The present application relates to a portable rope tow assembly device primarily used for transporting skiers, snowboarders, tubers or other people involved in snow-related activities up inclines that otherwise would be difficult, or time-consuming, to traverse on foot.
Many prior art rope tow devices are large, bulky, permanent or semi-permanent fixtures employed near the bottom of small hills used for new or beginner level skiers and snowboarders. As such, they tend to transport skiers relatively slowly up the incline. Other prior art rope tow devices are designed to be temporary and portable. These portable prior art systems use gasoline engines, are loud, and typically require many people and a great deal of effort to set-up and secure for safe operation. As such, there has not been a significant commercial market for these portable gasoline rope tow systems. Another drawback with these gasoline systems is that they typically operate at a constant speed, which may be too slow for some situations and too fast for other applications.
For temporary applications such as sporting events, exhibitions, or competitions, there remains a need for a lightweight, portable rope tow device that can be set up quickly, is robust and reliable, emits low noise during operation, and capable of transporting users uphill at a controllable rate.
The invention is a portable rope tow assembly having a portable drive unit with an electric motor and an electric power converter comprising a variable frequency drive. The assembly also includes a return unit. The transport rope is looped continuously around drive pulleys and idlers pulleys in the drive unit and around idler pulleys in the return unit. The assembly is suitable for transporting skiers, snowboarders and the like uphill at a variety of speeds while minimizing mechanical noise.
In addition to the electric motor and the power converter using a variable frequency drive, the portable drive unit includes a pair of drive pulleys that are each rotated by a belt driven by the electric motor. The portable drive unit also includes a pair of idler pulleys. The transport rope passes around each drive pulley and a respective idler pulley. The drive pulleys and the idler pulleys are aligned in a generally horizontal plane when the portable drive unit is set flat on a level surface. Also, the drive pulleys are desirably made of rubber and grooved, and the position of the idler pulleys with respect to the drive pulleys is such that the transport rope contacts the grooved drive pulleys for 180 degrees or more as the transport rope is driven around the respective grooved drive pulley. Desirably, the grooved drive pulleys of the portable drive unit also each have a groove cross section configured to receive a single wrap of rope and wedge the rope within the groove when the rope enters the respective drive pulley.
The return unit is located at the opposite end of the loop of transport rope and is normally installed on the downhill end of the assembly with the drive unit on the uphill end. The return unit has two laterally displaced idler pulleys on a frame in order to separate the uphill moving portion of the transport rope from the downward moving portion of the transport rope. While the return unit can staked or tethered in place when the rope tow assembly is in use, it is preferred to hold the frame and laterally displaced idler pulleys with straps and a steel cable come along that is staked or anchored in the snow or tethered to a stationary object like a tree. The come along is tightened to ensure sufficient tension is present on the transport rope to enable the drive unit to reliably drive the transport rope when the rope tow assembly is in use.
The portable rope tow assembly may also include a rope tensioner to reduce slack in the transport rope. The preferred tensioner is used at the return unit and uses a spring-biased idler wheel mounted between the laterally displaced pulleys. The transport rope passes on a proximal side of the spring biased idler wheel and around the distal sides of the laterally spaced pulleys. When a skier grabs the transport rope to be pulled up hill in front of the return unit at the bottom of a hill, for example, the rope can slack behind the skier if a tensioner is not used. The spring-biased tensioner takes this slack out of the transport rope and helps it pull smoothly.
The drive unit is desirably enclosed in a housing with integrated skid pan for easy movement over snow and lifting handles on the sides. The drive unit is held in place with snow stakes, or anchors that are installed under the snow. During set up, the continuous loop of transport rope is run down the hill to a 2-pulley return unit. The return unit is collapsible for easy transport. As mentioned, it uses straps or cable and securing device, such as a steel cable come along, to attach to a snow stake or anchor to hold it in place. The securing device takes up initial slack in rope, and can be mounted in line with a strain gauge to ensure that an appropriate amount of tension is present on the rope. The uphill moving side of the rope does not require any mid-support pulleys and therefore eliminates the need for special hooks or harnesses attached to the rope. The skier simply grabs onto the rope and has a clear unobstructed run back to the top of the hill. The downhill side of the rope can use guide stakes to keep the rope from dragging in the snow if desired.
