EP4327905A1 - Ferris wheel ride - Google Patents

Abstract

The invention relates to a Ferris wheel ride with a spoked wheel (12) with a plurality of gondolas (14) arranged thereon for passengers, a support structure (16) in which the spoked wheel (12) is rotatably mounted, and an entry area (24) for the Entry and exit of passengers into and out of the gondolas (14), with photovoltaic elements (32, 34, 36) on the spoke wheel (12), the gondolas (14), the support structure (16) and/or the entry area (24). , 38, 40, 42, 44, 56) are arranged and the Ferris wheel ride (10) has at least one electric motor (26) and one with the photovoltaic elements (32, 34, 36, 38, 40, 42, 44, 56) electrically connected electrical energy storage (28), which is set up to store electrical energy from the photovoltaic elements (32, 34, 36, 38, 40, 42, 44, 56), the electric motor (26) being connected to the energy storage (28) in such a way is electrically connected so that the spoke wheel (12) can be driven controlled by the electric motor (26).

Description

The invention relates to a Ferris wheel ride according to the preamble of claim 1.

The invention deals with Ferris wheels as rides, as they regularly appear at fairs or festivals in the form of transportable Ferris wheels or as permanently installed Ferris wheels as city attractions, such as the Vienna Ferris Wheel in the Prater in Vienna or the so-called "London Eye" in London. or “Millennium Wheel”.

The power requirement of such Ferris wheel rides is generally high, since large masses on the circumference of the Ferris wheel, i.e. at a large distance from the center of rotation, typically have to be accelerated and braked regularly with every entry and exit process. In addition, such Ferris wheel rides are objects that are intended to attract attention and are therefore typically extensively equipped with lighting. The lighting should make the rides visible from afar and serve as a point of orientation. However, the intense lighting also leads to high electricity requirements. The electricity costs of such Ferris wheel rides are therefore generally high.

The invention is therefore based on the object of reducing the electricity costs of Ferris wheel rides.

The invention solves this problem with the features of a Ferris wheel ride according to claim 1.

The Ferris wheel ride according to the invention comprises a spoked wheel with a plurality of gondolas arranged thereon for passengers, a support structure in which the spoked wheel is rotatably mounted, and an entry area for passengers to get in and out of the gondolas. Photovoltaic elements are arranged on the spoke wheel, the gondolas, the support structure and/or the entry area. The Ferris wheel ride also has at least one electric motor and an electrical energy storage device electrically connected to the photovoltaic elements and set up to store electrical energy from the photovoltaic elements, the electric motor being electrically connected to the energy storage device in such a way that the spoke wheel can be driven under control by the electric motor is.

The invention makes it possible to reduce the electricity costs of Ferris wheel rides to zero, since the electricity required to operate a Ferris wheel ride can be generated with the photovoltaic elements arranged on the Ferris wheel ride.

The operation of a Ferris wheel ride according to the invention therefore does not require the use of fossil fuels and therefore avoids the entry of carbon dioxide into the earth's atmosphere. In this way, the invention provides a sustainable concept for an amusement device, namely a ride in the form of a Ferris wheel.

The invention also makes it possible to operate a Ferris wheel ride independently of conventionally required power connections. The Ferris wheel ride according to the invention is therefore advantageously suitable for uncomplicated operation, for example at festivals, where suitable power connections are often not available or have to be created in a complex and expensive manner. This is particularly the case with festivals that are held on meadows or agricultural areas. The Ferris wheel ride according to the invention can therefore advantageously be set up and operated practically anywhere, even on terrain, with no or no suitable power connections.

According to a further development of the invention, the gondolas have gondola roofs and side panels, the gondola roofs and/or side panels being completely or partially covered with photovoltaic elements. The gondolas of Ferris wheel rides are in constant motion during operation. This means that part of the gondolas is permanently in an optimized orientation towards the sun and outside of shadow zones, which can arise particularly in the lower area of the spoke wheel. The gondola roofs and/or side panels of the gondolas are therefore particularly suitable for the arrangement of photovoltaic elements.

A further development of the invention provides that the nacelle roofs and/or side panels are completely or partially covered, for example glued, with flexible photovoltaic elements. The photovoltaic elements can thus advantageously be adapted to curved or arched surfaces on the gondolas or gondola roofs. This means that the contour of the gondolas remains unchanged, even if photovoltaic elements are subsequently attached to the gondolas.

