Patent Application
20180229611
The methods and systems disclosed herein relate to providing energy to one or more components.
In certain industries, unpowered vehicles such as chairlifts and certain amusement park rides transport individuals from one place to another place. Such vehicles are typically attached to a system that moves the vehicles from place to place, while the vehicles themselves are merely shells to provide space to carry the individuals. In some instances, the vehicles carry radios or other low energy systems that can be powered by batteries that are charged over a long period of time prior to use. In these industries, the vehicles are in constant motion and cannot be taken out of service to recharge batteries during periods when they are in use—periods that can last for up to 10 hours or longer.
Nevertheless, there are many applications in which present batteries are insufficient. For instance, media systems comprising LCD screens require a tremendous amount of power. In addition, systems that stream media require energy sources with high energy storage capacity. Such systems require a device that can deliver the energy necessary to run these devices. However the device would also need to be charged rapidly in an environment where long periods for recharging are not available, such as in the case of a chairlift or an amusement park ride.
Therefore, there remains a need for a device that can charge rapidly, while having the energy storage capacity to deliver large amounts of energy to systems.
Disclosed herein are devices that are capable of providing large amounts of energy over a prolonged period of time to systems on a mobile unit. The disclosed devices further are capable of rapid charging so that the mobile unit can be charged while in use and there is no requirement to take the mobile unit out of service. The disclosed devices further have the capacity to power devices with very high energy demands—a feature that has not been available before this disclosure.
Aspects of the devices disclosed herein are rapid-charging devices. The devices comprise a first element connected to one or more capacitors. The one or more capacitors are connected to one or more electronic components by a conductive link. Furthermore, the first element, capacitors, and one or more electronic components are positioned on the mobile unit. These aspects also include a second element, wherein the second element is connected to an electricity source and is positioned at a location other than the mobile unit.
In certain embodiments, operation of the one or more electronic components involves the mobile unit moving into a proximity of the second element. When the mobile unit moves into the proximity of the second element, the first element is operably connected to the second element. By “operably connected,” it is meant that the second element is capable of transferring electricity to the first element. In certain embodiments, the second element is a charging coil that transfers electricity to the first element, which is also a charging coil. The transfer of electricity is contactless. In other embodiments, the second element is a member, such as a rail, to which the first element makes contact, which comprises a material that allows for the transfer of electricity when contact is made (as disclosed herein). It should be noted that in embodiments where the first element makes contact with the second element, the first element can be any structure that makes sufficient contact with the second element to allow for the transfer of electricity to the first element.
Aspects of devices disclosed herein include a rapid-charging device for powering one or more electronic components on a mobile unit. The device comprises a first charging coil connected to one or more capacitors. The one or more capacitors are connected to one or more electronic components by a conductive link. Furthermore, the first charging coil, capacitors, and one or more electronic components are positioned on the mobile unit. These aspects also include a second charging coil, wherein the second charging coil is connected to an electricity source and is positioned at a location other than the mobile unit. The first charging coil comes into operative proximity of the second charging coil as the mobile unit moves near the location of the second charging coil.
In certain embodiments, the device further comprises a voltage regulator. In other embodiments, the one or more electronic components comprise an electronic multimedia component. In still other embodiments, the electronic multimedia component comprises an electronic visual display.
In particular embodiments, the electronic multimedia component comprises a USB port. In still more particular embodiments, the one or more electronic components each comprise a battery that is connected to the one or more capacitors. In even more particular embodiments, the electronic components are selected from the group consisting of WiFi router, heating element, computer, computer-readable memory, audio system, display, charger, and radio.
In certain embodiments, the one or more capacitors are arranged in series. In some embodiments, the one or more capacitors are connected to one or more lithium batteries. In further embodiments, the one or more capacitors are connected in parallel to the one or more electronic components.
In specific embodiments, the mobile unit is selected from the group consisting of chairlift, gondola, tram, monorail, and amusement park ride. In particular embodiments, the second charging coil is located at a base station.