All of the pulleys are in a horizontal position making it significantly easier to route the rope, which decreases setup time. The many of the components can be made of lightweight aluminum, which facilitates portability and set up. In addition, the drive unit components located in the housing are weather resistant, and the system is safer to operate because these moving parts are not exposed.
In addition, it is desirable to have a safety gate, and emergency off (EMO) switches (one at top of hill and one at the bottom) that cut power to the drive motor in the event of emergency. The safety gate is located on the uphill side rope, close to the drive unit, in a normal set up where the drive unit is positioned uphill of the return unit.
The invention has many advantages over prior art portable rope tow assemblies. One significant advantage is the use of the variable frequency drive with the electric motor and belt drive. Using the variable frequency drive enables the operator to control the speed of the transport rope as needed for the situation, e.g., from 0 mph to at least 13 mph. It also enables the operator, or a tripped safety gate, to stop the transport rope immediately without the need for an engine or motor to wind down.
Other features and advantages of the invention may be apparent to those skilled in the art after review the following drawings and description thereof.
Referring first to
In
The drive unit 1 is secured to the top of the incline 10 (described in greater detail below), desirably on a relatively flat area 11, and provides power to pull the transport rope 6. The transport rope 6 connected between the drive unit 1 to the return unit 9 is a single, continuous loop. The transport rope 6 is depicted as a single line in
In a preferred embodiment, the return unit 9 has two idler pulleys 12A, 12B that are mounted generally horizontally on a frame 2 and separated by a distance to keep the uphill moving section 6A of the rope separated from the downhill moving section 6B of the transport rope. The return unit 9 is set up in order to provide tension to transport rope 6. Referring now also to
Although not shown in the drawings, guide bars can be driven into the ground underneath the downhill moving portion 6B of transport rope 6 to keep it from contacting the snow.
In an alternative set up, the positions of drive unit 1 and return unit 9 are reversed from that depicted in
Exemplary components of the drive unit 1 and its operation are now described in connection with
The skid plate 3 is a continuous plate attached to the underside of drive unit 1 to aid in sliding drive unit 1 along the ground or snow covered surface. Skid plate 3 can be composed of any of the aforementioned structural materials. In a preferred embodiment, skid plate 3 is composed of plastic or aluminum, and in a highly preferred embodiment skid plate 3 is composed of plastic to minimize friction on the snow. Skid plate 3 can be welded, bolted or riveted to the frame of housing 20.
Hold down 5 holes pass through the peripheral base of the frame of the housing 20 and through the skid plate 3. This part of the frame resides outside of the housing side panels. The hold down holes 5 are configured to receive stakes 4 driven through hold down 5 holes into the underlying ground, which at a ski resort would normally be snow and ice. Suitable stakes are made of aluminum or steel and should have a length of 24 inches or more. The figures show the drive unit 1 being staked in to place, and also tethered with straps 24 connected to a snow anchor 26. It is not normally necessary to both stake and tether the drive unit 1. The drive unit 1 can also be tethered to a stationary object.
Although not shown in the drawings, the frame of the housing 20 can include hooks, as desired, in various locations. Frame hooks can be used to securing drive unit 1 to the top of incline 10 instead of the handle, or to serve as a location to aid in dragging drive unit 1 using a vehicle. Frame hooks 4 can be made of aluminum and welded to the peripheral base of the housing frame.
The transport rope 6 enters and exits drive unit 1 between horizontal guide bars 17 on a front side of the drive unit. As discussed in more detail below, the drive pulleys and idler pulleys in the drive unit 1 are mounted horizontally (or nearly horizontally) with respect to the housing frame and skid plate, and in a common plane so that the rope 6 is driven through the drive unit 1 in a common plane. The opening on the front of the drive unit 1 between the horizontal guide bars 17 is located within this plane. The guide bars 17 allow the tow rope system to operate at a wide range of vertical angles to accommodate various slopes of incline 10. Because the guide bars obviate the need for pulley alignment, the setup and take-down of tow rope system is simplified and expedited. The guide bars 17 can be composed of metal, plastic or wood. In a preferred embodiment, guide bars 17 are composed of a high hardness and/or corrosion resistant metal such as stainless steel to reduce wear.
