Classifications

• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B62—LAND VEHICLES FOR TRAVELLING OTHERWISE THAN ON RAILS
  • B62M—RIDER PROPULSION OF WHEELED VEHICLES OR SLEDGES; POWERED PROPULSION OF SLEDGES OR SINGLE-TRACK CYCLES; TRANSMISSIONS SPECIALLY ADAPTED FOR SUCH VEHICLES
  • B62M9/00—Transmissions characterised by use of an endless chain, belt, or the like
  • B62M9/04—Transmissions characterised by use of an endless chain, belt, or the like of changeable ratio
  • B62M9/06—Transmissions characterised by use of an endless chain, belt, or the like of changeable ratio using a single chain, belt, or the like
  • B62M9/10—Transmissions characterised by use of an endless chain, belt, or the like of changeable ratio using a single chain, belt, or the like involving different-sized wheels, e.g. rear sprocket chain wheels selectively engaged by the chain, belt, or the like
  • B62M9/12—Transmissions characterised by use of an endless chain, belt, or the like of changeable ratio using a single chain, belt, or the like involving different-sized wheels, e.g. rear sprocket chain wheels selectively engaged by the chain, belt, or the like the chain, belt, or the like being laterally shiftable, e.g. using a rear derailleur
  • B62M9/121—Rear derailleurs
  • B62M9/122—Rear derailleurs electrically or fluid actuated; Controls thereof
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B62—LAND VEHICLES FOR TRAVELLING OTHERWISE THAN ON RAILS
  • B62M—RIDER PROPULSION OF WHEELED VEHICLES OR SLEDGES; POWERED PROPULSION OF SLEDGES OR SINGLE-TRACK CYCLES; TRANSMISSIONS SPECIALLY ADAPTED FOR SUCH VEHICLES
  • B62M25/00—Actuators for gearing speed-change mechanisms specially adapted for cycles
  • B62M25/08—Actuators for gearing speed-change mechanisms specially adapted for cycles with electrical or fluid transmitting systems
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B62—LAND VEHICLES FOR TRAVELLING OTHERWISE THAN ON RAILS
  • B62M—RIDER PROPULSION OF WHEELED VEHICLES OR SLEDGES; POWERED PROPULSION OF SLEDGES OR SINGLE-TRACK CYCLES; TRANSMISSIONS SPECIALLY ADAPTED FOR SUCH VEHICLES
  • B62M9/00—Transmissions characterised by use of an endless chain, belt, or the like
  • B62M9/04—Transmissions characterised by use of an endless chain, belt, or the like of changeable ratio
  • B62M9/06—Transmissions characterised by use of an endless chain, belt, or the like of changeable ratio using a single chain, belt, or the like
  • B62M9/10—Transmissions characterised by use of an endless chain, belt, or the like of changeable ratio using a single chain, belt, or the like involving different-sized wheels, e.g. rear sprocket chain wheels selectively engaged by the chain, belt, or the like
  • B62M9/12—Transmissions characterised by use of an endless chain, belt, or the like of changeable ratio using a single chain, belt, or the like involving different-sized wheels, e.g. rear sprocket chain wheels selectively engaged by the chain, belt, or the like the chain, belt, or the like being laterally shiftable, e.g. using a rear derailleur
  • B62M9/121—Rear derailleurs
  • B62M9/124—Mechanisms for shifting laterally
  • B62M2009/12413—Rear derailleur comprising telescoping mechanisms

Definitions

• the invention relates to an electromechanical bicycle gear shift specified in the preamble of claim 1.
• the invention has for its object to provide an electromechanical bicycle gear shift of the type mentioned, which is characterized by a high switching accuracy and low wear over long periods of use.
• the extension extends the rotor, so to speak, and protrudes from the housing through the sliding seal.
• An effective shield against the ingress of dirt and moisture can be created in this area.
• the sliding seal can help guide the rotor; however, this is not necessary for proper functioning.
• An embodiment according to claim 5 is also structurally simple. Furthermore, the runner cooperates with the guides very easily and remains the same Sliding resistance for the rotor movement is practically constant regardless of temperature and time influences. An unfavorable play between the rotor and the guides does not occur even after a long period of use.
