The field relates to installation of walls and sound barriers.
It is known to use walls to reduce hazards and noise from busy highways and other roadways. Precast panels may be used as walls and may be lowered into slots formed in H-shaped posts. The H-shaped posts may be attached to footings, mechanically, or may be inserted into holes in the ground that are filled with grout. If the latter, then the posts must be held in position by a jig to ensure that the posts are vertical, aligned with each other and spaced correctly to accommodate the wall panel. This requires careful setup, extra steps, extra time for setting up the grout before removing the jig and a volume of grout that fills the hole, when the hole is drilled, without the post even being inserted, yet, all of which is time consuming and wasteful of materials.
U.S. Pub. No. 2005/0120644 discloses a precast, post-tensioned segmental pole, which does nothing to solve the problems of time consuming installation and wasteful use of grout.
U.S. Pub. No. 2005/0252124 discloses a post anchoring device that anchors a post to a foundation surface, such as a slab or footing, such as a cast in place slab or foundation.
U.S. Pat. No. 5,689,927 discloses poured concrete footings with closed loop reinforcing rods arrayed around a depression in which sound barrier posts are inserted and grouted using fast setting grout. While this reduces the time for installing the posts, after the footings are poured, it does nothing to reduce the wasteful use of concrete in the poured footing. Also, the overall time is still quite long, because the footings must be precisely poured and must be allowed to set before the posts are grouted into the depressions surrounded by closed loop reinforcements. The drawings of
U.S. Pat. No. 5,806,262 discloses a partial poured footing that is mechanically fastened to the bottom of a post before the remainder of a footing is poured. This reduces the time to install the posts and gives some flexibility in plumbing the posts before pouring the remaining portion of the footing, but it requires additional steps and more time for the setting up of the partial footing and then the remaining footing.
U.S. Pat. No. 4,887,691 discloses a post-tensioning cable system used in a post mounted in poured footing. After attaching the post by the post-tensioning cable system, grout is poured to fill voids. Again, this adds steps and requires time for both the footing to set up and for the grout in the voids to set up. While this adds a tensioning cable, it does not solve the wasteful use of materials or the wasted time setting the concrete footing and setting the post in grout.
U.S. Pat. No. 4,605,090 illustrates another example of an H-shaped post and noise barrier panel system that is capable of following contours in the terrain.
U.S. Pat. No. 3,617,028 illustrates yet another example of H-shaped posts and panels, which may be decorative in this example.
In all of the examples, the steps required to position and anchor the posts result in extra labor, materials and time in order to install wall panels retained by the retaining posts. The need to precisely space the posts and to accurately plumb the posts makes pouring and setting up footings tricky.
A wall is comprised of a panel retained in place by a pair of retaining members. The pair of retaining members are disposed on opposite sides of the wall such that one of the pair of retaining members engages at least a portion of one of the opposite sides of the wall and the other of the pair of retaining members engages the other of the opposite sides of the wall. The retaining members are pre-stressed concrete or post-tensioned reinforcing members in a cementitious material, such as a concrete, for example, providing superior resistance to cracking and improved load bearing capacity. In one example, the retaining member comprises at least one channel extending from an inlet port at a portion of the retaining member intended to remain above ground and an exit port at an end of the retaining member intended to be inserted into the ground, such that a fluid may be injected at a pressure and a flow rate.
For example, the pair of retaining members are not installed by grouting a hole and setting the retaining members in the grout. Instead, the pair of retaining members are installed by fluidizing the soil below the retaining members using a fluid, such as water and/or air, at a pressure and a volume sufficient to reduce the bearing capacity of the soil such that the retaining member penetrates into the soil under its own weight and/or due to a force applied to the retaining member. In one example, the fluidized soil is compacted following fluidization of the soil and insertion of the retaining member into the soil, such that the soil firmly supports the end of the retaining member inserted into the soil, without drilling a hole and grouting the retaining member in the hole. In one example, a drill or other mechanism is used to pre-condition the soil and any roots or other obstructions passing through the soil. However, the soil is retaining in the pre-conditioned column of soil. In this example, the retaining member penetrates into the ground by fluidizing the soil, following pre-conditioning. Again, the fluidization compacts the soil, such that the soil supports the retaining member in the ground without grouting.
The end of the retaining member that is inserted into the ground may be shaped differently from the end extending above ground. For example, the end inserted into the ground may be wider in a direction extending along the line of the wall and thinner in a direction transverse to the direction extending along the line of the wall.
In one example, the retaining member may be made of a separate post and pile. The pile may be jetted into the ground, and the post may be coupled to the pile, later. For example, this may be used under overhead power lines.
