Difference between revisions of "XPod Bridge - Strain gauge"

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===connection ===
==Connection==
The Xpods feature 8 connectors on the side of the analyzer. The connectors correspond to the front-end channels located at the Xpod level by set of 8.
The Xpods feature 8 connectors on the side of the analyzer. The connectors correspond to the front-end channels located at the Xpod level by set of 8.
[[File:correspondance_table.png|framed|none]]
[[File:correspondance_table.png|framed|none]]

Revision as of 10:35, 7 May 2020

X-Pod Strain gauge Bridge

OROS analyzers feature optional Wheatstone bridge conditioner.

Xpod strain.png

Expander modules

The XPod is a device that can be fixed on OR3X TW analyzer. Each XPod is associated to a block of 8 inputs.


Xpod-plug.png

In the connected mode, when and XPod is present each corresponding input can be routed to:

· The BNC input (Standard)

· The XPod connector


General Xpod settings

  • Type: For acquisition setup preparation, the XPod presence can be simulated in the office mode:

One XPod type selector is available for each XPod position.

Xpod bridge.png
  • Bridge max current: Select the max excitation current for the corresponding active Bridge Xpod. Each bridge Xpod excitation current can be limited to 30 mA up to 4 V and 12 mA up to 10 V.
  • Bridge voltage: Select the excitation voltage for the corresponding active Bridge Xpod. From 0 to 10 V.

input settings

Xpod bridge2.png

For each input, you can select the following options dedidctaed for Xpod gauge:

  • Type: bridge signal conditioning for strain gage.
  • Gauge type: Full, Half or Quarter bridge mount. The completion resistors are included in the Xpod.
  • Resistance: Bridge completion resistor: 120 or 350 Ohms for quarter bridge mount.
  • Gain: Bridge gain: 10 or 100 depending on the required precision and range.
  • Max current: the provided current can be limited to 30 mA up to 4 V and 12 mA up to 10 V.
  • Excitation voltage: Each Xpod provides an excitation voltage from 0 to 10 V.
  • Offset Comp.: Bridge offset comp: Can be used for manual balance of the bridge.


Connection

The Xpods feature 8 connectors on the side of the analyzer. The connectors correspond to the front-end channels located at the Xpod level by set of 8.

Correspondance table.png

Then weld the connector pins according to the pin-out diagram below:

Strain Gage User Guide 03.png

Full.png Annotation 2020-04-16 184550.png File:Annotation 2020-04-16 184709.png

tutorial: How to set up XPOD conditioners for strain gage

Hard Connection

Let us see how to proceed a half bridge connection.

Use a male SUB D 9 pins connector and a "bullet proof" cable like Ethernet cable to link the strain gages to the connector.

Strain Gage User Guide 01.png
Strain Gage User Guide 02.png

Then weld the connector pins according to the pin-out diagram below:

Strain Gage User Guide 03.png

Full.png Annotation 2020-04-16 184550.png File:Annotation 2020-04-16 184709.png


Set up NVGate

Sensitivity

In quarter bridge configuration, the gauge is usually glued toward the beam direction to measure the bending for example. In this case the right formula is

Strain Gage User Guide 04.jpg

 

Strain Gage User Guide 05.jpg

Where

-       S = Em/V is the sensitivity (*V / µdef)

-        e , 2, 3 et 4 are the resistivity of the gage or generated by the hardware depending on the type of the

bridge.Here, 2, 3 and 4 are XPOD internal resistors

-       V, the excitation voltage (in NVGate, the settings is  "Expender module/Bridge voltage")

-        ΔEm, the strain measurement voltage

-         r, equal to R1/R4=R2/R3 often equal to 1.

-        Sg is the gage factor (often equal to 2 x 1E-06 volts per micro-def

- n, the number of gages (For full bridge, it’s 4. For ¼ bridge it’s 1.)

You can notice that the sensitivity is not linear with the stress  = L/L. For low strain, the formula is equivalent to:

Strain Gage User Guide 06.jpg

For a half-bridge configuration, it is possible to glue 2 gauges toward the beam direction as shown in the figure below:

Strain Gage User Guide 07.jpg

In this case, the sensitivity is linear and is equal to:

Strain Gage User Guide 08.jpg

So the fact that 2 gages are used instead of only one gets the bridge sensitivity twice better.

NVGate setup

It is advised to first add a "transducer" in NVGate database in order to register the bridge configuration.

Browse the Home menu  Transducer tab  Database

Strain Gage User Guide 09.png

Add a new transducer which is in fact a bridge configuration.

In the Conditioner area, fill the Gauge bridge type, the gauge resistance, the excitation voltage and so on.

The sensitivity to be filled is the bridge’s one (in red below). So, it is necessary to compute this sensitivity according to the above formula.

Strain Gage User Guide 10.jpg

Measurement

The XPOD contains 8 inputs. In case of XPOD connection, the 8 BNC inputs are disabled for using the XPOD inputs.

These XPOD inputs can be connected to different plug-ins like FFT or Time domain analyzer for example.

Then the bridge has to be balanced through the Bridge Auto-zero feature (this option has to be setup to ON in the Input settings).

Strain Gage User Guide 11.jpg

Press on « Bridge Auto-zero » from the "measurement" tab to start the bridge balancing. This step may last about 30 seconds.

Strain Gage User Guide 12.jpg

Now, the measurement is ready to start.

download

Download : OROS BRIDGE CONDITIONERS XPOD™ CONNECTIONS

See also

Compute Main stress with rosette