| Image | Part Number | Description / PDF | Quantity | Rfq |
|---|---|---|---|---|
 |
Cantherm |
THERMOSTAT 135DEG C SPST-NC RAD |
340 |
|
 |
Cantherm |
THERMOSTAT 70DEG C SPST-NC RAD |
0 |
|
 |
Cantherm |
THERMOSTAT 100DEG C SPST-NC WIRE |
1408 |
|
 |
Cantherm |
THERMOSTAT 130DEG C SPST-NC CYL |
532 |
|
 |
Cantherm |
THERMOSTAT 100DEG C SPST-NC 2SIP |
0 |
|
 |
Cantherm |
THERMOSTAT 160DEG C SPST-NO WIRE |
0 |
|
 |
Cantherm |
THERMOSTAT 100DEG C SPST-NO RAD |
0 |
|
 |
Cantherm |
THERMOSTAT 140DEG C SPST-NC WIRE |
222 |
|
 |
Cantherm |
THERMOSTAT 125DEG C SPST-NO 2SIP |
0 |
|
 |
Cantherm |
THERMOSTAT 95DEG C SPST-NO WIRE |
151 |
|
 |
Cantherm |
THERMOSTAT 40DEG C SPST-NC CYL |
392 |
|
 |
Cantherm |
THERMOSTAT 145DEG C SPST-NC 2SIP |
0 |
|
 |
Cantherm |
THERMOSTAT 70DEG C SPST-NO WIRE |
128 |
|
 |
Cantherm |
THERMOSTAT 145DEG C SPST-NO RAD |
0 |
|
 |
Cantherm |
THERMOSTAT 80DEG C SPST-NO CYL |
129 |
|
 |
Cantherm |
THERMOSTAT 20DEG C SPST-NC CYL |
0 |
|
 |
Cantherm |
THERMOSTAT 80DEG C SPST-NC CYL |
0 |
|
 |
Cantherm |
THERMOSTAT 0DEG C SPST-NC RECT |
23 |
|
 |
Cantherm |
THERMOSTAT 145DEG C SPST-NC 2SIP |
0 |
|
 |
Cantherm |
THERMOSTAT 50DEG C SPST-NC CYL |
417 |
|
Mechanical temperature sensors and thermostats are electromechanical devices that detect temperature changes through physical deformation or phase-state variations. They convert thermal energy into mechanical displacement to trigger switching actions. These components remain critical in temperature regulation systems where reliability, cost-effectiveness, and simplicity are prioritized over digital precision. Their importance persists in industrial, automotive, and household applications despite advancements in electronic sensors.
| Type | Functional Characteristics | Application Examples |
|---|---|---|
| Bimetallic Strip | Uses differential expansion of two metal alloys to bend at specific temperatures | HVAC systems, electric kettles, space heaters |
| Gas/Vapor-Pressure | Operates via pressure changes in sealed gas-filled capsules | Refrigeration systems, industrial ovens |
| Fluid Expansion | Relies on liquid/wax volume changes to actuate mechanical switches | Automotive engines, radiator systems |
| Mercury Bulb | Uses mercury's conductivity and thermal expansion for precise switching | Medical equipment, laboratory incubators |
Typical construction includes: - Sensing Element: Bimetallic strip, liquid-filled bulb, or gas capsule - Actuation Mechanism: Spring-loaded contacts or mercury tilt switches - Adjustment System: Calibrated springs or set-point knobs - Enclosure: Metal/aluminum housing for thermal conductivity - Electrical Contacts: Silver-nickel or gold-plated terminals
| Parameter | Description | Importance |
|---|---|---|
| Temperature Range | Operating limits (-50 C to 300 C typical) | Determines application suitability |
| Accuracy | 2 C to 10 C depending on design | Process control reliability |
| Response Time | 5-60 seconds | System reaction speed |
| Switching Current | 1-15A ratings | Load compatibility |
| Environmental Rating | IP54 to IP67 protection | Operational durability |
Case Example: Automotive engines use wax pellet thermostats to regulate coolant flow, maintaining optimal operating temperatures between 90-105 C.
| Manufacturer | Key Products | Special Features |
|---|---|---|
| Honeywell | T6000 series | Adjustable hysteresis, IP65 rating |
| OMRON | E5CC Temperature Controller | Digital display with mechanical backup |
| TE Connectivity | MA320-12 | High-vibration resistance design |
| Danfoss | KPI 316E | Food processing compliant materials |
Key considerations:
Current developments include: - Hybrid systems integrating mechanical sensors with digital interfaces - Miniaturization for portable device integration - Enhanced materials for extreme temperature applications - Wireless-enabled mechanical-electronic combined systems - Improved hysteresis control for energy-efficient systems
Market projections indicate sustained demand in industrial sectors, with a 3.2% CAGR expected through 2030 despite increasing digital competition.