WO2018114870A1

WO2018114870A1 - Sensor system having a solar cell

Info

Publication number: WO2018114870A1
Application number: PCT/EP2017/083417
Authority: WO
Inventors: Dietmar Weisser; Martin Götz
Original assignee: Marquardt Gmbh
Priority date: 2016-12-21
Filing date: 2017-12-19
Publication date: 2018-06-28
Also published as: EP3559615A1; DE102017011673A1

Abstract

The invention relates to a sensor system (2) having a sensor (4) for measuring a measurement variable of a medium and/or having an actuator (5) for outputting an item of information. The sensor system (2) has a solar cell (6) for supplying power to the sensor (4) and/or to the actuator (5) for operation of same. The solar cell (6) comprises a support, wherein an active layer for generating energy, in particular electrical current, from incident light is applied to the support. The active layer has a recess (10). The sensor (4) and/or the actuator (5) are arranged facing the recess (10), in particular such that the sensor (4) can be brought into contact with the medium and/or that the output of the information by means of the actuator (5) is unimpaired.

Description

Sensor system with a solar cell

The invention relates to a sensor system according to the preamble of patent claim 1.

Such a sensor system is particularly suitable for optically operating sensors.

Such a sensor system comprises a sensor for measuring a measured variable, in particular a medium, and / or an actuator for outputting information. Furthermore, the sensor system comprises a solar cell for powering the sensor and / or the actuator for its operation. The solar cell has a carrier, wherein an active layer for generating energy, in particular of electric current, is applied to the carrier with incident light. The sensor and the solar cell are arranged separately from each other to prevent their mutual interference. However, this requires a large-scale sensor system.

The invention has for its object to further develop the sensor system such that its size is reduced. In particular, the sensor system should be able to be provided substantially completely with the active layer in a compact size.

This object is achieved in a generic sensor system by the characterizing features of claim 1.

In the sensor system according to the invention, the active layer has a recess. The sensor and / or the actuator is arranged facing the recess. In particular, such that the measurement of the measured variable by means of the sensor and / or that the Output of the information by the actor is unaffected. In other words, influencing the sensor and / or the actuator by the active layer of the solar cell is largely prevented. Advantageously, the sensor system according to the invention provides a high power generation with a minimum area for the active layer and / or the carrier, and thus a largely self-sufficient power supply, with no impairment of the sensor and / or actuator functions are to be feared. Further embodiments of the invention are the subject of the dependent claims.

In a further embodiment, such, the recess facing arrangement of the sensor may be provided that the sensor can be brought into contact and / or in cooperation with the medium. The medium may be electromagnetic radiation, i. The sensor works with electromagnetic radiation. In particular, the electromagnetic radiation may be light radiation, infrared (IR) radiation or the like. Such a sensor can be used in a variety of applications, for example, the sensor may be a brightness sensor, a motion sensor or the like. The inventive design ensures that the sensor function is not affected by the solar cell. Furthermore, the information may be an alarm. The actuator may comprise a sound generator, a loudspeaker, a buzzer, a light signal transmitter or the like. The embodiment of the invention also ensures that the actuator function is not affected by the solar cell.

In functionally reliable manner, the carrier can be made of glass. For high energy efficiency for the solar cell, the surface of the carrier may be at least partially provided with an antireflection coating. For example, offers a matting for this. It can further easily in a way to the recess

corresponding breakthrough be located in the carrier to further improve access to the sensor and / or actuator. The sensor and / or the actuator can in turn be arranged facing in the opening and / or the opening. To extend the opening angle of the breakthrough may have a chamfer and / or a rounding, so that the access for the medium to the sensor and / or actuator is improved. To protect the sensor system from external influences, a housing may be provided. Conveniently, the solar cell can be arranged on one side of the housing. This arrangement can be designed so that the solar cell simultaneously forms a wall for the housing, whereby costs are saved. In a preferred manner, the sensor may be a sensor for measuring a measured variable of light radiation. In this case, the sensor may be arranged in the housing such that light passes from the outside of the housing through the recess and / or the opening to the sensor.

In particular, due to this arrangement, the determination of the measured variable by the sensor is unaffected.

