The MBX11-18-F2N-0202-GG-WP is a high-performance, miniature thermoelectric cooler. The MBX11-18-F2N-0202-GG-WP is primarily used in applications to stabilize the temperature of sensitive optical components in the telecom and photonics industries. It has a maximum Qc of 1.3 Watts when ΔT = 0 and a maximum ΔT of 72.9 °C at Qc = 0.
The MBX11-15-F2N-0202-GG-W0 is a high-performance, miniature thermoelectric cooler. The MBX11-15-F2N-0202-GG-W0 is primarily used in applications to stabilize the temperature of sensitive optical components in the telecom and photonics industries. It has a maximum Qc of 1.1 Watts when ΔT = 0 and a maximum ΔT of 72.9 °C at Qc = 0.
The MBX14-09-F1N-0101-GG-W0 is a high-performance, miniature thermoelectric cooler. The MBX14-09-F1N-0101-GG-W0 is primarily used in applications to stabilize the temperature of sensitive optical components in the telecom and photonics industries. It has a maximum Qc of 0.8 Watts when ΔT = 0 and a maximum ΔT of 72.9 °C at Qc = 0.
The MBX14-08-F2N-0101-GG-W0 is a high-performance, miniature thermoelectric cooler. The MBX14-08-F2N-0101-GG-W0 is primarily used in applications to stabilize the temperature of sensitive optical components in the telecom and photonics industries. It has a maximum Qc of 0.8 Watts when ΔT = 0 and a maximum ΔT of 72.9 °C at Qc = 0.
The MBX16-06-F2N-0101-GG-W0 is a high-performance, miniature thermoelectric cooler. The MBX16-06-F2N-0101-GG-W0 is primarily used in applications to stabilize the temperature of sensitive optical components in the telecom and photonics industries. It has a maximum Qc of 0.7 Watts when ΔT = 0 and a maximum ΔT of 72.9 °C at Qc = 0.
The MBX16-06-F2N-0101-GG-W0 is a high-performance, miniature thermoelectric cooler. The MBX16-06-F2N-0101-GG-W0 is primarily used in applications to stabilize the temperature of sensitive optical components in the telecom and photonics industries. It has a maximum Qc of 0.7 Watts when ΔT = 0 and a maximum ΔT of 72.9 °C at Qc = 0.
Infrared Sensors are electronic devices that use infrared radiation to perform a variety of functions across a wide range of applications from consumer electronics to industrial automation to medical and scientific research to military and aerospace.
The ETX8-12-F1-4040-TA-W6 high temperature, high-performance thermoelectric cooler uses Laird's enhanced thermoelectric module construction preventing performance degrading copper diffusion, which is common in standard grade thermoelectric coolers operating in high temperature environments exceeding 80 °C. It has a maximum Qc of 83.8 Watts when ΔT = 0 and a maximum ΔT of 83.2 °C at Qc = 0.
The ETX8-12-F2-2525-TA-W6 high temperature, high-performance thermoelectric cooler uses Laird's enhanced thermoelectric module construction preventing performance degrading copper diffusion, which is common in standard grade thermoelectric coolers operating in high temperature environments exceeding 80 °C. It has a maximum Qc of 77.8 Watts when ΔT = 0 and a maximum ΔT of 83.2 °C at Qc = 0.
When mechanical engineers are designing systems, their goal is to create the best possible combination of components based on the needs and limitations of the application. They will run models researching and analyzing performance criteria until they find the right solution for each piece of the system.
