Vortex Flowmeters VY series

Vortex Flowmeters, Ideal for Steam Flow Measurement

Vortex flowmeters are highly versatile flowmeters that can measure liquids, gases, and steam over a wide range of temperatures and pressures. The advantages offered by this type of flowmeter make them better suited than other types to measuring steam flow.

Steam is the most commonly used high-temperature, high-pressure heat medium across a wide range of industries. For example, it is used for heating, distillation, and concentration in chemical plants; sterilization, disinfection, and cleaning in biotechnology, food, and pharmaceutical plants; and air conditioning in semiconductor plants and district heating/cooling plants, among many other applications. There are two types of steam: saturated steam and superheated steam. Saturated steam is a fluid with good thermal efficiency, but it is difficult to maintain saturation due to the pressure loss and heat radiation associated with steam transportation, so it is sometimes supplied in a superheated state at higher temperature and pressure. Vortex flowmeters are chosen as the best steam flowmeter for steam flow measurement at many facilities because they can measure the flow rate of even high-temperature, high-pressure steam, including superheated steam.

The vortex flowmeters in Yokogawa’s VY Series offer a wide measurable flow range of up to 400mm in connection size, as well as the ability to measure fluids at high temperatures of up to 450°C and high pressures of up to ASME Class 1500. In addition to excellent solidity and stability, the series has been added with remote maintenance and self-diagnostic functions that help ensure efficient maintenance, supporting long-term stability of plant operations and improved production efficiency.

 

Advantages of Introducing Vortex Flowmeters for Steam

This section describes the advantages of using vortex flowmeters for measuring steam flow, comparing them with orifice flowmeters (differential pressure flowmeters), which are used at many work sites.

Wide Rangeability to Accommodate Fluctuating Steam Flow Rate

A typical orifice flowmeter has a rangeability of around 5:1, which may result in a large error depending on the measurement range. By contrast, with a rangeability of 80:1, Vortex Flowmeter VY Series have a wide measurement range, with accuracy errors kept to a consistent level. This superior rangeability means that they can handle steam flow rates that vary with the season and operating load.

Low Pressure Loss Helps Ensure Stable Operation

Orifice flowmeters measure flow rate from the differential pressure created by the orifice (throttle valve), resulting in a pressure loss due to the orifice. On the other hand, vortex flowmeters have pressure loss due to vortex shedder bar, but it is smaller than that of orifices. Pressure loss causes a decrease in steam quality, which leads to higher costs due to energy loss. Therefore, a vortex flowmeter with small pressure loss is advantageous for maintaining steam quality and stable plant operation.

No Mechanical Moving Parts, Less Prone to Failure

Orifice flowmeters are easy to maintain because they are not in-line instruments, but they have many components such as an orifice (throttle valve), impulse piping, and a three-valve manifold and condensate pots, which require a large number of maintenance items. However, vortex flowmeters have a simple structure with no moving parts, and so are robust and less prone to failure. As such, their long-term robustness and low maintenance costs are a great help to plant operation.

 

The VY Series Is Recommended for the Following Users:

  • Those who want to improve the efficiency and stability of device operations by using temperature and pressure compensations to measure steam flow rates with higher accuracy
  • Those who want to minimize downtime by implementing predictive maintenance based on device conditions
  • Those who want to reduce maintenance costs through component-based maintenance of device

About the VY Series of Vortex Flowmeters


About OpreX

OpreX is the comprehensive brand for Yokogawa’s industrial automation (IA) and control business and stands for excellence in the related technology and solutions. It consists of categories and families under each category. This product belongs to the OpreX Field Instruments family that is aligned under the OpreX Measurement category.

