Surface building using webbing and aggregate materials, particularly road building.
Current methods for deploying and filling webbing for road materials and road maintenance generally use manual labor. Using such a system may have various drawbacks, including being costly, creating erosion, and causing construction materials to be deposited outside of the desired area.
There is proposed a system for creating roads where expandable webbing is stretched out and filled with sand, gravel or aggregate to reduce the required costs of road materials and road maintenance. This may reduce the effects of erosion and contain the construction materials to the correct area. The proposed system will automate the process of joining the sections of webbing and depositing raw material into the pockets of the webbing. Benefits of the proposed system may include increasing the speed at which road surface can be laid down while also greatly reducing the manual labor required.
In an embodiment, there is a road surfacing system including a mobile frame. A webbing conveyor is mounted on the frame. The webbing conveyor extends between a webbing receiving end and a webbing distributing end. A filler distributor is mounted on the frame adjacent to the webbing distributing end of the webbing conveyor.
In various embodiments of the system, there may be included one or more of the following features: a webbing connector mounted on the frame and adjacent to the webbing receiving end of the webbing conveyor; the webbing connector is an automatic welder; the webbing conveyor further comprises a webbing expander between the webbing receiving end and the webbing distributing end; the webbing expander further comprises a plurality of pins extending between guides; the webbing conveyor further comprises a plurality of conveyors between the webbing receiving end and the webbing distributing end; the filler distributor further comprises a hopper and an auger; a crane mounted on the mobile frame; a geocloth dispenser mounted on the frame adjacent to the webbing distributing end of the webbing conveyor; a control station mounted on the frame, the control station operatively connected to the webbing conveyor and the filler distributor; a vibration plate mounted on the frame adjacent to the webbing distributing end of the webbing conveyor; the automatic welder further comprises a plurality of welding elements and a first linear actuator operatively connected to the plurality of welding elements, the first linear actuator causing each of the plurality of welding elements to move between an open position and a closed position; the automatic welder further comprises a second linear actuator operatively connected to the plurality of welding elements, the second linear actuator causing the plurality of welding elements to move between a raised position and a lowered position; and the automatic welder having a guard plate.
In yet another embodiment, there is a method of surfacing a road. Webbing is placed onto a webbing conveyor mounted on a mobile frame. The webbing conveyor extends between a webbing receiving end and a webbing distributing end. The mobile frame is moved across the ground while webbing is distributed from a webbing distributing end of the webbing conveyor. Filler is distributed with the webbing from a filler distributor mounted on the frame adjacent to the webbing distributing end of the webbing conveyor.
In various embodiments of the method, there may be included one or more of the following features: the webbing including sections of webbing and the method further including connecting adjacent sections of webbing using a webbing connector mounted on the frame adjacent to the webbing receiving end of the webbing conveyor; the webbing connector is an automatic welder; the webbing includes sections of expandable webbing and in which the method includes expanding the sections of webbing using a webbing expander between the webbing receiving end and the webbing distributing end of the webbing conveyor; the webbing expander further includes a plurality of pins extending between guides; the webbing conveyor further includes a plurality of conveyors between the webbing receiving end and the webbing distributing end; the filler distributor further includes a hopper and an auger; dispensing geocloth using a geocloth dispenser mounted on the frame adjacent to the webbing distributing end of the webbing conveyor; a control station is mounted on the frame, the control station operatively connected to the webbing conveyor and the filler distributor; and vibrating the filler with the webbing as it is placed on the ground using a vibration plate mounted on the frame adjacent to the webbing distributing end of the webbing conveyor.
Embodiments will now be described with reference to the figures, in which like reference characters denote like elements, by way of example, and in which:
Immaterial modifications may be made to the embodiments described here without departing from what is covered by the claims. In the claims, the word “comprising” is used in its inclusive sense and does not exclude other elements being present. The indefinite articles “a” and “an” before a claim feature do not exclude more than one of the feature being present. Each one of the individual features described here may be used in one or more embodiments and is not, by virtue only of being described here, to be construed as essential to all embodiments as defined by the claims.
Referring to
A webbing connector 104 for connecting sections of webbing is mounted on the frame adjacent to the webbing receiving end 105 of the webbing conveyor. Preferably, as shown in the embodiment in
The filler distributor 108 includes a hopper 111 (
A vibration plate is mounted on the frame 103 adjacent to the webbing distributing end 107 of the webbing conveyor. For example, the vibration plate may be integral with the base of the filler distributor 108 as shown in
As shown in
The automatic welder 104 includes a second linear actuator 138 operatively connected to the plurality of welding elements 140. The second linear actuator 138 may be an electric drive which causes the plurality of welding elements 140 to move between an upper, non-welding position as shown in
The road surfacing system can be operated by placing webbing onto a webbing conveyor mounted on the mobile frame 103. The mobile frame may then be moved across the ground while the webbing is distributed from the webbing distributing end of the webbing conveyor. Filler is distributed with the webbing from the filler distributor 108. Adjacent sections of webbing may be connected using the webbing connector 104.
