WO2024138240A1 - Method for generating energy - Google Patents

Abstract

The invention relates to a method for generating energy using at least one energy generation device (4) which can be moved by a haulage means (6), wherein the haulage means (6) can be driven via a drive device (9). To provide an economical and efficient method, in order to activate the energy generation, the energy generation device (4) switches from a park mode, in which the energy generation device (4) located in a storage region (5) is decoupled from the haulage means (6), into an operating mode, in that the energy generation device (4) is conveyed out of the storage region (5), coupled directly to the haulage means (6) and connected to a power supply network (10).

Description

Process for energy generation

Technical area

The invention relates to a method for generating energy with at least one energy generation device that can be moved by a towing means, wherein the towing means can be driven by a drive device. The invention also relates to a method for converting a cable car into a power station, wherein the cable car has a towing means that can be driven by a drive device and on which transport means that can be coupled and uncoupled are arranged. Finally, the invention also relates to a device for generating energy with at least one energy generation device that can be moved by a towing means, wherein the towing means can be driven by a drive device.

State of the art

Cable cars for the transport of people with towing devices that can be driven by a drive system and, for example, lift cabins as a means of transport are known to be used for ski tourism in winter and for cycling and hiking tourism in summer. Due to the seasonal, weather and time-of-day dependent operating times, the cable cars regularly have downtimes. However, the increasing energy and maintenance costs for operating cable cars, as well as a possible lack of tourists, are increasingly reducing the profitability of operating such cable cars. In order to improve the profitability on the one hand and the ecological aspect on the other, it is known to install wind or photovoltaic systems in the local vicinity of the cable cars and use the electricity produced to operate them. However, such installations involve considerable investment costs and are often not accepted by local residents who do not like the changed landscape. In addition, the construction of wind farms and photovoltaic systems represents a significant intervention in nature, meaning that the construction of such systems, particularly in nature reserves, is associated with legal costs.

To avoid this, it is known from CN208789668U that means of transport, such as lift cabins, of the cable car can be equipped with energy generation devices that use the energy generated to operate the cabin's electrical system. However, this means that energy generation only takes place when people are being transported, so that although part of the energy required for transport can be covered, the capacity of the cable car is not increased. When not in use, the lift cabins must be garaged in a storage area with the energy generation devices arranged on them in accordance with regulations.

Description of the invention

The invention is therefore based on the object of creating a method and a device for generating energy which increases the utilization, profitability and efficiency of infrastructure with drivable towing means, in particular of cable cars, without causing a significant impact on the landscape. In particular, the invention is also based on the object of providing a method for converting a cable car, by means of which the utilization, profitability and efficiency of the cable car is increased without causing a significant impact on the landscape.

The invention solves the problem in that, in order to activate the energy generation, the energy generation device changes from a parking mode, in which the energy generation device located in a storage area is uncoupled from the towing means, to an operating mode in which the Energy generation equipment is transported from the storage area, directly coupled to the towing vehicle and connected to a feed-in network.

As a result of the measures according to the invention, the towing means of, for example, an existing infrastructure, in particular a cable car, can be used to move the energy generation device, preferably from several energy generation devices. Since the energy generation device is directly connected to the towing means in operating mode, i.e. in particular is not arranged as an intermediate piece on a cable car lift cabin coupled to the towing means, the energy generation device can be transported out of the storage area and connected to a feed-in network independently of other components of the existing infrastructure. Since the energy generation devices can be moved independently of other infrastructure, in particular means of transport such as lift cabins, towing hooks, etc., energy generation can also take place outside of passenger transport operations, which means a significant increase in the utilization of any existing system. Because the energy generated is fed into a feed-in network, it can not only be used for internal operation, but also for operating surrounding infrastructure. The energy generation devices can have coupling clamps for coupling and uncoupling to the towing device, similar to typical lift cabins, whereby the energy generation devices can be garaged in and out of the parking mode, similar to lift cabins. This means that both the control and the drive device for moving the energy generation device from the storage area to an operating area, i.e. for changing from parking mode to operating mode, can be taken over by existing infrastructure, in particular cable cars, so that no external, resource-intensive systems have to be built. Solar cells and/or wind turbines can be used as energy generation devices, as described in more detail below. These can feed the energy generated into a preferably terrestrial feed-in network. In this way, the energy can be used for typical Consumers located in the vicinity of a cable car can be used, for example for snow cannons or the like.

