CN113507774A - Centralized control type fire-fighting indicator lamp debugging method - Google Patents

Abstract

The application discloses a centralized control type fire-fighting indicator lamp debugging method, after a user arrives at a construction site, lamps are installed in a plurality of places of the construction site, firstly, the user holds a remote controller and aims at one of the lamps, the lamps acquire the types of the lamps such as an emergency indicator lamp and an address code of the emergency indicator lamp through infrared bidirectional communication, secondly, information is sent to a base map of mobile equipment, a graph of the emergency indicator lamp can be generated at the base map, therefore, all lamp information of the site can be quickly input into the base map, in addition, the information of the base map and the lamps is sent to a master control console together, finally, a constructor can start or close the emergency indicator lamp on the base map at the master control console to complete debugging, centralized control is realized, and therefore, the constructor can quickly input, the centralized control method is convenient to use, and time and labor are saved. Compared with the existing coding mode, the production efficiency can be greatly improved, and the labor intensity of workers is reduced. The invention has higher integration and compatibility flexibility.

Description

Centralized control type fire-fighting indicator lamp debugging method

Technical Field

The invention relates to the field of fire emergency, in particular to a centralized control type fire-fighting indicator lamp debugging method.

Background

The construction personnel install multiple emergency lamps in different positions on the spot, the old read-write scheme is to determine the address code of the lamp in a pre-written mode, the lamp needs to communicate with the lamp through a PC end or a special terminal device and a special tool, and the lamp needs to be hung on the read-write device independently for communication, so that the practical use is very troublesome, the construction site is not suitable for use at all, and mistakes are easy to occur if thousands of emergency lamps exist on the spot.

Disclosure of Invention

In order to solve the problems, the technical scheme provides a centralized control type fire-fighting indicator lamp debugging method which can be used for rapidly communicating with an emergency lamp to obtain an address code of the lamp and uploading the address code to a PC (personal computer).

In order to achieve the purpose, the technical scheme is as follows:

the centralized control type fire-fighting indicator lamp debugging method is realized in the following modules;

remote controller: the system is used for infrared bidirectional communication to obtain the address code and the type of the lamp to be tested or used for recording the address code for the lamp to be tested;

a mobile device: the remote controller is in communication connection with the remote controller and is used for recording a base map of the architectural design in advance, confirming the actual installation position of the lamp on site, marking a virtual lamp mark on a corresponding area on the base map, and recording the type and the address code of the lamp to be tested on the lamp mark through the remote controller;

a master control console: the system is in communication connection with the mobile equipment, is used for acquiring a base map, the type of a lamp to be tested and an address code of the lamp to be tested, which are recorded by the mobile equipment, is also connected with the lamp to be tested through two bus communications, and is used for intensively controlling the lamp to be tested on site to finish on-off debugging;

based on the equipment, the debugging steps are as follows;

a: holding the mobile equipment to confirm the position of the on-site lamp to be detected;

b: the remote controller is used for recording an address code for the lamp to be tested through infrared bidirectional communication or automatically distributing the address code for the lamp to be tested through the master console;

c: acquiring an address code of the lamp to be tested and a type corresponding to the lamp to be tested by the remote controller through infrared bidirectional communication;

d: the remote controller is communicated with the mobile equipment, virtual lamp marks are marked at the installation positions of the base map of the architectural design corresponding to the actual field lamps, and the types and address codes of the lamps to be tested are obtained from the lamp marks;

e: the mobile equipment communicates with the master control station, and transmits the base map, the lamp marks on the base map, the address codes of the lamps to be tested and the types of the lamps to be tested to the master control station, so that the master control station can obtain the base map which is consistent with the site and is provided with the lamps;

f: the master control console communicates with each on-site lamp to be tested through two buses, and the lamp mark of the master control console is clicked to open or close the corresponding lamp on the base map for on-off debugging, so that whether the installation position of the lamp to be tested is correct or whether the lamp to be tested works normally is judged.

