LENZE EVS9323-EKK100 EVS9323-EKK100 EVS9323-EKK100 EVS9323-EKK100 EVS9323-EKK100

1: Error
ERR_OUT_VAL The value in OUTPUT_VALUE is invalid 0: No error
1: Error
ERR_SLOT_VAL The value in SLOT is invalid, where MODE_SLOT =
1 (permanent updating)+24 V DC of the supply voltage
② Ground of the supply voltage
③ Ground of the supply voltage for loop-through (maximum of 10 A permitted)
④ +24 V DC of the supply voltage for loop-through (maximum of 10 A permitted)
⑤ Spring-loaded NC contact (one spring-loaded NC contact per terminal)
Bridged internally:
① and ④
② and ③
Figure 4-1 Connection for supply voltage
If the CPU is supplied by a system power supply, it is not necessary to connect the 24 V
supplyThe assignment corresponds to the Ethernet standard for an RJ45 plug.
● When autonegotiation is deactivated, the RJ45 socket is allocated as a switch (MDI-X).
● When autonegotiation is activated, autocrossing is in effect and the RJ45 socket is
allocated either as data terminal equipment (MDI) or a switch (MDI-X)For more information on "Wiring the CPU" and "Accessories/spare parts", refer to the S7-
1500, ET 200MP system manual The CPU 1511C-1 PN has a PROFINET interface with two ports. The PROFINET interface
itself has a MAC address, and each of the two PROFINET ports has its own MAC address.
The CPU 1511C-1 PN therefore has three MAC addresses in total.
The MAC addresses of the PROFINET ports are needed for the LLDP protocol, for example
for the neighborhood discovery function.
The number range of the MAC addresses is continuous. The first and last MAC address are
lasered on the rating plate on the right side of each CPU 1511C-1 PN.
The table below shows how the MAC addresses are assigned.
Table 4- 1 Assignment of the MAC addressesThis section contains the block diagram of the analog on-board I/O (X10) and various wiring
options.
For information on wiring the front connector, establishing the cable shield, etc., refer to the
, ET 200MPVoltage input channel n (voltage only)
Mn+/Mn- Measuring input channel n (only resistance-type transmitters or thermal
resistors (RTD))
In+/In- Current input channel n (current only)
Ic n+/Ic n- Current output for RTD, channel n
QVn Voltage output channel
QIn Current output channel
MANA Reference potential of the analog circuit
CHx Channel or display of the channel statusThe analog on-board I/O does not require power to be supplied by the infeed element. The
infeed element is, however, necessary for shieldingThe following figure shows the terminal assignment for voltage measurement at the channels
available for this measurement type (channels 0 to 3).Analog-to-digital converter (ADC)
② LED interface
③ Infeed element (for shielding only)
④ Digital-to-analog converter (DAC)
⑤ Equipotential bonding cable (optional)
⑥ Voltage measurement
Figure 4-4 Block diagram and terminal assignment for voltage measurementAs an alternative to connecting a 4-wire measuring transducer, you can also connect 2-wire
measuring transducers to channels 0 to 3. An external 24 V power supply is required to
connect a 2-wire measuring transducer to the analog on-board I/O of the compact CPU.
Feed this voltage short-circuit proof to the 2-wire transducer. Use a fuse to protect the power
supply unit.
NOTICE
Defective measuring transducer
Note that the analog input of the measuring transducer is not protected against destruction
in the event of a defect (short circuit). Take the necessary precautions against such cases.
The figure below shows an example of the connection of a 2-wire measuring transducer toAnalog-to-digital converter (ADC)
② LED interface
③ Infeed element (for shielding only)
④ Digital-to-analog converter (DAC)
⑤ Equipotential bonding cable (optional)
⑥ 4-wire connection
Figure 4-7 Block diagram and terminal assignment for 4-wire connectionThe following figure shows the terminal assignment for 3-wire connection of resistance-type
sensors or thermal resistors at the channel available for this (channel 4).
Note
3-wire connection
Note that line resistances are not compensated with a 3-wire connection.
The following figure shows the terminal assignment for 2-wire connection of resistance-type
sensors or thermal resistors at the channel available for this (channel 4).
Note
2-wire connection
Note that line resistances are not compensated with a 2-wire connection.The figure below shows the terminal assignment for the wiring of the voltage outputs with:
● 2-wire connection without compensation for line resistancesAnalog-to-digital converter (ADC)
② LED interface
③ Infeed element (for shielding only)
④ Digital-to-analog converter (DAC)
⑤ 2-wire connection CH0 and CH1
Figure 4-10 Block diagram and terminal assignment for voltage output