There are four wiring terminals on the two sides of the instrument: power input, ultrasonic probe, temperature sensor/analog output, and antenna. The installation method and specifications for each are described below.

If you do not purchase a LORRIC transformer, the instrument's applicable power supply should be 9-30 volts DC. The minimum current supply capability of the external power supply should be greater than 1 ampere. Current consumption will change with input voltage, but total power consumption is maintained at less than 2 watts. Please pay attention to positive and negative polarity when wiring. Please refer to the mark on the instrument case or wire according to the figure below. Incorrect polarity will cause the instrument to not operate and may damage it.

The instrument sends an ultrasonic signal. The transmission and reception of the signal through the pipe wall and interior fluid are performed through a piezoelectric ultrasonic probe and then transmitted through the ultrasonic signal. The resulting time differential is used to measure the flow. The distance between probes must be precisely calculated and the probes must be correctly placed to ensure measurement accuracy. This section describes the relevant wiring and installation precautions.

Each probe has three wires, so there are six contacts on the meter as shown below. Install the probe in the order shown in the figure below. If the probe model has no ground connections, it is okay to only install the positive and negative contacts.

The accuracy of an ultrasonic flowmeter is mostly determined by correct probe installation. If the installation method or location is incorrect, it may result in failure to achieve the desired results, or even an inability to send and receive ultrasonic signals. In general the conditions for the best installation location are as follows:

● It is better to mount the ultrasonic probe on a longer tube or pipe; be sure to verify that the pipe is filled with liquid.

● Installing the probe on the side of the pipe can reduce bubbles and interference caused by partially empty tube cavities.

● Make sure the probe can withstand the temperature of the measuring point; the closer it is to room temperature, the better.

● There are linings on the inner walls of some pipes. Though this product can be configured to be compatible with lined tubing, in practice this inner layer tends to block the transmission of ultrasound and thus the measurement results, so install as far as possible from this type of tubing.

Correct probe installation will greatly enhance measurement accuracy.

This product deals with ultrasonic signals in a differential manner. Therefore, probe wiring must include "Signal ㊉", "Signal ㊀" and "Ground Isolation ". Use 2-core cable (2C) with a grid structure, outside diameter (OD) of less than 7 millimeters, conductor cross-section of 0.5-0.75 mm2 , with a total length of less than 10 meters, so as to avoid signal attenuation caused by poor measurement quality. In addition, the upstream and downstream probe wire length must be consistent to avoid transmission error. The wiring method is as shown below:

After removing the cover, Erminals can be seen inside: "Signal ㊉", "Signal ㊀" and "Ground Isolation " . Secure the wires through the waterproof packing head to the corresponding terminals in the sequence shown below.

Before replacing the cover, it may be advisable to reinforce the waterproof features of the cover by screwing, gluing, etc., as shown by the dotted line on the figure below-left. After covering, screw the cover on tightly to complete the probe wiring procedure.

<Reference: Wiring essentials>

1.The quality of the wiring will affect ultrasound signal quality and measurement accuracy. It is important to install the wiring correctly and securely.

2.After cutting the length of wire required, first pass one side of the head through the waterproof packing head of the probe and then peel off the 40-millimeter insulation layers on both sides. Finish the insulation layer as shown in the figure below.

3.Separate the jacket with a corresponding 35-millimeter heat shrink sleeve and a 20-millimeter heat shrink sleeve on the outer circumference of the cable. Heat to fasten, then clip the Y-shaped terminal.

4.Secure each terminal of the probe in the correct position, as shown in the following figure. Tighten and fix the wires, then glue the probe cover shut as described in the previous section. (If there is further need for waterproofing, waterproof resins or rubbers can be used to fill in the space.

5.Equipped the other end of the wire with a corresponding 35 millimeter heat shrink sleeve on the isolation layer, and a 20 millimeter heat shrink sleeve on the outer side of the cable. Heat to fasten, and then clip the European style terminal to complete as shown below.

Generally, the probe should be set up using a V​ or Z configuration. A small number of specific applications may require an N​ or W​ configuration. The four configurations are described below:

● V configuration: In general, tubing with a diameter of 50 ~ 300 millimeters takes this configuration. The two probes are mounted on the same side of the tubing, with the resulting ultrasound signal having a V-shaped bounce. Because the probes are on the same side, it is easier to measure the distance between probes, and because the ultrasound only reflects once, a balanced signal strength is achieved.

● Z configuration: Generally used in diameters of more than 300 millimeters, the ultrasonic signal is not reflected, thus helping to maintain signal strength. This helps avoid a weak or distorted signal. However, because the probes are mounted diagonally on opposite sides of the tube, measuring the probe distance is more difficult.

● N configuration Generally used in tubing of less than 50 millimeters, the probes are mounted diagonally on opposite sides of the tube, making it more difficult to measure the distance between them. The ultrasonic signal is reflected two times, making three paths, and thus increasing signal flight time and enhancing measurement accuracy in thin-diameter pipes. This method is only recommended if the V configuration cannot be adjusted to produce the ideal signal state.

● W configuration Generally used in tubing of less than 50 millimeters, the ultrasonic signal is reflected three times, making four paths, and thus extending signal flight time. There are cases when this method can improve measurement accuracy for small tubes. This configuration makes measuring probe distance easier than the N configuration does, because the probes are mounted on the same side of the tubing, but it is not recommended unless it is otherwise impossible to attain the ideal signal state.

