CROSS REFERENCE TO RELATED APPLICATIONS

This application claims priority to U.S. Provisional Patent Application No. 63/246,183, filed September 20, 2021, entitled “SEGMENTED WALL SYSTEMS HAVING TAIL BLOCKS AND METHODS OF MANUFACTURING,” and U.S. Provisional Patent Application No. 63/277,909, filed November 10, 2021, entitled “SEGMENTED WALL SYSTEMS HAVING TAIL BLOCKS AND METHODS OF MANUFACTURING”, and U.S. Provisional Patent Application No. 63/311 ,890, filed February 18, 2022, entitled “SEGMENTED WALL SYSTEMS HAVING TAIL BLOCKS AND METHODS OF MANUFACTURING”, and U.S. Provisional Patent Application No. 63/391,192, filed July 21, 2022, entitled “SEGMENTED WALL SYSTEMS HAVING TAIL BLOCKS AND METHODS OF MANUFACTURING”, each of which is incorporated by reference herein, in the entirety and for all purposes.

BACKGROUND

Numerous methods and materials exist for the construction of retaining walls and landscaping walls, including dry-stacked (e.g., built without the use of mortar) segmental concrete retaining wall (SRW) units. SRW units have become a widely accepted product for the construction of retaining walls, because they are relatively inexpensive and can be mass produced. They also tend to be structurally sound, easy and relatively inexpensive to install, and couple the durability of concrete with the attractiveness of various architectural finishes.

Building a retaining wall using SRWs often involves adding reinforcing materials to ensure the integrity of the wall over time. Depending upon their location, the soil type, the amount of water that can flow through the retaining wall, and the mineral content of the water, can affect the the strutural integrity of the retaining wall . Thus, many retaining wall systems use geogrids, geosynthetic reinforcement, or geogrid soil reinforcement. These terms sometimes are used interchangeably, and “geogrid” as used herein is intended as a generic term. Reinforcement materials may be inextensible, such as steel mesh, or extensible geosynthetic materials, such as mats and oriented polymeric materials. For example, flat polymeric sheets are used to form geogrids by forming holes in the sheets and then drawing them to orient the polymer and increase the modulus. Such polymeric materials include high density polyethylene (HDPE) and these materials form relatively stiff geogrids commercially available under the trade designation “TENS AR”. However, these reinforcing materials can add quite a bit of expense to install projects, as they often involve quite a bit of extra labor. A SRW system that improves known reinfircement systems is desired. SUMMARY

Segmented wall systems are described herein. An example segmented wall system may include a first course extending in a first direction and including a first wall block and a second wall block. A rear side of the first wall block may be connected to a first side of a first tail block and a rear side of the second wall block may be connected to a first side of a second tail block; The example segmented wall system may further include a second course stacked on the first course. The second course may include a third wall block having a rear side connected to a first side of a third tail block. The rear side of the third tail block may have a width in the first direction that is equal to or greater than a width in the first direction of the rear side of the third wall block.

Wall block forming systems may be described herein. An example wall block forming system may include a mold box having a cavity configured to form sides of a wall block, and a cutoff bar including a bottom edge configured to extend across a one set of opposing sides of the mold box and to move across the top of the mold box to remove excess material from the mold box during a process to form the wall block. The bottom edge of the cutoff bar may including a fixed portion and a movable portion. As the cutoff bar moves across a top surface of the mold box, the fixed portion may be configured to remove material from the mold box down to a first height across the top surface of the mold box and the movable portion is configured to selectively remove material from the mold box down to the first height or a second height different than the first height from the top surface of the mold box. The example wall block forming system may further include a stripper shoe configured to compress the material into the mold box after the cutoff bar has removed the excess material. The stripper shoe may include a bottom surface that has a fixed portion and a movable portion. During compression to form the wall block, the fixed portion of the bottom surface may be configured to form a top surface of the wall block at a third height and the movable portion is configured to recess to form a feature in the top surface of the wall block that has a fourth height different than the third height. The feature may be co-located with portions of material formed at the second height by movable portion the cutoff bar. When the stripper shoe is extracted, the movable portion may be configured to return from the recessed position such that its bottom surface aligns with a bottom surface of the fixed portionA

BRIEF DESCRIPTION OF THE DRAWINGS

Figures 1-7 depict a first embodiment of a segmented wall system with tail blocks, in accordance with an embodiment of the present disclosure.

