KR102157178B1 - Remote control system for SMPS - Google Patents

Abstract

An embodiment of the present invention includes an electric sign for displaying traffic information; As an SMPS providing DC-type driving power to the electric sign, a DC power supply device that senses the SMPS operation state and provides it to a field monitoring PC, and performs power control according to a power remote control command received from the field monitoring PC; A site that relays the SMPS operation status received from the DC power supply to the VMS operation server, and relays the received power remote control command to the DC power supply when a power remote control command is received from the VMS operation server server. Monitoring PC; And monitoring the SMPS operation status of the DC power supply received from the field monitoring PC, and transmitting a power remote control command including power on, power off, and power reset according to the received SMPS operation status to the field monitoring PC. VMS operation server; may include.

Description

Remote control system for power supply for variable information signs {Remote control system for SMPS}

The present invention is a power supply remote control system for VMS, a power supply remote control system for VMS that remotely controls the power supply of VMS

In general, traffic flows, such as traffic flow, delays, congestion, operation time for a specific section, rain, ice, road pavement work, etc., on roads where many vehicles travel, such as urban arterial roads, highways, and local national highways. A variable information sign (VMS) is installed to indicate to the vehicle driver.

1 is a block diagram showing the configuration of a conventional VMS control system. In FIG. 1, a VMS (Variable Message Sign) control system is composed of a variable information sign 10 (hereinafter, referred to as VMS) and an operator system 20 of a traffic information center.

VMS (10) is installed on the road to output text data and image data, an electric sign (11), a field controller that outputs text data and image data to the electric sign (11), and controls the overall operation of the VMS (10) (12), a modem 14 for transmitting and receiving data to and from the operator server 21 in the operator system 20 to communicate with and a VMS power supply 13 for providing power to the VMS 10.

Further, the operator system is provided with communication means for communicating with a plurality of VMSs 10 to communicate with the VMS. Accordingly, traffic information may be displayed on the electronic board 11 of the VMS according to the traffic information data transmitted from the operator server 21 of the operator system 20.

Conventionally, a technology for remotely controlling the VMS by detecting the operation status of the modem installed in the VMS is also described.

However, in the case of a VMS installed on the road in such a conventional technology, the field controller 12 that controls the VMS in the field malfunctions, not a state in which communication is disabled due to wire breakage or other communication failures, such as VMS reset and VMS power off. If the control is not possible, there is a problem in that the operating personnel must go to the site, reset the site controller, and turn off the power circuit breaker of the VMS to make the VMS empty, resulting in an increase in manpower and maintenance costs for operation.

Therefore, for the DC power supply that supplies DC power to the VMS operating on national highways and highways, maintenance manpower and costs are wasted because even minor failures that can be resolved by turning on/off the power must be dispatched to the site and directly controlled. .

Korean Patent Publication No. 10-2015-0100230

An object of the present invention is to provide a means for remotely controlling and maintaining a DC power supply of a VMS.

An embodiment of the present invention includes an electric sign for displaying traffic information; As an SMPS providing DC-type driving power to the electric sign, a DC power supply device that senses the SMPS operation state and provides it to a field monitoring PC, and performs power control according to a power remote control command received from the field monitoring PC; A site that relays the SMPS operation status received from the DC power supply to the VMS operation server, and relays the received power remote control command to the DC power supply when a power remote control command is received from the VMS operation server server. Monitoring PC; And monitoring the SMPS operation status of the DC power supply received from the field monitoring PC, and transmitting a power remote control command including power on, power off, and power reset according to the received SMPS operation status to the field monitoring PC. VMS operation server; may include.

The SMPS operation state includes an input power state, a ventilation fan driving state, and a heat sink temperature state, and the VMS operation server monitors the SMPS operation state to detect when an input power abnormality, a ventilation fan abnormality, or a temperature abnormality is detected. A matching power remote control command may be generated according to an abnormal condition and transmitted to the on-site monitoring PC.

