KR20160079496A - Illumination lamp system and power distributer having ac/dc convertor module - Google Patents

Abstract

The present invention relates to an illumination lamp system having an AC/DC converter module. The illumination lamp system comprises: a plurality of illumination lamps; the AC/DC converter module which converts external alternating current power into direct current power and includes N AC/DC converters; a distributor which is isolated from the illumination lamps and converts the direct current power from the AC/DC converter module to supply illumination power to the illumination lamps; and a controller which controls at least one of the AC/DC converters to operate based on consumption power of the illumination lamps and controls an operation of each of the illumination lamps by controlling the distributor.

Description

TECHNICAL FIELD [0001] The present invention relates to an illumination lamp system and an AC / DC converter module having an AC / DC converter module,

The present invention relates to an illumination lamp system having an AC / DC converter module and a power distributor.

In general, there are incandescent lamps or fluorescent lamps widely used in homes, offices, and the like. Such incandescent lamps or fluorescent lamps have a high power consumption, wasting resources and adversely affecting environmental protection, There is a problem that the electrical resistance of the filament is high and the environmental temperature is increased and the service life of the lamp is short.

Accordingly, in recent years, a lighting lamp using a light emitting diode capable of maximizing a lighting effect with a variety of illumination light and high visibility has been developed and widely used because it has a low power consumption and can be miniaturized, and is economical.

In this case, the light emitting diode (LED) has a structure in which an N-type semiconductor crystal in which a plurality of carriers are electrons and a P-type semiconductor crystal in which a plurality of carriers are holes are bonded to each other, Means a semiconductor device. The light emitting diode refers to a semiconductor light emitting device using spontaneous emission light generated when electrons injected into a PN junction are recombined with holes.

Since the LED has high photoelectric conversion efficiency (lumen / watt), it consumes less power than incandescent bulbs and fluorescent lamps, and does not need preheating time, so it is lighted and turned off fast.

In addition, since the LED has no gas or filament, it is resistant to impact, safe, and has a low power consumption by adopting a stable DC lighting method. In addition, the LED can perform pulse operation and reduce the fatigue of the optic nerve. In addition, the lifetime of the LED is semi-permanent, and it can emit light effects of various colors and can be downsized.

However, there is a problem that the brightness and service life of the LED deteriorate due to heat generated when the LED chip is driven.

In most conventional light emitting diode type illumination lamps, typically a bulb type illumination lamp, a converter, which is a power supply module, is installed in the illumination lamp itself. These converters themselves cause heat generation, are not only vulnerable to heat, but also have a short life span. LED chips, which make up a light-emitting diode-type lighting lamp, have a lifetime of about 60,000 hours, while converters have a lifespan of only 15,000 hours.

Accordingly, despite the fact that the lifetime of the LED chip is still long, if the converter reaches its end of life, the entirety of the illumination lamp or the illumination bulb must be replaced. In fact, a power supply module ('a component included in a converter') having an electrolytic capacitor having a short degradation characteristic, that is, a power supply module, is often caused to fail earlier than the LED chip .

In addition, since such a power supply module is integrated or built-in in an illumination lamp or an illumination bulb, it may be another factor for raising the heat inside the illumination lamp during operation. Also, the power supply unit occupies a certain space in terms of mechanism, which has a disadvantage in that design flexibility is lowered when designing a product. In addition, the power supply module (SMPS) itself occupies more than 20% of the weight of the lighting lamp, thereby increasing the weight of the entire lighting lamp.

In order to solve this problem, in order to remove the power supply module from the illumination lamp or the illumination bulb and simultaneously control the plurality of different LED illumination lamps, it is necessary to use a conventional (integrated or built-in) A power supply technology of a concept different from that of the power supply module of the power supply is required.

Another typical light-emitting diode type lighting lamp is a T-8 LED lighting lamp, which is a rod-type fluorescent lamp type. In the case of T-8, the power supply unit is built-in or external, but when replacing general fluorescent lamp with LED etc. using external type T-8, each power supply module corresponding to one-to-one correspondence with LED etc. is installed separately shall. At this time, when the fixture of the existing fluorescent lamp is to be used as it is, the electric wire connected to the ballast installed in the lamp should be cut off and the power supply module should be installed separately. That is, the replacement cost may be separately generated. Further, when the LED or the like is installed on the ceiling, the workability is deteriorated.

In particular, when the power supply module needs to be replaced after the installation, it is not possible to substitute other specification besides the power supply specified for each LED lighting lamp because the electric capacity (voltage and current) required for each LED illumination lamp is different, The flexibility of the apparatus is deteriorated.

Therefore, in order to facilitate the system management and to separately supply the electric capacity (voltage and current) required by any LED lighting lamp as required, a power distribution device having a different concept from the conventional power supply device is required.

In addition, the conventional power distribution system has a problem in that unnecessary power is consumed by performing AC / DC conversion at a time regardless of the power consumption of the lamp. There is a need for a new concept device that can prevent unnecessary power consumption.

SUMMARY OF THE INVENTION The present invention has been conceived to solve the above-mentioned problems, and it is an object of the present invention to provide an illumination lamp capable of preventing unnecessary power consumption by operating at least one AC / DC converter among the AC / System.

