This crate compiles the following three binaries for logging, preprocessing, and plotting load time series.
CLI app to log load cells via Flintec DAD 141.1 digital amplifier with TCP-UTF8. The app allows automatic logging at rounded intervals of minutes or hours that are divisors of 1 day. Valid minutes intervals are 1, 2, 3, 5, 10, 15, 20, 30, and 60 minute(s). Valid hours intervals are 1, 2, 3, 6, 12, and 24 hour(s). The standard format RFC 3339 - ISO 8601 is used for the datetime to be more general and robust to time zones and daylight saving.
This CLI app processes the load time series with the following steps:
- Read and parse the logged load time series.
- Convert all datetime to a chosen time zone, i.e., removing daylight saving if needed or changing the time zone is desired.
- Make the time series continuous using the minimum time interval found in the data.
- Optionally, replace logging errors with NAN.
- Optionally, replace given datetimes from an input file with NAN (e.g., values disturbed by maintenance).
- Optionally, replace a given daily interval with NAN (e.g., daily temperature effects or maintenance period).
- Optionally, use a weighted moving average to smooth the time series (e.g., wind and temperature) and fill the NAN values. It uses a moving average with linear weights between a user-defined central weight (typically the max weight) and a side weight (typically the minimum weight). The width of the window can be adjusted by specifying the number of data points on each side, this parameterization guaranties the window symmetry. Constraints can be set to define when the missing information is too large to fill the NAN values (maximum number of missing load values or their cumulative associated weight).
- The CLI app saves a new csv file compatible with flintec_plot.
CLI app to plot the load time series saved by flintec_log or flintec_process. The app automatically adjust the datetime format. The output format of the figure is svg.
Note, throughout the crate, load is used for the load cells data, while weight is used for the moving average.
Documentation: rust_crate
The CLI apps are written in the Rust programming language.
- Remove the seal switch jumper to enable all the commands, that is just for legal applications.
- Use function
2.4
to display the actual raw voltage mV/V. - Menu 3.1 for overload, make sure it is above the required maximum load.
See examples in the DAD manual and section 7.4 (pag. 34) in the DOP manual.
- Zeroing with function
1.2 - CZ
(gravimetric) or1.3 - AZ
(electronic), this associates the current measured voltage (mV/V) with the zero reading. - Set span_kg with function
2.1
, set RO_kg_sum. - Set span_V, from the formula below, with function
2.3
.
span_kg = RO_kg_sum = RO_kg_1 + RO_kg_2 + ... RO_kg_n.
In our case, span_kg = 20kN * 6 = 120 kN = 120 = 12,236.5921 kg. Put RO_kg_sum in function 2.1.
RO_V_1 + RO_V_2 + ... + RO_V_n = RO_V_sum, in mV/V.
span_V = (V_sum / kg_sum) * kg_max, in mV/V. In our case 12.00062 / 6 = 2.000103333 mV/V.
In our case, SPAN_V = 2.00032 + 2.00034 + 1.99979 + 2.00014 + 2.00011 + 1.99992 = 12.00062 mV/V. Put span_V in function 2.3.
Where:
- RO_V is the voltage output (mV/V) at the rated output (RO) from the calibration certificates.
- RO_kg is the rated output, always from calibration.
kg@x = (mV@x / (mV@RO * ExcitationVoltage)) * kg@RO
kg@RO = 2039.43 kg mv/V@RO ~ 2 mv/V ExcitationVoltage should be 5 V
Example, ~2040 kg should give 10mV (i.e., 2 mv/V * 5 V) Example, ~1020 kg should give 5mV (i.e., 2 mv/V * 5 V / 2) in general, 204 kg = 1 mV
The app expects the 10-byte DAD format, with flexibility on the position of the decimal separator. The first two characters are the description of the value and are excluded from the parsing of the numerical load value. However, the raw string is also written into the csv file to avoid losing information on the type of reading and recover the values in case of parsing errors. Possible whitespace-property characters (Unicode standard) will be correctly trimmed and ignored.
Three types of mounting modules are used to obtain the correct degrees of freedom, matching the deformation of the system.
- Fixed: No mobility, the modules fixes the system point in that position (0D freedom).
- Bumper: Constrains the movement in one direction (1D freedom).
- Free: It allows the movement in all the directions, within the load cell plane (2D freedom).
Align the load cells considering the degrees of freedom of the mechanical deformation. In particular, pay attention to the fixed and bumper load cell, and their alignment with respect to the main deformation at the bumper. See figures are in the manuals.
It is used to protect the mobile parts of the mounting module during their movement (rocker pin and matching top surface).
- Mettler Toledo manual: Loctite Anti Seize, Food Grade
- Flintec: At Flintec use RENOLIT ST-80, by Fuchs. However, they provided a similar one already with the load cells.
- find the ip address, e.g.,
ifconfig
. - find the hostname with
host ipaddr_from_ifconfig
.
- ssh to raspberry pi,
ssh user@ip
- open tmux,
tmux
- start the logging process, see
./compiled_binary --help
- detach the tmux session n from terminal with
Ctrl+b
thend
, which returns [detached (from session n)] - check if tmux session is still there with
tmux ls
, it should return n: 1 windows (created datetime 2), where datetime is of point 2 - close terminal/ssh connection,
exit
, it returns Connection to uset@ip closed
- ssh to raspberry pi,
ssh user@ip
, as step 1 of starting - find tmux session with
tmux ls
, as step 5 of starting - attach the session with
tmux attach -t n
, where n is the number from starting step 4 - repeat steps 4, 5, 6 from starting
- open terminal and copy file from raspberry to laptop with
scp
, e.g.,scp user@localhost:~/path/to/file/loadcells.log ./Desktop/
- ssh to raspberry pi,
ssh user@ip
, as step 1 of starting - find tmux session with
tmux ls
, as step 5 of starting - close running logging with
Ctrl+c
, should return [exited] - double check with
tmux ls
, should return no server running on ...