In a further advantageous embodiment, a battery can be in electrical connection with the solar cell. As a result, the battery can be charged by means of the energy generated by the solar cell. Furthermore, the sensor and / or the actuator can be operated with the energy stored in the battery, so that failures of the sensor system with low and / or lack of illumination, for example, at night, are prevented.

Finally, a radio system for transmitting data for the sensor system may be provided. In a simple manner, the measured value of the measured variable can then be transferred without the need for complex wiring of the sensor system. Of course, the radio system can also be used for external control of the

Use sensor system. For the sake of compactness, it can be offered that the

Radio system is located in the housing. An additional power supply is not necessary for the radio system if the radio system can be supplied with energy from the battery and / or from the solar cell for its operation. In an advantageous embodiment, a completely self-sufficient sensor system is created in such an embodiment.

For a particularly preferred embodiment of the sensor system according to the invention is to be determined below.

Solar cells are mostly used to make devices with low energy requirements independent of an external power supply. In addition, buffer accumulators are used to the absence of the sun, for example, at night, cloudy o. Like, to bridge. Also various sensor modules are increasingly provided with solar cells. An integrated radio module can then ensure that the sensor module provides its determined data wirelessly and thus can operate completely independently.

Especially for indoor use, solar cells made of amorphous silicon are used. This type of solar cell consists of a thin "photovoltaic" layer, which is applied to a carrier material, which is usually glass, with the glass side facing the light

Equipped with power supply, it is common for the solar cell to be aligned in the direction of the light source. For a room sensor on the ceiling and / or on the

Room wall, the solar cell is therefore in the direction of the room, and not in the direction of the ceiling and / or room wall, aligned.

However, it may become necessary for a sensor also to be oriented in the same "viewing direction." This applies, for example, to optical sensors, such as brightness sensors and / or motion sensors However, aesthetics and / or energy requirements may require nearly the entire area of the sensor module to be photovoltaic-coated, but the thin silicon photovoltaic layer does not allow light to pass through to a brightness sensor, which is absorbed or reflected. In addition, no infrared radiation can pass through the glass to a PIR (Passive Infrared) motion detector, which is absorbed or reflected.

It is therefore intended to create a sensor module which is covered almost completely with solar active surface, but still allows the operation of other sensors.

For example, the sensor module should comprise a motion detector and / or light sensors. Alternatively and / or additionally, the sensor module should offer the possibility of a breakthrough for a sound generator. For example, it may be at the

Sensor module to act a smoke detector with glass optics. The solution according to the invention provides that at the required locations the solar-active layer is subsequently removed from the substrate or not applied at all. In the substrate also openings for sensors and / or sounder can be introduced. For example, the edges can be provided with phases and / or curves for design requirements. The surface of the solar cell can also be provided with an AR (antireflection) coating, eg a matting, in order to avoid disturbing reflection.

Created is thus a solar cell with a breakthrough for a sensor and / or actuator application.

The advantages achieved by the invention are, in particular, that the surface of the sensor system does not require separate zones for the solar cells. This achieves an optically uniform surface. Thus, an integration of the solar active surface as a design element for the sensor system can take place. Furthermore, this offers

Sensor system a compact size. The solar cell can simultaneously serve as a housing wall for the sensor system, which involves the saving of an additional cover. In addition, no additional assembly steps for the solar cells are necessary, which also involves a cost savings.

An embodiment of the invention with various developments and

Embodiments is illustrated in the drawings and will be described in more detail below

described. Show it

Fig. 1 is a arranged on the ceiling of a house sensor system in perspective

View,

1, FIG. 3 is a section along the line 3-3 in FIG. 1, FIG.

4a is a section along the line 4-4 in Fig. 1, wherein the sensor is omitted, 4b is a section along the line 4-4 in Fig. 1, wherein the sensor is shown schematically,

5a shows a section as in Fig. 4a according to a further embodiment,

5b shows a section as in Fig. 4b according to the further embodiment,

Fig. 6 is a section as in Fig. 5b according to yet another embodiment and

Fig. 7 is a plan view of the sensor system in the direction VII of Fig. 3 seen according to a further embodiment.