The DC power supply includes: a primary-side rectification module for rectifying an AC voltage input from the outside into a DC voltage; FET switching module for FET switching the DC voltage output from the primary rectification module to output AC; A voltage transformer that provides the AC voltage output from the ET switching module to a primary coil and converts it into an AC converted voltage that is converted power of the secondary coil; A secondary-side rectification module rectifying an AC converted voltage output from the voltage transformer to a DC converted voltage; A voltage/current detection module for detecting a voltage level and a current level output from the secondary rectification module; And a control module that provides the voltage level and current level detected by the voltage/current detection module as the input power state to the field monitoring PC, and performs power control according to a power remote control command received from the field monitoring PC. It may include.

The DC power supply may include a primary filter for filtering an AC voltage input from the outside and providing it to the primary rectifying module; And a secondary-side filter filtering noise of the DC conversion voltage output from the secondary-side rectification module and transferring the noise to the voltage/current detection module.

The DC power supply device includes a ventilation fan that lowers the temperature of the heat sink, and the control module may provide the sensing value of the ventilation fan to the on-site monitoring PC as information on the driving state of the ventilation fan.

The DC power supply device includes a heat sink temperature detection module that detects the temperature of the heat sink, and the control module may provide the detected heat sink temperature to the field monitoring PC.

When a plurality of DC power supplies are provided, each DC power supply is assigned a unique address address, and the on-site monitoring PC monitors the SMPS operation status to the on-site monitoring PC along with the unique address address of the DC power supply. The VMS operation server may transmit a power remote control command together with a unique address address of a DC power supply to be remotely controlled.

The VMS operation server may give priority to each DC power supply and transmit a power remote control command to sequentially control power to each DC power supply based on the priority.

The on-site monitoring PC may transmit a power remote control command directly input by the on-site manager to the DC power supply.

According to an embodiment of the present invention, by remotely controlling power to a DC power supply device that supplies DC power to VMS operating on national highways and highways, it is possible to reduce maintenance manpower and cost.

1 is a block diagram showing the configuration of a conventional VMS control system.
2 is a conceptual diagram of the configuration of a power supply remote control system for a VMS according to an embodiment of the present invention.
3 is a detailed configuration diagram of a power supply remote control system for a VMS according to an embodiment of the present invention.
Figure 4 is a diagram showing the operation flow of the VMS power supply remote control system according to an embodiment of the present invention.
5 is a block diagram of a DC power supply according to an embodiment of the present invention.

Hereinafter, the advantages and features of the present invention, and a method of achieving them will become apparent with reference to the embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various different forms, and is provided to completely inform the scope of the invention to those of ordinary skill in the art to which the present invention belongs. As such, the invention is only defined by the scope of the claims. In addition, when it is determined that related well-known technologies or the like may obscure the subject matter of the present invention in describing the present invention, detailed descriptions thereof will be omitted.

2 is a conceptual diagram of the configuration of a remote control system for VMS power supply according to an embodiment of the present invention, Figure 3 is a detailed configuration diagram of the remote control system for power supply for VMS according to an embodiment of the present invention, and Figure 4 is the present invention It is a figure showing the operation flow of the VMS power supply remote control system according to an embodiment of.

The present invention remotely controls and monitors the DC power supply 200 that supplies DC power to the VMS used on national highways and highways. Therefore, there is a risk of various accidents due to the necessity of checking the DC power supply unit 200 directly to the display unit, but it is intended to secure safety by applying the remote monitoring technology of the present invention.

