PSI-MOS-DNET CAN/FO 660/EM

Fiber optic converter for DeviceNet and CANopen Data sheet 100514_en_04 co © PHOENIX CONTACT - 2010-01-28 Description The PSI-MOS-DNET CAN/FO… modular fiber optic transmission system enables the transmission of CAN-based bus systems such as DeviceNet or CANopen via fiber optics. up to 2800 m using HCS fiber, and up to 48 mode glass fiber. Please note that the specified distances ar performance of the optical interface of the converter in association with the type of op Please take into consideration the restrictio expansion due to the signal runtimes of the structure (see page 11). om po ne The main advantage of this system is the electrically isolated connection of bus devices, which prevents the negative effects of voltage equalization currents and electromagnetic interference on the bus cables. In addition, bus cable short circuits only affect the specific potential segment. This increases the overall availability of the system, and improves flexibility in terms of the design of the bus topology in a linear, star or tree structure. nt s. 1 m INTERFACE ec Up to 20 fiber optic modules can be connected side by side to form optical star couplers, which are tailored to the specific application. Cross-wiring within a modular star coupler is created automatically via the backplane. The integrated fiber optic diagnostics perm the optical transmission quality. A drop in t is indicated by an integrated early warning transmission errors can occur. If necessary automatically switches to a redundant path The PSI-MOS system can be used in a supp from 10 V DC to 58 V DC and in a tempera from -20°C to +60°C. on lin Depending on the required transmission distance, modules for polymer/HCS fiber or glass fiber cables can be combined. Polymer and HCS fiber cables can be assembled locally using fast connection connectors. The system supports transmission speeds from 10 kbps to 800 kbps. Depending on the set transmission speed, distances up to 100 m can be covered using polymer fiber, The devices are also equipped with compr diagnostic functions to increase system av simplify startup. This means that faulty seg disconnected selectively. If you have any technical problems, which you cannot resolve with the aid of this documentation, us during the usual office hours at: Phone: +49 - 52 35 - 31 98 90 Fax: +49 - 52 35 - 33 09 99 E-mail: interface-service@phoenixcontact.com Make sure you always use the latest documentation. It can be downloaded at www.phoenixcontact.net/catalog. This data sheet is valid for all products listed on the following page: 3 Technical data ......................................................................................................... 4 Safety regulations and installation notes.................................................................. 4.1 4.2 Supported network structures.................................................................................. Branch/point-to-point connections.......................................................................................... Linear structures..................................................................................................................... Star structures ........................................................................................................................ Tree structures ....................................................................................................................... m 5.1 5.2 5.3 5.4 co 5 Installation and operation ....................................................................................................... Installation in zone 2 ............................................................................................................... Function elements ................................................................................................... 7 Configuration ........................................................................................................... Basics for CAN-based networks............................................................................................. Configuring networks using PSI-MOS-DNET CAN/FO ... ....................................................... Configuration example ........................................................................................................... om 8.1 8.2 8.3 Connection notes..................................................................................................... 