Related to "transformer manufacturer"

The Rugged Monitoring O201 is a compact design, designed for reliability to operate in extreme EMI, RFI, Microwave and high voltage environments. The O201 Fiber optic monitor combines reliability and user friendly configuration software.  It is a multi-channel fiber optic temperature monitor with precision measurement for Original Equipment manufacturers. The O201 has a measuring range from -271 °C to +300 °C. The system offers complete immunity to RFI, EMI, microwave radiation, and High Voltages  making it an optimal choice  for environments where the limitations of conventional temperature sensors/ monitors impact usage in extreme conditions. The system is based on proven GaAs technology  and designed for Plug and Play operation.

The O201 is designed to collect data and easy to integrate into existing systems through serial communication like RS-485 or analog outputs like 0-10 V / 4-20 mA. The O201 supports Modbus, CANbus protocols and a system fault relay. The module is designed with capability to add additional application logic for customer specific applications. It is designed with the needs of Monitoring, Test platforms or Industrial Process monitoring integration needs. It has the data integration capability of multiple test platforms.  Industry standard drivers availlable for a quick and easy connect to most popular laboratories softwares. There is a dedicated team for application specific customizations for fiber optic sensors,  monitor configuration and software integration to simplify the data collection of testing and monitoring applications.  

Description:

The Rugged Monitoring O201 is a compact design, designed for reliability to operate in extreme EMI, RFI, Microwave and high voltage environments. The O201 Fiber optic monitor combines reliability and user friendly configuration software.  It is a multi-channel fiber optic temperature monitor with precision measurement for Original Equipment manufacturers. The O201 has a measuring range from -271 °C to +300 °C. The system offers complete immunity to RFI, EMI, microwave radiation, and High Voltages  making it an optimal choice  for environments where the limitations of conventional temperature sensors/ monitors impact usage in extreme conditions. The system is based on proven GaAs technology  and designed for Plug and Play operation.

The O201 is designed to collect data and easy to integrate into existing systems through serial communication like RS-485 or analog outputs like 0-10 V / 4-20 mA. The O201 supports Modbus, CANbus protocols and a system fault relay. The module is designed with capability to add additional application logic for customer specific applications. It is designed with the needs of Monitoring, Test platforms or Industrial Process monitoring integration needs. It has the data integration capability of multiple test platforms.  Industry standard drivers availlable for a quick and easy connect to most popular laboratories softwares. There is a dedicated team for application specific customizations for fiber optic sensors,  monitor configuration and software integration to simplify the data collection of testing and monitoring applications.  

Related Keyphrases:

O201 Fiber optic monitor combines reliability | Industrial Process monitoring integration needs | application specific customizations | Industry standard drivers availlable | fiber optic temperature monitor | friendly configuration software | customer specific applications | data integration capability | Original Equipment manufacturers | popular laboratories softwares | additional application logic | high voltage environments | conventional temperature | monitoring applications | monitor configuration

Description:

The Rugged Monitoring Tsens probes have been designed and built so they can be incorporated in your transformers to give precise results (direct measurements of temperature). The sensing technology is based on the proven zero-drift GaAs technology. They are completely built using first quality materials, all with very high dielectric strength, so your transformers can benefit from accurate temperature readings, which is essential to a good knowledge of transformer aging rate. During a factory heatrun tests these probes will give to both transformer manufacturer and operator invaluable information regarding the transformer expected MVA performance. The patented tip construction makes them extremely robust, while being very easy to install in radial spacers or in other pressboard material (such as for temperature measurements in yokes or other transformer components). The spiral-wrap cable is especially constructed to allow complete oil penetration so you can be assured that no air can be present. All materials used in the probe construction are compatible with high temperature kerosene desoprtion processes.

Related Keyphrases:

high temperature kerosene desoprtion processes | accurate temperature readings | operator invaluable information | allow complete oil penetration | temperature measurements | transformer manufacturer | high dielectric strength | transformer components | first quality materials | Monitoring Tsens probes | factory heatrun tests | direct measurements | probe construction | tip construction | GaAs technology

Description:

The Rugged Monitoring Tsens probes have been designed and built so they can be incorporated in your transformers to give precise results (direct measurements of temperature). The sensing technology is based on the proven zero-drift GaAs technology. They are completely built using first quality materials, all with very high dielectric strength, so your transformers can benefit from accurate temperature readings, which is essential to a good knowledge of transformer aging rate. During a factory heatrun tests these probes will give to both transformer manufacturer and operator invaluable information regarding the transformer expected MVA performance. The patented tip construction makes them extremely robust, while being very easy to install in radial spacers or in other pressboard material (such as for temperature measurements in yokes or other transformer components). The spiral-wrap cable is especially constructed to allow complete oil penetration so you can be assured that no air can be present. All materials used in the probe construction are compatible with high temperature kerosene desoprtion processes.

