Phoenix Contact 1708 M12 POE User Manual

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User manual

FL SWITCH 1708 M12 POE

Order No. —

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2015-05-18

PHOENIX CONTACT 105648_en_01

FL SWITCH 1708 M12 POE

UM EN FL SWITCH 1708 M12 POE

—

Designation Version Order No. FL SWITCH 1708 M12 POE 2701883

User manual

Designation:

Revision:

Order No.:

This user manual is valid for:

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PHOENIX CONTACT

Please observe the following notes

User group of this manual

The use of products described in this manual is oriented exclusively to: – Qualified electricians or persons instructed by them, who are familiar with applicable

standards and other regulations regarding electrical engineering and, in particular, the relevant safety concepts.

– Qualified application programmers and software engineers, who are familiar with the

safety concepts of automation technology and applicable standards.

Explanation of symbols used and signal words

How to contact us

Internet Up-to-date information on Phoenix Contact products and our Terms and Conditions can be

found on the Internet at:

phoenixcontact.com

Make sure you always use the latest documentation. It can be downloaded at:

phoenixcontact.net/products

Subsidiaries If there are any problems that cannot be solved using the documentation, please contact

your Phoenix Contact subsidiary. Subsidiary contact information is available at phoenixcontact.com.

Published by PHOENIX CONTACT GmbH & Co. KG

Flachsmarktstraße 8 32825 Blomberg GERMANY

Should you have any suggestions or recommendations for improvement of the contents and layout of our manuals, please send your comments to:

tecdoc@phoenixcontact.com

This is the safety alert symbol. It is used to alert you to potential personal injury hazards. Obey all safety measures that follow this symbol to avoid possible injury or death.

There are three different categories of personal injury that are indicated with a signal word.

DANGER This indicates a hazardous situation which, if not avoided, will

result in death or serious injury.

WARNING This indicates a hazardous situation which, if not avoided, could

result in death or serious injury.

CAUTION This indicates a hazardous situation which, if not avoided, could

result in minor or moderate injury.

This symbol together with the signal word NOTE and the accompanying text alert the reader to a situation which may cause damage or malfunction to the device, hardware/software, or surrounding property.

This symbol and the accompanying text provide the reader with additional information or refer to detailed sources of information.

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Please observe the following notes

PHOENIX CONTACT

General terms and conditions of use for technical documentation

Phoenix Contact reserves the right to alter, correct, and/or improve the technical documentation and the products described in the technical documentation at its own discretion and without giving prior notice, insofar as this is reasonable for the user. The same applies to any technical changes that serve the purpose of technical progress.

The receipt of technical documentation (in particular user documentation) does not constitute any further duty on the part of Phoenix Contact to furnish information on modifications to products and/or technical documentation. You are responsible to verify the suitability and intended use of the products in your specific application, in particular with regard to observing the applicable standards and regulations. All information made available in the technical data is supplied without any accompanying guarantee, whether expressly mentioned, implied or tacitly assumed.

In general, the provisions of the current standard Terms and Conditions of Phoenix Contact apply exclusively, in particular as concerns any warranty liability.

This manual, including all illustrations contained herein, is copyright protected. Any changes to the contents or the publication of extracts of this document is prohibited.

Phoenix Contact reserves the right to register its own intellectual property rights for the product identifications of Phoenix Contact products that are used here. Registration of such intellectual property rights by third parties is prohibited.

Other product identifications may be afforded legal protection, even where they may not be indicated as such.

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Table of contents

1 Factoryline FL SWITCH 1708 M12 POE ....................................................................................7

1.1 Properties..............................................................................................................7

1.1.1 Dimensions of the FL SWITCH 1708 M12 POE .....................................7

1.1.2 Status and diagnostic indicators ............................................................8

2 Mounting and installation .........................................................................................................11

2.1 Mounting and removing the IP67 switch..............................................................11

2.2 Connections on the device ..................................................................................11

2.3 Installing the device .............................................................................................12

2.3.1 Connecting the supply voltage .............................................................12

2.3.2 Signal contact/diagnostic socket ..........................................................13

2.3.3 Assignment of the M12 Ethernet connections ......................................14

2.3.4 Selecting suitable data cables for PoE(+) applications ........................14

2.3.5 Cascading several FL SWITCH 1708 M12 POE switches ................... 14

2.3.6 Grounding ............................................................................................16

3 Startup and function .................................................................................................................17

3.1 Basic settings ......................................................................................................17

3.1.1 Delivery state/default settings ..............................................................17

3.2 Special notes regarding the use of PoE...............................................................17

3.3 Overload response and reset ..............................................................................17

3.3.1 Method of operation of the PSE system ...............................................18

3.3.2 Schematic view of the system and display behavior

in the event of overload ........................................................................ 19

3.4 Frame switching ..................................................................................................21

3.4.1 Store and forward ................................................................................21

3.4.2 Multi-address function ..........................................................................21

3.4.3 Learning addresses .............................................................................22

3.4.4 Prioritization .........................................................................................22

4 Technical data and ordering data .............................................................................................25

4.1 Technical data.....................................................................................................25

4.2 Ordering data ......................................................................................................28

A Appendixes...............................................................................................................................31

A 1 List of figures .......................................................................................................31

B 1 Index....................................................................................................................33

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1 Factoryline FL SWITCH 1708 M12 POE

1.1 Properties

The Gigabit Power over Ethernet switch, which is suitable for industrial applications, enables the common transmission of power and data according to IEEE 802.3at/802.3af via an Ethernet cable. Up to 30 W supply power per port is possible.

