The present invention relates generally to a bollard with an adjustable mount for protecting structures from moving objects, controlling or directing a flow of traffic of heavy equipment, carts or vehicles, and/or blocking access to particular areas, and relates more particularly to a bollard with an adjustable mount employing a rigid post body and legs for mounting the post having an adjustable distance therebetween.
In supermarkets and retail stores floor fixtures such as freezer and refrigerator cases, floor shelving, and product displays are susceptible to damage due to collisions with shopping carts, floor scrubbers, pallet jacks, stock carts, and the like. For example, freezer and refrigerator cases typically include a glass or transparent plastic door for viewing the product without opening the door. The glass can be shattered, or the plastic scratched, upon impact with shopping carts, or the like. Since the body of many of these floor fixtures is constructed of lightweight aluminum or hardened plastic, it can be easily dented or cracked by such impacts.
A bollard is commonly used to protect floor fixtures from collisions with shopping carts and heavy equipment. Bollards are also commonly employed inside a store to block shopping cart access to certain areas and outside a store to protect outdoor structures from collisions, to indicate parking areas, to block vehicle and heavy equipment access to a particular area, and to direct a flow of traffic. Bollards can also be used to block vehicular access for security reasons. While some bollards are permanently fixed in place, others need to be removable to temporarily permit access to an area, or when a change in location is required.
Bollards can be difficult to mount to a floor or to the ground, often requiring large diameter holes or cement to be held in place. The large diameter hole for mounting a bollard can be difficult to make in the floor or in asphalt, concrete, etc., and if the bollard is removed, the very large diameter hole in the floor, in a sidewalk or in a parking lot is a hazard. Bollards held in place with cement are not easily installed and are not easily removed. Alternatively, a bollard can be mounted using two or more smaller diameter legs that are attached to the body of the bollards. The legs fit into two or more smaller holes in the floor or the ground. If the bollard is removed, the two or more small holes in the floor or the ground do not present as great a hazard. The two or more smaller holes are easier to form in the floor or ground than the single large diameter hole, however, unlike the single large diameter hole that does not require precise positioning, the two or more smaller mounting holes must be precisely spaced for the two or more legs to align with the two or more smaller mounting holes. The bollard with legs requires a significant degree of precision when one is forming the mounting holes into which the legs are positioned to install the bollard. If the mounting holes are not precisely spaced, the two or more legs may not fit well, and/or may not fit at all.
Accordingly, what is needed is a bollard for use where collisions with other equipment may occur, while also providing some degree of adjustment with regard to the installation of the bollard. The present invention is directed to this need.
In accordance with one example embodiment of the present invention, a bollard with an adjustable mounting mechanism includes a rigid post body having a first end and a second end. A first leg couples with the rigid post body at the second end. A second leg couples with the post rigid post body at the second leg substantially parallel with the first leg, the second leg coupled with the rigid post body through an adjustable support. The adjustable support is configured to vary a distance between the first leg and the second leg upon adjustment. A sliding support slidably couples with the first leg, the second leg, or both.
In accordance with various aspects and embodiments of the present invention, wherein the sliding support can be fixedly coupled with the rigid post body and slidably coupled with the first leg. The second leg can be affixed to the rigid post body and the sliding support can be affixed to the second leg.
In accordance with additional aspects and embodiments of the present invention, the adjustable support can include a threaded bolt. The rigid post body can include a threaded channel configured to engage threads on a portion of the adjustable support. The second leg can include a threaded channel configured to engage threads on a portion of the adjustable support.
In accordance with additional aspects and embodiments of the present invention, rotation of the adjustable support about a longitudinal axis of the adjustable support varies the predetermined distance between the first leg and the second leg. The adjustable support can include a driving head for rotating the adjustable support about the longitudinal axis of the adjustable support.
In accordance with additional aspects and embodiments of the present invention, the adjustable support can include a retaining element adapted to fix a translational position of the adjustable support relative to the first leg. The second leg can be affixed to an outward facing side of a wall of the rigid post body. The second leg can be affixed to an inward facing side of a wall of the rigid post body. The adjustable support can be configured to adjust the predetermined distance over a total range of about 0.5 inches.