• the embodiment of claim 6 is also advantageous, because such a runner is dimensionally accurate and relatively small, e.g. can be produced in series production.
• the oval cross-section leads to high structural strength and ensures a large distance between the guides, as it is expedient for perfect guidance even under relatively high forces.
• the oval cross section also largely corresponds to that of the housing, so that it has a pleasing appearance and compact dimensions.
• the plain bearings only need to be pressed into the holes.
• the embodiment of claim 7 is also advantageous because the force for the switching movements in the rack is close to the guides, so that harmful torque loads are largely absent.
• the arrangement of the rack on the top and the longitudinal positioning element on the underside of the rotor benefits from the compact dimensions that are sought for the housing.
• the bracket for the chain changer designed in this way can easily be accommodated in the rotor, which has the advantage of being compact Dimension and a clean and stable mounting of the rocker has.
• the housing of the gear shift can be placed close to the chain, so that the protrusion over the contour of the bicycle is as small as possible and thus the risk of injury or damage to the housing is largely reduced.
• the tensioning rocker can not only perform its own movements required for the tensioning function in this bearing, but is also coupled with the runner practically without play, so that the switching movements are transmitted exactly to the chain. This means that with the switching accuracy guaranteed thanks to the good guidance of the rotor, this is also maintained by the clamping rocker.
• the idea of claim 10 is also favorable because the axial sliding surfaces ensure that the rotational resistance of the clamping rocker remains low and constant, which is particularly important for the clamping function of the clamping rocker.
• sliding contacts are mounted in a row on a housing wall. These are run over one after the other by a contact finger on the clamping rocker as it moves. The closed contact indicates to the motor that a certain one Gear stage position of the tensioning rocker is reached so that the motor can pivot a shift lever for a drive gearwheel to prevent further movement of the tensioning rocker.
• the sliding contacts tend to wear and corrode, and that in the selected circuit and construction principle with the multi-part mechanical feedback path, the clamping rocker does not always reach or maintain exactly the position that corresponds exactly to the selected gear stage. Even small deviations lead to the chain jamming on the gear and the efficiency of the gear shift noticeably reduced.
• the invention is therefore based on the further object, in an electromechanical bicycle gearshift, in which a positioning device for the carrier is provided in the housing, which belongs to the electrical circuit for controlling the electric motor and is aligned with a positioning element movable with the carrier, the construction effort for the accommodation of the electrical circuit and the cooperating
• the circuit board can be easily integrated into the housing without requiring additional space.
• the board also acts as a carrier for the positioning device. Since the positioning element with the carrier that acts as a runner is formed, is structurally combined, space is saved, which benefits the compact dimensions.
• the electrical circuit immediately receives the respective position of the carrier.
• the sensors are commercially available, inexpensive and, thanks to the protected housing in the housing, work trouble-free even over long periods of inactivity.
• the positioning element is inexpensive and easy to manufacture and attach; it desirably contributes to the desired switching accuracy, the scanning areas being easy to manufacture.
• the fork light barriers work very reliably with the strip.
• the embodiment of claim 15 is also expedient because the driver does not have to operate the gear shift until the next desired gear stage is reached, but only needs to give the impulse for the direction in which he wishes to shift, whereupon the gear shift visits the next gear automatically. This benefits the convenient handling of the gear shift. At the same time, this does not rule out that the driver can skip several gears, for which he only needs to generate a permanent directional impulse.
• the embodiment of claim 17 is also advantageous because the standstill circuit ensures that the driver, for example after a stop at a traffic light, to whom he has approached with a small gear ratio without having to switch, can start with a large gear ratio or the largest one. It might be very difficult to start with the previously selected small translation.
• a control circuit for a DC motor-operated electromechanical bicycle gear shift is also known.
• the known control circuit has a sliding contact disk connected to the direct current motor, which rotates with respect to a plurality of sliding contacts assigned to the individual gear stages.
