The ET20-24-F2A-0709-11-22-W2.25 high temperature Thermoelectric Cooler uses Laird's enhanced Thermoelectric Module construction preventing performance degrading copper diffusion, which is common in standard grade TEMs operating in high temperature environments exceeding 80 °C. It has a maximum Qc of 3.4 Watts when ΔT = 0 and a maximum ΔT of 77.9 °C at Qc = 0.
The ET19-35-F1N-0612-GG-W2.25 high temperature Thermoelectric Cooler uses Laird's enhanced Thermoelectric Module construction preventing performance degrading copper diffusion, which is common in standard grade TEMs operating in high temperature environments exceeding 80 °C. It has a maximum Qc of 4.7 Watts when ΔT = 0 and a maximum ΔT of 77.9 °C at Qc = 0.
The ET19-35-F1N-0612-21-EP-W2.25 high temperature Thermoelectric Cooler uses Laird's enhanced Thermoelectric Module construction preventing performance degrading copper diffusion, which is common in standard grade TEMs operating in high temperature environments exceeding 80 °C. It has a maximum Qc of 4.7 Watts when ΔT = 0 and a maximum ΔT of 77.9 °C at Qc = 0.
The ET19-35-F1N-0612-22-W2.29 high temperature Thermoelectric Cooler uses Laird's enhanced Thermoelectric Module construction preventing performance degrading copper diffusion, which is common in standard grade TEMs operating in high temperature environments exceeding 80 °C. It has a maximum Qc of 4.7 Watts when ΔT = 0 and a maximum ΔT of 77.9 °C at Qc = 0.
The ET19-35-F1N-0612-11-RT-W2.25 high temperature Thermoelectric Cooler uses Laird's enhanced Thermoelectric Module construction preventing performance degrading copper diffusion, which is common in standard grade TEMs operating in high temperature environments exceeding 80 °C. It has a maximum Qc of 4.7 Watts when ΔT = 0 and a maximum ΔT of 77.9 °C at Qc = 0.
The ET19-35-F1N-0612-11-RT-28AWG high temperature Thermoelectric Cooler uses Laird's enhanced Thermoelectric Module construction preventing performance degrading copper diffusion, which is common in standard grade TEMs operating in high temperature environments exceeding 80 °C. It has a maximum Qc of 4.7 Watts when ΔT = 0 and a maximum ΔT of 77.9 °C at Qc = 0.
The ET19-23-F1N-0608-GG-W2.25 high temperature Thermoelectric Cooler uses Laird's enhanced Thermoelectric Module construction preventing performance degrading copper diffusion, which is common in standard grade TEMs operating in high temperature environments exceeding 80 °C. It has a maximum Qc of 3.1 Watts when ΔT = 0 and a maximum ΔT of 77.9 °C at Qc = 0.
The ET12-65-F2A-1312-TB-W2.25 high temperature Thermoelectric Cooler uses Laird's enhanced Thermoelectric Module construction preventing performance degrading copper diffusion, which is common in standard grade TEMs operating in high temperature environments exceeding 80 °C. It has a maximum Qc of 5.5 Watts when ΔT = 0 and a maximum ΔT of 77.9 °C at Qc = 0.
The ET12-65-F2A-1312-GG-W2.25 high temperature Thermoelectric Cooler uses Laird's enhanced Thermoelectric Module construction preventing performance degrading copper diffusion, which is common in standard grade TEMs operating in high temperature environments exceeding 80 °C. It has a maximum Qc of 5.5 Watts when ΔT = 0 and a maximum ΔT of 77.9 °C at Qc = 0.
The Nextreme™ Recirculating Chiller is a refrigeration-based chiller designed for precise and reliable temperature control of equipment. It can be used in several user applications such as medical, analytical instrumentation, industrial and semiconductor. This family of compressor-based chillers offer different configurable options for pumps selection, coolant flow control, supply pressure monitoring and filtering. This chiller also uses a semi-closed system for low coolant maintenance.