A high efficiency, low noise thermoelectric dehumidifier that includes a heat pipe array, a condensing heat sink, an air intake duct, and a thermoelectric cooler. A first air flow is directed over the condensing heat sink that is cooled by the thermoelectric cool such that the first air flow is dehumidified by the cooled condensing heat sink. Heat is removed from a hot side of the thermoelectric cooler via the heat pipe array. A second air flow is directed over the heat pipe array such that the heat extracted from the hot side of the thermoelectric cooler is extracted and circulated back into the ambient environment.

Certain disclosed embodiments pertain to controlling temperature in a passenger compartment of a vehicle. For example, a temperature control system (TCS) can include an air channel configured to deliver airflow to the passenger compartment of the vehicle. The TCS can include a one thermal energy source and a heat transfer device connected to the air channel. A first fluid circuit can circulate coolant to the thermal energy source and a thermoelectric device (TED). A second fluid circuit can circulate coolant to the TED and the heat transfer device. A bypass circuit can connect the thermal energy source to the heat transfer device. An actuator can cause coolant to circulate selectively in either the bypass circuit or the first fluid circuit and the second fluid circuit. A control device can operate the actuator when it is determined that the thermal energy source is ready to provide heat to the airflow.

An apparatus for water purifying and dehumidifying with an air purifying system purifies air and purifies condensate water produced by dehumidification such that the condensate water can be used as drinkable water, as a single product, whereby various functions are given to one product. Accordingly, there is an effect that the manufacturing cost of the product is reduced and expenses by customers are decreased, whereby it is possible to improve competitiveness of the product in terms of practical use.

A system for thermally conditioning and moving a fluid includes a thermoelectric device to convert electrical energy into thermal energy and produce a temperature change in response to an electrical current being applied thereto. The thermoelectric device can include a main-side and a waste side. A fluid moving device can produce a fluid flow that is in thermal communication with the thermoelectric device so that the thermal energy generated by the thermoelectric device is transferred to or from the fluid flow. A flow control valve selectively can direct the fluid flow along a main-side fluid flow path and/or a waste side fluid flow path.

A thermo-electric heating assembly for forced air, residential and commercial heating, ventilation and air conditioning (HVAC) systems includes a housing, a controller and a plurality of carbon nanotube (CNT) heating elements, arranged in the housing. The controller is adapted to respond to a signal received by the controller indicating a need for heat by powering the carbon nanotube (CNT) heating elements at a controlled electrical power level for a controlled period, commensurate with the indicated need for heat. The CNT heating elements include upper and lower metallic radiator, at least two composite containment vessel and at least two 3D CNT graphene films. The CNT heating elements preferably include a third composite containment vessel and a layer of MgSO.sub.4 or MgO.

Various examples are provided for a modular thermoelectric apparatus. In one example, a modular thermoelectric apparatus with a thermoelectric module is removable from a lid of a thermoelectric portable cooler. In another example, a modular thermoelectric apparatus includes a housing and a thermoelectric module disposed within the housing. The housing is coupled to a lower fan shroud with a warm air inlet and a cold air outlet. The housing is adapted to be removably coupled to a lid or a sidewall of a portable cooler.

Disclosed are a cooling device and a vehicle including the same. The cooling device according to one aspect of the present disclosure includes a housing part having a first hole formed at one side thereof and a second hole formed at the other side thereof, a heat exchange part accommodated in an internal space of the housing part and having one side communicating with the first hole and the other side communicating with the second hole, a thermoelectric element part provided above the heat exchange part, and a radiational cooling part provided above the thermoelectric element part and at least partially exposed to the outside.

A thermo-electric cooler pump system includes a liquid pump. The liquid pump comprises an integrated chiller and a heater. The thermo-electric cooler pump system includes a case component. The case component seals a liquid with the thermo-electric cooler pump system so that the liquid does not enter the thermo-electric cooler pump system except by an inlet port and escape the thermo-electric cooler pump system except by an exit port. The system includes a motor component. The motor component is situated outside of the case component. The motor component is not wetted by the liquid. The shaft of the motor component enters the case through a sealed hole. The system includes an impeller component. The impeller component is contained within the case component, wherein the impeller is wetted by the liquid. The impeller component is attached to the shaft such that the motion of motor component is transferred to the impeller component causing it to move. The motion of impeller component causes the liquid to enter the inlet port and flow toward the exit port. The system includes a chiller/heater component.

A humidor heat exchanger system and method for using thereof to control temperature and relative humidity are disclosed. The humidor heat exchanger system comprises two or more processors coupled to one or more memories, one or more communication interfaces, one or more thermoelectric modules, one or more compressors, one or more heaters, two or more LEDs, one or more fans, one or more sensors, one or more displays, one or more water collectors, one or more doors, one or more water reservoirs, and one or more evaporators. The two or more processors are communicatively connected to the one or more thermoelectric modules, one or more compressors, one or more heaters, two or more LEDs, one or more fans, one or more sensors, one or more displays, one or more water collectors, one or more doors, and one or more water reservoirs, and one or more evaporators. The two or more processors of the humidor heat exchanger system are configured to control temperature and relative humidity of a humidor by: detecting temperature in the one or more thermoelectric modules; detecting temperature in the one or more evaporators; checking temperature difference between the one or more thermoelectric modules and the one or more evaporators; calculating average temperature value in the one or more thermoelectric modules as to not force the one or more compressors to operate outside a safety region and not be powered on before the necessary period of time to balance cooling circuit pressure; activating the one or more compressors depending on the temperature difference between the one or more thermoelectric modules and the one or more evaporators; dynamically adjusting temperature control parameters as a function of adjusted temperature variation conditions; initiating relative humidity control; checking output of the one or more thermoelectric modules; adjusting power output of the one or more thermoelectric modules to attain desired relative humidity value; and stabilizing relative humidity exactly to the value adjustment made without oscillating about 1%.

An improved locker seat includes a pair of spaced-apart upstanding sidewalls having a pair of lateral edges. A generally horizontal seat is disposed between the lateral edges of the sidewalls. In a first mode, an air source is connected to an airway formed within the seat to create an airflow. The airflow from the air source creates a first temperature differential to cool the seat. In a second mode, an external or internal heat source provides heat to a top surface of the seat, creating a second temperature differential to heat the seat. The first and second temperature differential are distributed across the top surface of the seat. The seat is hinged to be movable about the hinge between an open and a closed position.