Temperature Sensors - RTD (Resistance Temperature Detector)

Part Number	Description / PDF	Quantity
35110013 Heraeus Nexensos USA	TEMP SENSOR RTD 100 OHM	41
NB-PTCO-160 TE Connectivity Measurement Specialties	SENSOR RTD 100OHM 0.001% 2SIP	1261
R-8205 TE Connectivity Measurement Specialties	300H N3C 10.00 3S H 180 A	5
32208180 Heraeus Nexensos USA	SENSOR RTD 100OHM 0.3% 2SIP	0
SA10160543 Delta Electronics	100/385/A 1.7X2.8 CHIP SENSOR(NI	0
34015120 TE Connectivity Measurement Specialties	SENSOR RTD 100OHM PROBE	0
NB-PTCO-012 TE Connectivity Measurement Specialties	SENSOR RTD 1KOHM 0.001% 2SIP	0
USW3483 Wickmann / Littelfuse	SENSOR RTD 1KOHM 0.06% PROBE	0
RTDW1N-100RF8 Riedon	SENSOR RTD 100 OHM 1% 6000PPM	73
TT2081 ifm Efector	TEMPERATURE SENSOR FOR CONNECTIO	0
32208392 Heraeus Nexensos USA	SENSOR RTD 100OHM 0.3% 2SIP	709
PTS120602B1K00P100 Vishay / Beyschlag	SENSOR RTD 1KOHM 1206	0
20009209-02 TE Connectivity Measurement Specialties	1000 OHM RTD, 3 WIRE, CLASS B	142
HEL-777-A-T-0 Honeywell Sensing and Productivity Solutions	SENSOR RTD 100OHM 2SIP	4
TT3291 ifm Efector	TEMPERATURE SENSOR FOR CONNECTIO	0
32208191 Heraeus Nexensos USA	SENSOR RTD 1KOHM 0.3% 2SIP	57
NB-PTCO-024 TE Connectivity Measurement Specialties	SENSOR RTD 100OHM 0.001% 2SIP	2152
SA10200542 Delta Electronics	1K/385/B 2X3 CHIP SENSOR(NI WIRE	166
32206914 Heraeus Nexensos USA	SENSOR RTD 100OHM 0.15% PROBE	0
50782200 Sensata Technologies	SENSOR RTD 500OHM CYLINDER	0

Temperature Sensors - RTD (Resistance Temperature Detector)

1. Overview

Resistance Temperature Detectors (RTDs) are temperature sensors that operate based on the principle of electrical resistance variation in metals with temperature changes. Platinum is the most commonly used material due to its stability and linear resistance-temperature relationship. RTDs provide precise and repeatable temperature measurements, making them critical in industrial process control, scientific research, and quality assurance systems.

2. Major Types and Functional Classification

Type	Functional Characteristics	Application Examples
Platinum RTD (Pt100/Pt1000)	High accuracy ( 0.1 C), wide temperature range (-200 C to 850 C)	Industrial process control, HVAC systems
Copper RTD	Lower cost, limited range (-50 C to 150 C)	Motors temperature monitoring
Nickel RTD	High sensitivity but non-linear output	Aerospace applications
Thin-Film RTD	Compact size, fast response time	Medical devices, semiconductor manufacturing
Wire-Wound RTD	High vibration resistance, mechanical durability	Power generation plants

3. Structure and Components

Typical RTD construction includes:

Sensing Element: Platinum/copper/nickel wire or thin-film deposit
Lead Wires: 2-wire (cost-effective), 3-wire (compensated), or 4-wire (high precision)
Insulation: Ceramic or glass encapsulation for electrical isolation
Protective Sheath: Stainless steel or Inconel for environmental protection
Connection Head: Terminal for wire connections and mounting

4. Key Technical Specifications

Parameter	Significance	Typical Values
Temperature Range	Determines operational limits	-200 C to 850 C (Pt100)
Accuracy Class	Defines measurement precision	Class A ( 0.15 C), Class B ( 0.3 C)
Response Time	Critical for dynamic temperature tracking	0.5-20 seconds
Electrical Resistance	Affects signal transmission quality	100 (Pt100), 1000 (Pt1000)
Self-Heating Error	Impact of excitation current on measurement	<0.02 C/mW

5. Application Fields

Industrial: Chemical reactors, boiler systems, turbine monitoring
Healthcare: MRI machine temperature regulation
Automotive: Battery management systems in EVs
Food Processing: Pasteurization temperature control
Energy: Nuclear reactor coolant monitoring

6. Leading Manufacturers and Products

Manufacturer	Representative Product	Key Features
Honeywell	TD Series	IP67 rating, -50 C to 250 C range
Omega Engineering	PX Series	Explosion-proof design, Class A accuracy
Yokogawa	YTA Series	HART protocol support, 4-wire configuration
ABB	MT Series	Digital signal processing, SIL2 compliance

7. Selection Guidelines

Key considerations:

Temperature range requirements
Accuracy vs. cost trade-offs
Environmental factors (vibration, corrosion)
Installation constraints (space, mounting type)
Signal transmission distance (wire resistance impact)

Industry Trends

Emerging developments include:

Miniaturization for embedded applications
Wireless RTD sensors for IoT integration
Advanced materials (ceramic matrix composites)
AI-based self-calibration features
Increased adoption in renewable energy systems