• the rotating disc is connected via a Bowden cable to a chain launcher, which has the same construction as a chain launcher of a mechanically operated bicycle gear shift.
• a switch contact set which can be actuated with a rotary lever and is electrically connected to the sliding contacts is provided, so that the desired actuation of the DC motor is achieved depending on the position of the switch contacts and on the rotary position of the contact disk. Because of the large number of electromechanical switching parts and sliding contacts, the known circuit is not only complex in terms of production technology, but is also unsuitable for the operation of a bicycle circuit under changing ambient conditions.
• the present invention is based on the further object of developing a control circuit for an e-romechani bicycle gear shift that can be actuated by a direct current motor in such a way that the control circuit has an extremely simple mechanical structure Operational security is further increased.
• control circuit according to the invention are the subject of subclaims 19 to 22.
• FIG. 3 shows an enlarged detail from FIG.
• FIG. 4 shows an enlarged detail from FIG.
• FIG. 5 shows a control circuit for an electromechanical bicycle gear shift, in particular for those with reference to FIG. 1 up to 4 gear shift described,
• Fig. A detail from the control circuit of Fig. 5, and
• FIG. 5 shows a further detail from the control circuit of FIG. 5.
• a bicycle 1 with a frame 2 has a front wheel 3 and a rear wheel 4, the rear wheel 4 being fastened to the so-called dropout 5 of the frame 2 in a conventional manner.
• the rear wheel 4 is driven by a sprocket 6, a chain 9 and a schematically indicated gear cassette 7 with several gears.
• the gearwheels define several gear stages with different ratios of the circumferential gearwheel speed.
• an electromechanical gear shift 8 which is only schematically indicated in FIG. 1, is attached to the dropout 5.
• a power source 10 is used to supply power to the gearshift and, if appropriate, bicycle lighting elements (not shown).
• the gearshift 8 can be actuated, for example, by means of a gear selector 11 attached to the handlebar.
• a conventional bottom bracket generator 12, which can also be used for the power supply, is arranged on the pedal gear 6.
• a splined drive sleeve 14 which carries a number of gears corresponding to the number of gear steps.
• gear 15a for the limit gear stage with the smallest ratio and the closest, larger gear 15b for a gear stage with a larger ratio. The greater the selected gear ratio, the more revolutions the rear wheel 4 executes with one turn of the turntable 6.
• a side wall 16 of a closed housing 18 is also fixed by means of a clamping screw 19, which also serves to fix the rear wheel, and a dowel pin 17.
• a clamping screw 19 which also serves to fix the rear wheel, and a dowel pin 17.
• a housing 21 of an electric motor M is integrated with a gear 22 and a drive pinion 23 so that the rear end of the housing 21 protrudes from the housing 18, while the drive pinion 23 lies inside the housing.
• the longitudinal axis of the motor M is approximately perpendicular to the longitudinal axis of the housing 18, that is to say approximately parallel to the rear wheel 4.
• the longitudinal axis of the housing 18, however, is approximately parallel to the rear wheel axis.
• the housing 18 has a circumferential boundary wall 24 and a cover 25 placed on the side facing away from the bicycle. Between the side wall 16 and the cover 25, parallel and spaced-apart rod-shaped guides 26 for a rotor 27 with an oval cross section run.
• the rotor 27 is shorter than the interior of the housing 18 (see also FIG. 3). It has an integrally formed, cylindrical extension 28 which passes through the side wall 16 in a sliding seal 35.
• a switching element S is attached to the rotor 27 for switching the desired gear stages.
• the switching element is in this embodiment, a so-called clamping rocker 29, the idler idler wheels 30 and 30 a (see FIG. 3).
• the chain runs with its lower strand coming from the chain disc 6 from below around the deflection wheel 30, then onto the deflection wheel 30a and from there around the respective gear 15a or 15b back to the front to the chain disc 6.
• a circuit board 31 is arranged as the housing base or on the housing base (not shown) which carries a circuit (not shown) for the electric motor M and is connected to the gear selector 11 and the current source 10.
• a longitudinal rack 32 is attached or integrally formed with it, which meshes with the drive pinion 23.