Figures 8-16 depict a second embodiment of a segmented wall system with tail blocks, in accordance with an embodiment of the present disclosure. Figures 17-24 depict a third embodiment of a segmented wall system with tail blocks, in accordance with an embodiment of the present disclosure.

Figures 25-33 depict a fourth embodiment of a segmented wall system with tail blocks, in accordance with an embodiment of the present disclosure.

Figures 34-42 depict a fifth embodiment of a segmented wall system with tail blocks, in accordance with an embodiment of the present disclosure.

Figures 43-46 depict a sixth embodiment of a segmented wall system with tail blocks and connector, in accordance with an embodiment of the present disclosure.

Figures 47-60 depict a seventh embodiment of a segmented wall system with tail blocks and inter-course or layer lug connections, in accordance with an embodiment of the present disclosure.

Figures 61-69 depict an eighth embodiment of a segmented wall system with tail blocks and inter-course or layer pin connections, in accordance with an embodiment of the present disclosure.

Figures 70-82 depict method of manufacturing segmented wall blocks with lugs, in accordance with an embodiment of the present disclosure.

DETAILED DESCRIPTION

Certain details are set forth below to provide a sufficient understanding of embodiments of the present disclosure. However, it will be clear to one skilled in the art that embodiments of the present disclosure may be practiced without these particular details. Moreover, the particular embodiments of the present disclosure described herein are provided by way of example and should not be used to limit the scope of the disclosure to these particular embodiments.

This application includes examples of segmented wall systems having one or more tail blocks attached to a rear side of outward-facing structural wall blocks forming a segmented wall. In some examples, a segmented wall may be constructed from several vertically stacked courses or layers of wall blocks. Each course or layer of the segmented wall may generally extend in a first horizontal direction to form a face of the segmented wall and in second horizontal direction extending rearward from the face of the segmented wall. To form the segmented wall, each course or layer may include a respective set of wall blocks positioned side-by-side in a level plane. A number of respective wall blocks in each course or layer may be based on a horizontal length of the segmented wall in the first direction and a respective width in the first direction of each of the wall blocks.

In addition, one or more courses or layers of the segmented wall may include a respective tail block attached to (e.g., interlocked with) with a rear side of one or more of the respective set of wall blocks. For example, if the front of the segmented wall is straight or has a concave shape, a respective tail block may be attached to each of the set of wall blocks of one or more courses or layers. If the segmented wall has a concave shape that exceeds a particular curvature, additional tail blocks not connected to any wall blocks may be interleaved between tail blocks attached to the wall blocks to provide lateral support between the tail blocks. In some examples, if the front of the segmented wall has a comer or a convex shape, a respective tail block may be attached to fewer than all of the set of wall blocks of one or more courses or layers.

The wall blocks may each have a uniform size and shape, and the tail blocks may each have a uniform size and shape that is different than the size and shape of the wall blocks. In some examples, the wall blocks and the tail blocks may have a same, as installed, vertical height. In some examples, a length of the tail blocks may be greater than a length of the wall blocks. The wall blocks and the tail blocks may be made of a rugged, weather resistant material, such as precast concrete (e.g., dry cast or wet cast). Other suitable materials are plastic, reinforced fibers, wood, metal and stone. In some examples, the wall block may include at least one opening formed between a front portion having the front side and a rear portion having the rear side, with opposing neck portions extending between the front portion and the rear portion on opposing sides of the opening. If more than one opening is included, additional, inner neck portions may be formed between each pair of openings.

