EP4168299A1 - Photovoltaic device for a drivable wheel of a bicycle and bicycle - Google Patents

Abstract

A photovoltaic device for a drivable wheel of a bicycle has: • - a string having a plurality of photovoltaic cells (8) which are electrically connected in series, the string being able to be mechanically coupled to the drivable wheel, wherein • - a first photovoltaic cell (8a) of the photovoltaic cells (8) of the string has a first outer shape (101) and a second photovoltaic cell (8b) of the photovoltaic cells (8) has a second outer shape (102), the first outer shape (101) and the second outer shape (102) differing from each other and a first photoactive area (103) of the first photovoltaic cell (8a) being equal in size to a second photoactive area (104) of the second photovoltaic cell (8b), and/or – a charge controller (7) is electrically coupled to the string on the input side, the charge controller (7) being configured to transform a first electrical voltage of the photovoltaic cells (8) to a second electrical voltage, the second voltage serving to charge an energy storage device and/or the charge controller (7) being configured to operate the photovoltaic cells (8) in the MPP.

Description

description

Photovoltaic device for a bicycle wheel and bicycle

The invention relates to a photovoltaic device for a wheel of a bicycle, in particular a so-called electric bicycle. The invention also relates to a bicycle with at least one such photovoltaic device.

Bicycles with an electric auxiliary motor are referred to, for example, as e-bikes, electric bikes or pedelecs. The electric motor is used, for example, to support the drive force while pedaling.

It is desirable to provide a photovoltaic device for a bicycle wheel that enables reliable operation. It is also desirable to provide a bicycle with a photovoltaic device that can be operated reliably.

According to at least one embodiment, a photovoltaic device for a wheel of a bicycle has a string with a plurality of photovoltaic cells. The photovoltaic cells are electrically connected in series with one another. The strand can be mechanically coupled to the impeller. A first photovoltaic cell of the

Photovoltaic cells of the string have a first external shape. A second photovoltaic cell of the photovoltaic cells has a second external shape. The first outer shape and the second outer shape are different from each other. A first photoactive area of the first photovoltaic cell is the same size as a second photoactive area of the second photovoltaic cell.

During operation, the photovoltaic device is used, for example, to charge an energy store for storing electrical energy. By means of the photovoltaic cells, the energy storage device can be automatically charged while driving or when parking the bike. This increases the range. The photovoltaic cells are each designed to convert radiant energy into electrical energy. The photovoltaic cells are, for example, organic or inorganic photovoltaic cells. They can be designed as thin-film photovoltaic cells or as crystalline photovoltaic cells. For example, the photovoltaic cells are each formed on the basis of a semiconductor, for example silicon or another suitable semiconductor. Suitable materials are, for example, CIGS, CdTe, perovskite, GaAs and / or organic materials. Other materials can also be used.

The mutually different shape of the photovoltaic cells enables good space utilization and comparatively little shading of individual photovoltaic cells. The same size of the photoactive surfaces of the photovoltaic cells enables the photovoltaic cells to generate the same current in each case. This avoids a power loss in the series connection.

According to at least one embodiment, a photovoltaic device for a wheel of a bicycle has a string with a plurality of photovoltaic cells. The photovoltaic cells are electrically connected in series with one another. The strand is mechanical with the impeller connectable. The photovoltaic device has a charge regulator. The charge regulator is electrically coupled to the line on the input side. On the output side, the charge regulator can be electrically coupled to an energy storage device, for example a rechargeable battery. The charge regulator is set up to transform a first electrical voltage from the photovoltaic cells into a second electrical voltage, the second voltage being used to charge the energy storage device. For example, the second voltage has a higher value than the first voltage. Alternatively or additionally, the second voltage has a lower value than the first voltage, for example. This is useful for thin-film photovoltaic cells, for example. As an alternative or in addition, the charge controller is set up to set the MPP point of the photovoltaic cells. It is also possible for the charge controller to set the MPP point of the photovoltaic cells without transforming the voltages. The operating point of the photovoltaic cells at which the greatest possible power can be drawn from the photovoltaic cell is referred to as the MPP point (MPP: Maximum Power Point; maximum power point). For this purpose, for example, the electrical load on a photovoltaic cell and / or the string and / or the star is adapted.

