KR200349273Y1 - Sensor with infrared rays of multibeam - Google Patents

Abstract

The present invention relates to a multi-beam infrared sensor, the control unit 160 for defining and controlling a predetermined set value, the transmitter 120 for controlling the infrared light emitting LED 520 and the receiver for controlling the infrared receiving sensor (540) ( In the multi-beam infrared sensor 100 composed of the 140, the CPU unit 161 and the transmitter 120 are formed inside the controller 160 to exchange a predetermined set value with the transmitter 120 and the receiver 140. Transmitting control unit 121 is formed inside to give the sequence code and identification code to the multiple beams, the selection unit 122 for selecting one of the sequence code and the identification code and the modulation unit for converting the infrared rays into a modulation wave of 38 kHz ( 123 and an infrared light emitting LED unit 124 for transmitting infrared rays converted into a 38 kHz modulation wave, and an infrared ray receiving sensor unit 144 for selecting and receiving 38 kHz infrared rays formed inside the receiving unit 140 to analyze the received data. Phrase to the reception control unit 142 A multi-beam infrared sensor is provided that is configured.

Description

Sensor with infrared rays of multibeam

The present invention relates to an infrared sensor, and in particular, by multiplexing the number of beams to generate one-to-one corresponding transmission / reception beams to recognize whether the beams are interrupted, and analyzing them in the receiving control unit. The CPU unit relates to a multi-beam infrared sensor configured to inform an external device of an intrusion alert signal.

Various kinds of security devices are installed and operated around us. No matter how advanced security devices are, if the sensors to detect intruders are not functioning properly, they may allow intrusion or suffer false alarms. One of many installed and used sensors is an infrared sensor.

In general, the infrared sensor has only one beam, and thus cannot cover one large intrusion space. In order to solve this problem, the number of beams is increased by using a combination of several, but since there is no individual recognition code, a receiving device other than the corresponding infrared receiver may be detected at the same time. There was also a lot of trouble.

Also, because the coder is not coded, the intruder purchases a pseudo-infrared sensor and activates the infrared light emitting unit so that the infrared light transmitting unit installed for intrusion detection becomes useless and easily invades. there was.

In order to solve this problem, the number of beams in the sensor is increased, but the number of beams is fixed for each sensor, so even if it is necessary to modify the number, it was necessary to purchase an infrared sensor with a different number of beams. There was a problem.

The present invention is to solve this problem, and to implement an infrared sensor that is safe even in the disturbance of the similar sensor by having the effect of multiple beams in one installation and the identification code. In order to implement this, a plurality of infrared light emitting LEDs 520 and an infrared ray receiving sensor 540 are formed, and a sequence number is individually and sequentially operated from a piece PC inside the transmitter and the receiver, and at the same time, a corresponding identification code is given to the wrong one. Its purpose is to provide a multi-beam infrared sensor that can be prevented from being recognized and that the length can be adjusted by a simple circuit connection and that the setting value can be changed as desired by using a piece PC in the sensor. .

1 is a block diagram showing an operation according to an embodiment of the present invention.

2 is a view schematically showing an operation example of a transmitter.

3 is a view schematically showing an example of an operation of a receiver;

4 is a view schematically showing an example of an operation of a control unit;

5 is a cross-sectional view showing an infrared light emitting LED unit and an infrared receiving sensor unit.

6 is a view showing a data flow according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

120: transmitter 140: receiver

121: transmission control unit 142: reception control unit

124: infrared light emitting LED unit 144: infrared receiving sensor unit

160: control unit 161: CPU unit

The present invention configured to achieve the object of the present invention as described above, the control unit 160 for defining and controlling a predetermined set value, the transmitter 120 for controlling the infrared light emitting LED 520, and the infrared receiving sensor In the multi-beam infrared sensor 100 composed of a receiving unit 140 for controlling the 540, the CPU unit formed inside the control unit 160 to exchange setting values from the transmitting unit 120 and the receiving unit 140 Alarm output that is connected to the 161 and the CPU unit 161 is turned on when the power is connected and is connected to the power LED 165 and flashes when the alarm occurs and the alarm signal is input when the alarm signal is input A transmission control unit 121 formed inside the transmission unit 166 and the transmission unit 120 to assign a sequence code and an identification code to the multiple beams, and one of a plurality of sequence codes and identification codes granted by the transmission control unit 121. Selection unit 122 and the above to select A modulator 123 for converting the infrared rays of the code selected by the selector 122 into a modulated wave of 38 kHz and an infrared light emitting LED unit 124 for transmitting the infrared rays converted into a modulated wave of 38 kHz by the modulator 123 and the transmission When connected to the control unit 121 and synchronized with the receiving unit 140, the transmission LED 125 and the receiving unit 140 formed inside the receiving unit 140 to receive and receive the 38 kHz infrared rays transmitted from the infrared light emitting LED unit 124 A reception control unit 142 and a reception control unit 142 for analyzing data received from the infrared reception sensor unit 144, the infrared reception sensor unit 144, the transmission control unit 121, and the CPU unit 161. A multi-beam infrared sensor is provided which is configured to receive LED 146 which is connected to and is turned on when it is synchronized with the transmitter 120.