Further, it is an object of the present invention to provide an illumination lamp system which improves the stability and life of an LED lighting lamp, facilitates replacement of a general lamp with an LED or the like, and facilitates replacement of a power supply module, .

In addition, in the case of an incandescent bulb type, it is possible to provide a lighting lamp system capable of expanding the flexibility of the luminaire design by eliminating the space required to accommodate the power supply module in the mechanical mechanism of the LED lighting lamp will be.

Further, by setting the upper limit value of the current applied to the illumination lamp by the mechanical control unit, it is possible to prevent the upper limit value of the current from being changed due to an external hacking or a malfunction caused by the program error, The present invention provides an illumination lamp system which is improved in stability and flexibility.

Other objects and advantages of the present invention will become apparent from the following description, and it will be understood by those skilled in the art that the present invention is not limited thereto. It will also be readily apparent that the objects and advantages of the invention may be realized and attained by means of the instrumentalities and combinations particularly pointed out in the appended claims.

In order to solve the above problems, an illumination lamp system having an AC / DC converter module, which is one embodiment of the present invention, includes a plurality of illumination lamps, an external AC power source to DC power source, A distributor installed separately from the lamp for illumination and for converting a DC power source from the AC / DC converter module to supply illumination power to the plurality of lamps; And a controller for controlling at least one of the AC / DC converters to operate based on the power consumption, and controlling the operation of the illumination lamp by controlling the distributor.

The distributor may further include a watt-hour meter capable of measuring the power consumption of the plurality of illumination lamps, and the controller may control at least one of the AC / DC converters to operate based on the power consumption measured in the watt-hour meter.

An illumination lamp system with an AC / DC converter module may have different rated powers for the N AC / DC converters.

The sum of the rated outputs of the AC / DC converter operated by the controller may be greater than the power consumption.

The controller extracts a selected combination of the AC / DC converters corresponding to the sum of the rated outputs of the AC / DC converters to be controlled to be operated and the AC / DC converter for the selected combination of the extracted AC / The AC / DC converter with the best AC / DC converter efficiency can be controlled to operate with the best combination of converter efficiency.

An illumination lamp system having an AC / DC converter module further includes a mechanical adjustment unit for setting an upper limit value of a current applied to the illumination lamp, and the controller applies a current control signal to the illumination lamp within the set upper limit value range, So that the operation of the illumination lamp can be controlled by controlling the distributor.

The mechanical regulator includes N switches, and the upper limit of the current limited by each of the N switches may be different from each other.

The distributor is provided with a rack having a plurality of compartment spaces and a plurality of compartments arranged in the compartment space, respectively, for receiving DC power from the AC / DC converter module in each of the lamps for illumination, A buck converter, and an output port for connecting the buck converter and the illumination lamp, respectively.

The output port having a first sub output port for outputting a first sub output power; And a second sub output port for outputting a second sub output power when said first sub output port and said second sub output port are connected together to said lamp for illumination, The sum power of the sub output powers can be output.

The buck converter includes a voltage regulator for reducing the DC power from the AC / DC converter module, a current regulator for rectifying the DC power, and a dimming circuit for dimming the constant current output from the current regulator, . ≪ / RTI >

An illumination lamp system having an AC / DC converter module further includes a mechanical switch installed around the illumination lamp and generating a signal for turning on / off the illumination power supplied to the illumination lamp, The buck converter can be controlled so that the illumination power source is supplied to the illumination lamp according to an on / off signal generated by the switch.

The distributor further includes a battery charged by a DC power source from the AC / DC converter module. When the supply of the external AC power is interrupted, the controller controls the distributor to supply the illumination power using the battery .

The distributor may further include an input unit for setting the illumination power source, and when the distance between the distributor and the illumination lamp is input through the input unit, the controller may control the illumination power source in consideration of a voltage drop according to the distance .

A buck converter may be removably installed in the rack.

The buck converter may include a buck converter for LED lighting and a buck converter for general backlight.

The lamp is a ceiling mounted lamp, and the distributor can be installed on the wall or ceiling of the room.

A power distributor having an AC / DC converter module according to an exemplary embodiment of the present invention includes a distributor installed separately from an illumination lamp and adapted to convert DC power from an AC / DC converter module to supply illumination power to the plurality of illumination lamps And a controller for controlling at least one of the AC / DC converter included in the AC / DC converter module to operate based on the power consumption of the plurality of illumination lamps and controlling the operation of the illumination lamp by controlling the distributor can do.

The distributor may further include a watt-hour meter capable of measuring the power consumption of the plurality of illumination lamps, and the controller may control at least one of the AC / DC converters to operate based on the power consumption measured in the watt-hour meter.

The sum of the rated outputs of the AC / DC converter operated by the controller may be greater than the power consumption.

The controller extracts a selected combination of the AC / DC converters corresponding to the sum of the rated outputs of the AC / DC converters to be controlled to be operated and the AC / DC converter for the selected combination of the extracted AC / The AC / DC converter with the best AC / DC converter efficiency can be controlled to operate with the best combination of converter efficiency.

According to an embodiment of the present invention having the above-described configuration, unnecessary power consumption can be prevented by operating at least one AC / DC converter among the AC / DC converter modules based on the power consumption of the LED illumination lamp.