9.1 9.2 9.3 Assembly as an individual device in the control cabinet (stand-alone) ................................... Assembly in potentially explosive areas ................................................................................. Removal ................................................................................................................................. ec 9 ne Configuration rules................................................................................................... lin 8 Setting the DIP switches......................................................................................................... Activating the termination resistor (S5) ................................................................................... Activating the redundancy function (DIP 1)............................................................................. Setting the transmission speed (DIP 2 - 4) ............................................................................. po 7.1 7.2 7.3 7.4 nt s. 6 10 Cabling notes........................................................................................................... 100514_en_04 Connecting the supply voltage ............................................................................................... Connecting the data cables .................................................................................................... Wiring the switch contact........................................................................................................ Connecting the fiber optic cables ........................................................................................... on 10.1 10.2 10.3 10.4 PHOE Basic module for converting a CAN-based interface to a fiber optic interface for: 660 nm, for polymer/HCS fiber cable, F-SMA PSI-MOS-DNET CAN/FO 660 BM 2708054 850 nm, for glass fiber cable, B-FOC (ST®) PSI-MOS-DNET CAN/FO 850 BM 2708083 660 nm, for polymer/HCS fiber cable, F-SMA PSI-MOS-DNET CAN/FO 660 EM 2708067 850 nm, for glass fiber cable, B-FOC (ST®) PSI-MOS-DNET CAN/FO 850 EM 2708096 Extension module for converting a CAN-based interface to a fiber optic interface for: Type Bus cable for CANopen and DeviceNet, sold by the meter SAC-5P-920 End clamps CLIPFIX 35 Polymer fiber connectors (4 connectors in the set) PSM-SET-FSMA/4-KT Polishing set for polymer fiber connectors (required to assemble polymer fiber connectors) PSM-SET-FSMA-POLISH Fiber optic polymer fiber cable for indoor installation PSM-LWL-KDHEAVY 2744319 F-SMA HCS fiber connectors (4 connectors in the set) PSM-SET-FSMA/4-HCS 2799487 m Accessories Description nt s. co Order No. B-FOC (ST®) HCS fiber connectors (4 connectors in the set) ne PSM-SET-B-FOC/4-HCS Tool set for HCS connectors (B-FOC (ST®)) (required for HCS connector assembly) Tool set for F-SMA and SCRJ connectors (polymer fiber) Fiber optic HCS cable for indoor installation om Fiber optic HCS cable for outdoor installation 3022218 2799720 2799348 2708481 PSM-HCS-KONFTOOL 2799526 PSM-HCS-KONFTOOL/B-FOC 2708465 po Tool set for HCS connectors (F-SMA) (required for HCS connector assembly) 1511504 PSM-POF-KONFTOOL 2744131 PSM-LWL-HCS RUGGED-200/230 2799885 PSM-LWL-HCSO-200/230 2799445 PSM-LWL-GDM-RUGGED-50/125 2799322 PSM-LWL-GDO-50/125 2799432 Measuring device for fiber optic power measurement PSM-FO-POWERMETER 2799539 on lin ec Fiber optic glass fiber cable for indoor installation Fiber optic glass fiber cable for outdoor installation 100514_en_04 PHOE in screw terminal block optional redunda COMBICON plug block with 10 V to Nominal current consumption 100 mA, maximum (at 24 V DC) per basic module/extens Bus interface According to ISO/IS 11898 for DeviceNet and CANopen Connection 4-pos. COMBICON plug-in screw terminal block Via backplane of 120 Ω, integrated and can be connected Bus access method CSMA/CA m Bus termination resistor 10, 20, 50, 125, 250, 500, 800 kbps can be set via DIP swit 1000 m, maximum; shielded cables Optical interface According to technical guideline PNO No. 2.021 Transmission protocol co Data rate Transmission length B-FOC (ST®) F-SMA Wavelength 660 nm 850 nm Minimum transmission power (fiber type) -6.2 dBm (980/1000 μm) -5.1 dBm (200/23 -16.9 dBm (200/230 μm) -17.9 dBm (50/12 nt s. Connection method ne Receiver sensitivity Minimum -30.2 dBm om connectors General data Maximum configuration Electrical isolation Alarm output on Test voltage lin Cascading depth of fiber optic paths ec Runtime equivalent/bit delay Status and diagnostic indicators -32.5 dBm (50/12 -32.1 dBm (200/2 100 m with F-P 980/1000; 230 dB/km 2800 m with F-K 8 dB/km with qui 800 m with F-K 200/230; connectors 10 dB/km with quick mounting po Minimum transmission length including 3 dB system reserve -14.1 dBm (62.5/ 4200 m with F-G 4800 m with F-G 24 m per individual device/120 ns 20 individual devices per star coupler topology at 24 V 12 individual devices per star coupler topology at 12 V 60 fiber optic paths at 10 kbps, 30 at 20 kbps, 12 at 50 kb 3 at 250 kbps, 1 at 500 - 800 kbps Power supply//data interface 1.5 kVrms, 50 Hz, 1 min. 60 V AC/DC, 1 A, maximum; relay contact opens if VCC fails, the fiber optic performance limit is rea occurs at the fiber optic or copper bus interface Power supply (VCC), bus activity, fiber optic bar graph (F optic error (FO ERR) Housing material PA 6.6-FR, green Connection data for screw terminal blocks 0.2 mm2 ... 