The present disclosure relates to mixing plants, and in particular mobile mixing plants for forming concrete and concrete-like materials in batches.
Greatly valued for its durability, high compressive strength, and fire-resistance, concrete is one of the world's oldest and most used man-made building materials. In its simplest form, it consists of three main components: aggregates such as sand, gravel and crushed stone; a binder such as Portland cement; and water. Once these components have been mixed, the concrete must be quickly delivered to its intended location, before it hardens and becomes impossible to pour.
Because concrete production is time-sensitive, various methods and devices have been developed over the years for producing and transporting concrete to its ultimate destination in a quick and efficient manner. Central mixing, or wet-batch, concrete production is a method in which all of the ingredients are weighed and mixed in a stationary plant before being discharged to a truck that transports the wet concrete mixture to the construction site. Transit mixing is a method in which all the dry ingredients are weighed at the stationary plant and then charged into a truck that mixes the ingredients as they are being transported to the construction site, where water is added. In shrink mixing, mortar ingredients (sand, cement, water, and admixtures) are added, and the coarse aggregates are added as the mortar is discharged to the truck. All of these methods have certain advantages and disadvantages. Central mixing is generally recognized as allowing better quality control and faster production, but is not practical for all construction sites. The complexity of the plant makes portable set up more costly and time consuming. Transit mixing plants are generally less complex and less costly to operate, but standard transit mix plants do not have a concrete mixer, removing some of the advantages of the product quality control. Shrink mixing plants retain the product control that central mix gives, and allow the batch size to be increased and the mixing time to be decreased. By performing the final mixing in the revolving drum mixer truck or other transport unit, the plants allow for potentially higher production rates.
Some attempts have been made to design mobile mixing plants that allow concrete to be mixed and poured at the construction site. However, most of these plants have required a large number of individual components, such as bins and mixers, which are typically transported on separate trucks and assembled together at the site. The time and labor involved in transporting and installing these plants can be prohibitive. The volumetric trucks that are capable of mixing concrete in one complete unit do not provide concrete quality control required for all structural applications.
Another problem associated with modern-day concrete production is that Portland cement is produced in large, fossil fuel-burning kilns that create air pollution and emit large amounts of carbon, contributing significantly to global warming. As a result, various alternative binders such as environmentally friendly geo-polymer cements are growing in popularity. These cements require the use of activators and various other additives that require the use of additional bins and tanks. Current cement trucks and mobile mixing plants are not configured to accommodate these extra containers.
The above problems and other problems are addressed by this disclosure as summarized below.
The present disclosure relates to a construction plant including a plurality of bins adapted to hold construction materials, a horizontal shaft mixer configured to receive and mix materials discharged from bins, and conveying mechanisms for transporting the materials from the bins to the mixer. The bins, mixer, and conveying mechanisms are supported on a frame that keeps the components together as a compact unit for convenient transportation. A plurality of lift legs attached to the frame to allow the construction plant to be set at a job site. In some embodiments, plant has a maximum dimension of no more than 53 feet in length, 13 foot 6 inches in height, and 8 foot 6 inches in width. In one embodiment, the length of the plant is less than 40 feet.
In one embodiment, the frame includes a plurality of wheels and is provided with a fifth wheel hitch, allowing the construction plant to be attached to a motorized vehicle for towing. In another embodiment, the wheels and trailer fifth wheel hitch may be eliminated, and the frame may be transported or mounted on a flatbed truck.
The plurality of bins includes a first set of low-profile bins configured to contain and dispense granular materials, and a second set of low-profile bins configured to contain and dispense powdery materials. In some embodiments, the granular materials may be aggregates and the powdery materials may be cementitious materials. Each bin may be provided with a scale configured to measure the weight of the material contained in the bin. Tanks containing liquids such as water, cement activators, and cement admixtures may also be supported on the frame.