According to a further development of the invention, the spoke wheel has spokes, with gaps between the spokes being formed between adjacent spokes, in which photovoltaic elements are arranged. There are large areas between the spokes of the spoked wheel that can be used for arranging photovoltaic elements. Thanks to large photovoltaic areas, the installed photovoltaic elements advantageously have a large nominal output.

A further development of the invention provides that the spoke spaces used for the arrangement of photovoltaic elements are formed between adjacent spokes in the tangential direction of the spoke wheel. The photovoltaic elements are thus arranged in a substantially vertical plane. This results in an advantageous constant alignment of the photovoltaic elements despite rotation of the spoke wheel in one direction.

Another development of the invention provides that the spoke spaces used for the arrangement of photovoltaic elements are alternatively or additionally formed between spokes adjacent in the axial direction of the spoke wheel. In this case, the vertical of the surfaces of the photovoltaic elements rotates around the axis of rotation of the spoke wheel. Such an arrangement is advantageous because these surfaces do not offer any relevant wind resistance acting laterally, i.e. in the axial direction of the spoked wheel, and therefore the wind pressure exerted by these surfaces laterally, i.e. in the axial direction of the spoked wheel, is negligible.

According to a further development of the invention, the photovoltaic elements arranged in the spaces between the spokes have a wind-permeable structure. This significantly reduces wind resistance. The wind pressure acting on the spoked wheel is also significantly reduced. This enables the use of larger areas for photovoltaic elements and thus a larger installable nominal power of photovoltaic elements.

A further development of the invention provides that the photovoltaic elements arranged in the spaces between the spokes have or are a wind-permeable photovoltaic film. Such a film has the advantage that it is light and thin. This is advantageous with regard to the transportability of the Ferris wheel ride according to the invention, since the weight to be transported and the transport space required are reduced in this way. In one embodiment of the invention, this photovoltaic film is stretched onto a frame which is attached in the spaces between the spokes.

According to a further development of the invention, in an area adjacent to the axis of rotation of the spoke wheel, the occupancy of the spaces between the spokes with photovoltaic elements is higher than in an area that is radially further away from the axis of rotation of the spoke wheel. This is advantageous because in an area near the axis of rotation the maximum lever arm acting when the spoke wheel rotates is shorter in relation to the floor surface than in an area that is away from the axis of rotation. The susceptibility of the Ferris wheel ride to wind is thereby reduced by reducing the tipping moment due to wind. The stability of the ride can therefore be guaranteed even in strong winds.

A further development of the invention provides that the support structure has support pillars which are completely or partially provided with photovoltaic elements arranged on panels, preferably alignable panels, and/or covered, for example glued, with flexible photovoltaic elements. According to a further development, it is further provided that photovoltaic elements are arranged, for example glued, on a disk-like surface, preferably an alignable surface, or panels, preferably an alignable panel, on the support pillars in the area of the axis of rotation of the spoke wheel. Such an assembly of panels is advantageous because it takes place at fixed assembly points and thus avoids rotating assembly points. Rotating mounting points require more complex and therefore more expensive designs due to the alternating loads resulting from rotation. Thanks to the attachment of panels to fixed mounting points, such constructions can be made less complex and therefore less expensive.

According to a further development of the invention, the entry area has a canopy which is completely or partially covered with photovoltaic elements and/or the entry area is surrounded by a fence which is formed entirely or partially from photovoltaic elements or has photovoltaic elements. The canopy of the entry area is usually a large fixed area. It allows the installation of a comparatively large electrical photovoltaic nominal output. The fencing extends along a distance of substantial length and therefore also enables the installation of a comparatively large electrical photovoltaic power rating.

A further development of the invention provides that the canopy is completely or partially covered, for example pasted, with flexible photovoltaic elements. The shape of the photovoltaic elements can therefore be adapted to the shape of the canopy. The canopy can therefore easily be designed to be curved, for example, without There are special challenges with regard to the installation of photovoltaic elements.

According to a further development of the invention, the capacity of the electrical energy storage and the nominal power of all photovoltaic elements on the Ferris wheel ride are dimensioned such that the operation of the Ferris wheel ride is self-sufficient, i.e. without an additional supply of electrical energy. The Ferris wheel ride can therefore be operated independently, i.e. without additional power connections or other power generators being required to operate the Ferris wheel ride.