Related Keyphrases:

high temperature kerosene desoprtion processes | accurate temperature readings | operator invaluable information | allow complete oil penetration | temperature measurements | transformer manufacturer | high dielectric strength | transformer components | first quality materials | Monitoring Tsens probes | factory heatrun tests | direct measurements | probe construction | tip construction | GaAs technology

Description:

The Rugged Monitoring Tsens probes have been designed and built so they can be incorporated in your transformers to give precise results (direct measurements of temperature). The sensing technology is based on the proven zero-drift GaAs technology. They are completely built using first quality materials, all with very high dielectric strength, so your transformers can benefit from accurate temperature readings, which is essential to a good knowledge of transformer aging rate. During a factory heatrun tests these probes will give to both transformer manufacturer and operator invaluable information regarding the transformer expected MVA performance. The patented tip construction makes them extremely robust, while being very easy to install in radial spacers or in other pressboard material (such as for temperature measurements in yokes or other transformer components). The spiral-wrap cable is especially constructed to allow complete oil penetration so you can be assured that no air can be present. All materials used in the probe construction are compatible with high temperature kerosene desoprtion processes.

Related Keyphrases:

high temperature kerosene desoprtion processes | accurate temperature readings | operator invaluable information | allow complete oil penetration | temperature measurements | transformer manufacturer | high dielectric strength | transformer components | first quality materials | Monitoring Tsens probes | factory heatrun tests | direct measurements | probe construction | tip construction | GaAs technology

Description:

The Rugged Monitoring Tsens probes have been designed and built so they can be incorporated in your transformers to give precise results (direct measurements of temperature). The sensing technology is based on the proven zero-drift GaAs technology. They are completely built using first quality materials, all with very high dielectric strength, so your transformers can benefit from accurate temperature readings, which is essential to a good knowledge of transformer aging rate. During a factory heatrun tests these probes will give to both transformer manufacturer and operator invaluable information regarding the transformer expected MVA performance. The patented tip construction makes them extremely robust, while being very easy to install in radial spacers or in other pressboard material (such as for temperature measurements in yokes or other transformer components). The spiral-wrap cable is especially constructed to allow complete oil penetration so you can be assured that no air can be present. All materials used in the probe construction are compatible with high temperature kerosene desoprtion processes.

Related Keyphrases:

high temperature kerosene desoprtion processes | accurate temperature readings | operator invaluable information | allow complete oil penetration | temperature measurements | transformer manufacturer | high dielectric strength | transformer components | first quality materials | Monitoring Tsens probes | factory heatrun tests | direct measurements | probe construction | tip construction | GaAs technology

Description:

The Rugged Monitoring Tsens probes have been designed and built so they can be incorporated in your transformers to give precise results (direct measurements of temperature). The sensing technology is based on the proven zero-drift GaAs technology. They are completely built using first quality materials, all with very high dielectric strength, so your transformers can benefit from accurate temperature readings, which is essential to a good knowledge of transformer aging rate. During a factory heatrun tests these probes will give to both transformer manufacturer and operator invaluable information regarding the transformer expected MVA performance. The patented tip construction makes them extremely robust, while being very easy to install in radial spacers or in other pressboard material (such as for temperature measurements in yokes or other transformer components). The spiral-wrap cable is especially constructed to allow complete oil penetration so you can be assured that no air can be present. All materials used in the probe construction are compatible with high temperature kerosene desoprtion processes.

Related Keyphrases:

high temperature kerosene desoprtion processes | accurate temperature readings | operator invaluable information | allow complete oil penetration | temperature measurements | transformer manufacturer | high dielectric strength | transformer components | first quality materials | Monitoring Tsens probes | factory heatrun tests | direct measurements | probe construction | tip construction | GaAs technology

Description:

Why Wood drying: In the wood industry, wood is dried     


  • Remove moisture 
  • Improve structural integrity to avoid damage from shrinkage    
  • Control the color, shape    
  • Elimination of living organisms like insects and parasites.