In certain embodiments, the second charging coil is stationary and creates a charging zone in which the first charging coil and second charging coil form an inductive couple when the first charging coil moves into the charging zone. In other embodiments, the first charging coil moves with the mobile unit into the charging zone and the one or more capacitors are inductively charged. In still other embodiments, the first charging coil moves with the mobile unit out of the charging zone and into a discharging zone whereby the one or more capacitors discharge by providing power to the one or more electronic components.
In some embodiments, the ratio of time spent by the mobile unit in the discharging zone as compared to the charging zone is at least about 5 to 1. In more embodiments, the ratio is at least about 10 to 1. In still more embodiments, the ratio is up to about 100 to 1. In even more embodiments, the electronic media component comprises one or more batteries connected to the one or more capacitors.
In yet more embodiments, the first charging coil and one or more capacitors are positioned on the mobile unit in a position in which the first charging coil is stationary. In some embodiments, the first charging coil is positioned on the grip of the chairlift. In other embodiments, the first charging coil is positioned on the safety bar of the chairlift.
Aspects of devices disclosed herein include a rapid-charging device for powering one or more electronic components on a mobile unit. The device comprises a first element connected to one or more capacitors. The first element comprises a conductive material designed to operably connect with a second element as the second element moves along the distance of the first element. The first element, capacitors, and one or more electronic components are positioned on the mobile unit.
The second element is connected to an electrical source and comprises a conductive material. In certain embodiments, the first element is a wiper or brush. In some embodiments, the first element is a brush comprising multiple wipers. In particular embodiments, the second element contacts the first element along a particular linear distance sufficient to allow for the transfer of sufficient electricity to the first element.
In particular embodiments, the first element is a wiper designed to remain engaged with the second element. In more particular embodiments, the second element is a rail to which the mobile unit is attached. The wiper can be positioned on the bottom of the mobile unit to allow for the first contact to make constant contact with the rail (e.g., the rail of a monorail, trolley, or rollercoaster). It should be noted that the second element could be the entire rail, or alternatively, portions of the rail such that charge is transferred at select positions (e.g., base stations) of the rail. In other embodiments, the second element is selected from the group consisting of a commutator, ring, segment, or bar design.
Aspects disclosed herein include a method of powering one or more electronic components located on a mobile unit. The method comprises attaching a first element to the mobile unit and connecting the first element to one or more capacitors. The one or more capacitors are further connected to one or more electronic components on the mobile unit. The aspects also include attaching a second element to a base station such that the one or more capacitors are charged when the mobile unit moves the first element into the base station to be in close proximity to the second element. As used herein, “close proximity” means a proximity sufficient to allow for the transfer of electricity from the second element to the first element. Such proximity can be contactless or contact-based.
In certain embodiments, the methods comprise charging the one or more capacitors when the mobile unit moves into the base station and discharging the one or more capacitors to power the one or more electronic components when the mobile unit moves from the base station. In some embodiments, the one or more electronic components comprise an electronic multimedia component. In other embodiments, the electronic multimedia component comprises an electronic visual display. In still other embodiments, the electronic multimedia component comprises a USB port.
In certain embodiments, the one or more electronic components each comprise a battery connected to the one or more capacitors. In particular embodiments, the electronic components are selected from the group consisting of WiFi router, heating element, computer, computer-readable memory, audio system, display, charger, and radio. In more particular embodiments, the one or more capacitors are arranged in series. In still more particular embodiments, the one or more capacitors are connected to one or more lithium batteries. In yet more particular embodiments, the one or more capacitors are connected in parallel to the one or more electronic components.
In certain embodiments, the mobile unit is selected from the group consisting of chairlift, gondola, tram, monorail, and amusement park ride. In some embodiments, the methods further comprise moving the mobile unit when outside of the base station to allow for providing of power to the one or more electronic components while minimizing the probability that the one or more capacitors will discharge completely prior to entering the base station. In other embodiments, the ratio of time spent by the mobile unit outside of the base station as compared to in the base station is up to 5 to 1. In still other embodiments, the ratio is at least about 10 to 1. In particular embodiments, the device is designed to stored enough energy to power the one or more electronic components on the mobile unit until the mobile unit reaches a base station. In more particular embodiments, the device design takes into account the time spent in the discharging zone and the time spent in the charging zone by a mobile unit. Based on the time differential, the device is designed such that the device will charge sufficiently to power the one or more electronic components while the mobile unit is in the discharging zone.
