Patent Description:
Bicycle transmission systems are known. Bicycle transmission system can include a gear shifting mechanism. The gear shifting can be discrete or continuously variable. In some varieties, a gear shifting mechanism is included in or attached to a driven axle of the bicycle. It is known to actuate gear shifting by electronically actuated actuators. Electronically actuated actuators can be cumbersome in that power supply and/or signal supply needs to be extremely robust and stable to avoid malfunction of the gear shifting mechanism. Yet in many applications weight and or space allowed for electronically actuated actuators and/or power and/or signal supply is limited. In general supplying power and/or signals to/from electric components included in or attached to a driven axle of a bicycle can be cumbersome.

<CIT> discloses a bicycle according to the preamble of claim <NUM>. The bicycle is comprising a transmission having two switchable drives between a driver body on which rear sprockets are positioned and a wheel hub of a rear wheel. The bicycle is also provided with actuation means for switching between drives and operating means for operating the actuation means. The bicycle comprises only a single front sprocket. The actuation means of the transmission are embodied in an electrical version and the operating means are electrically coupled to the actuation means.

<CIT> is priort art in the sense of Article <NUM>(<NUM>) EPC and discloses a bicycle including a frame with a fork, the fork having dropouts between which a wheel axle is mounted. The wheel axle includes a sensor and/or an electric component arranged to be connected to a control element. A detachable electric connection is provided between the sensor and/or electric component and the control element. The detachable electric connection includes a short range wireless connection.

It is an object to obviate, or at least diminish, one or more of the disadvantages mentioned above.

Preferred embodiments are defined by dependent claims <NUM> to <NUM>.

According to an aspect is provided a bicycle including a frame with a fork, the fork having dropouts between which a wheel axle is mounted, a thru-axle arranged for positioning and/or holding the wheel axle between the dropouts, and a control element. The wheel axle includes a switchable transmission between a driver and a wheel hub of a wheel, wherein the switchable transmission includes a switching mechanism including an electric actuator arranged to be connected to the control element. A detachable electric connection is provided between the electric actuator and the control element. The detachable electric connection is positioned between electric actuator and the control element. The detachable electric connection includes an electrical contact connection, having first electrical contacts mounted on the thru-axle and second electrical contacts mounted on the wheel-axle or components thereof. The bicycle further includes a wireless receiver included in or attached to the thru-axle for wirelessly receiving a signal from the control element. The wireless receiver included in or attached to the thru-axle is hereinafter also referred to as second receiver or second wireless receiver. The electrical contact elements can include one or more electrical wires, magnetic contact elements, or mechanical contact elements.

According to an aspect the control element can include an electronic and possibly magnetic switch. The electronic and possibly magnetic switch can be arranged to be manually operated by a rider, such as with a shifter or one or more shifters or buttons. For example if the rider presses one shifter or two shifters at the same time the electric actuator can be actuated. Thus, a familiar feel can be retained for the rider for operating the switch. The electronic switch can include one or more inductive, capacitive, magnetic or optical sensors for determining the switch position. the sensor or sensors can be arranged to discriminate two or more unique switch positions of the switch. The electronic and possibly magnetic switch can be arranged to be manually operated by the rider via a cable, such as a Bowden cable, between the shifter or one or more shift buttons and the switch. Thus familiar shifting mechanisms can be retained for the rider. The electronic and possibly magnetic switch can be arranged to be manually operated by the rider via the cable between a FRONT / LEFT shifter or shift button and the switch.

The switch can be positioned in a housing on the handle bars of the bicycle. The switch can be positioned, e.g. in a housing, in the handle bars or frame of the bicycle. The switch can be positioned in a housing attached to a cable sheath of controls of a hydraulic or mechanical brake and/or a, e.g. rear, derailleur.

Optionally, the switch is positioned in a housing on the handle bars of the bicycle and the Bowden cable is connected to a spring in the housing. The spring can give feedback force to the shifter which is connected to the other side of the Bowden cable.

Optionally, the switch is arranged to be actuated by a Bowden cable. The Bowden cable can be connected to a spring in a housing which spring gives feedback to the shifter which is connected to the other side of the Bowden cable. A mechanism can be connected between the Bowden cable and the spring which transmits and/or amplifies the force of the spring. The mechanism can be arranged to convert a translation of the Bowden cable into a translation, such as a compression, of the spring. Alternatively, or additionally, the mechanism can be arranged to convert a translation of the Bowden cable into a rotation, such a compression, of the spring, e.g. a torsion spring. The mechanism and/or the spring can be arranged to limit a translation of the Bowden cable. The limitation can adjustable, e.g. from the outside of the housing. The Bowden cable may extend through the housing and is accessible at an end thereof.

