1. Field of the Invention
This invention relates generally to mold box assemblies and more particularly to such assemblies which are used to form molded products such as concrete products and which include structures for assisting in the exchange of one mold box with another within a concrete products forming machine (CPM).
2. Description of the Prior Art
Prior art machines for forming concrete products within a mold assembly include a product forming section comprising a stationary frame, an upper compression beam and a lower stripper beam. The mold assembly includes a head assembly that is mounted on the compression beam, and a mold box that is mounted on the frame and receives concrete material from a feed drawer. An example of such a system is shown in U.S. Pat. No. 5,807,591 which describes an improved concrete products forming machine (CPM) assigned in common to the assignee of the present application and herein incorporated by reference for all purposes.
In use, the feed drawer moves concrete material over the top of the mold box and dispenses the material into the contoured cavities of the mold box. The feed drawer typically includes an agitator assembly within the drawer that operated to break up the concrete and improve its consistency prior to dropping it into the mold. As the concrete material is dispensed, a vibration system shakes the mold box to spread the concrete material evenly within the mold box cavities in order to produce a more homogeneous concrete product. A wiper assembly, mounted to the front of the feed drawer, acts to scrape excess concrete from the shoes when the feed drawer is moved to an operative position above the mold box.
After the concrete is dispensed into the mold cavities, the feed drawer retracts from over the top of the mold box. A spreader, bolted separately to the front of the feed drawer, scrapes off excess concrete from the top of the mold when the feed drawer is retracted after filling the mold cavities. The compression beam then lowers, pushing shoes from the head assembly into corresponding cavities in the mold box. The shoes compress the concrete material during the vibration process. After compression is complete, the stripper beam lowers as the head assembly pushes further into the cavities against the molded material. A molded concrete product thereby emerges from the bottom of the mold box onto a pallet and is conveyed away for curing and a new pallet moved in its place beneath the underside of the mold assembly.
The mold box and head assembly are matched together and configured to form concrete products in a specific shape, size, and number. Each product configuration requires a different mold. When the operator desires the CPM to produce products in different configurations, the mold must be detached from mounts on the CPM and removed along with the assembly. A different mold box and head assembly must then be moved into place and mounted within the CPM.
Conventional methods for changing molds out in a CPM are typically labor intensive and result in a lot of downtime with the machine, leading to lost revenue. Accordingly, there is need for an improved system and method for better automating the process for changing molds within a concrete products forming machine that minimizes these drawbacks.
The invention consists of a two stage, well guided, hydraulic cylinder actuated telescoping mechanism attached to the underside of a top plate assembly of the feed drawer section of a concrete products forming machine. The two stage telescoping function allows the device to discretely position a mold in one of two horizontal positions, the first extended position is where the mold assembly is raised and lowered off of or onto the die supports with mold alignment dowels of the upper vibrator assembly located in the center section assembly of the concrete products forming machine. The second extended position is where the mold assembly is raised or lowered off of or onto a mold transfer cassette. A third fully retracted position keeps the mechanism stored when mold changes are not being performed. The vertical motion is controlled by an axis of motion already used in adjusting the top plate assembly of the feed drawer section of the concrete products forming machine into place for production.
The invention includes several new and useful features. First, the discrete horizontal positions and the use of tapered alignment blocks eliminate the chance of horizontal misalignment during the mold change process. Second, the telescoping functionality reduces the space requirements for operation and shipping, keeping the device within the envelope of the basic machine. Additionally, using the vertical motion of the existing top plate assembly eliminates the need for dedicated actuators to position the mold extractor assembly.
The purpose of the invention is to allow a mold assembly to be removed from the machine automatically and without use of hand tools or external overhead lifting devices, providing an increased isolation of the operator from the dangers associated with most mold change processes of industrial concrete product forming machines. This invention has the advantage of not requiring an additional vertical axis of motion by using the existing axis of the top plate assembly of the feed drawer section of the concrete products forming machine. An additional advantage of this system is its modular nature, allowing it to be integrated into an existing concrete products forming machine, thereby reducing the machine cost whereas many existing systems are integral to the machine and cannot be purchased without it.
The foregoing and other objects, features and advantages of the invention will become more readily apparent from the following detailed description of a preferred embodiment of the invention that proceeds with reference to the accompanying drawings.
