Temperature Sensors - NTC Thermistors

Part Number	Description / PDF	Quantity
EC95F103WN Thermometrics (Amphenol Advanced Sensors)	THERMISTOR NTC 10KOHM 3969K BEAD	687
NHQM472B355T5 Thermometrics (Amphenol Advanced Sensors)	THERM NTC 4.7KOHM 3550K 0805	0
RL1005-79K-150-D1 Thermometrics (Amphenol Advanced Sensors)	THERM NTC 150KOHM 4228K DISC	0
AL03006-331.8-55-G1 Thermometrics (Amphenol Advanced Sensors)	THERMISTOR NTC 500OHM 2983K DO35	1283
TH350J39GBSN Thermometrics (Amphenol Advanced Sensors)	THERM NTC 50KOHM 3952K AXIAL	2972
RL2005-1148-103-SA Thermometrics (Amphenol Advanced Sensors)	THERMISTOR NTC 2KOHM 4073K DISC	709
EC95F502WN Thermometrics (Amphenol Advanced Sensors)	THERMISTOR NTC 5KOHM 3969K BEAD	449
AB6B2-GC16KA143E/37C Thermometrics (Amphenol Advanced Sensors)	THERMISTOR NTC 22KOHM 3500K BEAD	60
3006-1576-101-G100 Thermometrics (Amphenol Advanced Sensors)	THERMISTOR NTC 27KOHM DO213AA	0
NHQ333B400T5 Thermometrics (Amphenol Advanced Sensors)	THERMISTOR NTC 33KOHM 4000K 1206	0
RL2007-16K-140-D1 Thermometrics (Amphenol Advanced Sensors)	THERMISTOR NTC 30KOHM 4615K DISC	0
DC95G104VN Thermometrics (Amphenol Advanced Sensors)	THERM NTC 100KOHM 4252K BEAD	108
MA100GG103CN Thermometrics (Amphenol Advanced Sensors)	THERM NTC 10KOHM 3969K PROBE	0
NHQM272B410T10 Thermometrics (Amphenol Advanced Sensors)	THERM NTC 2.7KOHM 4100K 0805	0
FP07DB154N Thermometrics (Amphenol Advanced Sensors)	FP 07 FAST TIP PROBE	1
C100Y103J Thermometrics (Amphenol Advanced Sensors)	THERMISTOR NTC 10KOHM 3690K BEAD	2584
RL2004-18.4K-150-D1 Thermometrics (Amphenol Advanced Sensors)	THERMISTOR NTC 35KOHM 4720K DISC	0
MA100GG103B Thermometrics (Amphenol Advanced Sensors)	THERM NTC 10KOHM 3969K PROBE	700
03006-111.3K-123-G100 Thermometrics (Amphenol Advanced Sensors)	THERM NTC 200KOHM 4365K DO213AA	0
RL1006-98.4-59-D1 Thermometrics (Amphenol Advanced Sensors)	THERMISTOR NTC 150OHM 3096K DISC	0

Temperature Sensors - NTC Thermistors

1. Overview

NTC (Negative Temperature Coefficient) thermistors are temperature-sensitive resistors whose resistance decreases with increasing temperature. This semiconductor ceramic device utilizes metal oxide materials to achieve precise temperature measurement and control. As a fundamental component in thermal management systems, NTC thermistors play critical roles in modern electronics, automotive engineering, and industrial automation due to their high sensitivity ( : 2000-5000 K) and accuracy ( 0.1 C to 5 C).

2. Major Types and Functional Classification

Type	Functional Characteristics	Application Examples
Bead Thermistors	Small size ( 0.5-5mm), fast response (<50ms), glass-encapsulated	Medical probes, liquid temperature monitoring
Disk Thermistors	Higher power rating, epoxy-coated, axial leads	Power supply thermal protection, HVAC systems
Chip Thermistors	SMD packaging, low profile (0.6-3.2mm), RoHS compliant	Smartphone thermal management, wearable devices
Glass-Encapsulated	Hermetic seal, corrosion resistance, operating temp: -50 C to +300 C	Automotive battery monitoring, aerospace sensors

3. Structure and Composition

Typical NTC thermistor construction includes:

Semiconductive ceramic core (Mn-Ni-Co-Ox system)
Platinum alloy electrode layers (sintered or plated)
Protective epoxy/glass encapsulation (IP67 rated)
Lead wires (Cu/Ni alloy, 26-34 AWG)

Manufacturing process involves powder synthesis at 1500 C, isostatic pressing, and controlled atmosphere sintering to achieve desired R-T characteristics.

4. Key Technical Specifications

Parameter	Description	Significance
Rated Resistance (R25)	Resistance at 25 C (100 -10M range)	System compatibility, signal conditioning design
B-Value (K)	Material constant (2000-5000K)	Determines sensitivity across operating range
Tolerance	Resistance deviation ( 1% to 15%)	Affects measurement accuracy
Operating Temp Range	-100 C to +600 C (varies by type)	Environmental suitability
Dissipation Factor	mW/ C (self-heating coefficient)	Power consumption and stability considerations

5. Application Fields

Primary industries utilizing NTC thermistors:

Industrial: Process control ( 0.5 C accuracy), motor protection
Consumer Electronics: Battery management (Li-ion charging), smart thermostats
Medical: Patient monitoring (Class F accuracy), lab equipment
Automotive: Battery pack thermal monitoring (ISO 14001 compliance), ECU protection

Notable application example: Tesla Model S battery management system uses 48-channel NTC array for cell temperature monitoring ( 1 C accuracy).

6. Leading Manufacturers and Products

Manufacturer	Key Products	Technical Highlights
Murata Electronics	NXFT Series	Automotive-grade (AEC-Q200), 0.5 C accuracy, -50 C to +150 C range
TE Connectivity	NTCLE Series	Medical certification (IEC 60601), 3.2mm chip format
Vishay Beyschlag	NTCAl Series	Aluminum housing, 50W power handling, IP68 rating

7. Selection Guidelines

Key considerations for NTC thermistor selection:

Resistance-Temperature curve matching application requirements
Environmental factors: humidity (IP rating), vibration (automotive shock specs)
Electrical parameters: operating current (self-heating effects)
Form factor constraints (SMD vs through-hole)
Calibration requirements (standard vs customized R-T tables)

Recommend verifying long-term stability (aging rate <0.2%/year) and RoHS compliance for production applications.

8. Industry Trends

Emerging developments include:

Micro-NTC fabrication (MEMS-based, <0.1mm chips)
High-temperature stability improvements (up to 600 C operation)
Integration with wireless sensor networks (Zigbee/LoRa compatibility)
AI-enhanced linearization algorithms (reducing external circuit complexity)

Market growth projected at 8.2% CAGR through 2027 driven by EV battery management demands.