KR20150077103A - Integrated lantern control system - Google Patents

Abstract

The present invention relates to an integrated control system of a lantern. According to an aspect of the present invention, the lantern, including a light emitting apparatus and a lantern housing, comprises: a PCB case installed inside the lantern housing, and including a multilayer printed-circuit board; and a heat radiation plate installed on a lower side of the PCB case, and discharging heat, produced in the multilayer printed-circuit board, outside. The multilayer printed-circuit board includes at least one among a charge/discharge control circuit, a flashing apparatus integrated control circuit having a wireless communication module, and an LED module power supply circuit. The charge/discharge control circuit carries out a charge/discharge of a storage battery in accordance with a control of the flashing apparatus integrated control circuit. The LED module power supply circuit supplies the power to the light emitting module in accordance with the flashing apparatus integrated control circuit. The flashing apparatus integrated control circuit controls operations of the charge/discharge control circuit and the LED module power supply circuit, and controls transmitting and receiving data for a central process through the wireless communication module.

Description

{INTEGRATED LANTERN CONTROL SYSTEM}

Embodiments of the present invention relate to equalizer integrated control systems.

A lightening device is an illuminating device installed on a route mark to indicate the maritime route, and it is generally used as a fixed lighthouse sign and a lighthouse sign, or a floating sign, which is a floating sign.

Particularly, the light is mounted on the light buoys on the sea, the control system is provided individually for each device, the local operating environment is operated unattended, and the management is not easy due to geographical factors. In view of this, a conventional remote terminal unit is equipped with a remote terminal unit (RTU) for wireless communication externally, and is used in a structure interlocked with a control system provided for each device. In general, the control system of the home name system is understood as a self-system in view of supporting the host system (central system) on the side sending the remote control signal.

1 is a view for explaining a conventional name changer. Fig. 2 is a diagram for explaining a name control system capable of controlling the name creator of Fig. 1. Fig.

The luminaires are classified according to the focal distance between the light source and the lens, and the luminaires exemplified are those classified as so-called medium and small with a size of around 300 mm.

Referring to Figs. 1 and 2, a lighting apparatus 10 includes a light emitting device 11, a scintillator 12, and a lighting housing 13. The scintillator 12 performs functions such as flash control of the light emitting device 11 and power supply.

The light emitting device 11 includes an LED module 11a and an optical lens 11b.

The LED module 11a is electrically connected to the LED module power supply circuit 12b and is driven by receiving power from the LED module power supply circuit 12b. The optical lens 11b is spaced apart from the LED module 11a by a predetermined distance, and condenses the light incident from the LED module 11a and emits the light to the outside.

The scintillator 12 is located inside the lamp housing 13 and includes a scintillator control circuit 12a, an LED module power supply circuit 12b and a GPS antenna 12c and a daylight detection sensor 70. [

The scrambler control circuit 12a controls the LED module power supply circuit 12b to supply power to the LED module 11a. However, according to the conventional configuration, since the operation voltage and the operation current are different according to the color and the array of the LED module 11a, the scrambler can not be used in combination.

On the other hand, the LED module power supply circuit 12b supplies power to the LED module 11a under the control of the scrambler control circuit 12a. The driving power of the light changer 10 generally uses the solar photovoltaic power to be converted into electric energy by using the solar cell 50 to be charged into the battery 60, And is connected to the charge / discharge control device 20 externally as shown in FIG.

The charge / discharge control device 20 monitors the state of the battery and controls the power source by the solar cell 50 to be charged in the battery 60. According to such a conventional configuration, separate wiring is required to connect the equalizer 10 to the charge / discharge control device 20, and the battery 60 is connected to the charge / There is a problem that the lifetime is shortened.

FIG. 3 is a diagram for explaining a communication system configuration of the equalizer control system of FIG. 2, specifically illustrating a communication system configuration of a local system. FIG. 4 is a diagram for explaining the internal configuration of a name changer in the name server control system of Fig. FIG. 5 is a view for explaining the configuration of a power supply system in the equalizer control system of FIG. 3, showing in detail the charge / discharge control device.

3, 4, 5, and 6, the equalizer control system (local system) includes a name changer 10, a charge / discharge control device 20, a remote terminal device 30, (40). Here, the remote terminal device 30 may be connected to the register 10 and the charge / discharge control device 20 via RS-232, and may be connected to the racone 40 via DI or AI.

The remote terminal device (30) includes a modem unit (31) and a control unit (32).

The modem unit 31 receives the central processing data provided by the name changer 10 via the wireless antenna or transmits the central processing data to the name changer 10 via the wireless antenna. The modem unit 31 transmits / receives data for central processing by, for example, an AtoN AIS (Automatic Identification System), a TRS (Trunked Radio System), and a CDMA (Code Division Multiple Access) method.

The control unit 32 receives power from the charge / discharge control device 20, supplies power to the modem unit 31, or supplies power to the name changer 40.

The lamp changer 10 includes a regulator 12, a quality setting terminal 13, a switching device 14, a boost / lowered voltage converter 15 and a microprocessor 16 as shown in Fig.

The regulator 12 is supplied with power through the connection terminal 11 and supplies power to the microprocessor 16.

