THE FIELD OF THE INVENTION
The present invention relates to masonry blocks, and more particularly to methods of making concrete blocks employing mold assemblies having at least one moveable liner plate and concrete blocks made by such methods.
BACKGROUND OF THE INVENTION
Concrete blocks, also referred to as concrete masonry units (CMU's), are typically manufactured by forming them into various shapes using a concrete block machine employing a mold frame assembled so as to form a mold box. A mold cavity having a negative of a desired shape of the block to be formed is provided within the mold box. A support board, or pallet, is moved via a conveyor system onto a pallet table. The pallet table is moved upward until the pallet contacts and forms a bottom of the mold box. The cavity is then filled with concrete by a moveable feedbox drawer.
As soon as the mold is filled with concrete, the feedbox drawer is moved back to a storage position and a plunger, or head shoe assembly, descends to form a top of the mold. The head shoe assembly is typically matched to the top outside surface of the mold cavity and is hydraulically or mechanically pressed down on the concrete. The head shoe assembly compresses the concrete to a desired pounds-per-square-inch (psi) rating and block dimension while simultaneously vibrating the mold along with the vibrating table, resulting in substantial compression and optimal distribution of the concrete throughout the mold cavity.
Because of the compression, the concrete reaches a level of hardness that permits immediate stripping of the finished block from the mold. To remove the finished block from the mold, the mold remains stationary while the shoe and pallet table, along with the corresponding pallet, are moved downward and force the block from the mold onto the pallet. As soon as the bottom edge of the head shoe assembly clears the bottom edge of the mold, the conveyor system moves the pallet with the finished block forward, and another pallet takes its place under the mold. The pallet table then raises the next pallet to form a bottom of the mold box for the next block, and the process is repeated.
For many types of CMU's (e.g., pavers, patio blocks, light weight blocks, cinder blocks, etc.), but for retaining wall blocks and architectural units in particular, it is desirable for at least one surface of the block to have a desired texture, such as a stone-like texture. One technique for creating a desired texture on the block surface is to provide a negative of a desired pattern or texture on the side walls of the mold. However, because of the way finished blocks are vertically ejected from the mold, any such pattern or texture would be stripped from the side walls unless they are moved away from the mold interior prior to the block being ejected.
One technique employed for moving the sidewalls of a mold involves the use of a cam mechanism to move the sidewalls of the mold inward and an opposing spring to push the sidewalls outward from the center of the mold. However, this technique applies an “active” force to the sidewall only when the sidewall is being moved inward and relies on the energy stored in the spring to move the sidewall outward. The energy stored in the spring may potentially be insufficient to retract the sidewall if the sidewall sticks to the concrete. Additionally, the cam mechanism can potentially be difficult to utilize within the limited confines of a concrete block machine.
A second technique involves using a piston to extend and retract the sidewall. However, a shaft of the piston shaft is coupled directly to the moveable sidewall and moves in-line with the direction of movement of the moveable sidewall. Thus, during compression of the concrete by the head shoe assembly, an enormous amount of pressure is exerted directly on the piston via the piston shaft. Consequently, a piston having a high psi rating is required to hold the sidewall in place during compression and vibration of the concrete. Additionally, the direct pressure on the piston shaft can potentially cause increased wear and shorten the expected life of the piston.
SUMMARY OF THE INVENTION
One aspect of the present invention provides a method of producing a masonry block having a front face, a rear face, an upper face, a lower face, and a pair of opposed side faces. The method includes providing a mold assembly having a plurality of liner plates that together form a mold cavity having an open top and an open bottom, wherein at least a first liner plate is moveable between a retracted position and an extended position with a gear drive assembly, and wherein the first liner plate is angled such that when the first liner plate is in the extended position the bottom of the mold cavity is narrower than the top by a predetermined distance. The first liner plate is moved to the extended position, a pallet is positioned below the mold to close the bottom of the mold cavity, dry cast concrete is placed in the mold cavity via the open top, a shoe assembly is positioned into the mold cavity via the open top, and the dry cast concrete is compacted to form a pre-cured masonry block with the rear face resting on the pallet, the front face contacting the shoe assembly, and one side face of the pair of opposed side faces contacting the first liner plate. The first liner plate is moved to the retracted position such that the bottom of the mold cavity is narrower than the top by the predetermined distance and at least as wide as the top when first liner plate is in the extended position, the pre-cured masonry block is expelled from the mold cavity and cured.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a perspective view of one exemplary embodiment of a mold assembly having moveable liner plates according to the present invention.
FIG. 2 is a perspective view of one exemplary embodiment of a gear drive assembly and moveable liner plate according to the present invention.
FIG. 3A is a top view of gear drive assembly and moveable liner plate as illustrated in FIG. 2.
FIG. 3B is a side view of gear drive assembly and moveable liner plate as illustrated in FIG. 2.
FIG. 4A is a top view of the mold assembly of FIG. 1 having the liner plates retracted.
FIG. 4B is a top view of the mold assembly of FIG. 1 having the liner plates extended.
FIG. 5A illustrates a top view of one exemplary embodiment of a gear plate according to the present invention.
FIG. 5B illustrates an end view of the gear plate illustrated by FIG. 5A.
FIG. 5C illustrates a bottom view of one exemplary embodiment of a gear head according to the present invention.
FIG. 5D illustrates an end view of the gear head of FIG. 5C.
FIG. 6A is a top view of one exemplary embodiment of a gear track according to the present invention.
FIG. 6B is a side view of the gear track of FIG. 6A.
FIG. 6C is an end view of the gear track of FIG. 6A.
FIG. 7 is a diagram illustrating the relationship between a gear track and gear plate according to the present invention.
FIG. 8A is a top view illustrating the relationship between one exemplary embodiment of a gear head, gear plate, and gear track according to the present invention.
FIG. 8B is a side view of the illustration of FIG. 8A.
FIG. 8C is an end view of the illustration of FIG. 8A.
FIG. 9A is a top view illustrating one exemplary embodiment of a gear plate being in a retracted position within a gear track according to the present invention.
FIG. 9B is a top view illustrating one exemplary embodiment of a gear plate being in an extended position from a gear track according to the present invention.
FIG. 10A is a diagram illustrating one exemplary embodiment of drive unit according to the present invention.
FIG. 10B is a partial top view of the drive unit of the illustration of FIG. 10A.
FIG. 11A is a top view illustrating one exemplary embodiment of a mold assembly according to the present invention.
FIG. 11B is a diagram illustrating one exemplary embodiment of a gear drive assembly according to the present invention.
FIG. 12 is a perspective view illustrating a portion of one exemplary embodiment of a mold assembly according to the present invention.
FIG. 13 is a perspective view illustrating one exemplary embodiment of a gear drive assembly according to the present invention.
FIG. 14 is a top view illustrating a portion of one exemplary embodiment of a mold assembly and gear drive assembly according to the present invention.
FIG. 15A is a top view illustrating a portion of one exemplary embodiment of a gear drive assembly employing a stabilizer assembly.
FIG. 15B is a cross-sectional view of the gear drive assembly of FIG. 15A.
FIG. 15C is a cross-sectional view of the gear drive assembly of FIG. 15A.
FIG. 16 is a side view illustrating a portion of one exemplary embodiment of a gear drive assembly and moveable liner plate according to the present invention.
FIG. 17 is a block diagram illustrating one exemplary embodiment of a mold assembly employing a control system according to the present invention.
FIG. 18A is a top view illustrating a portion of one exemplary embodiment of gear drive assembly employing a screw drive system according to the present invention.
FIG. 18B is a lateral cross-sectional view of the gear drive assembly of FIG. 18A.
FIG. 18C is a longitudinal cross-sectional view of the gear drive assembly of FIG. 18A.
FIG. 19 is flow diagram illustrating one exemplary embodiment of a process for forming a concrete block employing a mold assembly according to the present invention.
FIG. 20A is a top view illustrating one exemplary embodiment of a mold assembly in accordance with the present invention.
FIG. 20B is a top view further illustrating the mold assembly of FIG. 20A.
FIG. 21A illustrates an example of a concrete block formed by the mold assembly of FIGS. 20A and 20B.
FIG. 21B illustrates an example of a concrete block formed by the mold assembly of FIGS. 20A and 20B.
FIG. 21C is a simplified illustration of an exemplary implementation of a mold assembly according to the present invention and a corresponding concrete block formed by such an implementation.
FIG. 21D is a simplified illustration of an exemplary implementation of a mold assembly according to the present invention and a corresponding concrete block formed by such an implementation.
FIG. 21E is a simplified illustration of an exemplary implementation of a mold assembly according to the present invention and a corresponding concrete block formed by such an implementation.
FIG. 21F is a simplified illustration of an exemplary implementation of a mold assembly according to the present invention and a corresponding concrete block formed by such an implementation.
FIG. 22A is a top view illustrating one exemplary embodiment of a mold assembly in accordance with the present invention.
FIG. 22B is a top view further illustrating the mold assembly of FIG. 22A.
FIG. 22C is a side view illustrating one exemplary embodiment of the mold assembly of FIGS. 22A and 22B.
FIG. 22D is a side view illustrating another exemplary embodiment of the mold assembly of FIGS. 22A and 22B.
FIG. 23A illustrates an example of a concrete block formed by the mold assembly of FIGS. 22A through 22C.
FIG. 23B illustrates an example of a concrete block formed by the mold assembly of FIGS. 22A through 22C.
FIG. 23C illustrates an example of a concrete block formed by the mold assembly of FIGS. 22A through 22C.
FIG. 23D illustrates an example of a concrete block formed by the mold assembly of FIGS. 22A, 22B and 22D.
FIG. 24A is a simplified illustration of an exemplary implementation of a mold assembly according to the present invention and a corresponding concrete block formed by such an implementation.
FIG. 24B is a simplified illustration of an exemplary implementation of a mold assembly according to the present invention and a corresponding concrete block formed by such an implementation.
FIG. 24C is a simplified illustration of an exemplary implementation of a mold assembly according to the present invention and a corresponding concrete block formed by such an implementation.
FIG. 24D is a simplified illustration of an exemplary implementation of a mold assembly according to the present invention and a corresponding concrete block formed by such an implementation.
FIG. 24E is a simplified illustration of an exemplary implementation of a mold assembly according to the present invention and a corresponding concrete block formed by such an implementation.
FIG. 25A is a simplified illustration of an exemplary implementation of a mold assembly according to the present invention and a corresponding concrete block formed by such an implementation.
FIG. 25B is a simplified illustration of an exemplary implementation of a mold assembly according to the present invention and a corresponding concrete block formed by such an implementation.
FIG. 25C is a simplified illustration of an exemplary implementation of a mold assembly according to the present invention and a corresponding concrete block formed by such an implementation.
FIG. 25D is a simplified illustration of an exemplary implementation of a mold assembly according to the present invention and a corresponding concrete block formed by such an implementation.
FIG. 25E is a simplified illustration of an exemplary implementation of a mold assembly according to the present invention and a corresponding concrete block formed by such an implementation.
FIG. 25F is a simplified illustration of an exemplary implementation of a mold assembly according to the present invention and a corresponding concrete block formed by such an implementation.
FIG. 26A is a simplified lateral cross-sectional view of one exemplary embodiment of a mold assembly according to the present invention.
FIG. 26B is a simplified lateral cross-sectional further illustrating the mold assembly of FIG. 26A.