The application provides a centralized control type fire-fighting indicator lamp debugging method, after a user arrives at a construction site, a plurality of places of the construction site are provided with a geographical lamp, an emergency indicator lamp and a marker lamp, firstly, the user holds a remote controller to aim at one lamp, the lamp acquires the type of the lamp, such as the emergency indicator lamp and an address code of the emergency indicator lamp through infrared bidirectional communication, or automatically allocates the address code to the tested lamp through a master control console, then, the information is sent to a base map of mobile equipment, a mark of the emergency indicator lamp can be virtualized at the base map, therefore, all lamp information of the site can be rapidly recorded on the base map, the base map and the information of the lamp can be sent to the master control console together, finally, a constructor can click the mark at the master control console to turn on or turn off the emergency indicator lamp on the base map to complete debugging, and realize centralized control, therefore, constructors can quickly input the information, and the method is convenient to use, time-saving and labor-saving. Compared with the existing coding mode, the production efficiency can be greatly improved, and the labor intensity of workers is reduced. The invention has higher integration and compatibility flexibility.

In some embodiments, the method further includes a step g of sending a control command to the control display panel according to an operation command of a user, so that the main control circuit in the console receives the corresponding command and sends a control signal and a voltage to the lamp through two bus communications.

In some embodiments, step g includes the following modules:

the lamp comprises a routing board and routing cards, wherein the routing board is connected with a main control circuit through two buses in a communication mode, and the routing board is connected with 1-4 routing cards to receive control instructions of the main control circuit and output the control instructions to a lamp to turn on or turn off the lamp after the control instructions are integrated on the two buses.

In some embodiments, the routing board is further in communication with the centralized power control display board through 485 communication to reflect the working state of the centralized power in real time.

In some embodiments, step c includes the following modules: the remote controller circuit and the lamp receiving and transmitting circuit are communicated with the remote controller circuit;

the method comprises the following implementation steps:

in the remote controller circuit, the master control U1 sends a signal to the triode Q3, the voltage flows through the light emitting diode D3 and the triode Q3 and is grounded, and the light emitting diode D3 emits infrared light;

in the lamp transceiver circuit, the infrared sensor at the terminal H5 receives the infrared light of the led D3 and feeds back the infrared light to the main control U3, the main control U3 sends a signal to the transistor Q3, the voltage flows through the led D8 and the transistor Q3 and then is grounded, and the led D8 emits the infrared light;

in the remote controller circuit, the infrared sensor on the terminal H2 receives the infrared light of the led D8 and feeds back the infrared light to the main control U1, so that the remote controller can perform infrared two-way communication with the lamp.

In some embodiments, the remote controller circuit further comprises a plurality of keys, and the keys are turned on to trigger functions corresponding to the keys;

the infrared bidirectional communication method comprises the following steps:

when the key is not turned on, the voltage flows through the resistor R13 to the main control U1;

when the key is turned on, voltage flows through the resistor R13 to ground through the key S5, the voltage received by the master control U1 is reduced, communication is started, and a command is sent to the triode Q3.

In some embodiments, the step d sends the type and the address code of the lamp to be tested to the mobile device through bluetooth communication;

the method comprises the following steps:

the master control U1 sends a command to the triode Q5, the voltage flows through the triode Q5 to the terminal P2, and the terminal P2 is connected with Bluetooth communication equipment;

the TXD and RXD pins of the Bluetooth communication equipment are connected with the master control U1 so as to send the type and the address code of the tested lamp stored in the master control U1 to the mobile equipment;

the mobile equipment records the type and the address code of the lamp in the construction base map.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below.

FIG. 1 is a schematic flow diagram of the present invention;

FIG. 2 is a schematic block diagram of the present invention;

FIG. 3 is a schematic diagram of a lamp transceiver circuit according to the present invention;

FIG. 4 is a schematic diagram of the remote controller circuit structure of the present invention;

FIG. 5 is a schematic diagram of the circuit configuration of the routing board of the present invention;

FIG. 6 is a circuit diagram of the routing card of the present invention;

FIG. 7 is a schematic diagram of a master control circuit according to the present invention;

fig. 8 is a schematic diagram of the circuit structure of the centralized power control display of the present invention.