The quality setting terminal 13 sets the quality of the scrambler according to the standard quality standard to generate a quality control signal and provides the quality control signal to the microprocessor 16.

The switching element 14 operates as a step-up converter or step-down converter in accordance with at least one of a quality control signal received from the microprocessor 16 and a status signal received from the LED module 11a To-step-down converter 15 so as to be controlled.

The step-up / step-down converter 15 operates as a step-up converter or a step-down converter under the control of the switching element 14. As an example, if the up / down converter 15 operates as a step-up converter under the control of the switching device 14, it boosts the voltage and provides it to the LED module 11a. As another example, when the step-up / down converter 15 operates as a step-down converter under the control of the switching element 14, the voltage is stepped down to provide the LED module with the voltage.

The microprocessor 16 operates by being supplied with power from the regulator 12 and provides the switching control signal to the switching element 14 upon receiving the quality control signal from the uniformity setting terminal 13. In addition, the microprocessor 16 receives the daylight sensing signal from the daylight sensing sensor 70 and controls the operation of the name changer 10. Here, the sunlight sensor 70 is a sensor for sensing the amount of sunshine of the sun. The sunlight sensor 70 senses the amount of sunshine of the sun and provides a daylight sensing signal to the microprocessor 16.

The charge / discharge control device 20 includes a first switching module 21, a second switching module 22, a first voltage / current sensor 23, a second voltage / current sensor 24, And a processor 25.

The first switching module 21 interrupts the output of the solar cell 50 under the control of the microprocessor 25. That is, the first switching module 21 interrupts the output of the power generated in the solar cell 50.

The second switching module 22 controls the output of the solar cell 50 to be applied to the battery 60 under the control of the microprocessor 25. That is, the second switching module 22 interrupts the supply of the power generated from the solar cell 50 to the battery 60.

The first switching module 21 and the second switching module 22 are changed to the ON state or the OFF state in accordance with the switching signal received from the microprocessor 25. [

As an example, each of the first switching module 21 and the second switching module 22 is changed from the OFF state to the ON state when the switching signal received from the microprocessor 25 indicates the ON state. When the states of the first switching module 21 and the second switching module 22 are changed to the ON state, the electric energy converted by the solar cell 50 is stored in the battery 60.

As another example, each of the first switching module 21 and the second switching module 22 is changed from the on state to the off state when the switching signal received from the microprocessor 25 indicates the off state. When the states of the first switching module 21 and the second switching module 22 are changed to the off state, the process of storing the electric energy converted by the solar cell 50 into the battery 60 is stopped .

The first voltage / current sensor 23 generates a first voltage / current sensing signal by sensing a voltage / current with respect to a power source generated in the solar cell 50, and outputs a first voltage / current sensing signal to the microprocessor 25 ).

The second voltage / current sensor 24 generates a second voltage / current sensing signal by sensing voltage / current with respect to the power supplied from the battery 60, and outputs a second voltage / current sensing signal to the microprocessor 25, .

The microprocessor 25 communicates with the remote terminal device 30 and controls the internal components of the charge / discharge control device 20, that is, the first switching module 21, Current sensor 23 and the second voltage / current sensor 24 so that the charge / discharge is performed.

Figs. 6 and 7 are diagrams for explaining another example of the communication system configuration of the equalizer control system of Fig. 2, specifically for explaining another example of the communication system configuration of the local system. 7 is a detailed illustration of the modem unit.

6 and 7, the equalizer control system (local system) includes a name changer 10, a charge / discharge control device 20, a remote terminal device 30, and a racock 40.

The remote terminal device (30) includes a modem unit (31) and a control unit (32).

The modem unit 31 receives the central processing data provided by the name changer 10 via the wireless communication antenna or transmits the central processing data to the name changer 10 via the wireless communication antenna. The modem unit 31 illustrated in FIG. 7 further transmits / receives data for central processing by AtoN Automatic Identification System (AIS), Trunked Radio System (TRS), and Code Division Multiple Access (CDMA). As shown in FIG. 7, the modem unit 31 may include an individual module that implements the respective communication methods, or may be configured in the form of an integrated unit incorporating modules implementing the communication methods.

When the control unit 32 receives power from the charge / discharge control device 20, the control unit 32 supplies power to the modem unit 31, supplies power to the name changer 10, or supplies power to the data logger unit 50 do. Further, the control unit 32 senses the current of the power supply separately supplied to the racock 40. [

However, as described above, a conventional remote terminal unit (RTU) for wireless communication is installed and used as a separate device in the host system of a medium / small-sized name register, so that an increase in the amount of electric power , And economic burden.

In addition, the conventional local and / or small-sized lighting system of the present invention has a problem that separate wiring is required when the charging / discharging controller is connected to the outside.

In addition, in the case of a scrambler of a conventional system of a medium and small light-emitting device, a flash control circuit and a circuit for supplying power to the LED module are included. However, depending on the color and module array of the LED module, Since the currents are different, the scintillator can not be used in combination, and accordingly, a dedicated scintillator is required to be connected in accordance with the scintillator.