In one example, a rocky soil is predrilled with an auger, water jet drilling, with or without an abrasive, a rock drill or hydraulic drilling, some or all of the rock is removed, forming a hole, and a suitable fill is inserted into the hole, prior to the steps of fluidizing the soil and lowering the pile to depth through the fluidized soil. For example, a sand, such as a wet sand, may be used to back fill the hole. Alternatively, if necessary, a grout or other cementitious fill material may be used to fill such a hole for some posts, while other posts are inserted into other soil types, without using cementitious materials in pre-drilled holes.
The following drawings are illustrative examples and do not further limit any claims that may eventually issue.
When the same reference characters are used, these labels refer to similar parts in the examples illustrated in the drawings.
In the example of
An advantage to jetting in the pile 14 is that the surrounding soil becomes compacted, by the jetting process, more than it was prior to being disturbed, allowing the pile 14 to be more securely retained by the soil, even though the soil prior to jetting in would not have been adequate to support the wall 1 and retaining member 2. The soil compaction offers further advantages in time savings and reduced waste of excess materials, because the retaining members 2 may be rapidly jetted in and the wall panels 1 installed by lowering between two adjacent posts 10, without waiting for footings or grouting to set up prior to installation of the wall panels 1. This allows a crew to rapidly construct sections of walls without delays caused by known methods that require setting of concrete footings and/or grouting before the posts can hold their own weight, much less the weight of the wall and wind shear on the wall.
In one example, a rocky substrate is not suitable for jetting in the piles and is predrilled, instead, such as by hydraulic drilling or other drilling capable of penetrating the substrate. Then, the rocky fragments and/or unsuitable materials are removed, and the hole created is back-filled with suitable material for jetting in the piles 14. For example, a soil may be backfilled into the holes, prior to jetting in the piles 14, according to the method already described for sinking the piles into unconsolidated soils. The end result is the same as the results in soils where jetting in can be done directly, where the material added consolidates, and the compaction of the soil readily supports the piles 14, the wall panels 1, and posts 10, and supports these structures against even high wind shears due to severe weather.
In the example illustrated in
Since the post 10 and pile 14 are integrally formed, a plurality of pretensioned strands 15 extending continuously through the post 10 and the pile 14, without discontinuity, provides a prestressed (or pretensioned), precast concrete retaining member 2 that is resistant to cracking. A pile without such pre-tensioned strands is known to crack, and only by cracking will rebar precast into the piles start to take up loads. The pretensioned strands 15, unlike normal rebar, can be pretensioned during the casting of the retaining member 2. When the precast retaining member 2 sets up and the pretensioning rig releases the strands, the strands 15 apply a compressive force (i.e. prestressed or pretensioned) along the entire length of the retaining member 2, reducing the tendency of the retaining member 2 to crack. By preventing cracking, the pretensioned strands 15 can prevent corrosion of the reinforcing strands 15, which further reduces waste of materials. Otherwise, in known walls, iron rebar must be inserted that exceeds the requirements for reinforcement, precisely due to the calculation that the rebar will start to rust when the cement and/or other components of a cementitious material used in the footings and posts starts to crack, early on in the life of the wall. The useful life of the wall is determined by how fast the rebar is expected to rust. In the examples shown in
This detailed description provides examples including features and elements of the claims for the purpose of enabling a person having ordinary skill in the art to make and use the inventions recited in the claims. However, these examples are not intended to limit the scope of the claims, directly. Instead, the examples provide features and elements of the claims that, having been disclosed in these descriptions, claims and drawings, may be altered and combined in ways that are known in the art.
This application is a continuation of U.S. non-provisional application Ser. No. 15/142,451 filed Apr. 29, 2016 which claims priority to U.S. Prov. Appl. 62/155,554, entitled Wall And Retaining Members And Fluidizing Installation Of Retaining Members, which was filed May 1, 2015 and the disclosures and drawings of which are incorporated by reference in their entirety.
Number | Name | Date | Kind |
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5428926 | Melfi | Jul 1995 | A |
5689927 | Knight, Sr. | Nov 1997 | A |
6231270 | Cacossa | May 2001 | B1 |
7416368 | Dagher | Aug 2008 | B2 |
20050120644 | Tadros | Jun 2005 | A1 |
20050163575 | Dagher | Jul 2005 | A1 |
20100054859 | He | Mar 2010 | A1 |
20100232888 | Kreis | Sep 2010 | A1 |
Number | Date | Country | |
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62155554 | May 2015 | US |
Number | Date | Country | |
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Parent | 15142451 | Apr 2016 | US |
Child | 15493771 | US |