The present application relates generally to a ramp and, more specifically, to a ramp with a curved top side and that is constructed from two or more overlapping components.
Ramps are used for a wide variety of purposes, including but not limited to elevating a vehicle. In one specific example, a ramp is used to elevate one side of a vehicle to level the vehicle while it is parked on a hill or other non-flat surface. In one specific example, the ramp is used to level a recreational vehicle such as a camper. In another specific example, the ramp is used to level a commercial vehicle, such as a medical vehicle that is providing medical services to persons.
The ramps include a length measured between a leading edge and a trailing edge. The ramps further include a different height that increases from the leading edge to the trailing edge. During use, the wheel of the vehicle initially contacts against the leading edge and moves along the length towards the trailing edge. The farther the wheel moves along the length the greater the vehicle is lifted.
Some ramps include a larger length with a gradually increasing height. The longer length provides for a more gradual increase in height that is often easier for the user to locate the wheel at the desired spot to gain the desired elevation for the wheel. A drawback of longer ramps is the inability for their use in many situations in which there is not adequate space for the ramp. A shorter ramp has the advantage that it can be used in more situations. A drawback is the shorter length has an increased steepness in height between the leading and trailing edge. This increased steepness makes it more difficult for the user to locate the wheel at the desired height.
There is a need for a ramp that is configurable to be used in different situations depending upon the needs of the user.
One aspect is directed to a ramp to elevate a wheel of a vehicle above a support surface. The ramp comprises a base block comprising: a leading edge; a trailing edge; a bottom side that extends between the leading and trailing edges and is configured to contact against the support surface; a top side that extends between the leading and trailing edges and is opposite from the bottom side with the top side comprising a first curved shape that extends between the leading and trailing edges. The ramp comprises a stacker block configured to connect to and be stacked on the base block with the stacker block comprising: a bottom side with a second curved shape; and a top side with a third curved shape. One or more projections extend outward from one of the top side of the base block and the bottom side of the stacker block. One or more openings are in the other of the top side of the base block and the bottom side of the stacker block. The one or more projections are configured to fit into the one or more openings to prevent relative movement between the base block and the stacker block.
In another aspect, the first curved shape of the top side of the base block has a constant radius between the leading edge and the trailing edge of the base block.
In another aspect, the first curved shape matches the second curved shape for the base block and stacker block to seat together when the one or more projections are inserted into the one or more openings.
In another aspect, each of the base block and the stacker block comprise a height measured between the respective bottom side and the top side, with the height increasing from the leading edge to the trailing edge and the height of the base block at the trailing edge is larger than the height of the stacker block at the trailing edge.
In another aspect, the top side of the base block comprises a lattice structure formed by a plurality of ribs with an intersecting pattern that extend within the peripheral wall of the base block.
In another aspect, the one or more openings and the one or more projections comprise complementary polygonal sectional shapes.
In another aspect, the bottom side of the base block comprises a curved shape that extends continuously between the leading and trailing edges.
In another aspect, the stacker block is a first stacker block and further comprising one or more additional stacker blocks each comprising: a bottom side with a fourth curved shape that matches the third curved shape of the first stacker block; a top side with a fifth curved shape; and one or more projections that extend outward from the bottom side and are configured to fit into the one or more openings of the first stacker block.
In another aspect, a length of each of the base block and the stacker block is equal with the lengths measured between the respective leading and trailing edges.
One aspect is directed to a ramp to elevate a wheel of a vehicle above a support surface. The ramp comprises a base block comprising a height that increases from a leading edge to a trailing edge with the base block further comprising a curved top side that extends continuously between the leading edge and the trailing edge, and a bottom side configured to contact against the support surface. The ramp also comprises one or more stacker blocks each configured to stack onto and connect to the top side of the base block with each of the one or more stacker blocks comprising a top side and a bottom side with the bottom side comprising a curved shape that matches the curved top side of the base block.
In another aspect, one or more projections that extend outward from the bottom side of the one or more stacker blocks and one or more openings that extend into the top side of the base block with the one or more projections configured to mate with the one or more openings to stack the one or more stacker blocks in a stacked arrangement with the base block.
In another aspect, the one or more projections completely fit into the one or more openings such that the bottom of one of the stacker blocks contacts against the top side of the base block when mounted together.
In another aspect, the top side of the one or more stacker blocks comprises a curved shape that extends continuously between a leading edge and a trailing edge.
In another aspect, each of the one or more stacker blocks comprises a common shape and size.
In another aspect, the base block comprises a greater height at the trailing edge than each of the one or more stacker blocks.
In another aspect, the base block comprises a lattice structure that is exposed on the top side of the base block.
One aspect is directed to a method of stacking a ramp comprising: positioning a base block on a support surface with a bottom side of the base block contacting against the support surface and a top side having a curved shape facing outward away from the support surface; stacking a stacker block onto the base block with a curved bottom side of the stacker block contacting against the curved top side of the base block and with a top side of the stacker block facing outward away from the support surface; and engaging the stacker block with the base block and preventing the stacker block from moving relative to the base block.