Korean Registered Patent No. 10-1030133 (registered on Apr. 12, 2011)

The present invention relates to an integrated control device which can reduce the size of a local system of a medium / small sized lightener by integrating a charge / discharge control circuit, a scrambler integrated control circuit, a wireless communication module and an LED module power supply circuit into one. And a system is provided.

Further, the present invention is characterized in that the LED module power supply circuit controls the quality of the light emitting device based on the control signal by the scrambler integrated control circuit, and the voltage and current of the light emitting device are sensed by the step- It is another object of the present invention to provide an equalizing integrated control system capable of automatically adjusting the rated voltage of the apparatus or performing a setting of the rated current so that the compatibility of the LED module power supply circuit can be significantly increased.

It is another object of the present invention to provide a lamp for maximizing the heat radiation effect of the switching module in the charge / discharge control circuit by forming a charge / discharge control circuit on the heat sink.

The problems to be solved by the present invention are not limited to the above-mentioned problem (s), and another problem (s) not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided a lighting apparatus comprising a light emitting device and a lighting housing, the lighting case comprising: a PCB case mounted in the housing housing and on which a multilayer printed circuit board is mounted; And a heat sink installed on a lower side of the PCB case to discharge heat generated from the multilayer printed circuit board to the outside, wherein the multilayer printed circuit board includes a charge / discharge control circuit, a scrambler integrated with a wireless communication module, Wherein the charge / discharge control circuit performs charging / discharging of the accumulator under the control of the scrambler integrated control circuit, and the LED module power supply circuit supplies the flash The integrated control circuit controls the operations of the charge / discharge control circuit and the LED module power supply circuit, and the data for central processing through the wireless communication module An equalizer integrated control system configured to control transmission and reception is disclosed.

Preferably, the PCB case includes a case having a space opened up and down, and a support plate having a connection fixing groove formed therein for coupling the heat dissipation plate. The bolt member is fixed to the connection fixing groove of the support plate, The heat sink may be connected to an upper portion of the heat sink when the heat sink is screwed through the connection fixing groove of the heat sink.

Preferably, each of the multilayer printed circuit boards includes a plurality of fastening holes, and the bolt members may be connected to each other through the fastening holes in the longitudinal direction and fastened with the nuts.

The PCB case may further include a PCB case cover having a connecting element electrically connected to the multilayer printed circuit board on the inside thereof.

Preferably, the charge / discharge control circuit includes: a first switching device for interrupting an output of the solar cell according to a switching signal received from the scrambler integrated control circuit; A second switching device for controlling the output of the solar cell according to a switching signal received from the scrambler integrated control circuit to be applied to the battery; A first voltage / current sensor sensing a voltage / current for a power source generated in the solar cell and providing a first voltage / current sensing signal to the scintillator integrated control circuit; And a second voltage / current sensor sensing the voltage / current of the power source supplied from the battery and providing a second voltage / current sensing signal to the scrambler integrated control circuit.

Preferably, the LED module power supply circuit senses the state of the light emitting device, provides a light emitting device state measurement signal to the scrambler integrated control circuit, senses the voltage and current of the light emitting device, and automatically adjusts the rated voltage of the light emitting device Or a step-up / step-down converter that performs a function of setting a rated current.

Preferably, the scintillator integrated control circuit includes: a regulator for receiving and supplying power from the charge / discharge control circuit through a connection terminal; A quality setting terminal for generating a quality control signal; And at least one of a first sensing signal, a first sensing signal, a second sensing signal, a second sensing signal, a second sensing signal, a first sensing signal, a second sensing signal, And a microprocessor for receiving and processing GPS data, providing the quality control signal to the up / down converter, and controlling the wireless communication module to perform central processing data transmission / reception processing .

Preferably, the charge / discharge control circuit is located at the lowest portion of the PCB case on which the multilayer printed circuit board is mounted, and the scrambler integrated control circuit is located above the charge / discharge control circuit, May be located above the charge / discharge control circuit.

Preferably, the heat sink may discharge heat generated from the charge / discharge control circuit among the multilayer printed circuit boards to the outside.

The details of other embodiments are included in the detailed description and the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and / or features of the present invention, and how to accomplish them, will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings. It should be understood, however, that the invention is not limited to the disclosed embodiments, but is capable of many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

According to the present invention, it is possible to remarkably reduce the size of the luminaire control system by integrating the charge / discharge control circuit, the scrambler integrated control circuit, the wireless communication module and the LED module power supply circuit into one.

Also, according to the present invention, a charge / discharge control circuit is formed on an upper portion of a heat sink mounted in a housing of the light housing, thereby maximizing the heat dissipation effect of the switching module in the charge / discharge control circuit.

According to the present invention, the power supply circuit of the LED module supplies power to the light emitting module by sensing and controlling the operation voltage and current of the color and array of the light emitting device so that the compatibility between the light emitting module and the LED module power supply circuit is significantly There is an effect that it can be raised.