FIG. 26C is a simplified longitudinal cross-sectional view of one exemplary embodiment of the mold assembly of FIGS. 26A and 26B.
FIG. 26D is a simplified longitudinal cross-sectional view of another exemplary embodiment of the mold assembly of FIGS. 26A and 26B.
FIG. 26E is a simplified longitudinal cross-sectional view of another exemplary embodiment of the mold assembly of FIGS. 26A and 26B.
FIG. 27A illustrates an example of a concrete block formed by the mold assembly of FIG. 26C.
FIG. 27B illustrates an example of a concrete block formed by the mold assembly of FIG. 26D.
FIG. 27C illustrates an example of a concrete block formed by the mold assembly of FIG. 26E.
FIG. 28A illustrates an example three-dimensional texture imprinted on a face of a concrete block produced by a mold assembly in accordance with the present invention.
FIG. 28B illustrates and example soil retaining wall employing retaining wall blocks having a front face imprinted with three-dimensional texture by a mold assembly in accordance with the present invention.
FIG. 29 is a flow diagram illustrating one embodiment of a process for creating a desired three-dimensional texture on a liner plate and/or liner face according to the present invention.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
In the following Detailed Description, reference is made to the accompanying drawings which form a part hereof, and in which is shown by way of illustration specific embodiments in which the invention may be practiced. In this regard, directional terminology, such as “top,” “bottom,” “front,” “back,” “leading,” “trailing,” etc., is used with reference to the orientation of the Figure(s) being described. Because components of embodiments of the present invention can be positioned in a number of different orientations, the directional terminology is used for purposes of illustration and is in no way limiting. It is to be understood that other embodiments may be utilized and structural or logical changes may be made without departing from the scope of the present invention. The following detailed description, therefore, is not to be taken in a limiting sense, and the scope of the present invention is defined by the appended claims.
FIG. 1 is a perspective view of one exemplary embodiment of a mold assembly 30 having moveable liner plates 32a, 32b, 32c and 32d according to the present invention. Mold assembly 30 includes a drive system assembly 31 having side-members 34a and 34b and cross-members 36a and 36b, respectively having an inner wall 38a, 38b, 40a, and 40b, and coupled to one another such that the inner surfaces form a mold box 42. In the illustrated embodiment, cross members 36a and 36b are bolted to side members 34a and 34b with bolts 37.
Moveable liner plates 32a, 32b, 32c, and 32d, respectively have a front surface 44a, 44b, 44c, and 44d configured so as to form a mold cavity 46. In the illustrated embodiment, each liner plate has an associated gear drive assembly located internally to an adjacent mold frame member. A portion of a gear drive assembly 50 corresponding to liner plate 32a and located internally to cross-member 36a is shown extending through side-member 34a. Each gear drive assembly is selectively coupled to its associated liner plate and configured to move the liner plate toward the interior of mold cavity 46 by applying a first force in a first direction parallel to the associated cross-member, and to move the liner plate away from the interior of mold cavity 46 by applying a second force in a direction opposite the first direction. Side members 34a and 34b and cross-members 36a and 36b each have a corresponding lubrication port that extends into the member and provides lubrication to the corresponds gear elements. For example, lubrication ports 48a and 48b. The gear drive assembly and moveable liner plates according to the present invention are discussed in greater detail below.
In operation, mold assembly 30 is selectively coupled to a concrete block machine. For ease of illustrative purposes, however, the concrete block machine is not shown in FIG. 1. In one embodiment, mold assembly 30 is mounted to the concrete block machine by bolting side members 34a and 34b of drive system assembly 31 to the concrete block machine. In one embodiment, mold assembly 30 further includes a head shoe assembly 52 having dimensions substantially equal to those of mold cavity 46. Head shoe assembly 52 is also configured to selectively couple to the concrete block machine.
Liner plates 32a through 32d are first extended a desired distance toward the interior of mold box 42 to form the desired mold cavity 46. A vibrating table on which a pallet 56 is positioned is then raised (as indicated by directional arrow 58) such that pallet 56 contacts and forms a bottom to mold cavity 46. In one embodiment, a core bar assembly (not shown) is positioned within mold cavity 46 to create voids within the finished block in accordance with design requirements of a particular block.
Mold cavity 46 is then filled with concrete from a moveable feedbox drawer. Head shoe assembly 52 is then lowered (as indicated by directional arrow 54) onto mold 46 and hydraulically or mechanically presses the concrete. Head shoe assembly 52 along with the vibrating table then simultaneously vibrate mold assembly 30, resulting in a high compression of the concrete within mold cavity 46. The high level of compression fills any voids within mold cavity 46 and causes the concrete to quickly reach a level of hardness that permits immediate removal of the finished block from mold cavity 46.
The finished block is removed by first retracting liner plates 32a through 32d. Head shoe assembly 52 and the vibrating table, along with pallet 56, are then lowered (in a direction opposite to that indicated by arrow 58), while mold assembly 30 remains stationary so that head shoe assembly 56 pushes the finished block out of mold cavity 46 onto pallet 52. When a lower edge of head shoe assembly 52 drops below a lower edge of mold assembly 30, the conveyer system moves pallet 56 carrying the finished block away and a new pallet takes its place. The above process is repeated to create additional blocks.
By retracting liner plates 32a through 32b prior to removing the finished block from mold cavity 46. liner plates 32a through 32d experience less wear and, thus, have an increased operating life expectancy. Furthermore, moveable liner plates 32a through 32d also enables a concrete block to be molded in a vertical position relative to pallet 56, in lieu of the standard horizontal position, such that head shoe assembly 52 contacts what will be a “face” of the finished concrete block. A “face” is a surface of the block that will be potentially be exposed for viewing after installation in a wall or other structure.
FIG. 2 is a perspective view 70 illustrating a moveable liner plate and corresponding gear drive assembly according to the present invention, such as moveable liner plate 32a and corresponding gear drive assembly 50. For illustrative purposes, side member 34a and cross-member 36 are not shown. Gear drive assembly 50 includes a first gear element 72 selectively coupled to liner plate 32a, a second gear element 74, a single rod-end double-acting pneumatic cylinder (cylinder) 76 coupled to second gear element 74 via a piston rod 78, and a gear track 80. Cylinder 76 includes an aperture 82 for accepting a pneumatic fitting. In one embodiment, cylinder 76 comprises a hydraulic cylinder. In one embodiment, cylinder 76 comprises a double rod-end dual-acting cylinder. In one embodiment, piston rod 78 is threadably coupled to second gear element 74.
In the embodiment of FIG. 2, first gear element 72 and second gear element 74 are illustrated and hereinafter referred to as a gear plate 72 and second gear element 74, respectively. However, while illustrated as a gear plate and a cylindrical gear head, first gear element 72 and second gear element 74 can be of any suitable shape and dimension.
Gear plate 72 includes a plurality of angled channels on a first major surface 84 and is configured to slide in gear track 80. Gear track 80 slidably inserts into a gear slot (not shown) extending into cross member 36a from inner wall 40a. Cylindrical gear head 74 includes a plurality of angled channels on a surface 86 adjacent to first major surface 84 of female gear plate 72, wherein the angled channels are tangential to a radius of cylindrical gear head 74 and configured to slidably mate and interlock with the angled channels of gear plate 72. Liner plate 32a includes guide posts 88a, 88b, 88c, and 88d extending from a rear surface 90. Each of the guide posts is configured to slidably insert into a corresponding guide hole (not shown) extending into cross member 36a from inner wall 40a. The gear slot and guide holes are discussed in greater detail below.
When cylinder 76 extends piston rod 78, cylindrical gear head 74 moves in a direction indicated by arrow 92 and, due to the interlocking angled channels, causes gear plate 72 and, thus, liner plate 32a to move toward the interior of mold 46 as indicated by arrow 94. It should be noted that, as illustrated, FIG. 2 depicts piston rod 78 and cylindrical gear head 74 in an extended position. When cylinder 76 retracts piston rod 78, cylindrical gear head 74 moves in a direction indicated by arrow 96 causing gear plate 72 and liner plate 32 to move away from the interior of the mold as indicated by arrow 98. As liner plate 32a moves, either toward or away from the center of the mold, gear plate 72 slides in guide track 80 and guide posts 88a through 88d slide within their corresponding guide holes.
In one embodiment, a removable liner face 100 is selectively coupled to front surface 44a via fasteners 102a, 102b, 102c, and 102d extending through liner plate 32a. Removable liner face 100 is configured to provide a desired shape and/or provide a desired imprinted pattern, including text, on a block made in mold 46. In this regard, removable liner face 100 comprises a negative of the desired shape or pattern. In one embodiment, removable liner face 100 comprises a polyurethane material. In one embodiment, removable liner face 100 comprises a rubber material. In one embodiment, removable liner plate comprises a metal or metal alloy, such as steel or aluminum. In one embodiment, liner plate 32 further includes a heater mounted in a recess 104 on rear surface 90, wherein the heater aids in curing concrete within mold 46 to reduce the occurrence of concrete sticking to front surface 44a and removable liner face 100.
FIG. 3A is a top view 120 of gear drive assembly 50 and liner plate 32a, as indicated by directional arrow 106 in FIG. 2. In the illustration, side members 34a and 34b, and cross member 36a are indicated dashed lines. Guide posts 88c and 88d are slidably inserted into guide holes 122c and 122d, respectively, which extend into cross member 36a from interior surface 40a. Guide holes 122a and 122b, corresponding respectively to guide posts 88a and 88b, are not shown but are located below and in-line with guide holes 122c and 122d. In one embodiment, guide hole bushings 124c and 124d are inserted into guide holes 122c and 122d, respectively, and slidably receive guide posts 88c and 88d. Guide hole bushings 124a and 124b are not shown, but are located below and in-line with guide hole bushings 124c and 124d. Gear track 80 is shown as being slidably inserted in a gear slot 126 extending through cross member 36a with gear plate 72 sliding in gear track 80. Gear plate 72 is indicated as being coupled to liner plate 32a by a plurality of fasteners 128 extending through liner plate 32a from front surface 44a.
A cylindrical gear shaft is indicated by dashed lines 134 as extending through side member 34a and into cross member 36a and intersecting, at least partially with gear slot 126. Cylindrical gear head 74, cylinder 76, and piston rod 78 are slidably inserted into gear shaft 134 with cylindrical gear head 74 being positioned over gear plate 72. The angled channels of cylindrical gear head 74 are shown as dashed lines 130 and are interlocking with the angled channels of gear plate 72 as indicated at 132.
FIG. 3B is a side view 140 of gear drive assembly 50 and liner plate 32a, as indicated by directional arrow 108 in FIG. 2. Liner plate 32a is indicated as being extended, at least partially, from cross member 36a. Correspondingly, guide posts 88a and 88d are indicated as partially extending from guide hole bushings 124a and 124d, respectively. In one embodiment, a pair of limit rings 142a and 142d are selectively coupled to guide posts 88a and 88, respectively, to limit an extension distance that liner plate 32a can be extended from cross member 36a toward the interior of mold cavity 46. Limit rings 142b and 142c corresponding respectively to guide posts 88b and 88c are not shown, but are located behind and in-line with limit rings 142a and 142d. In the illustrated embodiment, the limit rings are indicated as being substantially at an end of the guide posts, thus allowing a substantially maximum extension distance from cross member 36a. However, the limit rings can be placed at other locations along the guide posts to thereby adjust the allowable extension distance.