This means that termination devices such as WLAN or Bluetooth access points, IP phones or IP cameras can be connected quickly and inexpensively to the network, since the switch handles the power supply of the connected devices.

The device is a compact switch in a robust IP67 metal housing. It has eight 8-pos. M12 Ethernet connectors, which enable the supply of PoE/PoE+ devices and operation with speeds of 10/100/1000 Mbps. As it supports jumbo frames up to 9720 bytes, the switch is ideal for networking cameras.

A total power of 200 W is available for supplying up to eight PoE/PoE+ devices. The switch generates the 54 V DC required for Power over Ethernet according to IEEE 802.3at/802.3af from the 24 V module supply for the connected termination devices.

Features

– Eight PoE/PoE+ supply ports – No configuration required – Automatic detection of connected devices – Operation in networks with 10, 100, and 1000 Mbps supported – Convenient status and diagnostic indicators – Redundant 24 V supply possible – Quality of Service with up to six internal priority queues supported – MAC address table with up to 4000 MAC addresses – Jumbo frames with up to 9720 bytes supported

1.1.1 Dimensions of the FL SWITCH 1708 M12 POE

Figure 1-1 Dimensions of the device

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1.1.2 Status and diagnostic indicators

Des. Color Status Meaning

US1 Green On Supply voltage 1 within the tolerance range

Off Supply voltage 1 too low

US2 Green On Supply voltage 2 within the tolerance range

Off Supply voltage 2 too low

FAIL Red Group indication signaling that the system power has been exceeded (>200 W) or an

overload of one or more PDs or failure of the redundant power supply (see Figure 2-4 on page 12)

On 1st possibility: the current power consumption of all connected PDs was

>200 W at some point

2nd possibility: an overload occurred at a PD

3rd possibility: two voltage sources were connected to the device and a supply voltage failed

Off Since the last reset of the FAIL LED, the power consumption of all con-

nected PDs has not exceeded 200 W or no PD overload has occurred during this time or the redundant supply has not failed

LNK

(Link P1 - P8)

Green/ orange

On (green) Link with 10/100 Mbps active

On (orange) Link with 1000 Mbps active

Off Link not active

ACT

(Activity P1 - P8)

Green On (green) Transmitting/receiving telegrams with 10/100/1000 Mbps

Off Not transmitting/receiving telegrams

PoE

(P1 - P8)

Green PoE state of the connected PD

Flashing/1 x on every 2 s

No PoE/PoE+-capable PD detected or detection and classification are currently being carried out

On PoE-capable PD (max. 15 W) has been detected

Flashing/1 x off every 2 s

PoE+-capable PD (max. 30 W) has been detected

Flashing/

5 Hz

Port overloaded

Flashing/2 x

flashing

every 2 s

Port is not being supplied with power 1st possible reason: the connection/supply of this PD would have factored in the safety margin of 15% of the maximum system power 2nd possible reason: the PD was switched off in order to bring the total system load below 200 W again

PoE OUTPUT

(P1 - P5)

Green/

orange/

red

Power bar to indicate the current power output

P1 - P3 on

(green)

The higher the current power output, the more LEDs that light up

P4 on

(orange)

Lights up as soon as the total power consumption of all connected PDs is greater than around 145 W

P5 on

(red)

Danger that the safety margin may be exceeded: Starts to light up as soon as it is no longer possible to connect a Class 1 PD (4 W), so as to ensure that the safety margin of 15% of the total power is maintained (around 166 W)

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Mounting and installation

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2 Mounting and installation

2.1 Mounting and removing the IP67 switch

The device should be mounted on a flat, perpendicular mounting surface. The connectors/cables must be inserted from below. Secure the device using four screws, e.g., slotted cylinder head screws according to DIN EN ISO 1207-M6 x 16-8.8. For the drill hole spacing in mm, please refer to the drawing.

Figure 2-1 Spacing of the fixing holes

2.2 Connections on the device

Figure 2-2 Connections on the device

155

FLSWITCH IRT IP TX/3POF

Ord. No. 27 00 697

MAC -Address

X1 X2 X3 X4

US1

US2

FAIL

LNK

ACT

US1 GND US2 GND PEX6US1 GND US2 GND PE

R1 R2

MEM

00.A0.45.1B.D2.1D

Sno.: 200221439

signaling contact

power supply

8 gigabit ports

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2.3 Installing the device

2.3.1 Connecting the supply voltage

Power is supplied via a 4-pos., T-coded M12 power connector, which is designed for a current load of up to 12 A per pin. The supply voltage range is 18.7 - 30.5 V DC (24 V DC nominal value); the supply voltage can be connected redundantly. (See Figure 2-4)

Operation with one power supply

Figure 2-3 Operating the device with one power supply (example)

Redundant operation with two power supplies

Figure 2-4 Redundant operation with two power supplies (example)

Make sure that the power supply unit used meets the following basic requirements:

We recommend protecting the device with a 12 AT backup fuse (slow-blow). For appropriate fuse holders or thermomagnetic device circuit breakers, please refer to “Ordering data” on page 28.