Optionally, the housing includes an indicator, in or on the housing, for indicating a battery status, and optionally a control for activating the indicator.

An electronic switch signal from the switch is wirelessly sent to the thru-axle via a transmitter and the receiver. The switch and a transmitter for transmitting the signal can be positioned in a housing on the handle bars of the bicycle.

Optionally, the switch and the transmitter are positioned in a housing on the handle bars of the bicycle and the Bowden cable is connected to a spring in the housing. The spring can give feedback force to the shifter which is connected to the other side of the Bowden cable.

Optionally, an energy storage element is positioned in the housing. The energy storage element can power the transmitter in case of wireless transmission of the electronic switch signal from the switch to the thru-axle. The energy storage element can power the actuator in case of wired connection from the switch via the thru-axle to the wheel axle.

Optionally, an actuator controller is positioned in the housing.

Optionally, an energy storage element is positioned in the thru-axle. The energy storage element can power the receiver in case of wireless transmission of the electronic switch signal from the switch to the thru-axle. The energy storage element can power the actuator in case of wired connection from the thru-axle to the wheel axle. Optionally, the wheel axle is free from energy storage. It will be appreciated that exchanging or recharging an energy storage element at or in the wheel axle can be more cumbersome than exchanging or recharging an energy storage element at the thru-axle, or at the housing.

Optionally, the thru-axle includes an actuator controller arranged for controlling the electric actuator on the wheel axle.

According to an aspect a first energy storage element, such as a battery, is included in or attached to the thru-axle. A second energy storage element, such as a battery, can be included in or attached to the wheel axle.

Optionally, the first energy storage element has a storage capacity that is at least ten (<NUM>) times the storage capacity of the second energy storage element.

Optionally the system is arranged for charging the second energy storage element using energy stored in the first energy storage element. Hence, the second energy storage element can be maintained in a state of sufficient charge. Thereto energy can be transferred from the first energy storage element to the second energy storage element via the first and second coils.

The system can be arranged for providing energy to the actuator and/or a sensor included in or attached to the wheel axle from the second energy storage element. The system can be arranged for providing energy to the actuator and/or a sensor included in or attached to the wheel axle from the first energy storage element. This can also be done via the electrical contacts.

The system can be arranged for transferring a signal determining an actuation direction and/or amount for the actuator included in or attached to the wheel axle via the electrical contacts. The system can be arranged for transferring a signal from the control element (e.g. on the handlebars) to the thru-axle. Signal transfer from the control element (e.g. on the handlebars) to the thru-axle is wireless. The wireless receiveris included in or attached to the thru-axle. The wireless receiver is herein also referred to as second transceiver or second receiver, nevertheless still covering the possibility of it being a transceiver. The second wireless receiver can be mounted to the thru-axle so as to extend outside the wheel axle and outside the frame to reduce disturbance of wireless communication by metal parts of the wheel axle and/or frame. The system can be arranged for providing the second receiver with electric power from the first energy storage element.

It will be appreciated that when exchanging the wheel (and thus the wheel axle), the thru-axle can remain with the frame so that a pairing between the control element and the second receiver in/on the thru-axle can be maintained. Therefore, when exchanging the wheel no time is lost on pairing the control element with the replacement wheel.

The pairing of the control element, e.g. of a wireless transmitter of the control element, with the second receiver in/on the thru-axle can be performed, e.g. once when matching the thru-axle with the frame.

It will be appreciated that it suffices to recharge the first energy storage element, e.g. by external charging, e.g. using an electric charging apparatus. The second energy storage element can be charged from the first energy storage element. Since the first energy storage element is included in or attached to the thru-axle, it can easily be charged e.g. via a connector on the thru-axle. Charging can be performed while leaving the thru-axle in the bicycle or with the thru-axle removed from the bicycle.

The system can be arranged such that the first energy storage element automatically charges the second energy storage element so that the second energy storage element can always provide the actuator with electric power. In this way also the user never needs to charge or replace the second energy storage element. This provides a big advantage as the second energy storage element can be difficult to reach since it is mounted in or attached to the wheel axle, and because parts in the neighborhood of the second energy storage element can rotate (e.g. wheel hub and/or driver).