A further development of the invention provides that the electric motor can be switched to generator operation in such a way that the rotational energy released when the spoke wheel is braked is converted into electrical energy and stored in the electrical energy storage. Such operation is particularly sustainable and environmentally friendly, as it enables the rotational energy to be recovered into electrical energy.

Further developments of the invention result from the claims, the description and the drawing. The aforementioned advantages of features and combinations of several features are exemplary and can have an alternative or cumulative effect, without the advantages necessarily having to be achieved by embodiments according to the invention. Further features can be found in the drawing - in particular the geometries shown and the relative dimensions of several components to one another as well as their relative arrangement and operative connection. The combination of features of different embodiments of the invention or of features of different claims is also possible, deviating from the selected relationships of the claims, and is hereby proposed. This also applies to those features that are shown in the drawing or mentioned in the description. These features can also be combined with features of different claims. Likewise, features listed in claims can be omitted for further embodiments of the invention.

Fig. 1

ein Ausführungsbeispiel eines erfindungsgemäßen Riesenrad-Fahrgeschäfts in einer Seitenansicht und

Fig. 2

das Riesenrad-Fahrgeschäft in einer um 90° versetzten Seitenansicht in vereinfachter Darstellung.

Show in the drawing:

Fig. 1

an embodiment of a Ferris wheel ride according to the invention in a side view and

Fig. 2

The Ferris wheel ride in a side view offset by 90° in a simplified representation.

Fig. 1 shows an exemplary embodiment of a Ferris wheel ride 10 according to the invention. The Ferris wheel ride 10 comprises a spoke wheel 12 with a large number of gondolas 14 arranged thereon for passengers. The spoke wheel 12 is rotatably mounted in a support structure 16, which has support pillars 18, 20 which are mounted on a substructure 22. The substructure 22 also serves to accommodate an entry area 24, which is intended for passengers to get in and out of the gondolas.

At least one electric motor 26 drives the spoke wheel 12, preferably by pressing pressure rollers drivable by the electric motor 26 against the spoke wheel 12 in the area of the substructure. The electric motor 26 is supplied with electrical energy from an electrical energy storage 28.

In a ticket booth 30, passengers can not only pay their fare. A control panel for controlling the drive, in particular the electric motor 26, of the Ferris wheel ride 10 is also housed in the ticket booth 30. The spoke wheel 12 can be driven and braked using the control panel. Furthermore, the operation of the Ferris wheel ride 10 can be monitored using the control panel.

The Ferris wheel ride is provided with a large number of photovoltaic elements 32, 34, 36, 38, 40, 42, 44. These photovoltaic elements 32, 34, 36, 38, 40, 42, 44 are arranged on the spoke wheel 12, the gondolas 14, the support structure 16 and the entry area 24, namely photovoltaic elements 32 on gondola roofs 45 of the gondolas 14, photovoltaic elements 34 on side panels 46 of the gondolas 14, photovoltaic elements 36 on a canopy 48 of the entry area 24, photovoltaic elements 38 on the substructure 22, photovoltaic elements 40 in spaces 50 between adjacent spokes 52 of the spoke wheel 12 - herein referred to as spoke spaces -, photovoltaic elements 42 on the support pillars 18, 20 of the support structure 16 and photovoltaic elements 44 in an area adjacent to the axis of rotation 54. During daylight hours, these photovoltaic elements convert sunlight into electrical energy and store the electrical energy obtained in the electrical energy storage 28. This electrical energy is used to drive the electric motor 26.

In the area adjacent to the axis of rotation 54 of the spoke wheel 12, the photovoltaic elements 44 are arranged with a higher occupancy, i.e. a high number of photovoltaic elements per area, than in an area that is radially further away from the axis of rotation 54, in which the photovoltaic elements 40 are arranged in such a way that only a fraction of the spoke gaps 50 are provided with photovoltaic elements 40, for example only every second spoke gap 50 with photovoltaic elements 40.

The photovoltaic elements 44 within the axis of rotation 54 are advantageously mounted on the support structure 16 and therefore cannot be rotated. Alternatively, these photovoltaic elements 44 can be mounted on the spokes 52 of the spoke wheel 12 and thus follow the rotation of the spoke wheel 12.

