The CP10-127-06-L1-W4.5 is a high-performance and highly reliable standard Thermoelectric Module (TEM). Assembled with Bismuth Telluride semiconductor material and thermally conductive Aluminum Oxide ceramics. It has a maximum Qc of 27.1 Watts when ΔT = 0 and a maximum ΔT of 67 °C at Qc = 0 measured at a Th = 27 °C.
The CP14-71-06-L1-W4.5 is a high-performance and highly reliable standard Thermoelectric Module (TEM). Assembled with Bismuth Telluride semiconductor material and thermally conductive Aluminum Oxide ceramics. It has a maximum Qc of 29.3 Watts when ΔT = 0 and a maximum ΔT of 67 °C at Qc = 0 measured at a Th = 27 °C.
The CP2-31-06-L1-W4.5 is a high-performance and highly reliable standard Thermoelectric Module (TEM). Assembled with Bismuth Telluride semiconductor material and thermally conductive Aluminum Oxide ceramics. It has a maximum Qc of 30.6 Watts when ΔT = 0 and a maximum ΔT of 67 °C at Qc = 0 measured at a Th = 27 °C.
The CP10-127-05-L1-W4.5 is a high-performance and highly reliable standard Thermoelectric Module (TEM). Assembled with Bismuth Telluride semiconductor material and thermally conductive Aluminum Oxide ceramics. It has a maximum Qc of 35.1 Watts when ΔT = 0 and a maximum ΔT of 67 °C at Qc = 0 measured at a Th = 27 °C.
The CP14-7-10-L1-W4.5 is a high-performance and highly reliable standard Thermoelectric Module (TEM). Assembled with Bismuth Telluride semiconductor material and thermally conductive Aluminum Oxide ceramics. It has a maximum Qc of 1.9 Watts when ΔT = 0 and a maximum ΔT of 67 °C at Qc = 0 measured at a Th = 27 °C.
The CP08-31-06-L1-W4.5 is a high-performance and highly reliable standard Thermoelectric Module (TEM). Assembled with Bismuth Telluride semiconductor material and thermally conductive Aluminum Oxide ceramics. It has a maximum Qc of 4.6 Watts when ΔT = 0 and a maximum ΔT of 67 °C at Qc = 0 measured at a Th = 27 °C.
The CP14-17-10-L1-W4.5 is a high-performance and highly reliable standard Thermoelectric Module (TEM). Assembled with Bismuth Telluride semiconductor material and thermally conductive Aluminum Oxide ceramics. It has a maximum Qc of 4.6 Watts when ΔT = 0 and a maximum ΔT of 67 °C at Qc = 0 measured at a Th = 27 °C.
Laird Thermal Systems designs and manufactures thermoelectric coolers which adhere to strict process control standards and pass/fail criteria, assuring our customers receive the best possible modules. Our extensive standard product portfolio covers a wide range of cooling capacities, temperature differentials, input power requirements and geometric footprints. Standard finishing options are available to accommodate alternate lead lengths, lapping thickness tolerances, and moisture protective sealants.
It combines cutting, ablation, and coagulation properties for precise, virtually bloodless procedures; minimizing thermal damage to the surrounding tissue and shortening recovery time. The heat of the laser also destroys any microbiological bodies that could lead to infection. Laser systems also generate waste heat, and require sophisticated cooling systems to remove this heat and keep the laser stable and operating at peak performance during operation. Due to size constraints, power consumption requirements, and noise restrictions thermal management can be challenging.
Temperature stability is vital in medical/clinical diagnostic equipment such as reagent and centrifuge equipment. Even small fluctuations in the operating temperature of these machines can significantly affect the test results. In addition, small portable medical diagnostic machines are growing in popularity for point of care (POC) and lab on chip (LOC) testing devices. These machines require cooling solutions with a compact form factor and low weight.
