Archive for Signal Conditioners

How to Wire For Trouble Free Signal Conditioning

How to Wire For Trouble Free Signal Conditioning

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Signal conditioning equipment for process signals has kept pace with modern technology, but many users never realize the full potential of the equipment because of poor installation and wiring practices. Such practices can degrade equipment performance from a small percentage of error to the point where the equipment is unusable.

The most common complaints heard by this company are invariably associated with wiring problems. The most common problem encountered is an installation where all wiring is pulled in a common conduit or cable trough. A relay coil being switched or a relay contact switching an inductive load can easily generate a transient in excess of 1000 volts. This transient can easily couple into a signal conditioner and cause severe measurement problems.

Many products have input signal levels as low as 5 millivolts full scale and an output of 10 volts. With a gain of 2000, it is easy to understand the necessity of using good installation and wiring practices.

Accurate signal measurement and conditioning is vital if one is to maintain quality in their process control. Understanding the correct way to install and wire this important equipment is the proper responsibility of anyone who specifies control panels, wiring installations, or who manages factory personnel who install such equipment.

DEFINITIONS OF SOME COMMON PROBLEMS

Ground Loop – A ground loop exists whenever an extraneous current flows in a conductor carrying the desired signal. If the extraneous current is related to the power mains, it generally manifests itself as “noise”. If the extraneous current is DC, it can create an offset that can be difficult to recognize. The measured signal becomes the sum of the signal and ground loop current.

Ground Loop Diagram

Magnetic Coupling – AC currents can be induced into the conductors carrying the desired signal. The AC can be power mains, magnetic transients from switching inductive loads, or magnetic fields from coils, transformers, or motors.

Magnetic Interference

Capacitive Coupling – AC voltages can be capacitively coupled to the signal carrying conductors. This is accomplished by locating the signal leads near an AC voltage source such as power mains, SCR drive inputs or outputs, or any other source of AC potential.

Capacitive Coupling

Radio Interference – Radiation from radio transmitters can create measurement problems by having some portion of the signal conditioning circuit rectify the radio energy and adding the resultant DC to the process signal. The radio energy source can be a portable two-way radio or a fixed installation radio or television transmitter. The interference can be momentary with portable radio equipment or a permanent offset with fixed installations. AM radio transmitters can often modulate the process signal with the voice or music modulation on the radio carrier.

Lightning – Lightning interference is sporadic and the primary concern is for survival of the equipment. Central Florida in the United States has the most frequent and intense lightning storms in the country. It is nicknamed the ”lightning belt”. Survival is the desire in this environment.

INSTALLATION CONSIDERATIONS

The location of signal conditioning equipment is important for the prevention of the common problems defined above. Avoid mounting equipment next to high voltage sources such as breakers, fuse blocks, or terminal strips. Also avoid magnetic field sources such as large transformers, motor control relays, or motors. Wiring paths should also be considered when mounting equipment. Insure paths exist to route signal wires without having to run them in proximity to noise sources.

Ground Loop Avoidance – Avoiding a ground loop is simple. Never let an extraneous current flow in the signal leads. If a device must drive two or more loads with a voltage signal, use individual leads from the output to the input of each driven device.

Ground Loop Avoidance

When the driven device and the driver must both connect to earth ground, use an isolator to break the ground path for extraneous currents.

Ground Loop Avoidance Earth Ground

Magnetic Coupling Avoidance

Every effort should be made to keep signal leads away from AC magnetic field sources such as motors, transformers, or large relays. If it is necessary to route signal wiring near these devices, use a twisted pair of conductors for each signal. A pair of conductors with ten to twelve twists per foot offers an effective method of reducing magnetic pickup.

Magnetic Field

A major source of magnetic interference is created by running untwisted signal leads parallel to and in proximity to conductors carrying AC currents.

Twisting the signal leads and the power leads are an effective way to reduce this form of magnetic interference.

Mounting signal conditioning equipment in powerful magnetic fields can create interference inside the circuit boards and internally in the integrated circuits used in the equipment. The most reasonable and effective cure for this condition is to move the equipment away from the magnetic field.

Capacity Coupling Avoidance

AC potentials near signal carrying conductors can capacitively couple the AC to the signal conductors. The higher the frequency of the AC source the more extreme the potential interference problem. Common sources of interference are SCR drives, relay coil circuits, welders, and fluorescent lamp conductors.

If the interference cannot be avoided by equipment location and wire paths, shielded wire should be used between products.

Twisted shielded wire is the best choice because the twist provides magnetic interference protection and the shield prevents capacitive coupled interference.