The sections of webbing may be expanded during operation using the webbing expander 120, 156. Geocloth may be dispensed using the geocloth dispenser 116. The filler may be vibrated with the webbing as it is placed on the ground using the vibration plate.
The road surface system described herein creates a stable road surface using expandable webbing and sand, gravel, or aggregate. The mobile frame 103 of the road surfacing system may be formed from a number of separable frames that are sized and shaped to allow for transportation. A system of conveyors secure, expand, and transport the webbing through the system. The weld station or automatic welder 104 can join two sections of webbing, when given a signal or when the webbing is placed in position for welding. The filler distributor 108 may include a conveyor and at least one augur to receive and distribute the sand, gravel, or aggregate that is supplied. The vibration plate may cause the sand, gravel, or aggregate to settle fully. The crane 112 may facilitate the assembly of the system on site as well as moving raw product as needed. The mobile frame 103 may include a track system to support and direct the machine along its path. The mobile frame may also be mounted on wheels or supported on a separate system such as the bed of a truck so long as its weight can be supported and it is moveable.
The control station 114 allows for manual or automatic control and monitoring of the various systems within the road surface system. Preferably, the conveyor system may include the expanding conveyor 102 with pins projecting upwards which will pull the expandable webbing 122 out to the maximum width. The conveyor system will also preferably include the picker conveyor 106 after the expanding conveyor 102 with a set of conveyors where the pins are directed downwards to direct the expandable webbing towards ground level. Preferably also, the web will continue to be held by pins as the sand, gravel, or aggregate is deposited and distributed evenly. Preferably, the pins will continue to hold the expandable webbing in place while the vibration plate causes the raw material to settle into the pockets after which the pins will disengage and allow the completed product to be deposited on the ground allowing the trailing end of the system to ride along the new surface.
Preferably, the frame joint points will be flexible to allow transitions across variable terrain. In a preferred embodiment of the system, the height of deposited material will be regulated by moving the material receptacle and distribution system along a linear path to maintain its clearance above webbing of various heights.
The system for creating a stable road surface, according to a preferred embodiment, is capable of disassembly and transport along highways before being reassembled at the site. The system for creating a stable road surface should adhere to transportation guidelines when being transported. Preferably, as illustrated in
According to yet another aspect of the present disclosure, the road surface building device can be largely automated utilizing a programmable logic controller (PLC). The PLC allows the machine to operate on its own, requiring only a directional input along with the addition of more expandable webbing at the front of the machine and sand, gravel, or aggregate at the rear of the assembly.
The system for creating a stable road surface, according to a preferred embodiment, comprises a series of separable frames to facilitate transport including the conveyor section 102, 106, the automatic welder 104, the filler distribution system 108, and the vibration plate. Preferably, there is a section or controller room where the system operating and monitoring is carried out. The conveyor section comprises the set of conveyors 102 with pins directed upwards to locate and expand the expandable webbing that is input, followed by the set of conveyors 106 with pins directed downwards to take the webbing and direct it to ground level where it is deposited on a layer of geocloth. The automatic welding system is located above the first set of conveyors. For welder operation, the system may pause at set intervals to allow the new section of webbing to be welded onto the current sections.
As shown in
In
As best seen in
The picker conveyor 106 then disengages from the web and allows it to progress onto the ground.
Preferably the automatic welder 104 is automated utilizing a programmable logic controller (PLC). When given the signal to begin a weld, each step will be timed and controlled from the control station 114. The welder 104 will lower, compress the web 122, and hold for a set time to ensure a complete weld has been achieved and allowed to cool.
The automatic welder shown in
In a preferred embodiment, the connections between the sections discussed above are pinned to give the structure of the machine flexibility allowing an automatic adjustment as the system moves over slopes. To ensure consistent height on the finished road surface the sand distributor 108 height may be adjusted parallel to the face of the rear chassis 134. The method for this is best illustrated in
In a preferred embodiment, a layer of geocloth 118 (
In embodiments of the road surfacing system, the system creates a stable road surface by filling an expandable web with sand, gravel, or aggregate to create a contained and level road surface. The system may create a stable road surface along which the bulk of its weight can be transported as the road surface is created. This allows operation in wet or marshy conditions.
Although the system described herein is described as a ‘road surfacing’ system, the term ‘road’ should be understood in an inclusive sense that extends not just to roadways along which vehicles travel, but also includes other surfaces on which vehicles may be present such as parking lots or industrial work sites. Various configurations of mobile frames may be used to support the road surfacing system. The webbing conveyor may comprise only a single conveyor, two conveyors as shown in
Number | Date | Country | Kind |
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3,066,150 | Dec 2019 | CA | national |