1 is a view for explaining a conventional name changer.
Fig. 2 is a diagram for explaining a name control system capable of controlling the name creator of Fig. 1. Fig.
3 is a diagram for explaining a communication system configuration of the equalizer control system of FIG.
4 is a diagram for explaining the internal configuration of a name changer in the name server control system of Fig.
5 is a diagram for explaining the configuration of the power supply system in the equalizer control system of Fig. 3
Figs. 6 and 7 are diagrams for explaining another example of the communication system configuration of the equalizer control system of Fig. 2. Fig.
FIG. 8 is a view for explaining the equalizer integrated control system according to an embodiment of the present invention.
9 is a diagram for explaining a communication system configuration of the equalizer integrated control system of FIG.
FIG. 10 is a diagram for explaining a detailed configuration of a circuit view of the equalizer integrated control system of FIG. 9; FIG.
Fig. 11 is a diagram for explaining the internal structure of the equalizer integrated control system of Fig. 9 from a mechanical viewpoint.
Figs. 12 to 14 are diagrams for explaining an assembling structure of the equalizer integrated control system from a mechanical point of view according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

It is to be understood that the lighter is classified according to the focal distance between the light source and the lens, and the lighter explained in the following embodiments is classified as so-called small with a size of about 200 mm. For example, the Ministry of Land, Transport and Maritime Affairs Notice No. 2012-496 "Standard of the LED-200 Standard" (2012.04.16), the Ministry of Land, Transport and Maritime Affairs of the Republic of Korea The general general information is explained through the Ministry of Maritime Announcement No. 2012 - 497 'Standard Specification for Maritime Reference Lamp (LED-200HI)' (April 16, 2012). The contents not described in detail in the following description can be understood by those skilled in the art through the construction of such known data.

FIG. 8 is a view for explaining the equalizer integrated control system according to an embodiment of the present invention.

Referring to FIG. 8, the lighting apparatus 100 includes a light emitting device 110, a lighting device integrated control system 120, and a lighting housing 130.

The light emitting device 110 includes light emitting modules 111a, 111b and 111c and lenses 112a, 112b and 112c.

The light emitting modules 111a, 111b and 111c are electrically connected to the LED module power supply circuit 124 and are driven by receiving power from the LED module power supply circuit 124. For example, the light emitting modules 111a, 111b, and 111c may be implemented as a plurality of LED modules, and the LED modules may emit white, red, green, yellow, or blue light.

The light emitting modules 111a, 111b, and 111c may be manufactured in various sizes so that the light emitting modules 111a, 111b, and 111c may be stacked at a plurality of stages. Of the light emitting array.

In one embodiment, the light emitting modules 111a, 111b, and 111c may be stacked in multiple stages through the module support rods. The module support bar is manufactured so that a plurality of light emitting members may be sandwiched between the light emitting modules 111a, 111b, and 111c so as to support the light emitting modules 111a, 111b, and 111c. For example, the module support rods may be formed of corrosion resistant aluminum, stainless steel, or a material of equivalent or superior corrosion resistance.

Here, the number and arrangement of the plurality of light emitting members can be arbitrarily changed according to the size of the lamp holder 100. That is, the quantity of the light emitting members can be reduced when the size changer 100 requires a small quantity of light, and the quantity of the light emitting members can be increased if the size changer 100 requires a large quantity of light have.

In addition, the plurality of light emitting members are connected in series or in parallel so that the light emitting modules 111a, 111b, and 111c are not turned on even if a failure occurs in one light emitting member. The plurality of light emitting members may be spaced a predetermined distance from the focal point of the lenses 112a, 112b, and 112c.

The lenses 112a, 112b and 112c are spaced apart from the light emitting modules 111a, 111b and 111c by a predetermined distance and collect the light incident from the light emitting modules 111a, 111b and 111c and then diverge the light.

The lenses 112a, 112b, and 112c may be provided with a discoloring prevention member such as a coating to prevent discoloration of ultraviolet rays, and thus may not be deteriorated by the influence of light and seawater.

The lenses 112a, 112b, and 112c may be formed of a material having excellent optical performance and being formed of a product such as colorless transparent acrylic or the like, but is not limited thereto and may be formed of any material without optical defect. The lenses 112a, 112b, and 112c can be formed of any material that does not cause a deterioration phenomenon due to a temperature change even when the light emitting modules 111a, 111b, and 111c are turned on for a long time.

The equalizer integrated control system 120 includes a heat sink 121, a charge / discharge control circuit 122, a scintillator integrated control circuit 123, and an LED module power supply circuit 124.

The heat sink 121 is used for heat dissipation for electronic components (for example, a switching module) in the charge / discharge control circuit 122 formed on the upper part. The heat sink 121 may include a plurality of heat dissipation fins 121a to discharge the heat generated by the charge / discharge control circuit 122 to the lower portion.

The electronic component in the charge / discharge control circuit 122 changes to the on state or the off state in accordance with the control signal of the charge / discharge control circuit 122, so that much heat is generated. At this time, the high heat generated from the electronic component can be discharged to the outside through the heat sink 121, thereby maximizing the heat radiation effect of the electronic component.

The charge / discharge control circuit 122 is formed on the heat sink 121 and performs charge / discharge of the accumulator under the control of the scintillator integrated control circuit 123. The scintillator integrated control circuit 123 is formed on the upper part of the charge / discharge control circuit 122, and the LED module power supply circuit 124 is formed on the upper side thereof. The scintillator integrated control circuit 123 controls the operation of the charge / discharge control circuit 122 and the LED module power supply circuit 124.