In certain embodiments, the electronic media component comprises one or more batteries connected to the one or more capacitors. In particular embodiments, the first charging coil and one or more capacitors are positioned on the mobile unit in a position in which the first charging coil is stationary. In more particular embodiments, the first charging coil is positioned on the grip of the chairlift. In yet more particular embodiments, the first charging coil is positioned on the safety bar of the chairlift.
The foregoing and other objects of the disclosed processes and systems, the various features thereof, may be more fully understood from the following description, when read together with the accompanying drawings in which:
The patent and scientific literature referred to herein establishes knowledge that is available to those of skill in the art. The issued U.S. patents, allowed applications, published foreign applications, and references, which are cited herein are hereby incorporated by reference to the same extent as if each was specifically and individually indicated to be incorporated by reference.
The disclosed devices deliver energy to one or more systems located on mobile units. As used herein, the term “mobile unit” refers to a means used to transport people or materials in an open or closed compartment. Non-limiting examples of mobile units are gondolas, trams, monorail cars, cars used in amusement park rides, chairlifts, chairs, or any other means used to move people from one location to another location at any given time.
Regarding contact-based electricity transfer, the device 200 comprises first and second elements. The first element 201 can be a wiper or brush. As provided herein, a wiper can be any design that allows for the first element to make contact sufficient to transfer electricity from the second element 202 to the first element 201. For instance, the first element 201 can be designed to make contact with a rail (i.e., the second element 202) on which the mobile unit moves. Alternatively, the first element 201 can be designed to fit onto a structure in the base station specifically molded to contact the first element. The structure of the first element 201 can be a bar, roller, flat surface (e.g., plate), block, or any structure.
In additional contact-based embodiments, the first and second elements 201 and 202 can be any conductive material that allows for transfer of electricity from the second element to the first element. Furthermore, the first 201 and second 202 elements can make contact over any particular distance to allow for the transfer of electricity to the first element.
The energy storage unit 220 of the device is connected to one or more electronic components 230. In particular embodiments, the one or more electronic components 230 are further connected to a display 240. The electronic components 230 can comprise processors and memory. In particular embodiments, the electronic component 230 is a voltage regulator. In more particular embodiments, the one or more electronic components 230 comprise one or more additional displays and other electronics, which is described more fully below. The display 240 can be a LED, LCD, or other electronic display device. Furthermore, the display 240 is capable of receiving and displaying video content, such as streamed media, mpg files, Adobe® Flash Player files, and any known video technology files.
Aspects disclosed herein provide for rapid-charging devices. In certain embodiments, the disclosed devices comprise one or more capacitors that can store a large amount of energy in a relatively short period of time as compared to standard lithium batteries. Examples of capacitors that can store a large amount of energy are super capacitors. Capacitors can be charged at much faster rates than batteries and for 500,000 to 1,000,000 cycles. Although capacitors have energy densities lower than conventional batteries, the amount of capacitance can be selected to meet the requirements of the discharge rate for a given application. Furthermore, capacitors have distinct advantages over batteries that allow for much faster charging in environments where there may not be enough time to charge conventional batteries.
The devices disclosed herein further comprise a first element (e.g., a wiper or charging coil) that is connected to the one or more capacitors. In particular embodiments, the first charging coil is designed to convert an electromagnetic field from a second charging coil into an electrical current. As the first charging coil comes into a proximity to a second charging coil, the first charging coil enters into the electromagnetic field of the second charging coil. The first charging coil converts the electromagnetic field into an electric current that is provided to the capacitors for storage.
In certain embodiments, the second element is located at a base station. As used herein, the term “base station” refers to a location in which one or more second charging coils are located. Base stations can be located at any position where a mobile unit will move a first element into a close proximity to the one or more second elements to allow for the charging of the capacitors. In certain embodiments, base stations are at fixed positions such as in at the ends of ski lifts. Base stations can also be located on poles, towers, rails, or any position that allows the second charging coil to come into a proximity of the first charging coil of the disclosed devices.
