RU193876U1 - RADIO CHANNEL EXPANDER - Google Patents

Abstract

The utility model relates to the field of fire alarms and is intended to amplify the signal received from fire alarms connected via the CAN (Controller Area Network) interface and to further relay it over a wireless network at a frequency of 868 MHz to a fire alarm control panel. Technical problem, the solution of which is provided by implementing the utility model, is to relay data transmitted via the CAN interface in a wireless network at a frequency of 868 MHz. The technical problem is solved by the fact that radio channel extender having a power supply with galvanic isolation 6, the power controller 5, a microprocessor 2, the display circuit 3 CAN interface 1, the input power source 4 further introduced transceiver encoder 7 and 8 to a frequency of 868 MHz.

Description

The utility model relates to the field of fire alarm and is intended to amplify the signal received from the fire alarm equipment connected via the CAN (Controller Area Network) interface and its further relaying over the wireless network at a frequency of 868 MHz.

The prior art block extension loop signaling radio channel "Ladoga BRSHS-RK", various interface repeaters included in the alarm system [http://www.industrialnets.ru/can-hub-repeater]; [https://icp-das.ru/catalog/i-2534]; [http://www.industrialnets.ru/ anybus-com-can-cc-link-slave]. Typically, such devices consist of a microprocessor, CAN input and output interface, display circuit, input power supply, power controller, galvanically isolated power supply.

A known electronic device for protecting a vehicle from theft (patent for utility model RU 108337 U1), including a microcontroller, a data processing unit from the CAN bus, an electromechanical relay, an accelerometer.

Closest to the claimed device and selected as a prototype is a repeater of interfaces 1-5534-M (Industrial 4-port CAN bus switch, metal case), containing a galvanically isolated power supply, transformer, microprocessor, display circuit, switch, RS interface -232, CAN interface, input power supply, while the four inputs of the galvanically isolated power source are connected to the four inputs of the transformer and connected to a three-phase electrical network, the output of the power source is galvanic decoupling is connected to the first input of the microprocessor, the first output of which is connected to the display circuit, the second input of the microprocessor is connected to the first input of the RS-485 interface, the first input of the CAN interface, the output of the input power source, the third input of the microprocessor is connected to the first output of the switch, the second output of which connected to the second input of the RS-485 interface, and the third output connected to the second input of the CAN interface.

The disadvantage of the prototype is the inability to transmit CAN interface data over wireless networks.

The technical problem that can be solved by implementing the utility model is to relay data transmitted via the CAN interface in a wireless network at a frequency of 868 MHz.

The technical problem is solved in that a radio channel expander containing a galvanically isolated power supply, a power controller, a microprocessor, an indication circuit, a CAN interface, an input power source, while the four galvanically isolated power supply inputs are connected to a three-phase electrical network, the second microprocessor output connected to the display circuit, the second input of the microprocessor is connected to the first input of the CAN interface, an encoder and a transceiver for a frequency of 868 MHz are additionally introduced. In this case, the output of the galvanically isolated power source is connected to the first input of the power controller. The output of the input power source is connected to the second input of the power controller, the output of which is connected to the second input of the CAN interface, the first input of the microprocessor, the first input of the encoder, the first input of the transceiver at a frequency of 868 MHz. The first output of the microprocessor is connected to the second input of the encoder, the output of which is connected to the second input of the transceiver at a frequency of 868 MHz. The first output of the CAN interface is the output for connecting to the CAN bus.

The utility model is illustrated by a figure, which shows a block diagram of the proposed device, which includes a CAN 1 interface, a microprocessor 2, an indication circuit 3, an input power source 4, a power controller 5, a power source with galvanic isolation 6, an encoder 7, a transceiver 8 at a frequency of 868 MHz.

In this case, the four inputs of the power supply with galvanic isolation 6 are connected to a three-phase electrical network, the second output of microprocessor 2 is connected to the indicating circuit 3, the second input of microprocessor 2 is connected to the first input of CAN 1, the output of the power supply with galvanic isolation 6 is connected to the first input of the controller 5, the output of the input power source 4 is connected to the second input of the power controller 5, the output of which is connected to the second input of the CAN 1 interface, the first input of microprocessor 2, the first input of the cipher RA 7, the first input of the transceiver 8 interface at a frequency of 868 MHz, the first output of the microprocessor 2 is connected to the second input of the encoder 7, the output of which is connected to the second input of the transceiver 8 at a frequency of 868 MHz, the first output of the CAN 1 interface is an output for connection to the CAN bus.

At the initial stage, the radio channel expander is identified in the fire alarm system, for which it is installed in one of the rooms, the galvanically isolated power supply 6 is connected to a three-phase electrical network to supply power to the device from an external network, the connection with the control panel and fire control -analogue is carried out through a wireless network through a transceiver 8 at a frequency of 868 MHz.

After the identification process, the necessary fire alarm sensors are connected to the CAN 1 interface, an indication circuit 3 is triggered, which displays the current state of the sensor (on, off, no signal).

The object is included in the fire alarm system and, for example, a fire sensor is triggered, the signal from the sensor is input to the CAN 1 interface, the signal is converted to a microprocessor 2 that is convenient for operation. After conversion, the signal from the first input of the CAN 1 interface is fed to the second input of the microprocessor 2 Microprocessor 2 analyzes the received signal and, in accordance with a given program, generates a signal about the state of the system, then the generated signal is transmitted from the first output of microprocessor 2 to the second in od encoder 7. Encoder using an algorithm encrypts the input signal. After the encryption process, the received signal from the second output of the encoder 7 is fed to the second input of the transceiver 8, from where a wireless address and analog fire alarm is transmitted to the device via a wireless network at a frequency of 868 MHz.

In case of loss of external power, the power controller 5 is activated, which automatically switches the radio channel expander to the input power source 4, the display circuit 3 displays the absence of external power.

A new set of essential features allows to achieve a technical result, which consists in ensuring the retransmission of data transmitted via the CAN interface in a wireless network at a frequency of 868 MHz.

The analysis of the prior art allowed us to establish that analogues, characterized by a combination of features that are identical to all the features of the claimed radio channel expander, are absent. Therefore, the claimed utility model meets the condition of patentability “novelty”.

Claims (1)

A radio channel expander containing a galvanically isolated power supply, a power controller, a microprocessor, an indication circuit, a CAN interface, an input power source, while the four galvanically isolated power supply inputs are connected to a three-phase electrical network, the second microprocessor output is connected to the indication circuit, and the second input the microprocessor is connected to the first input of the CAN interface, an encoder and a transceiver at a frequency of 868 MHz are additionally introduced, while the output of the power source is galvanically isolated which is connected to the first input of the power controller, the output of the input power source is connected to the second input of the power controller, the output of which is connected to the second input of the CAN interface, the first input of the microprocessor, the first input of the encoder, the first input of the transceiver at a frequency of 868 MHz, the first output of the microprocessor is connected to the second the input of the encoder, the output of which is connected to the second input of the transceiver at a frequency of 868 MHz, the first output of the CAN interface is an output for connecting to the CAN bus.

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