FIG. 4A and FIG. 4B are top views 150 and 160, respectively, of mold assembly 30. FIG. 4A illustrates liner plates 32a, 32b, 32c, and 32d in a retracted positions. Liner faces 152, 154, and 154 correspond respectively to liner plates 32b, 32c, and 32d. FIG. 4B illustrates liner plates 32a, 32b, 32c, and 32d, along with their corresponding liner faces 100, 152, 154, and 156 in an extended position.
FIG. 5A is a top view 170 of gear plate 72. Gear plate 72 includes a plurality of angled channels 172 running across a top surface 174 of gear plate 72. Angled channels 172 form a corresponding plurality of linear “teeth” 176 having as a surface the top surface 174. Each angled channel 172 and each tooth 176 has a respective width 178 and 180. The angled channels run at an angle (Θ) 182 from 0°, indicated at 186, across gear plate 72.
FIG. 5B is an end view (“A”) 185 of gear plate 72, as indicated by directional arrow 184 in FIG. 5A, further illustrating the plurality of angled channels 172 and linear teeth 176. Each angled channel 172 has a depth 192.
FIG. 5C illustrates a view 200 of a flat surface 202 of cylindrical gear head 76. Cylindrical gear head 76 includes a plurality of angled channels 204 running across surface 202. Angled channels 204 form a corresponding plurality of linear teeth 206. The angled channels 204 and linear teeth 206 have widths 180 and 178, respectively, such that the width of linear teeth 206 substantially matches the width of angled channels 172 and the width of angled channels 204 substantially match the width of linear teeth 176. Angled channels 204 and teeth 206 run at angle (Θ) 182 from 0°, indicated at 186, across surface 202.
FIG. 5D is an end view 210 of cylindrical gear head 76, as indicated by directional arrow 208 in FIG. 5C, further illustrating the plurality of angled channels 204 and linear teeth 206. Surface 202 is a flat surface tangential to a radius of cylindrical gear head 76. Each angled channel has a depth 192 from flat surface 202.
When cylindrical gear head 76 is “turned over” and placed across surface 174 of gear plate 72, linear teeth 206 of gear head 76 mate and interlock with angled channels 172 of gear plate 72, and linear teeth 176 of gear plate 72 mate and interlock with angled channels 204 of gear head 76 (See also FIG. 2). When gear head 76 is forced in direction 92, linear teeth 206 of gear head 76 push against linear teeth 176 of gear plate 72 and force gear plate 72 to move in direction 94. Conversely, when gear head 76 is forced in direction 96, linear teeth 206 of gear head 76 push against linear teeth 176 of gear plate 72 and force gear plate 72 to move in direction 98.
In order for cylindrical gear head 76 to force gear plate 72 in directions 94 and 98, angle (Θ) 182 must be greater than 0° and less than 90°. However, it is preferable that Θ 182 be at least greater than 45°. When Θ 182 is 45° or less, it takes more force for cylindrical gear head 74 moving in direction 92 to push gear plate 72 in direction 94 than it does for gear plate 72 being forced in direction 98 to push cylindrical gear head 74 in direction 96, such as when concrete in mold 46 is being compressed. The more Θ 182 is increased above 45°, the greater the force that is required in direction 98 on gear plate 72 to move cylindrical gear head 74 in direction 96. In fact, at 90° gear plate 72 would be unable to move cylindrical gear head 74 in either direction 92 or 96, regardless of how much force was applied to gear plate 72 in direction 98. In effect, angle (Θ) acts as a multiplier to a force provided to cylindrical gear head 74 by cylinder 76 via piston rod 78. When Θ 182 is greater than 45°, an amount of force required to be applied to gear plate 72 in direction 98 in order to move cylindrical gear head 74 in direction 96 is greater than an amount of force required to be applied to cylindrical gear head 74 in direction 92 via piston rod 78 in order to “hold” gear plate 72 in position (i.e., when concrete is being compressed in mold 46).
However, the more Θ 182 is increased above 45°, the less distance gear plate 72, and thus corresponding liner plate 32a, will move in direction 94 when cylindrical gear head 74 is forced in direction 92. A preferred operational angle for Θ 182 is approximately 70°. This angle represents roughly a balance, or compromise, between the length of travel of gear plate 72 and an increase in the level of force required to be applied in direction 98 on gear plate 72 to force gear head 74 in direction 96. Gear plate 72 and cylindrical gear head 74 and their corresponding angled channels 176 and 206 reduce the required psi rating of cylinder 76 necessary to maintain the position of liner plate 32a when concrete is being compressed in mold cavity 46 and also reduces the wear experienced by cylinder 76. Additionally, from the above discussion, it is evident that one method for controlling the travel distance of liner plate 32a is to control the angle (Θ) 182 of the angled channels 176 and 206 respectively of gear plate 72 and cylindrical gear head 74.
FIG. 6A is a top view 220 of gear track 80. Gear track 80 has a top surface 220, a first end surface 224, and a second end surface 226. A rectangular gear channel, indicated by dashed lines 228, having a first opening 230 and a second opening 232 extends through gear track 80. An arcuate channel 234, having a radius required to accommodate cylindrical gear head 76 extends across top surface 220 and forms a gear window 236 extending through top surface 222 into gear channel 228. Gear track 80 has a width 238 incrementally less than a width of gear opening 126 in side member 36a (see also FIG. 3A).
FIG. 6B is an end view 250 of gear track 80, as indicated by direction arrow 240 in FIG. 6A, further illustrating gear channel 228 and arcuate channel 234. Gear track 80 has a depth 252 incrementally less than height of gear opening 126 in side member 36a (see FIG. 3A). FIG. 6B is a side view 260 of gear track 80 as indicated by directional arrow 242 in FIG. 6A.
FIG. 7 is a top view 270 illustrating the relationship between gear track 80 and gear plate 72. Gear plate 72 has a width 272 incrementally less than a width 274 of gear track 80, such that gear plate 72 can be slidably inserted into gear channel 228 via first opening 230. When gear plate 72 is inserted within gear track 80, angled channels 172 and linear teeth 176 are exposed via gear window 236.
FIG. 8A is a top view 280 illustrating the relationship between gear plate 72, cylindrical gear head 74, and gear track 80. Gear plate 72 is indicated as being slidably inserted within guide track 80. Cylindrical gear head 74 is indicated as being positioned within arcuate channel 234, with the angled channels and linear teeth of cylindrical gear head 74 being slidably mated and interlocked with the angled channels 172 and linear teeth 176 of gear plate 72. When cylindrical gear head 74 is moved in direction 92 by extending piston rod 78, gear plate 72 extends outward from gear track 80 in direction 94 (See also FIG. 9B below). When cylindrical gear head 74 is moved in direction 96 by retracting piston rod 78, gear plate 72 retracts into gear track 80 in direction 98 (See also FIG. 9A below).
FIG. 8B is a side view 290 of gear plate 72, cylindrical gear head 74, and guide track 80 as indicated by directional arrow 282 in FIG. 8A. Cylindrical gear head 74 is positioned such that surface 202 is located within arcuate channel 234. Angled channels 204 and teeth 206 of cylindrical gear head 74 extend through gear window 236 and interlock with angled channels 172 and linear teeth 176 of gear plate 72 located within gear channel 228. FIG. 8C is an end view 300 as indicated by directional arrow 284 in FIG. 8A, and further illustrates the relationship between gear plate 72, cylindrical gear head 74, and guide track 80.
FIG. 9A is top view 310 illustrating gear plate 72 being in a fully retracted position within gear track 80, with liner plate 32a being retracted against cross member 36a. For purposes of clarity, cylindrical gear head 74 is not shown. Angled channels 172 and linear teeth 176 are visible through gear window 236. Liner plate 32a is indicated as being coupled to gear plate 72 with a plurality of fasteners 128 extending through liner plate 32a into gear plate 72. In one embodiment, fasteners 128 threadably couple liner plate 32a to gear plate 72.
FIG. 9B is a top view 320 illustrating gear plate 72 being extended, at least partially from gear track 80, with liner plate 32a being separated from cross member 36a. Again, cylindrical gear head 74 is not shown and angled channels 172 and linear teeth 176 are visible through gear window 236.
FIG. 10A is a diagram 330 illustrating one exemplary embodiment of a gear drive assembly 332 according to the present invention. Gear drive assembly 332 includes cylindrical gear head 74, cylinder 76, piston rod 78, and a cylindrical sleeve 334. Cylindrical gear head 74 and piston rod 78 are configured to slidably insert into cylindrical sleeve 334. Cylinder 76 is threadably coupled to cylindrical sleeve 334 with an O-ring 336 making a seal. A window 338 along an axis of cylindrical sleeve 334 partially exposes angled channels 204 and linear teeth 206. A fitting 342, such as a pneumatic or hydraulic fitting, is indicated as being threadably coupled to aperture 82. Cylinder 76 further includes an aperture 344, which is accessible through cross member 36a.
Gear drive assembly 332 is configured to slidably insert into cylindrical gear shaft 134 (indicated by dashed lines) so that window 338 intersects with gear slot 126 so that angled channels 204 and linear teeth 206 are exposed within gear slot 126. Gear track 80 and gear plate 72 (not shown) are first slidably inserted into gear slot 126, such that when gear drive assembly 332 is slidably inserted into cylindrical gear shaft 134 the angled channels 204 and linear teeth 206 of cylindrical gear head 74 slidably mate and interlock with the angled channels 172 and linear teeth 176 of gear plate 72.
In one embodiment, a key 340 is coupled to cylindrical gear head 74 and rides in a key slot 342 in cylindrical sleeve 334. Key 340 prevents cylindrical gear head 74 from rotating within cylindrical sleeve 334. Key 340 and key slot 342 together also control the maximum extension and retraction of cylindrical gear head 74 within cylindrical sleeve 334. Thus, in one embodiment, key 340 can be adjusted to control the extension distance of liner plate 32a toward the interior of mold cavity 46. FIG. 10A is a top view 350 of cylindrical shaft 334 as illustrated in FIG. 10B, and further illustrates key 340 and key slot 342.
FIG. 11A is a top view illustrating one exemplary embodiment of a mold assembly 360 according to the present invention for forming two concrete blocks. Mold assembly 360 includes a mold frame 361 having side members 34a and 34b and cross members 36a through 36c coupled to one another so as to form a pair of mold boxes 42a and 42b. Mold box 42a includes moveable liner plates 32a through 32d and corresponding removable liner faces 33a through 33d configured to form a mold cavity 46a. Mold box 42b includes moveable liner plates 32e through 32h and corresponding removable liner faces 33e through 33h configured to form a mold cavity 46b.
Each moveable liner plate has an associated gear drive assembly located internally to an adjacent mold frame member as indicated by 50a through 50h. Each moveable liner plate is illustrated in an extended position with a corresponding gear plate indicated by 72a through 72h. As described below, moveable liner plates 32c and 32e share gear drive assembly 50c/e, with gear plate 72e having its corresponding plurality of angled channels facing upward and gear plate 72c having its corresponding plurality of angled channels facing downward.
