KR20090072746A - Device for sensing assembly using infrared rays of window type - Google Patents

Abstract

A window-shaped infrared rays sensing apparatus is provided to offer convenient expandability by determining a number of a transmission module and a light receiving module according to size of a detection region. A transmission controller(110) is arranged in a floodlighting device. The transmission controller supplies a predetermined pair of frequency bands to a transmission module through a signal line. The transmission module transmits infrared rays to a light receiving device according to a control signal of the transmission controller. The light receiving module receives infrared ray signals from the light receiving device. A receiving controller(240) determines a state of an invasion in a sensing region through analysis of the infrared ray signals.

Description

Device for sensing assembly using infrared rays of window type}

The present invention relates to an infrared sensing device consisting of a light emitting device and a light receiving device, and more particularly, to a window-type infrared sensing device that provides easy expansion of the light emitting device and the light receiving device according to the size of the monitoring area to be installed.

In recent years, homes and companies have installed and used unmanned security systems provided by private security companies to prevent the occurrence of various crimes and protect lives and property.

The unmanned security system is provided with one or more sensors for detecting the intrusion of outsiders at a predetermined position in the surveillance area, and the signals of these sensors are comprehensively detected by a sensing device installed in the surveillance area to provide its own boundary, and provide a dedicated line or public communication network. It is transmitted to the central control unit installed at the remote site through the network.

Therefore, the central control device detects whether an intruder has occurred in the surveillance area and provides a quick response accordingly to protect valuable human life and property in the surveillance area.

Infrared detectors are widely used in the unmanned security system.

In the conventional infrared sensing device, as shown in FIG. 8, the light transmitting device 10 and the light receiving device 20 are composed of one set so as to optically face each other in a monitoring area, for example, the window frame 40. It is installed to see.

The light emitting device 10 generates an infrared signal having a predetermined frequency and radiates it to the light receiving device 20 side, and the light receiving device 20 receives the infrared signal emitted from the light emitting device 10 and then analyzes the frequency band. Check if it is a promised frequency band, and analyze the amount of received light if it is a promised frequency band.

At this time, the light receiving device 20 determines that an external intruder is generated between the light transmitting device 10 and the light receiving device 20 or the infrared signal transmitted / received by an arbitrary object is blocked when the amount of light received is less than a predetermined value. To generate a set alarm sound for its own boundaries.

At the same time, it can be sent to security control centers such as central control devices and police stations installed remotely through leased lines or public communication networks so that rapid response can be made according to intruder detection.

Between the light transmitting device 10 and the light receiving device 20 is at least two or more, typically 2, 4, 6, 8... The sensor is formed of two times the number of detection lines (l1 to l4) is formed, each sensor transmits and receives an infrared signal of an independent frequency band.

In order to prevent erroneous detection caused by shading by animals or fallen leaves, two sensing lines l1 and l2 are generally set to one group, and both sensing lines l1 and l2 of one group are set to one group. It is determined that an intruder has occurred only when light shielding is detected.

In the conventional infrared sensor as described above, each infrared signal forming the sensing line between the light transmitting device 10 and the light receiving device 20 is set to have an independent frequency band.

Therefore, in order to transmit the infrared signal of the independent frequency band to each sensing line, the light emitting device must connect the control means for controlling the transmission of the infrared signal and the transmission module for transmitting the infrared signal by independent signal lines. The disadvantage is that the structure is complicated.

In addition, the control means provided in the light emitting device has a disadvantage in that a high-performance microcomputer and its operation program are required for generating and controlling independent frequencies, thereby increasing manufacturing costs.

In addition, the light receiving device also has a disadvantage in that the structure of the light receiving device is complicated because the receiving module and the control means for receiving the signal of the light transmitting device must be connected to each independent signal line.

Similarly, the control means provided in the light receiving device has a disadvantage in that a high performance microcomputer and an operation program are required for the analysis of the independent frequency, thereby increasing the manufacturing cost.

In addition, the size of the conventional infrared sensor is fixed, the area that can be detected by one infrared sensor consisting of a light transmitting device and a light receiving device is limited.

Therefore, for example, when the size of a window is large and one infrared sensor cannot detect the entire area, two infrared sensors are installed, and one infrared sensor monitors the entire area. If you cannot install two infrared sensors, there is a disadvantage that blind spots of unmanned detection occurs.

That is, there is a disadvantage in that it does not provide scalability and variability of the infrared sensing device according to the size of the sensing area.

The present invention has been invented to solve the above problems, and provides easy expansion of the floodlighting device and the light receiving device according to the size of the monitoring area (window) to be installed, convenient expansion and convenience of installation according to the size of the monitoring area. The purpose is to provide.