In order to be able to use existing infrastructure in a particularly cost-effective manner, it is proposed that the towing means is a traction means of a cable car comprising means of transport and that the energy generation device for changing between parking and operating mode is coupled to and uncoupled from the towing means independently of the means of transport. Lift cabins, towing brackets, towing plates or the like can be used as transport means. Conveyor ropes known from the state of the art, in particular cable car ropes, can be used as traction means.

In a very simple embodiment, the energy generation devices can be manually coupled to or uncoupled from the towing device in order to change from parking mode to operating mode. In this case, the transport from the storage area of the energy generation devices to the towing device is also carried out manually. In order to be able to automate this process as much as possible, especially in large lift systems, it is recommended in a particularly efficient embodiment of the method according to the invention that the change of the energy generation device from parking mode to operating mode is specified by a control unit which controls the mode change depending on the weather data and/or sensor data made available to the control unit. In this way, energy generation devices can, for example, only be taken out of the garage (by driving them out of the storage area and coupling them to the towing device) and thus controlled to change from parking mode to operating mode if this is economical and/or operationally safe according to the specified data. In the case of wind turbines as energy generation devices, for example, a change to the operating mode may not occur or a change to the parking mode may be forced if there is no wind or if the wind strength is too high. In the case of solar cells as energy generation devices, for example, a change into operating mode or a change to parking mode may be forced if the sun is not shining or if the wind strength is too high. If both wind turbines and solar cells are present as energy generation devices in the storage area, the weather data and/or sensor data can be used to determine which of the energy generation devices is more economical under the current conditions. The weather data can be obtained from online databases, for example. The sensor data can be obtained from sensors distributed along the towing device, which can in particular be wind sensors and/or solar sensors. Data on the utilization of the cable car, for example obtained via a turnstile or a video sensor, can also be used as sensor data, so that in the event of low utilization, transport vehicles can be uncoupled from the towing device and the space freed up on the towing device can be used by an energy generation device.

In principle, the energy generation devices can of course supply energy to the feed-in network as soon as they have switched from parking mode to operating mode and are connected to the feed-in network. For example, it is conceivable that the energy generation devices are used during passenger transport operations, for example when the means of transport are only used to a small extent, and thus generate energy while the towing device is powered. However, in order to further increase the efficiency of the energy generation devices, the at least one energy generation device can be driven into an operating area after being coupled to the towing device. The operating area is characterized by particularly favorable conditions with regard to energy generation, for example by a demarcated area running along the towing device with high wind speeds or with high solar radiation intensity. The energy generation devices can thus be driven into this operating area via the towing device and preferably kept stationary there. The operating area can be fixed or redefined in a time interval of, for example, 24 hours, preferably 12 hours. For The weather data and/or sensor data can preferably be used to define the operating range. Preferably, a certain operating range is only specified until, depending on the weather or sensor data, a better operating range is determined in terms of the efficiency of the energy generation devices, after which the energy generation device is moved into the newly determined operating range by the entraining agent, whereby the energy generation device is preferably only moved if the difference between the expected amount of energy produced in the new operating range and the expected amount of energy produced in the original operating range in a time interval x is greater than the amount of energy required to move the energy generation device to the new operating range. As a result, the energy generation device or the group of energy generation devices are only moved to the new operating range if this makes sense in terms of energy. The time interval x can be, for example, 12h, 6h, 3h, 1 h, 0.5 h.