1 2

4 3

24 V DC

12 AT

1 2

4 3

24 V DC

12 AT

24 V DC

12 AT

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– The 24 V outputs of the power supply unit are grounding-free and subject to the voltage

limitations of the SELV circuit according to IEC/EN 60950-1.

– Insulation requirements according to IEEE 802.3af (at), i.e., dielectric strength of the

secondary 24 V outputs leading to the (grounded) housing must be at least 1500 V AC at 50 to 60 Hz or 2250 V DC for one minute each.

– The power supply unit must be properly sized for the total occurring power (see “Tech-

nical data” on page 25).

Where the device is connected to a redundant power supply (two separate power supplies, see Figure “Redundant operation with two power supplies (example)” on page 12), both power supply units must comply with above requirements.

All devices operated on the external power supply unit must have a dielectric strength of at least 1500 V AC at 50 to 60 Hz or 2250 V DC for one minute each between their 24 V supply potentials on the one hand and between all conductive parts that can be touched on the other hand.

The power supply unit and the FL SWITCH 1708 M12 POE together are a current source with limited power (“limited power source” for the connected PDs according to

IEC 60950-1.

2.3.2 Signal contact/diagnostic socket

Signal contact The device has two floating signal contacts. An error is indicated when the contact is

opened.

Please note that load distribution does not take place. The device selects the supplying power supply unit independently.

In the case of non-redundant power supply, the switch indicates the failure of a supply voltage by opening the signal contact. You can prevent this by applying the voltage to both supply voltage connections in parallel, as illustrated in Figure 2-3 on page 12.

Table 2-1 Pin assignment of the diagnostic socket

Illustration Pin number Function

1 Signal contact 2 Digital input (DI) 3 Ext. GND 4 Signal contact 5n. c.

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2.3.3 Assignment of the M12 Ethernet connections

8-pos. M12 CAT6A sockets with X-coding are used as Ethernet connections. The supply voltage for the PDs is provided on the wire pairs that carry the signal.

According to IEEE 802.3at, this is an “end point PSE” of which the ports provide alternative A or B for phantom supply:

– Alternative A: ports X1 to X7 –Alternative B: port X8

2.3.4 Selecting suitable data cables for PoE(+) applications

A CAT5e cable with a minimum conductor cross section of 0.13 mm2 (AWG 26) is required to supply a PoE+ powered device with the maximum power of 25.5 W across the full distance of 100 m. Please only use shielded category CAT5e (or higher) cables.

2.3.5 Cascading several FL SWITCH 1708 M12 POE switches

For a direct line connection of type FL SWITCH 1708 M12 POE switches (referred to as cascading in the following), it is absolutely necessary that the supplied PoE voltage potentials of both PoE switches are decoupled on the common and connecting Ethernet data cable.

These voltage potentials can be isolated by using the previously mentioned PoE supply alternatives according to IEEE 802.3at, i.e., alternatives A and B.

For this, two PoE switches to be cascaded must only be connected to one another using port X1 to X7 connected to port X8 or vice versa. Connecting port X8 to port X8 or interconnecting ports X1 to X7, however, is not permitted.

A straight-through (1:1) Ethernet cable must be used for the direct line connection of the PoE switches in any case.

Table 2-2 Pin assignment of M12 connectors

Illustration Pin number 10Base-T/10 Mbps/

100Base-T/100 Mbps port 1 to port 7

1000Base-T port 1 to port 7

PoE/PoE+ port 1 to port 7

PoE/PoE+ port 8

1 RD+ (receive) DB+ - (0 V) 2 RD- (receive) DB- - (0 V) 3 TD+ (transmit) DA+ + (54 V) 4 TD- (transmit) DA- + (54 V) 5- DC+ + (54 V) 6- DC- + (54 V) 7 - DD- - (0 V) 8 - DD+ - (0 V)

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2.3.5.1 Installation specifications

• For connecting two cascaded PoE switches, only use the following configuration: only

connect ports 1 - 7 of switch 1 to port 8 of switch 2 or vice versa (see the following figure). Only connect a port from the area marked red to a port from the area marked green.

Figure 2-5 Correct cascading

Examples for incorrect cascading:

Figure 2-6 Incorrect cascading

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2.3.6 Grounding

All Factoryline devices must be grounded so that any possible interference is shielded from the data telegram and discharged to ground potential. A conductor of at least 2.5 mm² must be used for grounding. The functional earth ground connection must be established directly via the housing. Possible connection points are via the fixing points or by mounting on an grounded metal surface.

Grounding protects people and machines against hazardous voltages. To avoid these dangers, as far as possible, correct grounding, taking the local conditions into account, is vital.