The charge regulator is set up to transform the first electrical voltage, in particular a direct voltage, into the larger second electrical voltage, in particular a direct voltage. It is thus possible to provide the second voltage for charging the energy storage device with a sufficiently high value. Thus, the total power of the photovoltaic device for charging the energy storage device is sufficiently large and the energy storage device can be charged sufficiently quickly. For example, the first value of the first electrical voltage is 6 V. The second value of the second voltage is, for example, over 40 V, for example 41 to 42 V, in order to charge an energy storage device with 36 V. So it is possible to have one on a sunny day

100% recharge energy storage device. Other values for the first electrical voltage and / or other values for the second electrical voltage are also possible.

According to at least one embodiment, a combination of the two aforementioned embodiments is disclosed. Such a photovoltaic device according to one embodiment has both photovoltaic cells with mutually different external shapes, but the same size photoactive surface, as well as the charge controller, which transforms the first voltage from the photovoltaic cells into the second voltage.

The photoactive surface of the photovoltaic cell is in particular the surface on which radiation arrives during operation and is subsequently converted into electrical energy. In addition, a photovoltaic cell can have, for example, a frame, brackets or electrical feed and discharge lines. In the context of this disclosure, the same size means a deviation in size within specified tolerances. The tolerances can be specified, for example, in such a way that the photovoltaic cells supply essentially the same current in order to keep the current loss in the series connection as low as possible. For example, the tolerance is specified so that the photovoltaic surfaces of the individual photovoltaic cells differ from one another by a maximum of 30%. According to further embodiments, the tolerance is specified in such a way that the areas differ from one another by a maximum of 25%, a maximum of 20%, a maximum of 15% or between 0 and 15%.

According to at least one embodiment, the first photovoltaic cell and the second photovoltaic cell have the same nominal power. The nominal power of the first photovoltaic cell has at most a predetermined deviation from the nominal power of the second photovoltaic cell. For example, the nominal power has the values mentioned above for the tolerance of the surfaces. For example, the nominal power of the first photovoltaic cell deviates between 0% and 30% from the nominal power of the second photovoltaic cell.

According to at least one embodiment, the photovoltaic cells of the string are arranged radially along a sector of a circle. Thus, the cord and the external shape of the cord are well matched to use on the bicycle wheel.

According to at least one embodiment, the string is arranged in the circular sector in two rows, each with a plurality of photovoltaic cells. The two rows are electrically connected in series with each other. The voltage of the strand can thus be increased, in particular doubled.

According to at least one embodiment, a respective width of the photovoltaic cells increases with respect to a respective adjacent photovoltaic cell radially outward along the string. Thus, the outer shape of the photovoltaic cells is specified depending on an arrangement during operation on the bicycle wheel. Inside towards the outside, the width increases in order to utilize the surface of the impeller as well as possible. The height of the respective photovoltaic cells decreases accordingly in order to ensure the same size photoactive surface.

According to at least one embodiment, the photovoltaic device has a plurality of strings of the same type, each with a plurality of photovoltaic cells. The strings are connected electrically in parallel with one another. The strings are each electrically coupled to the charge controller. For example, eight or nine strings of the same type are connected in parallel with one another. A different number of identical strands is also possible, in particular more than two identical strands up to 15 identical strands or more. This enables a sufficiently large power for charging the energy storage device.

According to at least one embodiment, the photovoltaic device has the energy storage device for storing electrical energy. The output side of the charge regulator is electrically coupled to the energy storage device in order to charge the energy storage device by means of electrical energy from the photovoltaic cells. It is thus possible to charge the energy storage device of the photovoltaic device by means of radiant energy, for example from the sun, and with the aid of the photovoltaic cells and the charge controller.

According to one embodiment, a bicycle has a running wheel. The bicycle has a photovoltaic device according to at least one embodiment described here or one embodiment described here. the The photovoltaic device is mechanically fastened to the impeller, for example by means of clips, screws, hooks or other fastening means. For example, two photovoltaic devices are arranged on the impeller, one on each axial side. The two photovoltaic devices are in turn electrically coupled to one another in parallel.

The bicycle has, for example, a second wheel.

