A portable, potable water generator for producing high-purity liquid water by condensation of dew from ambient air is described. The generator employs filtration subsystems (38) to remove particulates and aerosols from the incoming air. An enclosed heat absorber (22) cools the filtered air below its dew point and collects (25) droplets of condensate into a closed system (26). The collected liquid dew is further continually treated in a bacteriostat loop (29, 31) to destroy adventitious living organisms and to filter out undesirable and dangerous contaminants. All the subsystems are failsafe-interlocked to disable the generator immediately and prevent delivery of water if any one of them stops functioning within predetermined safe limits. Hybrid embodiments of the water generator attached to or integrated with refrigeration-type appliances such as water coolers, refrigerators, freezers, icemakers and air-conditioners are illustrated.

Portable/potable water recovery and dispensing apparatus

Solid-state thermoelectric devices can directly convert electricity into cooling or enable heat pumping through the Peltier effect. The commercialization of thermoelectric cooling technology has been built on the Bi2Te3 alloys, which have had no rival for the past six decades around room temperature. With the discovery and development of more promising materials, it is possible to reshape thermoelectric cooling technology. Here we review the current status of, and future outlook for, thermoelectric cooling materials. Thermoelectric materials can generate electricity from waste heat but can also use electricity for cooling. This Perspective discusses coefficients of performance for these systems and the state-of-the-art for materials, and suggests strategies for the discovery of improved thermoelectric materials.

Thermoelectric cooling materials.

Devices and methods for controlling and monitoring the progress and properties of multiple reactions are disclosed. The method and apparatus are especially useful for synthesizing, screening, and characterizing combinatorial libraries, but also offer significant advantages over conventional experimental reactors as well. The apparatus generally includes multiple vessels for containing reaction mixtures, and systems for controlling the stirring rate and temperature of individual reaction mixtures or groups of reaction mixtures. In addition, the apparatus may include provisions for independently controlling pressure in each vessel, and a system for injecting liquids into the vessels at a pressure different than ambient pressure. In situ monitoring of individual reaction mixtures provides feedback for process controllers, and also provides data for determining reaction rates, product yields, and various properties of the reaction products, including viscosity and molecular weight. Computer-based methods are disclosed for process monitoring and control, and for data display and analysis.

Parallel reactor with internal sensing and method of using same

An apparatus and method for carrying out and monitoring the progress and properties of multiple reactions is disclosed. The method and apparatus are especially useful for synthesizing, screening, and characterizing combinatorial libraries, but also offer significant advantages over conventional experimental reactors as well. The apparatus generally includes multiple vessels for containing reaction mixtures, and systems for controlling the stirring rate and temperature of individual reaction mixtures or groups of reaction mixtures. In addition, the apparatus may include provisions for independently controlling pressure in each vessel, and a system for injecting liquids into the vessels at a pressure different than ambient pressure. In situ monitoring of individual reaction mixtures provides feedback for process controllers, and also provides data for determining reaction rates, product yields, and various properties of the reaction products, including viscosity and molecular weight.

Parallel reactor with internal sensing

Various present invention devices enable adherence to requirements for medical items. A medical item of the present invention includes a monitoring or data recording device to monitor and/or record medical solution conditions. The device may further include indicators to indicate compliance of the medical solution with prescribed requirements (e.g., manufacturer, medical standard or regulation, etc.). The medical item may alternatively include a barcode or transponder to uniquely identify the medical item to a thermal treatment system measuring and storing conditions in a central database. The present invention further includes various thermal treatment systems that monitor medical items for prescribed requirements and display the monitored parameters to medical personnel. In addition, the present invention may place time stamp information on medical items to enable determination by medical personnel of compliance with prescribed requirements.

Medical item thermal treatment systems and method of monitoring medical items for compliance with prescribed requirements

A modular thermoelectric assembly (30) is provided to maintain the temperature within a container or enclosed structure at a desired level. The thermoelectric assembly includes a thermoelectric device (32) with a hot sink (40) and a cold sink (50). A layer of insulating material (42) is disposed between the hot sink and the cold sink. The hot sink and the insulating material are used to install the thermoelectric assembly into an appropriately sized opening extending through the exterior of the container or enclosed structure. A thermoelectric device, contained within the layer of insulating material, functions as a heat pump to transfer heat between the cold sink and the hot sink. An electrical motor (60), rotating shaft (62) and propellers (64, 66) are carried by the assembly to assist in the circulation of air to improve the efficiency of the cold sink and the hot sink.

Modular thermoelectric assembly

A thermoelectric apparatus (10) is provided that is compatible with multiple power sources (12) each providing a different voltage. The present apparatus (10) includes a thermoelectric assembly (14) having a plurality of thermoelectric devices (18 & 20) and control circuitry (16) coupled between the thermoelectric assembly (14) and a power source (12). The control circuitry (16) can sense the voltage provided by the power source (12) and electrically configure the thermoelectric devices (18 & 20) in the thermoelectric assembly (14) between parallel and serial electrical configuration in response to the sensed voltage. The control circuitry (16) also couples the thermoelectric devices (18 & 20) to the power source (12).

Thermoelectric apparatus for use with multiple power sources and method of operation

A module for controlling the temperature within an enclosed structure is provided. The module comprises a thermoelectric assembly, a platform, and a panel. The thermoelectric assembly comprises a thermoelectric device with a first heat sink disposed on one side of the device and a second heat sink disposed on the other side of the device. The thermoelectric assembly further comprises an electric motor attached to one of the heat sinks with a rotating shaft extending longitudinally through the electrical motor and both heat sinks. A propeller may be attached to each end of the rotating shaft adjacent to the first heat sink and the second heat sink respectively. The platform may be removably engaged with the enclosed structure. A first fastener may be used to attach the thermoelectric assembly to the platform. A first opening may be provided in the platform adjacent to one of the propellers. The panel preferably attaches to the platform for use in mounting and sealing the thermoelectric module within the enclosed structure.

Compact thermoelectric refrigerator and module

A thermoelectric system which operates on AC input power without requiring external rectification or conditioning is provided The thermoelectric system includes a thermoelectric device with an integrated rectifier circuit The thermoelectric device includes a thermoelectric array which may function satisfactorily with 120 volt AC, 240 volt AC or any other desired input power A control circuit is also provided to allow switching the associated rectifier circuit of the thermoelectric system from full-wave rectification to half-wave rectification The thermoelectric system may use the control circuit to maintain the temperature of either the hot plate or the cold plate associated with the thermoelectric device at a desired value

Integrated thermoelectric system with full/half wave rectifier control

Fault tolerant thermoelectric device circuit (18) is provided including a plurality of thermoelectric elements (19, 20, 21, and 22) and a plurality of secondary by-pass circuits (24, 25, 26, and 27) coupled in parallel with a number of the thermoelectric elements. The secondary by-pass circuits provide by-pass paths to failed thermoelectric elements, thereby allowing the remaining elements to continue operating. Primary by-pass circuit (30) is also provided to provide a by-pass path to all of the thermoelectric elements as required.

Michael J. Doke

Papers

Modular thermoelectric assembly

Thermoelectric apparatus for use with multiple power sources and method of operation

Compact thermoelectric refrigerator and module

Integrated thermoelectric system with full/half wave rectifier control

Fault tolerant thermoelectric device circuit