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- 0...0.6 bar 1
- 0...0.6 bar__0...40 bar 5
- 0...0.6 bar__0...40 bar__PN 16/40 or Class 150/300 1
- 0...1.000 bar 1
- 0...1.000 mbar 1
- 0...1 bar__0...10 bar 1
- 0...1 bar__0...25 bar 1
- 0...1 bar__0...40 bar 1
- 0...10.000 bar 1
- 0...10 bar__0...600 bar 1
- 0...16 bar 1
- 0...25 bar 3
- 0...40 bar 1
- 0...60 bar 4
- 0...100 bar 1
- 0...250 bar 1
- 0...400 bar 2
- 0...600 bar 9
- 0...700 bar 3
- 0...1000 bar 2
- 0...1600 bar 1
- 2...20 bar 1
- 10 bar 1
- 10 bar__6 bar__8 bar 6
- 20 bar 1
- 25 bar__40 bar 2
- 25 mbar 1
- 40...400 mbar 1
- 100 bar 1
- 250 bar 1
- 300 bar 1
- 350...400 bar 2
- -0.2...21 bar 1
- -0.2...400 bar 1
- -0.95...40 bar 1
- -0.95...60 bar 1
- -1...1 bar__0...2.000 bar 1
- -1...1 bar__0...2500 bar 1
- -1...2 bar__0...1000 bar 1
- -1...3 bar__0...700 bar 1
- -1...3 bar__0...1000 bar 1
- -1...10 bar__0...1000 bar 1
- -1...18 bar 1
- -1...60 bar 1
- -1...210 bar 2
- -1...250 bar 1
- -1...400 bar 1
- -1...1000 bar 1
- Corresponding to flange specification 1
- From 400 mbar depending on diameter of diaphragm 1
- PN 10 10
- PN 10 €“ 100; Class 150 - 600 1
- PN 16 8
- PN 25 5
- PN 50 2
0...0.6 bar, PN 25, 0...1 bar__0...10 bar, 0...1 bar__0...40 bar - Corresponding to flange specification
9 items
990.15 Flanged Process Connection Diaphragm Seal
2282
Together with a block flange or a saddle flange, the WIKA 990.15 diaphragm seal forms a perfectly matched system. Through the process connection via block flanges or saddle flanges, compact assemblies can be optimally realised at the measuring point. Depending on customer requirements, the model 990.15 can be subsequently integrated into a process using the accessory models 910.19, 910.20 and 910.23. The process connection is designed as a flange connection. The measuring instrument is in a vertical position. Applications Specifically for connection with block flange or saddle flange and to combine with bourdon tube pressure gauges Suitable for corrosive, contaminated, hot or viscous pressure media Chemical and petrochemical industry
- USD
990.17 Sterile Connection Diaphragm Seal
2297
Thanks to its flush process connection, the WIKA 990.17 diaphragm seal is optimally suited for installation in storage tanks. With a suitable welding flange, this diaphragm seal can be integrated into any type of tank or vessel. Level measurement with diaphragm seals also works with media that, due to the process, are under pressure and have high or low viscosity. The WIKA 990.17 diaphragm seal is particularly suitable for CIP cleaning processes as it meets the requirements for elevated temperatures and chemical resistance to cleaning solutions. Mounting of the diaphragm seal to the measuring instrument may be made via a direct connection, for high temperatures via a cooling element or via a flexible capillary. For the material selection, WIKA offers a variety of solutions, in which the diaphragm seal and the wetted parts can be made of identical or different materials. The wetted parts can, as an alternative, be electropolished.
- USD
990.31 Threaded Connection Diaphragm Seal
3243
The WIKA 990.31 diaphragm seal with threaded connection in a plastic version is suitable for versatile application areas in the water supply and wastewater treatment industries. Mounting of the diaphragm seal to the measuring instrument may be made via a direct connection or a flexible capillary. The WIKA 990.31 diaphragm seal is used successfully in chemical plant construction, electroplating and wastewater treatment applications.
- USD
VHS Flow Switch
7589
The SIKA VHS flow switches are used for monitoring volume flows. Depending on conditions, the SIKA VHS flow switch is available for various nominal widths and set-point ranges. The SIKA VHS flow switch contains a paddle system to whose end a permanent magnet is attached. Above this magnet is a reed contact, located outside the flow of fluid. A second magnet creates the force necessary to reset the switch back to the no-flow position. When the flow being monitored pushes against the paddle system, the paddle swings away. This changes the position of the magnet in relation to the reed contact and thus activates the connection. As soon as the flow is interrupted, the paddle moves back to its starting position, thus activating the reed contact once again. The force necessary to push the magnet back is provided by the two magnets repelling each other. Using magnetic force instead of the usual leaf spring means that the switch is considerably more stable in the long term and much less sensitive to pressure peaks.