In addition, by separating the LED lighting lamp and the power supply module, it is possible to prevent the power supply module from being damaged by heat, and to eliminate the influence of the heat generated from the power supply module, thereby increasing the lifetime of the LED lighting lamp. Since the power supply module is not attached to the illumination lamp, the installation can be facilitated according to the weight reduction of the LED illumination lamp, so that the workability can be improved and at the same time the illumination lamp can be lightened.

Further, according to the embodiment of the present invention, since the distributor includes a plurality of exchangeable buck converters, individual correspondence becomes convenient when the required capacity for each illumination lamp is different.

In addition, by setting the upper limit value of the current to be applied to the illumination lamp by the mechanical control unit, it is possible to prevent malfunction that the upper limit value of the current is arbitrarily changed due to external hacking or program error, Can be accurately maintained, so that the stability of the power distributor can be secured.

In addition, since it enables to operate the system by distinguishing the user environment, manager environment and installer environment, it is convenient to reconfigure the system when the arbitrary replacement of the individual illumination such as the type and quantity of the LED lighting lamp is required, Can be prevented. That is, the manager inputs the control value for the individual illumination to the distributor in accordance with the user's demand environment to provide the user environment, and the user can use the normally used mechanical switch installed at the necessary position without going to the place where the distributor is installed It is possible to easily control the illumination power supplied to the plurality of lamps.

Unlike conventional LED lighting devices using an AC power system in the installer environment, the illumination lamp system and the power distributor of the present invention are designed such that the eletric path from the AC / DC converter module is not AC (alternating current) By using a bolt, typically a DC (DC) power source of 50 volts or less, the risk of electric shock to the installer and the user during installation or replacement of the LED lighting lamp can be reduced.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic view for explaining an illumination lamp system according to an embodiment of the present invention; Fig.
2 is a block diagram illustrating an electronic configuration of an illumination lamp system according to an embodiment of the present invention;
FIG. 3 is a table showing an AC / DC converter efficiency according to a selected combination of AC / DC converters according to an embodiment of the present invention; FIG.
4 is a block diagram for explaining an electronic configuration of a distributor in an illumination lamp system according to an embodiment of the present invention;
5 is a view for explaining an appearance of a distributor in an illumination lamp system according to an embodiment of the present invention.
FIG. 6 is a rear perspective view of a distributor for explaining an output port (power port) of a distributor among an illumination lamp system according to an embodiment of the present invention; FIG.
7 is a view for explaining an illumination lamp system which is an embodiment of the present invention.

Hereinafter, a power distributor for an illumination lamp and an illumination lamp system according to the present invention will be described in detail with reference to the drawings.

In this specification, it is understood that the illumination lamp system according to the present invention is applied to an indoor home, but it is not limited thereto, and it is understood that it can be applied to an outdoor illumination system such as a streetlight security system as well as an interior such as a factory or an office something to do.

1 is a schematic view for explaining an illumination lamp system according to an embodiment of the present invention. As shown in FIG. 1, an illumination lamp system having an AC / DC converter module, which is an embodiment of the present invention, can be applied to an indoor environment. In this case, the illumination lamp system includes an AC / DC converter module 100 that receives an external 110 V or 220 V commercial power and converts the same into a DC power source, and a DC power source that receives the DC power converted by the AC / DC converter module 100 A distributor 200 for supplying a rectified current to the illumination lamp 300 and a lamp 300 emitted by the power supplied from the distributor 200. [

At this time, the lamp 300 may be a ceiling-mounted lamp as a light emitting diode lamp. That is, the lamp 300 may be a ceiling-mounted LED lamp installed in each room or living room. A distributor 200 for supplying power to the LED lamps may include a plurality of buck converters 250 for supplying power to the respective lamps.

The plurality of lamps 300 may be the same or different.

In the present embodiment, the lamp 300 is limited to a ceiling-mounted type, but it is natural that the lamp can be installed at a different place such as a wall.

According to an embodiment of the present invention, since it is not necessary to attach a separate power supply module to the ceiling-mounted LED lamp 300, it is possible to facilitate construction when replacing a conventional fluorescent lamp, It is possible to improve the durability of the distributor 200 and the illumination system itself because the distributor 200 is isolated from the LED lamp having a lot of heat and is not likely to deteriorate.

Hereinafter, a specific configuration of the illumination lamp system having the above-described configuration will be described in more detail with reference to FIG.

2 is a block diagram illustrating an electronic configuration of an illumination lamp system according to an embodiment of the present invention.

In this embodiment, an example in which the AC / DC converter module 100 and the buck converter 250 are controlled by the controller 400 will be described. In this case, the controller 400 may be formed inside or outside the distributor 200.

2, the illumination lamp system according to the present invention includes an AC / DC converter module 100, a distributor 200, a lamp 300, a controller 400, a mechanical controller 410, (420) and a central control system (500).

The AC / DC converter module 100 is a component that converts AC commercial power to DC power. Since the LED lamp is usually driven by a DC power source, it is necessary to first change the AC power source to a DC power source. The output DC power of the AC / DC converter module 100 is supplied to the distributor 200.

The AC / DC converter module 100 includes a first AC / DC converter 110, a second AC / DC converter 120, a third AC / DC converter 130, and an Nth AC / DC converter 140 . The rated power of the first AC / DC converter 110, the second AC / DC converter 120, the third AC / DC converter 130, and the Nth AC / DC converter 140 may be different from each other have. For example, the first AC / DC converter 110 has a rated output of AW, the second AC / DC converter 120 has a rated output of BW, and the third AC / DC converter 130 has a rated output of CW With a rated output, the Nth AC / DC converter 140 may have a rated output of NW.

