LT5370B - Method and device for generating thermoelectric energy - Google Patents

Abstract

The invention relates to the field of semiconductor thermoelectric generators and may be used in heat and thermoelectric power plants, which use local cheap fuel. The invention increases exploitation of potential power of the semiconductor thermoelectric generators (STG). A device for generating thermoelectric energy comprises: a generator for generating electric energy (STG), an energy controller comprising an electronic commutator which distributes the STG energy for two condensers with supercargo capacity, a microprocessor controlling the electronic commutator, sensors measuring the charging and discharging voltages of the condensers, a loading block comprising two condensers, a module for standardizating and recuperating energy comprising an induction-coil and recuperating diodes. A method for generating thermoelectric energy is characterized by that two identical condensers are charged until fixed value of the charging voltage through an electronic commutator, therewith the fixed value of the c

Description

The invention relates to the field of semiconductor thermoelectric generators for power electronics and can be applied to thermal and thermoelectric power plants using local cheap fuel.

A method and apparatus for measuring and optimally controlling the voltage of the thermal generators and the load are known in the art. The apparatus is comprised of semiconductor modules in a thermoelectric generator (TEG) whose interconnection mode is controlled by a serial, parallel, or hybrid interconnection switching unit which, depending on the TEG and load voltages measured by the voltage measuring unit, selects the interconnection mode of the semiconductor modules controlled by a break break control unit (European Patent EP 0878851, H01L 35/00, H01L 35/28).

This method and apparatus allow the measurement and evaluation of TEG and load voltages and, by changing the way TEG modules are connected, make better use of the TEG-generated rated power. However, it cannot better exploit the TEG's potential power by increasing the TEG-generated power

Another embodiment of a thermoelectric power system is known, and a device wherein the TEG voltage is measured, controlled, and the power supply is controlled by a controller depending on the TEG voltage measurement result, and the system structure includes compensating means to provide uninterruptible power supply interrupts the power supply to the load from the TEG (European Patent EP 174996A1 H02N 11/00).

The method and device of this system allows to control only the TEG rated power supplied to the load and to efficiently store electricity depending on the TEG voltage generated. However, as with the first analogue, it cannot make better use of the potential power of the TEG by increasing its power output. In all known analogs and prototypes, the nominal power Pn of TEG is only 50% of the potential power, so it is underutilized.

However, in spite of this important disadvantage, due to the similarity of the essential features, this method and device have been adopted as a prototype of the possible invention.

The object of the invention is to increase the efficiency of TEG by better utilization of the potential power. The stated object is achieved by charging two identical super-capacitors [SDK] via a controller electronic commutator to a fixed charge voltage Ujk, which is selected below the idle voltage U _o (U _{! K} <U _o ) of the tenmoelectric generator [TEG], without in addition, one charged SDK is left connected to the TEG and the other is connected via the controller's electronic switch to the energy storage device and the load in the load device, discharging the SDK to a voltage U &amp; (0.7-0.85) from U _{> K} , partially discharged one SDK is connected to the TEG for charging via the controller and the other to the charged SDK for the storage and load depending on the magnitude of the measured charging and discharging voltages on the SDK, alternating between TEG and the storage and load in the electrical circuit.

The stated purpose. achieved by a controller consisting of an electronic commutator distributing TEG energy to two super-capacitance capacitors [SDKs], a microprocessor controlling an electronic commutator, sensors measuring the SDK charging and discharging voltages, a load unit consisting of two SDKs storing its TEG energy in its field. , a power standardization and recuperator module consisting of an induction coil and recoupling diodes of energy stored in its magnetic field.

A schematic diagram of a possible invention is shown in FIGS. 1, the charge and discharge voltages Doj and Uc ₂ processes in the SDK are illustrated in Figs. 2 is a graph of the time function P _A = f (t) of the load power P _A and Uc ^ = f (t) and FIG. 3.

An apparatus for generating thermoelectric power according to the present invention {Figs. 1) consists of a thermoelectric generator TEG (1) which supplies the thermoetochrome energy to the load module (2) via an electronic commutator (4) of the controller (3) controlled by a microprocessor (5) and its control signal being formed by the voltage sensor unit of the controller (3). (6). Thermal power from the controller (3) electronic switch (4) is supplied to the load module (2) by two super-capacitors [SDK] (7) _f which are alternately charged such that when one SDK is charged from TEG (1), the other is discharged through a power recovery unit (8) of the load module (4), supplying power to the long-term energy storage device (9) and the load (10).