2.5 mm2 Ambient temperature Operation Storage/transport -20°C ... +60°C -40°C ... +85°C Humidity 10% ... 95%, no condensation Dimensions (W x H x D) 22.5 mm x 105 mm x 115 mm Degree of protection IP20 Weight 120 g, approximately 100514_en_04 PHOE 82 years Ambient temperature 40°C Vibration resistance 47 years 89 years 5g according to IEC 60068-2-6, 2.5 h each in x, y, and z Shock resistance 15g according to IEC 60068-2-27 with 11 ms pulse lengt Free fall 1 m without packaging according to IEC 60950 Air and creepage distances DIN EN 60664-1/VDE 0110-1, DIN EN 50178, DIN EN 6 UL/CUL 1604 Ex listed PROCESS CONTROL EQUIPMENT FOR H LOCATIONS Class I, Zone 2, AEx nC IIC co c U CE m Tests/approvals Conformity assessment according to Directive 94/9/EC X II (2) GD [EX op is] IIC (PTB 06 ATEX 2042u) X II 3G Ex nAC IIC T4 X nt s. Fiber optic interface as an associated item of equipment for zone 1 devices Assembly and operation of the device in zone 2 Electrostatic discharge (ESD) EN 61000-4-2 Air discharge Contact discharge EN 61000-4-3 po Electromagnetic HF field ne Conformance with EMC Directive 2004/108/EC and Low Voltage Directive 2006/95/EC Noise immunity test according to EN 61000-6-21 Amplitude modulation EN 61000-4-4 Signal Power supply Surge current load (surge) Conducted interference 10 V/m Criterion B2 2 kV/5 kHz EN 61000-4-6 Criterion A3 ec Power supply 6 kV Criterion A3 Criterion B2 EN 61000-4-5 Signal 8 kV om Fast transients (burst) Criterion B2 2 kV/5 kHz 1 kV/42 Ω 0.5 kV/2 Ω 10 V Noise emission of housing lin Noise emission test according to EN 61000-6-4 EN 550114 Class A5 EN 61000 corresponds to IEC 61000 Criterion B: Temporary adverse effects on the operating behavior, which the device corrects automatically. 3 Criterion A: Normal operating behavior within the specified limits. 4 EN 55011 corresponds to CISPR11 5 Class A: on 1 2 100514_en_04 Industrial application, without special installation measures. PHOE gn OV 0V Alarm ALR *) *) Bus management Line CAN C_H ALR 124Ω ye C_L ACT ALR rd ERR co C_L Shield Figure 1 0V C_H nt s. Backplane 24V FO line diagnostics rd ERR Redundancy management C_GND C_H Redundancy m 24V *) Data rate C_L C_GND Block diagram RM *) Only for basic Housing dimensions (in mm) on Figure 2 lin ec om po ne Housing dimensions ALR 100514_en_04 PHOE NOTE: Installation, operation, and maintenance may only be carried out by qualified specialist personnel. The device is designed for install 2 potentially explosive areas. Observe the specified conditions for use in explosive areas. When installing and operating the device, the applicable safety directives (including national safety directives), accident prevention regulations, as well as general technical regulations, must be observed. WARNING: Explosion hazard m Install the device in suitable hous protection, minimum, that mee requirements of EN 60079-15. co NOTE: The device must not be opened or modified apart from the configuration of the DIP switches. Observe the requirements of EN WARNING: Explosion hazard om po NOTE: The IP20 degree of protection (IEC 60529/EN 60529) of the device is intended for use in a clean and dry environment. The device must not be subject to mechanical strain and/or thermal loads, which exceed the limits described. Disconnect the block power supp – Snapping it on or disconnect – Connecting or disconnecting ne Do not repair the device yourself, replace it with an equivalent device. Repairs may only be carried out by the manufacturer. nt s. NOTE: The switches that can be accessed may only be actuated when the power supply to the device is disconnected. on lin ec For the safety data, please refer to the operating instructions and certificates (EC-type examination certificate, other approvals, if necessary). 