Temperature Sensors for the Plastics, Rubber and Packaging Industries

Southeast Thermal Systems offers high quality sensors for the plastics, packaging and rubber industries provide an economical means of temperature sensing and are available in several standard thermocouple and RTD configurations. Sensor styles shown in this section represent some of the standard constructions available. We have several other styles, sheath sizes and materials, lead wire types, and thread sizes available. We also manufacture retrofit sensors for European equipment and offer a complete selection of metric sheath sizes and thread types. Contact our Technical Assistance Team for aid in selecting a sensor for your specific requirement.

All sheaths and tips are constructed from 316 stainless steel for superior resistance to corrosion, abrasion and deterioration. All sensor junctions are GTAW (TIG) or plasma welded. Brazing or silver soldering of sensor junction is not utilized due to the potential for flux contamination or deterioration.

TECHNICAL INFORMATION

BUILD SHEET FOR PLASTICS & RUBBER TCs

CONSTRUCTION TYPES

Mineral Insulated (MGO) Sensors

Temperature Transmitters

Resistance Temperature Detectors

Industrial Thermocouples

Thermowells

Custom Designed sensor

Plastics & Packaging

Food, Dairy, & Pharma

Calculators

Power Flow Rate Temp Calculator

Calculate the electrical power, flow rate or temperature requirement.

airflow in standard cubic feet per minute

SCFM

temperature rise in degrees F from the inlet to the exhaust

ΔT

Watts = SCFM x ΔT/2.5

Watts

Temperature Conversion Calculator

Calculate the electrical power, flow rate or temperature requirement.

°F = ((( °C * 9) / 5 ) + 32)

°F

°C = ((( °F - 32) * 5 ) / 9)

°C

Three-Phase Unit Calculator

Fill in two values to find the 3rd.

W = LC * (V * √2)

Watts

V = (W / LC) / √2

Voltage

LC = W / (V * √2)

Line Current

Single Phase Unit Calculator

Fill in two values to find the 3rd.

W = LC * V

Wattage

V = LC * W

Voltage

LC = W / V

Line Current

Ohms Law Calculator

Fill in two values to find the other two.

O = V / A

O = V² / W

O = W / A²

Ohms

V = A * O = A * (V/A)

V = √(W * O)

V = W / A

Volts

A = V / O

A = W/ V

A = √(W / O)

Amps

W = A * V

W = V² / O

W = A² * O

Watts

Heat Transfer Through Convection Calculator

ρ = density (lb/ft3)

V = volume flow rate (ft3/hour)

Cp = specific heat (Btu/lb°F)

Ta-Tb = temperature differential (°F)

Q = ρ x V x Cp x (Ta-Tb)

Fill in four values

ρ = density (lb/ft3)

V = volume flow rate (ft3/hour)

Cp = specific heat (Btu/lb°F)

Ta-Tb = TD (°F)

Ta-Tb

Q = ρ x V x Cp x (Ta-Tb)

ACFM to SCFM

ACFM = airflow in actual cubic feet per minute

P = gage pressure (psi)

T = gas temperature °R = 460 + °F

SCFM = airflow in standard cubic feet per minute

Find Standard Cubic Feet per Minute based on data from your Actual Cubic Feet per Minute Rotameter

airflow in actual cubic feet per minute

ACFM

gage pressure (psi)

gas temperature °R = 460 + °F

T (°R)

airflow in standard cubic feet per minute

SCFM

Standard Flow Rate (SCFM) Calculator

Calculate the SCFM.

Actual cubic feet per minute

CFM

Actual pounds per square inch at Gauge

PSI

Actual temperature in °F. °R = 460 + °F

CFM * (PSI actual / 14.7psi)*(528°R / T actual)

SCFM

Pressure Conversion

Fill in one value to calculate the other.

PSI = Bar * 14.504

PSI

Bar = PSI / 14.504

Bar

Mass Flow to volume Metric Flow

Fill in one value to calculate the other two

kg/h = Kilogram Per Hour (lb/min multiply by 27.216)

kg/h

Lbs/min = Pounds per minute (kg/h divide by 27.216)

lbs/min

SCFM = Standard cubic feet per minute

SCFM