The conveying mechanisms include a first conveying assembly for transporting granular materials from the first set of bins to the mixer and a second conveying assembly for transporting powdery materials from the second set of bins to the mixer. In some embodiments, the first conveying assembly may include a plurality of belt conveyors, wherein each conveyor is associated with and located below a different one of the bins in the first set. In some embodiments, the second conveying assembly may include a blending auger that receives and combines the powdered materials from the bins in the second set before delivering them to the mixer. The second conveying assembly may also include an internal auger at the bottom of each of the bins in the second set, for facilitating discharge of powdery materials from these bins.
In some embodiments, the first set of bins is located at the distal end of the plant, directly above the distal end of the mixer, which communicates with a discharge auger. One or more of the bins in this set may contain a vibrating mechanism for facilitating discharge of granular materials from the bin. The bin nearest the discharge auger contains coarse aggregates. The conveyor underneath this bin is a two-way conveyor, allowing the coarse aggregates to be transported either to an interior portion of the mixer, for central or transit mixing, or to a shrink mixing inlet at the discharge end of the mixer, where it combines with the mortar before discharge.
In some embodiments, the mixer includes a mixer mechanism mounted for rotation within a mixer housing. The mixer mechanism may be a reversible, twin-shaft mixer. The mixer housing may have a plurality of granular material inlets, including a shrink mixing inlet, central and transit mixing inlets, and a single cementitious inlet. The shrink mixing inlet may be located at the distal end of the mixer, below the distal end of the coarse aggregate conveyor. A first central and transit mixing inlet is located proximally of the shrink mixing inlet, below the proximal end of the coarse aggregate conveyors, and at least one other central transit mixing inlet is located proximally of the first central and transit mixing inlet, below a conveyor associated with at least one of the other granular material bins.
In some embodiments, a controller is electronically coupled weight scales, and configured operating the mixer, the conveyor mechanisms, and the discharge auger in response to information received from the weight scales. Both the controller and the mixer may be powered by a hydraulic power system comprising a diesel engine and a battery. Alternatively, the controller, mixer, and other components may be powered by electrical power and motors, or by alternative energy sources, such as solar energy, wind, and the like.
As required, detailed embodiments of the present invention are disclosed herein; however, it is to be understood that the disclosed embodiments are merely exemplary of the invention that may be embodied in various and alternative forms. The figures are not necessarily to scale; some features may be exaggerated or minimized to show details of particular components. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a representative basis for teaching one skilled in the art to variously employ the present invention.
For the purposes of this example, the invention will be described as a concrete plant, and will use terms, such as “cement” and “aggregate”, which are common in the concrete industry. However, a wide variety of products other than concrete may be produced in this plant, such as landscaping materials, USGA root zone mixes, and other products requiring a blend of granular and powdery materials. Thus, the term “cement” should be understood to include to any cement-like or cementitious product or binder or, more broadly, any powdery substances having a mesh size of smaller than 200 mesh. Similar, the term “aggregate” refers to sand, gravel, crushed stone, and similar granular products having a mesh size of 200 or greater.
Referring to
The bins supported on the rails 28 include a first set of bins 40 for containing granular materials such as aggregates and a second set of bins 42 for containing powdery materials such as cement and other binders. The first set of bins 40 is located at the distal end of the rails 28, and the second set of bins 42 is located at the proximal end of the rails 28. The first set of bins 40 includes a distalmost granular material bin 44, which may contain a coarser material than the other granular material bins 46, 48. For example, the distalmost granular material bin 44 may contain coarse aggregates, such as gravel or crushed stone for producing concrete. Bins 42, 46, and 48 may be substantially identical to one another in structure, and may be equal to one another in height and width, but may differ in length. For instance, the proximalmost granular material bin 48 may be shorter in length than bins 42 and 48, for containing materials that are required in smaller volumes. The powdered material bins 50, 52, 54, and 56 in the second set of bins 42 may also be the same height and width as the granular material bins 40 and in the illustrated embodiment are equal in the length to one another, but this is not required.
A rack 58 is supported on the base 24 of frame 22 proximally of the first and second sets of bins 40, 42. The rack 58 includes a lower shelf 60 supporting a first tank 62 for containing a first liquid such as water, and an upper shelf 64 supporting a second tank 66 for containing a second liquid such as cement activator. In addition, a pair of admixture tanks 68, 70 is supported on the base 24 of frame 22 between the liquid tanks 62, 66 and the bins 44-56.
