WO2012165990A4 - Cooling electric energy generator - Google Patents

Abstract

Cooling electric energy generator absorbs thermal energy from environment by cooling thermal-collector (4) and accumulates it in thermal-accumulative core (1) by internal heat-pump device (8) which is initially started by accu-battery (10). Temperature difference between thermal-accumulative core (1) and cooling thermal-collector (4) generates DC electric voltage in thermoelements couples set (3), by Seebeck effect. Electric energy from thermoelements couples set (3) overtakes further supply internal heat-pump device (8) so that absorption thermal energy from environment is continuous. Surplus of previously absorbed thermal energy thermoelements couples set (3) in the form of electric energy spends for recharging accu-battery (10) and for supply electric energy consumer (14). Cooling electric energy generator solves the problem of unnecessary heating material and spending various kind of fuel for producing great quantities of electric energy.

Claims

AMENDED CLAIMS received by the International Bureau on 14 December 2012 (14.12.2012)

1. Cooling electric energy generator, characterized in that, on the extensions (19) within a housing is supported thermal collector (4) which in its flanged layer has displaced conduits with cooled fluid (6), whilst in the center has positioned thermoaccumulative core (1) in which central cavity is settled temperature sensor (7) surrounded by conduits with heated fluid (2) of internal heat-pump device (8), and where between internal perimeter of thermal col lector (4) and outer perimeter of thermoaccumulative core (1) is positioned thermoelectric couple set (3) consisting of single thermoelements (5) which are insulated by electroinsulative, thermally non- conductive material (15), and where thermoelectric couple set (3) is Seebeck's effect generator, which is by insulated conductors (12) connected to programmed switcher (11), to which are connected internal heat-pump device (8) connected through adapter (9) of power supply and accu-battery (10) whilst to the output connections of programmed switcher (11) is connected the connector (13) of the load (14) which is consumer of electric energy.

2. Cooling electric energy generator, according to claim 1 , in the variant as cooling electric energy generator with internal heat-pump device (8) of fluid type, characterized in that, cooled fluid

(6) of internal heat-pump device (8) environmental thermal energy absorbed through thermal collector (4) through heated fluid (2) deliver to thermoaccumulative core (1) so that obtained necessary temperature difference between thermoaccumulative core (1) and thermal collector (4) through thermoelectric couple set (3), by Seebeck's effect, generate electric voltage in insulated electric conductors (12) are connected to programmed switcher (11) which through adapter (9) of power supply drives internal heat-pump device (8).

3. Cooling electric energy generator, according to claim 1 , in the variant as cooling electric energy generator with internal heat-pump device (8) of Peltier's type, characterized in that, on the extensions (19) within a housing is supported thermal collector (4) in center of which is positioned thermoaccumulative core (1) in which central cavity is settled temperature sensor

(7) and where between internal perimeter of thermal collector (4) and outer perimeter of thermoaccumulative core (1) is positioned thermoelectric couple set (3) consisting of single thermoelements (5) which are insulated by electroinsulative, thermally non-conductive 11

material (15), and where thermoelectric couple set (3) is Seebeck's effect generator, which is by insulated conductors (12) connected to programmed switcher (11), and where between internal perimeter of thermal collector (4) and outer perimeter of thermoaccumulative core (1) is placed a thermoelectric couple set (18) consisting of single thermoelements (17) which are insulated by electroinsulative, thermally non-conductive material (16), where thermoelectric couple set (18) is based on Peltier-s effect , and where said thermoelectric couple set (18) is integral part of internal heat-pump device (8) connected through adapter (9) of power supply to programmed switcher (11), to which is connected accu-battery (10) also, and where to the output connections of programmed switcher (11) is connected the connector (13) of the load (14) which is consumer of electric energy.

4. Cooling electric energy generator, in variant of cooling electric energy generator with internal heat-pump device (8) Peltier's type, according to claim 3, characterized in that, thermoelectric couple set (18) as integral part of internal heat-pump device (8) is initially supplied by electric power from accu-battery (10), wherewith by Peltier's effect obtained temperature difference between thermoaccumulative core (1) and thermal collector (4) brings to thermoelectric couple set (3) which by Seebeck's effect generated electric voltage through insulated conductors (12) bring it to programmed switcher (11) wherefrom through adapter (9) internal heat-pump device (8) is supplied by electric energy, where internal heat-pump device (8) increase thermal energy of thermoaccumulative core (1) which further increase electric energy of thermoelectric couple set (3) transferred to programmed switcher (11) which supply load (14) by electric energy and additionally charge accu-battery (10).

5. Cooling electric energy generator, according to claims 1 and 2, characterized in that, thermoaccumulative core (1) is made with elongated conduits for flow through of heated fluid (2).

6. Cooling electric energy generator, according to claims 1 and 2, characterized in that, the hot side of internal heat-pump device (8) through which flows heated fluid (2) thermally connected with thermoaccumulative core (1) whilst the cool side of internal heat-pump device (8) through which flows cooled fluid (6) thermally connected to thermal collector (4). 12

7. Cooling electric energy generator, according to claims 1 , 2 and 3, characterized in that, the protection against overheating of thermoaccumulative core (1) realized so that temperature sensor (7) data on thermoaccumulative core's (1) temperature, send to programmed switcher (11) and when the thermoaccumulative core's (1) temperature reach the upper limit of the working range, programmed switcher (11) temporary suspend supplying of internal heat-pump device (8) until the thermoaccumulative core's (1) temperature decrease.

8. Cooling electric energy generator, according to claims 1 , 2, 3 and 7, characterized in that, the programmed switcher (11) in first, initial mode, realize a continual electric connection between the accu-battery (10) and adapter (9) of the electric supply, than within second, autonomous mode, realize a continual electric connection between insulated electric conductors (12) and adapter (9) of electric supply, and in third, working mode, realize simu ltaneous continuous electric connections between insulated electric conductors (12) and adapter (9) of electric power supply, and connection between insulated electric conductors (12) and connector (13) for the supplying the load (14) by electric energy, like the connection for the controlled additional charging of accu-battery (10); and finally in fourth, switching mode, realize discontinuous electric connection between insulated electric conductors (12) and adapter (9) of electric supply, simultaneously with continual connection between insulated electric conductors (12) and connector (13) for supplying the load (14) by electric energy, like the connection for the controlled additional charging of accu-battery (10).

9. Cooling electric energy generator, according to claims 1 , 2, and 3, characterized in that, the turbo power amplification of cooling electric energy generator in outer environments like air and water, is realized by electromotor turbine (20) which provide air and water flow inside the housing around a thermal cooler (4) which is settled on extensions (19).

10. Method for the absorption of environmental thermal energy and its conversion into electrical energy for the supplying the load (14) by electric energy in cooling electric energy generator according to previous claims is, characterized in that, is realized in four working modes, whereas in the first, initial mode, cooling electric energy generator start supplied by electric energy received from accu-battery and supplied by thermal energy absorbed from environment by thermal collector (4); in second, autonomous, working mode, cooling electric energy 13

generator absorb thermal energy from environment by thermal collector (4) and concentrate the same within thermoaccumulative core (1); in third working mode, cooling electric energy generator absorb thermal energy from its environment by thermal collector (4) and supply the load (14) by electric energy, and simultaneously additionally charge by electric energy accu- battery (10); whilst in fourth, switching mode, absorb thermal energy from environment by thermal collector (4) and continuously supply the load (14) with electric energy, and simultaneously controlled additionally charge the accu-battery (10).