The distributor 200 is a component for supplying an appropriate constant current power to the plurality of LED lamps 300 installed in each room, as shown in FIG.

The distributor 200 may include a buck converter 250, a battery 207, and a watt-hour meter 208 that are the same or less than the LED lamp 300. The buck converter 250 is a step-down converter circuit, which is used when the output voltage is lower than the input voltage, and functions to supply a lighting power source to the corresponding lamp 300.

A plurality of distributors 200 may exist, and the distributors 200 may be connected to each other in series or in parallel. A plurality of lamps 300 may be connected to each of the distributors 200. As such, the distributor 200 is expandable.

The buck converter 250 includes a voltage regulator for reducing the direct current power from the AC / DC converter module 100, a current regulator for rectifying the direct current power source, a constant current circuit for dimming the constant current output from the current regulator, 300 for controlling the brightness of the lamp, thereby supplying the illumination power to the lamp.

The battery 207 is a component for allowing the lamp 300 to be turned on in an emergency state for a predetermined time when the supply of the AC commercial power is limited. That is, when it is determined that the DC power supply is not normally supplied from the AC / DC converter module 100, the controller 400 supplies the power generated from the battery 207 to the buck converter 250, Is turned on. At this time, the power source is supplied only to the minimum current set so that the light emission of the lamp 300 is performed for the longest time, so that the lamp 300 can be lighted to the minimum. The configuration of the distributor 200 will be described in more detail with reference to FIG.

The watt hour meter 208 can measure the power consumed in the lamp 300 in real time. The watt-hour meter 208 can transmit the measured power consumption to the controller 400 in real time.

The lamp 300 is a ceiling-mounted type LED and emits light through a power source from the buck converter 250. In other words, the LED emits light using a constant current direct current power source. In the present invention, since a separate power supply module does not need to be integrated or built-in in the lamp 300, As shown in FIG.

The controller 400 not only controls the operation of the battery 207 as described above but also is connected to the lamp 300 to check whether the lamp 300 is operating normally and also controls the operation of the central control system 500, And sets the output voltage and output current of the buck converter 250 under the control of a home automation system (e.g., a home automation system). The controller 400 may control the lighting power source in consideration of the voltage drop due to the distance when the distance between the distributor 200 and the illumination lamp 300 is inputted through the user input unit 211. [ That is, when installed in a room, when a voltage drop occurs due to a distance between the distributor 200 and the lamp 300, a value lower than the originally required voltage and current (i.e., rated voltage and current) (300). In consideration of this, in the present invention, when the distance between the distributor 200 and the lamp 300 is input through the user input unit 211, the controller 400 automatically adjusts the set voltage of the buck converter 250.

The controller 400 can control at least one of the AC / DC converters 110, 120, 130, and 140 to operate based on the power consumption of the plurality of illumination lamps 300. [ For example, the controller 400 controls the power consumption of the AC / DC converters 110, 120, 130, and 140 based on the power consumption of the plurality of illumination lamps 300 based on the power consumption measured in real- At least one can be controlled to operate.

The controller 400 may control at least one of the AC / DC converters 110, 120, 130, and 140 to operate such that the sum of the rated outputs of the operated AC / DC converters is greater than the consumed power. For example, if the power consumption is 2,000 W, then the controller 400 determines that at least one of the AC / DC converters 110, 120, 130, 140 is in a state where the sum of the rated outputs of the AC / DC converters is greater than 2,000 W Can be controlled to operate.

The controller 400 may extract a selected combination of AC / DC converters when the sum of the rated outputs of the AC / DC converters 110, 120, 130, and 140 to be controlled to operate is greater than the power consumption. The controller 400 may control the AC / DC converter to operate with the best combination of the AC / DC converter efficiencies among the AC / DC converter efficiencies for the selected combination of the extracted AC / DC converters. The AC / DC converter efficiency refers to the amount of output power (DC power output from the AC / DC converter) / input power (AC power input to the AC / DC converter).

FIG. 3 is a chart for evaluating AC / DC converter efficiency according to a selected combination of AC / DC converters according to an embodiment of the present invention.

Referring to FIG. 3, the controller 400 may extract a selected combination of AC / DC converters when the sum of the rated outputs of the AC / DC converters to be controlled to operate is greater than the power consumption. For example, when the power consumption is 2,700 W, the controller 400 determines that the sum of the rated outputs of the AC / DC converters 110, 120, 130, and 140 is greater than the power consumption, A combination that operates only the converter, a combination that operates both the second AC / DC converter, the third AC / DC converter, and the fifth converter can be extracted. For example, when the power consumption is 1,700 W, the controller 400 determines that the sum of the rated outputs of the AC / DC converters 110, 120, 130, and 140 is greater than the power consumption, DC converter, a combination that operates both the second AC / DC converter and the fifth AC / DC converter, and a combination that operates both the third AC / DC converter, the fourth AC / DC converter, and the fifth converter Can be extracted. For example, when the power consumption is 700 W, the controller 400 controls the first AC / DC converter 110 when the sum of the rated outputs of the AC / DC converters 110, 120, 130 and 140 is larger than the power consumption, DC converter, a combination that operates only the second AC / DC converter, a combination that operates only the third AC / DC converter, and a combination that operates both the fourth AC / DC converter and the fifth AC / DC converter can do.

