WO2003015186A2

WO2003015186A2 - Thermally driven power supply

Info

Publication number: WO2003015186A2
Application number: PCT/DE2002/002755
Authority: WO
Inventors: Andre Albsmeier; Wolf-Eckardt Bulst; Klaus Pistor; Frank Schmidt; Oliver Sczesny; Claus Seisenberger; Martin Vossiek
Original assignee: Enocean Gmbh
Priority date: 2001-07-31
Filing date: 2002-07-26
Publication date: 2003-02-20
Also published as: AU2002320917A1; DE10137504A1; WO2003015186A3

Abstract

The invention relates to a power supply (SV) that comprises at least one thermoelectric converter (1) with an energy accumulator (2) mounted downstream thereof, and a low-power activation unit (3) for monitoring the charge condition of the energy accumulator (2) and for the charge-dependent switching of an output signal of the energy accumulator (2). The inventive power supply is especially suitable for click sensors, and the activation unit is designed as an extremely power-saving element, for example by means of normally off FETs.

Description

Thermally drivable power supply

The invention relates to a thermally drivable power supply and a thermally drivable device using the power supply

WO 98/36395 A2 describes an arrangement for generating coded high-frequency signals, in which a thermocouple pair (“thermocouple”) or a pyroelectric converter for converting thermal process energy into electrical energy is used for voltage generation. This electrical energy is converted into high-frequency energy by means of an element with a non-linear characteristic; such an element can be a spark gap or a semiconductor component. The high-frequency signal is then encoded using a coding device. Transducers and filters, e.g. B. SAW filter described. Also described is the possibility of the arrangement depending on an environmental parameter, for. B. the ambient temperature.

So far, thermocouples are considered unsuitable to use an electronic circuit, e.g. B. to operate a sequential control system from semiconductor components, because they each only emit a small voltage of at best about 0.5 mV / degree. In order to achieve a voltage that is suitable for operating an electronic circuit even with a small temperature difference ΔT, several hundred thermocouples would previously have to be connected in series to form a so-called thermogenerator. This is inexpensive only in a micro technology such as. B. thin film technology possible; ' The resulting small dimensions of the thermocouples, however, result in a high internal resistance of the thermo generator of the order of 1 MΩ, so that this is at a voltage of 1 V can deliver its current of 1 μA, which is far too little to operate an electronic circuit.

So far, due to this problem, a thermally drivable voltage supply has only been realized with relatively large usable temperature differences or through the use of costly thermal generators with a large cross section of the thermocouples with a large number of elements at the same time.

It is the object of the present invention to provide a simplified possibility for the thermoelectric drive of an electronic circuit, in particular a sequence circuit.

This object is achieved by means of a thermally drivable voltage supply according to claim 1 and a device according to claim 7.

The thermally drivable voltage supply has at least one thermoelectric converter, for. B. a thermocouple system or a pyroelectric converter. An energy store is connected downstream of the converter, e.g. B. a capacitor or accumulator. The state of charge of the energy store is monitored by means of an extremely low-power activation unit, and an output signal of the energy store is switched depending on the state of charge, eg. B. turns a connection to an electronic circuit on or off. For example, when a threshold voltage is reached, the activation element can connect a (separate or integrated) voltage converter and a consumer (voltage monitoring). The optional voltage converter controls the output signal of the voltage supply so that a respective consumer can be operated; z. B. the voltage converter, the output signal within a to operate an electronic circuit, for. B. an electronic sequence control, keep the required voltage range. It is assumed that the electronic circuit or another consumer does not have to be operated permanently, that is to say can be switched on variably, so that the small amount of current generated by the converter even at a small temperature difference ΔT is used to charge the energy store. For this purpose, a converter is preferably used, which supplies a high voltage, for. B. in the order of 1 V.

The thermoelectric converter or thermogenerator preferably consists of a series connection of thermocouples or a pyroelectric element. The thermoelectric converter is preferably in microtechnology, e.g. B. in thin-film technology, because so a large number of transducers can be manufactured inexpensively.

The energy store is preferably a capacitor with an extremely low leakage current, which must be far below 1 μA, a typical value of the currents generated. An energy store with a leakage current of <0.1 μA is preferred. A capacitor with a plastic, e.g. B. polypropylene or polystyrene, as a dielectric or an oxide dielectric. The capacitor is advantageously constructed to have a very high resistance in the long term.

