Series S Double Beam

Transcript

Installation And commissioning manual Series S Double Beam 2 3 Index Main component list Pag. 5 Installation reccomendations Pag. 6 Mounting the bracket Pag. 7 Installation example Pag. 8 Application example Pag. 9 Alignment Vertical alignment Horizontal alignment Pag. Pag. Pag. 10 10 10 Terminal connections for and to the P.C.B Pag. 11 Synchronism cabling Pag. 12 Set-up using the test points Factory setting for Tx and Rx sequence identification Pag. Pag. 13 16 Set up examples Pag. 17 P.C.B setting and programming Functional description of the Led's Description of jumper setting and characteristics Pag. Pag. Pag. 18 19 20 Technical specifications Pag. 22 4 Main component list 5 N° Part Q.tà 1 1 Mounting plate 2 1 Front cover 3 2 Front cover top/end caps 4 2 Trasmitter / receiver optic 5 1 Flat cable 6 1 Receiver / trasmitter P.C.B. Terminal board 7 1 P.C.B. 8 4 Bracket Descrizione Installation reccomendations • Verify that the beam tower is fully watertight once the cover and end caps have been correctly filled at the end of the installation. • Use the cable glands supplied on the tower for all cabling must pass through the lower end cap using the cable glands supplied. • Avoid any type of obstruction between the transmitter and receiver. • Avoid installing the receivers beams in a position where direct sunlight, at the same angle as the receivers beams, can enter directly into optics especially at sunset and sunrise • Do not install multiple beams where the transmitter beam can interfere with other receiver beams. It is always better place either transmitter or receivers back to back. • Do not use switched power supplies which can induce noise on the power supply voltage which can in turn be amplified by the optical sync electronics creating unwanted problems. 6 Mounting the bracket Insert the bracket back to mounting plate A palo Pole mounting Diameter 50 mm Wall mounting 7 Installation example Pole mounting Wall mounting Wall mounting With interposed brakets 8 Application example Tx Rx Tx Tx Rx Rx Rx Rx Tx Tx Application in couple TX/RX, crossed beams Rx Rx Tx Rx Rx Rx Tx Rx Rx Rx Tx Tx Application in couple, crossed beams Tx Tx Tx Rx Rx Rx Rx Rx Rx Rx Rx Rx Tx Rx Application in couple parallel beams Rx 9 Tx Tx Application in perimeter control Alignment Initial alignment Once beam columns have been correctly installed point the transmitter optics towards its corresponding receiver and vice versa, repeat for all the beam pairs. This is achieved by manually positioning the lens holder horizontally and vertically using one of the two screws (which ever is more convenient) to be found above the lens. Horizontal alignment Vertical alignment 10 Terminal connections for and to the P.C.B. +12 Vdc 24 Vac -12 Vdc 24 Vac TMP G.IN TMP AND BEAM NA NC RL2 SGN LOW ANTIMASK C +S.OUT +S. IN -S.OUT -S.IN 12 Vcc (direct current) supply + 12 Vdc -12 Vdc 24 Vac Tamper circuit TMP G.IN 24 Vac TMP AND Bypass temporaneo della barriera Remote AND with +12 beams 1 and 2 interrupted -12 AND random BEAM +12 Beam 1 Interrupted -12 Beams 1 and 2 Interrupted NA change over relay Heat power supply NC SGN LOW Enviroment disqualification C Sync Input Rx +S.IN -S.IN ANTIMASK Antimasking +S.OUT Sync Output Tx -S.OUT CCTV camera connections CCTV camera connections 75 ohm coax cable 75 ohm coax cable 2 /2/4 4 xx0,22 0,22 Screened Multi-core cable 2 x 0,75 8/10 x 0,22 11 2 / 4 x2/4 0,22 x 0,22 2 x 1,5 Synchronism cabling Arrangement Tx/Rx synchronism connection Tx4 Tx4 Rx4 Tx4 Rx4 Rx4 Tx3 Tx3 Rx3 Tx3 Rx3 Rx3 Tx2 Tx2 Rx2 Tx2 Rx2 Rx2 Tx1 Tx1 Rx1 + - Sincr In Sincr + Out - Tx1 Rx1 Rx1 + - Sincr In Sincr Out + - + - Sincr In Sincr Out + - Synchronisms out are the transmitters which are connected with receivers to which synchronism In have to be linked. 