| Flow, max. | 3 l/min |
| Measuring range/ display range | 0.2 to 3 l/min |
| Viscosity | 39.8 cSt |
Flow Indicators
61 - 80 / 122
| Flow, max. | 3 l/min |
| Measuring range/ display range | 0.2 to 3 l/min |
| Viscosity | 5 cSt |
| Flow, max. | 1 l/min |
| Measuring range/ display range | 0.1 to 1 l/min |
| Viscosity | 205.6 cSt |
| Flow, max. | 1 l/min |
| Measuring range/ display range | 0.1 to 1 l/min |
| Viscosity | 5 cSt |
| Flow, max. | 1 l/min |
| Measuring range/ display range | 0.1 to 1 l/min |
| Viscosity | 39.8 cSt |
| Flow, max. | 1 l/min |
| Measuring range/ display range | 0.1 to 1 l/min |
| Viscosity | 119.2 cSt |
| Flow, max. | 16 l/min |
| Measuring range/ display range | 2 to 16 l/min |
| Viscosity | 70.4 cSt |
| Flow, max. | 16 l/min |
| Measuring range/ display range | 2 to 16 l/min |
| Viscosity | 205.6 cSt |
| Flow, max. | 60 l/min |
| Measuring range/ display range | 5 to 60 l/min |
| Viscosity | 5 cSt |
| Flow, max. | 60 l/min |
| Measuring range/ display range | 5 to 60 l/min |
| Viscosity | 14.4 cSt |
| Flow, max. | 60 l/min |
| Measuring range/ display range | 5 to 60 l/min |
| Viscosity | 70.4 cSt |
| Flow, max. | 60 l/min |
| Measuring range/ display range | 5 to 60 l/min |
| Viscosity | 205.6 cSt |
| Flow, max. | 16 l/min |
| Measuring range/ display range | 2 to 16 l/min |
| Viscosity | 119.2 cSt |
| Flow, max. | 16 l/min |
| Measuring range/ display range | 2 to 16 l/min |
| Viscosity | 119.2 cSt |
| Flow, max. | 60 l/min |
| Measuring range/ display range | 5 to 60 l/min |
| Viscosity | 39.8 cSt |
| Flow, max. | 60 l/min |
| Measuring range/ display range | 5 to 60 l/min |
| Viscosity | 5 cSt |
| Flow, max. | 3 l/min |
| Measuring range/ display range | 0.2 to 3 l/min |
| Viscosity | 70.4 cSt |
| Flow, max. | 3 l/min |
| Measuring range/ display range | 0.2 to 3 l/min |
| Viscosity | 119.2 cSt |
| Flow, max. | 3 l/min |
| Measuring range/ display range | 0.2 to 3 l/min |
| Viscosity | 14.4 cSt |
| Flow, max. | 3 l/min |
| Measuring range/ display range | 0.2 to 3 l/min |
| Viscosity | 119.2 cSt |
A flow meter is a measuring device for indicating the volume flow of liquids or gases. Flow meters can be constructed in different ways depending on the application and requirements. A simple flow meter consists of a housing, an indicator and a pipe with inlet and outlet openings.
Most flow meters use a scale or digital display to indicate the flow rate. Some flow meters also have an alarm function that is activated when the flow reaches or exceeds a certain limit. Most flow meters operate on the basis of flow measurement, e.g. Venturis, orifices or rotameters.
Venturis use a conical orifice to accelerate the flow and measure the pressure drop. Orifices use a plate with a hole to restrict the flow and measure the pressure drop. Rotameters are float flowmeters that use a float in a vertical glass tube that moves with the flow.
The accuracy and sensitivity of flow meters depend on several factors, such as the measuring principle used, the size and shape of the housing and scale, and the sensitivity and accuracy of the calibration. Some flow indicators have high sensitivity and accuracy, but can be sensitive to interference and vibration. Other indicators are more robust and stable, but have lower resolution and sensitivity.
Flow meters are used in many applications, such as the chemical industry to monitor the volume flow of liquids and gases, water treatment to monitor water flow, and the food industry to monitor the volume flow of liquids and gases.
The selection of the right flowmeter depends on the type of medium whose flow needs to be monitored, as well as the specific requirements for the measurement, such as accuracy, sensitivity, flow range and pressure range.
Most flow meters use a scale or digital display to indicate the flow rate. Some flow meters also have an alarm function that is activated when the flow reaches or exceeds a certain limit. Most flow meters operate on the basis of flow measurement, e.g. Venturis, orifices or rotameters.