In some embodiments, the tail block may include a front portion having a first end configured to connect to the wall block and a rear portion having a second opposing end, with the front portion and the rear portion being connected via one or more neck portions. In some examples, the front portion and the rear portion may include wing portions that are configured to interlock with adjacent tail blocks. In some examples, the tail block may include two opposing neck portions that form an opening between the front portion and the rear portion. In some examples, the opposing neck portions of the tail block have a non-parallel relationship from the front portion to the rear portion (e.g., the first distance between the opposing neck portions at the front portion is greater than the second distance between the opposing neck portions at the rear portion). In some examples, the opposing neck portions merge together at or near the rear portion. In some examples, the opposing neck portions of the tail block have a parallel relationship from the front portion to the rear portion (e.g., the first distance between the opposing neck portions at the front portion is equal to the second distance between the opposing neck portions at the rear portion). In some examples, the first distance is approximately equal to a distance between the opposing neck portions of the wall block at the rear portion of the wall block such that the opposing neck portions of the wall block align with the opposing neck portions of the tail block. In alternative embodiments, the tail block may have single neck portion extending between a front portion having the first side and a rear portion having a second side. In some examples, the second end of the rear portion of the tail blocks may be configured to attach to another tail block such that multiple tail blocks to could be attached together in a chainlike manner. In some examples, the front portion of the tail blocks may connect to the wall blocks (or to another tail block) using a connection system formed in the wall block and the tail block. For example, the tail block may connect to the wall block (or to another tail block) using a vertical (e.g., extending from an, as-installed, top side to a bottom side of the wall block) dovetail connection. In some examples, the wall block (and the second end of the tail block) may include the male dovetail connection protruding from the rear side of the wall block and the tail block may include a female dovetail connection formed in the first side of the tail block. The dovetail connection between the tail block and the wall block (or another tail block) may extend an entire height of the rear side of the wall block (or the second side of the tail block). In some examples, male dovetail connection on the wall block may extend more than half of the width of the rear side of the wall block.

In some examples, as segmented walls are constructed, courses or layers of wall blocks are formed by vertically stacking wall blocks. For courses or layers that include tail blocks, the tail blocks from an upper layer may also stack on tail blocks from a lower layer in a similar manner. In some examples, the shape of the wall may cause a neck portion of a tail block of a first course or layer to at least partially overlap in a vertical direction with a neck portion of a tail block of a second course or layer on which the first layer or course is stacked to form a column of vertically- supported neck portions. In some examples, a segmented wall having a concave shape exceeding a particular curvature may cause a neck portion of a tail block of a first course or layer to at least partially overlap in a vertical direction with a neck portion of a tail block of a second course or layer that is not connected to any wall blocks (e.g., interleaved between two tail blocks connected to wall blocks) to form vertically-supported column of neck portions. The stacking of the tail blocks may add additional stability to the segmented wall by adding additional interlocking structure between two adjacent courses of the segmented wall. As the tail blocks are covered with fill material, the interlocking between layers of the tail blocks may be further strengthened.

In some examples, the wall system may further include use of reinforced earth techniques such as geogrid reinforcement, geosynthetic reinforcement, or the use of inextensible materials such as steel matrices. After placement of a course or layer of the wall, a geogrid material may be placed over the course or layer before placement of a next course or layer. The weight of the upper course or layer on the geogrid material sandwiched between two layers may hold the geogrid material in place. In some examples, additional pins, stakes, or other connectors in the wall block 110, the tail block 140, or the fill material may be use to penetrate the apertures of the geogrid material to further hold it in place. The use of the geogrid material may form a lateral interlocking connection between wall blocks and tail blocks of a course or layer, which may further fortify the segmented wall.

Figures 1-7 depict a first embodiment of a segmented wall system with tail blocks, in accordance with an embodiment of the present disclosure. The segmented wall system of Figures 1-8 may be formed using a combination of wall blocks 110 and tail blocks 140. Figure 1 depicts various perspective views of a wall block 110 connected to a first tail block 140, and a second tail block 140 connected to the first tail block 140. Figure 2-4 depict different segmented wall shapes with various arrangements of the wall blocks 110 and tail blocks 140, in accordance with embodiments of the disclosure. Figure 4 depicts an example of two different setback options (e.g., near vertical setback or full setback) between two adjacent courses or layers at a front of a segmented wall, in accordance with embodiments of the disclosure. Figure 5A depicts an example pallet layout of wall blocks 110 in accordance with embodiments of the disclosure. Figure 5B depicts an example pallet layout of tail blocks 140 in accordance with embodiments of the disclosure. Figure 6 depicts various views of the wall block 110, in accordance with embodiments of the disclosure. Figure 7 depicts various perspective views of the tail block 140, in accordance with embodiments of the disclosure.