● Pipeline Installation Location Liquid flow in the pipe will be obstructed by bends and other forms of obstacle. In order to ensure flow measurement precision, probes should be installed in such a manner as to avoid confusion in the flow field. The following table shows a variety of common pipeline configurations, and the corresponding upstream and downstream probe recommendations. The installation location for the upstream and downstream probes should correspond as much as possible to the positions recommended in the table (select the situation that most closely meets actual site conditions).

● Probe distance calculation Set the initial value of each parameter in the meter setup. After setting the values, find the probe spacing item in the initial value menu. After the values have been entered, this will display the probe distance calculation results. Please set up the probe in accordance with this distance. Setup accuracy will directly affect the accuracy of the measurement results. It is recommended that adjust TOM/TOS to 99.90%~100.10%

The probe should be installed on the side of the pipe in order to avoid cavities produced by gases accumulated at the top of the pipe that affect the transmission and reception of ultrasonic signals. If the probe cannot be installed on the side, it is important to ensure that the pipe is filled with fluid at all times. Any gap between the probe and the tube walls will result in substantial attenuation of signal intensity, seriously affecting signal strength and quality. Therefore, a coupling agent must be applied between the head of the probe and the tube wall during installation to ensure that no air bubbles remain between the probe and the tube wall.

This product is equipped with two PT1000 temperature sensor connection interfaces to provide accurate upstream and downstream pipeline temperature measurements. The measurement function can be used as an extended application of the BTU thermal energy meter. The relevant precautions are as follows:

● Please use a two-wire PT1000 sensor; the product is not compatible with PT500 and PT100 sensors.

● The measuring range of the instrument is -100 ~ 300 °C. The quality and accuracy of the sensor used will directly affect temperature measurement results. Please select the correct, appropriate temperature sensing element.

● The sensor has no polarity, but there is a distinction between upstream and downstream. Care should be taken to note this during installation.

● Wire length should be less than 3 meters. If wires are too long, it will affect measuring accuracy.

● Keep the wires away from any instruments or devices that may generate electromagnetic noise, such as large cables, motors, power strips, inverters, etc. Wire and product connectors must be securely mounted. Weak or loose contacts may result in resistance and affect the measurement results.

The wiring method is shown below. Please refer to the terminal below the printed logo. (It has been set on the circuit board when it is setup. If you need to adjust, please contact LORRIC.)

This product also has a built-in 4-20-milliampere analog power output signal which provides analog output of the measured values. It is used as follows:

● Outputs include flow rate, flow velocity, upstream temperature, downstream temperature, liquid sound velocity, and upstream/downstream temperature differential.

● Upper and lower limits can be customized to provide the required range of output.

● The 4-20-milliampere signal is a passive signal that requires an external power source. Please note that an independent power supply must be used. The 4-20-milliampere output signal cannot share power with the instrument; otherwise it may cause instrument burnout! Please wire the positive and negative terminals correctly. The external power supply voltage range is 12 ~ 30 volts DC. 12 volts is recommended; higher voltages may cause the temperature of the instrument to rise.

There are two sets of RSSI values on the meter screen; these represent the signal strength received by the upstream and downstream probes. It is recommended that signal strength should be maintained at above 10% to ensure the normal operation of the system. If RSSI is found to be excessive or unstable, please refer to the following adjustment methods:

● Try to fine-tune the distance between the probes.

● Select a different site for mounting the probe.

● To confirm if there is any sediment in the pipe.

● Check whether the outer wall of the pipe is too thick with rust, oil, paint, or other substances. Afterwards, evenly apply more coupling agent.

● The signals from the two probes may not align. Try moving the probes slowly until the unit has a better RSSI value; check the probe for misalignment.

● After taking any of the above actions, be sure to double check whether the probe distance deviates too much; an excessive offset will result in flow measurement error.

● Check the setting in the MeterRx Peak Level settings. If the diameter of the pipe is large, the wire is too long, or other factors cause the RSSI to always be biased, try to adjust the relevant setting values. For related setting information, refer to the following instructions.

The Q value represents the received signal quality and can be regarded as an indicator of signal-to-noise ratio (SNR). The value is displayed at the lower right of the display interface. The value ranges between 0 and 100%. Under normal conditions, the Q value should be > 60%. The higher the Q value, the better the signal quality, and the more reliable the measured value. A Q value of less than 10% will not be measured. Try the following solutions:

● Sometimes the RSSI value is high, but a low Q value may be displayed due to slight distance, angle, or other errors in the probe. If the Q value is low, try to adjust the distance and angle of the probe slightly.

● If the pipe surface is rough, smooth it and confirm that the probe can completely adhere to the pipe surface with no gaps.

● If the coating provided by the coupling agent isn’t smooth, recoat to provide a smooth surface.

● If the pipe surface has impurities, dirt, or grime, the probe should be moved to another location.

● If surrounding equipment causes electromagnetic interference, change the installation location or strengthen shielding.

● If the fluid flow field is unstable, change the installation location.

● If the pipe diameter is too large, set up the probe in the Z​ configuration.

The seventh interface of the display output interface displays all values related to ultrasonic signal flight time (Time of Flight, or ToF). TOM (as shown in the picture) represents measured flight time, and TOS the calculated theoretical flight time. Ideally, the two values should be equal. If TOM/TOS yields a value that exceeds 100% ± 3%, the following steps should be taken:

● Check if the relevant setting parameters are correct. Check pipe material, pipe diameter, whether there is a liner, fluid type, and other relevant parameters. Check to ensure that the probe is mounted correctly.

● Check to ensure that the probe mounting distance is correct.

If> 100%, adjust upstream and downstream probes and bring them closer together.

If <100% adjust distance of probe, by moving them further apart.