Advantages of Microwave/RF Drying:    


  • Fast drying ( 2 days in a Kiln instead of 2 month in the back yard )
  • The most homogeneous drying process
  • Minimize danger of cracks, shape and changing the color of wood    
  • Avoiding burning the center of the beam  

Chemical free     


  • Methyl bromide (MeBr) has been widely used to decontaminate wood infected by living organisms.
  • MeBr is highly toxic and depletes the stratospheric ozone layer, the use of Microwave is non toxic and eco friendly 

Typical Costomers


  • Wood Processors
  • Wood Exporters
  • Furniture Manufacturers
  • Shipping Material Provider

Related Keyphrases:

Typical CostomersWood ProcessorsWood ExportersFurniture ManufacturersShipping Material Provider | Improve structural integrity | stratospheric ozone layer | processMinimize danger | decontaminate wood | nbsp | living organisms | wood industry | Remove moisture | Methyl bromide | decontaminate | Chemical free | stratospheric | avoid damage | homogeneous

The Rugged Monitoring O201 is a compact design, designed for reliability to operate in extreme EMI, RFI, Microwave and high voltage environments. The O201 Fiber optic monitor combines reliability and user friendly configuration software.  It is a multi-channel fiber optic temperature monitor with precision measurement for Original Equipment manufacturers. The O201 has a measuring range from -271 °C to +300 °C. The system offers complete immunity to RFI, EMI, microwave radiation, and High Voltages  making it an optimal choice  for environments where the limitations of conventional temperature sensors/ monitors impact usage in extreme conditions. The system is based on proven GaAs technology  and designed for Plug and Play operation.

The O201 is designed to collect data and easy to integrate into existing systems through serial communication like RS-485 or analog outputs like 0-10 V / 4-20 mA. The O201 supports Modbus, CANbus protocols and a system fault relay. The module is designed with capability to add additional application logic for customer specific applications. It is designed with the needs of Monitoring, Test platforms or Industrial Process monitoring integration needs. It has the data integration capability of multiple test platforms.  Industry standard drivers availlable for a quick and easy connect to most popular laboratories softwares. There is a dedicated team for application specific customizations for fiber optic sensors,  monitor configuration and software integration to simplify the data collection of testing and monitoring applications.  

Description:

The Rugged Monitoring O201 is a compact design, designed for reliability to operate in extreme EMI, RFI, Microwave and high voltage environments. The O201 Fiber optic monitor combines reliability and user friendly configuration software.  It is a multi-channel fiber optic temperature monitor with precision measurement for Original Equipment manufacturers. The O201 has a measuring range from -271 °C to +300 °C. The system offers complete immunity to RFI, EMI, microwave radiation, and High Voltages  making it an optimal choice  for environments where the limitations of conventional temperature sensors/ monitors impact usage in extreme conditions. The system is based on proven GaAs technology  and designed for Plug and Play operation.

The O201 is designed to collect data and easy to integrate into existing systems through serial communication like RS-485 or analog outputs like 0-10 V / 4-20 mA. The O201 supports Modbus, CANbus protocols and a system fault relay. The module is designed with capability to add additional application logic for customer specific applications. It is designed with the needs of Monitoring, Test platforms or Industrial Process monitoring integration needs. It has the data integration capability of multiple test platforms.  Industry standard drivers availlable for a quick and easy connect to most popular laboratories softwares. There is a dedicated team for application specific customizations for fiber optic sensors,  monitor configuration and software integration to simplify the data collection of testing and monitoring applications.  

Related Keyphrases:

O201 Fiber optic monitor combines reliability | Industrial Process monitoring integration needs | application specific customizations | Industry standard drivers availlable | fiber optic temperature monitor | friendly configuration software | customer specific applications | data integration capability | Original Equipment manufacturers | popular laboratories softwares | additional application logic | high voltage environments | conventional temperature | monitoring applications | monitor configuration

Description:

The Rugged Monitoring Tsens probes have been designed and built so they can be incorporated in your transformers to give precise results (direct measurements of temperature). The sensing technology is based on the proven zero-drift GaAs technology. They are completely built using first quality materials, all with very high dielectric strength, so your transformers can benefit from accurate temperature readings, which is essential to a good knowledge of transformer aging rate. During a factory heatrun tests these probes will give to both transformer manufacturer and operator invaluable information regarding the transformer expected MVA performance. The patented tip construction makes them extremely robust, while being very easy to install in radial spacers or in other pressboard material (such as for temperature measurements in yokes or other transformer components). The spiral-wrap cable is especially constructed to allow complete oil penetration so you can be assured that no air can be present. All materials used in the probe construction are compatible with high temperature kerosene desoprtion processes.

