Overview, Installation and alignment, 1 ossd output connections – Banner EZ-SCREEN Low-Profile Safety Light Curtain Systems User Manual

36

P/N 133487

Banner Engineering Corp.

•

Minneapolis, U.S.A.

www.bannerengineering.com • Tel: 763.544.3164

Overview

36

P/N 140044 rev.

E

Banner Engineering Corp.

•

Minneapolis, U.S.A.

www.bannerengineering.com • Tel: 763.544.3164

EZ-SCREEN LP

Instruction Manual

Installation and Alignment

3.5.1 OSSD Output Connections

Both the output signal switching device (OSSD) outputs must

be connected to the machine control so that the machine’s

safety-related control system interrupts the circuit or power to

the machine primary control element(s) (MPCE), resulting in a

non-hazardous condition.
Final switching devices (FSDs) typically accomplish this when

the OSSDs go to an OFF state. See Figure 3-24.
Refer to the output specifications in Section 2.7 and the

warnings on page 35 before making OSSD output connections

and interfacing the EZ-SCREEN LP to the machine.

3.5.2 FSD Interfacing Connections

Final switching devices (FSDs) can take many forms, although

the most common are forced-guided, mechanically linked relays

or an interface module. The mechanical linkage between the

contacts allows the device to be monitored by the external

device monitoring circuit for certain failures.
Depending on the application, the use of FSDs can facilitate

controlling voltage and current that differs from the OSSD

outputs of the EZ-SCREEN LP. FSDs can also be used to

control an additional number of hazards by creating multiple

safety stop circuits.

Safety Stop (Protective Stop) Circuits

A safety stop allows for an orderly cessation of motion for

safeguarding purposes, which results in a stop of motion

and removal of power from the MPCEs (assuming this does

not create additional hazards). A safety stop circuit typically

comprises a minimum of two normally open (N.O.) contacts from

forced-guided, mechanically linked relays, which are monitored

(via external device monitoring) to detect certain failures in order

to prevent the loss of the safety function. Such a circuit can

be described as a “safe switching point.” Typically, safety stop

circuits are either single-channel, which is a series connection of

at least two N.O. contacts; or dual-channel, which is a separate

connection of two N.O. contacts. In either method, the safety

function relies on the use of redundant contacts to control a

single hazard (if one contact fails ON, the second contact will

arrest the hazard and prevent the next cycle from occurring).

See Figure 3-24.
The interfacing of the safety stop circuits must be accomplished

so that the safety function can not be suspended, overridden,

or defeated, unless accomplished in a manner at the same or

greater degree of safety as the machine’s safety related control

system that includes the EZ-SCREEN LP.

The normally open safety outputs from an interface module

provide a series connection of redundant contacts that form

safety stop circuits for use in either single-channel or dual-

channel control. (See Figure 3-26.)

Dual-Channel Control

Dual-channel control provides the ability to electrically extend

the safe switching point beyond the FSD contacts. With proper

monitoring (i.e., EDM), this method of interfacing is capable of

detecting certain failures in the control wiring between the safety

stop circuit and the MPCEs. These failures include a short-circuit

of one channel to a secondary source of energy or voltage, or

the loss of the switching ability of one of the FSD outputs. Such

failures could lead to the loss of redundancy — or to a complete

loss of safety, if not detected and corrected.
The possibility of a failure to the wiring increases as the physical

distance between the FSD safety stop circuits and the MPCEs

increase, as the length or the routing of the interconnecting wires

increases, or if the FSD safety stop circuits and the MPCEs are

located in different enclosures. For this reason, dual-channel

control with EDM monitoring should be used in any installation

where the FSDs are located remotely from the MPCEs.

Single-Channel Control

Single-channel control uses a series connection of FSD contacts

to form a safe switching point. After this point in the machine’s

safety-related control system, failures can occur that would result

in the loss of the safety function (such as a short-circuit to a

secondary source of energy or voltage).
For this reason, single-channel control interfacing should be

used only in installations where FSD safety stop circuits and the

MPCEs are mounted within the same control panel, adjacent to

each other, and are directly connected to each other; or where

the possibility of such a failure can be excluded. If this can not

be achieved, then dual-channel control should be used.
Methods to exclude the possibility of these failures include, but

are not limited to:
• Physically separating interconnecting control wires from each

other and from secondary sources of power.

• Routing interconnecting control wires in separate conduit, runs,

or channels.

• Locating all elements (modules, switches, and devices under

control) within one control panel, adjacent to each other, and

directly connected with short wires.

• Properly installing multi-conductor cabling and multiple wires

through strain relief fittings. (Over-tightening of a strain-relief

can cause short-circuits at that point.)

• Using positive-opening or direct-drive components, installed

and mounted in a positive mode.