Hereinafter, the charging / discharging control circuit 122, the scintillator integrated control circuit 123 and the LED module power supply circuit 124 will be described in more detail with reference to Figs. 9 to 11. Fig.

9 is a diagram for explaining a communication system configuration of the equalizer integrated control system of FIG. FIG. 10 is a diagram for explaining a detailed configuration of a circuit view of the equalizer integrated control system of FIG. 9; FIG. Fig. 11 is a diagram for explaining the internal structure of the equalizer integrated control system of Fig. 9 from a mechanical viewpoint.

9 to 11, the equalizer integrated control system 120 includes a charge / discharge control circuit 122, a scintillator integrated control circuit 123, and an LED module power supply circuit 124. The modem unit and the control unit, which have conventionally been installed separately, are integrally configured in the scrambler integrated control circuit 123 of this embodiment.

The modem unit is implemented in the form of a wireless communication module 123a and receives central processing data provided by the name changer 100 through a wireless communication antenna or transmits data for central processing to the name changer 100 through a wireless communication antenna . In one embodiment, the modem unit transmits / receives data for central processing using a communication method such as RF (Radio Frequency) communication, Long Term Evolution (LTE), Trunked Radio System (TRS), and VDES .

When the control unit is implemented in the form of a scintillator integrated control circuit 123 and receives data for central processing through the wireless communication module 123a, the control unit controls the / discharge control circuit 122, The integrated control circuit 123 and the LED module power supply circuit 124 can be controlled.

The charge / discharge control circuit 122 is a circuit for charging / discharging the storage battery under the control of the scintillator integrated control circuit. The charge / discharge control circuit 122 includes a first switching device 122a, a second switching device 122b, A first voltage / current sensor 122c and a second voltage / current sensor 122d.

The first switching device 122a interrupts the output of the solar cell 140 under the control of the scrambler integrated control circuit 123. That is, the first switching device 122a can interrupt the output of the power generated in the solar cell 140. [

The second switching element 122b controls the output of the solar cell 140 to be applied to the battery 140 under the control of the scrambler integrated control circuit 123. In other words, the second switching device 122b can block the power generated from the solar cell 140 from being applied to the battery 140.

Here, the solar cell 140 is a module for converting solar energy into electric energy in the daylight hours, the battery 140 is a module capable of storing electric energy, and the battery 140 is connected to the solar cell 140 The supplied power is stored.

The first switching device 122a and the second switching device 122b are changed to the on state or the off state in accordance with the switching signal received from the scrambler integrated control circuit 123. [

In one embodiment, each of the first switching device 122a and the second switching device 122b is changed from the off state to the on state when the switching signal received from the scrambler integrated control circuit 123 indicates the on state . When the states of the first switching device 122a and the second switching device 122b are changed to the on state, the electric energy converted by the solar cell 140 is stored in the battery 140. [

In another embodiment, each of the first switching device 122a and the second switching device 122b is changed from the on state to the off state when the switching signal received from the scrambler integrated control circuit 123 indicates the off state do. When the states of the first switching device 122a and the second switching device 122b are changed to the off state, the process of storing the electric energy converted by the solar cell 140 into the battery 140 is stopped .

The first voltage / current sensor 122c generates a first voltage / current sensing signal by sensing a voltage / current with respect to a power source generated in the solar cell 140, and outputs a first voltage / current sensing signal to the scintillator integrated control Circuit 123 as shown in FIG.

The second voltage / current sensor 122d generates a second voltage / current sensing signal by sensing a voltage / current with respect to a power source supplied from the battery 140, and outputs a second voltage / current sensing signal to the scrambler integrated control circuit (123).

The scintillator integrated control circuit 123 controls operations of the charge / discharge control circuit 122 and the LED module power supply circuit 124. The scintillator integrated control circuit 123 includes a wireless communication module 123a, a wireless communication antenna 123b A connection terminal 123c, a regulator 123d, a quality setting terminal 123e, a GPS antenna 123f and a microprocessor 123g.

The wireless communication module 123a receives the central processing data provided from the name changer 100 via the wireless communication antenna 123b or transmits the central processing data to the name changer 100 via the wireless communication antenna 123b do. At this time, the wireless communication module 123a can use only a wireless communication modem (or module) that can be installed inside the name changer 100. [

In one embodiment, the wireless communication module 123a transmits data for central processing in a manner such as RF (Radio Frequency) communication, LTE (Long Term Evolution), TRS (Trunked Radio System), VDES (VHF Data Exchange System) / Receive. Also, the wireless communication module 123a of the present embodiment may use an individual module that implements the above communication methods, or an integration module that selectively provides at least one of these communication methods.

On the other hand, from the viewpoint of functionality, the wireless communication module 123a of the present embodiment can be understood as being integrated from the regulator 123d of the scrambler integrated control circuit 123 And may be understood as a concept of an independent module that receives power and performs the above-described data transmission / reception process under the control of the microprocessor 123g. The wireless communication module 123a may be configured to selectively connect the individual modules or the integration modules according to each communication method to the scrambler integrated control circuit 123. [

The regulator 123d receives power from the charging / discharging control circuit 122 through the connection terminal 123c and supplies power to the microprocessor 123g and the wireless communication module 123a.