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects solved by the present invention more clearly apparent, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Referring to fig. 1 to 8, a centralized control type fire indicator debugging method is implemented in the following modules;

remote controller: the system is used for infrared bidirectional communication to obtain the address code and the type of the lamp to be tested or used for recording the address code for the lamp to be tested; the type of the lamp to be detected is self-contained, if the lamp is a geographical lamp, a virtual mark of the geographical lamp appears after the lamp is obtained;

a mobile device: the remote controller is in communication connection with the remote controller and is used for recording a base map of the architectural design in advance, confirming the actual installation position of the lamp on site, marking a virtual lamp mark on a corresponding area on the base map, and recording the type and the address code of the lamp to be tested on the lamp mark through the remote controller;

a master control console: the system is in communication connection with the mobile equipment, is used for acquiring a base map, the type of a lamp to be tested and an address code of the lamp to be tested, which are recorded by the mobile equipment, is also connected with the lamp to be tested through two bus communications, and is used for intensively controlling the lamp to be tested on site to finish on-off debugging;

based on the modules, the centralized control type fire-fighting indicator lamp debugging method comprises the following steps;

a: holding the mobile equipment to confirm the position of the on-site lamp to be detected;

b: the remote controller is used for recording an address code for the lamp to be tested through infrared bidirectional communication or automatically distributing the address code for the lamp to be tested through the master console;

c: acquiring an address code of the lamp to be tested and a type corresponding to the lamp to be tested by the remote controller through infrared bidirectional communication;

d: the remote controller is communicated with the mobile equipment, virtual lamp marks are marked at the installation positions of the base map of the architectural design corresponding to the actual field lamps, and the types and address codes of the lamps to be tested are obtained from the lamp marks;

e: the mobile equipment communicates with the master control station, and transmits the base map, the lamp marks on the base map, the address codes of the lamps to be tested and the types of the lamps to be tested to the master control station, so that the master control station can obtain the base map which is consistent with the site and is provided with the lamps;

f: the master control console communicates with each on-site lamp to be tested through two buses, and the lamp mark of the master control console is clicked to open or close the corresponding lamp on the base map for on-off debugging, so that whether the installation position of the lamp to be tested is correct or whether the lamp to be tested works normally is judged.

The application provides a centralized control type fire-fighting indicator lamp debugging method, after a user arrives at a construction site, geographic lamps, emergency indicator lamps and marker lamps are installed in a plurality of places of the construction site, the user firstly holds a remote controller to aim at one lamp, the lamp acquires the type of the lamp, such as the emergency indicator lamp and the address code of the emergency indicator lamp through infrared bidirectional communication, or the address code can be automatically distributed to the lamp from a master control console and then read, then the information is sent to a base map of mobile equipment, a mark of the emergency indicator lamp can be virtualized at the lamp installation position of the base map and marked as a shape graph of each lamp, all lamp information on the site can be rapidly recorded on the base map, then the base map and the information of the lamps are sent to the master control console together, and finally a constructor can click the mark of the lamp to turn on or turn off the emergency indicator lamp on the base map to finish debugging, can judge whether lamps and lanterns can normally work and whether the mounted position of lighting the back and instructing at the base map realizes centralized control, and constructor just can type into fast like this, convenient to use, labour saving and time saving. Compared with the existing coding mode, the production efficiency can be greatly improved, and the labor intensity of workers is reduced. The invention has higher integration and compatibility flexibility.

In this embodiment, a plurality of keys are arranged in the remote controller circuit, for example, a read/write code is taken, VCC flows through the single chip microcomputer U1 through the resistor R10, when the key of the read/write code is triggered, VCC is grounded through the resistor R10, so that the pin voltage of the single chip microcomputer U1 is reduced, the read/write code mode is turned on, after the infrared bidirectional communication protocol is established, the remote controller circuit can record an address code or obtain the address code for a lamp, and the address code does not need to be recorded when the lamp leaves a factory.

In this embodiment, after the remote controller establishes infrared communication with the lamp, the main control single chip microcomputer U1 of the remote controller sends different high levels and low levels to define an address code to be received by the lamp, so that the lamp writes in a specific address code, and then obtains the address code to store, so that the remote controller has the address code of the lamp and the type of the lamp.