FIG. 11B is diagram illustrating a gear drive assembly according to the present invention, such as gear drive assembly 50c/e. FIG. 11B illustrates a view of gear drive assembly 50c/e as viewed from section A-A through cross-member 36c of FIG. 11A. Gear drive assembly 50c/e includes a single cylindrical gear head 76c/e having angled channels 204c and 204e on opposing surfaces. Cylindrical gear head 76c/e fits into arcuate channels 234c and 234e of gear tracks 80c and 80d, such that angled channels 204c and 204e slidably interlock with angled channels 172c and 172e of gear plates 72c and 72e respectively.
Angled channels 172c and 204c, and 172e and 204e oppose one another and are configured such that when cylindrical gear head 76c/e is extended (e.g. out from FIG. 11B) gear plate 72c moves in a direction 372 toward the interior of mold cavity 46a and gear plate 72e moves in a direction 374 toward the interior of mold cavity 46b. Similarly, when cylindrical gear head 76c/e is retracted (e.g. into FIG. 11B) gear plate 72c moves in a direction 376 away from the interior of mold cavity 46a and gear plate 72e moves in a direction 378 away from the interior of mold cavity 378. Again, cylindrical gear head 76c/e and gear plates 72c and 72c could be of any suitable shape.
FIG. 12 is a perspective view illustrating a portion of one exemplary embodiment of a mold assembly 430 according to the present invention. Mold assembly includes moveable liner plates 432a through 4321 for simultaneously molding multiple concrete blocks. Mold assembly 430 includes a drive system assembly 431 having a side members 434a and 434b, and cross members 436a and 436b. For illustrative purposes, side member 434a is indicated by dashed lines. Mold assembly 430 further includes division plates 437a through 437g.
Together, moveable liner plates 432a through 4321 and division plates 437a through 437g form mold cavities 446a through 446f, with each mold cavity configured to form a concrete block. Thus, in the illustrated embodiment, mold assembly 430 is configured to simultaneously form six blocks. However, it should be apparent from the illustration that mold assembly 430 can be easily modified for simultaneously forming quantities of concrete blocks other than six.
In the illustrated embodiment, side members 434a and 434b each have a corresponding gear drive assembly for moving moveable liner plates 432a through 432f and 432g through 4321, respectively. For illustrative purposes, only gear drive assembly 450 associated with side member 434a and corresponding moveable liner plates 432a through 432g is shown. Gear drive assembly 450 includes first gear elements 472a through 472f selectively coupled to corresponding moveable liner plates 432a through 432f, respectively, and a second gear element 474. In the illustrated embodiment, first gear elements 472a through 472f and second gear element 474 are shown as being cylindrical in shape. However, any suitable shape can be employed.
Second gear element 474 is selectively coupled to a cylinder-piston (not shown) via a piston rod 478. In one embodiment, which is described in greater detail below (see FIG. 12), second gear element 474 is integral with the cylinder-piston so as to form a single component.
In the illustrated embodiment, each first gear element 472a through 472b further includes a plurality of substantially parallel angled channels 484 that slidably mesh and interlock with a plurality of substantially parallel angled channels 486 on second gear element 474. When second gear element 474 is moved in a direction indicated by arrow 492, each of the moveable liner plates 432a through 432f moves in a direction indicated by arrow 494. Similarly, when second gear element 474 is move in a direction indicated by arrow 496, each of the moveable liner plates 432a through 432f moves in a direction indicated by arrow 498.
In the illustrated embodiment, the angled channels 484 on each of the first gear elements 432a through 432f and the angled channels 486 are at a same angle. Thus, when second gear element 474 moves in direction 492 and 496, each moveable liner plate 432a through 432f moves a same distance in direction 494 and 498, respectively. In one embodiment, second gear element 474 includes a plurality of groups of substantially parallel angled channels with each group corresponding to a different one of the first gear elements 472a through 472f. In one embodiment, the angled channels of each group and its corresponding first gear element have a different angle such that each moveable liner plate 432a through 432f move a different distance in directions 494 and 498 in response to second gear element 474 being moved in direction 492 and 496, respectively.
FIG. 13 is a perspective view illustrating a gear drive assembly 500 according to the present invention, and a corresponding moveable liner plate 502 and removable liner face 504. For illustrative purposes, a frame assembly including side members and cross members is not shown. Gear drive assembly 500 includes double rod-end, dual-acting pneumatic cylinder-piston 506 having a cylinder body 507, and a hollow piston rod 508 with a first rod-end 510 and a second rod-end 512. Gear drive assembly 500 further includes a pair of first gear elements 514a and 514b selectively coupled to moveable liner plate 502, with each first gear element 514a and 514b having a plurality of substantially parallel angled channels 516a and 516b.
In the illustrated embodiment, cylinder body 507 of cylinder-piston 506 includes a plurality of substantially parallel angled channels 518 configured to mesh and slidably interlock with angled channels 516a and 516b. In one embodiment, cylinder body 507 is configured to slidably insert into and couple to a cylinder sleeve having angled channels 518.
In one embodiment, cylinder-piston 506 and piston rod 508 are located within a drive shaft of a frame member, such as drive shaft 134 of cross-member 36a, with rod-end 510 coupled to and extending through a frame member, such as side member 34b, and second rod-end 512 coupled to and extending through a frame member, such a side member 34a. First rod-end 510 and second rod-end 512 are configured to receive and provide compressed air to drive dual-acting cylinder-piston 506. With piston rod 508 being fixed to side members 34a and 34b via first and second rod-ends 512 and 510, cylinder-piston 506 travels along the axis of piston rod 508 in the directions as indicated by arrows 520 and 522 in response to compressed air received via first and second rod-ends 510 and 512.
When compressed air is received via second rod-end 512 and expelled via first rod-end 510, cylinder-piston 506 moves within a drive shaft, such as drive shaft 134, in direction 522 and causes first gear elements 514a and 516b and corresponding liner plate 502 and liner face 504 to move in a direction indicated by arrow 524. Conversely, when compressed air is received via first rod-end 510 and expelled via second rod-end 512, cylinder-piston 506 moves within a gear shaft, such as gear shaft 134, in direction 520 and causes first gear elements 514a and 516b and corresponding liner plate 502 and liner face 504 to move in a direction indicated by arrow 526.
In the illustrated embodiment, cylinder-piston 506 and first gear elements 514a and 514b are shown as being substantially cylindrical in shape. However, any suitable shape can be employed. Furthermore, in the illustrated embodiment, cylinder-piston 506 is a double rod-end dual-acting cylinder. In one embodiment, cylinder piston 506 is a single rod-end dual acting cylinder having only a single rod-end 510 coupled to a frame member, such as side member 34b. In such an embodiment, compressed air is provided to cylinder-piston via single rod-end 510 and a flexible pneumatic connection made to cylinder-piston 506 through side member 34a via gear shaft 134. Additionally, cylinder-piston 506 comprises a hydraulic cylinder.
FIG. 14 is a top view of a portion of mold assembly 430 (as illustrated by FIG. 12) having a drive assembly 550 according to one embodiment of the present invention. Drive assembly 550 includes first drive elements 572a to 572f that are selectively coupled to corresponding liner plates 432a to 432f via openings, such as opening 433, in side member 434a. Each of the first drive elements 572a to 572 if further coupled to a master bar 573. Drive assembly 550 further includes a double-rod-end hydraulic piston assembly 606 having a dual-acting cylinder 607 and a hollow piston rod 608 having a first rod-end 610 and a second rod-end 612. First and second rod-ends 610, 612 are stationary and are coupled to and extend through a removable housing 560 that is coupled to side member 434a and encloses drive assembly 550. First and second rod ends 610, 612 are each coupled to hydraulic fittings 620 that are configured to connect via lines 622a and 622b to an external hydraulic system 624 and to transfer hydraulic fluid to and from dual-acting cylinder 607 via hollow piston rod 608.
In one embodiment, as illustrated, first drive elements 572b and 572e include a plurality of substantially parallel angled channels 616 that slideably interlock with a plurality of substantially parallel angled channels 618 that form a second drive element. In one embodiment, as illustrated above by FIG. 12, angled channels 618 are formed on dual-acting cylinder 607 of hydraulic piston assembly 606, such that dual-acting cylinder 607 forms the second drive element. In other embodiments, as will be described by FIGS. 15A-15C below, the second drive element is separate from and operatively coupled to dual-acting cylinder 607.
When hydraulic fluid is transmitted into dual-acting cylinder 607 from second rod-end 612 via fitting 620 and hollow piston rod 608, hydraulic fluid is expelled from first rod-end 610, causing dual-acting cylinder 607 and angled channels 618 to move along piston rod 608 toward second rod-end 612. As dual-acting cylinder 607 moves toward second rod-end 612, angled channels 618 interact with angled channels 616 and drive first drive elements 572b and 572e, and thus corresponding liner plates 432b and 432e, toward the interior of mold cavities 446b and 446e, respectively. Furthermore, since each of the first drive elements 572a through 572f is coupled to master bar 573, driving first gear elements 572b and 572e toward the interiors of mold cavities 446b and 446e also moves first drive elements 572a, 572c, 572d, and 572f and corresponding liner plates 432a, 432c, 432d, and 432e toward the interiors of mold cavities 446a, 446c, 446d, and 446f, respectively. Conversely, transmitting hydraulic fluid into dual-acting cylinder 607 from first rod-end 610 via fitting 620 and hollow-piston rod 608 causes dual-acting cylinder 607 to move toward first rod-end 610, and causes liner plates 432 to move away from the interiors of corresponding mold cavities 446.
In one embodiment, drive assembly 550 further includes support shafts 626, such as support shafts 626a and 626b, which are coupled between removable housing 560 and side member 434a and extend through master bar 573. As dual-acting cylinder 607 is moved by transmitting/expelling hydraulic fluid from first and second rod-ends 610, 612, master bar 573 moves back and forth along support shafts 626. Because they are coupled to static elements of mold assembly 430, support shafts 626a and 626b provide support and rigidity to liner plates 432, drive elements 572, and master bar 573 as they move toward and away from mold cavities 446.
In one embodiment, drive assembly 550 further includes a pneumatic fitting 628 configured to connect via line 630 to and external compressed air system 632 and provide compressed air to housing 560. By receiving compressed air via pneumatic fitting 628 to removable housing 560, the internal air pressure of housing 560 is positive relative to the outside air pressure, such that air is continuously “forced” out of housing 560 through any non-sealed openings, such as openings 433 through which first drive elements 572 extend through side member 434a. By maintaining a positive air pressure and forcing air out through such non-sealed opening, the occurrence of dust and debris and other unwanted contaminants from entering housing 560 and fouling drive assembly 550 is reduced.
First and second rod ends 610, 612 are each coupled to hydraulic fittings 620 that are configured to connect via lines 622a and 622b to an external hydraulic system 624 and to transfer hydraulic fluid to and from dual-acting cylinder 607 via hollow piston rod 608.
FIG. 15A is a top view illustrating a portion of one embodiment of drive assembly 550 according to the present invention. Drive assembly 550 includes double-rod-end hydraulic piston assembly 606 comprising dual-acting cylinder 607 and a hollow piston rod 608 with first and second rod-ends 610 and 612 being and coupled to and extending through removable housing 560.