Extraction arms 18, 20 are coupled together via a front bracing plate 24 and a rearwardly disposed cross-bracing plate 26 running between top ends of the arms. A hydraulic cylinder 28 is positioned along a central axis of the extraction assembly 10 and includes a cylinder mount block 30 at a rear end and a cylinder support block 32 at a front end mounted upward to the top plate assembly of the feed drawer section of the concrete products forming machine. A cylinder housing 34 is fixedly coupled between the mount block 30 and support block 32 and receives a hydraulic piston 36. A terminal end of the hydraulic piston 36 is coupled to an underside of the cross-bracing plate 26 spanning between extraction arms 18, 20. Actuation of the hydraulic cylinder 28 causes the piston 36 to extend out of the end of the housing 34 and push the plate 26, thereby causing the connected arms 18, 20 to slide forwardly along the inner guide rails 12, 14 to an extended position. Likewise, the hydraulic piston 36 may be retracted into the housing 34 and withdraw the arms 12, 14 to a retracted position as shown in
Mold extraction assembly 10 further includes a set of outer guide rails 38, 40, with each affixed to outside walls of respective extraction arms 18, 20 and extending parallel to the inner guide rails 12, 14 and mold extraction path 16. A pair of mold extraction forks 42, 44 are telescopically nested about the arm assembly and slidingly coupled to respective arms 18, 20 via a set of guide blocks, such as extraction fork guide block 46 (hidden in
Horizontal movement of the arm assembly is implemented by a pair of hydraulic cylinders 58, 60 coupled via a bracket (e.g. bracket 62) affixed to a back end of respective extraction arms 18, 20. Cylinders each include a cylinder housing 64 fixedly coupled to bracket 62 and a hydraulic piston 66 received in the housing and extending parallel to the extraction path 16. A terminal end of the hydraulic piston 66 is coupled to a rear end of a respective fork 44. Actuation of the hydraulic cylinders 60 causes the piston 66 to extend out of the end of the housing 64 and push the fork 44, thereby causing the fork assembly to slide forwardly along the outer guide rails 38, 40 to an extended position. Likewise, the hydraulic piston 66 may be retracted into the housing 64 and withdraw the forks 42, 44 to a retracted position as shown in
Vertical movement 56 of the mold extraction assembly 10 via means described further below acts to approach and lift the mold assembly 110 from below so it can be placed on either the concrete products machine shelves 134 or the cassette assembly 210 shelves 264, 266 during a mold exchange process. Retraction and extension of the mold extraction assembly occurs in three phases: (1) the fully retracted position is shown in
The mold assembly 110 includes a mold box portion 112 and a head assembly portion 114 that are fitted together in alignment with one another for mounting together onto a concrete products forming machine as described further below. Assemblies 112 and 114 are constructed to form mold concrete products having a certain size and configuration, whereas different mold assemblies can have differently configured assemblies resulting in different products. As the exchange of one mold assembly with another on a concrete products forming machine typically requires a large amount of manual labor and downtime, enabling an automated exchange of one mold assembly with another using the extraction assembly described herein is a key goal of the invention.
Generally, mold box 112 includes a body with a front wall and a back wall joined together with side walls and having cavities for receiving and molding the concrete products. The side walls each have a side face that spans between a bottom facing surface of the side face and a top facing surface.
A mounting bracket extension 132 is coupled to each side wall of the mold box 112 to extend the width of the mold assembly 110. In use, the front and back walls of the mold box 112 are sized for extending substantially between a pair of shelves 134 (
Formed in an underside of this lower mounting surface are die alignment holes 136 (
Mold transfer locators 140 (
Coupled on either side of the spreader plate 260 are features configured to guide and retain a mold assembly within the cassette. A pair of shelves 264, 266 are spaced on each side of the spreader plate 260. The shelves are spaced an identical distance apart as the shelves or die supports 134 on the CPM to which the mold assemblies are operatively mounted. The pair of shelves 264, 266 are separated by a central expanse configured to receive the forks 42, 44 of a mold exchange assembly, noting that the spreader plate 260 is located below the bottom surface of the shelves to establish a height of the vertical expanse between the shelves 264, 266. The height of the vertical expanse—and in this case the height of shelves 264, 266—is large enough so as to accommodate the height of a front end of the mold extractor forks 42, 44 and prevent collision with the spreader plate 260 when the forks have set the mold assembly 110 onto the top surface of shelves 264, 266 and is then withdrawn back to a retracted position.
A pair of inwardly sloped guide plates 268, 270 are coupled to outside peripheral sections of the shelves. These plates 268, 270 are angled from a wider top spacing to a narrower bottom spacing and are configured to provide surfaces that guide the mold onto the shelves. Mold alignment dowels 272 are centrally located on a top surface of each of the shelves 264, 266. In use, the mold extraction device 10 would lift mold assembly 110 from the shelves 134 on the CPM and carry it through the opening 262 of cassette 210. The mold extraction device would then lower the mold assembly 110 onto cassette shelves 264, 266 so that apertures on an underside of the mold assembly receive dowels 272.
In summary, therefore, the mold extractor assembly is comprised of a mold extractor fork assembly which during mold change supports the mold assembly and is supported by the mold extractor arm assembly. Hydraulic cylinders are used to move the mold extractor fork assembly horizontally relative to the mold extractor arm assembly.
The mold extractor fork assembly is comprised of two extractor forks to support the mold assembly, tapered alignment blocks that indicate the correct position of the mold assembly on the two extractor forks, and mounted linear runner blocks that guide the mold extractor fork assembly on horizontal guide rails mounted to the mold extractor fork assembly. Each extractor fork has means for attaching to the rod end of a hydraulic cylinder to move the extractor forks relative to the mold extractor arm assembly.
The mold extractor arm assembly is comprised of two extractor arms that support the mold extractor fork assembly and are mounted to the top plate assembly of the rear feed drawer section. Horizontal guide rails are mounted to the extractor arms that support and guide the mold extractor fork assembly. Runner blocks are mounted to the extractor arms that are supported by guide rails mounted to the top plate assembly. The mold extractor arm assembly has a means for attaching the rod end of a hydraulic cylinder to move the mold extractor arm assembly relative to the top plate assembly.
The mold assembly is comprised of two main sections, the mold head assembly and the mold box assembly. These two sections are placed together by the center section assembly to be ready for transport by the mold extractor assembly. The position of the mold assembly for transport by the mold extractor assembly is indicated by tapered alignment blocks fitting into like holes in the mold box assembly.
Having described and illustrated the principles of the invention in a preferred embodiment thereof, it should be apparent that the invention can be modified in arrangement and detail without departing from such principles. For instance, it is understood that the hydraulic cylinders are just one aspect of drive means that can extend and retract the forks and arms of the mold extraction device and can take the form of hydraulics, pneumatics, electric screw-driven mechanisms, etc. We claim all modifications and variation coming within the spirit and scope of the following claims.