Details

Features of the VY Series

Using Digital Technology to Help Improve Efficiency and Manpower-saving Maintenance Activities

Plants with many pieces of device in operation require “Condition-Based Maintenance (CBM),” which is efficient and systematic predictive maintenance based on the condition of the device. The VY series is equipped with a "self-diagnostic function (built-in verification)" for the entire device, including the vortex shedder bar with sensor elements, and a "process diagnostic function" that detects pulsation and fluctuation of the measured fluid and piping vibration based on the characteristics of the measured signals, through advanced digitization of the internal signals. In combination with the FSA130 Magnetic Flowmeter and Vortex Flowmeter Verification Tool (sold separately) and FieldMate which is adjustment, configuration, and management software (sold separately), those provides "verification functions" and "remote maintenance functions". These functions can be easily used on a PC screen in an instrument room away from the site, dramatically improving the checking and management of device health and operating conditions. In this way, the VY series promotes efficiency and manpower savings in maintenance activities and supports efficient plant operation.

*For more details on the FSA130 Magnetic Flowmeter and Vortex Flowmeter Verification Tool, click here

Using Digital Technology to Help Improve Efficiency and Manpower-saving Maintenance Activities

 

Unique Structure and Technology to Reduce Downtime for Maintenance and Stabilize Flow Measurement

The VY series inherits the high reliability and proven original sensing structure of the previous YEWFLO series. The vortex shedder bar has a unique sensing structure that incorporates two flow sensors and one temperature sensor (optional) and can be detached from the body. This structure not only results in robustness, long-term stability, short face-to face length, and short upstream straight pipe length, but also allows cleaning and replacement of the vortex shedder bar without removing the entire flowmeter from the piping when maintenance is required due to fluid deposition and other factors. This helps minimize the downtime required for maintenance. In addition, our unique digital signal processing technology effectively eliminates piping vibration, resulting in stable measurement. Mechanically and functionally compatible with successive generations of the YEWFLO series, the VY series can be installed in the same locations without the need for any additional piping work.

Unique structure and technology to reduce downtime for maintenance and stabilize flow measurement

The VY series facilitates efficiency and labor savings in maintenance operations, supporting efficient plant operations.

Product Lineup

VY Series Common Specifications

Vortex Flowmeter VY Series can measure the flow rates of liquids, gases, saturated steam, and superheated steam, and has self-diagnostic and remote maintenance functions. A choice of materials is available for the wetted parts, stainless steel including duplex stainless steel or nickel alloys. The series complies with a wide range of standards, including explosion-proof and SIL2. The external input (analog input function for HART7 with analog input option or input via MAO function block for FOUNDATION Fieldbus) supports more accurate calculation capabilities* than ever before, including mass flow rate and energy flow rate of liquids, gases, and steam.
*Saturated and superheated steam tables built in

[Common Specification]

Model VY □ □ □ (Integral Flowmeter, Remote Sensor), VY4A (Remote Transmitter)
Measurement Fluid Liquid, Gas, Saturated Steam, Superheated Steam
(Avoid multiphase flow and sticky or corrosive fluids)
Communication and Input/Output HART 7 communication, 4 to 20 mA DC, Pulse / Status output, Analog input
FOUNDATION Fieldbus communication
Modbus RTU communication, Pulse / Status output
Explosion Protected Type IECEx Ex db / Ex ia, ATEX Ex db / Ex ia, FM Ex db / Ex ia, FMc Ex db / Ex ia, Japan Ex db, NEPSI Ex db / Ex ia, Korea Ex db / Ex ia, INMETRO (Brazil) Ex db / Ex ia
Conformity Standards EMC, PED, EU RoHS, CE marking, NACE, Functional Safety (SIL2), NAMUR (NE21 / NE107), Marine Certificate (ABS, DNV)

Refer to the General Specification sheet located under the Downloads tab for detailed specifications.

General Type

The general type is the basic model of the VY series.
The lineup includes connection size from 15 to 400 mm, process temperatures from -40°C to 250°C, and process pressures up to ASME Class 900.