The quality setting terminal 123e sets the quality of the scintillator according to the standard quality standard to generate a quality control signal, and provides a quality control signal to the microprocessor 123g. The microprocessor 123g may then provide a quality control signal to the LED module power supply circuit 124 to automatically adjust the voltage / current according to the color and array of the light emitting modules 111a, 111b, and 111c. The microprocessor 123g will be described in more detail below.

The GPS antenna 123f receives a signal transmitted from a GPS satellite (not shown) so that the microprocessor 123g can calculate the current position (e.g., longitude, latitude, altitude) and timing.

When the microprocessor 123g receives the daylight sensing signal from the daylight sensing sensor 150, the microprocessor 123g generates a switching signal in accordance with the daylight sensing signal and outputs the switching signal to the first switching device 122a and the second switching device 122a of the charge / Device 122b, respectively.

Here, the daylight sensing sensor 150 is a sensor that senses the amount of sunshine of the sun, and determines the lighting time point of the lightening device 100. The daylight sensing sensor 150 senses the amount of sunlight and provides a daylight sensing signal to the microprocessor 123g.

In one embodiment, the microprocessor 123g receives the daylight sensing signal from the daylight sensing sensor 150, and determines that the current state is the daylight when the amount of light contained in the daylight sensing signal is greater than or equal to a specific daylight, And provides the switching signal to the first switching device 122a and the second switching device 122b of the charging / discharging control circuit 122, respectively.

In another embodiment, the microprocessor 123g receives a daylight sensing signal from the daylight sensing sensor 150, and if the amount of light contained in the daylight sensing signal is below a certain amount of light, the microprocessor 123g determines that the current state is night, And provides the switching signal to the first switching device 122a and the second switching device 122b of the charge / discharge control circuit 122, respectively.

The microprocessor 123g generates a switching signal based on the sensing signal received from the charge / discharge control circuit 122 and provides it to the charge / discharge control circuit 122. [

More specifically, the microprocessor 123g is connected to the power generated from the solar cell 140 from the first voltage / current sensor 122c and the second voltage / current sensor 122d of the charge / discharge control circuit 122, Current sensing signal for the battery 140 and the second voltage / current sensing signal for the power supplied from the battery 140, it is possible to generate a switching signal using the second voltage / current sensing signal.

In one embodiment, if the current value of the power supply generated in the solar cell 140 is greater than or equal to the pre-stored current reference value based on the first voltage / current sensing signal, the microprocessor 123g supplies the power of the solar cell 140, Discharge control circuit 122 to the first switching device 122a and the second switching device 122b of the charge / discharge control circuit 122, have.

Accordingly, when the states of the first switching device 122a and the second switching device 122b are changed to the ON state according to the switching signal, the power generated in the solar cell 140 is applied to the battery 140, Is charged.

In another embodiment, if the current value of the power supply generated in the solar cell 140 is less than the pre-stored current reference value based on the first voltage / current sensing signal, the microprocessor 123g outputs the second voltage / The voltage value of the power source supplied from the storage battery 140 is compared with the stored voltage reference value.

If the voltage value of the power source supplied from the battery 140 is equal to or greater than the pre-stored voltage reference value, the microprocessor 123g determines that the power source charged in the battery 140 is sufficient, Signal to the first switching device 122a and the second switching device 122b of the charge / discharge control circuit 122, respectively.

When the state of the first switching device 122a and the second switching device 122b is changed to the off state, the power generated from the solar cell 140 is applied to the battery 140, The process of charging stops.

If the voltage value of the power supply supplied from the battery 140 is less than the pre-stored voltage reference value, the microprocessor 123g determines that the power stored in the battery 140 is insufficient, Signal to the first switching device 122a and the second switching device 122b of the charge / discharge control circuit 122, respectively.

Accordingly, when the states of the first switching device 122a and the second switching device 122b are changed to the ON state according to the switching signal, the power generated in the solar cell 140 is applied to the battery 140, Is charged.

When the microprocessor 123g receives the light emitting module status measurement signal from the LED module power supply circuit 124, the microprocessor 123g generates a switching signal according to the light emitting module status measurement signal and supplies the switching signal to the second switching device 122b.

In one embodiment, the microprocessor 123g generates a switching signal for instructing a change to the off state when the current of the light emitting module included in the light emitting module status measurement signal is equal to or greater than the pre-stored current reference value, 122 to the second switching device 122b.

When the state of the second switching device 122b is changed to the off state, the power supplied from the battery 140 is cut off and can be limited to supply only the optimal current to the light emitting module.

In another embodiment, the microprocessor 123g generates a switching signal for instructing a change to the ON state when the current of the light emitting module included in the light emitting module status measurement signal and the stored current reference value is less than the pre- To the second switching element 122b of the second switch 122.

When the state of the second switching device 122b is changed to the ON state, the power supplied from the battery 140 is supplied to the LED module power supply circuit 124, so that current can be supplied to the light emitting module have.

The microprocessor 123g receives a quality control signal from the quality setting terminal 123e and outputs a quality control signal for operating the light emitting device 110 according to the quality control signal, Converter 125a.