In another aspect, the method further comprises contacting the curved bottom side of the stacker block continuously across an entirety of the top side of the base block.
In another aspect, engaging the stacker block with the base block and preventing the stacker block from moving relative to the base block comprises inserting projections on the bottom side of the stacker block into openings in the top side of the base block.
The features, functions and advantages that have been discussed can be achieved independently in various aspects or may be combined in yet other aspects, further details of which can be seen with reference to the following description and the drawings.
The present application is directed to a ramp configured to support a wheel of a vehicle. The ramp includes a tapered height and a curved surface for a wheel of a vehicle to move along and elevate above a support surface. The ramp includes a base block configured to contact against the support surface. One or more stacker blocks are configured to connect to the base block to increase the elevation of the wheel of the vehicle. The base block and one or more stacker blocks are configured to be removably connect together to be adjustable to the needs of the user.
The ramp 10 can be used for various purposes and on a variety of different vehicles 101. One application is to level the vehicle 101, such as when the vehicle 101 is a camper or other vehicle that requires a level orientation. Another application is a medical vehicle that requires the vehicle 101 to be within a predetermined level orientation.
As illustrated, the ramp 10 includes a leading edge 11 and a trailing edge 12 each with a height H measured between the bottom of the base block 20 and the top of the top stacker block 30b. The leading edge 11 has a reduced height to allow a wheel 100 of the vehicle 101 to roll from a support surface 200 onto the ramp 10. The trailing edge 12 includes a greater height configured to elevate the wheel 100 above the support surface 200. The bottom side of the ramp 10 is formed by the bottom side 21 of the base 20 and the top side 13 of the ramp 10 is formed by the top of stacker block 30b. The top side 13 has a curved shape that extends between the leading and rear edges 11, 12. The extent of curvature can vary.
In one example, the length L and width W of the base block 20 is equal to the one or more stacker blocks 30. This provides for the base and stacker blocks 20, 30 to be aligned along the leading and rear edges 11, 12, as well as the lateral sides.
The base block 20 is configured to contact against the support surface 200 and support the one or more additional stacker blocks 30. As illustrated in
The top side 22 is configured to contact against and connect with a stacker block 30. The top side 22 includes a curved shape that extends the length Lb between the leading and trailing edges 23, 24. In one example, the curved shape is consistent across the length Lb and includes a radius R2. In one example, the radius is constant along the entire length Lb. In another example, the curvature varies across the length L.
In one example, the radius R1 of the bottom side 21 is larger than the radius R2 of the top side 22. In one specific example, the radius R1 of the bottom side 21 is 21.00 inches and the radius of the top side 22 is 14.12 inches. In one example as illustrated in
In one example as illustrated in
The one or more stacker blocks 30 are configured to connect to the base block 20. The connection prevents the stacker block 30 from moving relative to the base block 20 to maintain the relative positioning of the stacker block 30 and base block 20. The connection also provides for removably connecting the stacker block 30 to the base block 20. One example of the stacker block 30 is illustrated in
As illustrated in
The top side 32 includes a curved shape. In one example, the curved shape includes a radius R4 that is continuous along the length Ls. In another example, the curvature varies along the length Ls.
In one example, the stacker block 30 is solid. In another example as illustrated in
One or more projections 35 extend outward from the bottom side 31 and are configured to connect to the base block 20 or other stacker block 30. Each of the one or more projections 35 are sized and shaped to be inserted into one of the receptacles 29 in the top side 22. In one example, the projections 35 include a sectional shape and size that matches the sectional shape and size of the receptacles 29. In one example, the projections 35 include a polygonal sectional shape that matches the shape of the receptacles 29. In one example, each of the projections 35 includes the same shape and size. In another example, two or more of the projections 35 include a different shape and/or size. The number of projections 35 can vary. In one example, the stacker block 30 includes a single projection 35. In other examples, the stacker block 30 includes two or more projections 35. In one example, the one or more projections 35 engage with a releasable friction engagement with the one or more receptacles 29.
The projections 35 and receptacles 29 are configured for the projections 35 to fit fully into the receptacles 29. This provides for the stacker block 30 to fully seat onto the base block 20 and for the bottom side 31 of the stacker block 30 to contact against the top side 22 of the base block 20. This provides for the weight applied by the wheel 100 to transfer by the bottom side 31 to the base block 20 rather than for the transfer to occur through the projections 35. This provides for the ramp 10 to function as a one-piece unit to support the vehicle 101.
The ramped shape of the base block 20 results in the depth of the receptacles 29 measured between the top side 22 and the bottom side 21 to increase towards the trailing edge 24 (i.e., the receptacles 29 towards the trailing edge 24 are deeper than the receptacles 29 towards the leading edge 23). To ensure fully insertion of the projections 35 into the receptacles 29, in one example the one or more projections 35 are positioned along a rear section of the stacker block 30 in closer proximity to the trailing edge 34 than to the leading edge 33. In one example as illustrated in
The ramp 10 can include one or more stacker blocks 30 stacked onto the base block 20.