FIG. 1 shows a sensor system 2 arranged on the ceiling 1 in a room. The sensor system 2 is, for example, a motion detector operating with electromagnetic radiation. The sensor system 2 has a housing 3, wherein the housing 3 according to FIG. 2 can be fastened to the ceiling 1. In the housing 3 is a sensor 4 for measuring a measured variable, in particular the measured variable of a medium. In the present case, the medium is the electromagnetic radiation, that is to say in particular light, infrared (IR) radiation or the like, optical radiation. Alternatively or additionally, the sensor system 2 may have an actuator 5 for outputting information. For example, the actuator 5 may be a sound generator, a loudspeaker, a buzzer, a beacon or the like, so that an alarm can be generated as information to be output.

On the housing 3 is aligned in the direction of the room solar cell 6 to

Power supply of the sensor 4 and / or the actuator 5 is arranged, whereby the sensor 4 and / or the actuator 5 by means of the energy generated by the solar cell 6 is operable. Preferably, the solar cell 6 is arranged on one side of the housing 3, specifically on the side facing the room, so that the solar cell 6 also serves as a corresponding housing wall. An in Fig. 3 only schematically illustrated, located in the housing 3 battery 7 is in electrical communication with the solar cell 6, such that the Battery 7 can be charged by means of the energy generated by the solar cell 6. The sensor 4 and / or the actuator 5 are operable with the stored energy in the battery 7, so that the sensor system 2 is operable even in the dark and / or lack of light.

According to FIG. 3, the solar cell 6 comprises a carrier 8 made of glass and a photovoltaically active layer 9. The active layer 9 applied to the carrier 8 serves to generate energy, namely electrical current, with incident light. As can be seen further in FIG. 1, the active layer 9 has a recess 10. The sensor 4 and / or the actuator 5 are arranged facing the recess 10. In such a way that the measurement of the measured variable by means of the sensor 4 and / or that the output of the

Information by means of the actuator 5 of the active layer 9 is unaffected.

In particular, due to this arrangement, the sensor 4 can be brought into contact and / or in interaction with the medium uninfluenced. The recess 10 in the active layer 9 is also closer in Fig. 4a and the recess 10 facing sensor 4 in Fig. 4b to see. Furthermore, a breakthrough 11 corresponding to the recess 9 can be located in the carrier 8, as shown in FIG. 5a. The sensor 4 and / or the actuator 5 can then be arranged in the opening 3 and / or the opening 1 1 facing in the housing 3, as shown in Fig. 5b.

The sensor 4 may be a sensor for measuring a measured variable of

Light radiation, for example, as already mentioned to a motion sensor, a brightness sensor o. The like., Act. The sensor 4 is then arranged in the housing 3 in such a way that light passes from the outside of the housing 3 through the recess 10 and / or the aperture 11 to the sensor 4, so that the determination of the measured variable by the sensor 4 can take place without being affected. This is shown in more detail in Fig. 4b and Fig. 5b. A first light beam 12 penetrates the glass carrier 8 and passes to the photovoltaic active layer 9, where the light beam 12 is absorbed to generate energy. According to FIG. 4b, a second light beam 13 penetrates the carrier 8 made of glass at the recess 10 and / or penetrates the carrier 8 at the aperture 11 according to FIG. 5b and reaches the sensor 4, the sensor 4 then determining the corresponding measured variable. A third light beam 14 is reflected as shown in FIG. 4b on the existing glass carrier 8, for example, if it is light in the IR (infrared) range. To reduce reflections, the surface of the carrier 8 may be at least partially provided with a matting serving as an antireflection coating, which is not shown further.

As can be seen in Fig. 6, the aperture 11 may have a chamfer 15 and / or a rounding. By the chamfer 15 of the opening angle and the viewing angle for the sensor 4 is extended accordingly, so that the measurement accuracy for the sensor 4 is increased. The breakthrough 1 1 may consist of a bore with chamfer 15 or without bevel 15 in the glass substrate of the carrier 8. Furthermore, in Fig. 7, an embodiment can be seen in which the glass for the carrier 8 is provided with curves 16 instead of corners. In Fig. 7 in the carrier 8 is a bore with chamfer as a breakthrough 11 for a motion detector 17 in the manner of a PIR (passive infrared) sensor, another breakthrough 1 1 as a sound opening for a speaker and / or buzzer (Buzzer) 18 and another opening as

Recess 10 in the photovoltaic Itaisch active layer 9 for a brightness sensor 19 is provided.