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Startup and function

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3 Startup and function

3.1 Basic settings

3.1.1 Delivery state/default settings

The following functions and properties are available by default: – The available M12 ports are set to auto negotiation and autocrossing – The alarm contacts only open in the event of a PoE system or PD (powered device)

overload

– The MAC address table does not contain any entries

3.2 Special notes regarding the use of PoE

For easy configuration, the complete performance framework of PoE/PoE+ is available at all eight ports, provided the combined total power consumption of all connected powered devices (PDs) does not exceed 200 W. Otherwise, the internal PSE management system for the PoE switch makes sure that, starting with the port with the highest number (x8), the ports are deactivated by the system one at a time until the resulting total load falls below this threshold value again.

Maximum freedom and flexibility is ensured as it is possible to connect PoE as well as PoE+ loads at all eight ports. Thanks to the power status display, i.e., the power bar, you can determine at a glance how high the current power consumption is in relation to the maximum power provided. The last red LED on the bar starts to light up as soon as insufficient system power is available to connect a new class 1 PD (max. 4 W) to the system, since otherwise a safety margin of 15% of 200 W can no longer be maintained for the continued safe operation of the PoE loads already connected.

If at some point during operation there is an overload situation in the form of the total permissible PoE load of 200 W being exceeded or an overload of a connected PD, this is indicated by a FAIL LED being activated and by a signal contact being opened. Even after the system has independently removed these overload situations by switching off low-priority ports or by deactivating the overloaded PD, the FAIL LED is still active and the signal contact is still open. The signal contact can be reset manually via a digital input.

The PSE system of the PoE switch is designed so that it is possible, in principle, to use PoE/PoE+-capable powered devices (PDs) with a power consumption of up to 30 W each on all eight ports, provided the total PoE load of the switch does not exceed 200 W.

3.3 Overload response and reset

The diagnostic socket has a standard digital input (DI) and a relay output (N/O contact). The input and output are in the M12 connector integrated in the housing.

The relay opens the contact on the one hand as soon as the PoE power management system of the module finds itself in a PoE overload situation, i.e., as soon as the current total power consumption of all PDs rises above 200 W. In this case, the PDs are switched off one

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at a time, starting with port 8, until the resulting system load is below 200 W again. The PoE status LEDs of the PDs deactivated by the management system flash twice every 2 seconds.

Another reason why the contact may be opened is the overload of one or more connected PDs. This happens, for example, in the event of an error (e.g., short circuit) at a PD. The PoE port where the error occurred is disconnected by the power management system. The PoE status LED of the corresponding port indicates this state by flashing at 5 Hz. The port can only be supplied again when the cause of the overload has been removed and the PD has been reconnected to the device.

In addition, both overload responses are also indicated by the activation of the FAIL LED, which remains active, regardless of whether the PoE port has been reset, until the signal is reset by a High signal at the digital input (e.g., by using a key switch). Provided there is no other error state at the PoE ports at that time, the N/O contact closes again and the FAIL LED goes out.

3.3.1 Method of operation of the PSE system

The maximum total PoE power of the system that can be managed is 200 W.

A newly connected powered device (PD) is only supplied with power if the currently calculated power consumption of all devices plus the worst case power consumption of the new PD (4 W, 7 W, 15 W or 30 W depending on the classification) allows a power reserve of at least 15%.

As soon as the power consumption of the connected PDs exceeds the total power during operation, low-priority ports are switched off in order of priority until the resulting total power is no longer exceeded.

If the current power consumption exceeds the available total power by 10% or more, all lowpriority ports are instantly switched off.

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3.3.2 Schematic view of the system and display behavior in the event of overload

Example 1:

Power reserve: 200 W

Start of safety margin (200 W - 15%): 170 W

PD power consumption on system start 7 x PoE+ with 25 W each: 175 W

Number of active LEDs: 5

FAIL LED: Off

Relay: Closed

Figure 3-1 Example 1 of the display behavior

25W

PD4

25W

PD3

25W

PD2

25W

PD1

25W

PD6

25W

PD5

25W

PD7

Relais

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Example 2:

Power consumption at ports 3 - 7 increased to 30 W each: 200 W

Power consumption at port 1 increased to 26 W: 201 W

PD at port 7 is disconnected by the PSE system, the LED at port 7 flashes twice every 2 s

FAIL LED: On

Relay: Open

Total power falls to 171 W, but all PoE LEDs are still active

Figure 3-2 Example 2 of the display behavior

PD7 has since been removed, the FAIL LED and relay have been reset by a “High” signal at the DI.

30W

PD4

30W

PD3

25W

PD2

26W

PD1

30W

PD6

30W

PD5 PD7

Relais

Wird vom Management getrennt

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Example 3:

Overload by the PD at port 2

PD at port 2 is disconnected by the PSE system, the LED at port 2 flashes at 5 Hz

FAIL LED: On

Relay: Open

Total power falls to 146 W, the PoE LEDs of port 1 and port 3 to port 6 are active

Figure 3-3 Example 3 of the display behavior

3.4 Frame switching

The switch operates in store-and-forward mode. When receiving a data packet, the switch analyzes the source and destination addresses. The switch stores up to 4000 MAC addresses with an aging time of 40 seconds in its address table.

3.4.1 Store and forward

All data telegrams received by the switch are stored and checked for validity. Invalid or faulty data packets and fragments (<64 bytes) are rejected. Valid data telegrams are forwarded by the switch.