As illustrated, dual-acting cylinder 607 is slideably-fitted inside a machined opening 641 within a second gear element 640, with hollow piston rod 608 extending through removable end caps 642. In one embodiment, end caps 646 are threadably inserted into machined opening 641 such that end caps 646 butt against and secure dual-acting cylinder 607 so that dual-acting cylinder 607 is held stationary with respect to second drive element 640. Second drive element 640 includes the plurality of substantially parallel angled channels 618, in lieu of angled channels being an integral part of dual-acting cylinder 607. With reference to FIG. 14, angled channels 618 of second gear element 640 are configured to slideably interlock with angled channels 616 of first gear elements 572b and 572e.
Second gear element 640 further includes a guide rail 644 that is slideably coupled to linear bearing blocks 646 that are mounted to housing 560. As described above with respect to FIG. 14, transmitting and expelling hydraulic fluid to and from dual-acting cylinder 607 via first and second rod-ends 610, 612 causes dual-acting cylinder 607 to move along hollow piston-rod 608. Since dual-acting cylinder 607 is “locked” in place within machined shaft 641 of second gear element 640 by end caps 642, second gear element 640 moves along hollow piston-rod 608 together with dual-acting cylinder 607. As second drive element 640 moves along hollow piston-rod 608, linear bearing blocks 646 guide and secure guide rail 644, thereby guiding and securing second drive element 640 and reducing undesirable motion in second drive element 640 that is perpendicular to hollow piston rod 608.
FIG. 15B is a lateral cross-sectional view A-A of the portion of drive assembly 550 illustrated by FIG. 15A. Guide rail 644 is slideably fitted into a linear bearing track 650 and rides on bearings 652 as second drive element 640 is moved along piston rod 608 by dual-acting cylinder 607. In one embodiment, linear bearing block 646b is coupled to housing 560 via bolts 648.
FIG. 15C is a longitudinal cross-sectional view B-B of the portion of drive assembly 550 of FIG. 15A, and illustrates dual-acting cylinder 607 as being secured within shaft 641 of drive element 640 by end caps 642a and 642b. In one embodiment, end caps 642a and 642b are threadably inserted into the ends of second drive element 640 so as to butt against each end of dual-acting cylinder 607. Hollow piston rod 608 extends through end caps 642a and 642b and has first and second rod ends 610 and 612 coupled to and extending through housing 560. A divider 654 is coupled to piston rod 608 and divides dual-acting cylinder 607 into a first chamber 656 and a second chamber 658. A first port 660 and a second port 662 allow hydraulic fluid to be pumped into and expelled from first chamber 656 and second chamber 658 via first and second rod ends 610 and 612 and associated hydraulic fittings 620, respectively.
When hydraulic fluid is pumped into first chamber 656 via first rod-end 610 and first port 660, dual-acting cylinder 607 moves along hollow piston rod 608 toward first rod-end 610 and hydraulic fluid is expelled from second chamber 658 via second port 662 and second rod-end 612. Since dual-acting cylinder 607 is secured within shaft 641 by end caps 642a and 642b, second drive element 640 and, thus, angled channels 618 move toward first rod-end 610. Similarly, when hydraulic fluid is pumped into second chamber 658 via second rod-end 612 and second port 662, dual-acting cylinder 607 moves along hollow piston rod 608 toward second rod-end 612 and hydraulic fluid is expelled from first chamber 656 via first port 660 and first rod-end 610.
FIG. 16 is a side view of a portion of drive assembly 550 as shown by FIG. 14 and illustrates a typical liner plate, such as liner plate 432a, and corresponding removable liner face 400. Liner plate 432a is coupled to second drive element 572a via a bolted connection 670 and, in-turn, drive element 572a is coupled to master bar 573 via a bolted connection 672. A lower portion of liner face 400 is coupled to liner plate 432a via a bolted connection 674. In one embodiment, as illustrated, liner plate 432a includes a raised “rib” 676 that runs the length of and along an upper edge of liner plate 432a. A channel 678 in liner face 400 overlaps and interlocks with raised rib 676 to form a “boltless” connection between liner plate 432a and an upper portion of liner face 400. Such an interlocking connection securely couples the upper portion of liner face 400 to liner plate 432 in an area of liner face 400 that would otherwise be too narrow to allow use of a bolted connection between liner face 400 and liner plate 432a without the bolt being visible on the surface of liner face 400 that faces mold cavity 446a.
In one embodiment, liner plate 432 includes a heater 680 configured to maintain the temperature of corresponding liner face 400 at a desired temperature to prevent concrete in corresponding mold cavity 446 sticking to a surface of liner face 400 during a concrete curing process. In one embodiment, heater 680 comprises an electric heater.
FIG. 17 is a block diagram illustrating one embodiment of a mold assembly according to the present invention, such as mold assembly 430 of FIG. 14, further including a controller 700 configured to coordinate the movement of moveable liner plates, such as liner plates 432, with operations of concrete block machine 702 by controlling the operation of the drive assembly, such as drive assembly 550. In one embodiment, as illustrated, controller 700 comprises a programmable logic controller (PLC).
As described above with respect to FIG. 1, mold assembly 430 is selectively coupled, generally via a plurality of bolted connections, to concrete block machine 702. In operation, concrete block machine 702 first places pallet 56 below mold box assembly 430. A concrete feedbox 704 then fills mold cavities, such as mold cavities 446, of assembly 430 with concrete. Head shoe assembly 52 is then lowered onto mold assembly 430 and hydraulically or mechanically compresses the concrete in mold cavities 446 and, together with a vibrating table on which pallet 56 is positioned, simultaneously vibrates mold assembly 430. After the compression and vibration is complete, head shoe assembly 52 and pallet 56 are lowered relative to mold cavities 446 so that the formed concrete blocks are expelled from mold cavities 446 onto pallet 56. Head shoe assembly 52 is then raised and a new pallet 56 is moved into position below mold cavities 446. The above process is continuously repeated, with each such repetition commonly referred to as a cycle. With specific reference to mold assembly 430, each such cycle produces six concrete blocks.
PLC 700 is configured to coordinate the extension and retraction of liner plates 432 into and out of mold cavities 446 with the operations of concrete block machine 702 as described above. At the start of a cycle, liner plates 432 are fully retracted from mold cavities 446. In one embodiment, with reference to FIG. 14, drive assembly 550 includes a pair of sensors, such as proximity switches 706a and 706b to monitor the position of master bar 573 and, thus, the positions of corresponding moveable liner plates 432 coupled to master bar 573. As illustrated in FIG. 14, proximity switches 706a and 706b are respectively configured to detect when liner plates 432 are in an extended position and a retracted position with respect to mold cavities 446.
In one embodiment, after pallet 56 has been positioned beneath mold assembly 430, PLC 700 receives a signal 708 from concrete block machine 702 indicating that concrete feedbox 704 is ready to deliver concrete to mold cavities 446. PLC 700 checks the position of moveable liners 432 based on signals 710a and 710b received respectively from proximity switches 706a and 706b. With liner plates 432 in a retracted position, PLC 700 provides a liner extension signal 712 to hydraulic system 624.
In response to liner extension signal 712, hydraulic system 624 begins pumping hydraulic fluid via path 622b to second rod-end 612 of piston assembly 606 and begins receiving hydraulic fluid from first rod-end 610 via path 622a, thereby causing dual-acting cylinder 607 to begin moving liner plates 432 toward the interiors of mold cavities 446. When proximity switch 706a detects master bar 573, proximity switch 706a provides signal 710a to PLC 700 indicating that liner plates 432 have reached the desired extended position. In response to signal 710a, PLC 700 instructs hydraulic system 624 via signal 712 to stop pumping hydraulic fluid to piston assembly 606 and provides a signal 714 to concrete block machine 702 indicating that liner plates 432 are extended.
In response to signal 714, concrete feedbox 704 fills mold cavities 446 with concrete and head shoe assembly 52 is lowered onto mold assembly 430. After the compression and vibrating of the concrete is complete, concrete block machine 702 provides a signal 716 indicating that the formed concrete blocks are ready to be expelled from mold cavities 446. In response to signal 716, PLC 700 provides a liner retraction signal 718 to hydraulic system 624.
In response to liner retraction signal 718, hydraulic system 624 begins pumping hydraulic fluid via path 622a to first rod-end 610 via path 622 and begins receiving hydraulic fluid via path 622b from second rod-end 612, thereby causing dual-acting cylinder 607 to begin moving liner plates 432 away from the interiors of mold cavities 446. When proximity switch 706b detects master bar 573, proximity switch 706b provides signal 710b to PLC 700 indicating that liner plates 432 have reached a desired retracted position. In response to signal 710b, PLC 700 instructs hydraulic system 624 via signal 718 to stop pumping hydraulic fluid to piston assembly 606 and provides a signal 720 to concrete block machine 702 indicating that liner plates 432 are retracted.
In response to signal 720, head shoe assembly 52 and pallet 56 eject the formed concrete blocks from mold cavities 446. Concrete block machine 702 then retracts head shoe assembly 52 and positions a new pallet 56 below mold assembly 430. The above process is then repeated for the next cycle.
In one embodiment, PLC 700 is further configured to control the supply of compressed air to mold assembly 430. In one embodiment, PLC 700 provides a status signal 722 to compressed air system 630 indicative of when concrete block machine 702 and mold assembly 430 are in operation and forming concrete blocks. When in operation, compressed air system 632 provides compressed air via line 630 and pneumatic fitting 628 to housing 560 of mold assembly 420 to reduce the potential for dirt/dust and other debris from entering drive assembly 550. When not in operation, compressed air system 632 does not provide compressed air to mold assembly 430.
Although the above description of controller 700 is in regard to controlling a drive assembly employing only a single piston assembly, such as piston assembly 606 of drive assembly 500, controller 700 can be adapted to control drive assemblies employing multiple piston assemblies and employing multiple pairs of proximity switches, such as proximity switches 706a and 706b. In such instances, hydraulic system 624 would be coupled to each piston assembly via a pair of hydraulic lines, such as lines 622a and 622b. Additionally, PLC 700 would receive multiple position signals and would respectively allow mold cavities to be filled with concrete and formed blocks to be ejected only when each applicable proximity switch indicates that all moveable liner plates are at their extended position and each applicable proximity switch indicates that all moveable liner plates are at their retracted position.
FIGS. 18A through 18C illustrate portions of an alternate embodiment of drive assembly 550 as illustrated by FIGS. 15A through 15C. FIG. 18A is top view of second gear element 640, wherein second gear element 640 is driven by a screw drive system 806 in lieu of a piston assembly, such as piston assembly 606. Screw drive system 806 includes a threaded screw 808, such as an Acme or Ball style screw, and an electric motor 810. Threaded screw 808 is threaded through a corresponding threaded shaft 812 extending lengthwise through second gear element 640. Threaded screw 808 is coupled at a first end to a first bearing assembly 814a and is coupled at a second end to motor 810 via a second bearing assembly 814b. Motor 810 is selectively coupled via motor mounts 824 to housing 560 and/or to the side/cross members, such as cross member 434a, of the mold assembly.
In a fashion similar to that described by FIG. 15A, second gear element 640 includes the plurality of angled channels 618 which slideably interlock and mesh with angled channels 616 of first gear elements 572b and 572e, as illustrated by FIG. 14. Since second gear element 640 is coupled to linear bearing blocks 646, when motor 810 is driven to rotate threaded screw 808 in a counter-clockwise direction 816, second gear element 640 is driven in a direction 818 along linear bearing track 650. As second gear element 640 moves in direction 818, angled channels 618 interact with angled channels 616 and extend liner plates, such as liner plates 432a through 432f illustrated by FIGS. 12 and 14, toward the interior of mold cavities 446a through 446f.
