EP3122962A1 - Device for an actuation handle, actuation handle, and method for wireless transmission of a signal generated by autonomous energy - Google Patents

Abstract

The present invention relates to a device (10) for an actuation handle (1) comprising an actuation bolt (2) which, along its longitudinal axis of extension (A), has at least one section which has at least one outer edge (4; 44) on the circumferential side. The device (10) comprises a housing (12) with a first accommodation section (14) for accommodating an energy converter (30) for electrical supply of a radio transmitter module by converting mechanical energy into electrical energy, and an aperture (16) for the actuation bolt (2), wherein the aperture (16) comprises a second accommodation section (18) for rotatably accommodating the section of the actuation bolt (2) having the at least one outer edge (4; 44). The device (10) is characterized in that the first accommodation section (14) is arranged adjacent to the aperture (16), wherein, in an accommodation state of the energy converter (30), a switch element (32) of the energy converter (30) protrudes into a rotational path of the at least one outer edge (4; 44) and can be actuated by operation of a switch during the rotational movement of the actuation bolt (2) by means of the at least one outer edge (4; 44).

Description

 A device for an actuator handle, actuator handle, and method for wirelessly transmitting a self-sufficiently generated signal

The invention relates to a device for an actuating handle, in particular an energy-autonomous device for detecting at least one operation, more preferably an actuating direction of the actuating handle and further preferably a position of the actuating handle and for wireless transmission of a signal with information about the detected operation, actuation direction or position , Furthermore, the present invention relates to such an actuating handle and a method for the wireless transmission of an energy self-generated signal by means of an actuating handle.

Energy-autonomous systems are used in the field of building automation, for example in installation switches and window and door handles. Energy self-sufficient systems are characterized in that the system comprises an electrical energy generating device and thus requires no power connection, whereby connections and lines can be saved. Such an energy generating device may be, for example, a solar cell, a piezoelectric transducer, an inductive transducer or the like. Such power generators are advantageous in that the energy required for power generation can be taken from the environment or from a mechanical energy required for operating the installation switch or the window or door handle, whereby this type of energy converter is independent of battery capacities and maintenance measures.

Such energy self-sufficient systems are used in connection with condition monitoring, primarily based on radio-bound solutions. The radio-bound solutions have the advantage that a complex wiring can be omitted.

For example, document EP 1 838 941 B1 discloses an energy self-sufficient radio solution for an actuation handle, which has a device based on an inductive converter with the above-mentioned features. In the field of window and door handles, a uniform handle design has meanwhile prevailed, which consists of a standardized housing and a uniform interface to a locking mechanism. The interface is usually formed from a square bolt, which is rotatably coupled to a handle and engages with its free end in the locking mechanism. The housing has fastening means for attachment to the window frame or on the door.

Regardless of the exterior design, the demand for self-sufficient radio systems, which are able to sell complex radio protocols such as KNX-RF, Zigbee, Bluetooth Low Energy or W-LAN with high transmission power and with several repetitions, increases. High demands are also placed on data transmission security. Furthermore, the self-sufficient radio systems should offer the possibility to easily retrofit existing solutions.

With the present invention, a device for an actuating handle is to be provided which meets at least one of the above requirements, preferably all of the above requirements. In particular, the device should be inexpensive and energy self-sufficient and maintenance-free work. Furthermore, the device should preferably be designed so that the standardized design can be maintained. Furthermore, the device should preferably be designed to be retrofittable for existing solutions. In addition, further preferred different functional positions of the actuating handle should be detectable bar. In addition, should continue to be preferred, a high data transmission security can be guaranteed.

The present invention therefore proposes, according to one aspect, an apparatus for an actuating handle with an actuating bolt, which has along its longitudinal extension axis at least one section with at least one peripherally arranged outer edge, wherein the device is suitable at least for detecting an actuation of the actuating handle. The actuating handle is preferably a rotatable handle, in particular a window handle or a door handle. The device comprises a housing which has a first receiving section for receiving an energy converter for the electrical supply of a radio transmitter module by converting mechanical energy into electrical energy. In other words, the electrical energy generated by the energy converter is used by the radio transmitter module in particular for generating and wirelessly transmitting a radio signal.

The housing further has a passage. The passage has a second receiving portion for rotatably receiving the at least one outer edge having portion of the actuating bolt. The passage preferably extends in the passage direction at least along the second receiving portion. The passage may thus be associated with further, arranged outside the second receiving portion elements. The actuation bolt can be introduced into the passage and, in a state operatively connected to the device, projects beyond the passage along the passage direction or the introduction direction at least on one side, preferably on both sides. For example, more preferably, at least one passage opening formed in the housing can be associated with the passage. The passage opening may be further preferably associated with the second receiving portion.

The present invention is characterized in that the first receiving portion is disposed adjacent to the passage, wherein in a receiving state of the energy converter at least one switching element of the energy converter protrudes into a rotational path of the at least one outer edge and crosses the rotary path and by means of the at least one outer edge during a Rotary movement of the actuating bolt is operable switch effective. Switching means in this context that the energy converter converts by means of the switching-effective actuation of the switching element by the at least one outer edge of a transmitted from the at least one outer edge of the switching element mechanical energy into electrical energy. The energy converter is preferably an inductive converter. The energy converter is more preferably part of the device. With further preference, the energy converter has a soft-magnetic or magnetizable element and a permanent magnet which can be moved by means of the switching device. element are arranged movable relative to each other. The stationary component of this arrangement is surrounded by at least one coil, wherein the movable component of this arrangement is movable by means of the switching element to the stationary component. The stationary and movable components are designed such that by means of the relative movement, a temporal change of the magnetic flux or a magnetic flux direction reversal in the arrangement is effected, which each cause generation of an induction voltage in the coil. The switching element is preferably a spring element or a spring device which is suitable for transmitting the mechanical energy transmitted by the at least one outer edge to the movable component of the arrangement by moving the same. More preferably, the switching element is designed to initially store the mechanical energy transmitted by the at least one outer edge and to deliver it to the movable component of the arrangement as soon as a switching point is reached. More preferably, the energy converter is an induction generator according to DE 10 201 1078 932 A1. This energy converter is advantageous in that compared to other known inductive transducers, a magnitude greater electrical energy yield can be achieved.

The second receiving portion is preferably designed such that at least a portion of the actuating bolt with a sufficient for switching effective operation of the energy converter portion of the at least one outer edge is receivable. In other words, the second receiving portion is preferably formed depending on the dimensions of the portion having at least one outer edge, to completely or partially receive a portion of the actuating bolt having the at least one outer edge. The second receiving portion preferably extends in the forward direction between mutually opposite passage openings through which the actuating bolt in an assembly process with the housing by the same is feasible. Further preferably, the second receiving portion orthogonal to the passage direction on the rectified outer dimension of the portion with the at least one outer edge corresponding extent. The proposed device can be formed more compactly by means of the direct actuation of the energy converter by means of an outer edge provided on the actuating bolt. The housing can thus be adapted to the standardized design of a standard handle. By means of the energy converter, the device is designed energy self-sufficient and maintenance-free. Based for example on a use of the above-known energy converter energetically demanding radio protocols are easily feasible.

