Patent Application
20170230735
The invention relates to a sensor module having at least one interface.
Sensor modules that detect a property to be determined and convert said property into a sensor signal are known from the prior art. Said sensor modules are permanently installed in an external application. This has the disadvantage that the sensor module is disposed of when the application reaches the end of its life.
In contrast, the sensor module according to the invention having the features of the independent claim has the advantage that it can be connected in particular detachably to various external application units. In this context, “can be connected detachably” shall be understood to mean in particular that the sensor module can be connected to an external application unit but can be disconnected again non-destructively.
The sensor module advantageously comprises at least one sensor that is designed to detect and convert into at least one sensor signal at least one property. The sensor can advantageously be implemented at least as one of the following sensor applications: as a displacement sensor, an accelerometer, a motion detector, a yaw-rate sensor, a pressure sensor, an air-pressure sensor, a humidity sensor, a gas sensor, an attitude sensor, a light sensor, a proximity sensor, an acoustic sensor, a temperature sensor, a magnetic field sensor, a positioning sensor or the like.
A displacement sensor, for example, is a radar or an ultrasound sensor, and is used to measure the distance between an object and a reference point. In this case, the change in the distance is converted into a sensor signal. If the sensor comprised by the sensor module is a displacement sensor, the distance between the sensor module and a reference point in the surrounding area is measured and converted into a sensor signal.
An accelerometer is a sensor that measures its acceleration. If the sensor comprised by the sensor module is an accelerometer, the accelerations acting on the sensor module are measured and converted into a sensor signal.
A motion detector is an electronic sensor that detects movements in its immediate environment and can thereby work as an electrical switch. If the sensor comprised by the sensor module is a motion detector, then movements in the environment of the sensor module are detected and converted into a sensor signal.
Yaw-rate sensors measure the angular acceleration of a body. If the sensor comprised by the sensor module is a yaw-rate sensor, then angular accelerations of the sensor module are measured and converted into a sensor signal.
A pressure sensor measures a force. If the sensor comprised by the sensor module is a pressure sensor, the force acting on a measurement surface of the sensor of the sensor module is measured and converted into a sensor signal.
An air-pressure sensor measures an air pressure. If the sensor comprised by the sensor module is an air pressure, . . . .
One type of humidity sensor is used, for example, to measure the soil moisture continuously. If the sensor comprised by the sensor module is a humidity sensor, the soil moisture in the environment of the sensor module, which lies close to the soil, is measured and converted into a sensor signal.
A gas sensor is a sensor designed to detect gaseous substances. For instance, it can be used advantageously to detect too high a concentration of smoke or CO2. If the sensor comprised by the sensor module is a gas sensor, the production of smoke, gases or CO2 in the environment of the sensor module is measured and converted into a sensor signal.
An attitude sensor is used to determine the orientation and position. It can be used advantageously to determine the spatial orientation and/or position. If the sensor comprised by the sensor module is an attitude sensor, then the orientation and/or position of the sensor module is measured and converted into a sensor signal.
A light sensor uses the photoelectric effect to convert visible and/or invisible light, for instance UV or infrared light, into an electrical signal. If the sensor comprised by the sensor module is a light sensor, the light radiation in the environment of the sensor module is measured and converted into a sensor signal.
Proximity sensors are contactless sensors i.e. they respond to the approach of an object without coming into direct contact. They are used, for example, for detecting the position of workpieces and tools, and as a trigger mechanism for safety measures.
An acoustic sensor converts acoustic signals into electrical signals such as a voltage, for example. If the sensor comprised by the sensor module is an acoustic sensor, acoustic signals in the environment of the sensor module are measured and converted into a sensor signal.
Temperature sensors measure a temperature and convert the value of the temperature into an electrical signal, for instance into a voltage. If the sensor comprised by the sensor module is a temperature sensor, a temperature of the sensor module is measured and converted into a sensor signal.
Magnetic field sensors measure a magnetic field strength and convert the measured value into an electrical signal.
Positioning sensors measure a position property and convert this property into a sensor signal. If the sensor comprised by the sensor module is a GPS sensor, the position of the sensor module is determined and converted into a sensor signal.
At least one electrical interface is provided for sending the sensor signal to at least one external open-loop and/or closed-loop control unit and/or to an external data processing unit. An “external open-loop and/or closed-loop control unit” shall be understood to mean a component unit that is arranged outside the sensor module and is intended to provide or to control by open-loop or closed-loop means a function of the external application unit on the basis of the sensor signal.