The controller 400 may analyze the AC / DC converter efficiency for the selected combination of extracted AC / DC converters. For example, the controller 400 may analyze the AC / DC converter efficiency based on previously stored data (AC / DC converter efficiency data according to the selected combination) Efficiency can be calculated and analyzed.

The controller 400 may control the AC / DC converter to operate with the best combination of the AC / DC converter efficiencies among the AC / DC converter efficiencies for the selected combination of the extracted AC / DC converters. For example, if the power consumption is 2,700 W, the controller 400 selects the best AC / DC converter efficiency among the AC / DC converter efficiencies for the selected combination of AC / DC converters To be operated by the first AC / DC converter. In another example, if the power consumption is 1,700 W, the controller 400 selects the best AC / DC converter efficiency of the AC / DC converter efficiency for the selected combination of the AC / DC converter and the fifth AC / DC converter corresponding to the first AC / DC converter and the fifth AC / DC converter '). As another example, if the power consumption is 700 W, the controller 400 determines whether the AC / DC converter efficiency of the AC / DC converter efficiency for the selected combination of AC / DC converter and the fifth AC / DC converter corresponding to the first AC / DC converter 'and the fifth AC / DC converter').

By operating at least one of the AC / DC converters having different rated powers based on the power consumption of the lamp, instead of driving the AC / DC converter all at once regardless of the power consumption of the lamp, The system can be prevented from unnecessarily consuming power. Specifically, for example, if the rated power is 4000W AC / DC converter and the power consumption of the lamp is 400W, since the conventional illumination lamp system drives the 4000W AC / DC converter regardless of power consumption, the AC / To 60% to 70%, and unnecessary power was consumed. However, the illumination lamp system according to the present invention uses N AC / DC converter modules having different rated powers, so that the sum of the rated power of the AC / DC converter optimized for 400 W consumes 400 W , A combination in which the AC / DC converter efficiency is maximum '), it is possible to prevent unnecessary power from being consumed.

The mechanical adjuster 410 may set the upper limit of the current applied to the lamp 300. For example, the mechanical regulator 410 may be composed of N switches, and the upper limit value of the current limited by each N switches may be different from each other. For example, the upper limit value of the current set by the first switch is a value corresponding to 10% of the maximum value of the current output from the buck converter 250, and the upper limit value of the current set by the second switch is the value It may be a value corresponding to 20% of the maximum value of the output current. According to this method, the upper limit value of the current set by the N switches can be set differently. The upper limit value set by the switch can be variously set according to the convenience of the user or the manufacturer. A detailed description thereof will be described in detail with reference to FIG. 4 below.

As another example, the mechanical adjuster 410 may be a rotary switch that changes its contact point as it rotates. For example, when the rotary switch is in contact with four contact points as the rotary switch rotates, the upper limit value of the current corresponding to the first contact corresponds to 10% of the maximum current value output from the buck converter 250, The value of the current corresponding to the contact may be a value corresponding to 20% of the maximum value of the current that can be output from the buck converter 250. [ According to this method, the upper limit value of the current set by the N switches can be set differently. The upper limit value set by the switch can be variously set according to the convenience of the user or the manufacturer.

In addition to the mechanical adjustments described above, various types of mechanical devices may be used.

The controller 400 may control the operation of the lamp 300 by controlling the distributor 200 to adjust the current value applied to the lamp 300 within the upper limit value range set according to the applied current regulation signal.

By setting the upper limit value of the current to be applied to the illumination lamp by the mechanical control unit as described above, the upper limit value of the current may be changed by the external hacking or the setting of the current upper limit value may be accurately maintained even after the power supply cutoff recovery. .

The mechanical switch 420 is installed around the lamp 300 and can generate a signal capable of turning on / off the illumination power supplied to the lamp 300. For example, the mechanical switch 420 may be an on / off switch. The mechanical switch 420 may also be installed at any wall around the periphery of where the lamp 300 is installed.

The controller 400 may control the buck converter 250 such that the illumination power is supplied to the lamp 300 in accordance with the on / off signal generated by the mechanical switch 420. For example, when the mechanical switch 420 generates a signal for turning on the illumination power supplied to the lamp 300, the controller 400 controls the buck converter 250 to supply the illumination power to the lamp 300 .

The controller 400 may group the mechanical switch 420 and the lamp 300 according to the setting signal. For example, assume that the configuration signal is to group three lamps located in Region A with a first mechanical switch, and group four lamps in Region B with a second mechanical switch. When the setting signal is inputted, the controller 400 sets the three lamps and the first mechanical switch in the A region to the first group, and sets the four lamps and the second mechanical switch in the B region to the second group .

Accordingly, the user can easily set the illumination power supplied to the lamp 300 by using the mechanical switch 420 installed around the lamp 300, without going to the place where the distributor 200 is installed.

The sensor 430 may recognize motion of objects or sense illumination values. For example, the sensor 430 may be a sensor for detecting movement, a sensor for measuring an illuminance value, and the like.