A horizontal shaft mixer 72 is supported on the base 24 of the frame 22, below the bins 44-56. A first conveyor assembly 74 between the granular material bins 44-48 and the mixer 72 is provided for delivering granular materials from the bins 44-48 to the mixer 72. A second conveyor assembly 76 between the powdery material bins 50-56 and the mixer 72 is provided for providing powdery materials from the bins 50-56 to the mixer 72. In addition, a discharge auger 78 is provided for discharging the final mixture to a concrete form, a truck, or other location.
A batch controller 80 mounted on one side of the frame 22 includes a computer or other logic based technology for monitoring the materials in the various bins and tanks and operating the mixer 72, conveying assemblies 74, 76, discharge auger 78, and other components of the plant 20 as needed. Various commercially available programmable batch controllers may be suitable for use with the disclosed system. The Jonel Archer batch controller (Fullerton, Calif.) is one example of such a controller.
The batch controller 80 may receive information from a variety of sources. For instance, it may receive concrete quality information from concrete sensors located inside the mixer 72. It also receives weight information from load cells located under each of the bins and tanks containing construction materials. The controller 80 processes this information to determine parameters such as the proper opening and closing times, durations, and sequence for the valves associated with the various bins and tanks. More specifically, the batch controller 80 controls the operation of the various rams, valves, conveyors, and other components of the system as needed to batch the material mixtures.
In one operation, the batch controller 80 monitors the weight of materials entering or exiting the various bins and tanks, and cuts off flow when predetermined conditions are met. The controller 80 then waits for 2 seconds as required by NIST Handbook 44 before accepting the weight. If at this point, the materials are under the required weight, the materials are “jogged” until the weight is within accepted tolerances. If the materials are overweight, the controller 80 flags the operator to accept or reject the load.
The batch controller 80 may also ensure quality levels by determining, for instance that the discharge valves will not be opened unless and until certain quality requirements are met. In addition, the batch controller 80 may also be programmed to allow an operator to select a particular type of batch mixing operation to be performed. For instance, an operator may be allowed to select from such methods and approaches as truck-mixed, shrink-mixed, central-mixed batching processes, among others.
The controller 80, mixer 72, conveying assemblies 74, 76, discharge auger 78, and other components are powered by a power system 82. In the illustrated embodiment, the power system 82 is a hydraulic power system including a diesel engine 84, hydraulic pumps, diesel fuel tank, oil tank 86, oil cooler 88, battery 90, low pressure filter 92, and high pressure filter 94. In other embodiments, the power system may be electric or solar.
In one embodiment of the invention, the frame 12, bins, 44-56, tanks 62, 66, 68, 70, mixer 72, conveying assemblies 74, 76, controller 80, and power system 82 are all sized and configured such that the maximum dimensions of the plant are no more than 53 feet in length, 13 foot 6 inches in height, and 8 foot 6 inches in width. In one embodiment, the length of the plant is no more than 40 feet in length. This small footprint allows the plant to be towed on public roads without a special permit. In addition, it reduces the amount of time required to set up the plant, and allows for use in job sites with limited working space. In addition, the short height makes it convenient to fill the bins with equipment that is not as large as required for other plant setups. The bins may be refilled with super sacks of product on jobs that do not require high production rates. This eliminates the need for stockpiles of materials for replenishment.
At least one load cell 127 is provided underneath the lower corner portion 122 of the bin 44, in a space between the bin 44 and the rail 28. The number of load cells under each bin is determined by Handbook 44. As seen in
The small aggregate bins 46 and 48 may be substantially identical in structure to the coarse aggegrate bin 44, except that their respective conveyors 96, 98 need not be two-way conveyors.