100514_en_04 WARNING: Explosion hazard Only devices which are designed zone 2 potentially explosive area suitable for the conditions at the i location may be connected to the signal circuits in zone 2. WARNING: Explosion hazard The device must be stopped and removed from the Ex area if it is d subject to an impermissible load incorrectly or if it malfunctions. Installation in areas with a danger of du WARNING: Explosion hazard The device is not designed for in areas with a danger of dust explo If dust is present, install the devic approved housing. PHOE below. 5.1 Branch/point-to-point connections Two PSI-MOS…BM fiber optic basic modules can be used to easily convert a data link from copper cable to fiber optics. A PSI-MOS…BM basic module is used at the beginning and end of the line. BE B co m FO To increase system availability, the fiber optic line can also be designed redundantly. In this case, PSI-MOS…EM extension modules are connected either side of the basic modules and redundancy mode is configured. BE nt s. B Branch line / redundant branch line Linear structures PSI-MOS…BM basic modules are used at the beginning and end of the fiber optic line. ne 5.2 FO FO BE B B Star structures ...64x ...64x ...64x Linear structure lin 5.3 ec om po Combinations of basic modules and extension modules are used along the line as fiber optic repeaters. Depending on the transmission speed, up to 60 fiber optic paths can be cascaded (see "Configuration rules" on page 11). Modular fiber optic star couplers can be created by combining a basic module with up to 19 extension modules. A basic module should always be used at the end of a star line. on BEEE BEBE ...20 BE ...20 FO This structure again offers the option of combining basic modules and extension modules to form redundant circuits on critical lines in order to increase system availability. Modules with different transmission technologies (660 nm or 850 nm) can be freely combined within a star coupler topology. However, devices with the same transmission technology should always be used at the beginning and end of a fiber optic connection (PSI-MOS…660... or PSI-MOS…850...). B B B B BE BE BE Star structure / redundant star structure Please also refer to the configuration notes (see page 11) for the maximum network expansion. 100514_en_04 PHOE of up to 60 fiber optic segments can be achieved. BE E Please also refer to the configuration notes (page 11) for the maximum network expansion. BE E BE E FO B B B B B B 3 1 2 4 Des. 7 8 5 6 1 1 1 2 ec 1 4 Function elements 24 V DC supply voltage connection 0 V DC supply voltage connection Switch contact, connection 11 (basic module only) Switch contact, connection 12 (basic module only) CAN connection: SHD (basic module only) CAN connection: GND (basic module only) CAN connection: C_H (basic module only) CAN connection: C_L (basic module only) "VCC" LED "ACT" LED "RD" LED "FO SIGNAL" LED (3 LEDs) "FO ERR" LED Fiber optic transmitter Fiber optic receiver Backplane 100514_en_04 on 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 1 5 lin Figure 3 P S I-M O S 8 5 0 ... om 1 3 po 9 1 0 .../F O Color Green Flashing VCC green (1 Hz) OFF Yellow ACT OFF ERR Red Green FO Green SIGNAL Yellow ne 1 6 P S I-M O S .../F O 6 6 0 ... co Diagnostic and status indicators Function elements nt s. 6 m Tree structure FO ERR Mea Ready to operate Ready to operate mode in standby No supply voltag CAN bus active CAN bus not acti CAN bus error (c Receiving power at the fiber optic port Red The quality of the path is determined using optical power Popt and displayed using the LED bar graph Green Green Yellow Green Yellow Receive status Very good Yellow Critical Red Error Good Optical p Popt is consid than the sys Popt is still gre system Popt has reach rese Popt has sapp reserve/br In the event of a supply voltage failure, a cr receive level ("FO SIGNAL" = yellow) or an optic path ("FO ERR" = red), the floating w also opens (see "Wiring the switch contact PHOE disconnect the power to the devic settings can be applied. The device contains components that can be damaged or destroyed by electrostatic discharge. When handling the device, observe the necessary safety precautions against electrostatic discharge (ESD) according to EN 61340-5-1 and EN 61340-5-2. • o n nt s. on lin The DIP switches can then be freely accessed. • Configure the DIP switches according to the planned application. S 5 o ff (d e fa u lt) 7.4 S 5 Setting the transmission speed The transmission speed is set using DIP sw (default: 500 kbps). om ec Opening the housing Activating the redundancy func ne po 2 Figure 4 7.3 A PSI-MOS…BM basic module can be com PSI-MOS…EM extension module to create optic connections. • Place a basic module/extension modul both the beginning and end of the redu