According to an aspect an electric generator is included in or attached to the wheel axle for charging the second energy storage element. The generator can be driven by rotation of the hub and/or driver. Alternatively, or additionally, the generator can be arranged fro generating electric energy on the basis of vibrational energy.

Optionally the first energy storage element includes one or more, such as two, AAAA (LR61) batteries that can be rechargeable and/or replaceable.

According to an aspect a control unit can be included in or on the thru-axle. The control unit can be arranged for receiving control signals from the control element.

According to an aspect an actuator control unit is included in or attached to the wheel axle for controlling the actuator of the wheel axle. The actuator control unit can be arranged for controlling an electric current direction and/or an electric current amount and/or an electric current duration to the actuator. The actuator control unit can also be arranged for controlling a current, e.g. limiting a current to the actuator.

Optionally the actuator control unit is mounted on and/or in the thru-axle.

Optionally the actuator control unit is connected via first electrical contacts on the thru-axle to second electrical contacts on the wheel axle.

Optionally there is no second energy storage on the wheel axle.

Optionally, the one or more of the actuator, the actuator control unit, and the second energy storage element are mounted to a bracket, the bracket forming part of or being connected to the wheel axle. Hence, the electronics can easily be mounted to the wheel axle.

The control element can be an electronic switch actuatable with a rotary button or push button. Optionally, the electronic switch is arranged to be actuated via a cable extending from a mechanical switch (shifter), e.g. mounted on the handlebars. Hence, standard mechanical switches (shifters) can be used for actuating the electric component on/in the wheel axle.

Providing the electrical contacts between the thru-axle and the wheel axle provides that no pairing procedure is required.

In case an electrically switching rear derailleur is used, a battery used for the rear derailleur can then supply power to a third receiver of the rear derailleur, the actuator of the rear derailleur and/or the actuator controller, and even to the electric actuator. Hence, fewer batteries are required.

According to an aspect the electric actuator has only two modes between which can be switched. The electric actuator can e.g. have only two positions between which can be switched. Optionally, the actuator is arranged such that the switching direction is determined by an electric current direction (or voltage polarity) to the actuator. Hence it can be possible to switch from one mode to the other by reversing the current direction (or voltage polarity). Hence, a separate control signal may not be required for determining the switching direction.

It will be appreciated that any one or more of the above aspects, features and options can be combined. It will be appreciated that any one of the options described in view of one of the aspects can be applied equally to any of the other aspects. It will also be clear that all aspects, features and options described in view of the wheel axle apply equally to the bicycle, and vice versa, including use of electrical contacts instead of the coils.

The invention will further be elucidated on the basis of exemplary embodiments which are represented in a drawing. The exemplary embodiments are given by way of non-limitative illustration. It is noted that the figures are only schematic representations that are given by way of non-limiting example. <FIG> and <FIG> (optional) show an embodiment comprising electrical contacts mounted on the thru-axle and wheel axle and a wireless receiver included in or attached to the thru-axle in accordance with claim <NUM>.

<FIG> shows a schematic cross section of a wheel axle assembly <NUM>. In <FIG> the wheel axle assembly <NUM> is mounted in a frame <NUM> of a bicycle. Here, the wheel axle assembly <NUM> is mounted between two dropouts <NUM> of the frame <NUM>. The wheel axle assembly includes a thru-axle <NUM> for securing the wheel axle assembly <NUM> to the frame <NUM>. The thru-axle <NUM> here is inserted through the hollow axle <NUM>. The wheel axle assembly includes a hub <NUM>. The wheel axle assembly includes a driver <NUM> for driving the hub in rotation. Here the driver <NUM> includes a cassette <NUM> including a plurality of sprocket gears.

In this example, the driver <NUM> is connected to the hub <NUM> via a transmission <NUM>. The transmission is arranged to selectively be in a first mode and in a second mode. In the first mode a transmission ratio of the transmission <NUM> is different from a transmission ratio in the second mode. Here, in the first mode the transmission ratio is unity (output rotation speed at the hub equals input rotation speed at the driver). Here, in the second mode the transmission ratio is a speed reduction (output rotation speed at the hub is smaller than the input rotation speed at the driver). Hence, the transmission can e.g. mimic the functioning of a front derailleur.

