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Intrinsically Safe Thermocouple

Type: XI-TTP-BTW

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Specify the various parameters of the product for enquiry
Product's properties:
Thermocouple type
Multiplicity
Sheath material
Sheath diameter d [mm]
Tolerance class
Junction type
Sheath length L [mm]
Add to your enquiry

ATEX Designation:

I M1 Ex ia I Ma
II 1/2G Ex ia IIC T.. Ga
II 1/2D Ex ia IIIC T.. Da

 

IECEx Designation:

I M1 Ex ia I Ma
Ex ia IIC T.. Ga
Ex ia IIIC T.. Da

 

EAC Ex Designation:

PO Ex ia I Ma X
0Ex ia IIC T..Ga X
0Ex ia IIIC T..Da X

Certificate:

FTZU 10 ATEX 0062X

 

 

 

 

IECEx FTZU 16.0015X

 

 

 

 

RU C-PL.MЮ62.B.04104

 

Application

 

  • Measuring range: -40 .. +1200°C
  • General machinery and equipment design
  • Measuring temperature of liquids, gases and solid bodies
  • All branches of industry
  • Installation in hazardous areas:
    Gases, vapors, mists (G): Zone 0, 1, 2
    Dusts (D): Zone 20, 21, 22
    Mines: M1

 

Features

 

  • Mineral insulated thermocouple sensor serie XI-TTP-BTW with miniature size plug
  • Made of flexible mineral insulated cable
  • Sheath material: stainless steel or Ni-alloy
  • Small diameters from Ø0.5 mm
  • Quick response time
  • Bending of sensor possible
  • Vibration resistant

 

Multiplicity

 

Possible combinations:

 

TC Sheath diameter d [mm]
Ø0.5 Ø1.0 Ø1.5 Ø2.0 Ø3.0
1 x TC
(single)

2 x TC
(double)


 

 

 

Description

 

Mineral insulated thermocouples, also referred to as sheathed thermocouples, are made of metal sheathed cable with internal thermocouple wires are insulated from each other and from the outer sheath with magnesium oxide (MgO) powder. This provides the sensor with high vibration resistance, flexibility as well as resistance to temperature and with good electrical insulation.

 

These sensors are designed for direct temperature measuring in places with difficult access, as well as in all places, where it is required to use flexible sensors of small diameters, high resistance to vibrations and shock, and with short response time to temperature changes.

 

Due to tight pressing of the insulating layer (MgO) and appropriate structure of the inner wires and the sheath, the sensors can be bent with a minimal radius of curvature of three times the outer diameter of the sheath.

  • Description
  • ATEX Designation:

    I M1 Ex ia I Ma
    II 1/2G Ex ia IIC T.. Ga
    II 1/2D Ex ia IIIC T.. Da

     

    IECEx Designation:

    I M1 Ex ia I Ma
    Ex ia IIC T.. Ga
    Ex ia IIIC T.. Da

     

    EAC Ex Designation:

    PO Ex ia I Ma X
    0Ex ia IIC T..Ga X
    0Ex ia IIIC T..Da X

    Certificate:

    FTZU 10 ATEX 0062X

     

     

     

     

    IECEx FTZU 16.0015X

     

     

     

     

    RU C-PL.MЮ62.B.04104

     

    Application

     

    • Measuring range: -40 .. +1200°C
    • General machinery and equipment design
    • Measuring temperature of liquids, gases and solid bodies
    • All branches of industry
    • Installation in hazardous areas:
      Gases, vapors, mists (G): Zone 0, 1, 2
      Dusts (D): Zone 20, 21, 22
      Mines: M1

     

    Features

     

    • Mineral insulated thermocouple sensor serie XI-TTP-BTW with miniature size plug
    • Made of flexible mineral insulated cable
    • Sheath material: stainless steel or Ni-alloy
    • Small diameters from Ø0.5 mm
    • Quick response time
    • Bending of sensor possible
    • Vibration resistant

     

    Multiplicity

     

    Possible combinations:

     

    TC Sheath diameter d [mm]
    Ø0.5 Ø1.0 Ø1.5 Ø2.0 Ø3.0
    1 x TC
    (single)

    2 x TC
    (double)


     

     

     

    Description

     

    Mineral insulated thermocouples, also referred to as sheathed thermocouples, are made of metal sheathed cable with internal thermocouple wires are insulated from each other and from the outer sheath with magnesium oxide (MgO) powder. This provides the sensor with high vibration resistance, flexibility as well as resistance to temperature and with good electrical insulation.