12 Set-up using the test points It is necessary to put the transmitter PBC into test mode in order to complete the alignment. Phase 1 Insert into ON position the TEST P SET Link on the main transmitter PCB Phase 2 Move in OFF the dip switch corresponding to the beam to be aligned. Phase 3 Connect the Voltmeter, using the cable supplied, to the corresponding receiver test point, move the transmitter optics slightly in both axes (horizontal and vertical) until the maximum voltage is obtained. Repeat with receiver optics. Phase 4 Once the alignement is obtained replace the dip switch in ON Phase 5 Repeat the above procedure for all beam pairs after which reinsert, into OFF position the TEST P SET Link. 13 Transmitter 14 Receiver 15 Factory setting for Tx and Rx sequence identification It is necessary to put the transmitter PBC into test mode in order to complete the alignment. Phase 1 Insert into ON position the TEST P SET Link on the main transmitter PCB Phase 2 Move in OFF the dip switch corresponding to the beam to be aligned. Phase 3 Connect the Voltmeter, using the cable supplied, to the corresponding receiver test point, move the transmitter optics slightly in both axes (horizontal and vertical) until the maximum voltage is obtained. Repeat with receiver optics. Phase 4 Once the alignement is obtained replace the dip switch in ON Phase 5 Repeat the above procedure for all beam pairs after which reinsert, into OFF position the TEST P SET Link.Per la taratura completa del dispositivo occorre porre la scheda a dei trasmettitori in test Verifing on the tester at the Test Point RX Reading without Signal 0,20V Reading with signal From 3 From 6 to 4V to 7V 0,40V Use the cable supplied In alignement always obtain the maximum value Phase 3 16 Set up examples Jumper TEST POINT SET on Transmitters main P.C.B. Tx into ON Position Move the dip switch 1 in OFF Tx1 Replace in ON after each set up Move the dip switch 2 in OFF Tx2 Replace in ON after each set up Tx3 Move the dip switch 3 in OFF Replace in ON after each set up Tx4 Move the dip switch 4 in OFF Replace in ON after each set up Reinsert the Jumper TEST POINT SET into OFF position at the end of set up 17 P.C.B setting and programming Attention for 3 RX version only Jumper beam exclusion ray 1 Attention for 2 RX version only Jumper beam exclusion ray 1 + 2 18 Functional description of the led’s The five LED’s on the PCB give system status indication. Placing the appropriate link into the ON position can enable these LEDs. It is good practice, to increase security, to place the jumper (link) into the OFF position, once the beams have been set-up. LED MASK Indicates BEAM MASKING. The MASK will light or flash if an extraneous modulated IR source greater than that of the transmitter is detected by receiver electronics. If the ANTIMASK link is in the ON position an alarm condition will be generated when such IR source is detected. N.B.: the LED should be OFF in the quiescent condition. If it is either on or flashing check the TX beam set-up. LOW SIG LED Low signal (ENVIROMENT DISQUALIFICATION). When the LOW SIG. led lights up, this indicates the presence of INTENSE FOG. In the case of intense fog, before the missing signal alarm conditions are triggered, the LOW SIG led lights up and the Enviroment Disqualification output signal will be on the terminal board (OPEN COLLECTOR). N.B.: When the LOW Sig jumper is in ON position, and when the OPEN Disqualification intervenes, the barrier is excluded, returning to normal function as soon as the fog lifts. LED ALM Alarm confirmation LED. Normally OFF indicates and alarm when lit. The condition on the SANDOR is dependent how the links are set on the RX P.C.B the delay (between 50 mSec and 500 mSec) set on the on target SPEED trim pot. LED HTR Confirms that the system heaters are ON. The PARVIS beam are equipped with automatic electronic thermostatically controlled heaters, which guarantee an operating temperature within the housing between 17°C e i 22°C. The Led is normally OFF and ON when the heaters are ON. POWER POWER ON LED. The Power on LED is always ON and indicates that the that the supply voltage to the PCB is correct. SINC LED Confirms that synchronism system is ON. The Sinc LED is always FLASHING and indicates that the synchronism connection is correct. 