In accordance with one example embodiment of the present invention, a bollard with an adjustable mounting mechanism includes a rigid post body having a first end and a second end. A leg structure couples with and supports the rigid post body. The leg structure includes a first leg coupled with the rigid post body at the second end, a second leg coupled with the rigid post body at the second end substantially parallel with the first leg, and an adjustable support having a first end rotatably coupled with the first leg and a second end adjustably coupled with the second leg. The adjustable support is configured to vary a distance between the first leg and the second leg upon adjustment. A sliding support slidably couples with the first leg and fixedly couples with the second leg.
In accordance with aspects and embodiments of the present invention, the first leg can include a first channel slidably engaged with the sliding support. The second leg can include a threaded channel threadedly engaged with the adjustable support. The adjustable support can include a threaded bolt having a driving head disposed at a first end and a threaded portion disposed at a second end; and a retaining element disposed on the threaded bolt adapted to retain the first leg in a desired position along a length of the threaded bolt. The first leg can be disposed between the driving head and the retaining element.
The present invention will become better understood with reference to the following description and accompanying drawings, wherein:
An illustrative embodiment of the present invention relates to an adjustable bollard in which one embodiment is formed of a rigid post body to absorb impact forces. The rigid body is constructed of a material, such as a metal or heavy composite for ease of cleaning and for good stability and impact absorption ability. Other types of material are considered within the scope of the invention. The material must be sturdy enough to absorb the impact of many collisions while maintaining an attractive appearance, and not easily fracturing or denting. One embodiment of the present invention further includes at least two leg portions that support the rigid post body. The distance dimension between the leg portions is adjustable to enable minor variations in the placement of the mounting holes into which the leg portions fit to install the bollard in the ground or floor.
In accordance with one example embodiment, the bumper section 12 is formed of a stainless steel metal. Table 1 shows yield strengths for readily available stainless steels, a common aluminum alloy, a common cold-rolled steel alloy, a range for all carbon steels, and two types of high density polyethylene (HDPE). As described above, many conventional corner guards are formed of plastics such as HDPE and lightweight aluminum. However, most plastics and many aluminum alloys do not have sufficient strength for use in a corner guard where collisions with heavier industrial type equipment can occur. The yield strength of most metal materials (pure and alloys) depends both on the chemical composition of the metal material and the way that the metal material is processed. Cold working and/or annealing of a metal material can greatly increase its strength. For this reason, typical values of yield strength for a particular metal material composition may cover a large range.
As can be seen in Table #1, aluminum alloys are much stronger than plastics, such as impact resistant HDPE. Some aluminum alloys are as strong as some types of stainless steel alloys, but the range of strengths is higher for stainless steel than for aluminum alloys. Additionally, stainless steel alloys are more tough (resistant to fracture) than aluminum alloys.
Materials with a tensile yield strength of greater than about 190 Mpa and a fracture toughness greater than about 40 MPa-m1/2 are sufficiently strong and tough to withstand collisions with heavier industrial type collisions when used to form the bumper section 12.
The adjustable rigid corner guard 10 further includes two or more legs, such as a first leg 14 and a second leg 16, upon which the bumper section 12 rests. The first and second legs 14, 16 are preferably fabricated from stainless steel to provide strength when the bumper section 12 receives an impact blow. Other materials may, of course, be utilized as long as the appropriate strength is retained, and first and second legs 14, 16 do not break under predictable impact. The first and second legs 14, 16 are spaced a distance D apart.
The adjustable rigid corner guard 10 can have a number of different configurations, while still providing the desired level of protection of a corner upon which, or in front of which, it mounts. Referring now to
In accordance with one example embodiment of the present invention, the adjustable rigid corner guard 10 includes a rub rail 28 that extends horizontally across the front right side face 110 to the front left side face 120 of the adjustable rigid corner guard 10. The rub rail 28 runs parallel to the base and forms a bulge or outwardly projecting surface feature in the front of the bumper section 12, extending outwardly from the front wall, to receive the initial impact of any collision. The rub rail 28 is integral with the bumper section 12. It should be noted that the configuration of the rub rail 28 can vary, such that other type protrusions, such as a wedge or rectangular bulge, can form the rub rail 28 within the scope of the present invention, such that the rub rail 28 is not limited to the configuration illustrated herein.
