This disclosure relates generally to the manufacture of concrete blocks. More specifically, this disclosure relates to a mold and process for making concrete retaining wall blocks including a system for automatically cleaning portions of the mold.
Modern, high speed, automated concrete block plants and concrete paver plants make use of concrete block molds that are open at the top and bottom. These molds are mounted in machines that cyclically station a pallet below the mold to close the bottom of the mold, deliver dry cast concrete into the mold through the open top of the mold and densify and compact the concrete by a combination of vibration and pressure, and then strip the uncured blocks from the mold by relative vertical movement between the mold and the pallet. For efficient high-volume production, concrete block molds are typically configured to produce multiple blocks simultaneously. A concrete block mold generally comprises two side walls and two end walls (outside division plates) that define the periphery of a mold cavity. Within this mold cavity, inside division plates may be used to sub-divide the mold cavity into a plurality of block-forming cavities. The division plates, whether inside or outside, are generally rectangular-shaped plates attached to the side walls of the mold. Further, the side walls of the block cavity and the division plates may be covered with replaceable mold face linings to protect the mold components from abrasive wear.
As disclosed in U.S. Pat. No. 7,208,112, the complete disclosure of which is incorporated by reference herein, some blocks are formed with patterned, decorative, three-dimensional front faces while retaining the high-speed, mass production of the blocks. As disclosed in U.S. Pat. No. 7,208,112, the blocks can be formed front-face up in the mold, allowing the front face of the block to be contacted by a stripper shoe that imparts a desired three-dimensional pattern to the front face. When a block is formed front-face up in the mold, most of the top and bottom surfaces of the blocks (from the perspective of the block as laid in a wall) are formed by division plates. The side surfaces of the block preferably converge to allow the blocks to be laid up in a curved or radiused wall, making the front of the block wider than the rear of the block. For such a block formed front-face up to be discharged through the bottom of the mold, the side surfaces of a block must be formed by moveable side walls that, in a first position during molding, form the wider front portion and narrower bottom portion of the block, and in a second position during discharge of the block from the mold, moves sufficiently out of the way for the wider front portion of the block to pass through the bottom of the mold.
Some blocks are made to include a flange or lip that extends below the bottom of the block. The lip is designed to abut against the rear face of a like block in the course below that particular block to provide a predetermined set-back from the course below and provide course-to-course shear strength. To manufacture the block in a high speed concrete block mold process, the inside division plates and typically one of the outside division plates have an undercut or instep portion along the bottom edge. The undercut portion, in combination with the pallet that is introduced under the mold to temporarily close the open mold bottom during processing, defines a lip-forming subcavity. The lip-forming subcavity has a shape that results in the formation of the lip on the block. If the lips are not completely formed, there can be resulting problems. Such resulting problems may include a jagged edge at the interface between the lip and the bottom face of the block. This results in a wider inside lip radius. A wider inside lip radius may cause an upper block laid up on a lower block to ride forward, thus creating a forward pitch to the wall system. This can lead to an unstable wall.
Thus, there is a need for a mold and process that provide for an improved block, in which the inside lip radius is controlled.
In one aspect, a mold for forming dry cast concrete retaining wall blocks front molded face up is provided. The mold includes a pair of opposed mold sidewalls, at least a pair of division plates, and a cleaning system. The mold sidewalls and division plates define a mold cavity having an open top and an open bottom. At least one division plate has a first planar side, a bottom edge, and an undercut along the bottom edge which with a flat pallet under the mold defines a lip-forming subcavity therebetween. The cleaning system is constructed and arranged to non-manually remove dry cast concrete from the undercut.
In one example, the cleaning system includes a fluid injection system to deliver fluid to the undercut. In one example, the fluid is compressed gas, preferably compressed air. In other examples, the fluid can be oil. In other examples, the fluid can be an oil mist and air mixture.
In one embodiment, a control system is provided to direct the operation of the cleaning system. The control system is constructed and arranged to monitor the position of the mold and to emit a jet of compressed gas at the undercut based on the position of the mold.
In another aspect, a process for manufacturing concrete retaining wall blocks is provided. The retaining wall blocks have a bottom face with a lip projecting therefrom. The process includes molding a retaining wall block by depositing a dry cast concrete mixture into a mold, the mold being positioned upright and having two parallel mold sidewalls and at least a pair of division plates defining a mold cavity having an open top and an open bottom. The upright mold is positioned on a pallet so that the open bottom is closed by the pallet. At least one division plate has at least one planar side and a bottom edge with an undercut, which with the pallet, defines a lip-forming subcavity therebetween. Next, there is a step of forming the concrete retaining wall block by compacting the dry cast concrete mixture against surfaces within the cavity, including forming the lip by compacting the dry cast concrete against surfaces in the lip-forming subcavity. Next, the concrete retaining wall block is stripped from the open bottom of the mold and onto the pallet. Then, the undercut is non-manually cleaned.