Preferably, the actuating pin is designed as a polygonal pin. More preferably, the actuating pin is formed from a known from the field of standard handles square pin. At least one of the edges extending in the longitudinal axis direction of the actuating bolt forms the at least one outer edge. More preferably, more than one of the edges running in the longitudinal axis direction of the actuating bolt form an outer edge which is suitable for switching-effective actuation of the energy converter. Alternatively or additionally, the outer edge may be formed by a protruding from the outer surface of the actuating bolt protrusion. In this case, the projection may have any shape suitable for switching-effective actuation of the energy converter. In particular, the at least one outer edge or the projection cross-sectionally form a summit point, which moves during the rotational movement of the actuating bolt along a preferably circular path, which is crossed by the switching element, in particular a punctiform or planar actuator of the switching element. During a rotational movement of the actuating bolt, the switching element comes into abutment with the outer edge or the projection and is entrained or moved by the outer edge or the projection of an initial position of the switching element at least up to a switching position of the switching element for switching-effective operation of the energy converter.

Further preferred embodiments of the present invention are the subject of the dependent claims. According to a preferred embodiment, the housing has a trough-like section which forms the first receiving section and the passage with the second receiving section, wherein the passage in the passage direction has a passage opening formed in the trough bottom. Thus, a single space is created, which can be covered over an outer side of the housing for protection against external influences, more preferably is sealable.

More preferably, the housing forms a unilaterally open trough, which comprises the trough-like portion. The housing can be made simple and compact. To form the trough-like section, at least some of the housing walls forming the open trough can be used.

The housing outside of the trough-like section preferably has fastening means for fastening the housing to a wall provided for fastening the actuating handle. This wall may for example be part of a window frame or a door. The fastening means further preferably form on a side facing away from the trough-like portion of the housing from the selbigen projecting mounting pins, which are designed to engage with formed in the intended wall mounting recesses for fastening the actuating handle. The device can thus be installed at a mounting location of the actuating handle using existing fastening measures.

More preferably, the housing on a trough-like housing portion having side of the housing further fastening means for fixing the actuating handle on the housing, wherein the further fastening means are arranged outside of the trough-like housing portion. Thus, the device can be installed on the actuating handle and in intermediate position with the actuating handle and the intended wall for fastening the actuating handle. For this purpose, the actuating handle preferably has a rosette which can be connected to the housing via the further fastening means. A rosette is usually used to cover fasteners for the tion handle and / or used to attach the actuating handle. The rosette also visually separates the actuating bolt against an actuating portion such as a handle. The rosette further preferably has the other fastening means associated with them engageable counter-fastening means. As fastening means and counter-fastening means are any connecting means into consideration, which can cause a detachable or non-detachable connection between two parts. For example, you can

Screw, detent, adhesive and / or riveted joints are taken.

The housing is preferably made of plastic, more preferably molded from injection-molded plastic. Further preferably, the housing is formed with the trough-like portion, the fastening means and the further fastening means of one piece. The housing can thus be manufactured inexpensively.

Further preferably, the housing has an abutment section for abutment with a support element carrying at least one radio transmitting antenna, which in a contact state with the housing covers a section of the trough-like section surrounding at least the passage. In other words, the carrier element has a passage opening corresponding to the extent of the passage or passage for the actuating bolt, wherein the passage opening is formed coaxially with the passage in an abutment state of the carrier element. The system is preferably formed by frontal ends of the trough-like section enclosing housing walls. Alternatively or additionally, the system is preferably formed by front ends of inner housing walls, which are arranged within the outer housing forming the open trough, wherein the front ends of the inner housing walls have a smaller distance to the trough bottom than the front ends of the outer housing walls. This allows the carrier element between the outer housing walls to come into contact with the housing, whereby a further compact design of the device is possible. The support element preferably has an outer dimension corresponding to the tub interior of the open tub, as a result of which the support element can cover the open tub outside the passage area when in the contact state. The Carrier element thus forms a cover for the housing. The housing interior or the components received in the housing interior can be protected thereby more effectively against external influences.

In accordance with a further preferred embodiment, the device has an actuating adapter element which can be connected in a rotationally fixed manner to the actuating bolt and can be received by the second receiving section, which forms the at least one outer edge on the circumference of the actuating bolt. In this way, the device can be adapted, for example, to existing solutions which have an actuating bolt without at least one outer edge or too small a cross-section for actuating the energy converter in a switching-effective manner.

The actuating adapter element preferably comprises a bore through which the actuating bolt can be brought. The bore preferably forms a negative of the cross section of the actuating bolt. More preferably, an inner contour or an inner dimension of the bore corresponds to an outer contour or an outer dimension of the actuating bolt. The actuating adapter element can thus be arranged on the actuating bolt via a punctiform or flat press fit.

Alternatively or additionally, the actuating adapter element can preferably be connected to the actuating bolt via an adhesive connection, screw connection, clamping connection or similar connections.

Furthermore, alternatively or additionally, the actuating adapter element preferably has a base, more preferably a base plate, from which extends the at least one outer edge, wherein the base is rotatably receivable by the passage opening. The base preferably has an outer contour corresponding to the inner contour of the passage opening. The outer contour and the outer dimension of the base are preferably selected such that an unimpeded rotational movement of the base in the passage opening is possible.

Further preferably, the base can be held captive in the passage opening at least in a direction parallel to the passage opening direction. examples For example, this can be realized by means of a passage of the base which acts in the passage opening direction, with a section of the housing bottom bounding the passage opening. More preferably, the base is held captive in the passage opening in opposite directions parallel to the passage opening direction. This can also be realized by way of example by a kind of tongue and groove system between the base and the housing bottom in the passage opening.

By means of the base, a fastening of the actuating adapter element can be omitted, for example, on such an actuating bolt, which has at least one outer edge or an outer projection. The actuating element is only to be configured in such a way that the actuating element can be carried along by the actuating bolt during a rotational movement. This can be realized for example via an engagement between the existing outer edge or the outside protruding projection of the actuating bolt with a bore limiting the inside of the Betätigungsadapterelements.

In accordance with a further preferred embodiment, the device has a position detection device, which can be coupled to the energy converter and the radio transmission module, for electrically detecting a position of the actuating handle. For this purpose, the position detection device comprises a coding element which can be coupled non-rotatably to the housing and can be surrounded by the actuating bolt and an electrically conductive contact element which can be coupled non-rotatably to the actuating bolt. The coding element can be electrically coupled to the energy converter and has at least one electrically engageable contact bridge assigned to an engageable position of the actuating handle, which can be switched between an open, electrically nonconductive and a closed, electrically conductive state by means of the electrical contact element, contact bridges assigned to different positions being different from one another are electrically isolated, wherein upon receipt of a predetermined position of the actuating handle, the at least one of the position associated contact bridge is electrically connected or closed, while the other contact bridges are electrically non-conducting switched or open. The individual positions of the actuating handle preferably correspond to functional positions of, for example, a window or a door such as an opening Position, a closed position or a tilted position. In this way, a predetermined position of the actuating handle can be detected in a simplified manner, forwarded to the radio transmitter module and transmitted wirelessly via the radio transmitter module to a receiver, for example a condition monitoring device. The position detection device is therefore suitable for using an electrical energy generated by the energy converter for detecting the position of the actuating handle. Furthermore, the position detection device is suitable for transmitting information about the detected position to the radio transmitter module by means of an electrical signal, wherein the radio transmitter module further processes this signal for the wireless transmission of the information.

