RU78345U1 - OPTICAL FIRE DETECTOR - Google Patents

Abstract

The invention relates to fire alarm devices, namely to optical fire detectors, and can be used to detect fire in enclosed spaces of various buildings, structures, as well as in various open objects. The objective of the invention is to increase the detection efficiency of the source of ignition by expanding the range of signals perceived by the device from the source of ignition and increasing the noise immunity of the device. The matching circuit 3 of the infrared sensor 1 consists of a program-controlled amplifier 6, an analog-to-digital converter 7, a digital-to-analog converter 8, and a program-controlled divider, consisting of a program-controlled resistor 9 and a constant resistor 10. The input of the constant resistor 10 is connected to the output digital-to-analog converter 8, and its output is with a negative input of a program-controlled amplifier 6. The first input of a program-controlled resistor 9 is connected to the output of a program-controlled amplifier 6, w the swarm input is with the output of the control microprocessor 5, and its output is with the negative input of the program-controlled amplifier 6. The input of the analog-to-digital converter 7 is connected to the output of the program-controlled amplifier 6, the output is with the input of the control microprocessor 5, and the input is digital-analog the transducer 8 is connected to the output of the control microprocessor 5. 1 npf, 2 zpf, 1 ill.

Description

The utility model relates to fire alarm devices, namely to optical fire detectors, and can be used to detect fire in enclosed spaces of various buildings, structures, as well as in various open objects.

An optical fire detector is known that contains infrared and ultraviolet radiation sensors and a control microprocessor with a built-in analog-to-digital converter, while the infrared radiation sensor is connected via a normalization amplifier and the ultraviolet radiation sensor is connected to the microprocessor through a matching circuit (see IPES Fire Detector, website http : //www.intes.spb.ru/ipes.htm).

The known solution is characterized by a narrow dynamic range of perceived signals, due to the lack of automatic control of its sensitivity, which reduces the efficiency of detection of a fire source and limits its scope.

The closest technical solution to the claimed one is an optical fire detector containing a video surveillance unit, infrared and ultraviolet radiation sensors, the outputs of which are connected via a matching circuit to a control microprocessor, while the matching circuit of the infrared sensor consists of a program-controlled amplifier, an analog-to-digital converter, and a digital-to-digital -analog converter (see RF patent No. 522227 for a utility model, IPC OO8V 17/12, publ. March 10, 2006).

The known solution has not sufficiently high noise immunity with respect to the natural thermal background, as well as an insufficiently wide dynamic range of perceived signals due to the lack of adaptive control of the sensitivity of the device with respect to the average level of interference. This leads to a decrease in the detection efficiency of the source of ignition.

The objective of the utility model is to increase the detection efficiency of the source of ignition.

The technical result achieved by solving the task is to expand the range of signals perceived by the device from the source of ignition

and improving the noise immunity of the device.

The problem is achieved in that in an optical fire detector containing infrared and ultraviolet radiation sensors, the outputs of which are connected via a matching circuit to a control microprocessor, while the matching circuit of an infrared sensor consists of a program-controlled amplifier, an analog-to-digital converter and a digital-to-analog converter , according to a utility model, the matching circuit of the infrared sensor further comprises a program-controlled divider consisting of programs a non-controlled resistor and a constant resistor, while the input of the constant resistor is connected to the output of the digital-to-analog converter, and its output is connected to the negative input of the program-controlled amplifier, the first input of the program-controlled resistor is connected to the output of the program-controlled amplifier, the second input with the output of the control microprocessor, and its output with a negative input of a program-controlled amplifier.

In addition, the input of the analog-to-digital converter is connected to the output of a program-controlled amplifier, the output is connected to the input of the control microprocessor, and the input of the digital-to-analog converter is connected to the output of the control microprocessor.

In addition, the detector is equipped with a video camera, video processor, operational and non-volatile video memory, while the output of the video camera is connected to the input of the video processor, one of the inputs and outputs of the video processor is connected to the input-output of non-volatile video memory, the other input-output is connected to the input-output of random access memory, and the third input-output is connected to the input-output of the control microprocessor.