The control unit can specify different operating modes of a cable car:

Gondola operation: Here, the energy generation device or devices are installed and operated on the cable car during gondola operation, i.e. during passenger transport. This could be useful, for example, if the lift cabins or gondolas are not being used to full capacity and additional capacity is available to operate the energy generation devices.

Night operation: In this case, the energy generation device or devices are arranged in operating mode on the towing device overnight, with the towing device standing still. This could be useful, for example, if the cable car is not used to transport people at night. Continuous operation: In this embodiment, the energy generation devices are continuously attached to the towing device, whereby the towing device is basically stationary unless the control unit specifies a different operating area where better conditions prevail. This continuous operation can be used, for example, if the cable car is not used at all for passenger transport outside of the season.

In order to ensure that the movement or relocation of the energy generation device(s) itself is as energy-efficient as possible and at the same time protects them from any gusts of wind, it is proposed that the aerodynamic front surface of the energy generation device be adjustable in size. The aerodynamic front surface is understood to be the projected area that the shadow of the energy generation device casts in the longitudinal direction of the towing device. In this way, the area of contact of the energy generation devices can be reduced when being transported to the operating area so that they generate less resistance, which means that less traction has to be transferred from the drive to the towing device. In operating mode, the aerodynamic front surface can be extended again, resulting in a larger active area, for example a solar area or wind blade area, so that a larger amount of energy can be produced.

With regard to energy dissipation, particularly favorable conditions arise when the energy generated by the energy generation device is transported to the feed-in network via a power line that runs along the towing means. The power line can be, for example, a busbar that runs along, preferably parallel to, the towing means and that is in contact with the energy generation device. The power line can also be formed, for example, by the support and/or conveyor cables of the cable car. In a very simple embodiment, the power line can be a power cable that runs between several energy generation devices arranged one behind the other on the towing means and is in contact with them. In this case, the energy generation devices can preferably be provided with a A guying device can also be arranged downstream of the towing device, which tightens the power cable and thus prevents the power cable from getting caught in any turbine blades or other obstacles. The guying device can also form the connection point to the feed-in network. The electricity fed into the feed-in network can be used in hydrogen production plants, for example. In particular, snowmaking systems can be supplied with energy.

Using the method according to the invention, a cable car can thus be converted into a power plant, wherein the cable car has a towing means that can be driven via a drive device and on which transport means that can be coupled and uncoupled are arranged, wherein the cable car is equipped with at least one energy generation device that is designed to switch from a parking mode, in which the energy generation device located in a storage area is uncoupled from the towing means, to an operating mode in order to activate the energy generation, in that the energy generation device is transported out of the storage area independently of the transport means, coupled directly to the towing means and connected to a feed-in network. Thus, a method for generating electricity by means of a cable car power station is provided, comprising the steps of: a) removing at least one energy module (energy generating device) from the parking position (parking mode) in the cable car station, b) coupling at least one energy module (energy generating device) to a conveyor cable (towing means) of a cable car, c) transporting the energy module (energy generating device) out of the cable car station, d) generating electricity by at least one energy module (energy generating device) on the conveyor cable and feeding the generated electricity into a private power grid and/or a public power grid and/or an energy storage device (feed-in network), wherein the energy modules (energy generating device) convert wind and/or solar energy into electrical current.

The method according to the invention can be carried out with a device for

Energy generation with at least one movable by a towing device Energy generation device, wherein the towing means can be driven via a drive device. In order to increase the utilization, cost-effectiveness and efficiency of infrastructure with drivable towing means, in particular cable cars, without causing a significant impact on the landscape, it is proposed that the energy generation device has a hanger for direct coupling to the towing means and can be moved or changed between a parking mode, in which the energy generation device is located in a storage area and is uncoupled from the towing means, and an operating mode in which the energy generation device is coupled to the towing means, arranged outside the storage area and connected to a feed-in network. Direct coupling in the context of the invention means that the energy generation device itself has a hanger and does not use the hanger of another means of transport, such as that of a lift cabin. The energy generation device can be connected to the hanger, for example, via a lightweight frame. The hanger of the energy generation device can comprise a roller battery. Preferably, the suspension comprises a detachable clamp, which allows particularly easy coupling and uncoupling to the towing device.