To this end, the VMS power supply remote control system of the present invention, as shown in Figs. 2 and 3, provides driving power in DC form to the electric sign 100 displaying traffic information and the electric sign 100 As an SMPS that detects the SMPS operation state, provides it to the field monitoring PC 300, and performs power control according to the power remote control command received from the field monitoring PC 300, the DC power supply 200 and DC The SMPS operation state received from the DC power supply 200 is relayed to the VMS operation server 400 by being connected to the power supply 200 with a wired cable, and receives a power remote control command from the VMS operation server 400 In one case, the on-site monitoring PC 300 relaying the received power remote control command to the DC power supply 200 and the on-site monitoring PC 300 connected to the on-site monitoring PC 300 through wired communication or wireless communication Monitors the SMPS operation status of the DC power supply 200 received from and transmits a power remote control command including power on, power off, and power reset according to the received SMPS operation status to the on-site monitoring PC 300 It includes a VMS operating server 400. It will be described in detail below.

The electric sign 100 is an electric sign that displays traffic information. Such an electric sign 100 is implemented as an LED display panel, an LCD display panel, etc., so that traffic flows, such as smooth traffic, delays, congestion, and specific sections, are implemented on roads where many vehicles travel, such as urban arterial roads, highways, and local national highways. It is a variable information sign (VMS) that displays various road information such as driving time, rain, ice, road pavement work, etc. to the vehicle driver.

The DC power supply 200 is a device that provides DC driving power to the electric sign 100 and is provided with at least one. The DC power supply 200 (SMPS; Switched Mode Power Supply) is a power supply that converts AC power (AC power) into DC power (DC power) through switch control using a switching transistor or the like. This is a DC stabilized power supply device that stabilizes the output by controlling the ratio of the on-off time of the semiconductor switch element, and enables high efficiency, small size and weight reduction. In general, a method of converting and supplying stable power from a battery and commercial AC power is largely classified into a series regulator method and a switched mode method.

The DC power supply device 200 of the present invention detects the SMPS operation state and provides it to the field monitoring PC 300 as shown in FIG. 4. Here, the SMPS operation state refers to an operation state of the DC power supply 200 and includes an input power state, a ventilation fan driving state, and a heat sink temperature state. The input power state refers to the state of the input power provided to the electric light sign 100, the driving state of the ventilation fan 209 refers to the driving state of the ventilation fan 209 provided inside the DC power supply 200, and the heat sink temperature The state refers to the temperature state of the heat sink of the DC power supply 200.

In addition, the DC power supply device 200 of the present invention, when receiving a power remote control command from the field monitoring PC 300, as shown in FIG. 4, performs power control according to the received power remote control command. Here, the power remote control command may include power on, power off, and power reset. The DC power supply device 200 will be described in detail with reference to FIG. 5 to be described later.

The on-site monitoring PC 300 is a PC provided in the field where the VMS is installed, and may correspond to a desktop PC, a notebook PC, and the like. The field monitoring PC 300 may be connected to the DC power supply 200 by a wired cable or short-range wireless communication, for example, Ethernet, Universal Serial Bus, IEEE 1394, serial communication. communication) and parallel communication may be used, and wireless communication methods such as Infrared Radiation, Bluetooth, Home Radio Frequency (RF), and Wireless LAN are available. Can be used.

The field monitoring PC 300 relays the SMPS operation state received from the DC power supply 200 to the VMS operation server 400 as shown in FIG. 4.

In addition, when the field monitoring PC 300 receives a power remote control command from the VMS operation server 400 as shown in FIG. 4, the received power remote control command is relayed to the DC power supply 200.

In addition, the field monitoring PC 300, in addition to relaying the power remote control command received from the VMS operation server 400 to the DC power supply 200, the DC power supply remote control command directly input by the field manager. It can be implemented to transmit to the supply device 200.

The VMS operation server 400 is connected to the field monitoring PC 300 through wired communication or wireless communication through a wired or wireless communication network. For example, when a wired/wireless communication network is implemented as a wireless communication network, a wireless mobile communication network consisting of a base transceiver station (BTS), a mobile switching center (MSC), and a home location register (HLR) is provided. Can be used to communicate data. In addition, when the wired/wireless communication network is implemented as a wired communication network, it may be implemented as a network communication network, and data communication may be performed according to an Internet protocol such as Transmission Control Protocol/Internet Protocol (TCP/IP).