Capacity Coupling Avoidance

The shield should be connected to the circuit common of the driven device. It should never be connected to both devices. Current could flow in the shield and magnetically couple to the signal leads. If the signal conditioner is mounted near a high potential source, capacitively coupled interference can occur by direct coupling to components inside the product. Metal housed products can be effective in preventing direct coupling, but the preferred practice is to locate the equipment in a better environment.

Radio Interference

Well designed products will include internal filters to desensitize the product to radio frequency signals. There is no cure for direct radiation pickup by components in the product except extensive shielding. Metal housings with RFI gaskets can be used to shield the product. If the RFI source is powerful enough, individual RFI filters may be required on each conductor entering the metal housing.

Lightning

Lightning is basically radio interference except when a direct hit occurs on a power line or signal cable. Standard RFI shielding techniques work on radiation from lightning -to a point. The energy levels associated with lightning radiation can induce currents in conductors that will destroy products. Good lightning protection requires the following techniques as a minimum:

1.  Mount all equipment in a metal housing.

2.  All signal leads should have a gas discharge transient protector to circuit common.

3.  Circuit common should have a gas discharge transient protector to a good earth connection (very short heavy lead).

4.  Power connections should have a transient protector from each line to earth.

5.  Use twisted shielded pair for all signal leads.

6.  Run all wire underground where feasible – otherwise use metal conduit which is well grounded.

Fundamental Requirements

1. Never run signal leads in the same conduit or bundle that carries power mains, relay coil drive, relay contact leads, or other high level voltages or currents.

2. Never connect the shield of a shielded wire to anything other than the circuit common of the input of the product being driven by a signal.

Dc Input Isolated 2 Wire Transmitters and How They Work

DC INPUT ISOLATED TWO WIRE TRANSMITTER AND HOW THEY WORK

An isolated DC input two wire transmitter is a valuable tool for many difficult measurements.  The device can measure DC voltage or current inputs and provide a 4mA to 20mA output without a galvanic electrical connection between the input and output.

The isolation between input and output is typically rated with an insulation capability of 1000 volts or more.

HOW THEY WORK – ANALOG CIRCUITS

The transmitter has a DC amplifier as an input circuit.  It can typically be calibrated for a current or voltage input.  The power for this circuit requires an isolated power supply which uses a transformer for the isolation.

The signal out of this amplifier must be changed to a form which can be sent through the signal isolation circuit.

A common isolation circuit is to convert the DC signal to a square wave AC signal and transformer couple it to the output circuit.  The output circuit must convert the square wave AC signal back to a DC voltage which can drive the current output circuit.

Another common circuit is to convert the DC signal to a pulse signal where the data is determined by the width of the pulse.  This pulse is passed through an optical isolator and then converted back to a DC signal which drives the current output circuit.

HOW THEY WORK – DIGITAL CIRCUITS

The digital transmitter has a DC amplifier as an input circuit. The power for this circuit requires an isolated power supply which uses a transformer for the isolation.

The level of the DC output is measured with an analog to digital converter.  The binary code, in the form of pulses, is passed on to a digital to analog converter through optical isolators.  The analog output of the D/A converter drives the current output circuit of the transmitter.

APPLICATIONS FOR ISOLATED DC INPUT 2 WIRE TRANSMITTERS

Common Mode Definition

A DC input transmitter has 2 connections for the input signal.  These are the signal input and the common connection.  The common connection is the circuit common of the input amplifier.

If the input terminal and the common terminal are connected together, and a signal is connected to this connection, and the other signal lead is connected to its normal place, the transmitter has a common mode input.  The signal input and common terminal, being tied together, both have exactly the same signal attached.

The transmitter will not respond to this common mode signal.  It only responds to a difference in the level between the signal and common lead.

Application For Common Mode Capability

Measure current from a 138V battery pack by putting a .01 ohm resistor in series with the positive lead.  Connect the 2W transmitter input across the resistor.

The resistor drops 10mV per amp, which is processed by the transmitter and converted to the constant current output.

The common mode capability of the transmitter allows the signal input leads to be 138VDC above ground, but it can accurately process the low voltage across the shunt resistor.

The current output is not effected by the 138VDC battery voltage.

Two Wire Common Mode Diagram

Two Wire Common Mode Diagram

Application For PLC Input

Some PLC’s provide 24VDC at the input terminals of their analog inputs.  A 2 wire transmitter can be connected to the 24VDC.  The PLC will monitor the current drawn from the power supply and thereby ascertain the signal level at the remote 2W transmitter.

An isolated DC voltage or DC current 2W transmitter connected to the PLC allows many types of signals to be monitored in the field.  The isolation prohibits ground loops and maintains noise free signals into the PLC.

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