General Type

[Specific Specification of General Type]

Type of Body General Type
Type of Shedder Bar General Type, Long Neck Type
Accuracy Liquid ± 0.75 % of reading (depends on Reynolds number)
Gas, Steam ± 1.0 % of reading (depends on the flow velocity)
Process Temperature -40 °C to 250 °C
Max Process Pressure ASME Class 900, EN PN100, JIS 40K
Ambient Temperature -40 ( / -50 ) °C to 85 °C
Connection Size Wafer 15 to 100 mm
Flange 15 to 400 mm
Degree of Protection IP66 / IP67

Refer to the General Specification sheet located under the Downloads tab for detailed specifications.

Built-in Temperature Sensor Type

The built-in temperature sensor type has a temperature sensor (Pt1000) built into the shedder bar (vortex shedder bar), allowing simultaneous measurement of the process fluid temperature.
These flowmeters are compatible with connection size from 25 to 300 mm, and can also be used in conjunction with high-temperature type and reduced bore type models, allowing them to handle a wide range of fluids. Compensation calculations are performed at temperatures close to that at the center of the pipe, enabling more accurate measurement of flow rates. Signals from an external pressure gauge can be captured and used in compensation calculations with the external input (analog input function with HART7 with analog input option or input via MAO function block for FOUNDATION Fieldbus) to support even more accurate flow measurement.

Built-in Temperature Sensor Type

[Specific Specification of Built-in Temperature Sensor Type]

Type of Body General Type
[Combinationable Body] Reduced Bore Type (1 or 2 size reduction)
Type of Shedder Bar General Type with Temperature Sensor, Long Neck Type with Temperature Sensor
[Combinationable Shedder bar] Hight Temperature Type with Temperature Sensor
Accuracy Liquid ± 0.75 % of reading (depends on Reynolds number)
Gas, Steam ± 1.0 % of reading (depends on the flow velocity)
Process Temperature -40 °C to 250 °C (For General Type and Long Neck Type)
-40 °C to 400 °C (For High Temperature Type)
Max Process Pressure ASME Class 900, EN PN100, JIS 40K
Ambient Temperature -40 ( / -50 ) °C to 85 °C
Connection Size Wafer 25 to 100 mm
Flange 25 to 300 mm
Degree of Protection IP66 / IP67

Refer to the General Specification sheet located under the Downloads tab for detailed specifications.

High-Temperature / Cryogenic Type

The high-temperature and cryogenic models use the materials and sensors required for high-temperature and extremely low-temperature environments.
The high-temperature type handles connection size from 25 to 400 mm and fluid temperatures up to 450°C (up to 400°C with a built-in temperature sensor). The cryogenic type handles connection size from 15 to 100 mm and fluid temperatures of as low as -196°C. From this model, It is possible to select either type as an integral type or remote type.

High Temperature /Cryogenic Type

[Specific Specification of High Temperature Type]

Type of Body General Type
[Combinationable Body] Reduced Bore Type (1 or 2 size reduction)
Type of Shedder Bar High Temperature Type
High Temperature Type with Temperature Sensor
Accuracy Liquid ± 0.75 % of reading (depends on Reynolds number)
Gas, Steam ± 1.0 % of reading (depends on the flow velocity)
Process Temperature -40 °C to 450 °C
Max Process Pressure ASME Class 900, EN PN100, JIS 40K
Ambient Temperature -40 ( / -50 ) °C to 85 °C
Connection Size Wafer 25 to 100 mm
Flange 25 to 400 mm
Degree of Protection IP66 / IP67

[Specific Specification of Cryogenic Type]

Type of Body General Type
[Combinationable Body] Reduced Bore Type (1 or 2 size reduction)
Type of Shedder Bar Cryogenic Type
Accuracy Liquid ± 0.75 % of reading (depends on Reynolds number)
Gas, Steam ± 1.0 % of reading (depends on the flow velocity)
Process Temperature -196 °C to 250 °C
Max Process Pressure ASME Class 900, EN PN100, JIS 40K
Ambient Temperature -40 °C to 85 °C
Connection Size Wafer 15 to 100 mm
Flange 15 to 100 mm
Degree of Protection IP66 / IP67

Refer to the General Specification sheet located under the Downloads tab for detailed specifications.