The VMS operation server 400 monitors the SMPS operation state of the DC power supply 200 received from the field monitoring PC 300, and includes power on, power off, and power reset according to the received SMPS operation state. The power remote control command is transmitted to the on-site monitoring PC (300). That is, the VMS operation server 400 monitors the SMPS operation state and, when an input power abnormality, a ventilation fan abnormality, or a temperature abnormality is detected, generates a matching power remote control command according to the detected abnormality state, and the on-site monitoring PC It will be transmitted to 300.

For example, if current or voltage is not detected as a result of monitoring the input power state among the received SMPS operation states, a power remote control command for power on or power reset is transmitted to the on-site monitoring PC 300. In addition, when the ventilation fan 209 is not driven as a result of monitoring the ventilation fan driving state among the received SMPS operation states, a power remote control command for power on or power reset is transmitted to the on-site monitoring PC 300. In addition, when the heat dissipation fan is overheated as a result of monitoring the heat sink temperature state among the received SMPS operation states, it is recognized as an abnormal operation and a power remote control command for power off may be transmitted to the field monitoring PC 300.

As a result, in the VMS power supply remote control system of the present invention, as shown in FIG. 4, the DC power supply 200 detects the SMPS operation state of the SMPS providing DC driving power to the electric sign 100 Thus, when provided to the field monitoring PC 300, the field monitoring PC 300 relays the SMPS operation status received from the DC power supply 200 to the VMS operation server 400.

The VMS operation server 400 monitors the SMPS operation state of the DC power supply 200 received from the field monitoring PC 300. In addition, a power remote control command including power on, power off, and power reset according to the received SMPS operation state is generated and transmitted to the field monitoring PC 300.

When the field monitoring PC 300 receives a power remote control command from the VMS operation server 400, it relays the received power remote control command to the DC power supply 200.

When the DC power supply 200 receives a power remote control command from the field monitoring PC 300, it performs power control according to the power remote control command received from the field monitoring PC 300.

Therefore, when a minor failure that is solved by turning on/off the DC power supply unit 200 only occurs, the operator can perform power reset and power on/off processing through remote control without dispatching to the site. Manpower and cost can be saved.

5 is a block diagram of a DC power supply according to an embodiment of the present invention.

The DC power supply 200 includes a primary filter 201, a primary rectification module 202, a FET switching module 203, a voltage transformer 204, a secondary rectification module 205, and a secondary filter 206. ), a voltage/current detection module 207, and a control module 208. In addition, it may include a ventilation fan 209 and a heat sink temperature detection module (not shown).

The primary filter 201 noise-filters the AC voltage input from the outside.

The primary-side rectification module 202 rectifies the noise-filtered AC voltage to a DC voltage. For example, AC 220V is rectified with a diode to make the power of DC 300V voltage.

The FET switching module 203 switches a FET (Field Effect Transistor) at a constant frequency and transmits it as an AC voltage to the voltage transformer 204.

The voltage transformer 204 accumulates energy in the primary coil and transfers it to the insulated secondary coil. Accordingly, the FET-switched AC voltage output from the primary-side rectification module 202 is supplied to the primary-side coil and converted into an AC converted voltage, which is the converted power of the secondary-side coil.

The secondary-side rectification module 205 rectifies the AC converted voltage output from the transformer to a DC converted voltage. In other words, the AC converted voltage that has been switched over is rectified with a diode and rectified to the DC converted voltage.

The secondary filter 206 filters noise of the DC converted voltage output from the secondary rectification module 205 and provides it to the voltage/current detection module 207. That is, noise is removed to make the DC conversion current rectified at the secondary side more stable.

The voltage/current detection module 207 detects a voltage level and a current level of DC output from the secondary filter 206.

The control module 208 provides the voltage level and the current level detected by the voltage/current detection module 207 as an input power state to the field monitoring PC 300. For reference, the control module 208 is provided with a separate communication processing means, and the current size and voltage level of the DC conversion voltage are provided as information on the input power status through RS-422 serial communication, USB communication, etc. ).