The coding element preferably has, for each of the receptable positions of the actuating handle, at least one contact section and a further common contact section which is electrically insulated from these contact sections and arranged concentrically therewith, the contact sections associated with the actuating handle being electrically insulated from one another. An electrically conductive contact bridge is thus formed by a contact portion and the common contact portion.

The contact element preferably has at least one first contact for electrically conductive contacting of the common contact section and a second contact electrically conductively coupled to the first contact for electrically contacting one of the contact sections in dependence on a position of the actuating handle. Thus, the at least one of a predetermined position of the actuating handle associated electrically conductive contact bridge can be switched depending on the position or functional position of the actuating handle between the open and the closed state.

More preferably, the coding element is arranged on a printed circuit board. The printed circuit board further preferably forms the carrier element with the radio-transmitting antenna. Further preferably, the radio transmitter module is arranged on the printed circuit board. Thus, the entire electronics for detecting the position of the actuating handle and for wireless transmission of a signal with information about the summarized actuation, in particular be accommodated on the detected actuation direction and / or position of the actuating handle on a printed circuit board. The electronic components forming the radio transmitter module are preferably arranged on a side of the printed circuit board facing away from the coding element, the housing having a receiving section for the electronic components. Thus, the electronics may be provided on an inside protected to the outside of the device. Alternatively, the electronic components forming the radio transmitter module can be distributed on at least two printed circuit boards. Preferably, the one circuit board comprises only the radio transmitter antenna, while the remaining electronic components of the radio transmitter module are arranged on the second circuit board, which can be received in a further receiving portion of the housing and electrically coupled to the energy converter in particular via plug contacts. The first and second circuit boards are preferably electrically coupled to each other by means of a plug contact. Alternatively or additionally, other electrical couplings such as electrical lines, grinding or clamping contacts may be provided. As a result, a modular construction of the device is favored, whereby in a defect case only the circuit board carrying the defective component needs to be exchanged. The printed circuit board can be a commercially available printed circuit board, a stamped grid, a metal-plastic composite or another contact system. The radio transmitter module may be a radio transmitter module for bidirectional communication with a radio receiver module.

Further preferably, the contact portions and the common contact portion are each formed by sliding contact surfaces, wherein the first and second contact are formed by protruding from the contact element sliding contact fingers. This can be made depending on the position of the actuating handle between the contact element and the coding, in particular between the first and second contact and the correspondingly associated contact portions an electrically conductive sliding contact. Thereby, a low-cost and easily formed position detecting device can be provided. According to another aspect of the present invention, an actuating handle is proposed. The actuating handle comprises a handle, an actuating pin rotatably coupled to the handle, a device as described above, an energy converter for converting mechanical energy into electrical energy and a radio transmitter module coupled to the energy converter for wirelessly transmitting a radio signal, the energy converter generating the radio transmitter module supplied with electrical energy. The actuating bolt is intended to engage with its free end in a locking or opening mechanism. The actuating handle is preferably a window or door handle, wherein the free end of the actuating bolt is adapted to engage in a provided with the window or the door mechanism for closing and opening the window or the door. In this way, an actuating handle which satisfies the requirements described above can be provided.

According to a further aspect of the present invention, a method is proposed for the wireless transmission of an energy self-generated signal by means of an actuating handle, wherein the actuating handle comprises a rotatable actuating pin having at least one outer edge, in the rotational path of which a switching element of an energy converter for converting mechanical energy into electrical energy protrudes that a rotational movement of the actuating bolt causes a switching effective operation of the energy converter by means of actuation of the switching element by the outer edge, wherein the generated electrical energy supplied to the energy converter electrically coupled radio transmission module for wireless transmission of the radio signal. The actuation handle is preferably a preferred actuation handle as described above. The method includes a step of rotating the at least one outer edge from an initial position toward an end position via an actuation position operatively actuating the energy converter. The starting position may be one of the above-described functional positions of the actuating handle, the end position preferably being a different functional position of the actuating handle. Further preferably, the actuation position may be identical to the end position or alternatively lie between the starting position and the end position. The rotation step comprises a sub-step of generating an electrical energy by means of the energy converter, a subsequent sub-step of generating a radio transmission telegram with information about the actuation of the actuation handle and a subsequent sub-step of sending the radio transmission telegram. The generation and transmission of the radio transmission telegram is effected by means of the radio transmitter module, which has at least suitable electronic components and a radio transmitter antenna. The electronic components preferably form at least one logic and one radio module.

The method allows a cost-effective, self-sufficient and maintenance-free state query for a compact formable actuating handle.

Preferably, the energy converter is formed monostable for the process. Monostable corresponds to a further energy production by the energy converter without further actuation of the switching element. This can be realized, for example, by means of a spring device forming the switching element, which is configured in such a way that it automatically resets itself to the starting position after actuation, whereby further energy is generated in the energy converter. Alternatively, the energy converter is preferably formed bistable. Bistable corresponds to a further energy generation by the energy converter preferably by means of an actuation of a further in the rotational path of the at least one outer edge projecting switching element. This can be realized, for example, by an actuatable return spring coupled to the energy-generating components of the energy converter, which forms a further switching element which can be introduced into the rotary path of the outer edge after actuation of the switching element, which remains outside the rotary path of the outer edge after actuation thereof until a renewed actuation of the switching element , In the case of the monostable or bi-stable energy converter, the method preferably has further substeps associated with the rotation step and following the substep of the transmission in the order of regenerating an electrical energy by means of the energy converter and repeatedly sending the radio transmission telegram. As a result, for example, an energetic Sophisticated radio protocol to be sent. In addition, a higher frequency of transmission can be ensured, whereby a better transmission reliability can be achieved.

Alternatively, in the case of the monostable or bistable design of the energy converter, the method preferably comprises further substeps associated with the rotation step and following the substep of the transmission in the order of regenerating an electrical energy by means of the energy converter, generating a new radio transmission telegram and sending the new one Radio transmission telegram on. As a result, improved system security, in particular tamper resistance, can be achieved.

In accordance with a further preferred embodiment of the method, the actuating handle comprises an electrical position detection device as described above for electrically detecting a position of the actuating handle, wherein the rotation step precedes a substep of generating the radio transmission telegram by closing a contact bridge associated with a position of the actuating handle to detect the position the actuating handle, wherein the information of the radio transmission telegram includes information about the detected position of the actuating handle. The detection of the position of the actuating handle can be carried out by means of a query or signal evaluation, for example by a logic device, in particular the radio transmitter module, wherein the sub-step of the query or signal evaluation follows the sub-steps of closing and generating an electrical energy, wherein the step of closing the contact bridge preferably for the sub-step of the query preceded by the sub-step of generating an electrical energy and for the sub-step of the evaluation is the sub-step of generating an electrical energy below. The latter already favors automatic signal transmission to the logic module when the contact bridge is closed.