19 Description of characteristics jumper settings and The PCB can be set-up in a number of different configurations that are selected using the appropriate Links. LEDS When this jumper is ON , the leds are activated. AND 1 + 2 This configuration can be useful when tall grass and small animals are present . The function can also be programmed through remote control, by entering a positive command + 12V on the terminal marked AND on the terminal board BEAM OFF 1 The first beam at the bottom can be excluded, while the remaining beams continue to function . The function can also be programmed through remote control, by entering a positive command + 12V on the terminal marked BEAM on the terminal board BEAM OFF 1 + 2 The first two beams at the bottom can be excluded, while the remaining beams continue to function The function can also be programmed through remote control, by entering a negative command + 12V on the terminal marked BEAM on the terminal board RND DLY ON Each time the alarm is triggered with a random delay that varies between 0 and 1 seconds. This function is used to confuse and deceive any intruder who wishes to identify the sensor system. RND DLY OFF Alarm command output is generated in real time. TEST P. SET During the alignment stage, the bridge must be set in ON position in order to block the transmission sequence so that it will not generate signals that can disturb the alignment value readings. On completion of the single beam alignment operation, the bridge should return to the normal OFF function condition. 20 SINC ON : WIRE Function programmed in wire synchronism (always maintain in this position). G.IN TEMPORARY BLOCK TERMINAL BOARD. COMMAND ENVISAGED ON THE The alarm signal may be delayed for a time of about 60 seconds. This function is achieved providing a input to the terminal “G.IN”. An impulse sent to the negative will block the barrier alarm output for a period of about 60 seconds. This command is used when beams need to be crossed to enter or exit without triggering the alarms, and without the need for disconnecting and reconnecting the installation, that requires bringing the keyboard or keys outside the protected area. SETTING MODELS 3 RX Jumper setting on optical is modified as follows: For Rx optical Numbering starts from 2 - 3 -4 For Tx optical Numbering starts from 7 - 8 - 9 The Jumper beam on the PCB in exclusion 1 SETTING MODELS 2 RX Jumper setting on optical is modified as follows: For Rx optical Numbering starts from 3 -4 For Tx optical Numbering starts from 8 - 9 The Jumper beam on the PCB in exclusion 1 + 2 21 Technical specifications Max range 1350 m. Max range indoors 450 m. Max range outdoors 100 m. Synchronization wire Optical sensors Synchronised beams, twisted pair connection Enviroment Disqualification Automatic with signal towards exterior. Masking masked sensoring with another infrared signal, with signaling towards exterior Operating temperature - 25°C / + 65°C Alignment angle ± 10° Vertical Detection system And/Or on Tx e Rx / AND 1° e 2° beam Detection output Random can be inserted Piloting AND REMOTE / AND 1° e 2° beam External cover IR trasparent plastic Top Cap Tamper protected Protection rating IP 54. – 180° Horizontal Model 9200 9400 9600 9800 Total number of beams 2TX + 2RX 4TX or 4 RX 3TX + 3RX 4TX + 4RX Power requirements 12-16Vdc. Power consumption for tower 120 mA Internal heaters 30W 24Vac termostatically controlled 120 mA 125 mA 30W 24Vac 40W 24Vac termostatically termostatically controlled controlled 22 140 mA 50W 24Vac termostatically controlled 23 POLITEC s.r.l. Via Adda 66/68 – 20040 – Bellusco (Mi) – Italia Tel. + 39.(0)39.6883019 r.a. – Fax + 39.(0)39.6200471 www.politecsrl.it - E mail: [email protected] R 1.0 24