In addition, the control module 208 performs power control according to a power remote control command received from the field monitoring PC 300. For example, when receiving a power remote control command for power on (ON), the power is turned on, and when a power remote control command for power off (OFF) is received, the power is turned off (OFF), When a power remote control command of power reset (RESET) is received, control to reset power is performed.

In addition, DC power supply 200, DT (210) (Drive Trans), LOAD SHARE (211), OCP (212), OVP (213), voltage feedback (214), PWM IC (215), AUX POWER (216) may be further included.

The DT 210 (Drive Trans) amplifies a small signal and transmits it secondarily.

The LOAD SHARE 211 is a circuit for maintaining constant current sharing with each other when operating several power units in parallel.

The OCP 212 (Over Current Protection) is a circuit that lowers the output voltage in order to eliminate the influence on the load when the DC output current is higher than the rated output current by 130 or more.

OVP (213) (Over Voltage Protection) is a circuit that cuts off the output in order to eliminate the influence on the load when the DC output voltage is higher than the rated output voltage by 110% or more.

The voltage feedback 214 is a circuit that monitors in order to stably maintain the output voltage of the DC output terminal.

The PWM IC 215 is a control IC that controls FET SWITCHING by PWM (Pulse Width Modulation).

The AUX POWER 216 is an auxiliary source circuit that supplies power to the circuit IC inside the Power.

On the other hand, the control module 208 provides the voltage level and the current level detected by the voltage/current detection module 207 as an input power state to the field monitoring PC 300, in addition to the ventilation fan driving state, and the heat sink temperature. The status can be additionally provided to the on-site monitoring PC (300).

To this end, the DC power supply 200 includes a ventilation fan 209 that lowers the temperature of the heat sink, and the control module 208 uses the sensed value of the ventilation fan 209 as information on the driving state of the ventilation fan. It is provided to the field monitoring PC (300).

In addition, the DC power supply 200 includes a heat sink temperature detection module that detects the temperature of the heat sink, and the control module 208 provides the detected heat sink temperature to the on-site monitoring PC 300.

Therefore, the VMS operation server 400 receiving the SMPS operation state including the input power state, the ventilation fan driving state, and the heat sink temperature through the on-site monitoring PC 300 is powered on and off according to the received SMPS operation state. , It is possible to transmit a power remote control command including power reset to the field monitoring PC (300).

On the other hand, when the DC power supply 200 is provided in a plurality of two or more, the VMS operation server 400, the power remote control command that is allocated differently for each DC power supply 200 to each DC power supply ( 200).

To this end, when a plurality of DC power supply devices 200 are provided, each DC power supply device 200 is assigned a unique address address. Accordingly, the field monitoring PC 300 transmits the SMPS operation status to the field monitoring PC 300 together with the unique address address of the DC power supply 200, and the VMS operation server 400 supplies DC power to be remotely controlled. It is implemented to transmit a power remote control command along with the unique address of the device 200.

Furthermore, when a plurality of DC power supply devices 200 are provided, each DC power supply device 200 may need to be sequentially controlled for power. For example, when a part of the electric light sign 100 is to be restored with priority, it is necessary to provide remote power control as the highest priority. To this end, the VMS operation server 400 gives priority to each DC power supply 200, and power remote control so that each DC power supply 200 sequentially controls power based on the priority. Send the command.

As a result, the present invention having the above configuration detects an abnormal state of the power supply unit and an output voltage and an output current, and detects an abnormal temperature, an input power abnormality, and an abnormality of the ventilation fan 209 (FAN). Up to 50 logs can be stored and transmitted to the on-site monitoring PC 300 using RS-422 communication. By setting an address for each DC power supply 200 (SMPS), it is possible to simultaneously control and manage remotely from one computer. In addition, it is possible to turn ON/OFF the output power of the DC power supply 200 by issuing a command from the control computer (PC).