3.4.2 Multi-address function

The switch learns all the source addresses for each port. Only packets with: – Unknown source addresses – A source address for this port or – A multicast/broadcast address

30W

PD4

30W

PD3

PD2

26W

PD1

30W

PD6

30W

PD5 PD7

Relais Überlast

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in the destination address field are forwarded via the relevant port. The switch can learn up to 4000 addresses. This is important if more than one termination device is connected to one or more ports. Several independent subnetworks can be connected to one switch.

3.4.3 Learning addresses

The switch independently learns the addresses for termination devices, which are connected via this port, by evaluating the source addresses in the data telegrams. When the switch receives a data telegram, it forwards this da ta te legr am t o onl y tha t por t th at co nnec ts to the specified device (if the address could be learned beforehand). The switch can learn up to 4000 addresses and store them in its table. The switch monitors the age of the learned addresses. The switch automatically deletes address entries from its address table that have exceeded a specific age (default: 40 second aging time).

3.4.4 Prioritization

The switch supports four priority queues for adjusting the internal packet processing sequence (traffic classes according to IEEE 802.1D). Data telegrams that are received are assigned to these classes according to their priority, which is specified in the VLAN/prioritization tag:

– Data packets with the value “0” or “1” in the priority field are transmitted with the lowest

priority (default).

– Data packets with the value “2” or “3” in the priority field are transmitted with the second

lowest priority.

– Data packets with values between “4” and “5” in the priority field are transmitted with the

second highest priority by the switch.

– Data packets with values between “6” and “7” in the priority field are transmitted with the

highest priority by the switch.

Processing rules

The switch controller in the device forwards received packets to the available receive queues according to the following decisions:

– Packets with VLAN/prioritization tag are forwarded according to the queues listed

above.

– All remaining data is assigned to the low-priority queue.

3.4.4.1 Class of Service - CoS

Class of Service refers to a mechanism used to take into consideration the value of the priority field (values 1 to 7) in VLAN data packets with a tag. The switch assigns the data streams in various processing queues, depending on the priority information contained in the CoS tag. The switch supports four internal processing queues.

All learned entries are deleted on a restart. A link down deletes all the entries of the affected port.

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3.4.4.2 Quality of Service - QoS

Quality of Service affects the forwarding and handling of data streams and results in individual data streams being given differential treatment (usually preferential). QoS can be used, e.g., to guarantee a transmission bandwidth for individual data streams. The switch uses QoS in connection with prioritization (see CoS).

3.4.4.3 Flow control

Flow control can provide advantages during transmission in large network topologies in which peak loads are to be expected. The switch supports flow control.

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Technical data and ordering data

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4 Technical data and ordering data

4.1 Technical data

General data

Function Compact switch, Ethernet/Fast Ethernet/Gigabit switch; complies with

IEEE 802.3/802.3u/802.3ab

Switch principle Store and forward

Address table 4000 MAC addresses

Transmission capacity per port 64-byte packet size, half duplex

At 10 Mbps: 14880 pps (packets per second) At 100 Mbps: 148800 pps At 1000 Mbps: 1488000 pps

Housing dimensions (width x height x depth) in mm 176 x 112 x 100

Permissible operating temperature -40°C ... 70°C

Permissible storage temperature -40°C ... +85°C

Degree of protection IP65/67

Protection class Class 3 VDE 0106; IEC 60536

Humidity

Operation 5% to 95%, non-condensing

Storage 10% to 95%, non-condensing

Air pressure

Operation 86 kPa to 108 kPa, 1500 m above sea level

Storage 66 kPa to 108 kPa, 3500 m above sea level

Ambient compatibility Free from substances that would hinder coating with paint or varnish accord-

ing to VW specification

Mounting position Perpendicular on a flat surface / cable/connector insertion from below

Connection to protective earth ground By means of housing

Weight 2305 g, typical

Supply voltage (US1/US2 redundant)

Connection Via M12 connector; maximum conductor cross section = 2.5 mm

Nominal value 24 V DC

Permissible voltage range 18.7 V DC to 30.5 V DC

Permissible ripple (within the permissible voltage range) 3.6 V

Test voltage 2250 V DC for one minute between US1/US2 - FE/housing, US1/US2 - DI,

US1/US2 - signal contact

Current consumption at US at 24 V DC, maximum 290 mA (8 x Gigabit, without PD loads)

Maximum power consumption 7.0 W (8 x Gigabit, without PD loads)

17.0 W + maximum 200 W PD loads

Interfaces

Number of Ethernet ports 8

Floating signal contact

Voltage 24 V DC

Current carrying capacity 100 mA

Digital input

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Number 1

Connection method 2-wire technology

Input design According to EN 61131-2 type 1

Maximum low-level voltage <5 V

Minimum high-level voltage >15 V

Common potentials Supply, ground

Nominal input voltage 24 V DC

Permissible range 0 V to 30 V DC

Nominal input current 5 mA, typical

Interfaces (Fortsetzung)