More preferably, the energy converter monostable or bistable designed for the process and the actuating handle equipped with an electrical energy storage, wherein the rotation step one between the substep of generating a sub-step of storing a surplus electrical energy and preferably a sub-step following this sub-step of regenerating an electrical energy by means of the energy converter has a radio transmission telegram and the sub-step of sending the radio transmission telegram. As a result, an improved higher energy availability can be ensured, for example for complex radio protocols. The energy store is preferably arranged on a printed circuit board carrying at least one electronic component of the radio transmitter module.

Further preferred for the method, besides the monostable or bistable design of the energy converter, the radio transmitter module is designed for bidirectional communication with an associated radio receiver module, wherein the rotation step further sub-steps subsequent to the sub-step of sending in the order of generating a new radio transmission telegram after receiving a radio confirmation telegram from the Radio receiver module and sending the new radio transmission telegram, wherein a substep of re-generating an electrical energy by means of the energy converter preceded by the substep of generating a new radio transmission telegram or between the substep of generating a new radio transmission telegram and the substep of sending a new radio transmission telegram. This can ensure improved system security.

The above-described preferred embodiments of the actuating handle, the device and the method are particularly suitable for window or door handle monitoring systems, whereby a change or a manipulation of the actuating handle can be monitored. For example, the preferred embodiments may be used in conjunction with a security system for monitoring and securing a window or door. In addition to a preferred embodiment of an actuation handle, the safety system can include a solar energy converter for converting light energy into electrical energy with an energy store, in particular a rechargeable battery for storing the generated electrical energy. The solar energy converter can be arranged, for example, directly in the glass pane. Furthermore, the security system comprises a Vibration sensor and / or a sound transducer device such as a microphone for monitoring the window or the door for signaling an improper opening or damage to the window or the door. For this purpose, the security system further comprises a signal processing device with a radio transmitter module which can process the signal received from the vibration sensor or the acoustic transducer device and send a radio transmission telegram with information about an inadmissible opening or damage by means of the radio transmitter module. The signal processing device is coupled to the solar energy converter for supplying electrical energy. Preferably, the signal processing device is further configured to function as a repeater for a radio transmission telegram issued by the actuating handle according to a preferred embodiment.

Further features and advantages of the invention will become apparent from the following description of preferred embodiments of the invention, with reference to the figures and drawings showing essential to the invention details, and from the claims. The individual features may be implemented individually for themselves or for several in any combination in a preferred embodiment of the invention.

Various embodiments and details of the invention will be described in more detail with reference to the figures explained below. Show it:

1 is a perspective side view of an actuating handle with a device according to a preferred embodiment,

 2 is an exploded view of an actuating handle according to a preferred embodiment,

 3 is a perspective side view of a device according to a preferred embodiment,

 Fig. 4 is a side perspective view of an actuating handle with

Electronics carrier and energy converter according to a preferred embodiment, 5 is a front view of a partially disassembled actuating handle according to a preferred embodiment,

 6 is a perspective side view of an actuating handle with a device according to a preferred embodiment,

 7 is a flowchart of a method for the wireless transmission of a self-sufficient signal generated by means of an actuating handle according to a preferred embodiment, and

 8 shows a flowchart of a method for the wireless transmission of a self-sufficient signal generated by means of an actuating handle according to a preferred embodiment.

In the following description of preferred embodiments of the present invention, the same or similar reference numerals are used for the elements shown in the various figures and the same or similar, wherein a detailed repeated description of these elements is omitted.

Fig. 1 shows a perspective side view of an actuating handle 1 with a device 10 according to a preferred embodiment. The actuating handle 1 is designed in the form of a window or door handle and comprises a handle 6, which is non-rotatably connected to a longitudinally extending axis A of the actuating bolt 2 rotatably connected with an actuating pin 2 formed as a square, the four outer edges 4. The handle 6 remote from the free end of the actuating bolt 2 is adapted to engage in a locking or opening mechanism of a window or a door. By rotating the handle 6, the entrained rotational movement of the actuating bolt 2 and the engagement of the actuating bolt 2 in the mechanics, the actuating handle 1 between different predetermined functional positions such as an open position in which the window or the door is opened, a closed position in which the Window or the door is closed, and, for example, a tilted position in which the window is tiltable, to be moved. The actuating handle 1 comprises a rosette 8, through which the actuating pin 2 is passed and to which the handle 6 is rotatably movable. A rosette for an actuating handle is usually provided to attach the actuating handle to a window frame or to a door. In the preferred embodiment shown, the rosette 8 is connected on the side facing away from the handle 6 with a device 10 through which the actuating pin 2 is also passed.

Fig. 2 shows an exploded view of an actuating handle according to a preferred embodiment. The actuating handle can be, for example, an actuating handle 1 shown in FIG. As shown in detail, the device 10 comprises a housing 12 in the form of a unilaterally open trough. The housing 12 may for example be made of an injection-molded plastic. The housing 12 has two attachment openings 20, which are formed in a tub interior 22 of the housing 12 by protruding from the tub bottom 24 inner housing walls 26. The mounting holes 20 are adapted to receive from the rosette 8 or formed with the rosette 8 fasteners to allow attachment of the actuating handle 1 to a window frame or on a door. The protruding from the rosette 8 fasteners may be, for example, fastening pins or screw members, which project through the mounting holes 20 for attaching the actuating handle 1 on the window frame or the door.

Between the two fastening openings 20, the housing 12 has a trough-like section 1 3 within the tank interior 22, which is formed by further inner housing walls 26 protruding from the tank bottom 24. The trough-like section 13 comprises a first receiving section 14 for receiving an energy converter 30 and a passage 1 6 adjoining the first receiving section 14 with a second receiving section 18 for rotatably receiving a section of the actuating bolt 2. In the trough-like section 13 in the trough floor 24 a Passage opening 19 adjoining Zend formed to the second receiving portion 18 through which the free end of the actuating bolt 2 can be passed.

The inner housing walls 26 are surrounded by a the tub interior 22 delimiting circumferential outer housing 28 which is connected at the edge to the tub bottom 24. The inner housing walls 26 form at its free end-side end 27 a support or system for a carrier element 50. The free end-side end 27 has a smaller distance to the tub bottom 24 than the rectified free end-side end 29 of the outer housing wall 28. Thus, the support member 50 can be received by the tub interior 24.

The support element 50 has an outer contour corresponding to the inner contour of the outer housing wall 28, as a result of which the support element 50 covers the tub interior 24 in the state received by the housing 12. In conjunction with the outer housing wall 28, the tub interior 24 can be protected against external influences.

The carrier element 50 has passages 52 assigned to the attachment openings 20 and the passages 18 through which the actuating bolt 2 and the fastening means of the rosette 8 can be guided. The carrier element 50 carries a radio transmitter antenna 54, which can be coupled to a radio transmitter module for the wireless transmission of a radio signal. For this purpose, the carrier element 50 is formed as a printed circuit board. The arrangement of the radio transmitter antenna 54 on the carrier element 50 enables a reliable emission of the radio signal and, in the case of a design of the radio transmitter module for bidirectional communication, reliable reception of a corresponding radio signal. The surface provided with the carrier element 50 can therefore be optimally utilized for the radio transmitter antenna 54.