In addition, in the light transmitting apparatus, only two infrared signals forming one group are generated and transmitted as a monitoring signal, and when the transmitting module is extended, the two infrared signals are connected in parallel to the transmitting module which is connected to a separate module. The purpose is to provide an extended full area detection without setting a frequency band.

In addition, an object of the present invention is to provide an extension of the transmission module through the coupling of the connector in the light transmitting device.

The present invention for realizing the above object is provided in the surveillance region, the infrared detection device comprising a light emitting device for transmitting an infrared signal and a light receiving device for receiving and analyzing the infrared signal to determine whether an intruder,

A transmission control unit disposed in the light emitting device and configured to oscillate a predetermined frequency band and provide the transmission module to a transmission module through a signal line;

A transmission module configured to transmit an infrared signal of a band set according to a control signal of the transmission control unit to the light receiving device, and the number of which is variably expanded according to the size of the monitoring area;

At least one light receiving module disposed in the light receiving device and arranged in a number corresponding to a transmission module disposed in the light transmitting device to receive an infrared signal transmitted from a corresponding transmission module;

It includes a reception control unit for determining whether an intruder in the surveillance area by analyzing the received infrared signal,

The light receiving module includes a first lens for receiving an infrared signal of a contracted frequency band transmitted through a first monitoring line formed with a transmitting module and an infrared signal for a contracted frequency band transmitted through a second monitoring line. 2 lenses are placed,

A first end gate configured to perform an AND operation on the output signal of the first lens included in the light receiving module itself and the signal of the first surveillance line received through the first lens included in the extended light receiving module, and the light receiving module itself. A second end gate for performing an AND operation on the output signal of the two lenses and the signal of the second surveillance line received through the second lens included in the extended light receiving module;

And a third end gate for performing an AND operation on the outputs of the first and second end gates.

By the above-described configuration, the present invention is expected to provide convenience and efficiency of installation by providing convenient expandability according to the size of the area where the infrared sensing device is installed.

In addition, the present invention connects the infrared signal applied to the transmission module in the light emitting device which is expanded according to the size of the area to be installed in parallel with the infrared signal used in the light emitting device, and the light receiving module is easily extended to the light receiving device of the control means. The effect is to reduce the load and provide convenience in setting up the infrared sensor.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention.

As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention.

In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

In addition, when a part is said to "include" a certain component, this means that it may further include other components, except to exclude other components unless otherwise stated.

In addition, the term module described herein refers to a unit for processing a specific function or operation, which may be implemented in hardware or software, or a combination of hardware and software.

1 is a schematic diagram showing the installation of a window-type infrared monitoring device according to an embodiment of the present invention.

As shown, a light transmitting device 100 for transmitting an infrared signal of a frequency band set on one side of the window 300, which is a monitoring area, is disposed, the other side receives the infrared signal transmitted from the light emitting device 100 in advance The light receiving device 200 determines whether an infrared signal of the contracted frequency band is determined, and if the infrared signal of the contracted frequency band is analyzed, a light receiving amount is analyzed to determine whether an intruder is generated through the window 300.

The above configuration will be described in more detail with reference to FIG. 2 as follows.

2 is a view showing a schematic configuration of a window-type infrared monitoring device according to an embodiment of the present invention.

The light projector 100 includes a transmission controller 110 and at least one transmission module 120A-120N.

The transmission control unit 110 oscillates a pair of predetermined frequency bands and provides them to the transmission modules 120A through 120N through signal lines a and b.

The number of transmission modules 120A-120N varies depending on the size of the monitoring area, and each of the transmission modules 120A-120N connected in parallel with the signal lines (a, b) of the transmission control unit 110 are arranged in the same manner. The infrared signal of the frequency band is sent to the light receiving device 200 side.

The transmitting modules 120A-120N are oscillated by the transmission control unit 110 to transmit infrared signals applied through the signal line a and infrared rays applied through the one lens 122A-122N and the signal line b. Another lens 121A-121N for transmitting a signal is disposed to transmit a pair of infrared signals that have been previously agreed.

Typically, one to two transmission modules 120A-120B are disposed in the light emitting device 100 by default, but more transmission modules 120C-120N are expanded and connected through connector coupling depending on the size of the monitoring area. .

If the monitoring area is a window, the transmission modules 120A-120N can be extended to monitor an area of approximately 2.5M that can be defined by the window.

In addition, the light receiving apparatus 200 includes at least one light receiving module 210A-210N, an end gate 235, and a reception controller 240.