Additionally, base stations can be located at multiple positions for access to a mobile unit. For example, there can be a base station located at the bottom of a ski lift such that each chairlift (i.e., mobile unit) comes into close proximity to one or more second elements. There can also be multiple additional base stations located along the ski lift route up the mountain and at the top of the mountain. Thus, there can be a nearly innumerable number of base stations along the route that the chairlifts take.
It should be noted that each base station thus defines a “charging zone.” The charging zone is the region in which the first and second elements are in proximity such that the capacitors receive an electric current. Thus, the “charging zone” can be defined by distance or the time spent by a mobile unit in the charging zone. When the mobile unit leaves the close proximity of the second element in the base station, the mobile unit enters the “discharging zone.” The discharging zone is the region where the one or more capacitors discharge their stored energy to one or more electronic components located on the mobile unit. As with the charging zone, the “discharging zone” can be defined by distance or the time spent by a mobile unit in the discharging zone.
In some embodiments, the systems disclosed herein comprise a “standby zone.” The “standby zone” is a feature in which the mobile unit is in a power down mode to conserve energy. In some embodiments, the standby mode occurs when the mobile unit is empty and the one or more electronic components are in off or power save mode. In other embodiments, the “standby zone” overlaps with the “charging zone” and the capacitors of the device are charged.
In certain contactless embodiments, the first and second charging coils are tuned to resonate at the same frequency. In some embodiments, the device further comprises a resonance transformer. In other embodiments, the second charging coil is configured to generate an oscillating current. In further embodiments, the first and second charging coils resonate to extend the charging zone range.
As would be clear to one of ordinary skill in the art from this disclosure, the time spent in the charging zone can be tailored to the particular requirements of the particular ride. For example, the charging zone can be made large enough such that it is approximately 20 times smaller than discharging zone—establishing a ratio of discharging zone time to charging zone time of 20 to 1. This can be accomplished by placing a certain number of second charging coils in the base station to tailor the range of the charging zone. The ratio can be as low as 1 to 1, 5 to 1, 10 to 1, 20 to 1, 30 to 1, 40 to 1, 50 to 1, 60 to 1, 70 to 1, 80 to 1, 90 to 1, or as high as 100 to 1, 150 to 1, 200 to 1, 250 to 1, 300 to 1, 350 to 1, 400 to 1, 450 to 1, 500 to 1, or even greater. The charging and discharging zone ratios can be defined by the time that a mobile unit spends in each zone and is defined by the speed of the mobile unit set by the operator of the units. For example, a mobile unit can spend 30 seconds in a charging zone and have sufficient power stored in the presently disclosed device to be in the discharging zone for extended periods of time (such as 15 minutes or longer). Another example would be a mobile unit entering a base station and traveling for one minute in the base station charging zone and remaining in the discharging zone for 30 minutes. The only limitation is the number of electronic components on the mobile unit as compared to the number of capacitors provided in a device, as well as the available charging current and the time in the charging zone.
Furthermore, the ratio of time in the charging zone to discharging zone depends on the individual application. One of ordinary skill in the art will recognize that a higher power draw in the discharge zone requires more charging time and/or higher charge currents. The current draw of a capacitor is a function of the total capacitance and the rate of change of the capacitor voltage with respect to time. Thus, a higher rate of change of voltage in the capacitor during charging equates to a higher current requirement
The charging zone to discharging zone ratios depend on the ability of the one or more capacitors to absorb a high current in a short period of time, while discharging the stored energy over a longer period of time. By way of example only, the second charging coil can be connected to a power source that allows the second and first charging coils—when coupled—to transmit about 50 amps, about 100 amps, about 200 amps, or more to a capacitor. This can be accomplished at low voltages of about 5 volts or much higher voltages. In some embodiments, the device comprises one or more capacitors having a maximum voltage for each capacitor is 2.85 volts. Other voltages are possible for each capacitor. For instance, super capacitor have a predetermined maximum voltage that it can tolerate.