When motor 810 is driven to rotate threaded screw 808 in a clockwise direction 820, second gear element 640 is driven in a direction 822 along linear bearing track 650. As second gear element 640 moves in direction 822, angled channels 618 interact with angled channels 616 and retract liner plates, such as liner plates 432a through 432f illustrated by FIGS. 12 and 14, away from the interior of mold cavities 446a through 446f. In one embodiment, the distance the liner plates are extended and retracted toward and away from the interior of the mold cavities is controlled based on the pair of proximity switches 706a and 706b, as illustrated by FIG. 14. In an alternate embodiment, travel distance of the liner plates is controlled based on the number of revolutions of threaded screw 808 is driven by motor 810.
FIGS. 18B and 18C respectively illustrate lateral and longitudinal cross-sectional views A-A and B-B of drive assembly 550 as illustrated by FIG. 18A. Although illustrated as being located external to housing 560, in alternate embodiments, motor 810 is mounted within housing 560.
As described above, concrete blocks, also referred to broadly as concrete masonry units (CMUs), encompass a wide variety of types of blocks such as, for example, patio blocks, pavers, light weight blocks, gray blocks, architectural units, and retaining wall blocks. The terms concrete block, masonry block, and concrete masonry unit are employed interchangeably herein, and are intended to include all types of concrete masonry units suitable to be formed by the assemblies, systems, and methods of the present invention. Furthermore, although described herein primarily as comprising and employing concrete, dry-cast concrete, or other concrete mixtures, the systems, methods, and concrete masonry units of the present invention are not limited to such materials, and are intended to encompass the use of any material suitable for the formation of such blocks.
FIG. 19 is flow diagram illustrating one exemplary embodiment of a process 850 for forming a concrete block employing a mold assembly according to the present invention, with reference to mold assembly 30 as illustrated by FIG. 1. Process 850 begins at 852, where mold assembly 30 is bolted, such as via side members 34a and 34b, to a concrete block machine. For ease of illustration, the concrete block machine is not shown in FIG. 1. Examples of concrete block machines for which mold assembly is adapted for use include models manufactured by Columbia and Besser. In one embodiment, installation of mold assembly 30 in the concrete block machine at 852 further includes installation of a core bar assembly (not shown in FIG. 1, but known to those skilled in the art), which is positioned within mold cavity 46 to create voids within the formed block in accordance with design requirements of a particular block. In one embodiment, mold assembly 30 further includes head shoe assembly 52, which is also bolted to the concrete block machine at 852.
At 854, one or more liner plates, such as liner plates 32a through 32d, are extended a desired distance to from a mold cavity 46 having a negative of a desired shape of the concrete block to be formed. As will be described in further detail below, the number of moveable liner plates may vary depending on the particular implementation of mold assembly 30 and the type of concrete block to be formed. At 856, after the one or more liners plates have been extended, the concrete block machine raises a vibrating table on which pallet 56 is located such that pallet 56 contacts mold assembly 30 and forms a bottom to mold cavity 46.
At 858, the concrete block machine moves a feedbox drawer (not illustrated in FIG. 1) into position above the open top of mold cavity 46 and fills mold cavity 46 with a desired concrete mixture. After mold cavity 46 has been filled with concrete, the feedbox drawer is retracted, and concrete block machine, at 860, lowers head shoe assembly 52 onto mold cavity 46. Head shoe assembly 52 configured to match the dimensions and other unique configurations of each mold cavity, such as mold cavity 46.
At 862, the concrete block machine then compresses (e.g. hydraulically or mechanically) the concrete while simultaneously vibrating mold assembly 30 via the vibrating table on which pallet 56 is positioned. The compression and vibration together causes concrete to substantially fill any voids within mold cavity 46 and causes the concrete quickly reach a level of hardness (“pre-cure”) that permits removal of the formed concrete block from mold cavity 46.
At step 864, the one or more moveable liner plates 32 are retracted away from the interior of mold cavity 46. After the liner plates 32 are retracted, the concrete block machine removes the formed concrete block from mold cavity 46 by moving head shoe assembly 52 along with the vibrating table and pallet 56 downward while mold assembly 30 remains stationary. The head shoe assembly, vibrating table, and pallet 56 are lower until a lower edge of head shoe assembly 52 drops below a lower edge of mold cavity 46 and the formed block is ejected from mold cavity 46 onto pallet 56. A conveyor system then moves pallet 56 carrying the formed block away from the concrete block machine to an oven where the formed block is cured. Head shoe assembly 56 is raised to the original start position at 868, and process 850 returns to 854 where the above described process is repeated to create additional concrete blocks.
FIGS. 20A and 20B are simplified illustrations of one exemplary implementation of mold assembly 30 configured to form a concrete masonry unit (CMU), such as that illustrated below by FIGS. 21A and 21F. Mold assembly 30 includes side members 34a, 34b, cross-members 36a, 36, stationary liner plates 32a through 32c, and moveable liner plate 32d. Drive assembly 31d is coupled to moveable liner plate 32 and configured to extend and retract moveable liner plate 32d toward and away from mold cavity 46. A core bar assembly is installed in mold cavity 46, as illustrated by dashed lines 870. A liner face 100d is coupled to moveable liner plate 32d and comprises a negative of a desired three-dimensional texture or pattern which is desired to be imprinted, or formed, on a face of the block. FIG. 20A illustrates liner plate 32d in a retracted position. Upon extending moveable liner plate 32d and associated liner face 100d toward the interior of mold cavity 46, as illustrated by FIG. 20B, mold assembly 30 receives concrete and forms a block as described generally by process 850 of FIG. 19.
FIG. 21A illustrates one example of a CMU 900 as formed by mold assembly 30 as illustrated by FIGS. 20A and 20B. CMU 900 is commonly referred to as a gray block. Gray blocks having one or more textured surfaces, such as that illustrated by CMU 900 of FIG. 21A, are commonly referred to as architectural units. Architectural unit 900 includes a front face 902 having the three-dimensional pattern as imprinted by liner face 100 and a pair of hollow cores 904. A rear face 906 is formed by stationary liner plate 32b, and opposed side faces 908 and 910 are respectively formed by stationary liner plates 32a and 32c. A top face 912 and an opposing bottom face 914 are respectively formed by shoe assembly 52 and pallet 56 (see FIG. 1). Architectural masonry unit 900 has a width (w) 916, a depth (d) 918, and a height (h) 920. Gray block, or architectural masonry unit 930, as illustrated by FIG. 21A, can be formed with a plurality of dimensions including standard dimensions such as, for example, 4″(d)×8″(h)×12″(w), 8″(d)×8″(h)×16″(w), and 12″(d)×8″(h)×16″(w).
FIG. 21B illustrates another example of architectural unit 900, wherein side face 908 is also imprinted with a three-dimensional texture or pattern similar to that of front face 902. To produce architectural unit 900 of FIG. 21B, liner plate 32a of mold assembly 30 comprises a moveable liner plate and associated liner face similar to moveable liner plate 32d, in lieu of a stationary liner plate as illustrated.
FIGS. 21C through 21F are simplified illustrations of further exemplary implementations of mold assembly 30 and the corresponding architectural unit 900 produced by such implementations. FIG. 21C illustrates an implementation of mold assembly 30 wherein liner plates 32a and 32c are stationary and liner plates 32b and 32d are moveable. Liner plates 100b and 100d are coupled respectively to liner plates 32b and 32d and include a negative of a three-dimensional pattern or texture. Accordingly, front face 902 and rear face 906 of architectural unit 900 produced by mold assembly 30 of FIG. 21C are each imprinted with a three-dimensional pattern.
FIG. 21D illustrates an implementation of mold assembly 30 wherein liner plate 32c is stationary and liner plates 32a, 32b, and 32d are moveable. Liner plates 100a, 10b, and 100d are coupled respectively to liner plates 32a, 32b and 32d and include a negative of a three-dimensional pattern or texture. Accordingly, front face 902, rear face 906, and side face 908 of architectural unit 900 produced by mold assembly 30 of FIG. 21D are each imprinted with a three-dimensional pattern.
FIG. 21E illustrates an implementation of mold assembly 30 wherein each of the liner plates 32a, 32b, 32c, and 32d are moveable. Liner plates 100a, 10b, 100c, and 100d are coupled respectively to liner plates 32a, 32b, 32c and 32d and include a negative of a three-dimensional pattern or texture. Accordingly, front face 902, rear face 906, side face 908, and side face 910 of architectural unit 900 produced by mold assembly 30 of FIG. 21E are each imprinted with a three-dimensional pattern.
FIG. 21F illustrates an implementation of mold assembly 30 wherein liner plate 32b is stationary and liner plates 32a, 32c, and 32d are moveable. Liner plates 100a, 100c, and 100d are coupled respectively to liner plates 32a, 32c and 32d and include a negative of a three-dimensional pattern or texture. Accordingly, front face 902, side face 908, and side face 910 of architectural unit 900 produced by mold assembly 30 of FIG. 21F are each imprinted with a three-dimensional pattern.
FIGS. 22A through 22D are simplified illustrations of other exemplary implementations of mold assembly 30 configured to form concrete masonry units, such as those illustrated by FIGS. 23A through 23C. Mold assembly 30 includes side members 34a, 34b, cross-members 36a, 36b, stationary liner plates 32a through 32c, and moveable liner plate 32d. Drive assembly 31d is coupled to moveable liner plate 32 and configured to extend and retract moveable liner plate 32d toward and away from mold cavity 46. In one embodiment, a core bar assembly is installed in mold cavity 46, as illustrated by dashed lines 870. Liner face 100d is coupled to moveable liner plate 32d and includes a negative of a desired three-dimensional texture or pattern which is desired to be imprinted, or formed, on a face of the block. FIG. 20A illustrates liner plate 32d in a retracted position. Upon extending moveable liner plate 32d and associated liner face 100d toward the interior of mold cavity 46, as illustrated by FIG. 20B, mold assembly 30 receives concrete as described generally at 858 of process 850 of FIG. 19.
FIGS. 22C and 22D are simplified end views of mold assembly 30 as illustrated above by FIGS. 22A and 22B, and further illustrate pallet 56. FIG. 22C illustrates head shoe assembly 52 having a notch 872 configured to cooperate with stationary liner plate 32d to form a set-back flange on a lower face of a block after head shoe assembly 52 is lowered into mold cavity 46 and the concrete is compacted (as described generally at 860 and 862 by process 850 of FIG. 19), as will be described in greater detail with reference to FIG. 23A below. FIG. 22D illustrates head shoe assembly 52 having a negative of a three-dimensional patter 874 that will be imprinted on an upper face of a block, as will be described in greater detail with reference to FIG. 23D below.
FIG. 23A through 23D illustrate examples of a CMU 930 as formed by mold assembly 30 as illustrated by FIGS. 22A through 22B. CMU 930 is commonly referred to as a retaining wall block. FIGS. 23A through 23C illustrate examples of a CMU 930 as formed by mold assembly 30 of FIGS. 22A and 22B and having a shoe assembly 52 including a notch 872 as illustrated by FIG. 22C. Retaining wall block 930 includes a front face 932 having the three-dimensional pattern as imprinted by liner face 100d, a rear face 934 formed by stationary liner plate 32b, and opposed side faces 936 and 938 are respectively formed by stationary liner plates 32a and 32c. A bottom face 940 and an opposing top face 942 are respectively formed by shoe assembly 52 and pallet 56.