The controller 400 may control the lamp 300 based on the sensing value generated by the sensor 430. [ For example, if the sensor 430 generates a sensed value that senses the movement of objects in the first area, the controller 400 can turn on the lamp 300 capable of illuminating the first area . Conversely, if the sensor 430 generates a sensed value that senses the absence of movement of objects in the first area, the controller 400 can turn off the lamp 300 illuminating the first area.

As another example, when the illuminance value sensed by the sensor 430 is smaller than the illuminance value, the controller 400 can turn on the lamp 300 set. On the other hand, when the illuminance value sensed by the sensor 430 is larger than the illuminance value, the controller 400 can turn off the lamp 300 set.

Thus, based on the sensed values generated by the sensor, the controller can actively control the lamp, thereby making the lamp more efficient to control.

The central control system 500 is connected to the controller 400 and functions to set the output voltage and the output voltage of the buck converter 250. Thus, resetting the output current and voltage at the central control system 500, when the output voltage and current are replaced with different lamps 300 (e.g., as replaced by LEDs in a fluorescent lamp), the controller 400 , The output voltage and current of the buck converter 250 are reset so that the replaced LED or the like can be normally operated. At this time, the central control system 500 and the controller 400 can be connected through the TCP / IP protocol.

4 is a block diagram illustrating an electronic configuration of the distributor 200 among the illumination lamp systems according to an embodiment of the present invention.

In this embodiment, the buck converter 250 is controlled by the buck controller 220, and the controller 400 may control the buck controller 220. In this case, the controller 400 may be included in a fixed or portable terminal.

3, the distributor 200 includes a plurality of buck converters 250 connected to the lamps 300, a battery 207, a display unit 210, a user input unit 211, a buck control unit 220, and a mechanical adjustment unit 410.

For the sake of simplicity of explanation, the description of the parts explained in Fig. 2 will be omitted.

The output port 270 is a component for connecting the buck converter 250 and the corresponding lamp. The output port 270 may be disposed on the rear surface of the distributor 200 as shown in FIG. So that it is possible to supply various output power using the output port 270. This will be described in detail in FIG.

As shown in FIG. 4, the display unit 210 is a component for displaying the output voltage value set by the user input unit, the output voltage value actually output at the port, and the output current value. Here, the user input unit may be a knob 253 provided for each buck converter, or may be a user input unit 211 installed in the distributor 200 itself.

The buck control unit 220 is connected to the port 270 to check the measured output voltage and the current value and to display the output voltage and the current value set by the controller 400 together on the display unit 210 .

The mechanical adjuster 410 may set the upper limit of the current applied to the lamp 300. The mechanical adjuster 410 may be included in the distributor 200 or may be separately formed.

The buck controller 220 may control the operation of the lamp 300 by controlling the buck converter 250 to adjust the current value applied to the lamp 300 within the upper limit value range set in accordance with the applied current control signal.

The mechanical switch 420 is installed around the lamp 300 and can generate a signal capable of turning on / off the illumination power supplied to the lamp 300. For example, the mechanical switch 420 may be installed on a wall that is in the periphery of where the lamp 300 is installed.

The buck control unit 220 may control the buck converter 250 such that the illumination power is supplied to the lamp 300 in accordance with the on / off signal generated by the mechanical switch 420.

The controller 400 receives the setting value for the illumination lamp system and inputs the set value to the buck control unit 220. The set values for the illumination lamp system may be input via a user input (not shown) connected to the controller 400. For example, the controller 400 may be a configuration included in the computer. After connecting the computer and the distributor 200, the user can input a desired set value through the computer. In this case, the controller 400 of the computer may apply the input set value to the buck control unit 220. The buck controller 220 stores the input set values and controls connected components according to the input set values. After the set value is input to the buck control unit 220, the user or the system administrator can separate the computer and the distributor 200. In this way, the user can input the set value by connecting the computer and the distributor 200 for convenience.

Alternatively, the user may input a setting value for the illumination lamp system through the user input unit 211. The buck controller 220 stores the input set values and controls connected components according to the input set values.

Hereinafter, the outline of the distributor 200 having the above-described configuration will be described in detail with reference to the drawings.

5 is a view for explaining the appearance of the distributor 200 in the illumination lamp system according to an embodiment of the present invention. As shown in the figure, the distributor 200 includes a rack having a plurality of compartment spaces, and a buck converter 250, which is replaceably installed in each compartment space, is provided. The buck converter 250 is provided with a buck converter switch 251 for controlling operation on one side and a knob 253 for controlling the output current and voltage and an output port 270 . The buck converter switch 251 controls on / off of the buck converter 250.

The mechanical adjuster 410 may set the upper limit of the current applied to the lamp 300. For example, the mechanical regulator 410 may be composed of N switches 430 to 439, and the upper limit values of the currents limited by the N switches 430 to 439 may be different from each other. For example, the upper limit value of the current set by the first switch 430 is a value corresponding to 10% of the maximum value of the current output from the buck converter 250, and the upper limit value of the current set by the second switch 431 is And has a value corresponding to 20% of the maximum value of the current that can be output from the buck converter 250. The upper limit value of the third switch 432 to the ninth switch 438 also has an upper limit value of the current at the same interval. Finally, the upper limit value of the current set by the tenth switch 439 has a value corresponding to 100% of the maximum value of the current output from the buck converter 250.