The carrier element 50 further comprises a coding element 60 which can be assigned to a position detection device. The coding element 60 comprises four circle-segment-like sliding contact surfaces 62 which are arranged on a circle Housing 12 facing away from the support member 50 are disposed near the intended for the actuating pin 2 passage 52. The four sliding contact surfaces 62 are electrically isolated from each other. The coding element 60 furthermore has a common sliding contact surface 64 arranged concentrically with respect to the four sliding contact surfaces 62, which can be electrically coupled to the energy converter 30 via the carrier element 50. Each of the four sliding contact surfaces 62 forms an electrically conductive contact bridge with the common sliding contact surface 64. For electrical line closure of the respective contact bridge, a contact element 70 is provided which is non-rotatably arranged on the actuating pin 2 between the support element 50 and the rosette 8. The contact element 70 is likewise assignable to the position detection device. The contact element 70 is formed by an electrically conductive spring-elastic contact disc which covers the four sliding contact surfaces 62 and the common sliding contact surface 64. The contact element 70 has on a support element 50 facing side eight resilient sliding contact fingers 74 for electrically conductive sliding contact with the common sliding contact surface 64 and two resilient sliding contact fingers 72 for electrically conductive sliding contact with one of the four sliding contact surfaces 62 depending on a rotational position of the actuating pin 2 and Grip 6 on. As a result, a reliable electrically conductive contact between the coding element 60 and the contact element 70 can be ensured.

Depending on a rotational position of the actuating handle 1, the two sliding contact fingers 72 electrically contact one of the four sliding contact surfaces 62, while the eight sliding contact fingers 74 contact the common sliding contact surface 64 in an electrically conductive manner. As a result, in the case of a current flow based on generation of an electrical energy of the energy converter 30, an electrical line connection is established between one of the four sliding contact surfaces 62 and the common sliding contact surface 64. By assigning the four sliding contact surfaces 62 to a respective functional position or position of the actuating handle 1, a position of the actuating handle 1 can be reliably detected and transmitted by means of the radio transmitter module. Further sliding contact surfaces and to be attributed sliding contact fingers for a more reliable detection of the position of the actuating handle 1 are conceivable.

As further shown in FIG. 2, an actuating adapter element 40 for the actuating bolt 2 can be provided. The actuating adapter element 40 is formed from a plastic-containing material and has a disc-shaped base 41, from which a four-sided receiving element 42 protrudes with a receiving opening 43 for receiving a portion of the actuating bolt 2. The four-sided receiving element 42 has pronounced outer edges 44 at its corners. Two adjacent outer edges 44 are connected to each other via a side wall, which is concave to the receiving opening 43 with a center between the outer edges 44 arranged. The base 41 has an outer contour corresponding to the passage opening 19, wherein the base 41 is rotatably receivable by the passage opening 19. In a state received by the housing 12, the four-sided receiving element 42 protrudes into the interior of the housing 12. The base 41 thereby comes into abutment with an end face 34 projecting from an inner housing wall 26 into the passage 18, whereby the actuating adapter element 40 can be fixed in the passage opening 19 in the direction of the housing 12.

FIG. 3 shows a perspective side view of a device 10 according to a preferred embodiment in a state receiving the carrier element 50 and the contact element 70. The support member 50 is completely received by the housing 12, wherein the support member 50 is disposed between the tub bottom 24 and the free end-side end 29 of the outer housing wall 28 comprehensive level. In the state which is unobstructed with the rosette 8, the contact element 70 rests on the carrier element 50 in such a way that the contact element 70 with its main body, from which the sliding contact fingers 72, 74 protrude, is arranged outside the free end-side end 29 wherein the sliding contact fingers 72, 74 intersect this plane for electrically conductive contact with the coding element 60. In an associated with the rosette 8 state of the housing 12, the contact element 70 is resiliently moved toward the support member 50, whereby a reliable contact between the sliding contact fingers 72, 74 and the sliding contact surfaces 62, 64 can be ensured.

As further shown with Fig. 3, the housing 1 2 on the side facing away from the support member 50 two mounting pins 15 for fixing the device 10. Each of the fastening pins 15 is formed coaxially with one of the two fastening openings 20 and arranged such that they can be engaged in fastening openings of, for example, windows or doors, which are provided for fastening commercially available grip devices. Thus, in connection with the attachment openings 20 of the housing 12, the device 10 can be used in a simple manner in commercial grip devices.

4 shows a perspective side view of an actuating handle with carrier element 50 and energy converter 30 according to a preferred exemplary embodiment. The actuating handle can be an actuating handle 1 shown in FIGS. 1 and / or 2. In this preferred exemplary embodiment, the carrier element 50 embodied as a printed circuit board comprises the radio electronics and at least one logic module electrically coupled thereto. The logic module can be part of the radio electronics. The logic module coupled to or integrated into the radio electronics, in conjunction with the coding element 60 and the contact element 70, detects the actuation or the actuating direction or the position of the actuation handle 1 and provides a signal with the information about the actuation, the direction of actuation or the position, wherein the signal may be a coded signal. The radio electronics are further electronic components, by means of which the signal coming from the at least one logic module can be converted into a radio signal with information about the actuation of the actuating handle 1 or with information about a detected actuating direction or position of the actuating handle 1 and can be transmitted wirelessly.

The energy converter 30 is a previously known from the document DE 10 201 1078 932 A1 induction generator with a switching element 32 which is coupled to a coil assembly 34 and a magnet assembly 36 such that the Magnetan- Order 36 by means of actuation of the switching element 32 to the coil assembly 34 is movable. The switching element 32 is formed of a leaf spring device. The leaf spring device is designed to first store the mechanical energy transmitted by the actuating pin 2 by means of the outer edge 4 or the actuating adapter element 40 shown in FIG. 2 by means of the outer edge 44 and from a predetermined switching point to the magnet assembly 36 to move the same leave. The switching point is reached as soon as the amount of stored energy exceeds at least the amount of the magnetic self-holding forces between the magnet arrangement 36 and the coil arrangement 34.

