DE102012214468A1 - AUTARKE SENSOR UNIT FOR SOLAR MODULES - Google Patents

Abstract

The present invention relates to a sensor unit for measuring the state and the change in physical quantities, for example temperatures and temperature differences, as a function of a physical environmental variable, for example the intensity of the solar radiation associated with the change in temperature. An autonomous sensor unit for measuring a measured variable comprises an electrical energy generating element (102) for generating electrical energy from thermal and / or mechanical energy and a control and evaluation unit for controlling the energy generating element. The control and evaluation unit (104) is designed such that it generates a sensor signal from measured operating variables of the energy generating element, which sensor signal depends on the measured variable.

Description

For measuring the state and the change of physical quantities, such as temperatures and temperature differences, depending on a physical environment size, such as the associated with the temperature change intensity of the solar radiation, at the present time in known systems several corresponding sensors and an electronic evaluation and safe Energy supply of the entire system necessary, as in 1 is shown. In this figure, the measurement of the module and ambient temperature and an intensity measurement of the solar radiation in the photovoltaic are shown by way of example. Three sensor elements are needed to obtain this information.

2 schematically shows the structure of a sensor element, with the help of the known arrangement of 1 the measurement of the temperature difference between a solar module and the environment in dependence on the solar radiation is performed. In general, each sensor element requires its own power supply and data component for preprocessing and transmission of the measured values to an external component, eg. B. a controller. The power supply consists for example of a battery or a wired connection to an external power supply. The environmental quantity acts on the sensor, for example due to a temperature change.

For detecting various measured variables in known arrangements such as photovoltaic modules, a plurality of sensors for detecting the associated environmental variables as well as for each sensor its own power supply and possibly also its own signal processing are used.

Cables and batteries for energy supply are expensive due to material and installation costs, or require maintenance and thus limit the self-sufficiency of the system. In addition, the number of components (sensor units, power supply, etc.) is high, making the system also expensive and more susceptible to component failure.

In the US patent US 4,253,764 is an example of a known measuring and recording system for solar radiation according to the "sensor B" 1 shown. However, this sensor is set up only for the detection of the solar radiation, but not for the measurement of the module temperature or the ambient temperature.

The object on which the present invention is based is to provide a sensor unit for measuring at least one measured variable, which is largely maintenance-free, robust and cost-effective, but nevertheless ensures high reliability and functional reliability.

The invention solves this problem by the simultaneous use of an energy converter as a sensor and power supply. This ensures a secure power supply and a complete self-sufficiency of the system, increases the reliability, and reduces the total cost of the system including consequential costs such as maintenance.

According to an advantageous embodiment of the sensor unit according to the invention, a thermoelectric energy converter (TEW) is operated as a sensor, which supplies itself with the required energy. According to the invention, therefore, the sensor is also used as a transducer and as a power supply, which is operated by the ambient energy.

Furthermore, the energy converter sensor element can be characterized in such a way that its change of state can be set in relation to the measuring environment variable, so that the second sensor, which was previously required especially for photovoltaic modules, is eliminated. In particular, the sensor element according to the invention can be used for example for measuring module and ambient temperature and the intensity of the solar radiation. By accurately characterizing the voltage changes of, for example, a thermoelectric generator in relation to the solar radiation, two sensors can be compared to the in 1 omitted arrangement shown omitted.

Systems that use an energy converter both as a power supply and as a sensor, are not yet known. Likewise, no system is known in which the associated intensity of the solar radiation can be linked by measuring a temperature difference by means of a thermoelectric generator.

The inventive integrated unit of transducer and power generation unit results in the following advantages for the user.

The use of an energy converter, such as a thermoelectric generator, to power the electronics and as a sensor offers the classic advantages of micro-energy harvesting (MEH) technology: no cables and thus the reduction of installation costs, easy retrofitting and complete self-sufficiency of the system, Waiver of batteries and thus a significant reduction in maintenance costs and no accumulation of battery waste and reduction in the number of components required, and thus a further cost reduction.

Due to the autarky of the system, there are also completely new application fields, such. B. the use of a solar module.

The present invention will be explained in more detail with reference to the figures. The same parts are provided with the same reference numerals and the same component names. Furthermore, individual features or combinations of features from the embodiments shown and described can in themselves represent independent inventive or inventive solutions.

Show it:

1 a schematic representation of a photovoltaic module with three different sensors for the ambient temperature, the solar radiation and the module temperature;

2 a schematic representation of a conventional sensor with separate power supply and Meßgrößenverarbeitung;

3 a schematic representation of a sensor unit according to the invention;

4 a schematic representation of a photovoltaic module with a sensor according to the present invention;

5 a schematic representation of a thermoelectric generator according to the present invention.

The basic principle of the sensor unit according to the invention 100 will be referred to below with reference to 3 explained in more detail. As shown in this figure, the ambient energy applied to the sensor unit 100 acts from a power generating element 102 at least partially recorded, to obtain both the information about the actual measured variable, as well as the operation of the sensor unit 100 to gain the required energy.

For this purpose, the sensor unit has 100 a control and evaluation unit 104 derived from certain operating quantities of the energy generating element 102 generates the required sensor signal in dependence on the measured variable and in particular performs the signal processing.

A communication interface 106 , which is preferably set up for wireless communication, is provided to transmit the generated measurement data to an external evaluation unit 105 For example, transfer a control computer, a heating control system or a PDA (personal digital assistant). Of course, a bidirectional communication interface 106 be provided, which is also capable of communication signals from the external unit 105 to recieve. This can be used, for example, for feeding in calibration data or for driving the sensor during interrogation routines.