Referring now to
Referring back to
With the rotation of the adjustment mechanism 40 in the first direction to pull the right and left side edges 112, 122 together, contemporaneous movement of the first and second legs 14, 16 occurs, and the distance D therebetween is reduced. With the rotation of the adjustment mechanism 40 in the opposite second direction to push the right and left side edges 112, 122 apart, contemporaneous movement of the first and second legs 14, 16 occurs, and the distance D therebetween is increased.
One of ordinary skill in the art will appreciate that the first and second leg supports 18, 20 can take a number of different forms, and are merely intended to provide sufficient support coupling the bumper section 12 with the first and second legs 14, 16 in a manner that will allow the adjustable rigid corner guard 10 to receive predictable impact levels from carts, and the like, as described, while protecting the corner 30 in front of which the adjustable rigid corner guard 10 is mounted.
The primary function of the adjustment mechanism 40 is to couple the front right side face 110 and the front left side face 112 together in a manner that enables or allows for a flexing of the bumper section 12 of the adjustable rigid corner guard 10 to affect the distance D between the first and second legs 14, 16 when installing the adjustable rigid corner guard 10. The flexing of the bumper section 12 along provides both increasing and decreasing adjustment of the distance D between the first leg 14 and the second leg 16. As such, if during an installation process, mounting holes 44 and 46 into which the first leg 14 and the second leg 16 are intended to fit are not precisely spaced at the exact distance between the first leg 14 and the second leg 16 without flexing the bumper section 12, then a user performing the installation can adjust the distance D as necessary using the adjustment mechanism 40.
Specifically, during installation, the distance D can be adjusted by an installer by applying a force to the front right side face 110 and the front left face section 112, either expanding them apart to increase distance D or compressing them together to decrease distance D. Thus, if any minor adjustments are required based on the placement of the mounting holes 44, 46 in the ground, the installer can flex the bumper section 12 using the adjustment mechanism 40, to line up the first and second legs 14, 16 to match up with the mounting holes 44, 46.
It should be noted that in the illustrative embodiment the first and second legs 14, 16 are welded to the bumper section 12 of the adjustable rigid corner guard 10. Accordingly, the adjustable rigid corner guard 10 maintains superior strength and impact resistance properties to plastic bumpers, while still having the ability to accommodate minor installation misalignments.
In accordance with one example embodiment, several adjustable rigid corner guards 10 were constructed. The bumper sections 12 ranged between 12 inches in height, to 18 inches in height, to 24 inches in height. With such dimensions, the flexibility provided by the adjustment mechanism 40 enabled variation of the dimension D between the first and second legs 14, 16 on the order of about ¼ inch in each direction (increasing and decreasing).
Another illustrative embodiment shown in
Another illustrative embodiment of the present invention is an adjustable bollard described in
An adjustable bollard 60 of the present invention, must withstand impacts from heavy equipment. The adjustable bollard 60 can be formed of a number of different rigid and high strength materials, such as metal and high strength composites, so long as the material provides sufficient support and durability to withstand an impact with heavy equipment. The material of the rigid post body 62 must be sturdy enough to absorb the impact of many collisions while maintaining an attractive appearance, and not easily fractured or dented. The rigid post body 62 of the adjustable bollard 60 can be formed of a steel, a composite material or another material with a high yield stress, preferably a material with a tensile yield strength of greater than about 150 MPa. For example, as shown in table 1, series 300 alloys of stainless steel, and 1008 steel, a popular alloy for cold-rolled steel, both have sufficient tensile strength. A suitable material must also be sufficiently tough to prevent fracture. Additionally, the structural details, such as wall thickness, and material properties of the rigid post body 62 must be selected such that the rigid post body 62 can adequately flex in response to a force exerted using the adjustment mechanism 76.
As shown, the two leg portions 72a and 72b can be joined by the adjustment mechanism 76, however, the adjustment mechanism 76 can instead be coupled with the rigid post body 62 or can be coupled with both the leg portions 72a, 72b and the rigid post body 62, according to aspects of the present invention. The adjustment mechanism 76 can include a cylindrical portion 77 that is threaded 81 in a first orientation at a first end 77a and that is reverse threaded 82 at a second end 77b. A cylindrical axis 80 extends through the center of the cylindrical portion 77 and along a length of the cylindrical portion 77. The first leg portion 72a can include a threaded hole 73 configured to mate with the threaded first end 77a of the cylindrical portion 77. The threaded hole 73 forms a first coupling that couples the threaded first end 77a of the cylindrical portion 77 to the rigid post body 62. The second leg portion 72b can include a reverse threaded hole 74 configured to mate with the reverse threaded second end 77b of the cylindrical portion 77, The threaded hole 74 forms a second coupling that couples the reverse threaded second end 77b of the cylindrical portion 77 to the rigid post body 62. Rotation of the cylindrical portion 77 about the cylindrical axis 80 in a first direction applies a force to flex the rigid post body 62 to reduce the predetermined distance D1. Rotation of the cylindrical portion 77 about the cylindrical axis 80 in an opposite direction applies a force to flex the rigid post body 62 to increase the predetermined distance D1. The adjustment range will depend on the materials used, the overall size of the bollard and the size of the predetermined distance.