Accordingly, the user or the manager can mechanically set the upper limit value of the current applied to the lamp using the mechanical adjustment unit 410. [

According to this method, the upper limit value of the current set by the N switches can be set differently. The upper limit value set by the switch can be variously set according to the convenience of the user or the administrator.

Here, the knob 253 is a component for varying the resistance value. As the knob 253 is rotated in one direction, the resistance value connected to the output port is changed, thereby changing the output voltage and the output current . By using the knob 253, appropriate power (voltage and current) can be supplied to the lamps 300 of various kinds.

Instead of this knob, a plurality of resistance terminals (not shown) may be attached to the substrate of the buck converter 250 (i.e., the substrate on which the voltage regulator, current regulator, and dimming circuit are mounted). The resistor terminal is configured to be connected to the output port 270. The designer can adjust the output current by combining the resistor terminals so as to match the input power value of the corresponding lamp.

This buck converter 250 serves to supply power to the voltage and power set for the corresponding lamp 300, as described in Figures 1-4.

On the other hand, a display unit 210 for displaying a set output voltage, a current, a measured output voltage and a current is installed on one side of the distributor 200, and a user input unit 211 is provided below the display unit 210, So that the output voltage and current can be set.

Meanwhile, the buck converter 250 is mounted while being slidably mounted in the partition space of the rack. Accordingly, when the buck converter 250 fails, the entire lighting system can be normally repaired by exchanging only the corresponding one, so that the exchange cost and the management cost can be remarkably reduced.

Since the output of the buck converter 250 can be set to an input device provided in the knob 253 or the distributor 200 installed in the buck converter 250, The output of the buck converter 250 can be conveniently set.

Hereinafter, the output port 270 provided in the converter or the distributor 200 will be described with reference to FIG.

6 is a rear perspective view of a distributor for explaining an output port (power port) of the distributor in the illumination lamp system according to an embodiment of the present invention. 6, the output port 270 provided on the rear surface of each buck converter 250 may include a first sub output port 271 and a second sub output port 272.

The first sub output port 271 may be configured to output the first sub output power and the second sub output port 272 may be configured to output the second sub output power by the buck converter 250 .

The first sub output power and the second sub output power may be different from each other. Accordingly, when the lamp 300 is installed, the sub-output port matching the input power value of the lamp 300 is determined and the connection port of the lamp 300 is connected to the lamp 300 so that the lamp 300 and the distributor 200 are connected . When the input power of the lamp 300 is equal to the sum of the first sub output power and the second sub output power, the first sub output port 271 and the second sub output port 272 are connected to each other using the special gender, And the sum of the first sub output power and the second sub output power is output.

Alternatively, each output port 270 may be combined to output the summed power. That is, by connecting two or more output ports 270 to the corresponding lamp 300 at the same time, it is possible to supply the summed power to the lamp 300.

With the above configuration, it is easy to cope with a lamp that requires various input powers.

Although the example of two sub output ports has been described in the present embodiment, the present invention is not limited to this, and it is possible to provide various output powers by using three or more sub output ports.

7 is a view for explaining an illumination lamp system according to an embodiment of the present invention.

7, the illumination lamp system according to the present invention includes a distributor 600, mechanical switches 610, 611, and 612, and a controller 620. As shown in FIG.

In this embodiment, the controller 620 will be described separately from the distributor 600, but it is obvious that the controller 620 can be formed inside the distributor 600. [

The distributor 600 is a component for supplying an appropriate constant current power to a plurality of LED lamps (not shown) installed in each room.

The divider 600 may include a first buck converter 601, a second buck converter 602, and a third buck converter 603. The first buck converter 601 can supply illumination power to the lamps installed in room 1 and the second buck controller 602 can supply lighting power to the lamps installed in room 2, The converter 603 can supply power for illumination to the lamps installed in the room 3. [

The first mechanical switch 610 may be installed around the lamp installed in the room 1 and may generate a signal capable of turning on / off the illumination power supplied to the lamp.

For example, when the first mechanical switch 610 generates a signal for turning off the illumination power supplied to the lamp, the controller 620 determines that the first buck converter 601 does not supply the illumination power to the lamp .

For example, when the second mechanical switch 611 generates a signal for turning on the illumination power supplied to the lamp, the controller 620 causes the second buck converter 602 to turn on the illumination power to the lamp .

Accordingly, the user can use the mechanical switches 610, 611, and 612 installed in the periphery of the lamp to illuminate the lamps located in the rooms 1, 2, and 3, respectively, The power source can be easily controlled.

According to an embodiment of the present invention having the above-described configuration, by isolating the illumination lamp and the power supply module, it is possible to prevent the distributor, which is a power supply module, from being damaged by heat, The power supply module is not attached. Therefore, when the illumination lamp is a ceiling mount type, the stability can be improved, the installation can be facilitated, and the weight of the illumination lamp can be reduced.

Further, according to the embodiment of the present invention, since the distributor includes a plurality of exchangeable buck converters, the maintenance becomes easier when the capacity per illumination lamp is different.

The above-described illumination lamp system and the power distributor for the illumination lamp system used therein are not limited to the configuration and method of the above-described embodiments, but the embodiments may be applied to various embodiments It is needless to say that all or some of these elements may be selectively combined.