The light receiving modules 210A-210N are arranged in a number corresponding to the transmission modules 120A-120N disposed in the light transmitting apparatus 100, and are transmitted in a predetermined frequency band from the corresponding transmission modules 120A-120N. Receives infrared signals.

Therefore, the monitoring line L1, the infrared signal of the same frequency band between each transmission module (120A-120N) and each light receiving module (210A-210N) disposed in the light receiving device 200 and the light receiving device (100). L2) is formed.

The light receiving module 210A-210N includes one lens 212A-212N and a monitoring line for receiving an infrared signal of a contracted frequency band transmitted through the monitoring line L1 formed with the transmission module 120A-120N. Another lens 211A-211N for receiving an infrared signal of a contracted frequency band transmitted through L2 is disposed.

In addition, one end gate 220A-220N and an AND that perform a logical AND operation on the signal received through the lens provided to the light receiving module itself and the signal of the monitoring line L1 received through the lens included in the extended light receiving module are monitored. The AND gates 230A-230N are arranged to AND the signals of the line L2.

In the above, one side of the end gates 220N and 230N disposed in the light receiving module 210N that is maximized according to the size of the window is always set to a “high” condition.

The AND gate 235 performs an AND operation on the result of performing an AND operation on the signal of the monitoring line L1 and the operation performing an AND operation on the signal of the monitoring line L2, and provides the result to the reception controller 240. .

The reception controller 240 analyzes the output of the AND gate 235 to determine whether an intruder is generated in the surveillance region.

The transmission module 120A-120N and the light receiving module 210A-210N, which are extended to the light transmitting device 100 and the light receiving device 200, are coupled to each other in a pin-to-pin manner of a connector as shown in FIG. 3. It provides efficient connection and parallel connection structure.

For example, assuming that the distance between the top and bottom of the lenses 121 and 122 is 20 cm and the total height of one module is limited to 30 cm, the transmission module 120A extended to the connector 124B of the basic transmission module 120A. The connector 123B is coupled in a pin-to-pin manner, and the signal lines are connected in parallel.

According to the pin-to-pin coupling, the light emitting device and the light receiving device are provided with N expansions according to the size of the surveillance area.

4 is a circuit diagram showing the detailed configuration of the transmission control unit and the transmission module of the window-type infrared monitoring apparatus according to an embodiment of the present invention.

The microcomputer (MCU1) which is operated by the power supply (Vcc) rectified from the power supply means (not shown) or the stored charge / discharge battery power source (C3) to control the overall operation for the transmission of the infrared signal, and 2 Oscillator (X1) for oscillating the two frequency bands, the light emitting diode (D1) for indicating the operating state, the infrared signal of the first frequency band output from the microcomputer (MCU1) applied through the resistor (R5) to amplify through switching Transistors Q2 and Q3 and transistors Q4 and Q5 which amplify through switching the infrared signals of the second frequency band output from the microcomputer MCU1 and applied through the resistor R6.

The transmission module 120A-120N connected to the expansion connector JP4 for the infrared signals of the contracted first and second frequency bands amplified through the transistors Q2, Q3 and Q4 and Q5. The light is emitted through the infrared lamps D11 and D21 provided at the light emitting device 200, and is sent to the light receiving device 200.

At both ends of the PCB of the transmission module (120A-120N) is a connector for connecting the signal line (a, b) in parallel by coupling the extended transmission module pin-to-pin.

5 is a circuit diagram showing the detailed configuration of the receiving control unit and the receiving module of the window-type infrared monitoring apparatus according to an embodiment of the present invention.

Receiving modules (210A-210N) is a light receiving element (D51) for receiving an infrared signal of the first frequency band transmitted from the transmission module (120A-120N) and a light receiving element (D52) for receiving an infrared signal of the second frequency band, A transistor Q51 that is turned on / off in response to a first frequency band infrared signal receiving operation of the first light receiving element D51 and a second frequency band infrared signal receiving operation of the second light receiving element D52 is turned on. And a transistor Q52 for switching on / off.

Connectors at both ends of the PCB of the receiving module (210A-210N) is provided a connector to provide a pin-to-pin coupling of the receiving module.

The reception control unit 240 is operated by the power supply Vcc rectified and supplied by the power supply means or the stored charge / discharge battery power supply C31, and receives the received first and second reception modules of the reception module applied through the expansion connector J10. A microcomputer (MCU2) for determining whether an intruder is generated in the surveillance area by analyzing an infrared signal of a second frequency band, an oscillator (X11) for oscillating a frequency of a set band to identify a frequency band of an infrared signal received from a light emitting device; And a display element D41 for displaying an operation state of the reception control unit 240.