In accordance with one particular example embodiment, an adjustable bollard, with a rigid post body made from a cold-rolled steel, has a predetermined distance D1 of about 4.6 inches that can be increased or decreased by about 0.25 inches, resulting in a total adjustment range of about 0.5 inches. The adjustment range for each embodiment will depend on the materials used, the overall size of the bollard and the size of the predetermined distance.
An enlarged portion 90 of the leg structure 70 and adjustment mechanism 76 viewed along the cylindrical axis 80 is depicted in
After the leg portions 72a, 72b are inserted into the mounting holes 98a, 98b and the adjustable bollard 60 has been locked into place (if desired), the hexagonal-head wrench 102 is removed, ballast 97 can be added and a bollard cover 104 can be placed on the adjustable bollard, as shown in
Although
Both
According aspects of the present invention, rotation of the adjustable support 250 about a longitudinal axis of the adjustable support 250a varies the predetermined distance DP between the first leg 230 and the second leg 240. In accordance with the example embodiment, the adjustable support 250 includes a threaded bolt 252. The second leg 240 may include a threaded channel 240c configured to engage threads 252b on a portion of the threaded bolt 252. The rigid post body 220 may include a threaded channel 220c configured to engage threads 252b on a portion of the threaded bolt 252; however, this may not be necessary if threaded channel 240c exists, and vice versa threaded channel 240c may not be necessary if threaded channel 220c exists. The first leg 230 may include a channel 230c through which the threaded bolt 252 passes. The threaded bolt 252 may include a driving head 252d for rotating the adjustable support 250 about the longitudinal axis 250a of the adjustable support 250. The adjustable support may include a retaining element 254 adapted to fix a translational position of the adjustable support 250 relative to the first leg 230. The retaining element 254 may be disposed on the threaded bolt 252 and configured to retain the first leg 230 in a desired position along a length of the threaded bolt 252 with the first leg 230 disposed between the driving head 252d and the retaining element 254 as depicted.
According to aspects of the present invention, the sliding support 260 may be fixedly coupled with the rigid post body 220 and slidably coupled with the first leg 230. The first leg 230 may include a second channel 230d with the sliding support 260 passing therethrough for slidably coupling the first leg 230 and the sliding support 260. The sliding support 260 may be fixedly coupled with the second leg 240, the rigid post body 220, or both. The sliding support 260 may be fixedly coupled with the second leg 240 and/or the rigid post body 220 using at least one weld 272 as depicted in
Numerous modifications and alternative embodiments of the present invention will be apparent to those skilled in the art in view of the foregoing description. Accordingly, this description is to be construed as illustrative only and is for the purpose of teaching those skilled in the art the best mode for carrying out the present invention. Details of the structure may vary substantially without departing from the spirit of the invention, and exclusive use of all modifications that come within the scope of the appended claims is reserved.
The present invention is a continuation-in-part of U.S. patent application Ser. No. 11/800,233, filed on May 4, 2007 and entitled “Adjustable Bollard”, and a continuation-in-part of U.S. patent application Ser. No. 11/633,935 filed Dec. 5, 2006, and entitled “Adjustable Rigid Corner Guard”, which claims priority to Provisional Application No. 60/742,660 filed Dec. 6, 2005. The contents of both U.S. patent application Ser. No. 11/800,233 and U.S. patent application Ser. No. 11/633,935 are herein incorporated by reference in their entirety.
Number | Date | Country | |
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60742660 | Dec 2005 | US |
Number | Date | Country | |
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Parent | 11800233 | May 2007 | US |
Child | 12009167 | US | |
Parent | 11633935 | Dec 2006 | US |
Child | 11800233 | US |