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Measuring range
Medium Temperature
- 0...20°C__0...60°C 1
- 0...50 °C 3
- 0...85°C 2
- 0...90°C 1
- 0...90°C__95°C 2
- 2€°200°C__ 150°C 1
- 5...60°C 1
- 10...100°C 1
- 30...100°C 2
- 60°C 7
- 80°C 2
- 120°C__30...100°C 1
- 200°C 1
- 200°C__Max. 100°C 4
- -10€°160°C 1
- -10...50°C 3
- -10...60°C 5
- -10...70 °C 1
- -10...90°C 5
- -10...120°C 1
- -20°200°C 1
- -20...60°C 1
- -20...70°C 1
- -20...70°C__0...70°C 1
- -20...80°C 3
- -20...85°C 1
- -20...90°C 3
- -20...100°C 3
- -20...110°C 1
- -20...130°C__-20...150°C 1
- -20...150°C 3
- -25...100°C 5
- -25...100°C__0...20°C 1
- -25...110°C 3
- -30...60°C 1
- -30...85°C 1
- -30...150°C 5
- -30...200°C 1
- -40°80°C 2
- -40...75°C 1
- -40...85°C 1
- -40...100°C 4
- -40...110°C 1
- -40...120°C 2
- -40...125°C 1
- -50°180°C 3
- Max. 60°C 4
- Max. 85°C 5
- Max. 100°C 17
- Max. 100°C__Max. 200°C 1
- Max. 110°C 3
- Max. 115°C 1
- Max. 120°C 1
- Max. 125°C  1
- Max. 150°C 1
- Max. 200°C 5
- O-Ring FKM: -15°C...150°C__O-Ring NBR: -30°C...100° 1
- see sealing material 1
Nominal Size
-20°200°C - Max. 85°C
6 items
SITRANS FUS SONO 3100
3570
The SIEMENS SITRANS FUS SONO 3100/SITRANS FUS060 flowmeter consists of a SITRANS FUS SONO 3100 sensor with O-ring or flange transducers depending on the application. The standard version is delivered as a 2-track sensor with or without flanges; 4 tracks are available upon request. Available pipe materials include carbon or stainless steel on request. The SITRANS FUS060 transmitter is engineered for high-performance applications and designed for remote installation in hazardous and non-hazardous environments. In addition to the standard outputs, it also offers communication.
- USD
VTM 40 Turbine Flow Sensor
7803
The SIKA VTM 40 turbine flow sensor is made for flow measurement or dosing applications for liquids. Because of the very compact design, the extensive measuring range and the convincing precision of measurements, almost unlimited applications are possible. The sturdy bearing materials – sapphire and tungsten carbide – also guarantee an exceptionally long endurance. The liquid flowing into the SIKA VTM 40 turbine flow sensor is split into individual jets by the guiding blade. These jets hit the rotor evenly from different directions, setting the rotor in motion. The rotation speed of the rotor is then converted to an electrical pulse signal (frequency): The rotor is fitted with magnets and a Hall effect sensor detects the rotation of the rotor. A flow-proportional frequency signal (square-wave signal) is made available. The construction of the guiding blade and rotor enables to realize the very low start-up flow values.
- USD
VTH 40 Turbine Flow Sensor
7805
The SIKA VTH 40 turbine flow sensor is made for flow measurement or dosing applications for liquids. Because of the very compact design, the extensive measuring range and the convincing precision of measurements, almost unlimited applications are possible. The sturdy bearing materials – sapphire and tungsten carbide – also guarantee an exceptionally long endurance. The liquid flowing into the SIKA VTH 40 turbine flow sensor is split into individual jets by the guiding blade. These jets hit the rotor evenly from different directions, setting the rotor in motion. The rotation speed of the rotor is then converted to an electrical pulse signal (frequency): The rotor is fitted with magnets and a Hall effect sensor detects the rotation of the rotor. A flow-proportional frequency signal (square-wave signal) is made available. The construction of the guiding blade and rotor enables to realize the very low start-up flow values.
- USD
VTM 25 Turbine Flow Sensor
7807
The SIKA VTM 25 turbine flow sensor is made for flow measurement or dosing applications for liquids. Because of the very compact design, the extensive measuring range and the convincing precision of measurements, almost unlimited applications are possible. The sturdy bearing materials – sapphire and tungsten carbide – also guarantee an exceptionally long endurance. The liquid flowing into the SIKA VTM 25 turbine flow sensor is split into individual jets by the guiding blade. These jets hit the rotor evenly from different directions, setting the rotor in motion. The rotation speed of the rotor is then converted to an electrical pulse signal (frequency): The rotor is fitted with magnets and a Hall effect sensor detects the rotation of the rotor. A flow-proportional frequency signal (square-wave signal) is made available. The construction of the guiding blade and rotor enables to realize the very low start-up flow values.
- USD
VTI 15 Turbine Flow Sensor
7819
The SIKA VTI 15 turbine flow sensor is made for flow measurement or dosing applications for liquids. Because of the very compact design, the extensive measuring range and the convincing precision of measurements, almost unlimited applications are possible. The sturdy bearing materials – sapphire and tungsten carbide – also guarantee an exceptionally long endurance. The liquid flowing into the SIKA VTI 15 turbine flow sensor is split into individual jets by the guiding blade. These jets hit the rotor evenly from different directions, setting the rotor in motion. The rotation speed of the rotor is then converted to an electrical pulse signal (frequency): The rotor is fitted with magnets and a Hall effect sensor detects the rotation of the rotor. A flow-proportional frequency signal (square-wave signal) is made available. The construction of the guiding blade and rotor enables to realize the very low start-up flow values.
- USD
VTH 15 Turbine Flow Sensor
7825
The SIKA VTH 15 turbine flow sensor is made for flow measurement or dosing applications for liquids. Because of the very compact design, the extensive measuring range and the convincing precision of measurements, almost unlimited applications are possible. The sturdy bearing materials – sapphire and tungsten carbide – also guarantee an exceptionally long endurance. The liquid flowing into the SIKA VTH 15 turbine flow sensor is split into individual jets by the guiding blade. These jets hit the rotor evenly from different directions, setting the rotor in motion. The rotation speed of the rotor is then converted to an electrical pulse signal (frequency): The rotor is fitted with magnets and a Hall effect sensor detects the rotation of the rotor. A flow-proportional frequency signal (square-wave signal) is made available. The construction of the guiding blade and rotor enables to realize the very low start-up flow values.
- USD
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