Front face 932 has a width (wf) 944 and rear face 934 has a width (wr) 946. In one embodiment, as illustrated, wr 946 is less than wf 944 such that opposing side faces 936 and 938 are angled inwardly from front face 932 to rear face 934 at an angle (θ) 948. Retaining wall block 930 has a height (h) 950 and a depth (d) 952. Retaining wall block 930, as illustrated by FIG. 23A, can be formed with a plurality of dimensions including standard dimensions such as, for example, 4″(h)×12″(d)×9″(wf), 6″(h)×10″(d)×12″(wf), and 8″(h)×12″(d)×18″(wf).
In one embodiment, as illustrated, retaining wall block 930 includes a set-back flange 954 extending from bottom face 940 along the edge with rear face 934. Retaining wall blocks, such as retaining wall block 930, are generally stacked in courses to form a retaining wall. Set-back flange 941 is adapted to abut against a rear face of a similar block in a course of block below retaining wall block 930 to position front face 932 a desired back from the front face of the block(s) in the course below. As described above, and as is known to those skilled in the art, notch 872, as illustrated by FIG. 22C, is configured to cooperate with stationary liner plate 32d to form a set-back flange during the compaction process.
In one embodiment, as illustrated by FIG. 23B, the three-dimensional pattern of liner face 100d is angled relative to mold cavity 46 such that front face 932 of retaining wall block is at an angle (θ) 956 so that a depth (dU) 958 of upper face 942 is less than a depth (dL) 960 of lower face 940 by a depth (dF) 962 of set-back flange 954.
FIG. 23C illustrates retaining wall block 930 including a pair of hollow cores 956 which are formed by core bar assembly 870, as illustrated in FIGS. 22A and 22B. By including hollow cores 956 in the formation of retaining wall block 930, the weight of retaining wall block 930 is reduced and, as a result, the dimensions of block 930 can be increased without increasing its weight.
FIG. 23D illustrates an example of a retaining wall block 930 as formed by mold assembly 30 of FIGS. 22A and 22B, wherein mold assembly 30 includes a shoe assembly 52 having a negative of a three-dimensional pattern 874 as illustrated by FIG. 22C. Note that in this embodiment, shoe assembly 52 imprints the three-dimensional pattern on upper face 942 of retaining wall block 930, in lieu of forming a set-back flange on lower face 940. Retaining wall block 930, as illustrated by FIG. 23D, may be employed as what is commonly referred to as a “cap” block on an uppermost course of blocks of a soil retention wall.
FIGS. 24A through 24E are simplified illustrations of further exemplary implementations of mold assembly 30, as illustrated by FIGS. 22A and 22B and employing a head shoe assembly having a notch 872 as illustrated by FIG. 22C, and the corresponding retaining wall block 930 produced by such implementations.
FIG. 24A illustrates an implementation of mold assembly 30 wherein liner plates 32a, 32b, and 32c are stationary and liner plate 32d is moveable. Liner plate 32a is inwardly angled (e.g. at an angle θ 948 as illustrated by FIG. 23A) from liner plate 32d, while opposing liner plate 32c is perpendicular to liner 32d. Liner plate 100d is coupled to liner plate 32d and includes a negative of a three-dimensional pattern or texture. Accordingly, retaining wall block 930 produced by mold assembly 30 of FIG. 24A includes front face 932 imprinted with a three-dimensional pattern, a straight side face 936, an angled side face 938, and a set-back flange 954. Retaining wall block 930 can also be formed with hollow cores, indicated by dashed lines 956, by placing a core assembly within mold cavity 46 (see FIGS. 22A and 22B).
FIG. 24B illustrates an implementation of mold assembly 30 wherein liner plates 32a and 32b are stationary and liner plates 32c and 32d are moveable. Liner plate 32a is inwardly angled (e.g. at an angle θ 948 as illustrated by FIG. 23A) from liner 32d, while opposing liner plate 32c is perpendicular to liner 32d. Liner plates 100c and 100d are respectively coupled to liner plates 32c and 32d and include a negative of a three-dimensional pattern or texture. Accordingly, retaining wall block 930 produced by mold assembly 30 of FIG. 24B includes a front face 932 and a side face 936 each imprinted with a three-dimensional pattern, an angled side face 938, and a set-back flange 954. Retaining wall block 930 can also be formed with hollow cores, indicated by dashed lines 956, by placing a core assembly within mold cavity 46 (see FIGS. 22A and 22B).
FIG. 24C illustrates an implementation of mold assembly 30 wherein liner plates 32a and 32b are stationary and liners plates 32c and 32d are moveable, and wherein stationary liner plate 32a is perpendicular to moveable liner plate 32d. Liner plates 100c and 100d are respectively coupled to liner plates 32c and 32d and include a negative of a three-dimensional pattern or texture. Accordingly, retaining wall block 930 produced by mold assembly 30 of FIG. 24C includes a front face 932 and a side face 936 each imprinted with a three-dimensional pattern, side face 938 perpendicular to front face 932, and a set-back flange 954. Retaining wall block 930 can also be formed with hollow cores, indicated by dashed lines 956, by placing a core assembly within mold cavity 46 (see FIGS. 22A and 22B).
FIG. 24D illustrates an implementation of mold assembly 30 wherein liner plate 32b is stationary and liners plates 32a, 32c and 32d are moveable. Liner plates 100a, 100c and 100d are respectively coupled to liner plates 32a, 32c and 32d and include a negative of a three-dimensional pattern or texture. Accordingly, retaining wall block 930 produced by mold assembly 30 of FIG. 24D includes a front face 932 and opposing side faces 936 and 938 each imprinted with a three-dimensional pattern, and a set-back flange 954, wherein opposing side faces 936 and 938 are perpendicular to front face 932. Retaining wall block 930 can also be formed with hollow cores, indicated by dashed lines 956, by placing a core assembly within mold cavity 46 (see FIGS. 22A and 22B).
FIG. 24E illustrates an implementation of mold assembly 30 wherein liner plates 32a, 32b and 32c are stationary and liner plate 32s is moveable, and wherein liner plates 32a and 32c are perpendicular to liner plate 32d. Liner plate 100d is coupled to liner plate 32d and includes a negative of a three-dimensional pattern or texture. Accordingly, retaining wall block 930 produced by mold assembly 30 of FIG. 24E includes a front face 932 imprinted with a three-dimensional pattern, and a set-back flange 954, wherein opposing side faces 936 and 938 are perpendicular to front face 932. Retaining wall block 930 can also be formed with hollow cores, indicated by dashed lines 956, by placing a core assembly within mold cavity 46 (see FIGS. 22A and 22B).
FIGS. 25A through 25F are simplified illustrations of further exemplary implementations of mold assembly 30, as illustrated by FIGS. 22A and 22B and employing a head shoe assembly having a negative of a three-dimensional pattern 874 as illustrated by FIG. 22D, and the corresponding retaining wall block 930 produced by such implementations.
FIG. 25A illustrates an implementation of mold assembly 30 wherein liner plates 32a, 32b, and 32c are stationary and liner plate 32d is moveable. Liner plate 32a is inwardly angled (e.g. at an angle θ 948 as illustrated by FIG. 23A) from liner 32d, while opposing liner plate 32c is perpendicular to liner plate 32d. Liner plate 100d is coupled to liner plate 32d and includes a negative of a three-dimensional pattern or texture. Accordingly, retaining wall block 930 produced by mold assembly 30 of FIG. 25A includes front face 932 and upper face 942 each imprinted with a three-dimensional pattern, a straight side face 936, and an angled side face 938.
FIG. 25B illustrates an implementation of mold assembly 30 wherein liner plates 32a and 32b are stationary and liner plates 32c and 32d are moveable. Liner plate 32a is inwardly angled (e.g. at an angle θ 948 as illustrated by FIG. 23A) from liner 32d, while opposing liner plate 32c is perpendicular to liner 32d. Liner plates 100c and 100d are respectively coupled to liner plates 32c and 32d and include a negative of a three-dimensional pattern or texture. Accordingly, retaining wall block 930 produced by mold assembly 30 of FIG. 25B includes a front face 932, a side face 936, and an upper face 942 each imprinted with a three-dimensional pattern, and an angled side face 938.
FIG. 25C illustrates an implementation of mold assembly 30 wherein liner plates 32a and 32b are stationary and liners plates 32c and 32d are moveable, and wherein stationary liner plate 32a is perpendicular to moveable liner plate 32d. Liner plates 100c and 100d are respectively coupled to liner plates 32c and 32d and include a negative of a three-dimensional pattern or texture. Accordingly, retaining wall block 930 produced by mold assembly 30 of FIG. 25C includes a front face 932, a side face 936, and an upper face 942 each imprinted with a three-dimensional pattern, wherein side face 938 perpendicular to front face 932.
FIG. 25D illustrates an implementation of mold assembly 30 wherein liner plate 32b is stationary and liners plates 32a, 32c and 32d are moveable. Liner plates 100a, 100c and 100d are respectively coupled to liner plates 32a, 32c and 32d and include a negative of a three-dimensional pattern or texture. Accordingly, retaining wall block 930 produced by mold assembly 30 of FIG. 25D includes a front face 932, opposing side faces 936 and 938, and an upper face 942 each imprinted with a three-dimensional pattern, wherein opposing side faces 936 and 938 are perpendicular to front face 932.
FIG. 25E illustrates an implementation of mold assembly 30 wherein liners plates 32a, 32b, 32c and 32d are moveable. Liner plates 100a, 10b, 100c and 100d are respectively coupled to liner plates 32a, 32b, 32c and 32d and include a negative of a three-dimensional pattern or texture. Accordingly, retaining wall block 930 produced by mold assembly 30 of FIG. 25D includes a front face 932, a rear face 934, opposing side faces 936 and 938, and an upper face 942 each imprinted with a three-dimensional pattern, wherein opposing side faces 936 and 938 are perpendicular to front face 932 and rear face 934.
FIG. 25F illustrates an implementation of mold assembly 30 wherein liner plates 32a, 32b and 32c are stationary and liner plate 32s is moveable, and wherein liner plates 32a and 32c are perpendicular to liner plate 32d. Liner plate 100d is coupled to liner plate 32d and includes a negative of a three-dimensional pattern or texture. Accordingly, retaining wall block 930 produced by mold assembly 30 of FIG. 25F includes a front face 932 and an upper face 942 imprinted with a three-dimensional pattern, wherein opposing side faces 936 and 938 are perpendicular to front face 932.
FIGS. 26A through 26E are simplified illustrations of exemplary implementations of mold assembly 30 configured to form retaining wall blocks, such as those illustrated by FIGS. 27A through 27C, wherein the retaining wall blocks are formed in a vertical position (i.e., rear face formed by pallet 56) rather than in a horizontal position as illustrated by mold assembly 30 of FIGS. 22A and 22B.