Figure 1 identifies detailed elements of the wall blocks 110 and the tail blocks 140 using reference numbers. Many of those reference numbers are not repeated in Figures 2-8 in the interest of clarity and brevity. One of skill in the art would appreciate that those common elements exist as described with reference to Figure 1.

The wall blocks 110 may each have a uniform size and shape, and the tail blocks 140 may each have a uniform size and shape that is different than the size and shape of the wall blocks 110. In some examples, the wall blocks 110 and the tail blocks 140 may have a same, as installed, vertical height H. In some examples, a length of the tail blocks 140 may be greater than a length of the wall blocks 110. The wall blocks 110 and the tail blocks 140 may be made of a rugged, weather resistant material, such as pre-cast concrete (e.g., dry cast or wet cast). Other suitable materials are plastic, reinforced fibers, wood, metal and stone.

In some examples, the wall block 110 may include at least one opening 118 formed between a front portion 112 having the front side 120 and a rear portion 114 having the rear side 122, with opposing neck portions 116 extending between the front portion 112 and the rear portion 122 on opposing sides of the opening 118. The outer surfaces of the opposing neck portions 116 may form sides 124 and 126 of the wall block 110. A top and bottom of the wall block 110 may include a flat surface to facilitate stacking of other wall blocks on top of one another.

The tail block 140 may include a front portion 142 having a first end 150 configured to connect to the wall block 110 and a rear portion 144 having a second opposing end 152, with the front portion 142 and the rear portion 144 being connected via one or more neck portions 146. In some examples, the front portion 142 and the rear portion 144 may include wing portions that are configured to interlock with adjacent tail blocks. In some examples, the tail block 140 may include two opposing neck portions 146 that form an opening 148 between the front portion 142 and the rear portion 144. The outer surfaces of the opposing neck portions 146 may form sides 154 and 156 of the tail block 140. A top and bottom of the tail block 140 may include a flat surface to facilitate stacking of other tail blocks 140 on top of one another.

In some examples, the opposing neck portions 146 of the tail block 140 may have a nonparallel relationship from the front portion 142 to the rear portion 144 (e.g., the first distance between the opposing neck portions 146 at the front portion 142 is greater than the second distance between the opposing neck portions 146 at the rear portion 144). In some examples, the opposing neck portions 146 merge together at or near the rear portion 144.

In some examples, the front portion 142 of the tail blocks 140 may connect to the wall blocks 110 (or to another tail block 140) using a connection system 123 and 151 formed in the wall block 110 and the tail block 140, respectively. For example, the tail block 140 may connect to the wall block 110 (or to another tail block 140) using a vertical (e.g., extending from an, as-installed, top side to a bottom side of the wall block 110) dovetail connection (e.g., using connectors 123 and 151). In some examples, the wall block 110 (and the second end of the tail block 140) may include the male dovetail connection 123 protruding from the rear side 122 of the wall block 110 and the tail block 140 may include a female dovetail connection 151 formed in the first side 150 of the tail block 140. The dovetail connection (using connectors 123 and 151) between the tail block 140 and the wall block 110 (or another tail block 140) may extend an entire height of the rear side 122 of the wall block 110 (or the second side 152 of the tail block 140). In some examples, male dovetail connection 123 on the wall block 110 may extend more than half of the width of the rear side 122 of the wall block 110. As previously described, the second end 152 of the rear portion 144 of the tail blocks 140 may be configured to attach to another tail block 140 such that multiple tail blocks 140 to could be attached together in a chain-like manner (e.g., such as at least three tail blocks, as shown in Figure 1). While the connection shown in Figures 1-7 includes a dovetail connection, other types of connections may be used, such as a rounded connection or additional slotted connections where a connector is slid into slots formed in each of the wall block 110 and the tail block 140.