     

    These sensors are designed for direct temperature measuring in places with difficult access, as well as in all places, where it is required to use flexible sensors of small diameters, high resistance to vibrations and shock, and with short response time to temperature changes.

     

    Due to tight pressing of the insulating layer (MgO) and appropriate structure of the inner wires and the sheath, the sensors can be bent with a minimal radius of curvature of three times the outer diameter of the sheath.

  • Documents
Kalkulator
Unit converter

RTDs and TCs
characteristic calculator

Resistance thermometers

Thermocouples

Cold Junction Compensation = °C

Calculate value of resistance to temperature
(values according to ITS-90 scale)

R = Ω  T = 0 °C

Calculate value of temperature to resistance
(values according to ITS-90 scale)

T = °C R = 0 Ω

Limit values for the calculator

-200 °C - 850 °C

18,52 Ω - 390,48 Ω

Cold Junction Compensation = °C

Calculate value of resistance to temperature
(values according to ITS-90 scale)

R = Ω  T = 0 °C

Calculate value of temperature to resistance
(values according to ITS-90 scale)

T = °C R = 0 Ω

Limit values for the calculator

-60 °C - 250 °C

69,52 Ω - 289,16 Ω

Cold Junction Compensation = °C

Calculate value of thermoelectric emf to temperature

E = mV T = 0 °C

Calculate value of temperature to thermoelectric emf

T = °C  E = 0 mV

Limit values for the calculator

-210 °C - 1200 °C

-8,095 mV - 69,553 mV

Cold Junction Compensation = °C

Calculate value of thermoelectric emf to temperature

E = mV T = 0 °C

Calculate value of temperature to thermoelectric emf

T = °C  E = 0 mV

Limit values for the calculator

-270 °C - 1372 °C

-6,458 mV - 54,886 mV

Cold Junction Compensation = °C

Calculate value of thermoelectric emf to temperature

E = mV T = 0 °C

Calculate value of temperature to thermoelectric emf

T = °C  E = 0 mV

Limit values for the calculator

-270 °C - 1300 °C

-4,345 mV - 47,513 mV

Cold Junction Compensation = °C

Calculate value of thermoelectric emf to temperature

E = mV T = 0 °C

Calculate value of temperature to thermoelectric emf

T = °C  E = 0 mV

Limit values for the calculator

-270 °C - 1000 °C

-9,835 mV - 76,373 mV

Cold Junction Compensation = °C

Calculate value of thermoelectric emf to temperature

E = mV T = 0 °C

Calculate value of temperature to thermoelectric emf

T = °C  E = 0 mV

Limit values for the calculator

-270 °C - 400 °C

-6,258 mV - 20,872 mV

Cold Junction Compensation = °C

Calculate value of thermoelectric emf to temperature

E = mV T = 0 °C

Calculate value of temperature to thermoelectric emf

T = °C  E = 0 mV

Limit values for the calculator

-50 °C - 1768.1 °C

-0,226 mV - 21,103 mV

Cold Junction Compensation = °C

Calculate value of thermoelectric emf to temperature

E = mV T = 0 °C

Calculate value of temperature to thermoelectric emf

T = °C  E = 0 mV

Limit values for the calculator

-50 °C - 1768.1 °C

-0,236 mV - 18,694 mV

Cold Junction Compensation = °C

Calculate value of thermoelectric emf to temperature

E = mV T = 0 °C

Calculate value of temperature to thermoelectric emf

T = °C  E = 0 mV

Limit values for the calculator

0°C - 1820 °C

-0,003 mV - 13,820 mV

Pomoc. Instrukcja użytkownika.

Unit
converter
RTDs and TCs
characteristic calculator