The activation element is preferably an electronic circuit which has self-blocking field-effect transistors as switching elements, in particular if these are connected to one another according to a feedback principle, e.g. B. to achieve a certain switching characteristic. The activation element is advantageously constructed in such a way that it already works with a supply current of far below 1 μA, in particular with a supply current <0.25 μA. The activation element can be realized with discrete and / or integrated components. It is also advantageous if the activation element has a voltage converter for control, e.g. B. to keep constant, the output voltage. The activation element can also be implemented in other forms, for. B. by means of one or more electrostatic miniature switches, provided that the required low current consumption is met.

Application examples of the voltage generator are:

- Power supply for temperature sensors for heat cost distribution;

- Power supply for sensors in the household, especially in cookware, stoves, refrigerators and other household appliances;

- Power supply for sensors in traffic engineering, e.g. B. in motor vehicles;

- Power supply for sensors in production and storage.

This list is of course not exhaustive, rather the voltage generator can also be used in other areas of application.

As sensors come e.g. B. Devices in question that their measurements over radio, z. B. crack sensors, or by wire, z. B. using PLC ("Power Line Communication").

The consumer is expediently designed in ULP construction with an energy consumption of less than 500 mWs per work cycle, preferably with an energy consumption of less than 300 mWs per work cycle.

The voltage generator is shown schematically in more detail in the following exemplary embodiments.

FIG. 1 shows a sketch in two partial figures of the structure of a thermally drivable device using the voltage generator; Figure 2 shows a circuit diagram of an activation unit.

Figure la shows a thermally drivable device K with a thermally drivable voltage supply SV and a consumer 5. The voltage supply SV includes a thermoelectric converter 1, an energy store 2 connected to its output and an activation element 3 with an integrated voltage converter 4.

In this exemplary embodiment, the thermoelectric converter 1 is designed as a set of thermocouples 10 implemented in thin-film technology. The energy store 2 is a high-resistance capacitor with an oxide dielectric 20. The activation element 3 is implemented with the aid of field-effect transistors 30, a feedback principle being used to achieve the desired switching characteristic. A voltage converter 4 in the form of a switching converter is integrated in the activation element 3. The consumer 5 is designed in ULP ("Ultra Low Power") technology and here comprises an electronic sequence control with the possibility of identification, eg. B. in a memory M, z. B. EEPROM, stored identity code, and a transmitter 8 for sending a transmission telegram.

In FIG. 1b, the voltage converter 4 is connected downstream of the activation element 3 as a separate component.

FIG. 2 shows a circuit diagram of a voltage supply SV with a current requirement of a voltage monitoring as activation unit 3 of less than 200 nA.

The thermoelectric converter 1 made of thermocouples 10 connected in series is connected in parallel to a capacitor 20. For this purpose, the activation element 3 is in turn connected in parallel with field effect transistors 6, which the resistors R are wired in such a way that they interact with each other in feedback. Connected to this is a voltage converter 4, which detects a certain threshold value and, after it has been reached, applies a voltage to its output; the circuit is controlled by means of a logic module 7.

FIG. 3 shows a sketch of a diagram of a consumer 5.

The consumer 5 includes a semiconductor technology, for. B. as ASIC, executed sequence control to which a memory M is connected, which stores an identity code. At least one sensor 9 is coupled to the sequence control. By means of the sequential control 7, the z. B. is given by switching on the voltage supply SV, a send telegram is created, which may contain measurement data of the sensor 9 and the identity code. The transmission telegram is then emitted via a transmission stage 8 with the antenna 81 attached.

Claims

claims

1. Thermally drivable power supply (SV), having

- at least one thermoelectric converter (1),

- an energy store (2) connected downstream of the converter (1),

- A low-power activation unit (3) for monitoring the state of charge of the energy store (2) and for switching an output signal of the energy store (2) depending on the state of charge.

2. Power supply (SV) according to claim 1, the thermoelectric converter (1) u a set of thermocouples (10) in microtechnology.

3. Power supply (SV) according to one of the preceding claims, in which the activation unit (3) has at least two field effect transistors (6) which are connected to one another in a feedback manner.

4. Power supply (SV) according to one of the preceding claims, in which the activation unit (3) has at least one electrostatic miniature switch.

5. Power supply (SV) according to one of the preceding claims, which has a voltage converter (4) for controlling an output signal.

6. Thermally drivable device (K, K '), comprising at least one voltage supply (SV) and at least one consumer (V) connected to it in ULP technology.

7. Thermally drivable device (K, K ') _/ in which the consumer (V) comprises at least one sequence control and a transmitter connected downstream thereof, in particular if the sequence control comprises a memory with an identification code.