The claimed combination of features allows you to expand the range of signals perceived by the device from the source of ignition and increase the noise immunity of the device, due to the possibility of continuous assessment of both the instantaneous value and the average level of interference and, depending on the average value of the level of interference, set the sensitivity of the device, and depending on frequency spectrum to form programmatically the bandwidth of a program-controlled terminal amplifier.

This makes it possible to optimize the operation of the infrared channel to obtain the maximum possible sensitivity with a varying level of interference during operation and leads to an increase in the efficiency of detection of a source of ignition.

The drawing shows a block diagram of an optical fire detector.

Positions in the drawings mean the following: 1 - infrared radiation sensor; 2 - ultraviolet radiation sensor; 3 is a matching diagram of an infrared sensor 1; 4 is a matching diagram of the ultraviolet sensor 2; 5 - control microprocessor; 6 - software-controlled amplifier; 7 - analog-to-digital Converter; 8 - digital-to-analog converter; 9 software-controlled resistor; 10 - constant resistor; 11 - video camera; 12 - video processor; 13 - operational video memory; 14 - non-volatile video memory.

The fire detector contains an infrared radiation sensor 1, an ultraviolet radiation sensor 2, the outputs of which are connected to the control microprocessor 5 through matching circuits 3 and 4.

The matching circuit 3 of the infrared sensor 1 consists of a program-controlled amplifier 6, an analog-to-digital converter 7, a digital-to-analog converter 8, and a program-controlled divider, consisting of a program-controlled resistor 9 and a constant resistor 10.

The input of the constant resistor 10 is connected to the output of the digital-to-analog converter 8, and its output is connected to the negative input of the program-controlled amplifier 6.

The first input of the program-controlled resistor 9 is connected to the output of the program-controlled amplifier 6, the second input is connected to the output of the control microprocessor 5, and its output is connected to the negative input of the program-controlled amplifier 6.

The input of the analog-to-digital converter 7 is connected to the output of the program-controlled amplifier 6, the output is connected to the input of the control microprocessor 5, and the input of the digital-to-analog converter 8 is connected to the output of the control microprocessor 5.

To track the causes and history of the development of fire, the detector is equipped with a video camera 11, video processor 12, operational 13 and non-volatile 14 video memory.

The output of the video camera 11 is connected to the input of the video processor 12, one of the inputs / outputs of the video processor 12 is connected to the input-output of the non-volatile 14 video memory, the other input-output is connected to the input-output of the operative 13 video memory, and the third input-output is connected to the input-output of the control microprocessor 5.

The control microprocessor 5 contains algorithms for digital processing of the signals of sensors 1 and 2, deciding on a fire, the diagnostic sequence of the entire device and communication protocols with control panels (not shown in the diagram),

as well as a protocol for exchanging data with a video processor 12.

The fire detector operates as follows.

The signal of the infrared sensor 1 enters the matching circuit 3, in which it is possible to continuously evaluate both the instantaneous value and the average interference level and, depending on the average value of the interference level, set the sensitivity of the device, and, depending on the frequency spectrum, a band is formed by software transmittance of a programmable terminal amplifier.

The signal from the infrared sensor 1 is fed to the direct input of the program-controlled amplifier 6. Simultaneously, at the output of the digital-to-analog converter 8, the control microprocessor 5 generates a frequency-dependent negative feedback signal, which, through the constant resistor 10, is added to the negative feedback signal from the program-controlled resistor 9 and is fed to the negative input of a program-controlled amplifier 6, where it is subtracted from the signal from the output of the infrared sensor 1.

The amplifier 6 performs analog subtraction, amplification of the resulting signal, which is fed to the input of the analog-to-digital converter 7.

The gain is set by a program-controlled divider consisting of a program-controlled resistor 9 and a constant resistor 10. The ratio of the current values of the resistors 9 and 10 forms the gain of the program-controlled amplifier 6.