• a positioning element 33 is fastened or formed on the underside of the rotor 27, which in this embodiment is a longitudinal, upright strip (FIG. 4).
• a positioning device works together with the positioning element 33, of which a fork light barrier 34 can be seen in FIG. 2.
• the rotor 27 is a die-cast or plastic molded part with an oval cross section and an integrally molded extension 28.
• the rotor 27 contains two bores 52 parallel to its longitudinal axis, into which linear roller bearings 36 are pressed, with which the rotor 27 is pressed onto the rod-shaped Guides 26 is guided.
• An enlarged stepped bore 37 is provided between the bores 52, in which a bearing pin 38 of the clamping rocker 29 is rotatably and resiliently biased.
• a helical spring 39 surrounds the journal 38 over part of its length.
• the coil spring 39 is anchored at one end 40 in a collar 43 of the journal 38 and at its other end 42 in the extension 28.
• the helical spring 39 is preloaded in such a way that it loads the tensioning rocker 29 in FIG. 3 in a clockwise direction, so that the tensioning rocker pivots in the counterclockwise direction but is then automatically moved again in the opposite direction.
• a plain bearing 41 is provided in the stepped bore 37, which supports the bearing pin 38 and is optionally directed with an axial bearing surface against the clamping rocker 29, so that it can be easily rotated here.
• a retaining screw 44 is screwed into the bearing pin 38, the head 45 and. can rotate part of their shaft in a plain bearing 46.
• an axial bearing surface 47 is also provided for the head 45 in the case of the slide bearing 46, so that the entire unit comprising the rocker 29, the bearing pin 38 and the retaining cap 44 can rotate easily in the rotor 27 without having any play in the axial direction.
• FIG. 4 it can be seen how on the board 31, which carries the circuit shown in FIGS. 5 to 7, the positioning devices in the form of the fork light barrier 34, a further fork light barrier m and a third fork light barrier 34 a.
• the fork light barrier 34m is responsible for the individual possible gear levels and for the correct position of the rotor 27 corresponding to a gear level.
• the fork light barriers 34 and 34a are so-called limit fork light barriers that are used for this are responsible that the runner is not moved so far in the event of a possible incorrect actuation that the chain is thrown off a limit gear, eg 15a.
• the positioning element 33 which - as mentioned before - is a high-standing sheet metal strip or plastic strip, is attached to the underside of the rotor 27 and has scanning areas 48 corresponding to the number and the distances between the gear steps, which are formed here in the form of bores.
• the scanning areas 48a and 48b correspond to the gearwheels 15a and 15b shown in FIG. 2.
• the positioning element has a front and a rear scanning edge 49 and 50, which are intended for cooperation with the limit fork light barriers 34 and 34a.
• the distance between the fork light barrier 34m and the two boundary fork light barriers 34 and 34a is in each case a dimension a larger than the distance between a boundary scanning region 48a and the associated scanning edge 49 or the other boundary scanning region (indicated by 48 in FIG. 4) and that this associated scanning edge 50.
• the electromechanical gear shift works as follows:
• the driver need only briefly press the gear selector to downshift, via the electric
• the electric motor is then started and the rotor 27 is moved in the desired direction via the drive pinion 23 and the toothed rack 32.
• the scanning area 48a leaves the Fork light barrier 34m because the rotor moves to the right in Fig. 4 (double arrow 51).
• the driver needs to give a directional impulse via the gear selector 11.
• the electrical circuit keeps the electric motor running until the next scanning area 48b releases the previously interrupted light beam in the fork light barrier 34m.
• the electric motor then stops and brakes electrically via the electrical circuit.
• the electrical circuit is equipped with a so-called pulse lock, so that it only accepts a new directional pulse if one has previously been processed.
• the tensioning rocker 29 has placed the chain from the toothed wheel 15a onto the toothed wheel 15b and positioned it correctly.
• the electrical circuit sets the electric motor in motion so that the runner moves to the left in FIG. 4 .