In order to be able to use the device not only for energy generation but also for transporting people, it can comprise at least one means of transport, whereby the means of transport and the energy generation device can be coupled to and uncoupled from the towing device independently of one another. In this way, the device can be used both for transporting people for tourist purposes and for energy generation. Since the means of transport and the energy generation device can be connected to the towing device independently of one another, the device can be flexibly adapted to current requirements. In a peak tourist season, the towing device can therefore be equipped primarily with means of transport, for example lift cabins, towing bars, etc., while when there is little tourist traffic, energy generation devices can be arranged on the towing device. The energy generation device can comprise a solar cell and/or a wind turbine. Wind turbines that can be used include, for example, wind turbines with two-blade rotors, with three-blade rotors, horizontally aligned wind turbines, vertically aligned wind turbines, Darreius wind turbines, H-shaped wind turbines, Savonius wind turbines. Photovoltaic modules in particular can be used as solar cells. The different energy generation devices can be garaged separately from one another in groups, so that groups of certain energy generation devices can switch to operating mode independently of other groups in order to use only those energy generation devices that have the highest efficiency under the prevailing weather conditions. In addition, a combination of wind turbines and solar cells, in particular photovoltaic modules, can be used, which makes electricity generation from renewable energy sources even more effective. The individual energy generation devices can be equipped with appropriate buffer storage modules, such as battery packs or capacitors, for temporarily storing energy.

To easily control the change between passenger transport operation and energy generation, the means of transport and the energy generation device can be arranged in separate storage areas in parking mode. In this way, the means of transport and the energy generation devices can be garaged independently of each other, so that the towing device can be quickly equipped with the desired equipment (means of transport or energy generation device).

The aerodynamic front of the energy harvesting device can be adjustable in size. In particular, the energy harvesting devices can change their horizontal orientation and/or their geometry and/or their size after leaving the storage area, for example a cable car station. In this way, they offer less Surface area for possible gusts of wind, so that less force has to be applied via the towing device.

In order to be able to generate sufficiently high power, it is proposed that several energy generation devices are electrically coupled via at least one power line. The energy generation devices can be connected in series via a power line. Alternatively, the energy generation devices can be connected to a busbar, via which a parallel connection is made. Contact with the busbar can be made via a sliding contact on the hanger of an energy generation device.

Brief description of the invention

The drawing shows the subject matter of the invention as an example.

Fig. 1 is a schematic representation of the device according to the invention,

Fig. 2a shows a first embodiment of an energy generation device,

Fig. 2b shows a second embodiment of an energy generation device,

Fig. 3a shows a third embodiment of an energy generation device,

Fig. 3b shows a fourth embodiment of an energy generation device,

Fig. 4a shows a fifth embodiment of an energy generation device in

Transport position,

Fig. 4b the embodiment of Fig. 4a in energy generation position and

Fig. 5 shows a sixth embodiment of an energy generation device with a hanger, which can be used in all embodiments.

Ways to implement the invention

In Fig. 1, a cable car 1 with a valley station 2, with gondolas as means of transport

3, with energy modules designated as energy generation facilities 4 in storage areas 5, with a conveyor rope as a towing device 6, with a mountain station 7 and with a power line 8 for the discharge of the generated energy, shown schematically.

A device for generating energy according to the invention has, as can be seen in particular from this Fig. 1, at least one, preferably several, energy generation devices 4, which can be moved via the towing means 6, for example a conveyor cable, preferably between a valley station 2 and a mountain station 7. The towing means 6 is driven in a known manner via a drive device 9. The energy generation devices 4 can be moved between a parking mode, in which the energy generation devices 4 are located in a storage area 5 and are uncoupled from the towing means 6, into an operating mode by coupling the energy generation devices 4 to the towing means 6, arranging them outside the storage area 5 and connecting them to a feed-in network 10. A garage in the valley station 2 or mountain station 7 can serve as the storage area 5, for example. The storage area 5 can comprise a guide device F for moving the energy generation devices 4 to the towing means 6.