Hereinafter, the multi-beam infrared sensor according to the present invention will be described according to an embodiment shown in the drawings.

As shown in FIG. 1, the multi-beam infrared sensor 100 of the present invention includes a control unit 160 for defining and controlling a predetermined set value, a transmitter 120 for controlling an infrared light emitting LED 520, and an infrared ray. In the multi-beam infrared sensor 100 composed of a receiving unit 140 for controlling the receiving sensor 540, formed in the control unit 160 to exchange setting values from the transmitting unit 120 and the receiving unit 140 An alarm that is connected to the CPU unit 161 and the CPU unit 161 and is turned on when the power is connected and connected to the power LED 165 and the controller 160 that is flashed when an alarm is generated and outputs an alarm when an alarm signal is input. One of a plurality of sequence codes and identification codes provided in the output unit 166 and the transmitting unit 120 to give a sequence code and an identification code to the multiple beams and the transmission control unit 121 The selection unit 122 and the line for selecting A modulator 123 for converting the infrared rays of the code selected by the unit 122 into a modulated wave of 38 kHz, an infrared light emitting LED unit 124 for transmitting the infrared rays converted into a modulated wave of 38 kHz by the modulator 123, and the transmission controller Infrared receiving sensor connected to the 121 and the transmission LED 125 is turned on when synchronized with the receiving unit 140 and the 38 kHz infrared rays formed in the receiving unit 140 and selected from the infrared light emitting LED unit 124 to receive And a reception control unit 142 and a reception control unit 142 for analyzing data received from the infrared reception sensor unit 144, the transmission control unit 121, and the CPU unit 161. It is composed of a receiving LED 146 which is turned on when the synchronization with the transmitter 120.

2 is a schematic diagram illustrating an operation example of the transmitter 120. The infrared beam 112 in the transmitting unit 120 uses a 38 kHz modulated wave, and before receiving the infrared beam 112 from the infrared light emitting LED unit 124 in an initial operation, through the DC power line 600. 142 transmits a ready signal for transmission and receives a signal that the signal may be transmitted from the reception control unit 142 and then transmits it when synchronization is performed.

The transmission from the transmitter 120 is easy to understand if it is associated with a ring counter.

An identification code is generated in each sequence code from the transmission control unit 121, and the contents of the code (order code (IR-1, ...) + identification code) using the DC power line 600 to the reception control unit 142. The reception control unit 142 prepares the reception while transmitting. The sign of the code is as simple as possible to shorten the length of the sign. When the reception preparation signal is received from the reception control unit 142, the infrared light emitting LED unit 124 transmits the code contents one by one in the order of the order code. When the code content is confirmed by the reception control unit 142, the code sequence of the next sequence is repeated.

In the transmission control unit 121, since the identification code is randomly generated and less likely to match with other sensors, the recognition rate between the sensors is increased, and the time required for all prepared code contents to be transmitted is 0.5 seconds to 1 second. It solves the problem. When the code contents are transmitted, the DC power line 600 is checked once.

In addition, since the data cannot be directly transmitted to the DC power line 600, the transmitter generates a modulation frequency of several tens of kHz, demodulates the data of the CPU unit 161, and sends the data to the DC power line 600.

3 is a schematic diagram illustrating an operation example of the receiver 140. The reception unit 140 is synchronized with the transmission control unit 121 through the DC power line 600 in an initial operation before receiving the infrared beam 112 from the infrared light emitting LED unit 124. In addition, the controller 160 receives a predetermined set value from the control unit 160 to prepare for reception.

After the initial operation, the reception unit 140 receives the code contents from the transmission control unit 121 through the DC power line 600, and is transmitted from the infrared light emitting LED unit 124 by the infrared reception sensor unit 144. The code contents are received and checked whether they match the code contents stored in the reception controller 142.

At this time, the receiving unit filters the high frequency modulation component loaded on the DC power line 600 to detect only the pure data signal and supplies it to the controller 160.

If the code contents match, the receiver prepares to receive from the transmitter 120. If the code contents do not match, or if there is no data, it is regarded as an intrusion and sends an alarm signal to the controller 160.

When all the code contents are transmitted, the transmission control unit 121 checks the data again through the DC power line 600 and receives new code contents from the transmission control unit 121.

4 is a schematic diagram illustrating an operation example of the controller 160. The controller 160 transmits a predetermined set value to the transmitter 120 and the receiver 140. The alarm is output through the alarm output unit 166 only when an alarm signal is transmitted from the receiver 140 or data is cut off.

