Thanks roydm,
Just a few other pointers on level application that all instrument technicians and engineers should know,
What I have found in the past is that everyone knows how to setup a level with a dryleg and in a open tank and then try to use that knowlage and apply it to all level setups.
It is important to realize that open tanks and dry legs can be setup with the normal sg x g x h formula (correct way is for exp: 1 x 9,81 x 3m = 29,43Kpa, so your UOM needs to be in meter and the answer will be in Kpa directly - you need to make sure the UOF is right otherwise the answer will be wrong)if you need a pressure answer in order to pump up the transmitter to the span value.
I personally don't use the formula anymore since I only have been working with smart transmitters the past couple of years and you don't need to pump up a smart transmitter. You just calculate the LRV and URV with the mm x sg = mmH2O formula as well, and input them with the HART and the job is done.
For any wet leg or capillary applications pressure or vacuum you need to use the method described above in my big writeup, and start to work with the ATM zero and process zero values.
Incidentally it is also not necessary to change the LP and HP leg around for wet leg applications anymore since smart transmitters can all measure in the negative which means that a wet leg and a capillary setup are pretty much the same thing these days, if you use the HP at the bottom and the LP on the top as normal.
Some people working on the boiler drum level applications have a bit of a hard time to accept this since they always had to change the transmitter legs around in the past so you might get a bit of a argument from them, but that is just because they do not understand the difference between a old 4 to 20 electronic transmitters and a new smart transmitter. Old electronic and pneumatic DP transmitters could only measure in the positive.
I have also found it to be mush simpler to start working in mmH2O since you can take measurements in the field and apply them directly to your calculations
(mm x sg = mmH2O)so I never work in any other UOF than mmH2O anymore on all applications. Afterwords you can just change the UOM on the transmitter if you need it to display some other UOM.
Something else I have found in the past couple of years is someone will say they cannot setup the level in some or other application since no one can tell them what the sg value is of the product inside.
There is a very simple way to determine the sg of any product very accurately yourself.
Use the same transmitter (tubing not capillary type)you will be using to measure the level, or an extra one, and measure the exact distance from the transmitter diaphragm to the position where the tubing is going into the fitting on the top tapping on the vessel. Say this distance is 2000mm.
Do a zero trim on the transmitter and then recalibrate your transmitter for LRV = 0mmH2O and URV = 2000mmH2O. If you should now fill this impulse line with clean water the transmitter will read exactly 2000mmH2O. We all know this, so fill the impulse line with the product inside the vessel and it will read a different value. Take the value it now reads and divide it by the 2000mmH2O, it would have red with water, and the answer is the sg value of the product inside the vessel. For exp: Say the transmitter only reads 1970mmH2O when you fill the line with vessel product, 1970 / 2000 = 0,985, so the sg of the product is 0,985.
Have fun - it's not a job, it's an adventure!!