Figures 2 and 3 depict front and rear views, respectively, of one example of a portion (e.g., courses 160, 162, and 164) of a segmented wall 100 with a non-linear shape formed using the wall blocks 110 and the tail blocks 140 in accordance with embodiments of the disclosure. As shown, the portion of the segmented wall 100 may be constructed from several vertically stacked courses or layers 160, 162, and 164 of wall blocks 110. Each course or layer 160, 162, and 164 of the segmented wall 100 may generally extend in a first horizontal direction to form a face of the segmented wall 100 and in second horizontal direction extending rearward from the face of the segmented wall 100. To form the segmented wall 100, each course or layer 160, 162, and 164 may include a respective set of wall blocks 110 positioned side-by-side in a level plane. A number of respective wall blocks 110 in each course or layer 160, 162, and 164 may be based on a horizontal length of the segmented wall 100 in the first direction and a respective width in the first direction of each of the wall blocks 110.

In addition, the courses or layers 160, 162, and 164 of the segmented wall 100 may include at least one respective tail block 140 attached to (e.g., interlocked with) with a rear side of one or more of the respective set of wall blocks 110. For example, if the front of the segmented wall 100 is straight or has a concave shape, a respective tail block 140 may be attached to each of the set of wall blocks of one or more courses or layers. If the segmented wall 100 has a concave shape that exceeds a particular curvature, additional tail blocks 140 not connected to any wall blocks may be interleaved between tail blocks 140 attached to the wall blocks 110 to provide lateral support between the tail blocks 140. In some examples, if the front of the segmented wall 100 has a comer or a convex shape, a respective tail block 140 may be attached to fewer than all of the set of wall blocks 110 of one or more courses or layers 160, 162, and 164.

In some examples, the segmented wall 100 is constructed, the courses or layers 160, 162, and 164 of wall blocks 110 are formed by vertically stacking wall blocks 110. For courses or layers 160, 162, and 164 that include tail blocks 140, the tail blocks 140 from an upper layer (e.g., 162 or 164) may also stack on tail blocks 140 from a lower layer (e.g., 160 or 162) in a similar manner. In some examples, the shape of the segmented wall 100 may cause a neck portion of a tail block 140 of a first course or layer (e.g., 162 or 164) to at least partially overlap in a vertical direction with a neck portion of a tail block 140 of a second course or layer (e.g., 160 or 162) on which the first layer or course (e.g., 162 or 164) is stacked to form a column of vertically-supported neck portions. In some examples, a segmented wall 100 having a concave shape exceeding a particular curvature may cause a neck portion of a tail block 140 of a first course or layer (e.g., 162 or 164) to at least partially overlap in a vertical direction with a neck portion of a tail block 140 of a second course or layer (e.g., 160 or 162) that is not connected to any wall blocks 110 (e.g., interleaved between two tail blocks 140 connected to wall blocks 110) to form vertically-supported column of neck portions. The stacking of the tail blocks 140 may add additional stability to the segmented wall 100 by adding additional interlocking structure between two adjacent courses or layer 160, 162, or 164 of the segmented wall 100. As the tail blocks 140 are covered with fill material, the interlocking between courses or layers 160, 162, and 164 of the tail blocks 140 may be further strengthened. As prevously described, the use of a geogrid material in construction of the segemented wall system may fortify lateral connections between wall blocks and tail blocks in a course or layer.

The segmented wall 100 depicted in Figures 2 and 3 is exemplary. Thus, while Figures 2 and 3 depict the segmented wall 100 with three courses or layers 160, 162, and 164; it is appreciated that the segmented wall 100 may include more or fewer than three courses or layers. It is also appreciated that the segmented wall 100 may include more or fewer than a number of wall blocks 110 and tail blocks 140 in each course or layer than depicted. It is also appreciated that a segmented wall may be constructed in a different shape than depicted without departing from the scope of the disclosure. Finally, it is appreciated that some courses or layers may of the segmented wall 100 may include no tail blocks 140, a single row of tail blocks 140, or more than two rows of wall blocks without departing from the scope of the disclosure.