Furthermore, the photovoltaic elements 36, 38 and 42 are not arranged on the spoke wheel 12 and therefore do not follow the rotation of the spoke wheel 12. The photovoltaic elements 36, 38 and 42 are therefore arranged in a rotationally fixed manner, just like advantageously (but not necessarily) the photovoltaic elements 44. However, these photovoltaic elements 36, 38, 42 and possibly 44 can be arranged such that they can be aligned. This enables these photovoltaic elements 36, 38, 42 and possibly 44 to be aligned in the direction of a position that is optimized with regard to the incidence of light. These photovoltaic elements 36, 38, 42 and possibly 44 are advantageously arranged on alignable panels.

Fig. 2 shows the Ferris wheel ride 10 in a side view offset by 90 ° in a simplified representation, in particular without gondolas 34 and the details of the entry area 24, to illustrate the arrangement of photovoltaic elements 56 in spoke spaces 58, which are formed between two spokes 52 which are adjacent in the axial direction of the spoke wheel 12, ie in the direction of the axis of rotation 54.

In contrast, shows Fig. 1 the arrangement of photovoltaic elements 40 in spoke spaces 50, which are formed between two spokes 52 which are adjacent in the tangential direction of the spoke wheel 12, ie in the direction of rotation of the spoke wheel 12.

Both arrangements are provided alternatively or cumulatively. The cumulative arrangement, i.e. the arrangement of photovoltaic elements 40, 56 in spoke spaces 50, 58, which are arranged on the one hand between two spokes 52 adjacent in the tangential direction of the spoke wheel 12 and on the other hand between two spokes 52 adjacent in the axial direction of the spoke wheel 12, provides a particularly high yield of electricity from solar energy. The cumulative arrangement is particularly advantageous for Ferris wheel rides with increased power requirements, such as Ferris wheel rides with air-conditioned gondolas.

Additional areas of the Ferris wheel ride 10 can be used for attaching photovoltaic elements as panels and/or as flexible photovoltaic elements, in particular as photovoltaic film. For example, such an attachment can be provided on the housings of headlights for illuminating the Ferris wheel ride 10, on the ticket booth 30 and on railings of the Ferris wheel ride 10.

Overall, thanks to the photovoltaic elements 32, 34, 36, 38, 40, 42, 44 and 56 arranged on the Ferris wheel ride 10, the invention enables self-sufficient operation of the Ferris wheel ride 10 without the need for a separate power connection. Furthermore, the invention makes it possible to reduce electricity consumption from the public power grid in inner cities. The Ferris wheel ride 10 according to the invention can therefore be used in a variety of ways, is cost-effective and can be operated sustainably from an environmental point of view.

The Ferris wheel ride according to the invention is not limited in terms of its height, the number of gondolas on the Ferris wheel, the maximum number of people in a gondola or the maximum load capacity of a gondola and/or the maximum load capacity of the entire Ferris wheel ride. These parameters can be chosen to be of any size.

10

Riesenrad-Fahrgeschäft

12

Speichenrad

14

Gondel

16

Stützkonstruktion

18

Stützpfeiler

20

Stützpfeiler

22

Unterkonstruktion

24

Einstiegsbereich

26

Elektromotor

28

elektrischer Energiespeicher

30

Kassenhäuschen

32

Photovoltaikelemente

34

Photovoltaikelemente

36

Photovoltaikelemente

38

Photovoltaikelemente

40

Photovoltaikelemente

42

Photovoltaikelemente

44

Photovoltaikelemente

45

Gondeldach

46

Seitenverkleidung

48

Vordach

50

Speichenzwischenräume

52

Speiche

54

Drehachse

56

Photovoltaikelemente

58

Speichenzwischenräume

The following reference numbers are used in the figures:

10

Ferris wheel ride

12

spoke wheel

14

gondola

16

Support structure

18

Support pillars

20

Support pillars

22

Substructure

24

Entry area

26

Electric motor

28

electrical energy storage

30

Ticket booth

32

Photovoltaic elements

34

Photovoltaic elements

36

Photovoltaic elements

38

Photovoltaic elements

40

Photovoltaic elements

42

Photovoltaic elements

44

Photovoltaic elements

45

Gondola roof

46

Side panel

48

canopy

50

Spoke spaces

52

spoke

54

Axis of rotation

56

Photovoltaic elements

58

Spoke spaces

Claims (15)

