 |
| Place of Origin: | GERMANY |
| Brand Name: | LENZE |
| Certification: | CE |
| Model Number: | EVS9324-EKK100 |
| Minimum Order Quantity: | 1pcs |
|---|---|
| Packaging Details: | carton |
| Delivery Time: | in stock |
| Payment Terms: | T/T, Western Union, MoneyGram |
| Supply Ability: | 100pcs/week |
| LENZE: | LENZE | EVS9324-EKK100: | EVS9324-EKK100 |
|---|---|---|---|
| GERMANY: | GERMANY | Material: | Iron |
| Color: | Black | Temperature: | 20-90 |
| Dimension: | 80mm |
| based on the additionally obtained basic error and noise: • with "voltage", "current" and "resistance" by ±0.1 % |
|
| with "Thermal resistor Pt 100 Standard" by ±0.4 K • with "Thermal resistor Pt 100 Climatic" by ±0.3 K |
|
| • with "Thermal resistor Ni 100 Standard" by ±0.2 K • with "Thermal resistor Ni 100 Climatic" by ±0.1 K |
A detailed descrtion of the basic and operating error is available in the function manual The individual measured values are smoothed by filtering. The smoothing can be set in 4
levels for individual channels in STEP 7 (TIA Portal).
Smoothing time = Smoothing (k) x configured integration time
The following figure shows the time it takes for the smoothed analog value to reach
approximately 100% depending on the set smoothing. This is valid for all signal changes at
the analog input.None (smoothing = 1 x integration time)
② Weak (smoothing = 4 x integration time) *
③ Medium (smoothing = 16 x integration time) *
④ Strong (smoothing = 32 x integration time) *
* The smoothing time can increase by 1 x integration time.
Figure C-5 Smoothing time depending on the set smoothing level
The following table shows the time it takes for the smoothed analog value to reach
approximately 100% depending on the set smoothing and the set interference frequency
suppression.
Table C- 2 Smoothing time depending on the set smoothing level and interference frequency suppression
The cycle times (1 ms, 1.04 ms and 1.25 ms) result from the configured interference
frequency suppression. The cycle time is independent of the number of configured analog
channels. The values for the analog input channels are detected sequentially in each cycle.
Reference
For more information on conversion time, cycle time and conversion method, refer to thevEach analog value is entered left aligned into the tags. The bits marked with "x" are set to
"0".
Note
This resolution does not apply to temperature values. The digitalized temperature values are
the result of a conversion in the analog on-board I/O.The following tables list the decimal and hexadecimal values (codes) of the possible current
measuring ranges.
Table C- 8 Current measuring range ±20 mAThe following tables list the decimal and hexadecimal values (codes) of the possible
resistance-type sensor ranges.
Table C- 10 Resistance-type sensors of 150 Ω, 300 Ω and 600 Ω"Wire break" diagnostics enabled
• "Overflow/Underflow" diagnostics
enabled or disabled
("Wire break" diagnostics has a higher
priority than "Overflow/Underflow" diagnostics)
32767 7FFFH "Wire break" or "Cable break" diagnostics
alarm
• "Wire break" diagnostics disabled
• "Overflow/Underflow" diagnostics
enabled
-32767 8000 H • Measured value after leaving the underrange
• Diagnostics alarm "Low limit" violated
• "Wire break" diagnostics disabled
• "Overflow/Underflow" diagnostics
disabled
-32767 8000 H Measured value after leaving the underrangeWith suitable parameter assignment, events that occur trigger a diagnostics entry and a
diagnostics interrupt.
Table C- 15 Measured values for wire break diagnosticspresentation of analog values in the voltage output ranges
The tables below list the decimal and hexadecimal values (codes) of the possible voltage
output ranges.
Table C- 18 Voltage output range ±10 VThe tables below list the decimal and hexadecimal values (codes) of the possible current
output ranges.
Table C- 21 Current output range ±20 mA
Values CIf more than one degree of danger is present, the warning notice representing the highest degree of danger will