In <FIG> the wheel axle assembly includes an electric component <NUM>. Here, the electric component <NUM> is an electric actuator arranged for actuating the transmission to switch from the first mode to the second mode and vice versa. The actuator can e.g. include a processor 16A and a motor 16B. It will be appreciated that the electric component can also e.g. be a sensor, such as a speed sensor.

For operating the actuator <NUM>, and not according to claim <NUM>, a first receiver <NUM> is placed in the wheel axle assembly <NUM>. Here, the receiver <NUM> is placed within the cassette <NUM>, e.g. near the actuator <NUM>. Also not according to claim <NUM>, a first transmitter <NUM> is placed on the frame <NUM>. Here the transmitter <NUM> is placed at the dropout <NUM>. If the wheel including the wheel axle assembly <NUM> is exchanged the transmitter <NUM> will remain attached to the frame. Optionally, pairing of the replacement receiver <NUM>' of the replacement wheel with the transmitter <NUM> ca be achieved by use of the thru-axle <NUM>. The thru-axle <NUM> can include a tag <NUM> that can be read out when placing the thru-axle back in the frame <NUM>. The tag causes the replacement receiver to be coupled to the transmitter <NUM> on the frame <NUM>.

<FIG> shows a schematic cross section of a wheel axle assembly <NUM>. In this example, not according to claim <NUM>, the first transmitter <NUM> is placed in the thru-axle <NUM>. Here, also not according to claim <NUM>, the receiver <NUM> is placed within the cassette <NUM>, e.g. near the actuator <NUM>, i.e. on the wheel axle. If the wheel axle assembly, or wheel, is exchanged the transmitter <NUM> remains with the frame <NUM> since the thru-axle <NUM> can remain with the frame when exchanging the wheel. Therefore, a pairing between the transmitter <NUM> and the receiver <NUM> only needs to be performed once. There is no need for pairing when exchanging the wheel.

In <FIG>, the first transmitter <NUM> is communicatively coupled, here wiredly, with a second receiver <NUM>. The second receiver <NUM> is in this example arranged for wirelessly receiving a control signal from a second transmitter <NUM>. The second transmitter <NUM> can be associated with a manual input module <NUM>, such as a shifter, for shifting gears. The shifter <NUM> can e.g. be mounted on handlebars of the bicycle. The second transmitter can be mounted on the handlebars. A controller <NUM> can include a processor <NUM> for processing manual input from the module <NUM>. The controller can include indicator means <NUM> for indicating a status to the user. Hence a user (rider) can trigger transmission of the control signal by actuating the shifter. Alternatively, or additionally, the control signal transmitted by the second transmitter <NUM> can be automatically generated by a processor, e.g. the processor <NUM> of the controller <NUM>.

The first transmitter <NUM> and the second receiver <NUM> are powered by a battery <NUM>. In this example, the battery <NUM> is attached to the handle 6A of the thru-axle <NUM>. It is also possible that the battery <NUM> is included in the thru-axle <NUM>, e.g. within the hollow axle <NUM>. It is also possible that the thru-axle is wiredly connected to the controller <NUM> on the frame. Then the second transmitter <NUM> and second receiver <NUM> can be omitted. Also, the battery <NUM> can be omitted in case the first transmitter <NUM> then is powered, e.g. wiredly, from the controller <NUM> (e.g. from a battery <NUM> of the controller).

The first receiver <NUM> is here positioned near the electric component <NUM>. As transfer of signals and/or power is effected over a short distance a short range wireless connection is used, and pairing between the first transmitter <NUM> and the first receiver <NUM> is not required. The signals and/or power can be transferred capacitively and/or inductively. A second battery <NUM>, e.g. an ultracapacitor, can be connected to the electric component <NUM>. This battery <NUM> can provide power, e.g. current, to the electric component <NUM> for actuation. The second battery <NUM> can be charged by the first transmiter <NUM>, e.g. using power from the first battery <NUM>. Optionally, the second battery <NUM> can be used for providing power to the first receiver <NUM>. It is also possible that the first receiver <NUM> is powered, e.g. directly, by the first transmitter <NUM>. It is also possible that the electric component, e.g. the actuator, is powered, e.g. directly, by the first transmitter <NUM>. The second battery <NUM> can be selected to last the entire life span of the wheel axle assembly <NUM>. Hence, replacement of the second battery <NUM> can be avoided. The first battery <NUM> can charge, via the first transmitter <NUM> and the first receiver <NUM>, the second battery <NUM>. Hence, the user only needs to take care that the first battery <NUM> is sufficiently charged. The first battery <NUM> can be exchangeably mounted to the thru-axle <NUM> so that it can easily be charged and/or exchanged.