The change of the energy generation device 4 or the energy generation devices 4 from parking mode to operating mode can be specified by a control unit S. This can control the mode change, i.e. the change between parking mode and operating mode, depending on the weather data and/or sensor data made available to the control unit S. The control of the control unit S can, for example, be wireless.

As can be seen in particular from Figs. 4a, 4b and 5, the energy generation devices 4 have a suspension 11. By means of this suspension 11, the energy generation devices 4 can be coupled directly to the towing means 6, so that they do not have to be arranged on the transport means 3, for example, but can be coupled to or uncoupled from the towing means 6 independently of these. The energy generation devices 4 can be connected to the feed-in network 10 via a power line 8. The power line 8 can be, for example, a busbar into which sliding contacts K of the energy generation device 4 engage (Fig. 1). Several energy generation devices 4 can be electrically coupled to one another via at least one power line 8.

From Fig. 1 it can be seen that the means of transport 3 and the energy generation devices 4 can be arranged in separate storage areas 5 in parking mode. In this way, it is possible to quickly switch between passenger transport operation and energy generation operation.

Fig. 2a shows that a wind turbine 4b with a 2-blade rotor can be used as the energy generation device 4, which has an enlarged attack surface by extending the rotor blade extensions 13 and can therefore convert more wind energy into electricity. This means that the aerodynamic front side of the energy generation device 4 can be adjusted in size. The rotor blade extensions 13 can comprise PV modules as solar cells 4a or can be covered with them in order to generate additional solar power. When entering the station or in strong gusts of wind, the mechanical adjustment of the size can also be advantageous in order to reduce the wind attack surface and thus protect the turbine. The flow surface of the energy generation device can have a surface area of 2 - 100 m ² , preferably 10 - 50m ² , more preferably 15 - 40m ² when extended. It has been shown that, depending on the design and execution, the increase in the area exposed to the flow between retracted rotor blades and extended rotor blades can be between a factor of 1 and 20, preferably 1 and 10, even more preferably 1 and 5. The performance of the wind turbine at 1 -30 m/s wind can be between 0.1 and 500 kW, preferably 0.5 and 100 kW, even more preferably 1 to 50 kW, depending on the design.

Fig. 2b shows a horizontal wind turbine 4b as an energy generation device 4.

The rotor blade extensions 13 can be extended to to vary the area exposed to the flow. The technical specifications can be analogous to the embodiment according to Fig. 2a.

Fig. 3a shows an example of a 3-part energy generation device 4 made up of 2 PV surfaces as solar cells 4a and a wind turbine 4b. After leaving the station, in particular the storage area 5, the energy generation device 4 can enlarge the area using a sliding mechanism along the towing means 6. The PV surfaces per sliding part can be 5-100m ² , preferably 10 to 50m ² , even more preferably 20-40m ² in size and can supply solar power between 1 kWp (kilowatt peak) and 100kwP, preferably 5 to 50kwP, even more preferably 10 to 40kwP. The wind turbine 4b in the middle can be between 10-50m2 in size and generate 1-50kW of power. The side PV parts can be shaped so that they direct the wind towards the wind turbine 4b. Fig. 3b shows a similar embodiment with a vertical extension mechanism.

A further embodiment is shown in Figs. 4a and 4b, according to which the wind surfaces 14 of the wind turbine 4b as energy generation devices 4 partially consist of PV surfaces (solar cells 4a) in order to generate additional electricity from sunlight. This could help to enable electricity generation around the clock and increase the effectiveness of the device. A further embodiment is that the wind turbines 4b are adaptable and automatically adjust to the wind direction in order to maximize the effectiveness of electricity generation. This can be achieved, for example, using sensors and control technologies. Fig. 4a shows that the energy generation device 4 is retracted (transport position) and in this state can only generate solar power. Fig. 4b shows the same energy generation device 4 with the wind surfaces 14 extended (energy generation position), which can also generate wind power.