In this embodiment, step g includes the following modules: the lamp comprises a routing board and routing cards which are connected with a main control circuit through two bus communication, wherein 1-4 routing cards are connected on the routing board to receive a control instruction of the main control circuit and output the control instruction to a lamp to turn on or turn off the lamp after the control instruction is integrated on two buses, concretely, the main control circuit 4 comprises a first two-bus communication transceiver module 41, a communication conversion module 42 and an isolation module 43, the communication conversion module 42 comprises a terminal P10 connected with the control display panel 5 and a terminal P11 connected with the isolation module 43, and further comprises a conversion main control IC3 arranged between the terminal P10 and the terminal P11, so that the conversion main control IC3 receives a signal for controlling the display panel 5 and converts the signal into a signal which can be read by the first two-bus communication transceiver module 41, the isolation module 43 comprises an optical coupler OPY4 and an optical coupler OPY6, so that the output end of the communication conversion module 42 controls the first two-bus communication transceiver module 41 through the optical coupler, the first two-bus communication transceiver module 41 integrates and outputs the received voltage and signal to the routing circuit 3, specifically, the master IC3 is SP232, one side of the master IC is provided with a terminal P10 through a resistor R45 and a resistor R46, and is connected to a console with a control display panel, the other side of the master IC is provided with a terminal P11 through a resistor R29 and a resistor R30, and converts the android signal of the console into a lower computer readable signal, meanwhile, pins 9-12 of the IC3 are communicated with the opto-coupler to control the output signal to MOUDLF1 through the isolation and level conversion of the opto-coupler, at this time, the MOS transistor Q2 and the MOS transistor Q4 and the transistor T2 and the transistor T4 are turned on, V1+ of the integrated signal is modulated and then output to the bus, the power bus manner is adopted, two buses with voltage and signal are output at an OUT1 terminal, and an OUT2 terminal are the same, the master IC circuit 4 further comprises an indication circuit 44 and a single chip U1, the single chip indication circuit comprises a T11 connected with the single chip 1, the emitter of the triode T11 is grounded, the collector is provided with a triode T5, the emitter of the triode T5 is connected with the collector of the triode T11 through a resistor R52, the emitter of the triode T5 also inputs a voltage, the collector is connected with the singlechip U1, an indicating circuit has an alarm function, a fault indicating function, an emergency function and a power supply function, taking alarm as an example, when the pin 24 of the singlechip U1 is not output, V + conducts the triode T5 through a resistor R52 and a resistor R31, V + flows through a terminal P3 from the emitter to the collector of the triode through a resistor R48 to be output, an alarm mode is started, when the pin 24 is output, the triode T11 is conducted, V + is conducted from the triode T11 to the ground, the triode T5 is disconnected, the alarm mode is closed, the singlechip U1 is connected with a mains supply relay and a battery relay, the corresponding power supply mode is started by sending a signal to conduct the triode T9 or the triode T10, the single chip microcomputer U1 is further provided with a serial communication circuit composed of an IC1, an IC2, an OPY2 and an OPY1, the lamp transceiver circuit 1 comprises a receiving input terminal P1, the main control circuit 4 outputs voltage to the receiving input terminal P1 through the routing circuit 3, the receiving input terminal P1 is connected with a power signal demodulation circuit unit 101 to output voltage for supplying power to the lamp transceiver circuit 1, the lamp central information processing control unit U3 is further included, the central information processing control unit U3 is connected with a triode Q3, a collector of the triode Q3 is connected with a light emitting diode D8 and inputs voltage, an emitter is grounded, the central information processing control unit U3 is further connected with a plug-in terminal H5 for connecting an infrared sensor, voltage output by a bus flows through the power signal demodulation circuit unit to generate voltage VCC, when the central information processing control unit U3 sends signals, the triode Q3 is conducted, VCC flows through the light emitting diode D8, the resistor R24 and the triode Q3 and is grounded, at the moment, the light emitting diode D8 emits infrared light, the terminal H2 with the infrared sensor of the remote controller receives the infrared light and outputs the infrared light to the single chip microcomputer U1 from the pin 3, similarly, the light emitting diode D3 also sends the infrared light to the infrared sensor on the terminal H5 of the lamp for receiving, so that the lamp and the remote controller are in infrared two-way communication, and the address code, the specification information and the like of the lamp are obtained.