Reduced Bore Type (1 or 2 Size Reduction)

The reduced bore type is a model in which both upstream and downstream sides of the sensor unit are integrated with a reducer (reduction/expansion pipe). As such, it is ideal for lines where flow rates fluctuate widely depending on the season and operating load.
The reduced bore type are available in two types, one-size reduction and two-size reduction, and the flange model accommodates connection size of up to 200 mm. The reduced bore type can be combined with the built-in temperature sensor type and the high-temperature/cryogenic type, allowing measurement of a wide range of fluids.

Reduced Bore Type (1 or 2 size reduction)

[Specific Specification of Reduced Bore Type (1 or 2 Size Reduction)]

Type of Body Reduced Bore Type (1 or 2 size reduction)
Type of Shedder Bar General Type
[Combinationable Shedder bar] General Type with Temperature Sensor, High Temperature Type
High Temperature Type with Temperature Sensor, Cryogenic Type
Accuracy Liquid ± 1.0 % of reading (depends on Reynolds number)
Gas, Steam ± 1.0 % of reading (depends on the flow velocity)
Process Temperature -40 °C to 250 °C
Max Process Pressure ASME Class 300, JIS 20K
Ambient Temperature -40 ( / -50 ) °C to 85 °C
Connection Size
Flange 1 size reduction: 25 to 200 mm
2 size reduction: 40 to 200 mm
Degree of Protection IP66 / IP67

Refer to the General Specification sheet located under the Downloads tab for detailed specifications.

High-Pressure Type

This is a one-size reduction model with an ASME Class 1500 flange pressure rating. This allows it to provide stable measurement even under harsh high-pressure conditions.
In combination with a general-type sensor, it uses a flange-type connection size 25 to 150 mm.

High Pressure Type

[Specific Specification of High Pressure Type]

Type of Body High Pressure Reduced Bore Type ( 1 size reduction)
Type of Shedder Bar General Type
Accuracy Liquid ± 1.0 % of reading (depends on Reynolds number)
Gas, Steam ± 1.0 % of reading (depends on the flow velocity)
Process Temperature -40 °C to 250 °C
Max Process Pressure ASME Class 1500
Ambient Temperature -40 ( / -50 ) °C to 85 °C
Connection Size
Flange 25 to 150 mm
Degree of Protection IP66 / IP67

Refer to the General Specification sheet located under the Downloads tab for detailed specifications.

Dual-Sensor Type

This type is dual-sensor (welded) type that has a flange pressure rating of up to ASME Class 900. The structure of these two units connected in series is the best choice for applications requiring high reliability.
Size is from 15 mm to 200 mm in combination with several types of sensor.

High Pressure Type

[Specific Specification of Dual-Sensor Type]

Type of Body Dual-Sensor (Welded) General Type
Type of Shedder Bar* General Type, Long Neck Type
[Combinationable Shedder bar] General Type with temperature sensor, Long Neck Type with temperature sensor, High Temperature Type, High Temperature Type with temperature sensor, Cryogenic Type
Accuracy Liquid ± 0.75 % of reading (depends on Reynolds number)
Gas, Steam ± 1.0 % of reading (depends on the flow velocity)
Process Temperature -196 °C to 450 °C
Max Process Pressure ASME Class 900
Ambient Temperature -40 ( / -50 ) °C to 85 °C
Connection Size
Flange 15 to 200 mm
Degree of Protection IP66 / IP67

* Type of shedder bar is same as upstream and downstream
* Refer to the General Specification sheet located under the Downloads tab for detailed specifications.