For example, when 100 amps at 5 volts is provided to the capacitor, this equates to 500 watts of power stored in the capacitor in a short period of time. However, one of ordinary skill in the art would recognize that the amount of power stored by the capacitors can be any amount that is necessary to provide power to the one or more electronic components during the entirety of the discharging zone. For instance, the device can store from about 10 watts of power to about 1000 watts or more. The amount of energy stored in the device is governed by the number of capacitors and the power source connected to the second charging coil. As used herein, the term “about” means+/−15% from the absolute number. For example, “about 20” would include from 17 to 23.
It should be noted that capacitors can draw large currents. An empty capacitor looks like a short circuit and will draw very large currents. This current is limited by an inline resistor or a current limited power supply. Once the capacitor begins to charge, the current tapers off until the capacitor reaches the charging voltage. The devices disclosed herein are only limited by the voltage rating of the capacitors (additive in series) and the current capacitor of the charging coils. The current limitation can be with the inductive interface.
Additionally, the period of time required to store the power can be less than about 30 seconds, about 30 seconds, less than about 1 minute, less than about 2 minutes, or a period of time that is allowed by the speed of the mobile unit. The amount of time needed to store the required power is governed by the power requirement of the electronic components on the mobile unit and the length of time that the mobile unit will be in the discharging zone, as well as the current limit of the inductive charging apparatus. As such, the disclosed devices can have a variable number of capacitors to store the required energy and the second charging coil can be connected to a sufficient power source to allow for enough electricity to be provided to the capacitors in the device.
When the device enters the discharging zone, the capacitors of the disclosed devices release the energy at lower currents. For example, a capacitor in the disclosed devices that received about 500 watts can discharge this energy to the one or more electronic components at currents of less than about 10 amps, less than about 5 amps, or about 1 amp at a voltage of about 5 volts. This equates to a power of about 5 watts released to the electronic components on the mobile unit. In such embodiments, the device stores a large amount of energy rapidly while releasing the energy more slowly. In certain embodiments, the devices comprise a voltage regulator to assist in maintaining a consistent voltage. In some embodiments, the one or more capacitors are connected to one or more batteries (e.g., lithium batteries).
In particular embodiments, the devices comprise a plurality of capacitors that are arranged in series when they are charged. As shown in
Aspects of the devices disclosed herein comprise the first charging coil and second charging coil that each can comprise a material selected from the group consisting of 6H40, MnZn ferrite core materials, nickel, copper-ferrite core material, ETD-49 core (EPCOS AG), and materials listed in Table 1 below.
In particular embodiments, the first 201 and second 202 charging coils both comprise the same materials. In other embodiments, the first charging coil 201 comprises a material that is different from the second charging coil 202.
It should be noted that the device can be located at any position on the mobile unit so long as the position allows the first element to come into a close proximity of the second element to allow for transfer of electricity from the second element to the first element. In certain embodiments, this transfer is performed by contactless transfer such as inductive coupling. For example, the chairlifts 110 of
In particular embodiments, the mobile unit comprises an electronic multimedia component comprising a mounted display. The mounted display can be a high-definition screen such as an LCD, LED, LCD-LED. The display can show images or video, such as streamed video. In other embodiments, the electronic multimedia component comprises a USB port. In particular embodiments, the electronic multimedia component comprises computer-readable memory. Such memory allows for the storage of data such as streaming data, email data, text data, video data, or messaging. In other embodiments, the electronic multimedia component comprises streaming capabilities.
The electronic multimedia component can also comprise WiFi technology, one-way radio, two-way radio, and routers. In certain embodiments, a mobile unit is a wireless access point. In particular embodiments, the mobile unit allows for public service announcements, instant messaging, and advertisements. The presently disclosed devices provide sufficient power to the mobile units to allow for other types of media such as movies, television shows, and other high power-demand content to be shown on a display located on the mobile unit.
In further embodiments, each mobile unit 110 of
In certain embodiments, the multimedia component 160 comprises a processor and memory. The memory stores instructions that are executable by the processor. In particular embodiments, the processor executes instructions to show a video or series of images. In other embodiments, the processor executes instructions so as to respond to a command from a user of the multimedia component 160. For instance, the multimedia component 160 can comprise a touchscreen responsive to a user's commands. In some embodiments, the multimedia component 160 comprises executable instructions allowing users to play videogames, connect with the internet, select media from a library, or connect with devices such as Smartphones or wireless media devices.