<FIG> shows a schematic cross section of a wheel axle assembly <NUM>. In this example, first electric contacts <NUM> are placed in the thru-axle <NUM>. Here, second electric contacts <NUM> are placed within the cassette <NUM>, e.g. near the actuator <NUM>, i.e. on the wheel axle. If the wheel axle assembly, or wheel, is exchanged the first electric contacts <NUM> remain close to the frame <NUM> since the thru-axle <NUM> can remain close to the frame when exchanging the wheel. In view of the wired connection between the switch and the thru-axle (and the wheel axle), there is no need for pairing when exchanging the wheel.

In <FIG>, the first electric contacts <NUM> are communicatively coupled, here wiredly, with a second receiver <NUM>. The second receiver <NUM> is in this example arranged for wirelessly receiving a control signal from a second transmitter <NUM>. The second transmitter <NUM> can be associated with a manual input module <NUM>, such as a shifter, for shifting gears. The shifter <NUM> can e.g. be mounted on or integrated in the handlebars of the bicycle. The second transmitter can be mounted on the handlebars. A controller <NUM> can include a processor <NUM> for processing manual input from the module <NUM>. The controller can include indicator means <NUM> for indicating a status to the user. Hence a user (rider) can trigger transmission of the control signal by actuating the shifter. Alternatively, or additionally, the control signal transmitted by the second transmitter <NUM> can be automatically generated by a processor, e.g. the processor <NUM> of the controller <NUM>.

The second receiver <NUM> is powered by a battery <NUM>. In this example, the battery <NUM> is attached to the handle 6A of the thru-axle <NUM>. It is also possible that the battery <NUM> is included in the thru-axle <NUM>, e.g. within the hollow axle <NUM>. It is also possible that the thru-axle is wiredly connected to the controller <NUM> on the frame. There can also be a connector in between the wired connection between the controller and the thru-axle to make it easier to disconnect the thru-axle. Then the second transmitter <NUM> and second receiver <NUM> can be omitted
The second electric contacts <NUM> are here positioned near the electric component <NUM>. The signals and/or power can be transferred wiredly from the thru-axle to the electric component <NUM>. A second battery <NUM>, e.g. an ultracapacitor, can be connected to the electric component <NUM>. The second battery <NUM> can be selected to last the entire life span of the wheel axle assembly <NUM>. Hence, replacement of the second battery <NUM> can be avoided. This battery <NUM> can provide power, e.g. current, to the electric component <NUM> for actuation. The second battery <NUM> can be charged via the first and second electric contacts, e.g. using power from the first battery <NUM>. It is also possible that the electric component, e.g. the actuator, is powered, e.g. directly, via the first and second electric contacts, e.g. from the first battery <NUM>. The second battery can then be omitted. The first battery <NUM> can be exchangeably mounted to the thru-axle <NUM> so that it can easily be charged and/or exchanged.

Energy transfer between the first transmitter <NUM> and the first receiver <NUM> can be in low or mid frequency range. The first transmitter <NUM> can be a low or mid frequency transmitter. The first receiver <NUM> can be a low or mid frequency receiver. <FIG> shows an example, not according to claim <NUM>, of a midfrequency, MF, transmitter <NUM> and midfrequency, MF, receiver <NUM>. In the example of <FIG> the energy storage <NUM> can e a battery or supercapacitor. Coupling between the transmitter <NUM> and receiver <NUM> can be through coils. the energy transfer can be arranged to indicate an actuation direction of the actuator. The receiver <NUM> can be arranged to wake up once the first transmitter <NUM> starts energy transfer. For the wireless energy transfer a frequency in the range of <NUM>-<NUM> can be used. This also provides advantages for the electronics used, such as switching FETs, which only need to be suitable for these relatively low frequencies.

Energy transfer can make of two coupled coils. A first coil <NUM> can be associated with the first receiver <NUM> and a second coil <NUM> can be associated with the first transmitter <NUM>. The coupled coils can be used at the resonance frequency of the two coils. At such resonance frequency a good coupling between the coils can be achieved, even if the coils are not at an optimum position relative to each other. Use can be made of flat coils and/or of concentric coils. The coils allow transfer of sufficient energy for powering the actuator <NUM>, and optionally the receiver <NUM>. The coils allow transfer of sufficient energy for directly powering the actuator <NUM> without the need for large energy storage in the exchangeable part of the wheel axle assembly. The coils allow for efficient transfer of signals.