The second impeller also has, for example, a photovoltaic device or two photovoltaic devices. It is thus possible to provide either a single, two, three or four photovoltaic devices on the bicycle, each of which is connected in parallel to one another. In the case of bicycles such as cargo bikes, more than two running wheels can be provided and, accordingly, more than four photovoltaic devices can also be provided.

It is possible for each of the photovoltaic devices to have its own charge controller. It is also possible to provide a common charge controller for each wheel or just a single charge controller for the bicycle, which is electrically coupled to all the photovoltaic cells on the input side. The photovoltaic cells of the plurality of photovoltaic devices are used, for example, to charge an energy storage device of the bicycle.

Further advantages, features and developments result from the following exemplary embodiments explained in connection with the figures.

Identical, identical and identically acting elements can be provided with the same reference symbols in all the figures. Show it:

Figure 1 is a schematic representation of a bicycle with a photovoltaic device according to an embodiment,

Figure 2 is a schematic representation of a

Photovoltaic device according to an embodiment, and

Figure 3 is a schematic representation of a photovoltaic device according to an embodiment.

FIG. 1 schematically shows a bicycle 1. The bicycle 1 is a so-called electric bicycle. The bicycle 1 has a frame and a front wheel 2 and a rear wheel 3. The rear wheel 3 can be driven, for example, by pedaling. The bicycle 1 also has at least one electric motor in order to transmit drive energy to the front wheel 2 and / or the rear wheel 3 and thus to support pedaling. The electric motor is supplied with electrical energy from an energy storage device 4.

Photovoltaic cells 8 are arranged on the front wheel 2 and the rear wheel 3. The photovoltaic cells 8 are arranged radially on the wheels 2, 3 along a plurality of strings 6. A plurality of strands are provided for each wheel 2, 3, each of which forms a so-called star 5. For example, a star 5 is provided on the front wheel 2 and a star 5 is also provided on the rear wheel 3. It is also possible for two stars 5 to be provided on the front wheel, each on the axial outside. It is also possible that two stars 5 are provided on the rear wheel 3, likewise each on the axial outside. Wheel 1 can have either a single star 5, two stars 5, three stars 5, or four stars 5.

The photovoltaic cells 8 are electrically connected to a charge controller 7. The charge regulator 7 is also electrically connected to the energy storage device 4. The charge regulator 7 is used to transform a first voltage of the photovoltaic cells 8 into a second voltage for charging the energy storage device 4. The value of the second voltage is in particular greater than the value of the first voltage. Efficient charging of the energy storage device 4 is thus made possible.

FIG. 2 schematically shows a detailed view of part of a photovoltaic device 100.

The star 5 is in particular part of the photovoltaic device 100. The photovoltaic cells 8 are arranged starting radially at the wheel hub 10 outward along a circular sector 105 in the string 6. Slip rings 9 are provided on the wheel hub 10 or in the vicinity of the wheel hub 10. The strand 6 is electrically connected to the slip rings 9 by means of electrical contacts, for example a positive pole with a first slip ring 9 and a negative pole with a second slip ring 9. The slip rings 9 are in turn electrically coupled to the charge controller 7. The photovoltaic cells 8 of the string 6 are electrically connected to one another in series. The individual strands 6 of the star 5 are in turn electrically connected to the slip rings 9 parallel to one another.

The photovoltaic cells 8 of the string 6 have mutually different external shapes. For example are at least two of the photovoltaic cells 8 are formed with mutually different outer shapes. It is also possible for each photovoltaic cell 8 of the string 6 to have its own external shape, which is different from the outer shapes of the other photovoltaic cells 8 of the string 6. For example, the photovoltaic cell 8a has a different external shape than the further photovoltaic cell 8b which is directly adjacent radially outward. In particular, both a width 106 of the first photovoltaic cell 8a and a height 108 of the first photovoltaic cell 8a differ from a width 107 and a height 109 of the second photovoltaic cell 8b. The height 109 is in particular less than the height 108 and the width 107 greater than the width 106. Thus, a first shape 101 of the first photovoltaic cell 8a and a second shape 102 of the second photovoltaic cell 8b are adapted to the radial position in the string. The farther radially outward on the strand 6 the photovoltaic cell 8 is arranged, the wider it is. The respective height 108, 109 decreases accordingly.