Related Keyphrases:

high temperature kerosene desoprtion processes | accurate temperature readings | operator invaluable information | allow complete oil penetration | temperature measurements | transformer manufacturer | high dielectric strength | transformer components | first quality materials | Monitoring Tsens probes | factory heatrun tests | direct measurements | probe construction | tip construction | GaAs technology

Thermocouples are widely used in automotive industry for temperature testing at product design and EOL (End of Line) stages and for permanent monitoring afterwards. However, with the increasing voltage levels in Emobility thermocouples possess many risks in product design and testing stages. Some of them are safety related risk and have potential to be life threatening for employees (research and test engineers).

Thermocouples are based on the principles, that a small voltage (in milli-volts) gets produced when a junction (joint) of two dissimilar metal wires is cooled or heated. The generated voltage signal is measured at the other end of the metal wires and calibrated for the temperature range. During the temperature testing the junction end is put on the test object and voltage is being measured at the other end to estimate the temperature of test object.

Now imagine if the two metal wires are put on the 1000 V Battery or Motor for temperature testing and somehow the test engineers touch the wire by mistake. Even worse how accurate will be the milli-volt signal when it passes through an environment where there is high electric and magnetic field.

Without getting into more technicality let us take a closer look on the common reasons why thermocouples have failed in Emobility testing and should be replaced with intrinsically safe sensors.

1. Safety

It is very obvious and common sensical thing to find out the safety risk of using thermocouples in Emobility testing, especially when test engineers have to adjust sensing location such as finding the right hot spot or reach to the measuring points that are not easily accessible (Inverters, Stator Windings, Battery Cooling duct). Thermocouples are subject to creating a short circuit and electrocution risks to the employees.


2. Noise

With the Emobility going towards 1000V and even higher 2500V (for commercial vehicles), thermocouples are highly susceptible to noise. The milli-volt signal requires lot of isolation under such large voltages and even then, the signal is not clear enough to measure accurate temperature.



3. Larger Size  

Thermocouples are not suitable for Emobility applications that has very tiny space for putting sensors such as Charging Points, Invertor IGBTs, Battery Inter-cell temperature measurement etc. It has been observed that thermocouples are less responsive and inaccurate (up to 20 to 30 Deg Celsius) if they are not put directly on the charging points. 


4. Non-Linearity Over The Range  

Though the thermocouples are calibrated for a certain range, they still need complex compensation algorithm to maintain linearity over the range since they are being used at harsh conditions (High electric, chemical and magnetic fields) and different test environments.



5. Longer Response Time  

Faster and accurate measurement is critical for Emobility during the performance, life cycle and abuse testing. Not only the accuracy, thermocouples are also limited by the response time requirements of Emobility applications such as detection of Thermal Runaway Issues, Charging Point Temperature, Stator Winding Temperature etc.


6. Poor Repeatability 

Thermocouples are made of two dissimilar metallic wires and susceptive to material purity which varies from batch to batch and manufacturer to manufacturer. This variation creates calibration issues resulting into non-repeatability of accurate measurements. Further the chemical composition of metal changes with time especially if they are put into chemical environment like Batteries.


Description:

Thermocouples are widely used in automotive industry for temperature testing at product design and EOL (End of Line) stages and for permanent monitoring afterwards. However, with the increasing voltage levels in Emobility thermocouples possess many risks in product design and testing stages. Some of them are safety related risk and have potential to be life threatening for employees (research and test engineers).

Thermocouples are based on the principles, that a small voltage (in milli-volts) gets produced when a junction (joint) of two dissimilar metal wires is cooled or heated. The generated voltage signal is measured at the other end of the metal wires and calibrated for the temperature range. During the temperature testing the junction end is put on the test object and voltage is being measured at the other end to estimate the temperature of test object.

Now imagine if the two metal wires are put on the 1000 V Battery or Motor for temperature testing and somehow the test engineers touch the wire by mistake. Even worse how accurate will be the milli-volt signal when it passes through an environment where there is high electric and magnetic field.

Without getting into more technicality let us take a closer look on the common reasons why thermocouples have failed in Emobility testing and should be replaced with intrinsically safe sensors.

1. Safety

It is very obvious and common sensical thing to find out the safety risk of using thermocouples in Emobility testing, especially when test engineers have to adjust sensing location such as finding the right hot spot or reach to the measuring points that are not easily accessible (Inverters, Stator Windings, Battery Cooling duct). Thermocouples are subject to creating a short circuit and electrocution risks to the employees.


2. Noise

With the Emobility going towards 1000V and even higher 2500V (for commercial vehicles), thermocouples are highly susceptible to noise. The milli-volt signal requires lot of isolation under such large voltages and even then, the signal is not clear enough to measure accurate temperature.