Referring to the operation of the infrared sensing device according to the present invention having the configuration as described above are as follows.

In response to the power supply of the light emitting device 100 and the light receiving device 200 installed in a specific monitoring area, the transmission control unit 110 in the light emitting device 100 is divided into two frequency signals AHz and BHz as shown in FIG. 6. Oscillates and sends out the infrared signal through the transmission module (120A-120N).

Accordingly, the lenses 212A-212N of the light receiving modules 210A-210N disposed corresponding to the transmission modules 120A-120N receive the infrared signal transmitted through the monitoring line L1 and are connected to the output terminal. It is applied to one end of (230A-230N).

In addition, the lenses 211A-211N of the light receiving modules 210A-210N receive an infrared signal transmitted through the monitoring line L2 and apply it to one end of the end gates 220A-220N connected to the output terminal.

The AND gates disposed on the light receiving modules 210A to 210N perform an AND operation on a signal applied from a corresponding lens and a signal provided by the extended light receiving module.

For example, the AND gate 230B disposed in the light receiving module 210B may be ANDed to the output signal of the signal applied from the lens 212B and the output signal of the AND gate 230C disposed in the extended light receiving module 210C. The result is applied to one side of the AND gate 230A disposed in the light receiving module 210A.

In addition, the AND gate 220B disposed on the light receiving module 210B performs an AND operation on the signal applied from the lens 211B and the output signal of the AND gate 220C disposed on the extended light receiving module 210C. The result is applied to one side of the AND gate 220A disposed in the light receiving module 210A.

Therefore, the AND gate 230A disposed in the light receiving module 210A is AND-operated by the AND signal of the lens 212B and the output signal of the AND gate 230B disposed in the extended light receiving module 210B. It is applied to one side of (235).

In addition, the AND gate 220A disposed on the light receiving module 210A may be ANDed by performing an AND operation on the signal applied from the lens 212A and the output signal of the AND gate 220B placed on the extended light receiving module 210B. To the other side of 235.

Accordingly, the AND gate 235 performs an AND operation on the signals applied to both sides, and applies the AND gate 235 to the reception controller 240.

The reception control unit 240 analyzes the signal of the end gate 235 to determine whether an intruder is generated in the monitoring area, and when it is determined that the intruder is generated, an alarm sound is issued to execute its own security and at the same time through a dedicated line or a public communication network. Inform relevant authorities so that prompt response can be made.

The AND gate disposed on the light receiving modules 210A to 210N outputs a “high” signal only when all input signals are normal, so that any one or more of the light emitting device 100 and the light receiving device 200 are connected to each other. In the case where shading by an intruder occurs in the monitoring lines L1 and L2, the output of the corresponding receiving module becomes “low”.

Therefore, since the output of the AND gate connected to the output terminal of the corresponding receiving module is also "low", the output of the AND gate 235 is also "low" and is applied to the reception control unit 240, accordingly, the reception control unit 240 Determines the occurrence of the intruder.

However, when the light blocking of the monitoring line (L1, L2) connecting the light emitting device 100 and the light receiving device 200 does not occur, the output of all receiving modules (210A-210N) is kept "high", accordingly The output of the AND gate also remains "high."

Therefore, since all information input to the AND gate 235 maintains "high", the output value is also applied to the reception control unit 240 as "high".

Therefore, the reception control unit 240 determines that the light shielding of the monitoring lines L1 and L2 is not detected and maintains the current state.

7 is a flowchart illustrating the operation of the window-type infrared monitoring apparatus according to an embodiment of the present invention.

When the power supply of the light transmitting apparatus 100 and the light receiving apparatus 200 installed in the monitoring area is detected, the light transmitting apparatus 100 generates a pair of infrared signals which have been contracted in advance, and transmits them to the light receiving apparatus 200 (S101) ( S102).

Accordingly, the light receiving device 200 receives the infrared signal transmitted from the light transmitting device 100 and then analyzes the frequency band (S103) to determine whether the frequency of the predetermined band (S104).

If it is not the frequency of the contracted band or the reception of the frequency is not detected in the determination of S104 (S105), it is determined that the monitoring lines L1 and L2 are shielded by an intruder, and an alarm sound is sent for self-expense. Notify the method control authority over a dedicated line or a public communication network to enable a quick response (S106) (S107).

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It is included in the scope of rights.

1 is a schematic diagram showing the installation of a window-type infrared monitoring device according to an embodiment of the present invention.

2 is a view showing a schematic configuration of a window-type infrared monitoring device according to an embodiment of the present invention.