100: AC / DC Converter Module
200: Power distributor
207: Battery
208: Watt hour meter
210:
220: Buck control unit
211: User input
250: buck converter
251: Buck converter switch
253: Knob
270: Output port
271: first sub output port
272: second sub output port
300: Lamp (LED)
400: controller
500: Central control system

Claims (20)

A plurality of illumination lamps;
An AC / DC converter module that converts external AC power to DC power and includes N AC / DC converters;
A distributor installed separately from the illumination lamp, for converting the DC power from the AC / DC converter module to supply illumination power to the plurality of illumination lamps; And
And a controller for controlling at least one of the AC / DC converters to operate based on the power consumption of the plurality of illumination lamps and controlling the operation of the illumination lamp by controlling the distributor Lighting lamp system.
The method according to claim 1,
Wherein the distributor comprises:
Further comprising a watt-hour meter capable of measuring the power consumption of the plurality of illumination lamps,
The controller comprising:
And an AC / DC converter module for controlling at least one of the AC / DC converters to operate based on the measured power consumption in the watt-hour meter. The method according to claim 1,
Wherein the N AC / DC converters have AC / DC converter modules having different rated powers.
The method of claim 3,
Wherein the sum of the rated outputs of the AC / DC converters operated by the controller is greater than the power consumption.
The method according to claim 1,
The controller comprising:
DC converter for the selected combination of the extracted AC / DC converters when the sum of the rated outputs of the AC / DC converters to be controlled to operate is larger than the power consumption, DC converter module, which controls the AC / DC converter corresponding to the best combination of the AC / DC converter efficiency.
The method according to claim 1,
Further comprising a mechanical regulator for setting an upper limit value of a current applied to the illumination lamp,
The controller comprising:
And an AC / DC converter module controlling the operation of the illumination lamp by controlling the distributor to adjust a current value applied to the illumination lamp within the set upper limit value in accordance with an applied current regulation signal.
The method according to claim 6,
The mechanical control unit includes:
And an AC / DC converter module including N switches, wherein the upper limit value of the current limited by each of the N switches is different.
The method according to claim 1,
Wherein the distributor comprises:
A rack having a plurality of compartment spaces;
A buck converter installed in each of the compartment spaces for respectively receiving DC power from the AC / DC converter module and outputting the DC power to the lighting power source; And
And an output port for connecting the buck converter and the illumination lamp, respectively.
9. The method of claim 8,
The output port
A first sub output port for outputting a first sub output power; And
And a second sub output port for outputting a second sub output power,
Outputting the sum of the first sub output power and the second sub output power when the first sub output port and the second sub output port are connected to the lamp for illumination, Lamp system.
9. The method of claim 8,
The buck converter includes:
A voltage regulator for reducing the DC power from the AC / DC converter module;
A current regulator rectifying the direct current power; And
And a dimming circuit for dimming the constant current output from the current regulator to adjust the brightness of the illumination lamp.
9. The method of claim 8,
Further comprising a mechanical switch provided around the illumination lamp and generating a signal for turning on / off the illumination power supplied to the illumination lamp,
The controller comprising:
And an AC / DC converter module for controlling the buck converter such that the illumination power source is supplied to the illumination lamp according to an on / off signal generated by the mechanical switch.
9. The method of claim 8,
Wherein the distributor comprises:
Further comprising a battery charged by a DC power source from the AC / DC converter module,
The controller comprising:
And an AC / DC converter module for controlling the distributor to supply the illumination power using the battery when supply of the external AC power is interrupted.
9. The method of claim 8,
Wherein the distributor comprises:
Further comprising an input unit for setting the illumination power source,
The controller comprising:
And an AC / DC converter module for controlling the illumination power source in consideration of a voltage drop according to the distance when the distance between the distributor and the illumination lamp is input through the input unit.
9. The method of claim 8,
Wherein the buck converter is removably mounted to the rack.
9. The method of claim 8,
The buck converter includes:
A lighting lamp system having an AC / DC converter module, including a buck converter for LED lighting and a buck converter for general lighting.
9. The method of claim 8,
The lamp is a ceiling mounted lamp,
Wherein the distributor has an AC / DC converter module installed on a wall or ceiling of a room.
A distributor installed separately from the plurality of illumination lamps for converting DC power from the AC / DC converter module to supply illumination power to the plurality of illumination lamps; And
And a controller for controlling at least one of AC / DC converters included in the AC / DC converter module to operate based on power consumption of the plurality of illumination lamps, and controlling the operation of the illumination lamp by controlling the distributor , A power distributor having an AC / DC converter module.
18. The method of claim 17,
Wherein the distributor comprises:
Further comprising a watt-hour meter capable of measuring the power consumption of the plurality of illumination lamps,
The controller comprising:
And an AC / DC converter module for controlling at least one of the AC / DC converters to operate based on the measured power consumption in the watt-hour meter.
18. The method of claim 17,
Wherein the sum of the rated output of the AC / DC converter operated by the controller is greater than the power consumed by the AC / DC converter module.
18. The method of claim 17,
The controller comprising:
DC converter for the selected combination of the extracted AC / DC converters when the sum of the rated outputs of the AC / DC converters to be controlled to operate is larger than the power consumption, AC / DC converter The AC / DC converter module has an AC / DC converter module, which controls the AC / DC converter corresponding to the efficient selection combination.

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