Examples of VY Series Applications

  • Flow measurement in steam piping
  • Flow measurement of utility gases such as air and nitrogen
  • Flow measurement of hot and cold water, LNG and other cryogenic liquids and chemicals (including inorganic substances)

“Total Insight”  - A Product Concept for Supporting Customers Throughout the Entire Product Lifecycle

From Sensing to Sensemaking

“Total Insight” is a shared concept for Yokogawa’s field products that supports customers throughout the entire product lifecycle. By providing new value through superior technology and insight, it is aimed at optimizing costs over the entire lifecycle. The VY series is developed from four perspectives based on the Total Insight concept.

  • Simplified Selection : Reduced engineering work hours and procurement costs
  • Smart Assist : Reduced start-up time
  • Process Guard : Improved operational efficiency and reduced errors
  • Expert Solution : Improved efficiency in maintenance operations

Reduced Engineering Work Hours and Procurement Costs / Total Insight - Simplified Selection -

Simplified Selection logo

A Comprehensive Lineup to Meet Various Flow Measurement Needs

  • Easy Device Selection
    A wide range of flow sizes, up to 400 mm, can be accommodated. The reduced bore type allows reductions of up to two sizes. With the same face-to face dimensions as successive generations of the YEWFLO series, they can be used safely and reliably for long periods of time.

Easy device selection
Image Zoom

 

  • Compliant With a Wide Range of Standards
    With high quality and functionality, these products conform to a variety of international standards, including
    • Functional safety: IEC 61508 compliant, Safety Integrity Level SIL2
    • Explosion protection: IECEx, ATEX, FM, FMc, Taiwan, UAE, Korea, Brazil, Japan
    • General safety: Various national EMC, PED, EURoHS, CE Mark, CRN, ABS classification, DNV classification
    • Industry standards: NAMUR NE21 , NE107, NACE materials

 

  • Extensive Built-in Calculation Functions
    Calculates volume, mass, and energy flow rates using temperature, pressure, and density from the built-in temperature sensor or external input. The steam tables built into the device are used to calculate the mass and energy of saturated and superheated steam.

Reduced Start-up Time / Total Insight - Smart Assist -

Smart Assist

Provides Stable Flow Measurement Resistant to Vibration

  • Ensures Stable Measurement
    The unique integrated sensing structure of the vortex shedder bar and sensor allows the entire vortex shedder bar to capture the vortex signal. A short straight pipe length enables stable measurement regardless of the mounting position.
  • Accurately Captures the Flow Signal
    The unique sensing structure with two sensor elements cancels piping vibration noise. Yokogawa's proprietary digital signal processing technology “SSP*” removes noise signals, extracting only the vortex signal. Possible false outputs due to piping vibration are indicated by an alarm.

     

    *SSP: Yokogawa's proprietary signal processing that removes noise signals from signals obtained from the two sensor elements to extract the vortex signal.

  • Ready to Use as Soon as Installed
    Device parameters are set at the factory before shipping. The automatic adjustment function provided by SSP basically eliminates the need for on-site adjustment. This means that the devices are ready for use as soon as they are installed. Verification tools, including waveform monitoring, make it easy to check status after installation.

Improved Operational Efficiency and Reduced Errors / Total Insight - Process Guard -

Process Guard

Advanced Self-Diagnostics and Remote Maintenance

  • Self-Diagnosis of the Entire Device Can Be Performed
    All functional blocks are self-diagnosing, allowing easy identification of areas requiring equipment maintenance. Since it conforms to the functional safety SIL2 standard requirements, it can be used in loops that require high reliability, such as safety instrumentation.

Self Diagnostics
Image Zoom

 

  • Supporting Condition-Based Device Maintenance
    Sensor status can be predicted by the FSA130 Magnetic Flowmeter / Vortex Flowmeter Verification Tool (Only for HART communication). Graphical display of the condition of sensor elements accumulated inside the flowmeter to check for changes over time and estimate when maintenance is required.