In one example, the step of non-manually cleaning the undercut includes emitting a jet of compressed gas at the undercut.
In one example, the step of stripping includes moving a moveable sidewall within a block-forming cavity, and the step of non-manually cleaning includes sensing the position of the mold. Based on the position of the mold, a jet of compressed gas is automatically emitted at the undercut.
In one example, there is a step of forming a front face of the concrete retaining wall block by compacting the dry cast concrete mixture with a stripper shoe in the open top of the mold to impart a predetermined three-dimensional pattern to the concrete retaining wall block front face. The predetermined three-dimensional pattern has a relief of at least 0.5 inch.
In another aspect, a division plate for use in a concrete retaining wall block is provided. The division plate includes a planar first side; a planar second side opposite of the planar first side; a first side edge extending between the planar first side and planar second side; a second side edge extending between the planar first side and planar second side; a top side extending between the first side edge and second side edge; and a bottom side extending between the first side edge and second side edge. A bottom edge is at an intersection of the planar first side and the bottom side. The bottom edge has an undercut, the undercut being spaced from at least the first side edge by a first bottom edge section. The undercut is spaced from at least the first side edge by a first bottom edge section. The division plate has a first hole or bore extending from the first side edge, through the first bottom edge section and to the undercut to define a first fluid passageway through the division plate from the first side edge to the undercut.
In one example, the undercut is spaced from the second side edge by a second bottom edge section. The division plate has a second hole or bore extending from the second side edge, through the second bottom edge section, and to the undercut to define a second fluid passageway through the division plate from the second side edge to the subcavity. The first and second fluid passageways oppose each other at opposite ends of the undercut.
a is an enlarged view of the portion in dotted lines of
This disclosure provides a mold and a process for non-manually cleaning a lip forming undercut of a division plate. This process results in a concrete block with an inside lip radius that is controlled to be within certain tolerances. The lip cleaning system will remove dry cast concrete from the undercuts of the division plates which could cause the incomplete lip formation that has been a problem. In the past, the undercuts have been manually cleaned, periodically, within the production environment which added to overall costs. The solution will automatically clean the undercut as part of the molding process.
A. Example Block Construction,
A concrete block 20 manufactured with a mold and process according to principles of this disclosure is illustrated in
The block 20 is formed from dry cast, no slump concrete. Dry cast, no slump concrete is well-known in the art of retaining wall blocks.
The front face 24, as shown in
The pattern 38 that is imparted to the front face 24 can vary depending upon the desired appearance of the front face 24. In some examples, the pattern 38 simulates natural stone so that the front face 24 appears to be a natural material, rather than a man-made material. The pattern 38 selected can be decorative, distinctive, eye-catching, and visually-pleasing to the intended users of the blocks 20.
The pattern 38 will typically be a three-dimensional pattern, in many example embodiments. By the term “three-dimensional,” it is meant a surface pattern that is non-planar with enough variation in the dimensions such that the relief (the distance between the highest and lowest point) in the pattern 38 is at least 0.5 inch, typically between about 0.5 inch and 1.5 inch.
In the embodiment depicted in
Typically, when blocks 20 are stacked into set-back courses to form a wall, such as wall 36 of
Although not depicted in the embodiment shown in
In
The upper face 28 illustrated in
The lower face 30 of the block 20 is formed so as to be suitable for engaging the upper face 28 of the block 20 or blocks 20 in the course below to maintain the generally parallel relationship between the upper face 28 of the blocks 20 when the blocks 20 are stacked into courses. In the embodiment illustrated, the lower face 30 is generally parallel and horizontal so that it is generally parallel to the upper face 28. In other embodiments, the lower face 30 can be non-planar, including one or more concave portions or one or more channels over portions of the lower face 30. The distance d6 between the upper face 28 and the lower face 30 is typically at least 3.75 inches, for example, about 4.0 inches.
In the embodiment illustrated, the side faces 32, 34 are generally vertical and join the upper and lower faces 28, 30 and join the front and rear faces 24, 26, as seen in
In the embodiment shown, the block 20 includes a lip or flange 48. The lip 48 extends below the lower face 30 of the block 20 as can be seen in
In
The front surface 50 is preferably angled at an angle 58 of between 15-20 degrees, typically about 18 degrees. The angled front surface 50, bottom edge 54, and radiused surface 55 result from corresponding shaped portions of the mold, which construction facilitates filling of the mold with dry cast concrete and release of the flange or lip 48 from the mold. This is explained further below.