An important aspect is mechanical positioning of the coils. The coils are arranged to be aligned reproducibly, also when exchanging a wheel. The coils are arranged such that metal parts have a minimum impact on signal and/or power transmission. In the example, not according to claim <NUM>, of <FIG> the second coil <NUM> is housed in a circumferential groove <NUM> in the thru-axle. The coil <NUM> can be protected from dirt and moisture, e.g. by a suitable potting or covering. In this example, the first coil <NUM> is enclosed surrounding the hollow axle <NUM>. <FIG>, not according to claim <NUM>, shows a detailed view of an example of the second coil <NUM> in the groove <NUM>. In this example, the coil <NUM> is covered with a cover <NUM>. Here the cover <NUM> is made of ferrite. In this example, the coils <NUM> is housed in a channel shaped insert <NUM> in the circumferential groove <NUM>. Here the insert <NUM> is made of ferrite.

<FIG> shows an example of a cross section of a thru-axle <NUM> not according to claim <NUM>. In this example, the first battery <NUM> includes two cells. The second coil <NUM> is placed closer to the tip 6T of the thru-axle than in <FIG>. <FIG> shows an example a cross section of a wheel axle assembly <NUM>. In this example, the wheel axle assembly includes a thru-axle <NUM> as shown in <FIG>. In this example, not according to claim <NUM>, the first coil <NUM> is positioned with respect to the hub <NUM> such that the first coil <NUM> is concentric with the second coil <NUM> when the thru-axle <NUM> is mounted to the frame <NUM> through the hollow axle <NUM>. In this example, a center of the first coil <NUM> substantially coincides with a center of the second coil <NUM>.

<FIG> and <FIG> each shows a schematic example of a system. The manual input module <NUM>, e.g. shifter, provides an input to the controller <NUM>. The controller <NUM> generates a control signal to be provided to the first transmitter <NUM> (<FIG>) or first electric contacts <NUM> (<FIG>). In <FIG>, not according to claim <NUM>, the first transmitter <NUM> is wiredly connected to the controller <NUM>. Alternatively it is also possible that the first transmitter <NUM> is wirelessly connected to the controller <NUM>. Then, the controller <NUM> includes, or is connected to, the second transmitter <NUM> and that the second receiver <NUM> is connected to the first transmitter <NUM>, see e.g. <FIG>. The second transmitter <NUM> and second receiver <NUM> can operate on a wireless transmission protocol such as ANT+, Bluetooth or the like. The transmission system of the second transmitter <NUM> and second receiver <NUM> requires no pairing when exchanging a wheel, as the second transmitter <NUM> and second receiver <NUM> remain with the frame <NUM>. The second receiver can e.g. be mounted to the thru-axle <NUM>. Similarly, in <FIG>, not according to claim <NUM>, the first electric contacts <NUM> are wiredly connected to the controller <NUM>. According to claim <NUM>, the first electric contacts <NUM> are wirelessly connected to the controller <NUM>.

It will be appreciated that the thru-axle can include a control unit. This control unit can be arranged for processing control signals from the controller <NUM>. The control unit can be arranged for converting input signals received from the controller <NUM> into signals to be transmitted towards the actuator, via the first transmitter/receivers <NUM>, <NUM> (not according to claim <NUM>) or via the first and second electric contacts <NUM>, <NUM>. The control unit can e.g. be arranged for indicating a current direction and/or current level to be transmitted towards the actuator. As shown in <FIG> and <FIG>, the processor 16A is included in or at the wheel axle. The processor 16A is here arranged for controlling the motor 16B. The processor 16A unit can be arranged for controlling the electric current direction and/or an electric current amount and/or an electric current duration to the motor. The processor 16A can also be arranged for controlling a current, e.g. limiting a current to the motor.

As shown in <FIG>, the manual input module <NUM> can include a shifter <NUM> or one or more shift buttons or shifters <NUM> to be manually operated by a user, such as a rider. The controller <NUM> can include an electronic and/or magnetic switch <NUM>. The electronic and/or magnetic switch can be arranged to be manually operated by the rider. The electronic and/or magnetic switch <NUM> can be indirectly operated by the rider, e.g. by being connected to the manual input mode, such as the shifter or shift buttons, e.g. a FRONT / LEFT shifter or shift button and the switch. The electronic and/or magnetic switch can also be automatically operated based on inputs from the bicycle such as wheel speed, torque, ratio, etc..

