This patent application claims priority from Italian patent application no. 102019000014676 filed on Aug. 12, 2019, the entire disclosure of which is incorporated herein by reference.
The present invention relates to a pedal for bicycles. In particular, the present invention refers to a pedal for bicycles which is designed to measure the power exerted by a cyclist while pedalling.
The use in bicycles, especially racing/road bicycles, of measurement systems that determine and display a series of parameters/quantities useful for monitoring the physical activity carried out by the cyclist while pedalling, generally the force/power exerted on the pedal and pedalling cadence, is well known.
Electronic measurement systems typically comprise an electronic measurement device which is arranged on the pedal and provided with electronic circuits and boards which measure the aforementioned parameters and transmit the measured parameters in the form of data to a display device generally arranged at the front of the bicycle, which receives the data and shows it to the cyclist.
Some types of electronic measurement devices are fitted on the pedal-pin of the pedal on the side of the pedal-body. An electronic measurement device of this type is for example the one described in Italian patent application no. TV2015A000010 filed by the Applicant.
A technical problem of electronic measurement devices of the aforementioned type is that their presence in the area of the pedal can be inconvenient and cumbersome for the cyclist, as well as exposed to the risk of damage in the event of accidental impacts.
The object of the present invention is therefore to provide a solution for measuring the power exerted by a cyclist while pedalling, which is capable of overcoming the technical problem described above.
This object is achieved by the present invention as it relates to a pedal for bicycles as defined in the appended claims.
The present invention will now be described with reference to the accompanying drawings, which illustrate a non-limiting embodiment thereof, wherein:
The present invention will now be described in detail with reference to the accompanying drawings in order to allow a skilled person to implement it and use it.
Various modifications to the described embodiments will be readily apparent to those of skill in the art and the general principles described may be applied to other embodiments and applications without however departing from the protective scope of the present invention as defined in the appended claims. Therefore, the present invention should not be regarded as limited to the embodiments described and illustrated herein, but they must be given the broadest protective scope consistent with the principles and features described and claimed herein.
With reference to
The pedal-pin 2 may have a first end 2a, which is preferably threaded and is coupled to the corresponding pedal crank 3 of the bicycle 4. The pedal-pin 2 may preferably have an elongated cylindrical shape and extend cantilevered from the pedal crank 3 along the longitudinal reference axis A, preferably approximately orthogonal to the pedal crank 3, and has a second end 2b axially opposite to the end 2a.
According to the example shown in
With reference to
In the example shown in
The pedal 1 further comprises an electronic measurement circuit 8, which is firmly coupled to the pedal-pin 2 and configured to provide electrical measurement signals indicative of the deformation of the pedal-pin 2 caused by the force exerted by the cyclist on the pedal-pin 2 during the pedalling. The electronic measurement circuit 8 is configured so as to measure physical quantities indicative of the cyclist's pedalling and output them, i.e. it may communicate them to other electronic devices, in the form of data or signals. According to a preferred embodiment, the electronic measurement circuit 8 is configured to measure a physical quantity corresponding to the mechanical power/force exerted by the cyclist on the pedal 1.
Preferably, the electronic measurement circuit 8 is provided with a plurality of electronic components/devices, some of which may preferably comprise deformation sensors, for example electrical strain gauge circuits 8a, fixed on or in the pedal-pin 2, and designed to measure changes in electrical quantities indicative of mechanical deformations caused by the cyclist on the pedal-pin 2 during pedalling. An electronic component of the electronic measurement circuit 8 may further comprise a processing unit 8b which determines the mechanical power generated by the cyclist and transmitted to the pedal 1 on the basis of the deformation(s), in turn determined as a function of the electrical quantities measured.
A component of the electronic measurement circuit 8 may also preferably comprise a communication module 8c, which is preferably wireless. The communication module 8c may communicate the measured electrical and/or physical quantities, for example the determined deformation and/or power, in the form of data/signals, to a user interface panel 9. Preferably, the interface panel 9 may be designed to be installed on the bicycle 4, preferably at the front (handlebar) (
In the example shown, the electronic components/devices of the electronic measurement circuit 8 are preferably positioned on the external surface of the pedal-pin 2 facing the inner surface of the hub 6. However, it should be understood that the present invention is not limited to the positioning of the electronic components/devices of the electronic measurement circuit 8 on the external surface of the pedal-pin 2, but, additionally and/or alternatively, may provide the positioning of one or more electronic components of the electronic measurement circuit 8 in a position inside the pedal pin 2, for example on the internal tubular wall and/or in recesses/seats formed inside the pedal pin 2.