Figures 8-16 depict a second embodiment of a segmented wall system with tail blocks, in accordance with an embodiment of the present disclosure. The segmented wall system of Figures 8-16 may be formed using a combination of wall blocks 210 and tail blocks 240. Figures 8 depicts examples of various perspective views of part of a course or layer of wall blocks 210 connected to tail blocks 240, with an additional tail block 240* between the two tail blocks 240, in accordance with embodiments of the disclosure. Figure 9-13 depict different segmented wall shapes with various arrangements of the wall blocks 210 and tail blocks 240, in accordance with embodiments of the disclosure. Figure 14A depicts an example pallet layout of wall blocks 210 in accordance with embodiments of the disclosure. Figure 14B depicts an example pallet layout of tail blocks 240 in accordance with embodiments of the disclosure. Figure 15 depicts various views of the wall block 210, in accordance with embodiments of the disclosure. Figure 16 depicts various perspective views of the tail block 240, in accordance with embodiments of the disclosure.

Figure 8 identifies detailed elements of the wall blocks 210 and the tail blocks 240 using reference numbers. Many of those reference numbers are not repeated in Figures 9-16 in the interest of clarity and brevity. One of skill in the art would appreciate that those common elements exist as described with reference to Figure 8.

The wall blocks 210 may each have a uniform size and shape, and the tail blocks 240 may each have a uniform size and shape that is different than the size and shape of the wall blocks 210. In some examples, the wall blocks 210 and the tail blocks 240 may have a same, as installed, vertical height H. In some examples, a length of the tail blocks 240 may be greater than a length of the wall blocks 210. The wall blocks 210 and the tail blocks 240 may be made of a rugged, weather resistant material, such as pre-cast concrete (e.g., dry cast or wet cast). Other suitable materials are plastic, reinforced fibers, wood, metal and stone. In some examples, the wall block 210 may include two openings 218 formed between a front portion 212 having the front side 220 and a rear portion 214 having the rear side 222, with opposing neck portions 216 and a middle neck portion 216 extending between the front portion 212 and the rear portion 222 on opposing sides of the opening 218. The outer surfaces of the opposing neck portions 216 may form sides 224 and 226 of the wall block 210. A top and bottom of the wall block 210 may include a flat surface to facilitate stacking of other wall blocks on top of one another.

The tail block 240 may include a front portion 242 having a first end 250 configured to connect to the wall block 210 and a rear portion 244 having a second opposing end 252, with the front portion 242 and the rear portion 244 being connected via one or more neck portions 246. In some examples, the front portion 242 and the rear portion 244 may include wing portions that are configured to interlock with and/or contact adjacent tail blocks. In some examples, the tail block 240 may include two opposing neck portions 246 that form an opening 248 between the front portion 242 and the rear portion 244. The outer surfaces of the opposing neck portions 246 may form sides 254 and 256 of the tail block 240. A top and bottom of the tail block 240 may include a flat surface to facilitate stacking of other tail blocks 240 on top of one another.

In some examples, the opposing neck portions 246 of the tail block 240 may have a parallel relationship from the front portion 242 to the rear portion 244 (e.g., the first distance between the opposing neck portions 246 at the front portion 242 is equal to the second distance between the opposing neck portions 246 at the rear portion 244).