FIGS. 26A and 26B are simplified illustrations of a lateral cross-section through one exemplary implementation of mold assembly 30. Mold assembly 30 includes side member 34a and 34b, and moveable liner plates 32b and 32d with corresponding drive assemblies 31b and 31d. Angled liner faces 100b and 100d are respectively coupled to moveable liner plates 32b and 32d. Pallet 56 is illustrated as forming a bottom to mold cavity 46. Shoe assembly 52 is indicated as being positioned above mold cavity 46. In one embodiment, as illustrated, shoe assembly 52 includes a negative of a three-dimensional texture or pattern 960 that is to be imprinted on a face of the block.
FIG. 26A illustrates liner plates 32b and 32d in a retracted position. FIG. 26B illustrates mold assembly 30 after mold cavity 46 has been filled with concrete. As such, liner plates 32b and 32d are shown as being extend toward the interior of mold cavity 46, and shoe assembly 52 as being positioned to form the top of mold cavity 46 and to compress the concrete as described at 860 and 862 of process 850 as described by FIG. 19.
FIG. 26C is simplified illustration of a longitudinal cross-section through mold assembly 30, as illustrated by FIGS. 26A and 26B. FIG. 64C illustrates cross-members 36a and 36b and stationary liner plates 32a and 32c. In one embodiment, one of the stationary liner plates (liner plate 32c as illustrated) includes a notch 962 adapted to form a set-back flange in the retaining wall block, as illustrated in greater detail below by FIG. 27A.
In one embodiment, as illustrated by FIG. 24D, liner plate 32a of mold assembly 30 illustrated by FIGS. 23A through 23C comprises a moveable liner plate in lieu of being a stationary liner plate. Moveable liner plate 32a is actuated by associated drive assembly 31a and includes an associated liner face 100a having a negative of a thee-dimensional texture or shape which is desired to be imprinted onto a face of the block.
In one embodiment, as illustrated by FIG. 24E, the three-dimensional pattern of head shoe assembly 52 is at an angle 964 relative to pallet 56 such that a surface of the block is at an angle, as described in further detail below by FIG. 27C.
FIG. 27A is an illustrative example of one embodiment of a retaining wall block 970 formed by mold assembly 30 as illustrated by FIGS. 20A through 20C. Retaining wall block 970 includes a front face 972 having the three-dimensional pattern as imprinted by liner face 960 of shoe assembly 52, a rear face 974 formed by pallet 56, and opposed side faces 976 and 978 respectively formed by moveable liner plates 32b and 32d. A bottom face 980 and an opposing top face 982 are respectively formed by stationary liner plates 32c and 32a. As illustrated, retaining wall block 970 includes a set-back flange 994 extending from bottom face 980 along the edge with rear face 974, wherein set-back flange is formed by notch 962 in stationary liner plate 32c.
Front face 972 has a width (wf) 984 and rear face 974 has a width (wr) 986. In one embodiment, as illustrated, liner faces 100b and 100d are outwardly angled so as to be wider where abutting pallet 56 than where abutting shoe assembly 52. As a result, wr 986 is less than wf 984 such that opposing side faces 976 and 978 are inwardly angled from front face 972 to rear face 974 at an angle (θ) 988. Retaining wall block 930 has a height (h) 950 and a depth (d) 952. Retaining wall block 930, as illustrated by FIG. 27A, can be formed with a plurality of dimensions including standard dimensions such as, for example, 4″(h)×12″(d)×9″(wf), 6″(h)×10″(d)×12″(wf), and 8″(h)×12″(d)×18″(wf).
FIG. 27B illustrates retaining wall block 970 as formed by mold assembly 30 of FIG. 24D, wherein top face 982 includes the three-dimensional pattern as imprinted by liner face 100a of moveable side liner 32a. Retaining wall block 970, as illustrated by FIG. 25B, can be employed as a “cap” block in a top row of blocks of a retaining wall structure, wherein the remaining courses of the retaining wall structure comprise blocks such as the embodiment of block 970 illustrated by FIG. 25A.
FIG. 27C illustrates retaining wall block 970 as formed by mold assembly 30 of FIG. 26E, wherein front face 972 of retaining wall block 970 is at angle (θ) 964 relative to rear face 974 so that a depth (dU) 983 of upper face 982 is less than a depth (dL) 981 of lower face 980 by a depth (dF) 995 of set-back flange 994.
Although not illustrated, in addition to the retaining wall blocks illustrated by FIGS. 27A through 27C, mold assembly 30 as illustrated by FIGS. 26A through 26E can also be configured to form retaining wall blocks similar illustrated by FIGS. 23D through 24F (without hollow cores 956).
As described above, in one embodiment, one or more of the moveable liner plates of a mold assembly in accordance with the present invention are provided with a negative of a desired three-dimensional pattern or texture that is desired to be imprinted on a corresponding face of a block. In one embodiment, a removable liner face, such as liner face 100 as illustrated by FIGS. 3A and 3B, is coupled to the moveable liner plate and includes the negative of the three-dimensional pattern or texture.
Also as described above, the three-dimensional texture or pattern may comprise any number of shapes, images, and text. In one embodiment, three-dimensional pattern simulates natural stone so that the faces of the block imprinted with the three-dimensional pattern (i.e., front face, upper face, opposed side faces) so that the concrete block has the appearance of natural stone or rock. Additionally, the liner plate can be shaped such that the surfaces of the block, particularly the front surface, are curved or faceted. Also, it is evident that the negative of the desired three-dimensional texture or pattern may be provided directly on the surfaces of the liner plates, such as surfaces 44a through 44d of liner plates 32a through 32 as illustrated by FIG. 1, in lieu of on a removable liner face, such as liner face 100.
FIG. 28A provides an illustration of an example three-dimensional texture 1000 imprinted on a front face of a concrete block produced by a mold assembly in accordance with the present invention, such as retaining wall block 970 of FIG. 27A. While three-dimensional texture 1000 simulates natural stone, the pattern may also simulate other naturally occurring or man made objects. The negative of the desired three-dimensional texture can be formed on the liner plate and/or liner face in various ways. For example, in one embodiment, liner face or liner plate having the negative of the desired three-dimensional texture can be formed using conventional casting techniques which are known to those skilled in the art. In another embodiment, the negative of the desired three-dimensional pattern or texture can be milled onto the liner face and/or liner plate employing digital scanning and computer-aided milling techniques.
FIG. 28B illustrates a soil retaining wall 1010 constructed employing retaining wall block 930 of FIG. 23A having a pattern 1000 imprinted on the front face, as well as similar retaining wall blocks employing other patterns.
FIG. 29 is a flow diagram 1020 illustrating an exemplary process for creating a negative of a desired three-dimensional image on a liner face and/or liner plate employing such digital scanning and computer-aided milling techniques. Process 1020 begins at 1022 with the selection of an object having a three-dimensional surface which is desired to be reproduced as a three-dimensional texture or pattern on a concrete block. For example, the object may be a naturally occurring rock or a man-made surface, such as a model/prototype of concrete block having a desired three-dimensional surface.
At 1024, the three-dimensional surface of the selected object is scanned using a digital scanning machine. An example of a suitable scanning machine for practicing the invention is the Laser Design Surveyor® 1200 available from Laser Design Incorporated of Minneapolis, Minn. The selected surfaces may be scanned at as many angles as necessary to collect data on all surfaces.
At step 1026, after the scanned data has been collected, various techniques can be employed to manipulate the scanned data. For example, initially, the Laser Design Surveyor® employs DataSculpt® software, available from Laser Design, Inc. of Minneapolis, Minn., to generate one or more DataSculpt® point clouds, or data sets including data positioned in X-Y-Z coordinates, from the scanned data.
In one embodiment, a computer-aided design (CAD) package is used to trim the point clouds, which are sampled to reduce the amount of scanned data while smoothing the data by removing extraneous points and noise. The data from the point clouds is blended to form a finished point cloud. The finished point cloud is then converted to a polygonal mesh, which is a three-dimensional rendition of the point cloud using polygonal shapes. Grids are applied to the polygonal mesh and converted to a Non-Uniform B-Splines (NURBS) surface. The resulting image is displayed and can be manipulated by a user by selecting and modifying one or more points on the digital image in the X, Y, and/or Z directions. The data is then scaled and/or trimmed to an overall block dimension and mirrored to create a negative of the desired three-dimensional image. The data can be output in an Initial Graphics Exchange Specification (IGES) format to a CAD system. A CAD system suitable for manipulating the scanned data is the Mastercam® Mill Version 8.1.1, available from CNC Software, Inc. of Tollan Conn.
At 1028, the IGES formatted data is input into a milling machine for milling of the liner face and/or liner plate. The data is converted into tool paths by the milling machine, which uses the tool paths to mill the negative of the desired three-dimensional pattern into the liner face and/or liner plate. Preferably, the milling machine is a three- or four-axis, numerically controlled milling machine, such as the Mikron VCP600 available from Mikron AG Nidau of Nidau Switzerland.
In one embodiment, as illustrated by the dashed line at 1029, process 1020 is complete upon milling of the liner plate and/or liner face. In another embodiment, as illustrated, process 1020 proceeds to 1030, where the liner plate and/or liner face is employed in a mold assembly, such as mold assembly 30 illustrated by FIGS. 22A through 22C, to produce a concrete block, such as retaining wall block 930 illustrated by FIG. 23A. Referring to FIGS. 22A and 22B, liner face 100 having the milled negative of the desired three-dimensional image is coupled to moveable liner plate 32d and imprints the three-dimensional texture on front face 932 of retaining wall block 930 of FIG. 23A.
At 1032, the resulting three-dimensional texture imprinted on the concrete block is evaluated to determine whether the actual texture produced is acceptable and provides the desired “look.” If the three-dimensional texture has the desired look, process 1020 is complete, as indicated at 1034. If the three-dimensional texture does not provide the desired “look”, process 1020 proceeds to 1036.
At 1036, the milled liner plate and/or liner face is physically altered through manually means, such as by grinding and welding, to modify the three-dimensional negative. Process 1020 then returns to 1030 and 1032 wherein another block is produced with the modified liner plate and/or liner face and the resulting three-dimensional texture on the concrete block is evaluated. This process is repeated until the desired look has been achieved, at which point process 100 proceeds to 1038.
At 1028, if the liner plate and/or liner face has not been manually altered, process 1020 is complete, as indicated at 1034. If the liner plate and/or liner face has been manually altered, process 1020 proceeds to 1040, where the manually modified liner plate and/or liner face is scanned in a fashion similar to that described at 1024 above. At 1042, the scanned data may be modified in a fashion similar to that described above at 1026 so that the data is scaled and/or trimmed to a desired dimension. At 1044, a “final” version of the liner plate based on the manually altered liner plate is milled in a fashion similar to that described above at 1028, at which point process 1020 is complete.
Alternatively, in lieu of manually altering the liner plate and/or liner face as described above by 1036 through 1044, scanned data can be repeatedly altered and corresponding liner plates and/or liner faces repeatedly milled based on the altered scanned data until a block having the desired look is produced at 1030. However, such a process may result in the milling of numerous liner plates and/or liner faces, while manually modifying the “prototype” liner plate and/or liner face may result in the milling of only two liner plates.
Although specific embodiments have been illustrated and described herein, it will be appreciated by those of ordinary skill in the art that a variety of alternate and/or equivalent implementations may be substituted for the specific embodiments shown and described without departing from the scope of the present invention. This application is intended to cover any adaptations or variations of the specific embodiments discussed herein. Therefore, it is intended that this invention be limited only by the claims and the equivalents thereof.