Ferris wheel ride with a spoked wheel (12) with a large number of gondolas (14) arranged thereon for passengers, a support structure (16) in which the spoked wheel (12) is rotatably mounted, and an entry area (24) for getting in and out of Passengers in and out of the gondolas (14),
characterized in that Photovoltaic elements (32, 34, 36, 38, 40, 42, 44, 56) are arranged on the spoke wheel (12), the gondolas (14), the support structure (16) and / or the entry area (24) and that the Ferris wheel ride (10) has at least one electric motor (26) and an electrical energy storage device (28) electrically connected to the photovoltaic elements (32, 34, 36, 38, 40, 42, 44, 56), which is used to store electrical energy Energy from the photovoltaic elements (32, 34, 36, 38, 40, 42, 44, 56) is set up, the electric motor (26) being electrically connected to the energy storage (28) in such a way that the spoke wheel (12) is controlled by the electric motor (26) can be driven. Ferris wheel ride according to claim 1,
characterized in that
the gondolas (14) have gondola roofs (45) and side panels (46), the gondola roofs (45) and/or side panels (46) being completely or partially covered with photovoltaic elements (32, 34). Ferris wheel ride according to claim 2,
characterized in that
the nacelle roofs (45) and/or side panels (46) are completely or partially covered, for example glued, with flexible photovoltaic elements (32, 34). Ferris wheel ride according to one of the preceding claims,
characterized in that
the spoke wheel (12) has spokes (52) with spoke spaces (50, 58) formed between adjacent spokes (52), photovoltaic elements (40, 56) being arranged in spoke spaces (52, 58). Ferris wheel ride according to claim 4,
characterized in that
the spoke spaces (50) are formed between adjacent spokes (42) in the tangential direction of the spoke wheel (12). Ferris wheel ride according to claim 4 or 5,
characterized in that
the spoke spaces (58) are formed between spokes (42) adjacent in the axial direction of the spoke wheel (12). Ferris wheel ride according to one of claims 4 to 6,
characterized in that
the photovoltaic elements (40, 56) arranged in the spoke spaces (50, 58) have a wind-permeable structure. Ferris wheel ride according to claim 7,
characterized in that
the photovoltaic elements (40, 56) arranged in the spoke spaces (50, 58) have or are a wind-permeable photovoltaic film. Ferris wheel ride according to one of claims 4 to 8,
characterized in that
in an area adjacent to the axis of rotation (54) of the spoke wheel (12), the occupancy of the spoke spaces (50) with photovoltaic elements (44) is higher than the occupancy of the spoke spaces (50) with photovoltaic elements (40) in a radial direction from the axis of rotation (54) area further away from the spoke wheel (12). Ferris wheel ride according to one of the preceding claims,
characterized in that
the support structure (16) has support pillars (18, 20) which are completely or partially covered, for example glued, with photovoltaic elements (42) arranged on panels, preferably alignable panels, and/or flexible photovoltaic elements (32, 34). Ferris wheel ride according to one of the preceding claims,
characterized in that
on the support pillars (18, 20) in the area of the axis of rotation (54) of the spoke wheel (12) photovoltaic elements (44) are arranged, for example glued, on a disk-like surface, preferably an alignable surface, or panels, preferably an alignable panel . Ferris wheel ride according to one of the preceding claims,
characterized in that
the entry area (24) has a canopy (48) which is completely or partially covered with photovoltaic elements (36) and/or the entry area (24) is surrounded by a fence which is formed entirely or partially from photovoltaic elements or has photovoltaic elements. Ferris wheel ride according to claim 12,
characterized in that
the canopy (48) is completely or partially covered, for example pasted, with flexible photovoltaic elements (36). Ferris wheel ride according to one of the preceding claims,
characterized in that
the capacity of the electrical energy storage (28) and the nominal power of all photovoltaic elements (32, 34, 36, 38, 40, 42, 44, 56) on the Ferris wheel ride (10) are dimensioned such that the operation of the Ferris wheel ride (10 ) is guaranteed to be self-sufficient, ie without additional supply of electrical energy. Ferris wheel ride according to one of the preceding claims,
characterized in that
the electric motor (26) can be switched to generator operation in such a way that the rotational energy released when the spoke wheel (12) is braked is converted into electrical energy and stored in the electrical energy storage (28).

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