In some examples, the front portion 242 of the tail blocks 240 may connect to the wall blocks 210 (or to another tail block 240) using a connection system 223 and 251 formed in the wall block 210 and the tail block 240, respectively. For example, the tail block 240 may connect to the wall block 210 (or to another tail block 240) using a vertical (e.g., extending from an, as-installed, top side to a bottom side of the wall block 210) dovetail connection (e.g., using connectors 223 and 251). In some examples, the wall block 210 (and the second end of the tail block 240) may include the male dovetail connection 223 protruding from the rear side 222 of the wall block 210 and the tail block 240 may include a female dovetail connection 251 formed in the first side 250 of the tail block 240. The dovetail connection (using connectors 223 and 251) between the tail block 240 and the wall block 210 (or another tail block 240) may extend an entire height of the rear side 222 of the wall block 210 (or the second side 252 of the tail block 240). In some examples, male dovetail connection 223 on the wall block 210 may extend more than half of the width of the rear side 222 of the wall block 210. As previously described, the second end 252 of the rear portion 244 of the tail blocks 240 may be configured to attach to another tail block 240 such that multiple tail blocks 240 to could be attached together in a chain-like manner. While the connection shown in Figures 8-16 includes a dovetail connection, other types of connections may be used, such as a rounded connection or additional slotted connections where a connector is slid into slots formed in each of the wall block 210 and the tail block 240.

As shown in Figures 9-13, different courses or layers 260, 262 of a segmented wall may include linear shapes, non-linear shapes, or combinations thereof formed using the wall blocks 210 and the tail blocks 240 in accordance with embodiments of the disclosure. In Figure 9, a portion of a straight/linear segmented wall with two courses 260, 262 is shown. In some examples, the straight/linear shape of the segmented wall may cause a neck portion of a tail block 240 of the course or layer 262 to at least partially overlap in a vertical direction with a neck portion of a tail block 240 of the course or layer 260 to form a column of vertically-supported neck portions.

Figures 10 and 11 depict a portion of a curved (e.g., concave) segmented wall, with part of two courses 260, 262 shown in Figure 11. The courses or layers 260, 262 may include at least one respective tail block 240 attached to (e.g., interlocked with) with a rear side of one or more of the respective set of wall blocks 21O.The curvature of the wall in Figures 10 and 11 may be uniform and have a radius and an angle A degrees from a center of a wall block 210 to a space between the wall blocks 210, and an angle of 2 times A degrees between the centers of the wall blocks 210. With the angle between the centers of the wall blocks 210 being at least A degrees, an additional tail block 240* not connected to any wall blocks 210 may be interleaved between tail blocks 240 attached to the wall blocks 210 to provide lateral support between the tail blocks 240. The interleaved tail block 240* may provide vertical support for the tail block 240 placed on top in the course or layer 262. In some examples, A degrees is based on a width of the wall blocks 210. In some examples, A degrees is between and including 8 and 20 degrees.

Figures 12 and 13 depict a portion of a curved (e.g., convex) segmented wall with part of two courses 260, 262. The courses or layers 260, 262 may include at least one respective tail block 240 attached to (e.g., interlocked with) with a rear side of one or more of the respective set of wall blocks 210. The curvature of the wall in Figures 12 and 13 may be uniform, each having a respective radius and a respective angle of B (Figure 12) or A (Figure 13) degrees between opposing edges of a wall block 210. With the angle of B degrees, only every other wall block 210 is attached to a tail block 240 and the rear portions line up to provide support of the upper course or layer 262 wall block by the lower course or layer260 wall block 210. With the angle of not more than A degrees, a neck portion of a tail block 240 of the course or layer 262 to at least partially overlap in a vertical direction with a neck portion of a tail block 240 of the course or layer 260 to form a column of vertically-supported neck portions.

The stacking of the tail blocks 240 may add additional stability to the segmented wall by adding additional interlocking structure between two adjacent courses or layer 260, 262. As the tail blocks 240 are covered with fill material, the interlocking between courses or layers 260, 262 may be further strengthened. In some examples, the wall system may further include use of reinforced earth techniques such as geogrid reinforcement, geosynthetic reinforcement, or the use of inextensible materials such as steel matrices. After placement of a course or layer of the wall, a geogrid material may be placed over the course or layer before placement of a next course or layer. The weight of the upper course or layer on the geogrid material sandwiched between two layers may hold the geogrid material in place. In some examples, additional pins, stakes, or other connectors in the wall block 210, the tail block 240, or the fill material may be use to penetrate the apertures of the geogrid material to further hold it in place. The use of the geogrid material may form a lateral interlocking connection between wall blocks and tail blocks of a course or layer, which may further fortify the segmented wall.