It should also be understood that the present invention is not limited to the measurement of the physical quantity corresponding to the mechanical power/force exerted by the cyclist on the pedal 1, but, alternatively and/or additionally, may provide the measurement/determination of other physical quantities generally associated with the movement made by the pedal 1 under the thrust of the foot. These physical quantities may comprise, for example, the angular speed/cadence of the pedal 1, the torque, the angular position of the pedal crank 3, the angular acceleration of the pedal 1 and/or the like.
According to the present invention, the pedal 1 further comprises a mechanical clamping member 10 which is structured so as to axially clamp the hub 6 of the pedal-body 5 to the pedal pin-2 in order to prevent the pedal-body 5 from slipping off of the pedal-pin 2 along the axis A.
According to an embodiment shown in
According to the embodiment shown in
In the example shown, the clamping element 10a is structured so as to engage the annular seat 11 and be arranged laterally in abutment against the two shoulders 2c of the pedal-pin 2. The shoulders 2c are structured to perform the function of a stop designed to interfere with, that is to block, the axial displacement of the clamping element 10a along the axis A both towards the end 2b and towards the end 2a of the pedal-pin 2.
The clamping element 10b is structured to mechanically couple the hub 6 to the clamping element 10a so that the hub 6 remains axially coupled to the pedal-pin 2 by means of the clamping element 10a, and therefore cannot slip off of the pedal-pin 2.
In the example shown in
According to a preferable embodiment shown in
Preferably, the clamping element 10b may comprise a cylindrical tubular body which is structured to be firmly connected to the axial end 6b of the hub 6 facing the annular flange 17. In the example shown in
With reference to the embodiment shown in
According to a preferred embodiment shown in
With reference to the embodiment shown in
The Applicant found out that the two semi-cylindrical bodies 12a and 12b forming the annular body 12 may comprise two half-bushings radially fitted in the annular seat 11 on opposite sides. The semi-cylindrical bodies 12a and 12b may be advantageously made of a material characterised by a reduced friction coefficient. The semi-cylindrical bodies 12a and 12b may be advantageously made of a metallic material, such as bronze or the like, or of a polymer-based material, such as Teflon or the like.
With reference to the embodiment shown in
With reference to the embodiment shown in
The pedal-pin 2 and the tubular portion may form a monolithic body. In this case the seat 18 is formed on the body of the pedal-pin 2 and extends from the second end 2b, axially extending into the pedal-pin 2. It should be understood that according to a variant, not shown, the tubular portion may be an additional and separate component, which is coupled, for example screwed, to one end of the pedal-pin 2 so as to define an extension along the axis A inside the hub 6.
The seat 18 is preferably cylindrical, preferably has a circular section transverse to axis A, and has an access opening/mouth. Preferably, the electrical power supply device 19 comprises a battery, for example a rechargeable battery, having a shape complementary to the seat 18. Preferably, the seat 18 is sized so as to allow the battery to be inserted therein through the corresponding access opening. Preferably, the electrical connection between the electrical power supply device 19 and the electronic measurement circuit 18 can comprise electrical wires arranged in the pedal-pin 2, for example in a through duct (not shown) formed therein.
Preferably, the end 6c of the hub 6 may be closed by a cap or cover 14 shaped so as to also close the access opening of the seat 18. Preferably, the cover 14 can be coupled, in a firm yet easily removable/separable manner, to the end 6c of the hub 6 and is designed to protect the electrical power supply device 19.
In use, the assembly of the pedal 1 may comprise the steps of: firmly arranging/fastening the electronic measurement circuit 8 onto/to the pedal-pin 2, arranging the electrical power supply device 19 into the seat 18 and connecting it to the electronic measurement circuit 8, fitting the bushing 16 into the pedal-pin 2, axially fitting the hub 6 of the pedal-body 5 onto the pedal-pin 2, radially engaging the two semi-cylindrical bodies 12a and 12b into the annular seat 11 from opposite radial directions approximately orthogonal to axis A, fitting the locking ring nut 13 by engaging it onto the end 2a of the pedal-pin 2 in the area of the flange 17, screwing the locking ring nut 13 onto the end 6b of the hub 6 so as to axially tighten the pedal-body 5 like a packet against the semi-cylindrical bodies 12a and 12b, so that, on the one hand, the hub 6 is axially clamped, and on the other hand, the two semi-cylindrical bodies 12a and 12b are radially trapped in the annular seat 11, while free to slide within the annular seat 11 around axis A, and closing the open end 6c of the hub 6 with the cover 14.
