The following parameters can be set in the 'ABULiner' parameter level of the LIS-SV.
|
Parameter |
Designation |
See |
|
5.10 |
Calling up the parameter level |
|
|
5.11 |
Activating the LIS-SV for the ABULiner |
|
|
5.11 |
Setting the gear ratio |
|
|
5.12 |
Activating double lifting speed |
|
|
5.14 |
Setting the run-on time of the auxiliary fan |
|
|
Danger during setting work! During setting work on the LIS-SV, monitoring of the wire rope hoist is switched off. This means the wire rope hoist cannot be monitored for excess load, among other things. This means the wire rope hoist cannot be monitored for excess load, among other things. This in turn means the load could fall and kill or injure people! Do not use the crane for normal work during setting work, and only lift loads very carefully for test purposes! |
All LIS-SV parameters which are important for the ABULiner are combined in a separate parameter level, which is shown as a submenu.
|
|
Move the load hook out of
the limit switch range (up or down).
During parameter setting, the load hook must not be within the limit switch range.
Open the menu of the
LIS-SV. See the documentation “Load indicator system LIS-SV”.
|
| |
|
Enter button |
Arrow buttons |
Select parameter 5.10.
Press ENTER.
● The 'ABULiner' parameter level is activated.
● Parameter 5.11 is displayed.
|
| |
|
Enter button |
Arrow buttons |
Select parameter 5.99.
Press ENTER.
● The previous parameter level is reactivated.
● Parameter 5.10 is displayed.
The LIS-SV is automatically activated for the ABULiner if a value is entered for the parameter 5.11.
In the ABULiner mode (a value is set for parameter 5.11):
─ The LIS-SV can monitor the total load for a maximum of two wire rope hoists.
─ Input F3 (normally used for measuring the load of wire rope hoist 3) now serves in monitoring the current rotational frequency of the hoist motor.
─ A value can be entered for parameter 3.0 (maximum load capacity of wire rope hoist 3). If a value is entered for this, parameter 5.11 cannot be set.
─ This interlocking thus excludes an incorrect setting.
─ The load-controlled switching point at output TxD of the LIS-SV cannot be used.
─ Parameter 4.5 (setting for load-controlled switching point) is not available.
In the normal mode (no value is set for parameter 5.11):
─ Operation of the ABULiner Lifting/Lowering unit is not possible.
─ The LIS-SV can monitor the total load for up to three wire rope hoists.
─ Input F3 serves in measuring the load of a third wire rope hoist.
─ A value can be entered for parameter 5.11 (gear ratio). If a value is entered for this, parameter 3.0 cannot be set.
─ This interlocking thus excludes an incorrect setting.
─ The load-controlled switching point at output TxD of the LIS-SV can be used.
─ Parameter 4.5 (setting for load-controlled switching point) can be used.
The LIS-SV uses the signal of the encoder and the gear ratio of the hoisting gear to calculate the hook travel distance, the maximum distance in the limit switch range and the current rotational frequency of the hoist motor. The gear ratio must be set on the machine.
|
| |
|
Cable speed |
|
Read off the type
designation at the type plate of the wire rope hoist.
Read off the cable
speed.
From this table, select
the gear ratio that matches the cable speed.
|
Cable speed | |||||
|
Hoist motor GM |
32 m/min at 50 Hz |
25 m/min at 50 Hz |
20 m/min at 50 Hz |
16 m/min at 50 Hz | |
|
800.4 |
50.01 |
63.49 |
77.77 |
98.16 | |
|
800.5 |
47.03 |
60.04 |
74.66 |
95.03 | |
|
1000.6 |
54.43 |
68.91 |
84.00 |
105.1 | |
|
1000.7 |
54.60 |
68.06 |
81.45 |
104.6 | |
|
2000.3 |
58.22 |
74.23 |
91.19 |
118.4 | |
|
3000.4 |
73.61 |
93.92 |
118.4 |
152.9 | |
|
5000.3 |
85.14 |
109.3 |
132.8 |
169.0 | |
|
5000.4 |
80.20 |
104.9 |
127.7 |
160.6 | |
|
6000.3 |
94.69 |
118.5 |
149.6 |
182.7 | |
|
7000.1 |
118.0 |
148.3 |
182.6 |
232.0 | |
Table: Gear ratios (numerical values) depending on hoist motor (lines) and cable speeds (columns) at 50 and 60 Hz.
|
| |
|
Enter button |
Arrow buttons |
Move the load hook out of
the limit switch range (up or down).
