and an LC filter, which is a second-order low-pass filter.

The output rectifying smoothing circuit 130d smoothes the DC voltage converted by the DC-DC converter once again, and outputs the smoothed DC voltage.

The feedback control circuit 130e stabilizes the voltage output from the output rectifying smoothing circuit. In general, the feedback control circuit 130e includes an error amplifier for amplifying an error of an output voltage, a comparator for generating a drive pulse by comparing the amplified error with a triangular wave, and a drive circuit for driving the main switch of the DC-DC converter have.

The protection circuit 130f is connected in parallel with the feedback control circuit 130e and functions to protect circuits constituting the SMPS.

Of course, the SMPS can be configured in a manner other than the above-described configuration.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the scope of the present invention .

110: switch unit 120: relay unit
130: SMPS 140: LED element

Claims (6)

A first switch for turning on / off a current supplied from the first power source;
A second switch for turning on / off the current supplied from the second power supply;
A third switch for turning on / off the current supplied from the third power supply;
A first relay unit receiving a current from the first power source by on / off of the first switch, the first relay unit including first to third relays;
A second relay for receiving a current from the second power supply by on / off of the second switch, a first resistor for driving the first relay, and a second resistor for driving the second relay;
A third relay unit including a third resistor receiving a current from the third power supply by on / off of the third switch and driving a third relay;
A first SMPS connected to the first relay unit and converting a current having an AC voltage received from the first relay unit into a current having a DC voltage;
And a second relay unit connected to the first relay unit and configured to convert a current having an AC voltage received from the first relay unit to a current having a DC voltage or an AC voltage transmitted from the second relay unit, A second SMPS for converting the current having the DC voltage into the current having the DC voltage and
And a third SMPS connected to the third relay unit for converting a current having an AC voltage received from the third relay unit into a current having a DC voltage,
The first relay unit includes:
A third relay connected to the first switch;
A first wiring including one side connected to the third relay and the other side including a first relay connected to the first SMPS;
A second wiring including a second relay connected to the third SMPS and the other end connected to the third relay;
Wherein the first wiring and the second wiring are connected in parallel.
The display device according to claim 1, further comprising: an LED element included in the first group; an LED element included in the second group; and an LED element included in the third group,
The first SMPS is connected to the LED devices included in the first group, the second SMPS is connected to the LED devices included in the second group, and the third SMPS is connected to the LED devices included in the third group, And an LED illumination light using a relay.
delete The apparatus according to claim 1, wherein the second relay unit comprises:
A third wiring connected to the second switch on one side and connected to the second relay on the other side;
One side of which is connected to the second switch and the other side of which is connected to a first converter, a first resistor and a second resistor,
When a current is supplied to the second relay through the second switch,
The first relay is driven by the first resistor to cut off current supply to the first SMPS,
And the second relay drives the second relay to cut off current supply by the second wiring, and supplies the current to the second SMPS by the third wiring.
5. The relay apparatus according to claim 4,
A fifth wiring connected to the third switch, one end connected to the third switch, and the other end connected to the third SMPS;
One end of the second switch is connected to the third switch, and the other end of the sixth switch is connected to the second converter and the third resistor,
When a current is supplied to the third relay unit through the third switch,
And the third relay drives the third relay to cut off the current supply to the first wiring and the second wiring and supplies the current to the third SMPS by the fifth wiring. Lighting.
An LED element including an LED element included in a first group, and an LED element included in a second group;
A first switch for turning on / off a current supplied from the first power source;
A second switch for turning on / off the current supplied from the second power supply;
A first relay part receiving current from the first power source by on / off of the first switch and including at least one relay;
A second relay unit receiving a current from the second power source by on / off of the second switch and including a resistor for driving the relay included in the first relay unit;
A first SMPS connected to the first relay unit for converting a current having an AC voltage received from the first relay unit into a current having a DC voltage and supplying current to an LED element included in the first group;
And a second relay unit connected to the first relay unit and configured to convert a current having an AC voltage received from the first relay unit to a current having a DC voltage or an AC voltage transmitted from the second relay unit, And a second SMPS for converting a current having a DC voltage into a current having a DC voltage and supplying an electric current to an LED element included in the second group,
The first relay unit includes:
A third relay connected to the first switch;
A first wiring including one side connected to the third relay and the other side including a first relay connected to the first SMPS;
A second wiring including a second relay connected to the third SMPS and the other end connected to the third relay;
Wherein the first wiring and the second wiring are connected in parallel.

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