The LED module power supply circuit 124 supplies power to the light emitting module in accordance with the control signal of the scrambler integrated control circuit 123, and includes a step-up / step-down converter 125a as shown in FIG. For example, a conventional buck-boost converter (Buck-Boost Converter) can be used as the boost / step down converter 125a of the present embodiment.

The step-up / step-down converter 125a senses the state of the light emitting device, provides the light emitting device state measurement signal to the scrambler integrated control circuit, and automatically senses the voltage and current of the light emitting device to automatically adjust the rated voltage of the light emitting device Perform the rated current setting function.

In a different viewpoint, the step-up / step-down converter 125a can change the states of the light emitting modules 111a, 111b, and 111c under the control of the scintillator integrated control circuit 123. [

Step-down converter 125a receives the quality control signal from the microprocessor 123g of the scrambler integrated control circuit 123 and supplies the light emission module 111a, 111b, or 111c in accordance with the quality control signal, Can be changed. Here, the quality control signal may include information on the light emitting time, the light emitting period, and the number of light emitting times of the light emitting modules 111a, 111b, and 111c.

For example, the boost / stepdown type converter 125a can control the light emitting modules 111a, 111b, and 111c to emit light according to the light emitting time included in the quality control signal. For example, the w / step-down converter 125a may control the light emitting modules 111a, 111b, and 111c to emit light in accordance with the light emission period included in the quality control signal. For example, the w / step-down converter 125a may control the light emitting modules 111a, 111b, and 111c to emit light in accordance with the number of light emissions included in the quality control signal.

That is, since the light emitting modules 111a, 111b, and 111c are controlled in accordance with the quality control signal, the time, cycle, and number of flashing lights at nighttime are different from each other. Thus, the quality control signal is a signal for controlling the states of the light emitting modules 111a, 111b, and 111c in order to distinguish the lighthouse.

The w / d type converter 125a senses the states of the light emitting modules 111a, 111b, and 111c to generate a light emitting module status measurement signal and outputs the light emitting module status measurement signal to the microprocessor 123g.

Figs. 12 to 14 are diagrams for explaining an assembling structure of the equalizer integrated control system from a mechanical point of view according to an embodiment of the present invention.

12 to 14, the equalizer-integrated control system 120 includes a heat sink 121 and a PCB case 160, and is connected to the inside of the lamp housing (for example, the lower housing of the light lifting device) It can be said.

The heat sink 121 discharges heat generated from the multilayer printed circuit boards 122, 123, and 124 mounted inside the PCB case 160 to the outside. In one embodiment, the heat sink 121 is mounted on a printed circuit board (e.g., charge / discharge control) located at the lowermost of the multilayer printed circuit boards 122, 123, 124 mounted within the PCB case 160 Circuit 122) to the outside.

A plurality of radiating fins 121a are formed on the lower side of the radiating plate 121. The plurality of radiating fins 121a may be spaced apart from each other by a predetermined distance and extend toward the lower side of the radiating plate 121.

The heat sink 121 is provided with a PCB case (not shown) on which a multilayer printed circuit board (e.g., a charge / discharge control circuit 122, a scintillator integrated control circuit 123, an LED module power supply circuit 124, 160 are formed on the outer circumferential surface of the base plate 121a. At this time, the connection fixing grooves 121b may be formed at regular intervals along the center of the heat sink 121, and preferably correspond to the positions of the connection fixing grooves 160d formed in the support plate 160a of the PCB case 160 As shown in FIG.

The heat dissipating plate 121 is fixed to the PCB case 160 when a plurality of bolt members 121c are inserted through the connection fixing groove 160d of the support plate 160a of the PCB case 160 and the connection fixing groove 121b of the heat sink 121, 160, respectively. The PCB case 160 will be described in more detail below.

Here, although the shape of the heat sink 121 is shown as a circular shape, the heat sink 121 may be formed in various shapes such as a square shape, a triangle shape, and the like.

The PCB case 160 is a case having a space opened up and down, and a multilayer printed circuit board 122, 123, 124 electrically connected to the inside can be mounted. A support plate 160a having a connection fixing groove 160d for coupling the heat sink 121 may be formed on the lower side of the PCB case 160. [

The connection fixing grooves 160d may be formed at regular intervals along the center of the support plate 160a and preferably at positions corresponding to the positions of the connection fixing grooves 121b formed in the heat sink 121. [ The support plate 160a may be formed by a circle having a center portion, a triangle having a center portion opened, a square having a central portion opened, or the like depending on the shape of the PCB case 160.

When the PCB case 160 is screwed through the plurality of bolt members 121c through the connection fixing groove 160d of the support plate 160a and the connection fixing groove 121b of the heat sink 121, Lt; / RTI >

Here, although the shape of the PCB case 160 is shown as a cylinder, it may be formed in various shapes such as a rectangular column, a triangular column, or the like depending on the shape of the heat sink 121, unlike the embodiment.

Fastening holes 122a, 123a, and 124a are formed in the multilayer printed circuit boards 122, 123, and 124, respectively. At this time, the fastening holes 122a, 123a and 124a may be formed at regular intervals along the centers of the multilayer printed circuit boards 122, 123 and 124, The fastening holes 122a, 123a and 124a can be formed at the same position.