• the scanning edge 49 covers the limit fork light barrier 34, whereupon the direction of rotation of the electric motor M is reversed via the electrical circuit and the rotor 27 is moved to the right in FIG. 4 until the scanning region 48a again the light beam of the fork light barrier 34m releases, so that the previous limit step remains in place.
• the driver is then required to give a directional impulse in the other direction so that the gearshift shifts down.
• the electric motor prefferably be axially parallel to the longitudinal axis of the housing 28 in the housing and to effect the movement of the rotor via a screw spindle or a worm drive.
• the switching element S could be a switching pin which switches the different gear stages in the case of a gear hub.
• the control circuit 31 has a first flip-flop circuit 60 and a second flip-flop circuit 61.
• the first flip-flop circuit 60 belongs to the circuit half shown in FIG. 5 above, which serves to increase the current number of gears during the second flip-flop circuit 61 belongs to the circuit half shown in FIG. 5, which serves to lower the current gear stage.
• Each flip-flop circuit 60, 61 has an inverting output Q and a non-inverting output Q, a set input S and a reset input R.
• a first and a second power control circuit 70, 71 are connected to the phototransistors 66, 67, which each consist of two operational amplifiers 70a, 70b, 71a, 17b connected in series.
• Each power control circuit 70, 71 is also supplied on the input side by a node 74 with a reference potential which has a center potential between a first potential and a second Is potential which is generated by a voltage divider 72, 73.
• the power control circuits 70, 71 are supplied with a supply potential by a common circuit 75.
• the first power control circuit 70 is supplied with the second potential and the second power control circuit 71 with the first potential.
• the output signal of the first power control circuit is substantially equal to the first potential value, while that of the second power control circuit is substantially equal to the second potential value.
• the output signal of the first power control circuit essentially corresponds to the second potential value and that of the second power control circuit essentially corresponds to the first potential value.
• the output signals of the power control circuits 70, 71 are supplied to the DC motor M.
• the reset inputs of the two flip-flop circuits 60, 61 can be connected to the second potential via a photo transistor 65 in its activated state. Together with a light-emitting diode 62, the phototransistor 65 forms the first fork light barrier 34m, to which reference has already been made in connection with the explanation of FIG. 4.
• the light path between this (first) light-emitting diode 62 and the (first) photo transistor 65 runs through a corresponding one in the engaged state of the respective gears of the bicycle gearshift Scanning window 48a, 48b of the positioning element 33.
• the first phototransistor 65 is in its open state.
• the set input S of the first flip-flop circuit 60 is connected via an up switch 68 to the inverting output Q of the second flip-flop circuit 61.
• the set input of the second flip-flop circuit 61 is connected to the inverting output Q of the first flip-flop circuit 60 via a down switch 69.
• the inverting output of the first flip-flop circuit 60 is also connected to a standstill circuit 77, which in turn is connected to a chain sensor 78 and a speed sensor 79.
• the chain sensor 78 detects the movement of the chain via a magneto-electrical movement sensor 90 and an oppositely connected diode pair 91 as well as via a switching amplifier 92 and an output diode 93.
• the speed sensor 79 is connected to the generator 80, which generates an AC voltage output signal with an amplitude proportional to the bicycle speed. This signal is converted in the speed sensor 79 via a diode 94 and a timing element 95 to 97 into a DC voltage signal, the amplitude of which indicates the current speed of the bicycle. If the standstill circuit 77 detects a standstill of the bicycle on the basis of the output signals supplied to it by the chain sensor 78 and the speed sensor 79, it generates a high signal on the output side which is fed to the set input of the second flip-flop circuit 61.
• the positioning element 33 is in its respective limit positions or end positions, the light path from the second or third light-emitting diode 63, 64 to the second or third photo transistor 66, 67 is interrupted, so that the latter is switched to its switched-off state.
• the associated power control circuit 70, 71 is switched over so that the polarity of the motor control signal is reversed and the motor control signal takes on the opposite direction of rotation until the positioning element 33 has again reached a position in which a scanning area 48a, 48b between the light path the first light-emitting diode 62 and the first phototransistor 65, so that the flip-flop circuits 60, 61 are brought into their reset state.