The coil assembly 34 comprises a U-shaped soft magnetic coil core whose respective leg is surrounded by an induction coil. The magnet assembly 36 is linearly movably disposed at the free ends of the coil core legs and includes an E-shaped magnetizable pole piece assembly, the outer legs of the E-shaped pole piece assembly having a magnetic pole of a permanent magnet enclosed by the E-shaped pole piece assembly and the middle leg of the E -shaped pole piece arrangement are magnetically connected to the other magnetic pole of the permanent magnet. The free leg ends of the E-shaped pole piece arrangement are magnetically coupled to the free leg ends of the coil arrangement 34 via a magnetizable sliding plate arranged between the pole piece arrangement and the coil arrangement 34. In a first movement end position of the magnet assembly 36 is a free end of the outer leg of the pole piece a free leg end of the coil assembly 34 and the free end of the middle leg of the pole piece opposite the other free leg end of the coil assembly 34 each with the interposition of the common sliding plate. In this first movement end position, a magnetic flux with a first direction is generated in the coil arrangement 34. In the second movement end position of the magnet assembly 36, the free end of the other outer leg of the pole piece assembly is a free leg end of the coil assembly 34 and the free end of the middle leg of the pole piece the other free leg end of the coil assembly 34 each with the interposition of the common sliding plate across from. In this second movement end position, a magnetic flux with a second direction is generated in the coil arrangement 34, which is opposite to the first direction. The magnetic flux direction reversal is effected by a movement of the magnet assembly 36 from the first to the second end of travel position or vice versa, whereby a corresponding induction voltage is induced in the respective induction coil.

The energy converter 30 has on the side facing away from the magnet assembly 36 of the coil assembly 34 electrical contacts 37, which are electrically connected to a further circuit board 38 by means of plug contact. The further printed circuit board 38 is electrically coupled to the carrier element 50. In this preferred embodiment, the further circuit board 38 is adapted to commutate the individual inductors of the coil assembly 34. According to a further preferred embodiment, the further printed circuit board 38 carries some or all components of the radio electronics and / or the at least one logic module.

Fig. 5 shows a front view of a partially disassembled actuating handle according to a preferred embodiment. The actuating handle can be an actuating handle 1 as described above. In detail, the side of the carrier element 50 facing the device 10 is shown with the energy converter 30. The support member 50 is bordered in this view by housing walls of the rosette 8, wherein a respective rosette fastening pin 9 projects through the two outer passages 52, which engages in an assembled state with the device 10 in the associated attachment opening 20. The central passage 52 is penetrated by the free end of the actuating bolt 2, wherein the actuating pin 2 is freely rotatably received by the central passage 52.

The actuating pin 2 is shown in a lying between two functional positions of the actuating handle 1 movement state, wherein the actuating pin 2 is carried by pivoting of the handle 6 along a direction pointing in the Blattebenendraktivität counterclockwise direction of rotation B. The actuating pin 2 touches with one of its outer edges 4, the switching element 32. If the actuating pin 2 is further rotated along the direction of rotation B, a compressive force transmitted by the outer edge 4 acts on the switching element 32, which is pressed by its resilient design in the direction of the coil assembly 34 without the magnet assembly 36 moves. The outer edge 4 approaches during the rotational movement of the actuating bolt 2 continuously until a coil assembly 34 closest point is reached, from which the outer edge 4 in a further rotational movement of the actuating bolt 2 along the rotational direction B of the coil assembly 34 shown. The magnet arrangement 36 is still held in its first end movement position due to the magnetic self-holding forces acting between the magnet arrangement 36 and the coil arrangement 34. The force acting on the switching element 32 mechanical force in the form of a compressive force is initially stored during the rotational movement of the actuating bolt 2. As soon as the amount of stored energy by means of further rotation of the actuating bolt 2 or the approach of the outer edge 4 to the coil assembly 34 exceeds the amount of magnetic self-holding forces, the magnet assembly 36 is abruptly moved from the first movement end position shown along a direction of movement C to the second end movement position. The abrupt movement of the magnet arrangement 36 preferably takes place before or alternatively preferably at the latest when the outer edge 4 reaches the locally closest point to the coil arrangement 34. The actuating pin 2 is in this case in an operating position. This movement causes a magnetic flux direction reversal in the coil assembly 34, thereby inducing a voltage in the induction coils. The electrical energy generated thereby is transmitted via the plug contacts 37. If the actuating pin 2 is rotated counterclockwise in the clockwise direction to the direction of rotation B, a similar actuation of the switching element 32 takes place.

According to a preferred embodiment, the energy converter 30 is monostable, in other words, self-resetting. For this purpose, the switching element 32 is preferably designed such that it is in the first movement end position of the magnet assembly 36 in a relaxed state and in the second movement end position in an elastically tensioned state. Once the amount of the outer edge 4 by further rotation of the actuating bolt. 2 acting on the switching element 32 compressive force is smaller than the amount of self-return spring force of the switching element 32 and the amount of self-restoring force at the same time greater than the amount of magnetic self-holding force, the magnet assembly 36 is abruptly moved back from the second end movement position in the first movement end position, creating a re-induction voltage becomes.

According to an alternative preferred embodiment, the energy converter 30 is formed bistable. For this purpose, a magnet assembly 36 resetting return spring means is provided, which has an operable end that schaltbetätig- bar in the rotational path of the outer edge 4 after actuation of the switching element 32 and after actuation until a renewed actuation of the switching element 32 outside the rotational path of the outer edge. 4 remains. The operable end of the return spring means may be arranged in the direction of rotation of the actuating bolt 2 and the outer edge 4 upstream or downstream of the switching element 32 in the rotational path of the outer edge 4 introduced. Thus, depending on a needs-based design of the actuating handle 1, a double operation to obtain a high energy yield or a single operation of the energy converter 30 during a rotational movement of the actuating bolt 2 or during the movement of the actuating handle 1 from a functional position to another functional position.

6 shows a perspective side view of an actuating handle with a device according to a further preferred embodiment. The actuating handle and the device can each be one of the above. The actuating handle 1 according to this preferred embodiment additionally has an outer antenna element 80 in the form of a rod antenna, which is passed through an opening 1 1 of the device 10 and is electrically coupled to the radio electronics within the device 10. In this preferred embodiment, the opening 1 1 is disposed adjacent to the fastening tap 15. Thus, the outer antenna element 80 can protrude, for example, into a cavity of a window profile, whereby the outer antenna element 80 is not visible to a user of the actuating handle 1. The Opening 1 1 may be provided at a different location of the device 10 as needed. By means of the outer antenna element 80, a radio transmission characteristic of the actuating handle 1 can be improved.

7 shows a flow diagram of a method 1000 for the wireless transmission of a self-sufficient signal generated by means of an actuating handle according to a preferred embodiment. The actuating handle can be, for example, a pre-described actuating handle 1. The method 1000 includes a step of rotating 1100 the at least one outer edge 4; 44 from an initial position in the direction of an end position via a switch 30 which actuates the energy converter operatively. The rotation step 1100 has a partial step of generating 1 1 10 an electrical energy by means of the energy converter 30. The actuating handle 1 is in an actuating position in this sub-step. This sub-step is followed by a substep of generating 1 120 a radio transmission telegram with information about the actuation of the actuating handle 1. In this substep, the electrical energy generated by the energy converter 30 is used by the electronics connected to the energy converter 30 to generate the radio transmission telegram. The radio transmission telegram itself can be regarded as information about the actuation of the actuating handle 1. Alternatively or additionally, a polarity of the electrical energy generated by the energy converter 30 can be used by the electronics for detecting an actuation direction of the actuating handle 1, wherein the radio transmission telegram not only information about the actuation of the actuating handle, but also information about an actuation direction of the detected Actuation includes. This sub-step is followed by a substep of the sending 1 130 of the generated radio transmission telegram.