In this embodiment, the main control circuit receives a corresponding command and sends a control signal and a voltage to the lamp through two-bus communication, and the lamp includes a routing board and a routing card connected with the main control circuit through two-bus communication, the routing board is connected with 1-4 routing cards to receive the control command of the main control circuit, and outputs the control command to the lamp to turn on or turn off the lamp through two buses after integrating the control command, the routing card 31 is provided with a third two-bus communication transceiver module 33 to output the voltage and the signal received by the second two-bus communication transceiver module 62 to the emergency lamp to be tested, the voltage is modulated and output through two buses by using the POWERBUS principle, and the terminals P13, P12, P7 and P8 of the routing board can be plugged with four routing cards.

In this embodiment, the routing board is further in communication with the centralized power supply control display board through 485 communication to reflect the working state in real time, the centralized power supply control display circuit 6 comprises a single-chip microcomputer U9, the single-chip microcomputer U9 is connected with a second bus communication transceiving module 62, an EPS communication isolation module 43 and a 485 communication module 63 to be used by a user selectively, and is further connected with a screen interface P12 used for being connected with a liquid crystal screen, so that various communication modes are provided for the user to select and use, and the working state of the centralized power supply is reflected in real time through the liquid crystal screen.

In the embodiment, the address code and the type of the lamp to be detected are acquired by the remote controller through infrared bidirectional communication, and the communication is realized through the remote controller circuit and the lamp transceiver circuit, wherein in the remote controller circuit, the master control U1 sends a signal to the triode Q3, the voltage is grounded through the light emitting diode D3 and the triode Q3, and the light emitting diode D3 emits infrared light;

in the lamp transceiver circuit, the infrared sensor at the terminal H5 receives the infrared light of the led D3 and feeds back the infrared light to the main control U3, the main control U3 sends a signal to the transistor Q3, the voltage flows through the led D8 and the transistor Q3 and then is grounded, and the led D8 emits the infrared light;

in the remote controller circuit, the infrared sensor on the terminal H2 receives the infrared light of the led D8 and feeds back the infrared light to the main control U1, so that the remote controller can perform infrared two-way communication with the lamp.

In this embodiment, the infrared bidirectional communication further includes a plurality of keys on the remote controller circuit, the keys are turned on to trigger functions corresponding to the keys, the key functions include key (add), key (subtract), confirm sending, code reading and writing, communication (infrared or serial port), and type status of the door sensor module, taking the communication keys as an example;

when the key is not turned on, the voltage flows through the resistor R13 to the main control U1;

when the key is turned on, voltage flows through the resistor R13 to the ground through the key S5, the voltage received by the main control U1 is reduced, the communication module is started, an instruction is sent to the triode Q3, and infrared bidirectional communication is started.

In the embodiment, the steps are that a base map of a construction site is recorded in advance in the mobile equipment, the type and the address code of the lamp to be tested are recorded on the base map, and the type and the address code of the lamp to be tested are sent to the mobile equipment through Bluetooth communication;

the master control U1 sends a command to the triode Q5, the voltage flows through the triode Q5 to the terminal P2, and the terminal P2 is connected with Bluetooth communication equipment;

the TXD and RXD pins of the Bluetooth communication equipment are connected with the master control U1 so as to send the type and the address code of the tested lamp stored in the master control U1 to the mobile equipment;

the mobile equipment records the type and the address code of the lamp in the construction base map.

The above description is only for the purpose of illustrating the preferred embodiments of the present application and is not intended to limit the scope of the present application, which is within the scope of the present application, except that the same or similar principles and basic structures as the present application may be used.

Claims (7)

1. A centralized control type fire-fighting indicator lamp debugging method is characterized in that: comprises the following steps of;

remote controller: the system is used for infrared bidirectional communication to obtain the address code and the type of the lamp to be tested or used for recording the address code for the lamp to be tested;

a mobile device: the remote controller is in communication connection with the remote controller and is used for recording a base map of the architectural design in advance, confirming the actual installation position of the lamp on site, marking a virtual lamp mark on a corresponding area on the base map, and recording the type and the address code of the lamp to be tested on the lamp mark through the remote controller;

a master control console: the system is in communication connection with the mobile equipment, is used for acquiring a base map, the type of a lamp to be tested and an address code of the lamp to be tested, which are recorded by the mobile equipment, is also connected with the lamp to be tested through two bus communications, and is used for intensively controlling the lamp to be tested on site to finish on-off debugging;