Finally, as shown schematically in Fig. 3, a radio system 20 is provided for the transmission of data. The radio system 20 is located in the housing 3 and is powered by the battery 7 and / or by the solar cell 6 with energy for its operation. With the aid of the radio system 20, the value of the measured variable measured by the sensor 4 can then be transmitted wirelessly for further processing. Such a sensor system 2 works

advantageously completely self-sufficient.

The invention is not limited to the described and illustrated embodiment. Rather, it also encompasses all expert developments within the scope of the invention defined by the claims. Thus, the invention can not only for a motion detector but also for other, a solar cell and sensors and / or actuators combining sensor systems, in particular in which light substantially unimpaired by the solar cell pass from and / or reach the sensor and / or actuator, for example in a smoke detector, find use. Reference Number List:: ceiling (from room)

: Sensor system

: Casing

: Sensor

: Actuator

: Solar cell

: Battery pack

: Carrier (of solar cell)

: active layer (of solar cell) 0: recess (in the active layer) 1: breakthrough (in the carrier)

, 13,14: light beam / light radiation5: bevel (on breakthrough)

: Rounding (to carrier)

: Motion detector

: Speaker and / or buzzer: Brightness sensor

: Radio system

Claims

Patent claim:

1. Sensor system with a sensor (4) for measuring a measured variable, in particular a medium, and / or with an actuator (5) for outputting information, and with a solar cell (6) for powering the sensor (4) and / or Actuator (5) for its operation, wherein the solar cell (6) comprises a support (8), and wherein an active layer (9) for generating energy, in particular of electric current, is applied to the support (8) with incident light , characterized in that the active layer (9) has a recess (10), and that the sensor (4) and / or the actuator (5) of the recess (10) is arranged facing, in particular such that the measurement of the measured variable means the sensor (4) and / or that the output of the information by means of the actuator (5) is unimpaired.

2. Sensor system according to claim 1, characterized in that the sensor (4) can be brought into contact and / or in cooperation with the medium, and that it is preferably in the medium to electromagnetic radiation, in particular light radiation, infrared (IR ) Radiation o. The like., Is, in particular that it is the sensor (4) to a brightness sensor, a motion sensor o. The like.

3. Sensor system according to claim 1 or 2, characterized in that it is the information is an alarm, and that the actuator (5) comprises a sounder, a speaker, a buzzer, a light signal transmitter o. The like.

4. Sensor system according to claim 1, 2 or 3, characterized in that the carrier (8) consists of glass, and that preferably the surface of the carrier (8) is at least partially provided with an antireflection coating.

5. Sensor system according to one of claims 1 to 4, characterized in that a recess (10) corresponding breakthrough (1 1) in the carrier (8) is located, that preferably the sensor (4) and / or the actuator (5) in the opening (11) and / or the opening (11) are arranged facing, and further preferably that the opening (11) has a chamfer (15) and / or a rounding.

6. Sensor system according to one of claims 1 to 5, characterized in that a housing (3) is provided, and that preferably the solar cell (6) on one side of the housing (3) is arranged, in particular a wall for the housing (3 ).

7. Sensor system according to one of claims 1 to 6, characterized in that it is the sensor (4) is a sensor for measuring a measured variable of light radiation (13), and that preferably the sensor (4) in the housing (3 ) is arranged so that the light radiation (13) from the outside of the housing (3) through the recess (10) and / or the aperture (1 1) to the sensor (4) passes, in particular such that the determination of the measured variable by the sensor (4) unimpaired.

8. Sensor system according to one of claims 1 to 7, characterized in that a battery (7) with the solar cell (6) is in electrical connection, such that the battery (7) by means of the solar cell (6) generated energy is rechargeable , and that preferably the sensor (4) and / or the actuator (5) with the energy stored in the battery (7) is operable.

9. Sensor system according to one of claims 1 to 8, characterized in that a radio system (20) is provided for the transmission of data, in particular such that the measured value of the measured variable is transferable, that preferably the radio system (20) in the housing (3). is located, and that further preferably the radio system (20) can be supplied with energy from the battery (7) and / or from the solar cell (6) for its operation.