According to Fig. 5, the coupling or uncoupling to a towing device 6 can be carried out via a detachable clamp 12. This detachable clamp 12 can also be used in all other embodiments. The The suspension 11 comprises a roller battery 15 which is arranged to be movable on support cables 16.

Claims

Patent claims 1. Method for generating energy with at least one energy generation device (4) that can be moved by a towing means (6), wherein the towing means (6) can be driven via a drive device (9), characterized in that to activate the energy generation, the energy generation device (4) changes from a parking mode, in which the energy generation device (4) located in a storage area (5) is uncoupled from the towing means (6), to an operating mode in which the energy generation device (4) is conveyed out of the storage area (5), coupled directly to the towing means (6) and connected to a feed-in network (10). 2. Method according to claim 1, characterized in that the towing means (6) is a traction means of a cable car (1) comprising transport means (3) and that the energy generation device (4) is coupled to the towing means (6) and uncoupled from the towing means (6) independently of the transport means (3) in order to change between parking and operating mode. 3. Method according to claim 1 or 2, characterized in that the change of the energy generation device (4) from the parking mode to the operating mode is predetermined by a control unit (S) which controls the mode change depending on weather data and/or sensor data made available to the control unit (S). 4. Method according to one of claims 1 to 3, characterized in that the at least one energy generation device (4) is moved into an operating area after coupling to the towing means (6). 5. Method according to claim 4, characterized in that the operating range (6) is specified as a function of weather data and/or sensor data. 6. Method according to one of claims 1 to 5, characterized in that the aerodynamic front surface of the energy generation device (4) is adjustable in size. 7. Method according to one of claims 1 to 6, characterized in that the energy obtained by the energy device (4) is transported to the feed-in network (10) via a power line (8) guided along the towing means (6). 8. Method for converting a cable car (1) into a power station, wherein the cable car (1) has a towing means (6) which can be driven via a drive device (9) and on which transport means (3) which can be coupled and uncoupled are arranged, characterized in that the cable car (1) is equipped with at least one energy generation device (4) which, in order to activate the energy generation, is set up to change from a parking mode in which the energy generation device (4) located in a storage area (5) is uncoupled from the towing means (6) to an operating mode in which the energy generation device (4) is conveyed out of the storage area (5) independently of the transport means (3), coupled directly to the towing means (6) and connected to a feed-in network (10). 9. Device for generating energy with at least one energy generation device (4) that can be moved by a towing means (6), wherein the towing means (6) can be driven via a drive device (9), characterized in that the energy generation device (4) has a hanger for direct coupling to the towing means (6) and can be shifted between a parking mode, in which the energy generation device (4) is located in a storage area (5) and is uncoupled from the towing means (6), into an operating mode, in which the energy generation device (4) is coupled to the towing means (6), arranged outside the storage area (5) and connected to a feed-in network (10). 10. Device according to claim 9 with at least one transport means (3), wherein the transport means (3) and the energy generation device (4) can be coupled to the towing means (6) and uncoupled from the towing means (6) independently of one another. 11. Device according to claim 9 or 10, characterized in that the Energy generation device (4) comprises a solar cell (4a) and/or a wind turbine (4b). 12. Device according to one of claims 9 to 11, characterized in that the transport means (3) and the energy generation device (4) are arranged in separate storage areas (5) in the parking mode. 13. Device according to one of claims 9 to 12, characterized in that the aerodynamic front side of the energy generation device (4) is adjustable in size. 14. Device according to one of claims 9 to 13, characterized in that several energy generation devices (4) are connected via at least one Power line (8) are electrically coupled.