Characterized in that the sensor unit according to the invention 100 Both the information about the measured variable to be measured, for example the temperature or a radiation density, as well as the energy required for their operation directly from the ambient energy, a complete self-sufficiency of the sensor unit is possible and with a correspondingly robust production, the maintenance of such a sensor unit kept to a minimum.

A sensor unit whose energy supply is ensured by the same principle as the detection of the environmental size, for example, by the use of the thermoelectric effect in Case of a thermoelectric generator (TEG) can be achieved. The thermal energy due to temperature changes is converted into electrical energy, which can be used to operate the signal processing and data transmission. At the same time on the electrical level and its change of power supply, such as the voltage in the case of a thermoelectric generator or the short-circuit current in the case of photovoltaic converters, on the state of the environmental size, such as the solar irradiance, closed and the element can be used as a sensor at the same time.

4 schematically shows a photovoltaic (PV) module 108 with a sensor unit according to the invention 100 ,

According to the 4 can the sensor unit 100 on a PV module 108 be attached to measure both the temperature of the module, as well as the environment and beyond the incident solar radiation. In particular, this measurement task by a thermoelectric generator 110 to be taken over as he is in 5 outlined. For example, for use in energy harvesting microsystems, conversion of thermal energy to electrical power is known. In particular, such a thermoelectric generator is based, as for example from DE 10 2009 016 154 A1 is known, on the Seebeck effect and generates an electrical voltage from a temperature gradient.

In the 5 is the region with the higher temperature than the heat bath 112 designated while the heat sink 114 the temperature T ₀ denotes the area with the lower temperature T ₁ . Regarding the 4 can the heat bath 112 for example, the area of the PV module heated by the sun 108 at which the sensor unit 100 be attached, while the heat sink 114 through the ambient air on the back of the sensor unit 100 is formed.

This calculates the load voltage U _{l of} the TEG 110 from the temperatures T ₀ and T ₁ , the thermal coupling K, the ohmic load resistance R _l , the figure of merit Z, the thermal resistance K _g , the electrical resistance R _g and the Seebeck coefficient a according to equation (1) below.

In der Gleichung (1) für U_l gibt es drei unbestimmte Größen: Die Temperaturen T₀, T₁ sowie die thermische Kopplung K. Da die U-I Kennlinie von thermoelektrischen Wandlern annähernd linear ist, ist diese bereits durch die Messung zweier Punkte festgelegt, so dass für eine der drei unbekannten Variablen eine Annahme getroffen werden muss. In this case dT = T ₁ -T ₀ and R _{eff are} the effective resistance according to equation (2).

In equation (1) for U _l, there are three indefinite quantities: the temperatures T ₀ , T ₁ and the thermal coupling K. Since the UI characteristic of thermoelectric transducers is approximately linear, this is already determined by the measurement of two points that an assumption must be made for one of the three unknown variables.

It can be shown that the influence of the temperature T ₀ on the load voltage is low. This allows them to be fixed to a fixed value.

Thus, the two unknowns dT and K remain, which can be determined by measuring the UI characteristic. By measuring the no-load voltage U ₀ , the relationship shown in equation (3) results for K.

The subsequent measurement of the load voltage U ₁ under a previously defined ohmic resistance finally yields the values for dT and K according to equations (4) and (5).

Thus, the parameter dT is determined, which is directly related to the radiated heat radiation.

The sensor unit 100 Thus, according to the present invention, it is possible to directly determine the temperature difference dT between a first and a second region of the sensor unit and to deduce the solar irradiance therefrom. The energy required for this measurement process is generated directly from the radiated heat and the temperature gradient generated thereby. Thus, no external power sources are needed and the sensor unit 100 can autonomously obtain the required information and send it wirelessly to an external control unit 105 communicate.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 4253764 [0005]
• DE 102009016154 A1 [0027]

Claims (9)

Autarkic sensor unit for measuring a measured variable, wherein the sensor unit ( 100 ) comprises: an electric power generating element ( 102 ) for generating electrical energy from thermal and / or mechanical energy and a control and evaluation unit for driving the power generation element, wherein the control and evaluation unit ( 104 ) is designed so that it generates a sensor signal from measured operating variables of the energy-generating element, which depends on the measured variable. Sensor unit according to claim 1, further comprising a wireless communication interface ( 106 ) for transmitting and / or receiving communication signals. Sensor unit according to claim 1 or 2, wherein the energy-generating element comprises a thermoelectric energy converter. Sensor unit according to claim 3, wherein the temperature difference between a first and a second region of the thermoelectric energy converter forms the measured variable. Sensor unit according to claim 4, wherein the control and evaluation unit ( 104 ) is designed so that it determines the temperature difference from a load voltage of the thermoelectric energy converter. Sensor unit according to one of the preceding claims, wherein the control and evaluation unit ( 104 ) is designed so that it determines a temperature difference and therefrom a solar irradiance acting on the sensor unit. Use of a sensor unit ( 100 ) according to one of the preceding claims for the combined determination of a module temperature and an ambient temperature on a solar module ( 108 ). Use according to claim 7, wherein the sensor unit is mounted such that it detects a temperature difference between a defined location of the solar module ( 108 ) and the environment. Use according to claim 8, wherein the control and evaluation unit ( 104 ) is designed so that they continue from the measured temperature difference with a on the solar module ( 108 ) acting solar radiation correlated output calculated.

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