Improved Efficiency in Maintenance Operations / Total Insight - Expert Solution -

Expert Solution

Various Functions to Support Efficient Maintenance Operations

  • Process-Side and Device-Side Anomalies Can Be Easily Identified
    The process diagnostic function detects piping vibration and fluid oscillation, while the self-diagnostic function monitors the health of the device. This ability to identify anomalies allows for a quick and precise response.
  • Easy Maintenance
    The unique sensing structure of Yokogawa’s vortex shedder bar is known for its robustness and long-term stability, but in the event of unforeseen circumstances, they can be removed for cleaning or replacement. The vortex shedder bar can be easily detached from the body, eliminating the need to remove the entire flowmeter from the piping.

 

  • Reduced Downtime
    Because transmitter parameters can be backed up in the remote sensor’s memory, the current state can be easily restored in the event of a transmitter replacement. This means that operation can be resumed after a short downtime.

Technical Information - Measurement principle -

Vortex flowmeters use the Von Karman Effect to measure the flow rate of liquids, gases, and steam. This section explains the principle.

The Operating Principle of Vortex Flowmeters

  • What Is a Von Karman Vortex?
    In the early 20th century, the Hungarian-born mathematician and physicist Theodore von Karman discovered that when a liquid or gas flows perpendicular to an obstacle, it creates alternating vortices on either side of that obstacle. These rows of vortices are called “Von Karman vortex streets.”

 

What is the Von Karman Effect?

Von Karman further found that the number of vortices generated is proportional to the velocity of the fluid that generates them. This number of vortices generated is called the “Von Karman vortex frequency.” The relationship between the frequency and the flow velocity can be mathematically expressed with the following formula (1). Formula (2) further expresses the relationship with the internal structure of a vortex flowmeter. Putting these two formulas together and expressing them in terms of volumetric flow rate yields formula (3).

Formula (1)Formula (1)

Formula (2)Formula (2)

Formula (3)Formula (3)

f: Von Karman vortex frequency, St: Strouhal number, v: flow velocity, d: width of vortex shedder bar, Q: volumetric flow rate, D: inner diameter of vortex flow meter

The Strouhal number (St) is a dimensionless number determined by the shape and dimensions of the vortex shedder bar, and by properly choosing the shedder bar’s shape, it becomes constant over a wide range of Reynolds number values. Figure 1 shows the relationship between the Reynolds number and the Strouhal number.

Relationship between Reynolds number and Strouhal number (St)
Relationship between Reynolds number and Strouhal number (St)

Therefore, if the Strouhal number is known in advance, the flow rate can be determined by measuring the vortex frequency. It has also been found that the volumetric flow rate can be measured irrespective of the pressure, temperature, density, viscosity, etc. of the fluid. However, when measuring volumetric flow or mass flow under standard (reference) conditions, temperature and pressure corrections are required.

  • How Is Vortex Frequency Measured?
    When vortices form and pass through a vortex shedder bar (obstacle), the pressure in that area is lower than that in the rest of the fluid. This low pressure creates a pressure differential (dp) on each side of the vortex shedder bar, and stress is applied to the vortex shedder bar from the high-pressure side toward the low-pressure side. The position where the vortices are generated switches regularly, causing the position of the low-pressure area to change and the direction of the stress to shift, causing the vortex shedder bar to oscillate. The frequency of this oscillation is the Von Karman vortex frequency.
How is vortex frequency measured?

The vortices generated create low-pressure and high-pressure areas on both sides of the vortex shedder bar, and force is exerted toward the low-pressure area. As the position of the vortices change from one side to the other, the direction of this force is switched, causing the vortex shedder bar to oscillate.

 

Several methods are available as means of measuring this oscillation. The most suitable for this application is the piezoelectric crystal sensor. When compressed, the piezoelectric crystal sensor produces an electrical signal that is processed by the flowmeter’s electronics. By measuring the Von Karman vortex frequency (the Strouhal number and the diameter of the cylinder are known), a simple calculation by the flowmeter’s electronics can determine the rate of volumetric flow through the pipe.