The method and apparatus of the present invention operate as follows:

At the beginning of the process, the TEG (1) charges two identical super-capacitance capacitors SDK 7 (e.g., 0.5; 1.0 Parade capacitance, the size of which depends on the TEG power) through the electronic switchboard (4) of the controller (3). ) to a fixed magnitude charging voltage Uk, which is less than the TEG idle voltage U _Q (e.g., UiK ~ (0.6-0.64) U _o ). One charged SDK (7) is left connected to the TEG (1) and the other is connected to the controller (3) by an electronic switch (4) via the load module (2) power recovery unit (8) to the long-term energy storage device (9) (e.g. to the battery or regenerative electrochemical generator) and the load (10), the SDK (7) is discharged to a voltage Ush which represents (0.7 - 0.85) from the charging voltage U to _K - The unloaded SDK (7) controller (3) electronic the switch (4) connects to the TEG (1) for charging and the other to the charged SDK (7), the electronic switch (4) connects to the long-term energy storage device (9) and the load (10) via the energy recovery unit (8). The electronic commutator (4) of the controller (3), controlled by the microprocessor (5) and the charging / discharging voltage sensor unit (6), alternates the thermal power of the SDK (7) alternately.

P LT 5370 B generator TEG (1) and long-term energy storage device (9) and load (10) in the electrical circuit.

The variation of the voltages Uc ^ and Uc _{2 of} the charging and discharging processes of the SDK (7) is illustrated in Figs. 2 shows the time functions Uoj = f (t) and Uc2 = f (t).

The graph of the load power P _A versus time function Pa ²⁵ f (t) is shown in Figs. 3. By comparing the average power Py of the function depicted in this graph with the nominal TEG power P _N obtained in known solutions, it is possible to evaluate the efficiency of the presented method and the utilization of the device. Here Py = (1, fxT, 6) P _N. Thus, the utilization efficiency of the potential TEG power from 50% obtained by the best known TEG utilization solutions can increase to (75 ^ 80)% after the use of the present invention.

The potential invention significantly improves the utilization of the TEG's potential power compared to the prototype, reducing the electrical power loss in the TEG's internal impedance and thereby immediately increasing its power output by:

- alternately charged SDKs due to the properties of the intermediate energy storage process in its electric field, causing less power loss in the TEG internal impedance.

- In the alternately discharged SDKs, all the energy stored in the electric field is transferred to the long-term energy storage device and the load because the capacitors have a very low active internal impedance (practically zero).

- The SDK supplies power to the long-term energy storage and load through the energy standardization and recovery unit where, during the normalization process, energy is stored in an inductive coil magnetic field, then returned to the long-term energy storage and load. The inductor coil in the SDK and load circuit normalizes the load power time function P _A = f (t) given in Figs. 3.

- The charging voltages of the SDK are set lower than the TEG idle voltage (U _iK <U _o ) and their discharge voltages Ujš are selected below the charging voltages U _{! K} (U® «θ, θ ⁵ ^« 3). discharge times and to ensure the stability of medium power Pv supplied to the long-term storage and load [see P _v = f (t) Fig. 3J.

- All named energy conversion operations that take place in the structure of a possible invention are fundamentally different from the prototype and provide unique results in operational efficiency.

Claims (2)

DEFINITION OF INVENTION 1. The method of generating thermoelectric energy is based on measuring the electrical voltage and the power supply to the load and the energy storage device by controlling the controller, characterized in that two identical super-capacitors [SDK] are charged via a controller electronic switch to a fixed charging voltage Ujk. behind the idle voltage U _o (U _lK <Uo) of the thermoelectric generator [TEG], in addition, one charged SDK is left connected to the TEG and the other connected via the controller electronic commutator to the energy storage device and the load in the load device. , which is (0.7 ^ 0.85) from U _3K , connects one unloaded SDK through the controller to TEG for charging and the other to the loaded SDK for energy storage and load depending on the magnitude of the measured SDK charging and discharging voltages, alternately switched between TEG energy storage and load e in an electric circuit. 2. A device for generating thermoelectric energy, comprising a thermoelectric power generating TEG, a regulating controller and an energy storage device and a load, characterized in that the controller is comprised of an electronic commutator for distributing TEG power to two super-capacitors capacitors, The charging and discharging voltages of an SDK, a power unit consisting of two SDKs transiently storing TEG energy in its electric field, an energy normalization and recuperation module consisting of an induction coil and recoupling diodes of energy stored in its magnetic field.