According to a further preferred embodiment of the method 1000, the energy converter 30 is designed to be monostable or bistable, wherein the rotation step 1100 also follows the substep of the sending 1 130 subsequent substeps in the order of regenerating 1 140 an electrical energy by means of the energy converter 30 and the repeated one Sending 1 150 of the has radiated transmit telegram. This can increase transmission reliability.

According to another alternatively preferred embodiment of the method 1000, the rotation step 1 100 further comprises the substep of the sending 1 130 subsequent substeps in the order of generating a new radio transmission telegram 1 1 60 with information about the operation of the actuating handle 1 and the sending 1 170 the new radio transmission telegram, wherein a re-generating sub-step 1 140; 1 1 65 an electrical energy by means of the energy converter the sub-step of generating 1 1 60 preceded by a new radio transmission telegram or between the substep of generating 1 1 60 a new radio transmission telegram and the sub-step of sending 1 170 of the new radio transmission telegram can be provided. This can be selected as needed, for example, depending on the energy requirements of the sub-steps for generating the radio transmission telegram and the new radio transmission telegram or other energy-taking aspects.

According to a further preferred embodiment of the method 1000, the actuating handle comprises an electrical position detection device coupled to the radio transmitter module for electrically detecting a position of the actuating handle. The actuation handle with the position detection device can be, for example, a previously described actuation handle 1. In the method according to this preferred embodiment, the rotation step 1 100 comprises a step of closing 1 105 preceding the substep of generating 1 120 a radio transmission telegram; 1 1 15 of a position of the actuating handle associated contact bridge for detecting the position of the actuating handle 1, wherein the information of the radio transmission telegram contains information about the position of the actuating handle 1. In this case, the closing step 1 105; 1 1 15 already preceded by the sub-step of generating 1 1 10 an electrical energy or between the sub-step of generating 1 1 10 and the substep of generating 1 120 a radio transmission telegram be arranged. Thus, in addition to information about the operation of the actuating handle 1 at the same time information about the detected position of the Actuating handle 1 are transmitted wirelessly. Condition monitoring of the actuating handle can be simplified thereby.

According to a further preferred embodiment of the method 1000, the actuating handle in addition to a monostable or bistable energy converter comprises an electrical energy storage, such as a capacitor, the rotation step 1 100 provided between the substep of generating 1 120 a radio transmission telegram and the substep of sending 1 130 of the radio transmission telegram Sub-step of storing 1 124 an excess electrical energy and a sub-step following this sub-step of re-generating 1 126 electrical energy by means of the energy converter has. This preferred method has the advantage of high energy availability, as a result of which energy-consuming radio protocols can be transmitted more reliably.

According to a further preferred embodiment of the method 1000, the actuating handle has a radio transmitter module for bidirectional communication with a radio receiver module. 8 shows by way of example a flow chart of this preferred method 1000 on the basis of the essential substeps of generating 1 1 10 an electrical energy, generating 1 120 of a radio transmission telegram and sending 1 130 of the radio transmission telegram. In this case, the rotation step 1 100 further comprises the sub-step of the sending 1 130 subsequent sub-steps in the order of switching 1 131 of the radio transmitter module in a receive mode and the receiving 1 132 132 a radio confirmation message from the radio receiver module by the radio transmitter module. This sub-step is followed either by the substeps in the order of re-generating 1 133 an electrical energy, generating 1 134 a new radio transmission telegram and sending 1 136 the new radio transmission telegram or generating 1 134 a new radio transmission telegram, regenerating 1 135 an electrical energy and sending 1 136 of the new radio transmission telegram. In this case, a sub-step of switching the radio transmitter module into a transmission mode can take place before or after one of the sub-steps following the sub-step of receiving 1 132 a radio-confirmation telegram. By means of bidirectional communication, high system security or manipulation security can be achieved. be ensured. Because upon receipt of only one of the two transmitted radio transmission messages may be generated by the radio receiver module, which may be a component of a state monitoring device or a control unit, an error message.

Between the individual sub-steps of the above-described preferred method 1000 further sub-steps may well be provided. For example, according to a further preferred embodiment of the method for an actuating handle with a position detection device, a sub-step of interrogating a position of the actuating handle by an electronic logic device downstream of the substep of generating an electrical energy and one of the (re) generating a (new) radio transmission telegram substeps be preceded. Alternatively, individual substeps may follow one another directly, in other words without further intermediate steps. Furthermore, with the partial step of sending a radio transmission telegram, a single or multiple transmission of the radio transmission telegram can take place. This applies equally to the substeps of resending the radio transmission telegram or sending a new radio transmission telegram. This can further improve transmission security.

The embodiments described and shown in the figures are chosen only by way of example. The dimensions of the geometric shape of the elements described are only examples and can be adjusted accordingly.

REFERENCE CHARACTERS

Actuating handle

 actuating pin

 outer edge

 grip

 rosette

 Rose fixing pins

 detection device

 opening

 casing

tub-like section

first receiving section

 fastening pins

 passage

second receiving section

 Port

 fastening opening

 When interior

 Wannenboden

inner housing wall

front end of the inner housing wall outer housing

frontal end of the outer housing wall

energy converters

 switching element

 coil assembly

 magnet assembly

 plug contact

further printed circuit board

 Operation adapter element

 support element

passage 54 radio transmitter antenna

 60 coding element

 62 sliding contact surface

 64 common sliding contact surface

 70 contact element

 72, 74 Slip contact fingers

 80 outdoor antenna element

1000 method for the wireless transmission of a self-sufficient signal generated

 1 100 step of turning

 1 105, 1 1 15 partial step of closing a contact bridge

 1 1 10 sub-step of generating an electrical energy

 1 120 sub-step of generating a radio transmission telegram

 1 124 sub-step of storing an electrical energy

1 126, 1 133, 1 135,

 1 140, 1 1 65 sub-step of re-generating an electrical energy

1 130 Sub-step of sending the radio transmission telegram

 1 131 Sub-step of switching the radio transmitter module to receive mode

 1 132 Sub-step of receiving a radio confirmation telegram 1 134, 1 1 60 Sub-step of generating a new radio transmission telegram 1 136, 1 170 Sub-step of sending the new radio transmission telegram

1 150 Sub-step of resending the radio transmission telegram

A longitudinal axis

 B direction of rotation

 C movement direction of the magnet arrangement

Claims

claims

1 . Device (10) for an actuating handle (1) comprising an actuating bolt (2) which has at least one section along its longitudinal axis (A), which has at least one outer edge (4; 44) peripherally, the device (10) comprising a housing (10). 12) with a first receiving portion (14) for receiving an energy converter (30) for the electrical supply of a radio transmitter module by converting mechanical energy into electrical energy, and a passage (1 6) for the actuating bolt (2), wherein the passage (1 6) has a second receiving portion (18) for rotatably receiving the portion of the actuating bolt (2) having the at least one outer edge (4; 44), characterized in that the first receiving portion (14) is disposed adjacent to the passage (16), wherein in a receiving state of the energy converter (30), a switching element (32) of the energy converter (30) in a rotational path of the at least one n outer edge (4; 44) and by means of the at least one outer edge (4, 44) can be operatively actuated during a rotational movement of the actuating bolt (1).