based on the equipment, the debugging steps are as follows;

a: holding the mobile equipment to confirm the position of the on-site lamp to be detected;

b: the remote controller is used for recording an address code for the lamp to be tested through infrared bidirectional communication or automatically distributing the address code for the lamp to be tested through the master console;

c: acquiring an address code of the lamp to be tested and a type corresponding to the lamp to be tested by the remote controller through infrared bidirectional communication;

d: the remote controller is communicated with the mobile equipment, virtual lamp marks are marked at the installation positions of the base map of the architectural design corresponding to the actual field lamps, and the types and address codes of the lamps to be tested are obtained from the lamp marks;

e: the mobile equipment communicates with the master control station, and transmits the base map, the lamp marks on the base map, the address codes of the lamps to be tested and the types of the lamps to be tested to the master control station, so that the master control station can obtain the base map which is consistent with the site and is provided with the lamps;

f: the master control console communicates with each on-site lamp to be tested through two buses, and the lamp mark of the master control console is clicked to open or close the corresponding lamp on the base map for on-off debugging, so that whether the installation position of the lamp to be tested is correct or whether the lamp to be tested works normally is judged.

2. The centralized control fire fighting indicator lamp debugging method according to claim 1, characterized in that: and g, sending a control instruction on the control display panel according to an operation instruction of a user so that a main control circuit in the master control console receives the corresponding instruction and sends a control signal and voltage to the lamp through two bus communication.

3. The centralized control fire fighting indicator lamp debugging method according to claim 2, characterized in that: step g comprises the following modules:

the lamp comprises a routing board and routing cards, wherein the routing board is connected with a main control circuit through two buses in a communication mode, and the routing board is connected with 1-4 routing cards to receive control instructions of the main control circuit and output the control instructions to a lamp to turn on or turn off the lamp after the control instructions are integrated on the two buses.

4. The centralized control fire fighting indicator lamp debugging method according to claim 3, characterized in that: the routing board is also communicated with the centralized power supply control display board through 485 communication, and the working state of the centralized power supply is reflected in real time.

5. The centralized control fire fighting indicator lamp debugging method according to claim 1, characterized in that: step c includes the following modules: the remote controller circuit and the lamp receiving and transmitting circuit are communicated with the remote controller circuit;

the method comprises the following implementation steps:

in the remote controller circuit, the master control U1 sends a signal to the triode Q3, the voltage flows through the light emitting diode D3 and the triode Q3 and is grounded, and the light emitting diode D3 emits infrared light;

in the lamp transceiver circuit, the infrared sensor at the terminal H5 receives the infrared light of the led D3 and feeds back the infrared light to the main control U3, the main control U3 sends a signal to the transistor Q3, the voltage flows through the led D8 and the transistor Q3 and then is grounded, and the led D8 emits the infrared light;

in the remote controller circuit, the infrared sensor on the terminal H2 receives the infrared light of the led D8 and feeds back the infrared light to the main control U1, so that the remote controller can perform infrared two-way communication with the lamp.

6. The centralized control fire fighting indicator lamp debugging method according to claim 5, characterized in that: the remote controller circuit also comprises a plurality of keys, and the keys are conducted to trigger the corresponding functions of the keys;

the infrared bidirectional communication method comprises the following steps:

when the key is not turned on, the voltage flows through the resistor R13 to the main control U1;

when the key is turned on, voltage flows through the resistor R13 to ground through the key S5, the voltage received by the master control U1 is reduced, communication is started, and a command is sent to the triode Q3.

7. The centralized control fire fighting indicator lamp debugging method according to claim 6, characterized in that: d, transmitting the type and the address code of the lamp to be tested into the mobile equipment through Bluetooth communication;

the method comprises the following steps:

the master control U1 sends a command to the triode Q5, the voltage flows through the triode Q5 to the terminal P2, and the terminal P2 is connected with Bluetooth communication equipment;

the TXD and RXD pins of the Bluetooth communication equipment are connected with the master control U1 so as to send the type and the address code of the tested lamp stored in the master control U1 to the mobile equipment;

the mobile equipment records the type and the address code of the lamp in the construction base map.

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