Technical Information - Our Proprietary Signal Processing Technology -

Vortex flowmeters using Von Karman vortices are vibration sensors that count vortex frequencies, and as such, they are susceptible to external vibration noise. However, the VY series uses Yokogawa’s proprietary signal processing technology to ensure stable measurements at all times. Here is how it works.

Noise Reduction

As with previous models, the VY series of vortex flowmeters incorporates Yokogawa’s proprietary signal processing technology, SSP. SSP performs frequency analysis of the signal detected from the vortex shedder bar, divides it into separate bands, and automatically selects the optimal bandpass filter to transmit only the correct vortex signal with the noise removed. Even if the vortex signal contains vibration noise, only the vortex signal is output, thus ensuring stable measurement.

Signal Processing (SSP: Spectral Signal Processing)

Noise Reduction

Noise from strong piping vibration can affect the accuracy of vortex frequency detection, but the two piezoelectric elements in the VY series have reversed polarity, and therefore do not detect vibrations in the flow direction or the perpendicular direction. Noise in the direction of lift is reduced, allowing only the vortex signal to be detected. With superior vibration resistance and diagnostic functions based on our proprietary technology, the VY series provides stable measurements at all times.

Technical Information - Required Straight Pipe Lengths for Different Installation Conditions -

In general, unbalanced velocity distribution in a pipe affects the accuracy of flow measurement in vortex flowmeters. Shown below are the required straight pipe lengths and key points to consider, along with typical installation examples.

Straight Pipe

Ensure at least 10D upstream and 5D downstream.

Straight Pipe

 

Reducer Pipe

Ensure at least 5D upstream and 5D downstream.

Reducer Pipe

 

Expander Pipe

Ensure at least 10D upstream and 5D downstream.

Expander Pipe

 

Bend Pipes

(1) Single bend pipe
Ensure at least 10D upstream and 5D downstream.

Ben Pipes


 

(2) Pipe with double bend in the same plane
Ensure at least 10D upstream and 5D downstream.

Double Bent Pipe in the Same Plane

 

(3) Pipe with double bend not in the same plane
Ensure at least 20D upstream and 5D downstream.

Double Bent Pipe in Another Plane

 

Valve Position and Straight Pipe Length

The valve should be installed downstream of the vortex flowmeter. Ensure an upstream straight pipe length of at least 5 to 10D (see above) and a downstream straight pipe length of at least 5D. If installing the valve upstream of the vortex flowmeter cannot be avoided, ensure a straight pipe length of at least 20D upstream and 5D downstream.

Valve Position and Straight Pipe Length

 

Technical Information - Mounting Orientation -

The mounting can be horizontal, vertical, or inclined, as long as the pipe is always filled with uniformed fluid. However, when installing on horizontal or inclined piping, be sure to mount above the pipe to avoid flooding of the terminal box of separated detectors or the transmitter of integrated models. This is illustrated in the diagrams below.

Horizontal Piping

Mounting Attitude - Horizontal piping 1

Mounting Attitude - Horizontal piping 2

 

Vertical Piping

Mounting Attitude - Vertical Piping Left                  Mounting Attitude - Vertical Piping Right

 

Inclined Piping

Mounting Attitude - Inclined Piping Left                  Mounting Attitude - Inclined Piping Right