In an advantageous embodiment, the electrical interface comprises at least one combination male connector. The male connector is advantageously in the form of a circular combination male connector. In another advantageous embodiment, the male connector is in the form of a rectangular combination male connector. The combination male connector advantageously comprises at least one of the following connections:
The male connector can be in the form of a flat male connector. Other embodiments considered practical by a person skilled in the art are also possible, however.
In another advantageous embodiment, the electrical interface comprises individual male connectors. The functions of the electrical interface can thus be implemented using less space in particular when the functionality required is less than that provided by a combination male connector.
The electrical interface advantageously comprises coding for identifying the external application unit. In this case, the sensor module can advantageously use the coding to determine an external application unit. The external application unit can advantageously be provided with a resistor or the like which is identified by the sensor module. Functions can hence advantageously be enabled that may differ from one application unit to another.
The sensor module advantageously comprises at least one communications module for establishing a data transmission connection. Data can thus be transmitted advantageously from the sensor module to an external data processing unit. A “communications module” shall be understood to mean in particular a component that allows data transmission from the sensor module to an external data processing unit.
The communications module is preferably designed to be a wireless communications module. In this case, the communications module can be in the form of a WLAN communications module, a Bluetooth communications module, a radio communications module, an RFID communications module, an NFC communications module, an infrared communications module, a cellular network communications module or the like. The communications module is advantageously designed for bidirectional data transmission. In an alternative embodiment, the communications module is designed to be a wired communications module such as a LAN communications module, a USB communications module or the like, for example.
The “external data processing unit” can be implemented as a data processing unit integrated in a body, i.e. as a data processing unit such as an implant, for instance, integrated in a body of a user. The external data processing unit, however, can also be embodied as a smartphone, a personal computer, a laptop, a netbook, a tablet, a portable power tool, an output unit such as a loudspeaker, for example, as work clothing, safety goggles, a safety helmet or as another external data processing unit considered practical by a person skilled in the art. In an embodiment as a smartphone, a personal computer, a laptop, a netbook or a tablet, preferably an app for communicating with the communications module is provided. This can advantageously facilitate transmission of electronic data.
At least one power supply unit is advantageously provided for supplying the sensor module in particular with electrical power. The power supply unit is preferably in the form of a rechargeable battery. The rechargeable battery can preferably be recharged by means of a charging interface.
It is proposed that the sensor module comprises at least one mechanical interface, via which the sensor module can be connected in particular detachably to various external application units.
The mechanical interface is preferably implemented as a clip, a bayonet catch, a slideway, a screw coupling, a hook-and-loop fastener or the like, in order to produce an interlocking connection to an external application unit. It is also possible, however, to implement the mechanical interface in a different embodiment considered practical by a person skilled in the art.
In another advantageous embodiment, the mechanical interface is implemented as a bonded connection, for example as an adhesive bond.
In another advantageous embodiment, the mechanical interface provides a force-fit connection to an external application unit, for example by means of magnetic holding forces or friction forces.
Advantageous developments of the sensor module as claimed in claim 1 can be obtained from the features defined in the dependent claims.
At least one of said sensors advantageously detects an environment-specific property and/or a property relating to an external application unit, and provides a parameter that relates to the environment and/or to the external application unit.
An “environment property” shall be understood to mean here in particular a property that defines an environment surrounding the sensor module. Said environment property, for example, may be in the form of an ambient pressure, an ambient temperature, an ambient noise level, an ambient gas parameter, an ambient gas concentration, an ambient moisture parameter, an ambient acidity and/or alkalinity parameter or another environment property considered practical by a person skilled in the art.
A property relating to an external application unit shall be understood to mean here in particular a property such as a rotational speed, a temperature, a torque, an impact energy, a feed rate, a current, a voltage, a vibration or the like or another property considered practical by a person skilled in the art.
In a preferred embodiment, the parameter relating to the environment and/or to the external application unit is transmitted to an open-loop and/or closed-loop control unit associated with the external application unit and/or to an external data processing unit.
If the parameter relating to the environment and/or to the external application unit is transmitted to an open-loop and/or closed-loop control unit associated with the external application unit, the open-loop and/or closed-loop control unit controls by open-loop and/or closed-loop means the external application unit on the basis of the sensor signal. It is thus possible that the open-loop and/or closed-loop control unit controls by open-loop and/or closed-loop means at least a rotational speed, a current, a voltage, a temperature or the like. If the parameter relating to the environment and/or to the external application unit is transmitted to an external data processing unit, the value of the parameter can be processed in the data processing unit particularly preferably as an electronic value.