2. Device (10) according to claim 1, characterized in that the housing (12) has a trough-like portion (13) which forms the first receiving portion (14) and the passage (1 6) with the second receiving portion (18), wherein the passage (1 6) in the passage direction has a formed in the tub bottom passage opening (19).

3. Device (10) according to claim 2, characterized in that the housing (12) has an abutment portion (27) for abutment with a at least one radio transmitting antenna (54) supporting the carrier element (50) which in an investment state with the housing (12 ) covers a at least the passage (1 6) surrounding portion of the trough-like portion (13).

4. Device (10) according to one of claims, characterized by a with the actuating bolt (2) rotatably connectable and by the second receiving portion (18) receivable actuating adapter element (40), which at least one outer edge (44) on the periphery of the actuating bolt ( 2) trains.

5. Device (10) according to one of the preceding claims, characterized by a couplable to the energy converter and the radio transmitter Positionserfas- sungseinrichtung for electrically detecting a position of the actuating handle (1), wherein the position detection means rotatably coupled to the housing (12) and the Actuating pin (2) encompassable coding element (60) and with the actuating pin (2) rotatably coupled electrically conductive contact element (70), wherein the coding element (60) with the energy converter (30) is electrically coupled and at least one of an engageable position of the actuating handle (1) associated electrically conductive contact bridge (62, 64), which is switchable between an open, electrically non-conductive and a closed, electrically conductive state by means of the contact element (70), wherein different positions associated contact bridges (62, 64) from each other electrically iso When taking a predetermined position of the actuating handle (1), the at least one of the position associated contact bridge (62, 64) is electrically switched or closed, while the other contact bridges (62, 64) are switched electrically non-conductive or open ,

6. Device (10) according to claim 5, characterized in that the coding element (60) for each of the ingestible positions of the actuating handle (1) at least one contact portion (62) and one of these contact portions (62) electrically isolated and arranged concentrically to another common contact portion (64), wherein the different positions of the actuating handle (1) associated contact portions (62) are electrically insulated from each other, and that the contact element (70) preferably at least a first contact (74) for electrically conductive contacting the common contact portion (64 ) and having a first contact (74) electrically conductively coupled to the second contact (72) for electrically conductive contacting one of the contact portions (62) in response to a position of the actuating handle (1).

7. Device (10) according to claim 6, characterized in that the coding element (60) is arranged on a printed circuit board (50), the contact sections (62) and the common contact section (64) each being characterized by sliding contact surfaces. are formed, and that the first (74) and second contact (72) are formed by projecting from the contact element (70) sliding contact fingers.

8. actuating handle (1) comprising a handle (6), a rotatably coupled to the handle (6) actuating pin (2), a device (10) according to one of the preceding claims, an energy converter (30) for converting mechanical energy into electrical Energy and a radio transmitter module coupled to the energy converter (30) for wirelessly transmitting a radio signal, wherein the energy converter (30) supplies the radio transmitter module with electrical energy.

9. A method (1000) for the wireless transmission of a self-powered signal by means of an actuating handle (1), wherein the actuating handle (1) comprises a rotatable actuating pin (2) with at least one outer edge (4; 44), in whose rotary path a switching element (32 ) of an energy converter (30) for converting mechanical energy into electrical energy such that a rotational movement of the actuating bolt (2) activates the energy converter (30) in a switching manner by actuating the switching element (32) through the at least one outer edge (4; 44) wherein the generated electrical energy supplies a radio transmitter module wirelessly transmitting a radio signal coupled to the energy converter (30), the method (1000) comprising a step of rotating (1100) the at least one outer edge (4; 44) from a home position Direction of an end position via the energy converter (30) switching actuated actuation wherein the rotation step (1100) comprises a substep of generating (1 1 10) an electrical energy by means of the energy converter (30), a subsequent substep of generating (1120) a radio transmission telegram with information about the actuation of the actuation handle (1 ) and a subsequent sub-step of sending (1 130) of the radio transmission telegram comprises.

10. The method (1000) according to claim 9, wherein the energy converter (30) is monostable or bistable, characterized in that the rotation step (1100) further comprises the substep of the sending (1130) subsequent substeps in the Order of re-generating (1 140) of electrical energy by means of the energy converter (30) and the repeated transmission (1 150) of the generated radio transmission telegram.

1 1. The method (1000) according to claim 9, wherein the energy converter (30) is monostable or bistable, characterized in that the rotation step (1100) further comprises substeps of the sending (1130) subsequent to the steps of regenerating (1 140) of an electrical energy by means of the energy converter, the generation (1 160) of a new radio transmission telegram with information about the actuation of the actuating handle (1) and the sending (1 170) of the new radio transmission telegram has.

12. The method (1000) according to any one of claims 9 to 1 1, wherein the actuating handle (1) comprises a device (10) coupled to the radio transmitter module electrical position detecting means for electrically detecting a position of the actuating handle (1), wherein the position detecting means a comprising a housing (12) of the device (10) rotatably coupled and the actuating pin (2) surrounded by a coding element (60) and with the actuating pin (2) rotatably coupled electrically conductive contact element (70), wherein the coding element (60) with the Energy converter (30) is electrically coupled and at least one of an engageable position of the actuating handle (1) associated electrically conductive contact bridge, which is switchable between an open, electrically non-conductive and a closed, electrically conductive state by means of the electrical contact element (70), wherein different position en assigned contact bridges (62, 64) are electrically isolated from each other, wherein when taking a predetermined position of the actuating handle (1) the at least one of the position associated contact bridge (62, 64) is electrically switched or closed, while the other contact bridges (62 , 64) are electrically non-conducting or open, characterized in that the rotation step (1100) precedes the sub-step of generating (1120) a radio transmission telegram sub-step of closing (1 105; 1 1 15) of a position of the actuating handle (1) associated with the contact bridge (62, 64) for detecting the position of the actuating handle (1), wherein the information of the radio Send telegram contains information about the position of the actuating handle (1).

The method (1000) according to claims 12 and 9, wherein the energy converter is monostable or bistable, characterized in that the radio transmitter module is designed for bidirectional communication with an associated radio receiver module, wherein the rotation step (1100) further corresponds to the substep of Sending (1 130) subsequent sub-steps in the order of generating (1 134) a new radio transmission telegram after receiving a radio confirmation telegram from the radio receiver module and sending (1 136) of the new radio transmission telegram, wherein a substep of re-generating (1 133; 1 135) of an electrical energy by means of the energy converter (30) preceded by the substep of generating (1 134) a new radio transmission telegram or between the substep of generating (1 134) a new radio transmission telegram and the substep of sending (1 136) a new radio transmission telegram is.

14. Method (1000) according to claim 9, wherein the energy converter (30) is designed to be monostable or bistable, and wherein the actuating handle (1) comprises an electrical energy store, characterized in that the rotation step (1100) comprises an electric energy store the partial step of generating (1 120) a radio transmission telegram and the sub-step of sending (1 130) of the radio transmission telegram provided substep of storing (1 124) an excess electrical energy.