Due to the mutually different shapes 101, 102 of the

Photovoltaic cells 8 of the string 6, it is possible to provide the respective photoactive surface of the photovoltaic cells 8 within predetermined limits to be the same size. For example, a first photoactive area 103 of the first photovoltaic cell 8a essentially corresponds to a photoactive area 104 of the second photovoltaic cell 8b.

This enables the individual photovoltaic cells to have shapes that differ from one another and are thus well adapted to their respective position within the string 6, while still generating an electric current of the same size from the individual photovoltaic cells 8. This avoids the need for a single cell that only has one generated small current, the total current of the string 6 is reduced. The different shapes 101, 102 and the photoactive surfaces 103, 104 of the same size enable both a good use of the axial surface of the impeller 2, 3 and an efficient conversion of the available radiation energy into electrical energy.

The photovoltaic cells 8 can have any geometric shapes. According to exemplary embodiments, the photovoltaic cells 8 are rectangular, right-angled and / or polygonal. According to exemplary embodiments, the photovoltaic cells 8 have other shapes, for example a trapezoid shape. This is useful, for example, for good use of space.

FIG. 3 shows a schematic illustration of a detail of the photovoltaic device 100 according to a further exemplary embodiment. Essentially, the photovoltaic device 100 corresponds to that explained so far. The differences between the exemplary embodiments in FIGS. 2 and 3 are primarily discussed below. In the exemplary embodiment according to FIG. 3, two rows 6 a, 6 b with respective photovoltaic cells 8 are provided for each string 6. The photovoltaic cells 8 of the respective rows 6a, 6b are connected to one another in electrical series. The rows 6a and 6b are in turn connected electrically in series. The number of photovoltaic cells 8 within the string 6 can thus be doubled in comparison to the exemplary embodiment in FIG. 2, for example. It is thus possible, for example, to double the voltage of the strand 6. The individual photovoltaic cells 8 are connected in series with one another by means of conduction strips 12 and then electrically coupled to the slip rings 9. The photovoltaic cells 8 of a star 5 are laminated, for example, on a common base plate. This base plate is then attached to the spokes of the impeller 2, 3, for example. It is also possible that the base plate replaces the spokes and the base plate simultaneously serves to carry the photovoltaic cells 8 and also to serve as the spokes of the impeller 2, 3. It is possible for photovoltaic cells 8 to be applied only to one axial side of the base plate, so that the star 5 is photosensitive only from one axial direction. It is also possible that photovoltaic cells 8 are attached to both axial sides of the base plate, so that both axial directions of the star 5 are photosensitive. It is thus possible to attach a star only on one axial side of the impeller 2, 3, and still provide photosensitivity and the possibility of converting radiant energy into electrical energy from both axial directions.

The photovoltaic device 100 enables the energy storage device 4 to be charged even while the bicycle 1 is in operation. Thus, a disadvantage of the limited capacity of the energy storage device 4 can be compensated for or reduced. This avoids the

Energy storage device 4 in conventional bicycles 1 without photovoltaic device 100 is emptied during operation and the bicycle 1 must continue to be operated with pure muscle power. The photovoltaic device 100 also enables the use of a permanently integrated energy storage device 4, which cannot be removed from the frame of the bicycle 1. The photovoltaic device 100 also enables the use of a removable energy storage device 4. Charging the Energy storage device by means of a cable at a socket can be avoided by means of the photovoltaic device 100 or the frequency of such a charge is greatly reduced. A large part of the electrical energy for charging the energy storage device 4 is provided by means of the photovoltaic cells 8. the

Energy storage device 4 can thus be automatically charged while driving or when parking bicycle 1. Thus, the range of the electric drive of the bicycle 1 is increased overall.

The individual photovoltaic cells 8 of each string 6 of the stars 5 are electrically matched to one another, in particular with regard to the use of space and also electrical characteristics. In addition, the number of photovoltaic cells 8 in the strings 6 can be reduced by using sufficiently large photovoltaic cells 8. This also reduces the wiring effort.