Ethernet interfaces

Properties of the M12 ports

Number Up to 8 with auto crossing and auto negotiation

Connection format 8-pos. M12 socket on the switch

Connection medium Twisted-pair cable with a conductor cross section of 0.14 mm2 to 0.22 mm

Cable impedance 100 ohms

Transmission speed 10/100/1000 Mbps

Maximum network segment expansion 100 m

Mechanical tests

Shock testing according to IEC 60068-2-27 Operation: 30g,

half-sine shock pulse 3 shocks in each direction

Shock testing according to IEC 60068-2-27 Operation: 10g,

half-sine shock pulse 1000 shocks in each direction

Vibration resistance according to IEC 60068-2-6 Operation/storage/transport: 5g, 10 Hz ... 150 Hz

Free fall according to IEC 60068-2-32 1 m

Conformance with EMC directives

Developed according to IEC 61000-6-2

Noise emission according to EN 55022: 1998 + A1: 2000 + A2: 2003 (interference voltage)

Class B

Noise emission according to EN55011: 1998 + A1: 1999 + A2: 2002 (electromagnetic interference)

Class B

Noise immunity according to EN 61000-4-2 (IEC1000-4-2) (ESD)

Contact discharge: Air discharge: Indirect discharge:

Requirements according to DIN EN 61000-6-2

Test intensity 3, criterion A Test intensity 3, criterion A Test intensity 3, criterion A

Noise immunity according to EN 61000-4-3 (IEC 1000-4-3) (electromagnetic fields)

Requirements according to DIN EN 61000-6-2

Test intensity 3, criterion A

Page 27

Technical data and ordering data

105648_en_01 PHOENIX CONTACT 27

Noise immunity according to EN 61000-4-6 (IEC 1000-4-6) (conducted) Requirements according to DIN EN 61000-6-2

Test intensity 3, criterion A

Noise immunity according to EN 61000-4-4 (IEC 1000-4-4) (burst)

Data cables: Power supply:

Requirements according to DIN EN 61000-6-2

Test intensity 3, criterion A Test intensity 3, criterion A

Noise immunity according to EN 61000-4-5 (IEC 1000-4-5) (surge)

Data cables: Power supply:

Requirements according to DIN EN 61000-6-2

Test intensity 2, criterion B Test intensity 1, criterion B

Conformance with EMC directives

Additional certification

RoHS EEE 2002/95/EC - WEEE 2002/96/EC

Differences between this user manual version and previous versions

Rev. 00: First version

Rev. 01: Notes on cascading added, EMC data adapted

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FL SWITCH 1708 M12 POE

PHOENIX CONTACT 105648_en_01

4.2 Ordering data

Products

Accessories

Description Order designation Order No. Pcs./Pkt.

Gigabit Power over Ethernet switch (PoE, PoE+) suitable for industrial applications, complies with IEEE 802.3at

FL SWITCH 1708 M12 POE 2701883 1

Description Order designation Order No. Pcs./Pkt.

Network monitoring with HMI/SCADA systems FL SNMP OPC SERVER 2832166 1

Fuse terminal block, for cartridge fuse-link, cross section: 0.5 - 16 mm², AWG: 24 - 6, width: 12 mm, color: black

UK 10-DREHSILED 24 (5X20) 3005138 50

Lever-type fuse terminal block, black, for 5 x 20 mm cartridge fuse-links, with LED for 24 V DC

UT 4-HESILED 24 (5X20) 3046090 50

Thermomagnetic circuit breaker, 1-pos., for DIN rail mounting, 2 A UT 6-TMC M 10A 0916610 6

Network cable, Ethernet, 8-pos., PUR, RAL 5021 (water blue), shielded, straight M12-SPEEDCON/IP67 plug (X-coding) to free cable end, cable length: 1 m

NBC-MSX/ 1,0-94F SCO 1407467 1

Network cable, Ethernet, 8-pos., PUR, RAL 5021 (water blue), shielded, straight M12-SPEEDCON/IP67 plug (X-coding) to free cable end, cable length: 2 m

NBC-MSX/ 2,0-94F SCO 1407468 1

Network cable, Ethernet, 8-pos., PUR, RAL 5021 (water blue), shielded, straight M12-SPEEDCON/IP67 plug (X-coding) to free cable end, cable length: 5 m

NBC-MSX/ 5,0-94F SCO 1407469 1

Network cable, Ethernet, 8-pos., PUR, RAL 5021 (water blue), shielded, straight M12-SPEEDCON/IP67 plug (X-coding) to free cable end, cable length: 10 m

NBC-MSX/ 10,0-94F SCO 1407470 1

Network cable, Ethernet, 8-pos., variable cable type, shielded, straight M12SPEEDCON/IP67 plug (X-coding) to free cable end, cable length: free entry (0.2 ... 40.0 m)

NBC-MSX SCO-10G/.../... 1408648 1

Network cable, Ethernet, 8-pos., PUR, RAL 5021 (water blue), shielded, straight M12-SPEEDCON/IP67 plug (X-coding) to straight RJ45/IP20 plug, cable length: 1 m

NBC-MSX/ 1,0-94F/R4AC SCO 1407471 1

Network cable, Ethernet, 8-pos., PUR, RAL 5021 (water blue), shielded, straight M12-SPEEDCON/IP67 plug (X-coding) to straight RJ45/IP20 plug, cable length: 2 m