Venturis use a conical orifice to accelerate the flow and measure the pressure drop. Orifices use a plate with a hole to restrict the flow and measure the pressure drop. Rotameters are float flowmeters that use a float in a vertical glass tube that moves with the flow.
The accuracy and sensitivity of flow meters depend on several factors, such as the measuring principle used, the size and shape of the housing and scale, and the sensitivity and accuracy of the calibration. Some flow indicators have high sensitivity and accuracy, but can be sensitive to interference and vibration. Other indicators are more robust and stable, but have lower resolution and sensitivity.
Flow meters are used in many applications, such as the chemical industry to monitor the volume flow of liquids and gases, water treatment to monitor water flow, and the food industry to monitor the volume flow of liquids and gases.
The selection of the right flowmeter depends on the type of medium whose flow needs to be monitored, as well as the specific requirements for the measurement, such as accuracy, sensitivity, flow range and pressure range.
What are flow indicators and what are they used for?
Flow indicators are devices that measure and display the flow of liquids or gases. They are used to monitor the flow rate, velocity or quantity of liquid or gas flowing through a pipe, line or system.
Flow indicators are used in various industries and applications, including the process industry, water treatment, food and beverage, chemical, oil and gas, pharmaceutical and many others. They help to control and monitor the flow in various systems to ensure efficient and reliable operation.
There are different types of flow indicators, including mechanical indicators such as impellers, turbines or floats, electronic indicators such as ultrasonic, magnetic-inductive or eddy current flow meters, and digital flow indicators that show the flow value on a display. The selection of the right flow indicator depends on various factors such as the medium, pressure, temperature and other specific requirements of the application.
Flow indicators are used in various industries and applications, including the process industry, water treatment, food and beverage, chemical, oil and gas, pharmaceutical and many others. They help to control and monitor the flow in various systems to ensure efficient and reliable operation.
There are different types of flow indicators, including mechanical indicators such as impellers, turbines or floats, electronic indicators such as ultrasonic, magnetic-inductive or eddy current flow meters, and digital flow indicators that show the flow value on a display. The selection of the right flow indicator depends on various factors such as the medium, pressure, temperature and other specific requirements of the application.
How do flow indicators work and what types are there?
Flow indicators are instruments for measuring and displaying the flow of liquids or gases in a pipe or line. They are used to monitor and control the flow to ensure that it meets the desired requirements.
There are different types of flow indicators based on different measuring principles:
1. Mechanical flow indicators: These use mechanical components such as impellers, floats or rotary pistons to measure the flow rate. The liquid or gas causes the components to move, and the rotation or movement is then displayed on a scale or counter.
2. Differential pressure flow indicators: These are based on the principle of the pressure difference generated by a constriction in the pipeline. The pressure difference is proportional to the flow rate, and an indicator or meter measures the pressure difference and displays the flow rate.
3. Ultrasonic flow indicators: These use ultrasonic waves to measure the flow rate. A transmitter sends ultrasonic waves into the medium and a receiver measures the time it takes for the sound waves to travel through the medium. Based on these measurements, the flow rate can be calculated and shown on a display.
4. Magnetic-inductive flow indicators: These use the principle of electromagnetic induction to measure the flow rate. An electrically conductive fluid flows through the medium and a magnetic field is generated. The movement of the fluid generates a voltage that is proportional to the flow rate, and this voltage is shown on a display.
5. Thermal flow indicators: These are based on the principle of heat transfer. A heating element heats the flow and a temperature sensor measures the temperature difference between the heated area and the unheated area. These measurements can be used to calculate and display the flow rate.
Different flow indicators can be used depending on the application and requirements. It is important to select the appropriate type of flow indicator to obtain accurate and reliable measurements.
There are different types of flow indicators based on different measuring principles:
1. Mechanical flow indicators: These use mechanical components such as impellers, floats or rotary pistons to measure the flow rate. The liquid or gas causes the components to move, and the rotation or movement is then displayed on a scale or counter.
2. Differential pressure flow indicators: These are based on the principle of the pressure difference generated by a constriction in the pipeline. The pressure difference is proportional to the flow rate, and an indicator or meter measures the pressure difference and displays the flow rate.
3. Ultrasonic flow indicators: These use ultrasonic waves to measure the flow rate. A transmitter sends ultrasonic waves into the medium and a receiver measures the time it takes for the sound waves to travel through the medium. Based on these measurements, the flow rate can be calculated and shown on a display.