As a result of the analysis of the average noise level in the control microcontroller 5, the program-controlled amplifier 6 carries out a change in the gain.

At a high level of interference, the minimum allowable, normalized value of the gain of the program-controlled amplifier is set 6. With a low level of interference or its absence, the maximum value of the gain of the program-controlled amplifier is set 6. As a result, the sensitivity of the device significantly exceeds the normalized value. This makes it possible to detect a much weaker signal about a fire, i.e. detect a fire at an earlier stage. In this case, the range of the device also increases. For example, the sensitivity to the test source of ignition TP5, TP6 (according to GOST R 50898-96 "Fire detectors. Fire tests" p. 4) increases from 25 m to 42 m.

The number-pulse signal of the ultraviolet sensor 2 through the matching circuit 4 is fed to the input of the control microprocessor 5.

The control microprocessor 5 runs an algorithm for processing signals from sensors 1 and 2. The algorithm describes the conditions for deciding on the absence or presence of a fire, which leads to corresponding changes in the state and operation mode of the entire detector.

In parallel with the operation of the infrared radiation sensor 1 and the ultraviolet radiation sensor 2, a video path of the detector is functioning.

A digital signal from the output of the video camera 11 is fed to the input of the video processor 12, to which the operational 13 and non-volatile video memory units are connected 14. The video processor 12 compresses the video frames and places them in a ring buffer in the random access memory 13.

In the event of a fire, the control microprocessor 5 gives a signal to the video processor 12, which stops the recording of new video frames to the online video memory 13 and rewrites the recorded video frames from the online 13 to non-volatile video memory 14.

The control microprocessor 5 also transmits a “fire” signal to the control panel (not shown in the diagram), which, if necessary, generates a command to read video frames. Having accepted the command, the control microprocessor 5 transmits it to the video processor 12, which in the reverse order sends the recorded video frames (video processor 12 - the control microprocessor 5 - the control panel). Similarly (upon request from the control panel), the current video frames are transmitted.

The inventive detector allows you to increase the efficiency of detection of the source of ignition by optimizing the operation of the infrared channel to obtain the maximum possible sensitivity with a changing level of interference during operation.

In addition, the presence of a video channel in the fire detector allows continuous monitoring of the condition of the object before the fire and the registration of events prior to the fire. This makes it possible to further analyze and investigate the cause of the fire, which extends the functionality of the fire detector. In addition, the video channel can significantly facilitate the installation and further control of the correct location and direction of the detector to cover the security zone.

In addition, the current level of technological development allows combining

several elements of the claimed block diagram into one functional element, which makes it possible to implement this device using various options and combinations of the element base.

Claims (3)

1. An optical fire detector containing infrared and ultraviolet radiation sensors, the outputs of which are connected via a matching circuit to a control microprocessor, and the matching circuit of the infrared sensor consists of a program-controlled amplifier, an analog-to-digital converter and a digital-to-analog converter, characterized in that the matching circuit the infrared sensor further comprises a programmable divider consisting of a programmable resistor and a constant res torus, while the input of the constant resistor is connected to the output of the digital-to-analog converter, and its output is connected to the negative input of the program-controlled amplifier, the first input of the program-controlled resistor is connected to the output of the program-controlled amplifier, the second input is to the output of the control microprocessor, and its output - with a negative input of a program-controlled amplifier. 2. The optical fire detector according to claim 1, characterized in that the input of the analog-to-digital converter is connected to the output of the program-controlled amplifier, the output is connected to the input of the control microprocessor, and the input of the digital-to-analog converter is connected to the output of the control microprocessor. 3. The optical fire detector according to claim 1, characterized in that the detector is equipped with a video camera, a video processor, operational and non-volatile video memory, while the output of the video camera is connected to the input of the video processor, one of the inputs / outputs of the video processor is connected to the input-output of non-volatile video memory, the other input The output is connected to the input / output of the operative video memory, and the third input / output is connected to the input / output of the control microprocessor.