Returning now to
The bin 50 has a lower corner portion 174 having a set of laterally projecting pins or bolts 175 that are received in the associated pear-shaped slots 144 in the hold-down mechanism 118. The lower corner portion 174 communicates with a very short tapered portion 176 that, in some embodiments, may be eliminated altogether. The tapered portion 176 terminates in a wide cylindrical neck 178 having a flat bottom 180 that defines a discharge opening 181. Internal auger 108, located just above the flat bottom 180 and driven by hydraulic motor 177 facilitates the flow of powdery material through the discharge opening 181. Below the blending auger 108 is a gate ram 179 which, when actuated by the controller 80, pushes against arm 183 causing shaft 185 to rotate 90°, opening the gate valve 154 to allow materials to be discharged.
As seen in
The length L of the mixer 72 is substantially longer than a conventional mixer that would be used for a plant of similar capacity. For instance, a mixer in a plant designed according to the present disclosure may have a length L of approximately 21 feet for a discharge capacity of 3 cubic yards, whereas the length of commercially available mixers for this capacity is typically around 12 feet. At the same time, the internal bore diameter of the mixer 72 is substantially less than the internal bore diameter of a conventional mixer. For instance, for a discharge capacity of 3 cubic yards, mixer 72 may have an internal bore diameter of about 22 inches, where a conventional mixer for this capacity typically has an inner bore diameter of 4 to 5 feet. The uniquely low bore diameter to length ratio of the mixer 72 allows the mixer to be operated at maximum speeds in the range of about 30 to 40 rpm or higher, in contrast to the maximum speeds of 14 to 27 rpm for conventional mixers. Thus, the mixer 72 may operate at a high speed of about 32 rpm, or even up to 40 rpm or greater, to maximize shear mixing and to complete the mixing and blending of the materials in a very short time, such as 30 seconds or less. The mixer 52 may also be operated at slower speeds to control the discharge rate exiting through the mixer discharge gates 192.
The mixing mechanism 182 is bi-directional. That is, the augers 186 may be rotated in one direction to cause materials in the mixer to move toward the mixer discharge gates 192, or in the opposite direction to cause materials at the discharge end of the mixer to move toward the center of the mixer. In central and transit mixing operations, for instance, it may be desirable initially to run the mixing mechanism 182 in a first direction, causing aggregates dropped in through inlets 102 and 104 to move in a proximal direction so they can be thoroughly mixed with the powdery materials dropped in through inlet 116. Then, after the materials are mixed, the direction of the mixing mechanism 182 is reversed, causing the materials to be discharged through the discharge gates 192. It may also be desirable to run the mixing mechanism 182 in two directions for cleaning. As another example, the mixing mechanism 182 may need to change directions to prepare a mixture with or without certain features. As an example of preparing a mixture without undesirable features, the mixing mechanism 182 may be used to reduce or eliminate balling (e.g., cement balling), pockets (e.g., aggregate pockets), deficiencies (e.g., paste deficiencies) or any other features deemed undesirable in a particular mixture.
Each mixer gate 192 is kept closed until the batch controller 80 determines that the contents are ready to be discharged, at which point, the corresponding gate ram 194 is actuated, causing the gate 192 to rotate approximately 90 degrees about a seal block, allowing concrete to be discharged. The discharged concrete drops into a chute 196, which directs it through a cylindrical tube 198 into the inlet 200 of discharge auger 78.
A pair of rearwardly extending flanges 202, 204 is provided at the bottom end of the discharge auger 78. Each flange 202, 204 includes a notch or aperture 206 that receives a pivot pin 208 projecting outwardly from cylindrical tube 198, allowing the discharge auger 78 to pivot about a horizontal axis. Each flange also includes a finger 210 that is received in a circumferentially extending groove 212 formed in the tube 198, allowing the discharge auger 78 to swivel about a vertical axis. Thus, the discharge auger can be moved from a transit position, minimizing the footprint of the mixing plant, to an operating position, in line with the concrete forms or other location where the mixed material is to be dispensed. Normally, the discharge auger 78 is locked in the transit position by a safety latch which is manually released when certain conditions are met. At this point, a user can manually operate a hydraulic control valve that actuates auger ram 214 to place the discharge auger 78 in the desired position. This position can be changed as needed during the discharge process.
Discharge mechanisms other than discharge auger 78 may also be used. For instance, materials may be transported away from the discharge end of the mixer using a conveyor, or fed directly into concrete pumps.
