Application of Split Vortex Flow Meter

Application of Split Vortex Flow Meter

Mainly used for flow measurement of industrial pipeline media fluids, such as gases, liquids, vapors, and other media. Its characteristics are small pressure loss, large range, high accuracy, and almost unaffected by parameters such as fluid density, pressure, temperature, viscosity, etc. when measuring volumetric flow rate under working conditions. No movable mechanical parts, therefore high reliability and low maintenance. The instrument parameters can remain stable for a long time.vortex flow meterUsing piezoelectric stress sensors, it has high reliability and can operate within a temperature range of -20 ℃ to 250 ℃. It has both analog standard signals and digital pulse signal outputs, making it easy to use in conjunction with digital systems such as computers. It is a relatively advanced and ideal flow meter.

Application of Split Vortex Flow Meter

As can be seen from the above equation, the pulse frequency signal output by VSF is not affected by fluid properties and composition changes, that is, the instrument coefficient is only related to the shape and size of the vortex generator and pipeline within a certain Reynolds number range. However, as a flowmeter in material balance and energy measurement, it is necessary to detect mass flow rate. At this time, the output signal of the flowmeter should simultaneously monitor volume flow rate and fluid density. Fluid properties and components still have a direct impact on flow measurement.
Split type vortex flowmeterIt is a new type of flowmeter for measuring fluid flow in closed pipelines based on the Karman vortex principle. Due to its excellent medium adaptability, it can directly measure the volumetric flow rate of steam, air, gas, water, and liquid without temperature and pressure compensation. Equipped with temperature and pressure sensors, it can measure standard volumetric flow rate and mass flow rate, making it an ideal alternative to throttling flow meters.
to improveSplit type vortex flowmeterOur company has recently developed the KY LU improved vortex flow sensor, which has high temperature resistance and vibration resistance. Due to its structure and material selection, the sensor can be used in harsh working conditions such as high temperature (350 ℃) and strong vibration (≤ 1g).
In practical applications, large flow rates are often much lower than the upper limit value of the instrument, and with changes in load, small flow rates often fall below the lower limit value of the instrument. The instrument is not working in its optimal operating range. To solve this problem, it is usually necessary to reduce the diameter at the measuring point to increase the flow rate at the measuring point, and use smaller diameter instruments to facilitate the measurement of the instrument. However, this variable diameter method requires a straight pipe section with a length of 15D or more between the variable diameter pipe and the instrument for rectification, which makes processing and installation inconvenient. Our company has developed an LGZ variable diameter rectifier with a curved longitudinal section, which has multiple functions of rectification, increasing flow velocity, and changing flow velocity distribution. Its structural dimensions are small, only one-third of the inner diameter of the process tubevortex flow meterAs a whole, it not only does not require an additional straight pipe section, but also reduces the requirements for the straight pipe section of the process pipe, making installation very convenient.
For ease of use, battery powered local display typevortex flow meterAdopting low-power consumption and lithium battery power supply, it can operate continuously for more than a year, saving the procurement and installation costs of cables and display instruments. It can display instantaneous flow, cumulative flow, etc. on site. temperature compensationIntegrated vortex flowmeterIt also comes with a temperature sensor that can directly measure the temperature of saturated steam and calculate the pressure, thereby displaying the mass flow rate of saturated steam. The temperature pressure compensation integrated type is equipped with temperature and pressure sensors, which can directly measure the temperature and pressure of the gas medium for gas flow measurement, thereby displaying the standard volume flow rate of the gas.

Three:vortex flow meterParameters and requirements

Measurement medium: gas, liquid, vapor
◆ Caliber specifications: Flange card mounted caliber selection: 25, 32, 50, 80, 100
◆ Flange connection type with a diameter selection of 100, 150, 200
◆ Flow measurement range Normal measurement flow velocity range Reynolds number 1.5 × 104~4 × 106; Gas velocity of 5-50m/s; Liquid 0.5-7m/s
The normal measurement range for liquid and gas flow is shown in Table 2; The steam flow range is shown in Table 3
Measurement accuracy level 1.0 and 1.5
◆ Temperature of the tested medium: normal temperature -25 ℃~100 ℃
◆ High temperature -25 ℃~150 ℃ -25 ℃~250 ℃
Output signal pulse voltage output signal high level 8-10V low level 0.7-1.3V
The pulse duty cycle is about 50%, and the transmission distance is 100m
Pulse current remote transmission signal 4-20 mA, transmission distance of 1000m
◆ Instrument operating environment temperature: -25 ℃~55 ℃ humidity: 5-90% RH50 ℃
◆ Material: Stainless steel, aluminum alloy
◆ Power supply DC24V or lithium battery 3.6V
Explosion proof grade intrinsic safety type iaIIbT3-T6
Protection level IP65

4： Vortex flowmeterSelection Table

Five:vortex flow meterInstallation requirements

Installation requirements

1. The sensor should be installed on a pipeline with the same diameter as the horizontal, vertical, and inclined (liquid flow from bottom to top) pipeline. The upstream and downstream of the sensor should be equipped with a certain length of straight pipe section, which should meet the requirements of 15-20D for the front straight pipe section and 5-1OD for the rear straight pipe section.

2. The pipeline near the installation of the liquid sensor should be filled with the measured liquid.

3. Sensors should be avoided from being installed on pipelines with strong mechanical vibrations.

4. The inner diameter of the straight pipe section should be as close as possible to the sensor diameter *. If * is not possible, a pipe slightly larger than the sensor diameter should be used, with an error of ≤ 3% and not exceeding 5mm.

5. When the measured medium contains a large amount of impurities, a filter should be installed beyond the required length of the straight pipe section upstream of the sensor.

Sensors should be avoided from being installed in places with strong electromagnetic field interference, small space, and inconvenient maintenance.