Zdroje

It converts pressure changes caused by the Karman vortex generated by a vortex shedder bar into an electrical signal. The vortex flowmeter uses that electrical signal to convert the Karman vortex into a flow rate and output it. ...
When an obstacle called a vortex shedder bar is placed in the flow, vortices are regularly generated alternately on both sides of the vortex shedder bar due to the viscous effect of the fluid. These vortices are called "Karman vortex street"...
JIS Z 8766 "Methods of Flow Measurement by Vortex Flowmeters" lists the following points as features 1) The frequency output is proportional to the flow rate. 2) The Karman vortex oscillation phenomenon of the fluid is utilized, and basica...
Catalogs, general specifications, instruction manuals, structural drawings, and technical information are available.
The vortex shedder bar that detects vortex signals can be removed from the body unit. This allows maintenance such as cleaning the inside of the flowmeter and ensures stable operation over the long term. The signal sensing structure consists of two s...
Zero adjustment is not required. In principle, the zero point of a vortex flowmeter is the state in which no Karman vortex is generated by the vortex shedder bar (i.e., the piezoelectric sensor does not detect the vortex frequency). The Vortex Flowme...
Basically, no adjustment is required after installation. The VY series operates in auto-adjustment mode immediately after power-on using the SSP function of digital signal processing technology. Manual adjustment can be used to avoid the effects of l...
Option specification: /A provides with interchangeable lightning protectors. In this case, the maximum power supply voltage is limited to 30 V DC.
The orientation of the transmitter case or sensor terminal case can be changed every 90 degrees (4 directions). If the flowmeter is non-explosionproof product, work can be performed in the site. If the flowmeter is explosion-proof product, work must ...
Although the operation of the vortex flowmeter is not a problem, Upside-down installation is not recommended except in situations where the transmitter is sufficiently waterproof.
Most flowmeters cannot accurately measure flow unless the inside of the sensor is filled with fluid. Although a bottom-to-top flow is preferable for installation, if it is unavoidable to install in a top-to-bottom flow location, be sure to take care ...
When the cable entry is facing upward, care must be taken to prevent rainwater and other elements from penetrating the cable entry. Therefore, when installing in vertical piping outdoors, etc., it is recommended that the cable entry face down or hori...
In the case of vortex flowmeters, swirling flow and uneven distribution of flow velocity in the piping can affect the measurement. These can be caused by upstream piping conditions, valves, pumps, misaligned joints, protruding weld burrs, or other ob...
If each element of the installation examples listed in GS is combined, add the required straight pipe lengths for each element. For details, please read GS 01F07A00-01JA.
Measurement accuracy cannot be specified because it depends on the measurement conditions. Please keep the required straight pipe length to use with measurement accuracy.
The vortex flowmeter should be installed upstream of the valve to prevent the influence of swirling flow caused by the valve. If the vortex flowmeter is installed downstream of the valve, the straight pipe length should be at least 20D upstream and 5...
Saturated vapor pressure is the pressure indicated by vapor that has reached condensed phase thermodynamic equilibrium at that temperature. Liquids can cause cavitation (bubble generation) depending on temperature and pressure conditions. This can in...
Available up to ASME Class 1500 for standard specification, and Available up to ASME Class 2500 for TOKUCHU specification. Please contact our sales person.
The analog input function enables measurement following changes in pressure in addition to temperature. At that time, the measured value of an external pressure transmitter must be taken in. By doing so, it is possible to follow changes in temperatur...
If an alarm for a built-in temperature sensor occurs, an alarm number is displayed on the display unit. And also self-diagnosis function can be performed using the Verification Tool. For details, refer to IM 01F07A02-01JA.
Size 400 mm with built-in temperature sensor is TOKUCHU specification. Please contact our sales person.
The required straight pipe length of the reduced bore type is the same as that of the general type (same connection size). It will not be shortened. For details, refer to GS 01F07A00-01EN.
One size reduction (body type: -1, -4) is about 15% larger, and two size reduction (body type: -2) is about 28% larger.
It varies depending on the fluid, but the maximum is around 40:1 (general type).
Parts for digitalYEWFLO can be ordered. Please contact our sales person.
Can be ordered as standard specifications. Hastelloy C is listed on the GS as a nickel alloy as a generic name. Please refer to GS01F07A00-01 EN.
If digitalYEWFLO sizing data exists, it can be used to size the VY series. Please contact our sales person.

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The self-diagnostic and remote maintenance functions support Condition Based Maintenance, which performs efficient and planned maintenance. Inherited YEWFLO's sensing structure brings robustness and long term stability.

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