When a plurality of bolt members 160c are fastened with the nuts at the top and / or bottom portions through the fastening holes 122a, 123a and 124a of the multilayer printed circuit boards 122, 123 and 124, , 123, and 124 may be integrally connected to each other. The detailed shape of the bolt member 160c can be appropriately deformed in a form suitable for such fastening. For example, it may be formed in a length and shape passing through the entire multilayer printed circuit boards 122, 123, and 124, and each bolt member is separately provided for each printed circuit board, and its length and shape are formed It is possible.

Although the multilayer printed circuit boards 122, 123, and 124 are shown in a circular shape, they may be formed in various shapes such as a square, a triangle, or the like depending on the bottom surface of the PCB case 160 have.

The PCB case cover 161 is attached with a connecting element (not shown in the drawing, a connector in a general form) for electrically connecting with the multilayer printed circuit board on the lower side. The electrical connections between the multilayer printed circuit boards may be in the form of interconnections using a variety of known connecting lines (LI) and connectors (CO).

A power supply line or the like connected to the light emitting module 111 provided in the upper side of the backlight unit may be connected to the upper surface of the PCB case cover 161. For example, And a plurality of power terminal fixing bolts 165 electrically connected to the connection elements are provided on the upper surface of the PCB case cover 161, The connecting connection of the power source line 201 can be achieved by the tight coupling of the power source line 165.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the scope of the appended claims and equivalents thereof.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, Modification is possible. Accordingly, the spirit of the present invention should be understood only in accordance with the following claims, and all equivalents or equivalent variations thereof are included in the scope of the present invention.

100: Lighting machine
110: Light emitting device
120: Integrated control system
130: housing housing

Claims (9)

In a lighting apparatus including a light emitting device and a lighting housing,
A PCB case mounted on the housing housing and on which a multilayer printed circuit board is mounted; And
And a heat sink installed on a lower side of the PCB case to discharge heat generated from the multilayer printed circuit board to the outside,
Wherein the multilayer printed circuit board includes at least one of a charge / discharge control circuit, a scintillator integrated control circuit having a wireless communication module, and an LED module power supply circuit,
The charge / discharge control circuit performs charging / discharging of the storage battery under the control of the scrambler integrated control circuit, and the LED module power supply circuit supplies power to the light emitting module under the control of the scrambler integrated control circuit , The scrambler integrated control circuit controls operations of the charge / discharge control circuit and the LED module power supply circuit, and controls the central processing data transmission / reception through the wireless communication module
Integrated control system.
The method according to claim 1,
The PCB case
And a support plate having a connection fixing groove for coupling the heat sink to a lower side of the case,
And the bolt member is connected to an upper portion of the heat sink when the bolt member is threaded through the connection fixing groove of the support plate and the connection fixing groove of the heat sink.
Integrated control system.
The method according to claim 1,
Each of the multilayer printed circuit boards
And a plurality of fastening holes, wherein the bolt members pass through the fastening holes in the longitudinal direction and are fastened with nuts and connected to each other
Integrated control system.
The method according to claim 1,
The PCB case
And a PCB case cover to which a connection element for electrically connecting to the multilayer printed circuit board is attached,
Integrated control system.
The method according to claim 1,
The charge / discharge control circuit
A first switching device for interrupting an output of the solar cell according to a switching signal received from the scrambler integrated control circuit;
A second switching device for controlling the output of the solar cell according to a switching signal received from the scrambler integrated control circuit to be applied to the battery;
A first voltage / current sensor sensing a voltage / current for a power source generated in the solar cell and providing a first voltage / current sensing signal to the scintillator integrated control circuit; And
And a second voltage / current sensor for sensing a voltage / current with respect to a power source supplied from the battery and providing a second voltage / current sensing signal to the scrambler integrated control circuit
Integrated control system.
6. The method of claim 5,
The LED module power supply circuit
A step of sensing the state of the light emitting device and providing a light emitting device status measurement signal to the scrambler integrated control circuit, sensing the voltage and current of the light emitting device to automatically adjust the rated voltage of the light emitting device, Lt; RTI ID = 0.0 >
Integrated control system.
7. The method according to any one of claims 5 to 6,
The scrambler integrated control circuit
A regulator for receiving and supplying power from the charge / discharge control circuit through a connection terminal;
A quality setting terminal for generating a quality control signal; And
Generates a switching signal according to at least one of a daylight sensing signal received from the daylight sensor, the first voltage / current sensing signal, and the second voltage / current sensing signal, and provides the switching signal to the first switching device and the second switching device And a microprocessor for receiving and processing GPS data, providing the quality control signal to the up / down converter, and controlling the wireless communication module to perform central processing data transmission / reception processing doing
Integrated control system.
The method according to claim 1,
The charge / discharge control circuit is located at the lowest portion of the PCB case on which the multilayer printed circuit board is mounted,
The scrambler integrated control circuit is located at the top of the charge / discharge control circuit,
Wherein the LED module power supply circuit is located above the charge / discharge control circuit
Integrated control system.
9. The method of claim 8,
The heat sink
And discharges heat generated in the charge / discharge control circuit among the multilayer printed circuit boards to the outside.
Integrated control system.

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