In one example, each of the stacker blocks 30 includes the same shape and size. In another example, the different stacker blocks 30 include different shapes and/or sizes. In one example of a ramp 10 having multiple stacker blocks 30, the top side 32 of an underneath stacker block 30 has a curved shape that matches the curved shape of a bottom side 31 of a covering stacker block 30. This matching configuration provides for the one or more projections 35 to insert into the corresponding one or more receptacles 29 for the bottom side 31 to contact against the top side 32 and transfer the weight along these surfaces rather than through the one or more projections 35. In another example, the curved shapes of the mating stacker blocks 30 are different.
The method includes stacking a stacker block 30 onto the base block 20 (block 302). The curved bottom side 31 of the stacker block 30 contacts against the curved top side 22 of the base block 20. The stacker block 30 is positioned with the top side 32 of the stacker block 30 facing outward away from the support surface 200. The stacker block 30 is engaged with the base block 20 to prevent the stacker block 30 from moving relative to the base block 20 (block 304).
Once the stacker block 30 is stacked onto and engaged with the base block 20, a wheel 100 of a vehicle 101 can be moved onto the ramp 10. The wheel 100 moves along the support surface 200 and onto the ramp 10 at a leading edge 11. The wheel 100 is then moved along the top side 32 of the stacker block 30 to elevate the wheel 100 to the desired height above the support surface 200.
In another example, one or more additional stacker blocks 30 are mounted onto the top of the ramp 10. This includes stacking the next stacker block 30 onto the top side 32 of the stacker block 30 that is engaged with the base 20. This additional stacker block 30 is engaged with the stacker block 30 to form a ramp 10 with three components (i.e., base block 20, first and second stacker blocks 30). The second stacker block 30 engages with the first stacker block 30 with the one or more projections 35 on the second stacker block 30 engaging with the one or more receptacles 39 on the first stacker block 30. Additional stacker blocks 30 can be added to the ramp 10 as necessary to obtain the desired elevation of the top side 13 of the ramp 10 above the support surface 200.
In one example, the base block 20 can be used independently to elevate a wheel 100 of a vehicle 100. The base block 20 is positioned on the support surface 200. The wheel 100 is moved along the support surface 200 to the leading edge 23 of the base block 20. The wheel 100 is then moved along the top side 22 of the base block 20 until the wheel 100 is elevated as necessary.
The ramp 10 can include various shapes and sizes. In one example, the ramp 10 includes a length L of 15.00 inches. In one example, the base block 20 includes a greater height at the trailing edge 24 than the one or more stacker blocks 30.
In one example, the curvature on the top side 22, 32 of each of the base block 20 and one or more stacker blocks 30 of the ramp 10 is the same.
In one example, the curvature of the sides that mate together are the same (i.e., top side 22 of base block 20 and bottom side 31 of stacker block 30, top side 32 of first stacker block 30 and bottom side 31 of second stacker block 30). This provides for the different blocks 20, 30 to stack together and for the blocks to engage along the entire length L of the blocks.
The base block 20 and one or more stacker blocks 30 can be constructed from a variety of different materials. Examples include but are not limited to polypropylene, plastic, and rubber. In one example, each of the base block 20 and one or more stacker blocks 30 are constructed from the same material. In another example, two or more of the base block 20 and one or more stacker blocks 30 are constructed from different materials.
In another example, the base 20 includes one or more projections that extend outward from and are configured to engage with corresponding one or more receptacles in the stacker block 30.
Spatially relative terms such as “under”, “below”, “lower”, “over”, “upper”, and the like, are used for ease of description to explain the positioning of one element relative to a second element. These terms are intended to encompass different orientations of the device in addition to different orientations than those depicted in the figures. Further, terms such as “first”, “second”, and the like, are also used to describe various elements, regions, sections, etc. and are also not intended to be limiting. Like terms refer to like elements throughout the description.
As used herein, the terms “having”, “containing”, “including”, “comprising” and the like are open ended terms that indicate the presence of stated elements or features, but do not preclude additional elements or features. The articles “a”, “an” and “the” are intended to include the plural as well as the singular, unless the context clearly indicates otherwise.
The present invention may be carried out in other specific ways than those herein set forth without departing from the scope and essential characteristics of the invention. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive.
Number | Name | Date | Kind |
---|---|---|---|
4050403 | Miller | Sep 1977 | A |
4165862 | Bennett | Aug 1979 | A |
4427179 | Price | Jan 1984 | A |
4819910 | Johnston | Apr 1989 | A |
6439543 | Peckham | Aug 2002 | B1 |
6517051 | Cavanaugh | Feb 2003 | B1 |
6752381 | Colak et al. | Jun 2004 | B2 |
7040461 | Chrisco | May 2006 | B2 |
7073777 | Branstetter | Jul 2006 | B2 |
7980532 | Wickwire | Jul 2011 | B2 |
8739941 | White et al. | Jun 2014 | B2 |
8935822 | Frederiksen | Jan 2015 | B2 |
10081948 | Gilsing | Sep 2018 | B2 |
D855005 | Delancey | Jul 2019 | S |
20100252788 | Wickwire | Oct 2010 | A1 |
Number | Date | Country | |
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20230104587 A1 | Apr 2023 | US |