4. Magnetic-inductive flow indicators: These use the principle of electromagnetic induction to measure the flow rate. An electrically conductive fluid flows through the medium and a magnetic field is generated. The movement of the fluid generates a voltage that is proportional to the flow rate, and this voltage is shown on a display.
5. Thermal flow indicators: These are based on the principle of heat transfer. A heating element heats the flow and a temperature sensor measures the temperature difference between the heated area and the unheated area. These measurements can be used to calculate and display the flow rate.
Different flow indicators can be used depending on the application and requirements. It is important to select the appropriate type of flow indicator to obtain accurate and reliable measurements.
What are the advantages of digital flow indicators compared to analog ones?
Digital flow indicators offer several advantages compared to analog flow indicators:
1. Accuracy: Digital flow indicators offer greater accuracy in measuring and displaying the flow rate. They can detect minor changes in the flow rate and provide more accurate measured values.
2. Flexibility: Digital flow indicators can be easily adapted to different measuring devices and systems. They can display different units and can be configured more easily to meet the user's requirements.
3. Data acquisition and processing: Digital flow indicators enable the recording and processing of flow data. You can save, analyze and display data in real time. This enables better monitoring and control of the flow.
4. Communication: Digital flow indicators enable communication with other devices and systems. They can be connected to other devices via interfaces such as USB, Ethernet or wireless connections in order to exchange and integrate data.
5. Ease of use: Digital flow indicators generally offer a user-friendly interface and operation. They are easier to read and often offer additional functions such as alarms, trend charts and settings for different applications.
6. Reliability: Digital flow indicators are often more robust and less susceptible to faults than analog indicators. They are less susceptible to wear and offer a longer service life.
These advantages make digital flow indicators a popular choice in various industries such as the chemical industry, food production, pharmaceuticals and the oil and gas industry.
1. Accuracy: Digital flow indicators offer greater accuracy in measuring and displaying the flow rate. They can detect minor changes in the flow rate and provide more accurate measured values.
2. Flexibility: Digital flow indicators can be easily adapted to different measuring devices and systems. They can display different units and can be configured more easily to meet the user's requirements.
3. Data acquisition and processing: Digital flow indicators enable the recording and processing of flow data. You can save, analyze and display data in real time. This enables better monitoring and control of the flow.
4. Communication: Digital flow indicators enable communication with other devices and systems. They can be connected to other devices via interfaces such as USB, Ethernet or wireless connections in order to exchange and integrate data.
5. Ease of use: Digital flow indicators generally offer a user-friendly interface and operation. They are easier to read and often offer additional functions such as alarms, trend charts and settings for different applications.
6. Reliability: Digital flow indicators are often more robust and less susceptible to faults than analog indicators. They are less susceptible to wear and offer a longer service life.
These advantages make digital flow indicators a popular choice in various industries such as the chemical industry, food production, pharmaceuticals and the oil and gas industry.
What factors influence the accuracy of flow indicators?
There are several factors that can influence the accuracy of flow indicators:
1. Calibration: The accuracy of the flow rate display depends on correct calibration. Regular checking and, if necessary, adjustment of the calibration is required to ensure accurate measurement.
2. Measurement range: The selected measuring range of the flow rate display can influence the accuracy. Exceeding or falling below the measuring range can lead to inaccurate measurement results.
3. Flow profile: The flow profile of the medium flowing through the flow indicator can influence the accuracy. A uniform and stable flow profile enables a more accurate measurement than a turbulent or unstable flow profile.
4. Pressure loss: The pressure loss caused by the flow indicator can affect the accuracy. A high pressure loss can lead to a change in the flow behavior and thus to inaccurate measurement results.
5. Temperature and viscosity changes: Changes in the temperature and viscosity of the medium can affect the accuracy of the flow rate display. These changes can lead to a change in the flow behavior and thus to inaccurate measurement results.
6. Pollution: Contamination of the flow indicator, for example due to deposits or particles in the medium, can impair the accuracy. Regular cleaning and maintenance is therefore necessary to ensure accurate measurement.
7. Installation position: The installation position of the flow indicator can influence the accuracy. An incorrect installation position can lead to a change in the flow behavior and thus to inaccurate measurement results.
It is important to consider these factors when selecting and using flow indicators to ensure accurate measurement.
1. Calibration: The accuracy of the flow rate display depends on correct calibration. Regular checking and, if necessary, adjustment of the calibration is required to ensure accurate measurement.