In an embodiment the electronic and/or magnetic switch <NUM> is connected to the shifter <NUM> or one or more shift buttons <NUM> via a cable <NUM>, such as a Bowden cable. The switch can be positioned in a housing <NUM> on the handle bars of the bicycle and the Bowden cable can be connected to a spring <NUM> in the housing which spring gives force feedback to the shifter <NUM> which is connected to the other side of the Bowden cable.

<FIG>, <FIG> show an example of a switch unit <NUM>. The shift unit <NUM> includes a switch <NUM> inside a housing <NUM>. Here, the housing includes attachment means <NUM>, here eyelets for attaching to a brake cable, e.g. by looping a tie wrap through the eyelet.

In this example the switch <NUM> is arranged to be actuated by a cable <NUM>, such as a Bowden cable. The Bowden cable <NUM> is connected to a spring <NUM> in the housing <NUM>. Thereto in this example a stopper <NUM> is attached to the Bowden cable <NUM> near a free end. The Bowden cable <NUM> here extends through the housing and is accessible at the free end thereof. The spring <NUM> gives feedback to the shifter <NUM> (not shown in <FIG>) which is connected to the other side of the Bowden cable.

The stopper <NUM> here is part of a mechanism connected between the Bowden cable <NUM> and the spring <NUM> which transmits the force of the spring <NUM> to the Bowden cable <NUM>. The mechanism is arranged to convert a translation of the Bowden cable <NUM>, here a pulling, into a translation, here a compression, of the spring <NUM>. It will be appreciated that alternative mechanisms are possible, e.g. using a torsion spring, and arranged to convert a translation of the Bowden cable into a rotation, such a compression, of the torsion spring. In this example, the mechanism is arranged to limit a translation of the Bowden cable. Thereto, in this example, the stopper <NUM> includes a bush 58A secured to the Bowden cable <NUM>, an adjustable nut 58C and a limiter 58C, such as a boss. The limiter 58C in this example runs in a groove <NUM> of the housing <NUM>. The movement of the limiter 58C is limited by the groove <NUM>. By positioning the nut 58B axially relative to the bush 58A, the position of the limiter 58C relative to the Bowden <NUM> cable can be adjusted. Hence movement of the Bowden cable, and limitation thereof, relative to the housing, and thus relative to the switch, is adjustable, here from the outside of the housing. Spring tension is adjustable via a tensioner <NUM>.

In this example a sensor <NUM> is included in the housing <NUM> for sensing a position of the stopper <NUM>, e.g. inductively, capacitively, magnetically and/or optically. Thus, the sensor <NUM> and the stopper <NUM> here form the switch <NUM>. Here the sensor <NUM> is arranged to discriminate two unique positions of the stopper <NUM>, i.e. two switch position.

In this example, the housing <NUM> includes a battery <NUM>. A battery status indicator <NUM> is also provided. A button <NUM> allows to activate the battery status indicator. This allows the battery status indicator to be switched off most of the time to conserve energy. The housing <NUM> can further include a controller and/or transmitter as described herein.

<FIG> shows a schematic example of a system. Here the controller <NUM> includes the second transmitter <NUM>, here a Bluetooth transmitter. The controller is connected to the manual input module <NUM>, here switches. Thus, in the module A the switch signal is converted to a Bluetooth signal. The second transmitter <NUM> is arranged for communicating with the second receiver <NUM>. The second receiver transfers control signals to the first transmitter <NUM>, not according to claim <NUM>. Thus, the module B receives a Bluetooth signal and transmits a power MF signal. The first transmitter <NUM>, not according to claim <NUM>, transmits control signals and/or power to the first receiver <NUM>. Thus, the module C receives a power MF signal and provides current to the DC motor. It will be appreciated that instead of the first transmitter <NUM> and the first receiver <NUM> the first and second electric contacts <NUM>, <NUM> can be used.

In this example, when the "left" switch is pressed, the actuator motor should turn clockwise until a mechanical end stop is reached, and when the "right" switch is pressed, the actuator motor should turn counter clockwise until a mechanical end stop is reached, or vice versa. The actuator motor can e.g. be driven at a nominal 3V and <NUM>.