NBC-MSX/ 2,0-94F/R4AC SCO 1407472 1

Network cable, Ethernet, 8-pos., PUR, RAL 5021 (water blue), shielded, straight M12-SPEEDCON/IP67 plug (X-coding) to straight RJ45/IP20 plug, cable length: 5 m

NBC-MSX/ 5,0-94F/R4AC SCO 1407473 1

Network cable, Ethernet, 8-pos., PUR, RAL 5021 (water blue), shielded, straight M12-SPEEDCON/IP67 plug (X-coding) to straight RJ45/IP20 plug, cable length: 10 m

NBC-MSX/ 10,0-94F/R4AC SCO 1407474 1

Network cable, Ethernet, 8-pos., variable cable type, shielded, straight M12SPEEDCON/IP67 plug (X-coding) to straight RJ45/IP20 plug, cable length: free entry (0.2 ... 40.0 m)

NBC-MSX-R4AC SCO-10G/.../... 1408647 1

Network cable, Ethernet, 8-pos., PUR, RAL 5021 (water blue), shielded, straight M12-SPEEDCON/IP67 plug (X-coding) to straight RJ45 pushpull/IP67 plug, cable length: 1 m

NBC-MSX/ 1,0-94F/R4RC SCO 1407475 1

Network cable, Ethernet, 8-pos., PUR, RAL 5021 (water blue), shielded, straight M12-SPEEDCON/IP67 plug (X-coding) to straight RJ45 pushpull/IP67 plug, cable length: 2 m

NBC-MSX/ 2,0-94F/R4RC SCO 1407476 1

Network cable, Ethernet, 8-pos., PUR, RAL 5021 (water blue), shielded, straight M12-SPEEDCON/IP67 plug (X-coding) to straight RJ45 pushpull/IP67 plug, cable length: 5 m

NBC-MSX/ 5,0-94F/R4RC SCO 1407477 1

Network cable, Ethernet, 8-pos., PUR, RAL 5021 (water blue), shielded, straight M12-SPEEDCON/IP67 plug (X-coding) to straight RJ45 pushpull/IP67 plug, cable length: 10 m

NBC-MSX/ 10,0-94F/R4RC SCO 1407478 1

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Technical data and ordering data

105648_en_01 PHOENIX CONTACT 29

Hotline:

If there are any problems that cannot be solved using this documentation, please call our hotline:

+ 49 - (0) 52 81 - 946 28 88

Network cable, Ethernet, 8-pos., variable cable type, shielded, straight M12SPEEDCON/IP67 plug (X-coding) to straight RJ45 push-pull/IP67 plug, cable length: free entry (0.2 ... 40.0 m)

NBC-MSX-R4RC SCO-10G/.../... 1408646 1

Network cable, Ethernet, 8-pos., PUR, RAL 5021 (water blue), shielded, straight M12-SPEEDCON/IP67 plug (X-coding) to straight RJ45 pushpull/IP67 plug, cable length: 1 m

NBC-MSX/ 1,0-94F/R4QC SCO 1407479 1

Network cable, Ethernet, 8-pos., PUR, RAL 5021 (water blue), shielded, straight M12-SPEEDCON/IP67 plug (X-coding) to straight RJ45 pushpull/IP67 plug, cable length: 2 m

NBC-MSX/ 2,0-94F/R4QC SCO 1407480 1

Network cable, Ethernet, 8-pos., PUR, RAL 5021 (water blue), shielded, straight M12-SPEEDCON/IP67 plug (X-coding) to straight RJ45 pushpull/IP67 plug, cable length: 5 m

NBC-MSX/ 5,0-94F/R4QC SCO 1407481 1

Network cable, Ethernet, 8-pos., PUR, RAL 5021 (water blue), shielded, straight M12-SPEEDCON/IP67 plug (X-coding) to straight RJ45 pushpull/IP67 plug, cable length: 10 m

NBC-MSX/ 10,0-94F/R4QC SCO 1407482 1

Network cable, Ethernet, 8-pos., variable cable type, shielded, straight M12SPEEDCON/IP67 plug (X-coding) to straight RJ45 push-pull/IP67 plug, cable length: free entry (0.2 ... 40.0 m)

NBC-MSX-R4QC SCO-10G/.../... 1408645 1

Network cable, Ethernet, 8-pos., PUR, RAL 5021 (water blue), shielded, straight M12-SPEEDCON/IP67 plug (X-coding) to straight M12-SPEEDCON/IP67 plug (X-coding), cable length: 1 m

NBC-MSX/ 1,0-94F/MSX SCO 1407483 1

Network cable, Ethernet, 8-pos., PUR, RAL 5021 (water blue), shielded, straight M12-SPEEDCON/IP67 plug (X-coding) to straight M12-SPEEDCON/IP67 plug (X-coding), cable length: 2 m

NBC-MSX/ 2,0-94F/MSX SCO 1407484 1

Network cable, Ethernet, 8-pos., PUR, RAL 5021 (water blue), shielded, straight M12-SPEEDCON/IP67 plug (X-coding) to straight M12-SPEEDCON/IP67 plug (X-coding), cable length: 5 m