2. Measurement range: The selected measuring range of the flow rate display can influence the accuracy. Exceeding or falling below the measuring range can lead to inaccurate measurement results.
3. Flow profile: The flow profile of the medium flowing through the flow indicator can influence the accuracy. A uniform and stable flow profile enables a more accurate measurement than a turbulent or unstable flow profile.
4. Pressure loss: The pressure loss caused by the flow indicator can affect the accuracy. A high pressure loss can lead to a change in the flow behavior and thus to inaccurate measurement results.
5. Temperature and viscosity changes: Changes in the temperature and viscosity of the medium can affect the accuracy of the flow rate display. These changes can lead to a change in the flow behavior and thus to inaccurate measurement results.
6. Pollution: Contamination of the flow indicator, for example due to deposits or particles in the medium, can impair the accuracy. Regular cleaning and maintenance is therefore necessary to ensure accurate measurement.
7. Installation position: The installation position of the flow indicator can influence the accuracy. An incorrect installation position can lead to a change in the flow behavior and thus to inaccurate measurement results.
It is important to consider these factors when selecting and using flow indicators to ensure accurate measurement.
What different units are used to measure the flow rate?
There are different units that are used to measure the flow rate. The most common units are
- cubic meters per second (m³/s): This unit measures the volumetric flow rate, i.e. the amount of liquid or gas that flows through a certain area per second.
- liters per minute (l/min): This unit is often used for smaller flow rates, for example in household appliances or medical applications.
- Gallons per minute (gpm): This unit is mainly used in the USA and measures the flow of liquids.
- cubic feet per minute (cfm): This unit is mainly used for the flow of gases, for example in air conditioning and ventilation technology.
- barrels per day (bpd): This unit is mainly used in the oil and gas industry and measures the daily flow of crude oil or natural gas.
There are other units such as liters per hour, cubic meters per hour, cubic feet per hour or cubic meters per day, which can be used depending on the area of application.
- cubic meters per second (m³/s): This unit measures the volumetric flow rate, i.e. the amount of liquid or gas that flows through a certain area per second.
- liters per minute (l/min): This unit is often used for smaller flow rates, for example in household appliances or medical applications.
- Gallons per minute (gpm): This unit is mainly used in the USA and measures the flow of liquids.
- cubic feet per minute (cfm): This unit is mainly used for the flow of gases, for example in air conditioning and ventilation technology.
- barrels per day (bpd): This unit is mainly used in the oil and gas industry and measures the daily flow of crude oil or natural gas.
There are other units such as liters per hour, cubic meters per hour, cubic feet per hour or cubic meters per day, which can be used depending on the area of application.
How can flow indicators be calibrated and adjusted?
Flow indicators can be calibrated and adjusted in various ways, depending on the type of flow indicator in question. Here are some common methods:
1. Use of a known reference current: One possibility is to connect the flow indicator to a known reference flow and compare the displayed values with the actual values. In this way, the display can be adjusted to ensure correct measurement.
2. Use of a calibration device: There are special calibration devices that can be used to calibrate flow indicators. These devices generate a known flow rate and allow the display to be adjusted accordingly.
3. Use of a liquid container: Another method is to use a container with a known amount of liquid and measure the time it takes to pass this amount through the flow indicator. The display can be adjusted by comparing it with the expected values.
4. Checking the sensors: If the flow indicator uses sensors, these should be checked regularly and calibrated if necessary. This can be done by comparison with a known flow rate or by using a special calibration device.
It is important to note that the exact procedure for calibrating and adjusting a flow indicator may vary from model to model. It is therefore advisable to consult the manufacturer's instructions and, if necessary, seek professional help to ensure accurate and reliable calibration.
1. Use of a known reference current: One possibility is to connect the flow indicator to a known reference flow and compare the displayed values with the actual values. In this way, the display can be adjusted to ensure correct measurement.
2. Use of a calibration device: There are special calibration devices that can be used to calibrate flow indicators. These devices generate a known flow rate and allow the display to be adjusted accordingly.
3. Use of a liquid container: Another method is to use a container with a known amount of liquid and measure the time it takes to pass this amount through the flow indicator. The display can be adjusted by comparing it with the expected values.
4. Checking the sensors: If the flow indicator uses sensors, these should be checked regularly and calibrated if necessary. This can be done by comparison with a known flow rate or by using a special calibration device.
It is important to note that the exact procedure for calibrating and adjusting a flow indicator may vary from model to model. It is therefore advisable to consult the manufacturer's instructions and, if necessary, seek professional help to ensure accurate and reliable calibration.