The charge controller 7 enables the photovoltaic device to be operated at the so-called MPP point (English: Maximum Power Point). Thus, the power of the photovoltaic cells 8 can be used as efficiently as possible and the voltage of the photovoltaic cells 8 can be stepped up in order to be able to efficiently feed the energy storage device 4.

For example, in the exemplary embodiment according to FIG. 324, photovoltaic cells 8 are provided for each string 6. The 24 photovoltaic cells generate, for example, an electrical voltage of 12 V. This voltage is applied to the charge regulator 7 on the input side. The charge controller transforms this to an output voltage of around 40 to 45 V for charging a 36 V. Energy storage device 4. The electrical currents are approximately 2 to 2.5 A per star 5 (with full solar radiation), so for example 10 A in the case of a bicycle 1 if four stars 5 are provided. A total output of the photovoltaic device 100 on the bicycle 1 of 120 to 130 W can thus be achieved.

For example, nine strands 6 are provided for each star 5.

Another number is also possible, in particular fewer than nine strands 6 or more than nine strands 6 per star 5. The strands 6 are electrically connected to the slip rings 9, for example via clamps and / or soldered connections. The electrical energy is then taken from the rotating slip rings 9, for example by means of carbon brushes, and to the charge controller 7 and

Energy storage device 4 passed. The MPP point for charging is set by means of the charge controller 7, which is electrically connected both to the photovoltaic cells 8 and to the energy storage device 4.

The charge controller 7 thus operates the photovoltaic cells 8 at the MPP point in order to achieve the maximum efficiency from the photovoltaic cells 8. The charge controller 7 is, in particular, a so-called DC / DC charge controller with an input voltage of 4.0 to 24.0 V and, for example, good efficiency at around 10 V. The input current is, for example, a maximum of 6 A or a maximum of 10 A. The output voltage is, for example 12 to 56 V and the output power, for example 80 W. The efficiency of the charge controller 7 is 97%, for example.

Due to the axial arrangement, there is always one axial side and the side assigned to this side in practical operation Photovoltaic cells 8 shaded. The real current of these photovoltaic cells 8 is lower than the maximum possible current. This enables the use of the adapted charge controller 7 with a smaller input current than the maximum possible current. Such a charge regulator is in particular more cost-effective than a charge regulator with a higher input flow.

Shading from components of the bicycle, for example

1 can lead to a reduction in the electrical current of the shaded strand 6. In particular, the MPP point does not change as a result of the shading. A single charge regulator 7 is therefore sufficient in accordance with exemplary embodiments.

According to the exemplary embodiments, a bypass diode (not explicitly shown) is connected for each strand 6. This reduces the risk of reverse currents flowing into shaded strands 6. In particular, reverse currents can thus be excluded. It is also possible for each photovoltaic cell 8 to be bridged with its own bypass diode. This enables a high tolerance towards individual, shaded photovoltaic cells 8. This enables an increase in efficiency.

If a single charge controller is used for all the stars 5 of the bicycle 1, the photovoltaic device 100 can be implemented cost-effectively. If, for example, a separate charge controller 7 is provided for the front wheel 2 and a second separate charge controller 7 is provided for the rear wheel 3, the photovoltaic cells 8 of the front wheel

2 and for the photovoltaic cells 8 of the rear wheel 3 set different MPP points of the respective charge controllers 7, which enables a higher electrical efficiency.

The photoactive surface 103, 104 of the photovoltaic cells 8 is, for example, in a range from 5 cm ^ to 15 cm ^, in particular in a range from 6 cm ^ to 8 cm ^, in particular in a range from 6.2 cm ^ to 6.7 cm ^ .

The individual photovoltaic cells 8 of a string 6 are, for example, spaced from one another. The individual photovoltaic cells 8 of the strings 6 are each spaced apart from one another, for example. The strands 6 are separated from one another by open gaps in the star 5, for example. An efficient use of the area of the axial surfaces of the running wheels 2, 3 is thus possible and, for example, susceptibility to wind can be reduced. The distances are, for example, in the range of a few millimeters between the cells and a few centimeters in the outer circumference of the wheel. The distances enable efficient electrical interconnection, for example.