The mixer housing 184 includes granular material inlets 102, 104, and 116 for receiving granular materials from granular bins 44, 46, 48. It also includes a powdery material inlet 216 for receiving powdery materials from blending auger 106, a liquid inlet 218 for receiving liquids from liquid tanks 62, 66 and admixture inlets 220, 222 for receiving admixture from admixture tanks 68, 70.
The present disclosure includes concrete batching methods. In one embodiment, the batching method includes the following steps: loading raw materials into the bins of the mixing plant; pre-weighing the raw materials; mixing the raw materials in the mixer; and transporting the mobile plant to a job site.
The order of the steps may vary depending on the requirements of the construction projects. For instance, some projects may require that the materials are mixed before transporting the plant to the job site, while other projects may require or allow mixing after the plant is transported to the job site.
The manner of mixing the materials may also vary depending on job requirements. For instance, for jobs requiring central mixing, all of the dry materials in bins 44-56 plus at least one of the liquids in liquid tanks 62, 66 are conveyed to the mixer 72, which thoroughly mixes materials before moving them to the discharge auger, which then discharges the final product into concrete molds or loads them into a mixer truck for further transport. For jobs requiring transit mixing, the dry materials in are conveyed to the mixer 72, while the liquid materials are transported separately to the discharge end of the discharge auger or directly into a revolving drum truck or similar transport for mixing en route to the job. For jobs requiring shrink-mixing, water, admixtures, and all the dry ingredients except the coarse aggregates are mixed in the mixer 72. The coarse aggregates are dropped through the shrink-mixing inlet 102 at the distal end of the mixer 72 so they only pass through the mixer discharge gates, before they drop through chute 196 into the discharge auger 78, where they join the other pre mixed ingredients (Concrete Mortar).
For both central and transit mixing approaches, the mixing step includes moving the conveyor 100 under the coarse aggregate bin 44 in a proximal direction to bring the coarse aggregate to the central and transmit mixing inlet 104 located in an interior section of the mixer housing 184. This also includes rotating the mixer mechanism 182 in a first direction to move the coarse aggregate into the interior of the mixer, and then rotating the mixer mechanism 182 in a second direction to discharge materials into the discharge auger 78.
For a shrink-mixing approach, the mixing step includes moving the conveyor 100 under the coarse aggregate bin 44 in a distal direction to bring the coarse aggregate to the mixing inlet 102. This may only require rotating the mixer mechanism 182 in the second direction, since it is not necessary to move the coarse aggregate into the interior of the mixer.
In addition to the steps mentioned above, the method may include installation steps, control steps, and discharge steps. The installation steps may, for instance, include detaching the mixing plant 20 from the transport vehicle, releasing the hold-down mechanism 140, and leveling the mixing plant. The control steps may include starting the power source 82, selecting the mixing approach, and selecting one or more mixer speeds and directions. The discharge step may include positioning the discharge auger 78, opening the mixer gates 192, positioning the discharge auger 78, and discharging the materials. Additional steps may include replenishing the materials and moving the plant to the next job site. The steps of the above methods need not be executed in a particular order. In certain embodiments, only some and not all of the steps are executed.
While exemplary embodiments are described above, it is not intended that these embodiments describe all possible forms of the invention. Rather, the words used in the specification are words of description rather than limitation, and it is understood that various changes may be made without departing from the spirit and scope of the invention. For instance, the various bins and tanks may be loaded with mixing materials for construction projects requiring products other than concrete. Similarly, the mixer 72 can be a ribbon mixer, a paddle mixer, a single-shaft ribbon or paddle mixer, or a twin-shaft ribbon or paddle mixer. In some applications, the belt conveyors under the aggregate bins may be replaced with augers. The energy source can be electric or solar. Manual controls may be used rather than an electronic logic-based controller. Additionally, the features of various implementing embodiments may be combined to form further embodiments of the invention.
This application claims the benefit of U.S. provisional application Ser. No. 62/195,247, filed Jul. 21, 2015 the disclosure of which is hereby incorporated in its entirety by reference herein.
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