The presently disclosed devices can also power other electronic components. Such components comprise seat warmers that remain warm during the entire time that a mobile unit is away from the charging region. Other electronic components include lights, amusement effects such as vibrating components in scats, loudspeakers, speakers, and any type of device that utilizes electricity.
Additionally, the disclosed devices can be used in almost any context in which a mobile unit does not have the capacity to power one or more electronic devices without resorting to onboard power storage. Examples of such applications include amusement park rides such as rollercoasters and other rides in which a mobile unit is moved from a first point to a second point. Other examples include trams, monorails, gondolas, or any vehicle, car, or other mobile unit moves from a first location to a second location and comprises electronic components that cannot be powered by the mobile unit.
Disclosed herein are methods of powering one or more electronic components located on a mobile unit. The methods can comprise the attaching of a first element (e.g., first charging coil or wipers) to a mobile unit. The first element is then connected to an energy storage unit that is also attached to the mobile unit. The first element and the energy storage unit can be located in the same position on the mobile unit or can be attached to different locations on the mobile unit. Additionally, the first element and energy storage unit can be located in a container. In certain embodiments, the container is weatherproof.
Aspects of the methods include attaching a second element (e.g., second charging coil or electrical contact such as a rail) to a base station. The second element is positioned on the base station such that the first element comes into a close proximity of a second element attached to the base station. When the first element comes into close proximity of the second element, the energy storage unit is charged. In certain embodiments, the energy charging unit comprises one or more capacitors such super capacitors.
In particular embodiments, the method includes the discharging of one or more capacitors to power one or more electronic components as the mobile unit moves out of the base station and enters a discharging zone. The one or more capacitors power the one or more electronic components more the energy stored in the one or more capacitors until the mobile unit reaches another base station.
The methods further comprise attaching one or more second elements at each one of multiple positions to allow a mobile unit to come into a close proximity of second elements along the route that the mobile unit takes. In some embodiments, the mobile unit moves through multiple charging zones during as moves along a particular route. In particular embodiments, the mobile unit moves when outside of the base station to allow for providing of power to the one or more electronic components while minimizing the probability that the one or more capacitors will discharge completely prior to entering the base station
In addition, the methods further can comprise connecting the one or more capacitors to one or more batteries (e.g., lithium batteries). The one or more capacitors can be connected serially to the first charging coil. In some embodiments, the one or more capacitors are connected in parallel to the one or more electronic components.
Aspects of the disclosed methods include providing power to one or more electronic components on a mobile unit in which the mobile unit is one of a plurality of mobile units forming a system. In certain embodiments, each mobile unit communicates with another mobile unit in the system. In other embodiments, each mobile unit allows users riding in the unit to communicate with other users riding in other mobile units in the system. In still other embodiments, each mobile unit comprises a router that allows for the mobile unit to become a WiFi hot spot. In particular embodiments, the mobile units create a WiFi network in the system. In still other embodiments, each mobile unit allows for the streaming of media content to the users riding in the unit and allows for content to be delivered from one mobile unit to another.
Aspects of the methods disclosed herein include mobile units comprising one or more media devices to create a multimedia experience in the system. For instance, each mobile unit can share media content with other mobile units and can store content in computer-readable memory. Each mobile unit in the system can also create an entertainment experience by syncing lights and audio between the mobile units within the system.
As noted herein, the disclosed devices and methods allow for all of these possibilities due to the increased power storage of the disclosed devices, as well as the increased rapidity by which energy can be stored in the device as compared to prior known storage devices. As such, the disclosed device and methods now allow for improved amusement rides, ski lifts, trams, monorails, gondolas, and other mobile units that heretofore were restricted due to the power consumption of modern devices. One of ordinary skill in the art will also recognize that the disclosed embodiments are illustrative and that equivalents of such embodiments also fall within the scope of this disclosure.
This application claims the benefit of priority of Provisional Application Ser. No. 62/055,358, which was filed on Sep. 25, 2014 and the contents of which are incorporated in their entirety.
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/US15/52396 | 9/25/2015 | WO | 00 |
| Number | Date | Country | |
|---|---|---|---|
| 62055358 | Sep 2014 | US |
