초록 ▼

In a thermoacoustic refrigerator, operating temperatures, ambient temperature, and selected user input are utilized to control frequency and/or input power in order to optimize the efficiency of the thermoacoustic refrigerator operation. In a thermoacoustic heat engine, operating temperatures, ambie

In a thermoacoustic refrigerator, operating temperatures, ambient temperature, and selected user input are utilized to control frequency and/or input power in order to optimize the efficiency of the thermoacoustic refrigerator operation. In a thermoacoustic heat engine, operating temperatures, ambient temperature, and selected user input are utilized to control impedance of a load to optimize the efficiency of the thermoacoustic heat engine operation.

대표청구항 ▼

1. A thermoacoustic apparatus, comprising: a sealed body having a hollow region therein containing a working gas;a regenerator disposed within said body;a first heat exchanger, configured for operating at a first temperature, disposed within said body and proximate said regenerator at a first longit

1. A thermoacoustic apparatus, comprising: a sealed body having a hollow region therein containing a working gas;a regenerator disposed within said body;a first heat exchanger, configured for operating at a first temperature, disposed within said body and proximate said regenerator at a first longitudinal end of said body;a second heat exchanger, configured for operating at a second temperature that is lower than said first temperature, disposed within said body and proximate said regenerator at a second longitudinal end of said body;an electromechanical driver disposed within said body proximate said first heat exchanger such that acoustic energy from said electromechanical driver is directed into said body;a temperature sensor for measuring the temperature of said thermoacoustic apparatus, outside of said thermoacoustic apparatus and in an area in which said thermoacoustic apparatus operates, and outside of a load connected to said second heat exchanger, and providing an ambient temperature data signal based on said measured temperature;a body temperature sensor for measuring temperature within said body proximate, but spaced apart from, at least one of said first or said second heat exchangers and providing a body temperature data signal;a controller, communicatively connected to said temperature sensor and said body temperature sensor for determining and providing a control signal based on said ambient temperature data signal and said body temperature data signal, said controller generating said control signal at least in part from a plurality of said ambient temperature data signals and said body temperature data signals taken at various times during operation of the thermoacoustic apparatus; anda variable frequency driver communicatively coupled to said electromechanical driver and said controller, for receiving a control signal from said controller, and at least in part as a function of said control signal providing a variable drive signal to said electromechanical driver to thereby provide a selected optimized efficiency of operation for said thermoacoustic apparatus. 2. The thermoacoustic apparatus of claim 1, further comprising: a first heat exchanger temperature sensor for measuring the temperature of a fluid disposed within said first heat exchanger during operation of said thermoacoustic apparatus and providing a first heat exchanger temperature data signal; anda second heat exchanger temperature sensor for measuring the temperature of a fluid disposed within said second heat exchanger during operation of said thermoacoustic apparatus and providing a second heat exchanger temperature data signal;said controller further communicatively connected to said first heat exchanger temperature sensor and said second heat exchanger temperature sensor, and wherein said control signal is further determined based on said first and second heat exchanger temperature data signals. 3. The thermoacoustic apparatus of claim 2, wherein said controller is configured to receive user data, and wherein said control signal is further determined based on said user data. 4. The thermoacoustic apparatus of claim 3, wherein said controller comprises memory containing a look-up table in which body temperatures, ambient temperatures, and user data are matched to frequency and drive current, and wherein at a point in time during operation of said thermoacoustic apparatus said control signal includes frequency and drive current values from said table based on corresponding body temperature, ambient temperature, and user data at that point in time. 5. The thermoacoustic apparatus of claim 4, wherein said memory of said controller is reprogrammable. 6. A method of operating a thermoacoustic apparatus of a type which includes a body containing a variable frequency electromechanical driver, a controller, a first heat exchanger configured to operate at a first temperature and a second heat exchanger configured to operate at a second temperature that is lower than said first temperature, and a regenerator, comprising: determining ambient temperature data of said thermoacoustic apparatus outside of said thermoacoustic apparatus and in an area in which said thermoacoustic apparatus operates, and outside of a load connected to said second heat exchanger during operation of said thermoacoustic apparatus, and providing said ambient temperature data to said controller;determining body temperature data within said body proximate, but spaced apart from, at least one of said first or said second heat exchangers and providing said body temperature data to said controller;generating, at said controller, a control signal based on at least said ambient temperature data and said body temperature data taken at various times during operation of the thermoacoustic apparatus, and providing said control signal to a variable frequency driver; andoperating said variable frequency driver so as to control the frequency and amplitude of said electromechanical driver based on said control signal such that operation of said electromechanical driver thereby provides a selected optimized efficiency of operation for said thermoacoustic apparatus.