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- 1/4 NPT-F 1
- 1/4 NPT-F__Adapter 1/2 NPT-F__Adapter 1/2 NPT-M 1
- 1 NPT__½ NPT__¾ NPT 1
- 1 NPT__G ½ B__G ¾ B male__½ NPT__¾ NPT 1
- 2-wire 1
- 2-wire__3-wire__4-wire 8
- 2-wire__3-wire__4-wire__G ¼__G ½__G…œ__M10 x 1__M14×1.5 1
- 2x 3-wire__3-wire__4-wire 1
- 2 x G ¼ B female__2 x G ½ B male__½ NPT male 1
- 2 x G ¼ female__2 x ¼ NPT female 2
- 2 x G ¼ female__Centre distance 26 mm__In-line__Lower 1
- 2 x G½ female, lower mount (LM) 1
- 3-wire__4-wire 1
- 14 mm flats lower mount 1
- 9/16 - 18 UNF (female)__M16 x 1.5 (female)__M20 x 1. 1
- 5/8 - 18 UNF (female)__9/16 - 18 UNF (female)__G ½__M 1
- 5/8 - 18 UNF x 27 (female)__9/16 - 18 UNF (female)__ 1
- 19 mm flats__2 x G 3/8 B (male)__Back mount__Lower mo 1
- 7/16-20 UNF 2B Schrader female 1
- 7/16-20 UNF BOSS__G¼ B EN 837 1
- 22 mm flats__G ½ 1
- 25.4...49.5 mm 1
- 26.7 mm__33.4 mm__48.3 mm 1
- 40 mm__50 mm 1
- ¼ NPT female 1
- ANSI Flange__DIN Flange 1
- ANSI Flange__Flange 4
- Back connection 1
- Back mount__G ½__Lower mount 1
- Back mount__Thermowell G½ B 1
- BSP ISO 228__NPT__ DN 50 1
- Butt Weld 2
- Clamp connection per DIN 32676 / ISO 2852 / BS4825 1
- Copper alloy, lower mount (LM) G 1/4 B (male), 14 1
- DIN 11864 1
- DN 100__DN 25__DN 40__DN 50__DN 80 1
- Flange 17
- Flange__G ¼__G ¼ A__G ½ A__¼ NPT female__½ NPT 1
- Flange__G…›__G…œ 1
- Flange__Screwed 1
- Flanged 74
- G 1/4 (female)__G 1/4 (male) 1
- G 1 1
- G 1„8__G ¼ 2
- G 1„8__G ¼__M10 x 1__R 1/8__¼ NPT__…› NPT 2
- G 1¼ 1
- G 1¼ male thread 2
- G 1__G 1„8 1
- G1__G2__G¼__G½__G¾ 1
- G 1__G 2__G ¼__G ½__G…œ 1
- G1__G¼__G½__G¾ 2
- G 1__M33 x 2 1
- G1 B__G½ B__M20 x 1.5__Push-in/weld-in__½ NPT 1
- G1 female__G¾ B__M20 x 1.5 male 1
- G1-ISO 228 male 1
- G 1 male thread 1
- G1 male thread 2
- G2 2
- G¼ 4
- G ¼...G 1 2
- G¼ / H16 UNF 1
- G¼__G¼ A__G½ A__M20 x 1.5__¼ NPT female__½ NPT 1
- G ¼__G¾ 1
- G¼__G…› 1
- G ¼__SW 14 1
- G¼__SW 14 1
- G¼ A DIN 3852-E__¼ NPT 1
- G¼ A DIN 3852-E__sealing FKM/FPM 1
- G¼ B (male)__G½ B (male)__SW14__SW22 1
- G ¼ B (male)__Stainless steel 316L 1
- G ¼ B (male)__SW 14 1
- G¼ B (NS63)__G½ B (NS80, 100) 1
- G ¼ B__G …› B__¼ NPT__…› NPT 1
- G ¼ B female__G ½ B male__½ NPT male 1
- G ¼ female__G ½ female 1
- G ½ 1
- G½ 4
- G ½...G 2 2
- G ½__G¼ 1
- G ½__G¼__M20 x 1.5__½ NPT 1
- G ½__G¼__SW 14__SW 17__SW 22 1
- G ½__G¾ 1
- G½__G¾__M20 x 1.5__M27 x 2 4
- G ½__G¾__M24x2 1
- G½__G…œ__M20 x 1.5 2
- G ½__Lower mount__SW22 1
- G ½__Lower mount__SW 27 1
- G ½__SW 22 1
- G ½ B 2
- G ½ B (lower mount) 1
- G½ B (male)__Stainless steel 316L__SW 22 1
- G ½ B__¼ NPT__½ NPT 1
- G ½ B__½ NPT__½ NPT female 1
- G½ B__G¾ B male 1
- G ½ B__M20 x 1.5__½ NPT 1
- G ½ B female__G ½ B male__½ NPT male 1
- G ½ B male__SW 22 1
- G ½ B thread 1
- G½-ISO 228 male 1
- G½-ISO 228 male__G¾-ISO 228 1
- G½ male 1
- G¾ 5
- G…œ 1
- G …œ...G 1 1
- JIS flange 4
- Lower mount__¼ NPT female 1
- NS 40: G 1/8 B (male) NS 50, 63: G 1/4 B (male), 1
- Pipe adapter 1
- Rp 1/2__Rp 3/4 1
- Rp - female thread cylindrical (BSPT) 1
- Socket Weld 3
- Stainless steel 1
- Surface mounting 1
- Threaded 15
- UExSC 1
- UExUE 1
- Union End Sil Braze 9
- Union nut 1
- Via subplate with lateral female thread connection 2
Flow Rate (l/min)
Material Spec
Medium Temperature
Nominal Diameter
Pressure Range
G¾
5 items
VMZ 15 Magnetic Inductive Flow Sensor
7639
The SIKA VMZ 15 magnetic inductive flow sensor for electrically conductive liquids is designed for OEM applications. Thanks to the use of cost-optimized plastic components, the SIKA VMZ 15 has a compact and lightweight design. The smart flow sensors of the SIKA VMZ 15 induQ® series operate according to the principle of induction: The measuring pipe is in a magnetic field (B). If an electrically conductive medium, with the flow (Q) to be measured, flows through the measuring pipe and thereby at a right-angle to the magnetic field, a voltage (U) is induced in the medium. This voltage is proportional to the average flow velocity and is picked up by two electrodes. Regarding flow proportional output signals, two versions are available: Frequency output signal (standard) Analog and frequency output signal (option) The pulse rate can be configured at the factory. The induQ® sensors enable the flow measurement/volume flow measurement or dosing of electrically conductive liquids without any moving parts. They are the ideal flow sensors when accuracy and reliability are a must.
- USD
VTY 15 Turbine Flow Sensor
7792
The SIKA VTY 15 turbine flow sensor gives you precise and robust products to measure flow rates or total flows, for water and water mixtures. The VTY 15 turbine flow sensor is specially developed for installation in electrical heat interface units (HIU). The sensors are particularly suitable for use in, e.g. dosing systems, heaters, coolers or temperature control units. The liquid flowing into the turbine flow sensor is split into individual jets by the flow straightener. These jets hit the rotor evenly, 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. Given the uniform inflow to the bearing, the forces largely cancel themselves out and wear reduced to a minimum. The sturdy bearing materials “ sapphire and hard metal “ also guarantee an exceptionally long endurance.
- 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
VTM 15 Turbine Flow Sensor
7823
The SIKA VTM 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 VTM 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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