3 is a view showing the expansion of the transmission module and the reception module in the window-type infrared monitoring device according to an embodiment of the present invention.

4 is a circuit diagram showing the detailed configuration of the transmission control unit and the transmission module of the window-type infrared monitoring apparatus according to an embodiment of the present invention.

5 is a circuit diagram showing the detailed configuration of the receiving control unit and the receiving module of the window-type infrared monitoring apparatus according to an embodiment of the present invention.

6 is a view showing a monitoring frequency transmitted and received in the window-type infrared monitoring device according to an embodiment of the present invention.

7 is a flowchart illustrating the operation of the window-type infrared monitoring apparatus according to an embodiment of the present invention.

8 is a view showing the installation of a conventional window-type infrared monitoring device.

<Explanation of symbols for the main parts of the drawings>

100: light transmitting device 110: transmission control unit

120A-120N: Transmission module 121,122: Infrared transmitter

200: light receiving device 210A-210N: receiving module

220A-220N, 230: AND gate 240: reception control unit

Claims (10)

In the infrared detection device is installed in the surveillance area, comprising a light transmitting device for transmitting infrared signals and a light receiving device for receiving and analyzing the infrared signal to determine whether an intruder is generated, A transmission control unit disposed in the light emitting device and configured to oscillate a predetermined frequency band and provide the transmission module to a transmission module through a signal line; A transmission module configured to transmit an infrared signal of a band set according to a control signal of the transmission control unit to the light receiving device, and the number of which is variably expanded according to the size of the monitoring area; At least one light receiving module disposed in the light receiving device and arranged in a number corresponding to a transmission module disposed in the light transmitting device to receive an infrared signal transmitted from a corresponding transmission module; It includes a reception control unit for determining whether an intruder in the surveillance area by analyzing the received infrared signal, The light receiving module includes a first lens for receiving an infrared signal of a contracted frequency band transmitted through a first monitoring line formed with a transmitting module and an infrared signal for a contracted frequency band transmitted through a second monitoring line. 2 lenses are placed, A first end gate configured to perform an AND operation on the output signal of the first lens included in the light receiving module itself and the signal of the first surveillance line received through the first lens included in the extended light receiving module, and the first light receiving module itself. A second end gate for performing an AND operation on the output signal of the two lenses and the signal of the second surveillance line received through the second lens included in the extended light receiving module; And a third end gate for performing an AND operation on the outputs of the first and second end gates. The method of claim 1, The extended transmission module is connected in parallel with the signal line of the transmission control unit, the transmission module disposed is a window type infrared sensor for transmitting an infrared signal of the same frequency band to the light receiving device side. The method of claim 1, The transmission module comprises a first lens for transmitting an infrared signal of the contracted first frequency band and a window type infrared sensing device comprising a second lens for transmitting an infrared signal of the second frequency band. The method of claim 1, The transmission module extends in a pin-to-pin manner through connection of a connector, and provides a window-type infrared sensing device that provides the expandability of the 2.5M surveillance area defined by the window. The method of claim 1, Window type infrared sensing device is disposed at both ends of the PCB of the transmission module is provided with a connector to provide a parallel connection of the pin-to-pin coupling and the signal line to the extended transmission module. The method of claim 1, At least one transmitting module disposed at the light emitting device and at least one receiving module, wherein at least one receiving module corresponding to the transmitting module forms a monitoring line (L1, L2) with infrared signals of the same frequency band. The method of claim 1, The transmission control unit is operated by the power supplied or rectified by the power supply means or stored charge-discharge battery power source to control the overall operation of the infrared signal transmission; An oscillator oscillating two contracted frequency bands; A light emitting diode displaying an operating state; First and second transistors for amplifying and transmitting infrared signals of a first frequency band output from the microcomputer; Window-type infrared detection device comprising a third, fourth transistor for amplifying and transmitting the infrared signal of the second frequency band output from the microcomputer. The method of claim 1, The receiving module includes a first and a second light receiving element for receiving infrared signals of the first and second frequency bands; And a first and second transistors which are switched on and off according to the reception of the infrared signal received through the first and second light receiving elements. The method of claim 1, Window-type infrared sensing device is disposed on both ends of the PCB of the receiving module is provided with a connector to provide a pin-to-pin coupling of the receiving module is extended. The method of claim 1, The reception control unit is operated by the power supplied or rectified by the power supply means or the charge-discharge battery power received, the microcomputer to determine whether an intruder in the monitoring area by analyzing the received infrared signal of the receiving module; An oscillator oscillating a frequency of a band set for comparing frequency bands of received infrared signals; Window type infrared sensing device including a light emitting diode to display the operating status.

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