5
G.M. International ISM0112-10
D5291
- 10 A SIL 3 Relay Output Module for ND Load with ND or NE Relay condition
Application for D5291S - SIL Load Normally De-Energized Condition (ND) and Normally De-Energized Relay
Normal state operation
Energized to trip operation
Load
SIL3
13
- / AC
+ / AC
PLC
Output OFF
0 Vdc
15
14
Service Load
- / AC
+ / AC
Load
SIL3
PLC
Output ON
24 Vdc
13
15
14
Service Load
Functional Safety Manual and Applications
1)
Description:
Input Signal from PLC/DCS is normally Low (0 Vdc) and is applied to pins 1-2 or 3-4 in order to Normally De-Energize (ND) the internal relays.
Input Signal from PLC/DCS is High (24 Vdc) during “energized to trip” operation, in order to energize the internal relays.
The Load is Normally De-Energized (ND), therefore its safe state is to be energized; the Service Load is normally energized, therefore it de-energizes during
“energized to trip” operation.
Disconnection of the ND Load is done on only one load supply line.
The following table describes the status (open or closed) of each output contact when the input signal is High or Low.
Safety Function and Failure behavior:
D5291S is considered to be operating in Low Demand mode, as a Type A module, having Hardware Fault Tolerance (HFT) = 0.
In the 1st Functional Safety application, the normal state operation of relay module is de-energized, with ND (Normally De-Energized) loads.
In case of alarm or request from process, the relay module is energized (safe state), energizing the load.
The failure behaviour of the relay module is described by the following definitions:
□
fail-Safe State: it is defined as the output load being energized;
□
fail Safe: this failure causes the system to go to the defined fail-safe state without a process demand;
□
fail Dangerous: failure mode that does not respond to a demand from the process (i.e. being unable to go to the defined fail-safe state)
so that the output load remains de-energized;
□
fail “No effect”: failure mode of a component that plays a part in implementing the safety function but is neither a safe failure nor a dangerous failure.
When calculating the SFF this failure mode is not taken into account.
□
fail “Not part”: failure mode of a component which is not part of the safety function but part of the circuit diagram and is listed for completeness.
When calculating the SFF this failure mode is not taken into account.
Failure rate date: taken from Siemens Standard SN29500.
Failure rate table:
Failure rates table according to IEC 61508:2010 Ed.2 :
PFDavg vs T[Proof] table
(assuming Proof Test coverage of 99%), with determination of SIL supposing module contributes
≤
10% of total SIF dangerous failures:
PFDavg vs T[Proof] table
(assuming Proof Test coverage of 99%), with determination of SIL supposing module contributes >10% of total SIF dangerous failures:
Systematic capability SIL 3.
Operation
Input Signal
Pins 1-2 or 3-4
Pins
13 - 14
Pins
13 - 15
ND Load (SIL3)
Pins 14 — - / AC Supply
Service Load (Not SIL)
Pins 15 — - / AC Supply
Normal
Low (0 Vdc)
Open
Closed De-Energized
Energized
Trip
High (24 Vdc)
Closed
Open Energized
De-Energized
Failure category
Failure rates (FIT)
λ
dd
= Total Dangerous Detected failures
0.00
λ
du
= Total Dangerous Undetected failures
3.64
λ
sd
= Total Safe Detected failures
0.00
λ
su
= Total Safe Undetected failures
96.00
λ
tot safe
= Total Failure Rate (Safety Function) =
λ
dd
+
λ
du
+
λ
sd
+
λ
su
99.64
MTBF (safety function, single channel) = (1 /
λ
tot safe
) + MTTR (8 hours)
1145 years
λ
no effect
= “No effect” failures
302.96
λ
not part
= “Not Part” failures
0.00
λ
tot device
= Total Failure Rate (Device) =
λ
tot safe
+
λ
no effect
+
λ
not part
402.60
MTBF (device, single channel) = (1 /
λ
tot device
) + MTTR (8 hours)
283 years
MTTF
S
(Total Safe) = 1 / (
λ
sd
+
λ
su
) 1189
years
MTTF
D
(Dangerous) = 1 /
λ
du
31387 years
λ
sd
λ
su
λ
dd
λ
du
SFF
0.00 FIT
96.00 FIT
0.00 FIT
3.64 FIT
96.35%
T[Proof] = 1 year
T[Proof] = 6 years
PFDavg = 1.59 E-05 - Valid for
SIL 3
PFDavg = 9.57 E-05 - Valid for
SIL 3
T[Proof] = 20 years
PFDavg = 3.19 E-04 - Valid for
SIL 3