As can be seen in
In the embodiment depicted in
B. Example Structures Made from Blocks,
Blocks 20, as described above, may be used to build any number of landscape structures. An example of a structure that may be constructed with blocks 20 is illustrated in
As described above, the lip or flange 48 on the block 20 provides set-back of the block from the course below. As a result, the course 61 is set-back from the course 62, and the course 60 is set-back from the course 61. The rearward incline of the front face 24 reduces the ledge that is formed between each adjacent course, by reducing the amount of upper face portion of each block 20 in the lower course that is visible between the front face 24 of each block 20 in the lower course and the front face 24 of each block 20 in the adjacent upper course.
The retaining wall 36 depicted in
The first course 68 may often include blocks 20 that are laid on their upper face 28 to define a pattern or stop at the base of the wall 64. As can be seen in
C. The Mold Assembly,
In
In the embodiment of
During block formation, the open bottom 88 of the mold 80 and each block-forming cavity 94 is closed by pallet 35 (
In this embodiment, the mold 80 is constructed so that the blocks 20 are formed so that the block front face 24 is facing upwardly, and the block rear face 26 is supported on the pallet 35 (
Often times, the block-forming surfaces of the mold cavities 94 are provided with replaceable wear liners that contact the concrete in the mold cavities 94. These liners help prevent wear on the inside division plates 96, block cavity moveable side walls 102, 103, and outside division plates 92, 93, which can be expensive to replace. The use of wear liners is known to those having ordinary skill in the art. Therefore, although not illustrated in the drawings, references to the moveable sidewalls 102, 103; mold end walls 92, 93 or outside division plates 92, 93; and inside division plates 96 as forming faces of the blocks 20 is meant to include direct formation of the faces by these parts as well as formation of the faces by wear liners attached to these parts.
The inside division plate 96 shown in
Located adjacent to and below the recesses 120, 121 are T-bars 122, 123, also provided for engaging mating structure within the mold 80 to help secure the inside division plate 96 therewithin.
Adjacent to and below the T-bars 122, 123 are cutouts 124, 125. The cutouts 124, 125 accommodate the camshafts 108, 109 (
Still in reference to
The inside division plate 96 depicted in
The inside division plate 96, in the embodiment shown, further includes an undercut 142 or instep 142. In the embodiment shown, the undercut 142 is defined by a recess along a bottom edge 143, which is at the intersection of the first planar side 112 and bottom side 136. The undercut 142, in this embodiment, extends only partially between the cutouts 124, 125 of the first and second side edges 116, 118 and is spaced from vertical portions 160, 161 by first and second bottom edge sections 156, 157. In other embodiments, the undercut 142 may extend an entire length between the first and second side edges 116, 118. When the mold 80 is oriented upright in normal usage on flat pallet 35 (
The undercut 142 has a geometry to result in a desirable and usable lip 48. While a variety of implementations are useful, in the embodiment shown, the undercut 142 has a width 144 of 0.1-0.3 inch, for example, about 0.25; a height 146 of 0.4-0.6 inch, for example, about 0.51 inch; a radius 148 of 0.2-0.3 inch, for example, about 0.25 inch; and a length 150 (
In accordance with principles of this disclosure, the undercut 142 will be cleanable through an automatic, non-manual system. In one embodiment, the undercut 142 is cleanable by emitting fluid at the undercut 142 by way of access with at least a single hole or bore 152 through the division plate 96. In the example shown in
In
The bores 152, 153 are constructed and arranged to permit fluid, such as compressed gas, preferably compressed air, to be passed threrethrough in order to reach the undercut 142. In the embodiment depicted in
The bores 152, 153 have a size suitable to convey the compressed air to the subcavity 142. For example, the bores 152, 153 can have a length of 2-3 inches, for example about 2.4-2.6 inches. The nozzle receptacle portions 168, 169 will have a diameter of about 0.5 inch (or, for example, ⅛ inch NPT), while the conduits 170, 171 will have a diameter of about 0.092 inch. The bores 152, 153 are spaced from the bottom side 136 a distance of, for example, 0.2-0.5 inch, for example, 0.30-0.35 inch.
As can be seen in the particular embodiment illustrated in
The cleaning system 180 is provided to non-manually remove dry cast concrete from the undercut 142. A variety of implementations may be used. In the particular embodiment shown, the cleaning system 180 includes a fluid injection system 182, which is used to deliver fluid to the undercut 142. Various fluids can be used, including fluids in the form of liquid, fluids in the form of gas, and mixtures of liquid and gas. The liquid may include a lubricant, such as oil. Oil may be atomized as a mist with the compressed air to be delivered to the undercut 142.