• the up switch 68 is actuated starting from a middle gear stage, the first flip-flop circuit 60 is supplied with a set signal. Accordingly, the first Lei power control circuit 70 generates a high output signal so that the motor M is rotated in the corresponding direction. Even if now during the movement of the motor and the
• Positioning element 33 is already opened the up switch 68 between two gear stages, the control state described continues until the reset input of the first flip-flop circuit 60, a reset signal is fed. This reset signal is generated when the next scanning window of the positioning element 33 establishes the light path between the first light-emitting diode 62 and the first photo transistor 65.
• the reset brings both flip-flop circuits 60, 61 into the reset state so that the output signals of the two power control circuits 70, 71 are each low, the actuation of the motor M ending.
• Downshifting is initiated by corresponding activation of downshift switch 69 and is analogous to upshifting.
• the second flip-flop circuit 61 is supplied with a high control signal, which leads to a downshift of the bicycle gearshift to the lowest gear.
• the control circuit is supplied by a current source 10, to which a driving light 88 and a rear light 89 are also connected via a light switch 87.
• the current source 10 comprises the generator 80 which is connected to an accumulator 82 via a rectifier 81.
• the generator 80 is also due to a timing circuit that responds when the generator output signal drops below a minimum value or falls to zero volts for more than a predetermined time, for example two minutes. In this case, an output switch 84 is opened, so that further consumption of current by the control circuit and by the DC motor is avoided in this stationary state of the bicycle.
• a switch-on control 85 which is also connected to the generator 80, responds as soon as the generator voltage 80 exceeds a certain minimum voltage value of, for example, one volt and actuates a switch 86 assigned to it, in order thereby to achieve an optimal charging and consumption behavior of the control circuit.
• the generator 80 can be designed as a pedal position dynamo.
• the control circuit according to the invention can also be operated by a rechargeable battery, which is to be charged in each case on a power network.
• the current source 10 with the generator 80 is omitted.
• a switch connected downstream of the generator 80 makes it possible to switch the generator or dynamo 80 on and off as desired, in order to switch the dynamo off, for example on slopes, and to actuate it when driving downhill to charge the battery 82.
• the control circuit according to the invention can be used not only in the bicycle gearshift described, but can be used for any bicycle gear shift operated by a DC motor6.
• a bicycle gearshift (8) which can be actuated by an electric motor (M), has a support for an actuator (S), which is a tensioning rocker (29) of a derailleur gear or a shift pin of a hub gear.
• the carrier is a guide (slide which can be moved in a sliding manner) on at least two spaced, parallel guides (27) which are fixed with respect to a housing (18).
• a control circuit for the bicycle gear shift which can be actuated by a direct current motor (M) has a first and second power control circuit (70, 71), which can be controlled by first and second flip-flop circuits (60, 61), the set inputs of which are connected to switches (68, 69) for increasing or decreasing the gear stage and whose reset inputs are connected via a switch ( 65) can be activated, which responds to the gear shift when a gear is locked.
• M direct current motor

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• Engineering & Computer Science (AREA)
• Chemical & Material Sciences (AREA)
• Combustion & Propulsion (AREA)
• Transportation (AREA)
• Mechanical Engineering (AREA)
• Connection Of Motors, Electrical Generators, Mechanical Devices, And The Like (AREA)
• Control Of Position Or Direction (AREA)
• Gear-Shifting Mechanisms (AREA)
• Transmission Devices (AREA)

Applications Claiming Priority (2)

Publications (1)

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• 1986
  • 1986-09-16 DE DE19863631481 patent/DE3631481A1/de active Granted
• 1987
  • 1987-09-16 JP JP62505358A patent/JPH01502176A/ja active Pending
  • 1987-09-16 US US07/207,044 patent/US4946425A/en not_active Expired - Fee Related
  • 1987-09-16 EP EP87905952A patent/EP0281601A1/de not_active Ceased
  • 1987-09-16 WO PCT/EP1987/000529 patent/WO1988001962A2/de not_active Application Discontinuation

Non-Patent Citations (1)

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