The widths 106, 107 of the photovoltaic cells 8 are, for example, in a range between 10 mm and 80 mm, for example between 15 mm and 35 mm. The heights 108, 109 of the photovoltaic cells 8 are, for example, in a range from 8 mm to 35 mm.

The photovoltaic device 100 can be used both in bicycles 1 as described and in other vehicles with wheels. The photovoltaic device 100 enables the range of electric bicycles to be increased in daily use and on bike tours, and enables one reliable operation and reliable loading of the

Energy storage device 4 by means of radiant energy.

Reference character

1 bike

2 front wheel 3 rear wheel

4 energy storage device

5 star

6 strand

6a, 6b row 7 charge regulator

8 photovoltaic cell

9 slip ring

10 wheel hub

11 contact 12 conduction ribbon

100 photovoltaic device

101 first form

102 second form 103, 104 photoactive surface

105 sector 106, 107 width 108, 109 height

Claims

Claims

1. Photovoltaic device for a wheel (2, 3) of a bicycle (1), comprising:

- A string (6) with a plurality of photovoltaic cells (8) which are electrically connected in series with one another, wherein the string can be mechanically coupled to the impeller (2, 3), wherein

- A first photovoltaic cell (8a) of the photovoltaic cells (8) of the string has a first outer shape (101) and a second photovoltaic cell (8b) of the photovoltaic cells (8) has a second outer shape (102), the first outer shape (101 ) and the second outer shape (102) are different from one another and wherein a first photoactive area (103) of the first photovoltaic cell (8a) is the same size as a second photoactive area (104) of the second photovoltaic cell (8b).

2. Photovoltaic device for a wheel (2, 3) of a bicycle (1), comprising:

- A string (6) with a plurality of photovoltaic cells (8) which are electrically connected in series with one another, the string being mechanically coupled to the impeller (2, 3), and

- A charge controller (7), wherein the charge controller (7) is electrically coupled on the input side to the strand (6) and on the output side can be electrically coupled to an energy storage device (4) and the charge controller (7) is set up to generate a first electrical voltage from the To transform photovoltaic cells (8) into a second electrical voltage, wherein the second voltage is used to charge the energy storage device (4) and / or wherein the Charge controller (7) is set up to operate the photovoltaic cells (8) in the MPP point.

3. Photovoltaic device according to claim 2, wherein a first photovoltaic cell (8a) of the photovoltaic cells (8) of the string has a first outer shape (101) and a second photovoltaic cell (8b) of the photovoltaic cells (8) has a second outer shape (102) , wherein the first outer shape (101) and the second outer shape (102) are different from one another and wherein a first photoactive area (103) of the first photovoltaic cell (8a) is the same size as a second photoactive area (104) of the second photovoltaic area ( 8b).

4. Photovoltaic device according to claim 1 or 3, wherein the first photovoltaic cell (8a) and the second photovoltaic cell (8b) have the same nominal power.

5. Photovoltaic device according to one of claims 1 to 4, in which the photovoltaic cells (8) of the string (6) are arranged radially along a circular sector (105).

6. Photovoltaic device according to claim 5, wherein in the

Circle sector (105) of strand (6) is arranged in two rows (6a, 6b) each with a plurality of photovoltaic cells (8), the two rows (6a, 6b) being electrically connected to one another

Series are switched.

7. Photovoltaic device according to one of claims 1 to 6, wherein a respective width (106, 107) of the

Photovoltaic cells (8) increases in each case radially outward along the string (6) with respect to an adjacent photovoltaic cell (8).

8. Photovoltaic device according to one of claims 1 to 7, comprising a plurality of similar strands (6) each with a plurality of photovoltaic cells (8), wherein the strands (6) are connected electrically in parallel with each other and each electrically with the charge controller (7) are coupled.

9. Photovoltaic device according to one of claims 1 to 8, having the energy storage device (4) for storing electrical energy, wherein the charge controller (7) is electrically coupled on the output side to the energy storage device (4) in order to use electrical energy from the photovoltaic cells (8) to charge the energy storage device (4).

10. Bicycle (1), comprising:

- an impeller (2, 3),

- A photovoltaic device (100) according to one of claims 1 to 9, which is mechanically attached to the impeller (2, 3).