In use, the hub 6 can rotate around axis A relative to the pedal-pin 2 thanks to the presence of the bushing 16 and the semi-cylindrical bodies 12a and 12b rotating in the annular seat 11. The semi-cylindrical bodies 12a and 12b rest against the shoulders 2c of the pedal-pin 2 and axially hold the locking ring nut 13 which, in turn, is screwed to the hub 6, thereby preventing the latter from axially slipping off of the pedal-pin 2.
In the embodiment shown in
For this purpose, as shown in
The pedal locking member described above is extremely advantageous as it makes it possible to:
Lastly, it is clear that the pedal described and illustrated above can be subject to modifications and variations without however departing from the scope of the present invention, as defined in the appended claims.
The embodiment shown in
Pedal 20 differs from pedal 1 in that the clamping element 10a is radially fastened in a firm and rigid manner to the hub 6 through the clamping element 10b. As shown in
As shown in
The hub 6 is therefore radially connected to the two semi-cylindrical bodies 12a and 12b by means of the screws and rotates with the same around the axis A, while remaining axially clamped by the shoulders 2c corresponding to the side walls of the annular seat 11 of the pedal-pin 2, which prevent the two semi-cylindrical bodies 12a and 12b, hence the hub 6, from moving along the axis A.
It should be understood that the clamping element 10a of the clamping member 10 of the pedal 20 shown in
In use, the assembly of the pedal 20 can comprise the steps of: firmly arranging/fastening the electronic measurement circuit 8 onto/to the pedal-pin 2, arranging the electrical power supply device 19 into the seat 18 and connecting it to the electronic measurement circuit 8, fitting the bushing 16 into the pedal-pin 2, radially engaging the two semi-cylindrical bodies 12a and 12b into the annular seat 11 from opposite radial directions approximately orthogonal to axis A, axially fitting the hub 6 of the pedal-body 5 onto the pedal-pin 2 so as to align the holes of the hub with the threaded holes formed in the two semi-cylindrical bodies 12a and 12b, engaging the screws 21 in the holes of the hub 6 and screwing them into the threaded holes of the two semi-cylindrical bodies 12a and 12b, so as to fasten the semi-cylindrical bodies 12a and 12b to the hub 6 of the pedal-body 5.
The embodiment shown in
The embodiment shown in
Pedal 40 differs from pedal 30 in that the screw 21 of the clamping element 10b of the mechanical clamping member is replaced by a fastening device 41, which has an external head 42 firmly fastened to the hub 6, preferably on the external surface thereof, preferably by means of fastening means 43, for example screws, and a rod 44 which protrudes from the head 42 and engages an opening 45, for example a cavity formed in a semi-cylindrical body 12a defining the clamping element 10a. Preferably, the section of the rod 44 which is transverse to axis A can have an approximately trapezoidal shape (
The embodiment shown in
The embodiment shown in
It should be pointed out that the clamping element 10a is arranged in abutment against at least one shoulder 2c defined by a lateral side of the annular projection 61 facing the flange 17. In the example shown, the two half-bushings are coupled to the annular projection 61 through the seat 62 in a freely rotatable manner around the axis A. The seat 62 of the two half-bushings is structured so as to have the inner side walls in abutment against the shoulders 2c defined by the two opposite lateral sides of the annular projection 61, so as to axially clamp the half-bushings to the annular projection 61 along the axis A. The locking ring nut 13 in the pedal 60 is structured to keep the half-bushings radially engaged against the annular projection 61 and to connect the hub 6 to the half-bushings.
Number | Date | Country | Kind |
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102019000014676 | Aug 2019 | IT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2020/057583 | 8/12/2020 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2021/028845 | 2/18/2021 | WO | A |
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Number | Date | Country | |
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20220411012 A1 | Dec 2022 | US |