- USD
VHS09 Flow Switch
7600
The SIKA VHS09 flow switches are used for monitoring volume flows. Depending on conditions, the SIKA VHS09 flow switch is available for various nominal widths and set-point ranges. The SIKA VHS09 flow switch contains a paddle system to whose end a permanent magnet is attached. Above this magnet is a reed contact, located outside the flow of fluid. A second magnet creates the force necessary to reset the switch back to the no-flow position. When the flow being monitored pushes against the paddle system, the paddle swings away. This changes the position of the magnet in relation to the reed contact and thus activates the connection. As soon as the flow is interrupted, the paddle moves back to its starting position, thus activating the reed contact once again. The force necessary to push the magnet back is provided by the two magnets repelling each other. Using magnetic force instead of the usual leaf spring means that the switch is considerably more stable in the long term and much less sensitive to pressure peaks.
- USD
VHS06 Flow Switch
7604
The SIKA VHS06 flow switches are used for monitoring volume flows. Depending on conditions, the SIKA VHS06 flow switch is available for various nominal widths and set-point ranges. The SIKA VHS06 flow switch contains a paddle system to whose end a permanent magnet is attached. Above this magnet is a reed contact, located outside the flow of fluid. A second magnet creates the force necessary to reset the switch back to the no-flow position. When the flow being monitored pushes against the paddle system, the paddle swings away. This changes the position of the magnet in relation to the reed contact and thus activates the connection. As soon as the flow is interrupted, the paddle moves back to its starting position, thus activating the reed contact once again. The force necessary to push the magnet back is provided by the two magnets repelling each other. Using magnetic force instead of the usual leaf spring means that the switch is considerably more stable in the long term and much less sensitive to pressure peaks.
- USD
VH0 Micro Flow Switch
7606
The SIKA VH0 flow switches are used for monitoring volume flows. Depending on conditions, the SIKA VH0 flow switch is available for various nominal widths and set-point ranges. The SIKA VH0 flow switch contains a paddle system to whose end a permanent magnet is attached. Above this magnet is a reed contact, located outside the flow of fluid. A second magnet creates the force necessary to reset the switch back to the no-flow position. When the flow being monitored pushes against the paddle system, the paddle swings away. This changes the position of the magnet in relation to the reed contact and thus activates the connection. As soon as the flow is interrupted, the paddle moves back to its starting position, thus activating the reed contact once again. The force necessary to push the magnet back is provided by the two magnets repelling each other. Using magnetic force instead of the usual leaf spring means that the switch is considerably more stable in the long term and much less sensitive to pressure peaks. Microswitch A microswitch used as a switching element allows a higher electrical switching capacity than a reed switch. The resetting force required by the paddle system is produced by a leaf spring.
- USD
VH3 Flow Switch
7610
The SIKA VH3 flow switches are used for monitoring volume flows. Depending on conditions, the SIKA VH3 flow switch is available for various nominal widths and set-point ranges. The SIKA VH3 flow switch contains a paddle system to whose end a permanent magnet is attached. Above this magnet is a reed contact, located outside the flow of fluid. A second magnet creates the force necessary to reset the switch back to the no-flow position. When the flow being monitored pushes against the paddle system, the paddle swings away. This changes the position of the magnet in relation to the reed contact and thus activates the connection. As soon as the flow is interrupted, the paddle moves back to its starting position, thus activating the reed contact once again. The force necessary to push the magnet back is provided by the two magnets repelling each other. Using magnetic force instead of the usual leaf spring means that the switch is considerably more stable in the long term and much less sensitive to pressure peaks.
- USD
VTR1010...1300 Turbine Flow Sensor
7800
The SIKA VTR1010…1300 turbine flow sensor allows you to determine precisely, dependably and easily the flow rates of different liquids, such as water and other low viscosity liquids, under the most severe conditions. The SIKA VTR1010…1300 sensor is particularly robust and, due to the wide range of nominal diameters and five different pick-ups, can cope with even the most severe conditions. The characteristic variable is the K-factor (pulses per litre) which is specific to each measuring unit, is determined by calibration and specified on the nameplate. A five-point calibration report can be supplied on request. The VTR sensor consists of the measuring turbine and a pick-up mounted on the outside. The liquid flows into the measuring turbine and causes the rotor to move. Due to the characteristic internal diameter, the speed of rotation is directly proportional to the flow rate. The moving rotor blades are detected by the pick-up and this is converted into a pulsed signal proportional to the flow rate.
- USD
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