line. • On all the devices in a redundancy line "ON" to activate redundancy mode (de 1 1 If the PSI-MOS…BM basic module is used copper segment, the integrated termination activated. • Set slide switch S5 to the "ON" positio m For configuration, release the housing cover using a screwdriver (A in Figure 4). Then carefully pull the PCB out of the housing as far as possible (B). Activating the termination resis co • 7.2 NOTE: Set all fiber optic converte connected bus devices to the sam speed. Transmission speed (kbps) 10 20 50 125 250 500 800 2 OFF OFF OFF ON ON ON OFF DIP s 3 OF O O OF OF O OF S 1 ...S 4 Figure 5 100514_en_04 Setting the DIP switches PHOE use shielded two-wire cables for transmission. • Due to the CSMA/CA bus access method, the total network expansion is limited by the data rate used. This restriction also applies when the network is implemented with fiber optics. 5000 2500 m1 1000 m 500 m 250 m 100 m 50 m Only when using repeaters, otherwise copper ≤ 1000 m (paths) 60 30 12 6 3 1 1 co m1 • • po 1 – – – 500 m 250 m 100 m – Maximum FO cascading nt s. 10 kbps 20 kbps 50 kbps 125 kbps 250 kbps 500 kbps 800 kbps Maximum network expansion (copper) DeviceNet CANopen ne Data rate In some cases, several signal paths co considered the "critical line". In this ca points should be considered for each l Determine the total length of all coppe segments LCable, total and the number optic segments nFO in this line. Note the maximum cascadability of fib segments depending on the data rate Calculate the effective total length Leff, line. Add 48 m per planned fiber optic segm length LCable, total. (This delay is caused by signal runtime optic converters.) Leff, total = LCable, total + nFO x 48 m Finally, compare this calculated effect Leff, total with the maximum network ex data rate. If the effective total length is less than expansion, the CSMA/CA mechanism properly. m The bus devices are passively connected to the main bus cable, which must be terminated at the ends using termination resistors. om At the lowest data rate, the maximum expansion for a copper segment without repeater is 1000 m. 8.3 Configuration example In addition to the general conditions, which depend on the data rate (see Section 8.2), the following parameters should always be considered: – A maximum of 64 CAN devices can be operated per copper segment. – The maximum length of a fiber optic path from converter to converter is: – Polymer fiber: 100 m, maximum – HCS fiber: 800 m (660 nm) or 2800 m (850 nm), maximum – Glass fiber: 4800 m, maximum Basic FO on lin ec FO 8.2 Configuring networks using PSI-MOS-DNET CAN/FO ... When configuring a network using PSI-MOS-... modules, the signal delay caused by the fiber optic modules must be taken into account. This signal delay reduces the maximum transmission distance by 48 m per fiber optic segment used. When configuring your CAN installation, proceed as follows: 100514_en_04 PLC Figure 6 Configuration example CANopen, 125 kbps Leff, total = 20 m + 130 m Cu FO +3x A maximum network expansion of 500 m is selected data rate of 125 kbps. This config PHOE WARNING: Connect the DIN rail to protective earth ground using a grounding terminal block. The devices are grounded when they are snapped onto the DIN rail (installation according to PELV). • on Areas with a danger of gas explosions The devices are suitable for use in zon are installed in zone 1 can be connect optic interface. The fiber optic interface item of equipment with protection type Areas with a danger of dust explosions The devices are not designed for insta with a danger of dust explosions. If dust is present, install the device in su housing. When installed outside areas with a da explosions, devices installed in zone 2 be connected to the fiber optic interfac ne Place the device onto the DIN rail from above. The upper holding keyway of the device must be hooked onto the top edge of the DIN rail (see Figure 7). Push the device from the front towards the mounting surface. Once the device has been snapped on properly, check that it is fixed securely on the DIN rail. lin • om • – Assembly as an individual device in the control cabinet (stand-alone) ec 9.1 Assembly in potentially explosi WARNING: Observe the safety n – po This ensures that the shielding is effective. Connect protective earth ground with low impedance. 9.2 m • Install the device on a 35 mm DIN rail according to DIN EN 60715. To avoid contact resistance only use clean, corrosionfree DIN rails. End clamps can be mounted on both sides of the device to stop the devices from slipping on the DIN rail (for ordering data see page 3). sides of both modules lie flush with on Now push the other modules together as described above. co • • nt s. WARNING: PSI-MOS-... devices are designed for SELV operation according to IEC 60950/EN 60950/VDE 0805. 