In another advantageous embodiment, the parameter relating to the environment and/or to the external application unit is converted into at least a first parameter output, and transmitted from the communications module to an open-loop and/or closed-loop control unit associated with the external application unit and/or to an external data processing unit.
A “parameter output” shall be understood to mean here a digitized value of the parameter relating to the environment and/or to the external application unit. Thus a voltage can be output digitally as a value of the voltage. This digitized value of the parameter is advantageously transmitted from the communications module to the open-loop and/or closed-loop control unit associated with the external application unit and/or to the external data processing unit.
The sensor module advantageously comprises at least one data interface, which is provided in particular to transmit information from the communications module to an external data processing unit. The sensor module is preferably integrated into at least one of the external application units:
In another advantageous embodiment, the sensor module comprises at least one information output unit. An information output unit for outputting information to an operator is preferably in the form of a visual, acoustic and/or haptic information output unit. Said information output unit is preferably part of the sensor module. It is also possible, however, that the information output unit is part of an external unit such as, for example, part of a smartphone, a tablet, a PC, a laptop or the like. The information output unit preferably comprises for outputting information to an operator at least one visual output unit such as, for example, an LC display, a touch-sensitive display, an LED display, a plasma display or the like, for outputting information visually to an operator. The information output unit preferably comprises at least one acoustic output unit such as, for example, a loudspeaker or the like, for outputting information acoustically to an operator. The information output unit particularly preferably comprises at least one haptic output unit such as, for example, a vibration excitation unit or the like, for outputting information haptically to an operator. Other forms of information output to an operator that are considered practical by a person skilled in the art are likewise possible.
The communications module advantageously sends data, in particular electronic data, to the external information output unit, and the external information output unit conveys in particular visual and/or acoustic and/or haptic information to an operator.
A communications module is advantageously provided particularly for use in a sensor module. Particularly preferably, the communications module exchanges data, in particular electronic data, with an external communications module.
Further advantages and advantageous embodiments can be found in the description of the figures and from the drawings.
Exemplary embodiments of a plurality of variants of the sensor module according to the invention and of a plurality of external application units are shown in the drawings, in which:
The same reference numbers are used for the same components appearing in the different exemplary embodiments.
The service module 10 comprises a communications module 18 for establishing a data transmission connection.
A power supply unit 20 is preferably implemented as a rechargeable battery 20. The power supply unit 20 is designed to supply the sensor module 10 with electrical power.
The sensor module 10 also comprises a mechanical interface 22. The mechanical interface 22 is designed to connect the sensor module 10 detachably to various external application units 24. The advantage is that the sensor module 10 can be attached to various required external application units 24 and can therefore be versatile to use.
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It is also possible, however that the mechanical interface 22 is implemented as a clip, a screw coupling or the like, in order to produce an interlocking connection to an external application unit 24.
The sensor module 10 comprises a sensor 11, which detects an environment-specific property and/or a property relating to the external application unit 24, and provides a parameter that relates to the environment and/or to the external application unit 24.
The sensor module 10 here comprises at least one of the following sensors 11:
The parameter relating to the environment and/or to the external application unit 24 is transmitted to the open-loop and/or closed-loop control unit 14 associated with the external application unit 24 and/or to the external data processing unit 16.
It is also possible, however, that the parameter relating to the environment and/or to the external application unit 24 is converted into a parameter output, and transmitted from the communications module 18 to the open-loop and/or closed-loop control unit 14 associated with the external application unit 24 and/or to an external data processing unit 16.
The sensor module 10 comprises a data interface 34. The data interface 34 transmits a piece of information provided by the communications module 18 to the external data processing unit 16.
The sensor module 10 is integrated into one of the following external application units 24:
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The sensor module 10 comprises an information output unit 40, which conveys visual information to an operator. The environment-specific property and/or the property relating to the external application unit 24 can hence be displayed to the operator. Thus, for example, the operator of a power hand tool 24a can be provided with a visual display of the parameters relating to the power hand tool. It is also possible, however, that acoustic and/or haptic information is conveyed to the operator.
In an embodiment shown in figure to 9, the communications module 18 sends data that characterizes the environment-specific property and/or the property relating to the external application unit 24b to 24f to an external information output unit 40b to 40f, and the external information output unit 40b to 40f conveys visual and/or acoustic and/or haptic information to an operator.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2014 215 504.5 | Aug 2014 | DE | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2015/062259 | 6/2/2015 | WO | 00 |