In the embodiment depicted, compressed air is delivered from a manifold 184. Connected to the manifold 184 is a plurality of hoses 186, with each hose 186 being connected to one of the bores 152, 153 of each division plate having undercut 142, which can include all of the inside division plates 96 and one of the outside division plates 92. In the embodiment depicted in
As mentioned above, the cleaning system 180 is operated non-manually. Typically, the cleaning system 180 is operated automatically as part of the overall molding process. For example, in a process for manufacturing concrete retaining wall blocks 20, dry cast concrete mixture is deposited into the top 86 of the mold 80. The mold 80 will be positioned upright with its two parallel mold sidewalls 90, 91 and two parallel mold outside division plates (or end walls) 92, 93 perpendicular to the mold side walls 90, 91. The upright mold 80 is positioned on pallet 35 (
The step of non-manually cleaning the undercut 142 can include emitting a jet of compressed air at the undercut 142. This step can be done automatically by sensing when the block 20 has stripped from the mold 80.
For example, one way of accomplishing this step of sensing is by sensing the position of the mold 80. For example, the sensors can sense when the uncured block 20 has left the mold. Based on this, the step of non-manually, or automatically, cleaning includes sensing the position of the mold 80 and based on the position, emitting a jet of compressed air at the undercut 142.
In one embodiment, when the moveable sidewalls 102, 103 move from the molding position to the second, de-molding position, a hydraulic control unit sends a signal to an air control unit indicating the status. Timers then begin and open an air solenoid valve after a set amount of time. This time delay gives the block 20 enough time to be ejected from the mold 80. Timers also begin and close the solenoid valve after a set amount of time. This gives adequate time to clean the undercut(s) 142. For example, after the moveable sidewalls 102, 103 move to the de-molding position, and the uncured block 20 leaves the mold 80, the timers will be set to open the air solenoid after a set time.
The above represents examples and principles. Many embodiments can be made and methods practiced in accordance with these principles.
Number | Name | Date | Kind |
---|---|---|---|
511098 | Shultz | Dec 1893 | A |
813901 | Leming et al. | Feb 1906 | A |
824235 | Damon | Jun 1906 | A |
838278 | Schwartz | Dec 1906 | A |
1166312 | Barten | Dec 1915 | A |
1219127 | Marshall | Mar 1917 | A |
1982730 | Erkman | Dec 1934 | A |
2038205 | Case | Apr 1936 | A |
2121450 | Sentrop | Jun 1938 | A |
2916793 | Ellis et al. | Dec 1959 | A |
2934807 | Donati | May 1960 | A |
3204316 | Jackson | Sep 1965 | A |
3545053 | Besser | Dec 1970 | A |
3940229 | Hutton | Feb 1976 | A |
4047690 | Winter et al. | Sep 1977 | A |
4171194 | Goretti | Oct 1979 | A |
4218206 | Mullins | Aug 1980 | A |
4909970 | Pardo | Mar 1990 | A |
5297772 | Stefanick | Mar 1994 | A |
5445514 | Heitz | Aug 1995 | A |
5542837 | Johnston | Aug 1996 | A |
5589124 | Woolford et al. | Dec 1996 | A |
5827015 | Woolford et al. | Oct 1998 | A |
5879603 | Sievert | Mar 1999 | A |
5939104 | Johnston | Aug 1999 | A |
6007321 | Meckel et al. | Dec 1999 | A |
6224815 | LaCroix et al. | May 2001 | B1 |
6814906 | Bergeron et al. | Nov 2004 | B2 |
7208112 | Scherer | Apr 2007 | B2 |
20010007380 | LaCroix et al. | Jul 2001 | A1 |
20030126821 | Scherer | Jul 2003 | A1 |
20030182011 | Scherer | Sep 2003 | A1 |
20040004310 | LaCroix et al. | Jan 2004 | A1 |
20040104511 | Griffith | Jun 2004 | A1 |
20060273492 | Johnson | Dec 2006 | A1 |
20070028548 | Johnson et al. | Feb 2007 | A1 |
Number | Date | Country |
---|---|---|
25 55 714 | Jun 1977 | DE |
100 02 390 | Jul 2001 | DE |
2 232 114 | Dec 1990 | GB |
WO 03060251 | Jul 2003 | WO |
Number | Date | Country | |
---|---|---|---|
20100213347 A1 | Aug 2010 | US |