The controller 160 continuously tries data communication with the transmitter 120 and the receiver 140 while the power is connected.

At this time, the CPU unit 161 located inside the controller to control all operations may increase the number of connections according to the situation.

The set value is to set the type of beam, the number of detection beams, the detection time, and so on. The type of beam is A TYPE (use 4 beams), B TYPE (use 6 beams), C TYPE (use 8 beams), D There are TYPE (using 10 beams) and E TYPE (using 12 beams), so the number of beams can be set according to the height of the window. The shape setting is made in the DIP SW1 162.

In addition, the number of detection beams is recognized as an intrusion when one is broken when one beam is set, an intrusion when two is broken when two beams are set, and an intrusion when three is broken when three beams are set. Decide whether you are sensitive or dull to respond to one. The detection beam number is set in the DIP SW2 163.

Detecting time is a kind of delay time setting that can be set in 0.25 second intervals from 1 step (0.5 seconds) to 7 steps (2 seconds). When the data is cut off by the set time, it is regarded as an intrusion and outputs an alarm signal, but there is a slight error in the delay time. The detection time is set in the DIP SW3 164.

FIG. 5 is a cross-sectional view illustrating the infrared light emitting LED unit 124 and the infrared receiving sensor unit 144. The spread prevention guide 522 and scattering incident prevention are prevented in each of the infrared light emitting LED 520 and the infrared receiving sensor 540. Providing the guide 542 can prevent the infrared beam 112 from spreading or scattering. The spread prevention guide 522 and the scattering incident prevention guide 542 may be used in various forms such as a cylindrical tube or a lens.

In addition, by connecting a simple circuit to adjust the length of the infrared light emitting LED unit 124 and the receiving sensor unit 144 and the number of infrared light emitting LED 520 and the infrared receiving sensor 540 can be installed according to the size of the window. In addition, since the transmission unit 120 and the receiving unit 140 can be rotated around an axis connected to the support, the position can be changed.

6 is a diagram illustrating a data flow according to the present invention, and by using a DC power line to transmit data, it is possible to prevent the line construction of the external connection device from becoming difficult and complicated.

As described above, the multi-beam infrared sensor according to the present invention compensates for the disadvantages of the conventional infrared sensor for intrusion detection, and can reduce costs because only one product using the present invention may be installed in a place where several should be installed. The system can be simplified by transmitting data through a DC power line without requiring a separate data line. In addition, the length can be adjusted by a simple circuit connection, and using the engraving PC in the sensor, the setting value can be changed as desired. In particular, the ripple effect can be widened as the intrusion space can be perfectly detected to maximize the efficiency of the security system.

Claims (9)

In the multi-beam infrared sensor comprising a control unit for defining and controlling a predetermined set value, a transmitter for controlling the infrared light emitting LED, and a receiver for controlling the infrared reception sensor, A CPU unit which is formed inside the controller to exchange setting values from the transmitter and the receiver; A power LED that is turned on when the power is connected to the CPU unit and blinks when an alarm occurs, An alarm output unit connected to the CPU unit and outputting an alarm when an alarm signal is input; A transmission control unit which is formed inside the transmission unit and assigns a sequence code and an identification code to the multiple beams; A selection unit for selecting one of a plurality of sequence codes and identification codes granted from the transmission control unit; A modulator for converting the infrared rays of the code selected by the selector into a modulated wave of 38 kHz, An infrared light emitting LED unit for transmitting infrared rays converted into modulation waves of 38 kHz by the modulating unit; A transmission LED which is connected to the transmission control unit and is turned on when it is synchronized with the reception unit; An infrared reception sensor unit formed inside the reception unit to selectively receive 38 kHz infrared rays transmitted from the infrared light emitting LED unit; A reception control unit for analyzing data received from the infrared reception sensor unit, the transmission control unit, and the CPU unit; The multi-beam infrared sensor connected to the reception control unit is configured to receive a LED lighted when the synchronization with the transmitter. The method of claim 1, The transmission control unit is to give an identification code generated random number during the infrared transmission, and to increase the recognition rate between the sensors individually when receiving the infrared multi-beam infrared sensor. The method of claim 1, And said infrared light emitting LED unit can connect a circuit to modify the length of said infrared light emitting LED unit and the number of infrared light emitting LEDs. The method of claim 1, And said infrared receiver sensor unit being capable of modifying the length of said infrared receiver sensor unit and the number of infrared receiver sensors by connecting a circuit. The method of claim 1, And said CPU unit is capable of modifying the number by connecting circuits. The method of claim 1, And said transmitting portion is rotatable about an axis connected to a support. The method according to claim 1 and 6, And the receiver is rotatable about an axis connected to a support. The method of claim 1, A multi-beam infrared sensor comprising a guide for preventing spreading of the infrared light emitting LED part. The method of claim 1, A multi-beam infrared sensor comprising a guide for preventing scattering incident on the infrared receiving sensor.