For the module A, the power Storage A <NUM> can be a replaceable battery (not necessarily chargeable), for example maximum <NUM> button cell CR2032 (240mAh, 3V). Preferably the battery life-time allows for at least <NUM> switch actions in <NUM> year, which could equate to approximately 500hrs of biking, at <NUM> switch actions per hour. The BT Transmitter <NUM> preferably uses Blue Tooth Low Energy protocol. The distance to the receiver <NUM> is less than <NUM> in a normal bicycle. The BT transmitter <NUM> here is arranged to start transmitting a signal at switch input. Pairing of the BT transmitter <NUM> to the receiver <NUM> is possible (at close distance). Preferably secure communication is used between the transmitter <NUM> and the receiver <NUM>. The controller <NUM> can be provided with a battery charge indication. The battery charge indication can be arranged to be observable on request. The standby power drain should be low, therefore, the controller <NUM> can be arranged to enter a sleep-mode when the bicycle is not moving. A movement sensor may thereto be included. Go to sleep time when no movement or switch activation is detected can be <NUM> minutes or more. The go to sleep time can be user selectable. Wake-up time from sleep by movement of the controller is preferably <NUM> or less. Preferably, wake-up time by activation of one or more of the switches is <NUM> or less.

For the module B, the power storage B <NUM> can be a chargeable battery (not necessarily replaceable). The battery <NUM> can e.g. include two AAAA / LR61 Ni-MH cells. <FIG> shows an example of two battery cells <NUM> included in the thru-axle <NUM>, not according to claim <NUM>. The BT Receiver <NUM> preferably uses Blue Tooth Low Energy protocol. Battery charge indication is possible, e.g. on request. The charge indication of the battery <NUM> may be provided to the user via the controller <NUM>. The module B can be arranged to enter a sleep-mode when the bicycle is not moving. A movement sensor may thereto be included. The MF power transmitter <NUM> can be arranged to start transmitting MF (<NUM>) power signal on actuation request of one or more of the switches. The MF transmitter <NUM> is also arranged to provide charge power to Power Storage C <NUM> to maintain State-of-Charge of storage <NUM>. The module B can e.g. be housed in a sealed box, preferably water resistant IP67. Charging through a USB or mini-USB cable can be provided.

For the module C, the power Storage C <NUM> can be a non-replaceable battery, such as a capacitor, e.g. mounted on a PCB. The module C can include the coil <NUM>, not according to claim <NUM>, here an NFC coil, and the PCB. The PCB can include the electronics for the receiver <NUM> and motor control 16A. Motor control includes sending current to the DC motor 16B in the requested rotation direction. A mechanical end stop detection can be provided by current feedback. A current limit and maximum actuation duration can be adjustable. The MF power receiver <NUM> is arranged to receive a MF (<NUM>) power signal and send power to the power storage C <NUM> and motor control 16A. In an example the PCB can have a full or partial, such as half, circle shape, mounted within a enclosure. The enclosure can contain grease and/or oil. It will be appreciated that when the first and second electric contacts <NUM>, <NUM> are used instead of the MF transmitter <NUM> and MF receiver <NUM>, the power storage C <NUM> may be omitted.

Herein, the invention is described with reference to specific examples of embodiments of the invention. It will, however, be evident that various modifications, variations, alternatives and changes may be made therein. The scope of the invention is however limited by the appended claims.

Claim 1:
Bicycle including a frame (<NUM>) with a fork, the fork having dropouts (<NUM>) between which a wheel axle (<NUM>) is mounted, a thru-axle (<NUM>) arranged for positioning and/or holding the wheel axle between the dropouts, and a control element (<NUM>),
wherein the wheel axle includes a switchable transmission (<NUM>) between a driver (<NUM>) and a wheel hub (<NUM>) of a wheel, wherein the switchable transmission includes a switching mechanism including an electric actuator (<NUM>) arranged to be connected to the control element (<NUM>),
wherein a detachable electric connection is provided between the electric actuator (<NUM>) and the control element (<NUM>), wherein the detachable electric connection includes an electrical contact connection, having first electrical contacts (<NUM>) mounted on the thru-axle (<NUM>) and second electrical contacts (<NUM>) mounted on the wheel-axle or components thereof,
characterized in that the bicycle includes a wireless receiver (<NUM>) included in or attached to the thru-axle (<NUM>) for wirelessly receiving a signal from the control element (<NUM>).