During parameter setting, the load hook must not be within the limit switch range.
Select parameter 5.11.
Press ENTER.
● The set value is displayed.
If the value is 0.00, the function is deactivated.
● Hold ENTER pressed.
● CODE is displayed.
Hold ENTER pressed.
|
| |
|
Enter button |
Arrow buttons |
Enter the code 1443.
Press ENTER briefly.
|
| |
|
Enter button |
Arrow buttons |
Set the value from the
table.
If the display ‘0.00’ cannot be changed, a value is set in parameter 3.0. In this case, set the value to zero first.
Press ENTER briefly.
| Code | Description | | :--- | :--- | | | Unbuffered DIMM (UDIMM) | | ASF | Micro-DIMM | | ATF | SODIMM (Laptop memory) | | ASV | Very Low Profile (VLP) RDIMM |
: Typically designates Engineering Samples (ES) not yet meant for mass production. FBGA and part decoder | Micron Technology Inc.
Following the hyphen is the speed grade. This tells you either the clock cycle time in nanoseconds or the maximum data rate.
), you can decode its specifications using Micron's standardized numbering systems. Example Code MT Micron Technology Product Family 40 DDR4 SDRAM (41=DDR3, 42=LPDDR2) Voltage A 1.2V (L=1.35V for DDR3L) Density/Org 512M16 512 Megabits depth x 16-bit width Package Code LY Specific FBGA package type Speed Grade -083R Clock speed/Latency (e.g., DDR4-2400) Die Revision :H Design iteration of the silicon Key Category Identifiers
Micron simplifies the speed bin into a single digit immediately following the dash. micron memory part number decoder
Micron utilizes a specialized part numbering system that differs between full Marketing Part Numbers (MPN) and abbreviated FBGA Marking Codes
Package codes dictate the physical footprint, ball count, and material composition of the chip. : 78-ball FBGA (typically used for x4/x8 DDR4) RC : 96-ball FBGA (typically used for x16 DDR4) HC : 78-ball FBGA (DDR5) HE : 102-ball FBGA (DDR5) 5. Speed Grade and Cycle Time
Notes:
Comprehensive Guide to Using the Micron Memory Part Number Decoder | Code | Description | | :--- |
The initial “MT” is the universal prefix for Micron Technology. This distinguishes Micron parts from those of Samsung (K4…), SK Hynix (H5…), or other vendors.
| Part Number | Density | Organization | Speed | Package | |-------------|---------|--------------|-------|---------| | MT40A1G8SA-075E | 8Gb | x8 | DDR4-2666 | BGA | | MT40A512M16JY-083E | 8Gb | x16 | DDR4-2400 | BGA | | MT40A256M16GE-062E | 4Gb | x16 | DDR4-3200 | BGA | | MT40A2G8VA-062E | 16Gb | x8 | DDR4-3200 | BGA |
By mastering this system, you can eliminate guesswork, streamline component sourcing, and guarantee system compatibility every time.
It is important to distinguish between the capacity and the DRAM chip capacity. This tells you either the clock cycle time
[MT] [40A] [1G8] [SA] - [062E] : [E] ── ─── ─── ── ──── ─ 1 2 3 4 5 6
Below is the breakdown for (the actual chips on a module).
The (starting with MT) or the 5-digit FBGA code (usually starts with D or N).
Misidentifying memory components leads to costly design errors, system incompatibilities, and supply chain delays. By mastering the Micron decoder, you can: Verify exact hardware specifications before purchasing. Find precise, drop-in replacements for obsolete parts.
The auxiliary fan of the hoist motor continues to run for several minutes after the lifting or lowering. This ensures that the hoist motor is adequately cooled even at slow lifting speeds. The run-on time can be adjusted.
|
| |
|
Enter button |
Arrow buttons |
Move the load hook out of
the limit switch range (up or down).
During parameter setting, the load hook must not be within the limit switch range.
Select parameter 5.14.
Press ENTER.
● The set value is displayed.
|
| |
|
Enter button |
|
Set the value to between 3
and 10 minutes using the arrow buttons.
Press ENTER.