3. Larger Size  

Thermocouples are not suitable for Emobility applications that has very tiny space for putting sensors such as Charging Points, Invertor IGBTs, Battery Inter-cell temperature measurement etc. It has been observed that thermocouples are less responsive and inaccurate (up to 20 to 30 Deg Celsius) if they are not put directly on the charging points. 


4. Non-Linearity Over The Range  

Though the thermocouples are calibrated for a certain range, they still need complex compensation algorithm to maintain linearity over the range since they are being used at harsh conditions (High electric, chemical and magnetic fields) and different test environments.



5. Longer Response Time  

Faster and accurate measurement is critical for Emobility during the performance, life cycle and abuse testing. Not only the accuracy, thermocouples are also limited by the response time requirements of Emobility applications such as detection of Thermal Runaway Issues, Charging Point Temperature, Stator Winding Temperature etc.


6. Poor Repeatability 

Thermocouples are made of two dissimilar metallic wires and susceptive to material purity which varies from batch to batch and manufacturer to manufacturer. This variation creates calibration issues resulting into non-repeatability of accurate measurements. Further the chemical composition of metal changes with time especially if they are put into chemical environment like Batteries.


Related Keyphrases:

two dissimilar metal wires | two dissimilar metallic wires | Emobility thermocouples | permanent monitoring afterwards | generated voltage signal | temperature measurement | complex compensation algorithm | Emobility applications | Stator Winding Temperature | Charging Point Temperature | response time requirements | test engineers touch | temperature range | accurate measurements | accurate measurement

Description:

Thermocouples are widely used in automotive industry for temperature testing at product design and EOL (End of Line) stages and for permanent monitoring afterwards. However, with the increasing voltage levels in Emobility thermocouples posses many risks in product design and testing stages. Some of them are safety related risk and have potential to be life threatening for employees (research and test engineers).

Researchers and testing experts in Emobility have seen the following major challenges with using Thermocouples for temperature testing in high voltage applications.

  1. Safety: Thermocouples are subject to creating a short circuit and electrocution risks to the employees.
  2. Noise: With the Emobility going towards 1000V and even higher 2500V (for commercial vehicles), thermocouples are highly susceptible to noise.
  3. Linearity: Though the thermocouples are calibrated for a certain range, they still need complex compensation algorithm to maintain linearity over the range
  4. Response Time: Thermocouples are not fast enough and accurate for thermal profiling of key components of Electric Vehicles such as Charging Points, Battery, Motor Windings and Power Electronics.
  5. Repeatability: Thermocouples are made of two dissimilar metallic wires and susceptive to material purity which varies from batch to batch and manufacturer to manufacturer.

Related Keyphrases:

permanent monitoring afterwards | complex compensation algorithm | two dissimilar metallic wires | Emobility thermocouples | electrocution risks | commercial vehicles | automotive industry | rangeResponse Time | Electric Vehicles | major challenges | product design | material purity | voltage levels | Charging Points | key components

Description:

Why Wood drying

In the wood industry, wood is dried

• Remove moisture

• Improve structural integrity to avoid damage from shrinkage

• Control the color, shape

• Elimination of living organisms like insects and parasites.

Advantages of Microwave/RF Drying

• Fast drying ( 2 days in a Kiln instead of 2 month in the back yard ) 

• The most homogeneous drying process

• Minimize danger of cracks, shape and changing the color of wood

• Avoiding burning the center of the beam


Chemical free

• Methyl bromide (MeBr) has been widely used to decontaminate wood infected by living organisms.

• MeBr is highly toxic and depletes the stratospheric ozone layer, the use of Microwave is non toxic and eco friendly

Typical Customers

• Wood processors

• Wood Exporters

• Furniture manufacturers

• Shipping material providers

Advantages of Fiber Optics

Fiber optic monitoring in wood drying provides significant benefits to traditional methods

• Test certificates for customer specification compliance

• Fiber optic sensors are immune to RF/ Microwave

• Avoid RF waves burning the center of the beam

• Continuous Monitoring for quality control

Advantages of Fiber Optics

Fiber optic monitoring in wood drying provides significant benefits to traditional methods


• Sensors 

• Monitors

• Softwarea






Related Keyphrases:

Fiber OpticsFiber optic monitoring | customer specification compliance | Improve structural integrity | material providersAdvantages | stratospheric ozone layer | friendlyTypical Customers | quality controlAdvantages | decontaminate wood | Fiber optic sensors | Furniture manufacturers | significant benefits | Continuous Monitoring | traditional methods | bull | wood industry