Drive unit cover is desirably a transparent lid enclosing drive unit 1 while permitting observation of drive motor 13, transport rope 6 and pulley system contained in the housing. The transparent lid can be made of a variety of transparent materials such as transparent polycarbonate or acrylic. Drive unit cover 7 should be configured to be easy to remove and replace for rapid setup, take-down and repair if necessary. It is therefore contemplated that drive unit cover 7 be attached to the housing using screws or quick access fasteners such as wing nuts, magnetic fasteners, and the like.
Power converter 8 is used to convert alternating current (AC) line power into a variable frequency and/or variable power source for the AC drive motor 13. As depicted in
Referring now to
Drive motor 13 is an electrical motor which provides rotational power to propel the transport rope 6 though the system. Drive motor 13 can be an alternating current (AC) or direct current (DC) style motor. When drive motor 13 is an AC motor, it may be a single, or multi-phase motor. In the exemplary embodiment, the drive motor 13 is an AC motor with a power rating, e.g., from 3 to 40 horsepower (HP). The motor power output and gears are selected to determine the maximum top end speed of the rope. A 3 HP motor can be used with appropriate gearing for systems having a capacity of 3-5 skiers at a slow speeds. On the other hand, a 40 HP motor can be used for a system having a capacity of 22-25 skiers at relatively high speeds, such 13 mph or slightly less. As mentioned previously, a maximum top end speed of 13 mph should be sufficient for most applications.
The input of gearboxes 36 are connected to the output shaft 34 of the drive motor 13 using belts 32. The gearboxes 36 are right angle style gearboxes whose output is connected to grooved pulleys 28 within which the transport rope 6 passes and is driven. Combinations of gearbox reduction and grooved pulley 28 diameter can be chosen to improve the pulling force of the transport rope 6 at the expense of velocity. Grooved pulleys 28 can be composed of a variety of materials (metal, plastic, etc.), however it has been found that rubber provides adequate and consistent adhesion to transport rope 6 during operation in snow.
Idler pulleys 30 serve to maximize the contact area between transport rope 6 and grooved drive pulleys 28. By increasing the contact area between transport rope 6 and grooved pulleys 28, idler pulleys 30 permit greater pulling force before slippage occurs. As shown in
Using a belt drive permits quiet and efficient mechanical coupling between the output shaft 34 of drive motor 13 and gearboxes 36 compared to chain-driven couplings. This benefit can be important during sports exhibitions and competitions when the added noise could detract from the show, or alternatively interfere with communication between personnel at the uphill and downhill stages of the lift.
While the present application has been particularly shown and described with respect to preferred embodiments thereof, it will be understood by those skilled in the art that the foregoing and other changes in forms and details may be made without departing from the spirit and scope of the present application.
Number | Name | Date | Kind |
---|---|---|---|
3739728 | Thompson | Jun 1973 | A |
3779171 | Littlehorn | Dec 1973 | A |
4023502 | Eising | May 1977 | A |
4920892 | Pesek | May 1990 | A |
5205219 | Groskreutz et al. | Apr 1993 | A |
6295936 | Dahlstrom | Oct 2001 | B1 |
8746148 | Niedermeyer | Jun 2014 | B1 |
20030047107 | Thomas | Mar 2003 | A1 |
20120187355 | Mehrkens | Jul 2012 | A1 |
20130213255 | Von Lerchenfeld | Aug 2013 | A1 |
20170120934 | Aramburo | May 2017 | A1 |
Number | Date | Country |
---|---|---|
102016224363 | Mar 2018 | DE |
WO-2009015878 | Feb 2009 | WO |
Entry |
---|
International Search Report and Written Opinion dated Apr. 21, 2020 in co-pending PCT Application PCT/US2020/013450. |
Number | Date | Country | |
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20200223456 A1 | Jul 2020 | US |
Number | Date | Country | |
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62918118 | Jan 2019 | US |