The embodiments in the description of the present invention described above are presented by selecting the most preferable examples to aid the understanding of those skilled in the art from among various possible examples, and the technical idea of the present invention is not necessarily limited or limited only by this embodiment. , Various changes and modifications, and other equivalent embodiments are possible within the scope of the technical spirit of the present invention.

100: electric sign
200: DC power supply
300: On-site monitoring PC
400: VMS operation server

Claims (9)

An electric sign that displays traffic information;
As an SMPS providing DC-type driving power to the electric sign, a DC power supply device that senses the SMPS operation state and provides it to a field monitoring PC, and performs power control according to a power remote control command received from the field monitoring PC;
Field monitoring that relays the SMPS operation status received from the DC power supply to the VMS operation server, and relays the received power remote control command to the DC power supply when a power remote control command is received from the VMS operation server PC; And
VMS that monitors the SMPS operation status of the DC power supply received from the on-site monitoring PC, and transmits a power remote control command including power on, power off, and power reset according to the received SMPS operation status to the on-site monitoring PC Includes an operational server,
A plurality of DC power supplies are mapped to one electric sign, and a plurality of DC power supplies are connected to one field monitoring PC.
Each DC power supply is assigned a unique address and transmits and receives data to and from the VMS operation server using the assigned unique address,
The VMS operation server gives priority of power control to each DC power supply, and the VMS operation server of the DC power supply allows each DC power supply to sequentially control power based on the priority. Power supply remote control system for VMS, characterized in that it transmits a power remote control command using a unique address.
The method according to claim 1,
The SMPS operation state includes an input power state, a ventilation fan driving state, and a heat sink temperature state,
The VMS operation server monitors the SMPS operation state and, when an input power error, a ventilation fan error, or a temperature error is detected, generates a matching power remote control command according to the detected abnormal state, and transmits the VMS to the field monitoring PC. Power supply remote control system.
The method according to claim 2, wherein the DC power supply,
A primary-side rectification module for rectifying an AC voltage input from the outside into a DC voltage;
FET switching module for FET switching the DC voltage output from the primary rectification module to output AC;
A voltage transformer that supplies the AC voltage output from the FET switching module to a primary coil and converts it into an AC converted voltage that is converted power of the secondary coil;
A secondary-side rectification module rectifying an AC converted voltage output from the voltage transformer to a DC converted voltage;
A voltage/current detection module for detecting a voltage level and a current level output from the secondary rectification module; And
A control module that provides a voltage level and a current level detected by the voltage/current detection module as the input power state to the field monitoring PC, and performs power control according to a power remote control command received from the field monitoring PC;
Power supply remote control system for VMS including a.
The method of claim 3, wherein the DC power supply,
A primary filter filtering the AC voltage input from the outside and providing it to the primary rectification module; And
A secondary-side filter filtering noise of the DC conversion voltage output from the secondary-side rectification module and transferring the noise to a voltage/current detection module;
Power supply remote control system for VMS including a.
The method of claim 3, wherein the DC power supply,
Includes; a ventilation fan to lower the temperature of the heat sink,
The control module is a power supply remote control system for VMS, characterized in that the sensing value of the ventilation fan is provided to the on-site monitoring PC as information on a ventilation fan driving state.
The method of claim 5, wherein the DC power supply,
Includes; a heat sink temperature detection module for detecting the temperature of the heat sink,
The control module is a power supply remote control system for VMS, characterized in that providing the detected heat sink temperature to the field monitoring PC.
The method according to claim 1,
The on-site monitoring PC transmits the SMPS operation status to the on-site monitoring PC together with the unique address address of the DC power supply,
The VMS operation server transmits a power remote control command along with a unique address address of a DC power supply to be remotely controlled.
delete The method of claim 1, wherein the field monitoring PC,
Power supply remote control system for VMS that transmits power remote control command directly input by the site manager to DC power supply.

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