9.3 • • • • • Removal To remove a PSI-MOS… unit, the PSIon the right-hand side must be pushed the entire male connector/female conn released. Pull the locking latch down using a scre nose pliers or similar. Pull the bottom edge of the module aw mounting surface. Pull the module diagonally upwards aw rail. If removing a complete star distributor, rail connectors from the DIN rail as we X X X X A 0 0 4 Figure 7 100514_en_04 Assembly in the control cabinet PHOE DC SELV. Redundant supply G N D C _ H C _ L nt s. co S H D m Individual supply Figure 8 Individual/redundant supply • om Operation as an individual device po ne Figure 9 NOTE: Use CAN-compatible bus Connect the cable shielding at bo transmission path. Connect the CAN cable to the COMBI of the basic module. Contact 1 2 3 4 5 6 7 8 Supply the supply voltage to the module via terminal blocks 1 (24 V) and 2 (0 V). ec Operation in a star coupler topology on lin When the devices are operated in a star coupler topology, the supply voltage must only be supplied to the first device in the station. The remaining devices are supplied via the backplane. A redundant supply concept can be created by connecting a second power supply unit to another device in the topology. • 100514_en_04 Connecting the data cables Function +24 V +0V Switch contact connection Switch contact connection CAN_Shield CAN_GND CAN_High CAN_Low In a star coupler topology, the CAN da automatically forwarded to adjacent ex via the backplane. For optimum shield connection, use the connection clamp. PHOE E M co m - in fo B M E M Figure 10 e rro r e rro r Early warning contact on lin ec om po NOTE: The maximum load capacity of the relay contact is 60 V DC/42 V AC, 1 A. B M ne To create a single group message for an entire topology, the switching outputs (N/O contacts) should be connected externally in series. e rro r nt s. If several basic modules are used in a star coupler topology, a new group message segment begins at each basic module. This means that when redundant structures are used, each redundant line can be monitored separately for errors via its basic module. e rro r The switch contact on the basic module opens if one of the following occurs on the basic module itself or on a connected extension module: – The supply voltage fails – The optical threshold on the fiber optic path is not reached – The fiber optic path is interrupted e rro r modules connected to the right of the basic module as group messages via the backplane (Figure 10). 100514_en_04 PHOE the glass fibers. The infrared light is not visible. NOTE: Dust protection caps should only be removed just before the connectors are connected. They prevent contamination of the transmit and receive elements. 2 1 • PSI-MOS-DNET CAN/FO 660 ... – 100 m with F-P 980/1000; 230 dB/km – 800 m with F-K 200/230; 10 dB/km Measuring and connecting devices ne po PSI-MOS-DNET CAN/FO 850 ... – 2800 m with F-K 200/230; 8 dB/km – 4200 m with F-G 50/125; 2.5 dB/km – 4800 m with F-G 62.5/125; 3.0 dB/km • Connect the fiber optic cable to the B-F connector for the transmit and receive push the connector clamp mechanism Secure the connection with a quarter t (see 2 in Figure 12). nt s. NOTE: The following fiber optic lengths must not be exceeded: B-FOC connection co Figure 12 m The same applies for the protective caps on the connectors. om NOTE: When using fiber optics, observe the fiber optic installation guidelines, DB GB IBS SYS FOC ASSEMBLY (Order No. 9393909). Due to the integrated optical diagnostics, th measure the path. NOTE: Note the fiber optic cable when coupling two PSI-MOS dev Device 1 fiber connection "TD" (tr device 2 fiber connection "RD" (re (Figure 13). ec F-SMA connection (PSI-MOS-DNET CAN/FO 660 ...) NOTE: Due to different operating PSI-MOS-DNET CAN/FO 660 ... PSI-MOS-DNET CAN/FO 850 de not be connected directly with on fiber optic cables. on lin PSI-MOS-DNET CAN/FO 660 ... devices use F-SMA connectors for the fiber optic connection. F-SMA is a standardized fiber optic connection. 2 1 Figure 11 • F-SMA connection The connectors are secured on the device by manually tightening the screw collar (see 2 in Figure 11). 101973A00 Figure 13 100514_en_04 Crossed cables PHOENIX CONTACT GmbH & Co. KG • 32823 Blomberg • Germany • Phone: +49 - 52 35 - 30 0 PHOENIX CONTACT • P.O.Box 4100 • Harrisburg • PA 17111-0100 • USA • Phone: +717-944-1300 www.phoenixcontact.com