How can flow indicators be used to monitor and control processes?
Flow indicators can be used to monitor and control processes in various ways:
1. Monitoring of the flow rate: Flow indicators make it possible to measure and monitor the current flow rate in a process. This can help to ensure that the flow is within certain limits and that the process is running properly.
2. Control of the flow rate: Flow indicators can also be used to control the flow in a process. This can be achieved by connecting them to control valves or other control elements to adjust the flow according to requirements.
3. Alerting in the event of deviations: Flow indicators can be connected to alarm systems to alert in the event of deviations from the desired flow level. This makes it possible to identify problems in the process at an early stage and take measures to rectify them.
4. Data collection and analysis: Flow indicators can also be used for data acquisition and analysis. By recording and analyzing flow data, trends and patterns can be identified that indicate potential problems or optimization opportunities.
Overall, flow indicators can help to improve the efficiency, safety and quality of processes by enabling precise monitoring and control of the flow.
1. Monitoring of the flow rate: Flow indicators make it possible to measure and monitor the current flow rate in a process. This can help to ensure that the flow is within certain limits and that the process is running properly.
2. Control of the flow rate: Flow indicators can also be used to control the flow in a process. This can be achieved by connecting them to control valves or other control elements to adjust the flow according to requirements.
3. Alerting in the event of deviations: Flow indicators can be connected to alarm systems to alert in the event of deviations from the desired flow level. This makes it possible to identify problems in the process at an early stage and take measures to rectify them.
4. Data collection and analysis: Flow indicators can also be used for data acquisition and analysis. By recording and analyzing flow data, trends and patterns can be identified that indicate potential problems or optimization opportunities.
Overall, flow indicators can help to improve the efficiency, safety and quality of processes by enabling precise monitoring and control of the flow.
What areas of application are there for flow indicators outside of industry?
Flow indicators are also used outside of industry in various areas, including:
1. Households: Flow indicators can be used in households to monitor and control water consumption. They help to reduce water wastage and save costs.
2. Agriculture: In agriculture, flow indicators can be used to monitor water consumption in irrigation systems. This enables efficient use of water resources and optimum irrigation of the plants.
3. Environmental monitoring: Flow indicators can also be used in environmental monitoring to measure the flow of water in rivers, streams or canals. This information is important for monitoring water quality and assessing environmental impacts.
4. Water treatment: Flow indicators are used in water treatment plants to measure and monitor the flow of water or other liquids. This helps to control processes for cleaning and treating water.
5. Swimming pools: Flow indicators can be used in swimming pools to monitor the water flow in the filters and pumps. This enables efficient purification of the water and good water quality.
6. Laboratories: Flow indicators are used in laboratories to measure the flow of liquids in various experiments and processes. This is important in order to achieve accurate and reproducible results.
7. Medical applications: In medicine, flow indicators can be used to monitor the flow of fluids in medical devices such as infusion pumps, dialysis machines or ventilators.
8. Vehicle technology: In vehicle technology, flow indicators can be used in fuel systems or cooling circuits to monitor the flow of fluids and ensure that the systems are working properly.
These applications show that flow indicators can be used in many different areas to measure and monitor the flow of liquids.
1. Households: Flow indicators can be used in households to monitor and control water consumption. They help to reduce water wastage and save costs.
2. Agriculture: In agriculture, flow indicators can be used to monitor water consumption in irrigation systems. This enables efficient use of water resources and optimum irrigation of the plants.
3. Environmental monitoring: Flow indicators can also be used in environmental monitoring to measure the flow of water in rivers, streams or canals. This information is important for monitoring water quality and assessing environmental impacts.
4. Water treatment: Flow indicators are used in water treatment plants to measure and monitor the flow of water or other liquids. This helps to control processes for cleaning and treating water.
5. Swimming pools: Flow indicators can be used in swimming pools to monitor the water flow in the filters and pumps. This enables efficient purification of the water and good water quality.
6. Laboratories: Flow indicators are used in laboratories to measure the flow of liquids in various experiments and processes. This is important in order to achieve accurate and reproducible results.
7. Medical applications: In medicine, flow indicators can be used to monitor the flow of fluids in medical devices such as infusion pumps, dialysis machines or ventilators.
8. Vehicle technology: In vehicle technology, flow indicators can be used in fuel systems or cooling circuits to monitor the flow of fluids and ensure that the systems are working properly.
These applications show that flow indicators can be used in many different areas to measure and monitor the flow of liquids.