NBC-MSX/ 5,0-94F/MSX SCO 1407485 1

Network cable, Ethernet, 8-pos., PUR, RAL 5021 (water blue), shielded, straight M12-SPEEDCON/IP67 plug (X-coding) to straight M12-SPEEDCON/IP67 plug (X-coding), cable length: 10 m

NBC-MSX/ 10,0-94F/MSX SCO 1407486 1

Network cable, Ethernet, 8-pos., variable cable type, shielded, straight M12SPEEDCON/IP67 plug (X-coding) to straight M12-SPEEDCON/IP67 plug (Xcoding), cable length: free entry (0.2 ... 40.0 m)

NBC-MSX-MSX SCO-10G/.../... 1408644 1

M12 connector, CAT6A, plug, straight, 8-pos., shielded, for cable diameter of 4 mm ... 8 mm

VS-08-M12MS-10G-P SCO 1417430 1

Connector, universal, 4-pos., straight M12 socket, T-coded, screw connection, knurl material: zinc die-cast, nickel-plated, Pg11 cable gland, outer cable diameter of 8 mm ... 10 mm

SACC-M12FST-3PECON-PG11-M 1404644 1

Connector, universal, 4-pos., angled M12 socket, T-coded, screw connection, knurl material: zinc die-cast, nickel-plated, Pg11 cable gland, outer cable diameter of 8 mm ... 10 mm

SACC-M12FRT-4CON-PG11-M 1408989 1

Description (Fortsetzung) Order designation Order No. Pcs./Pkt.

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Page 31

Appendixes

105648_en_01 PHOENIX CONTACT 31

A Appendixes

A 1 List of figures

Figure 1-1: Dimensions of the device ......................................................................7

Figure 2-1: Spacing of the fixing holes ..................................................................11

Figure 2-2: Connections on the device .................................................................11

Figure 2-3: Operating the device with one power supply (example) ......................12

Figure 2-4: Redundant operation with two power supplies (example) ................... 12

Figure 2-5: Correct cascading ...............................................................................15

Figure 2-6: Incorrect cascading ............................................................................ 15

Figure 3-1: Example 1 of the display behavior ...................................................... 19

Figure 3-2: Example 2 of the display behavior ...................................................... 20

Figure 3-3: Example 3 of the display behavior ...................................................... 21

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Page 33

Index

105648_en_01 PHOENIX CONTACT 33

B 1 Index

Accessories ................................................................ 28

Aging time................................................................... 22

Air pressure................................................................. 25

Backup fuse ................................................................ 12

BPDU packets............................................................. 22

Class of Service .......................................................... 22

CoS............................................................................. 22

Default settings ........................................................... 17

Degree of protection ................................................... 25

Delivery state .............................................................. 17

Destination address .................................................... 21

Destination address field............................................. 22

Device circuit breaker.................................................. 12

Diagnostic indicators..................................................... 8

Diagnostic socket.................................................. 13, 17

Digital input ................................................................. 25

Dimensions ................................................................... 7

Drill hole spacing......................................................... 11

FAIL LED..................................................................... 17

Floating signal contact ................................................ 25

Flow control................................................................. 23

Fragments................................................................... 21

Frame switching.......................................................... 21

Functional earth ground .............................................. 16

Ground potential ......................................................... 16

Grounding ................................................................... 16

Hotline......................................................................... 29

Housing dimensions.................................................... 25

Humidity...................................................................... 25

IEEE 802.1D ............................................................... 22

IEEE 802.3at/802.3af.................................................... 7

Jumbo frames............................................................... 7

Learning addresses .................................................... 22

Load distribution ......................................................... 13

M12 port...................................................................... 26

M12 power connector ................................................. 12

MAC address table ....................................................... 7

Maximum power ......................................................... 17

Mounting surface ........................................................ 11

Multi-address function................................................. 21

Multicast/broadcast address....................................... 21

N/O contact................................................................. 17

Operating temperature................................................ 25

Ordering data.............................................................. 28

Overload ..................................................................... 17

Packet processing sequence...................................... 22

Performance framework.............................................. 17

Power bar.................................................................... 17

Power consumption .................................................... 25

Powered device .......................................................... 18

Prioritization ................................................................ 22

Prioritization tag .......................................................... 22

Priority field ................................................................. 22

Priority queues ........................................................ 7, 22

Processing rules ......................................................... 22

Protection class .......................................................... 25

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PHOENIX CONTACT 105648_en_01

QoS............................................................................. 23

Quality of Service........................................................ 23

Receive queue............................................................ 22

Relay output................................................................ 17

Reset .......................................................................... 17

Ripple.......................................................................... 25

Safety margin.......................................................... 8, 17

Signal contact ....................................................... 13, 25

Source and destination addresses.............................. 21

Storage temperature ................................................... 25

Store and forward........................................................ 21

Store-and-forward mode............................................. 21

Supply voltage range .................................................. 12

Threshold value .......................................................... 17

Traffic classes............................................................. 22

Transmission capacity ................................................ 25

VLAN/priority tag......................................................... 22

Weight......................................................................... 25