The segmented walls depicted in Figures 8-16 are exemplary. Thus, while Figures 8-16 depict the segmented wall with not more than two courses or layers 260, 262; it is appreciated that the segmented wall may include more or fewer than two courses or layers. It is also appreciated that the segmented wall may include more or fewer than a number of wall blocks 210 and tail blocks 240 in each course or layer than depicted. It is also appreciated that a segmented wall may be constructed in a different shape than depicted without departing from the scope of the disclosure. Finally, it is appreciated that some courses or layers may of the segmented wall may include no tail blocks 240, a single row of tail blocks 240, or more than two rows of wall blocks without departing from the scope of the disclosure.

Figures 17-24 depict a third embodiment of a segmented wall system with tail blocks, in accordance with an embodiment of the present disclosure. The segmented wall system of Figures 17-24 may be formed using a combination of wall blocks 210 and tail blocks 340. Figures 17 depicts examples of various perspective views of part of a course or layer of wall blocks 210 connected to tail blocks 340, with an additional tail block 340* between the two tail blocks 340, in accordance with embodiments of the disclosure. Figures 18-22 depict different segmented wall shapes with various arrangements of the wall blocks 210 and tail blocks 340, in accordance with embodiments of the disclosure. Figure 23 depicts an example pallet layout of tail blocks 340 in accordance with embodiments of the disclosure. Figure 24 depicts various perspective views of the tail block 340, in accordance with embodiments of the disclosure.

Figures 17-24 may include elements that have been previously described with respect to Figures 8-16. Those elements have been identified in Figures 17-24 using the same reference numbers used in Figures 8-16 and operation of the common elements is as previously described. Consequently, a detailed description of the operation of these particular elements will not be repeated in the interest of brevity. Figure 17 identifies detailed elements of the tail blocks 340 using reference numbers. Many of those reference numbers are not repeated in Figures 18-24 in the interest of clarity and brevity. One of skill in the art would appreciate that those common elements exist as described with reference to Figure 17.

The tail block 340 may include a front portion 342 having a first end 350 configured to connect to the wall block 210 and a rear portion 344 having a second opposing end 352, with the front portion 342 and the rear portion 344 being connected via one or more neck portions 346. In some examples, the front portion 342 and the rear portion 344 may include wing portions that are configured to interlock with and/or contact adjacent tail blocks. In some examples, the tail block 340 may include a single neck portion 346 between the front portion 342 and the rear portion 344, which may be more narrow in a middle portion and may flare out near where the neck portion 346 connects to both the front portion 342 and the rear portion 344. The outer surfaces of the neck portion 346 may form sides 354 and 356 of the tail block 340. A top and bottom of the tail block 340 may include a flat surface to facilitate stacking of other tail blocks 340 on top of one another.

In some examples, the front portion 342 of the tail blocks 340 may connect to the wall blocks 210 (or to another tail block 340) using a connection system 223 and 351 formed in the wall block 210 and the tail block 340, respectively. For example, the tail block 340 may connect to the wall block 310 (or to another tail block 340) using a vertical (e.g., extending from an, as-installed, top side to a bottom side of the wall block 210) dovetail connection (e.g., using connectors 223 and 351). In some examples, the wall block 210 (and the second end of the tail block 340) may include the male dovetail connection 223 protruding from the rear side 222 of the wall block 210 and the tail block 340 may include a female dovetail connection 351 formed in the first side 350 of the tail block 340. The dovetail connection (using connectors 223 and 351) between the tail block 340 and the wall block 210 (or another tail block 340) may extend an entire height of the rear side 222 of the wall block 210 (or the second side 352 of the tail block 340). In some examples, male dovetail connection 223 on the wall block 210 may extend more than half of the width of the rear side 222 of the wall block 210. As previously described, the second end 352 of the rear portion 344 of the tail blocks 340 may be configured to attach to another tail block 340 such that multiple tail blocks 340 to could be attached together in a chain-like manner. While the connection shown in Figures 17-24 includes a dovetail connection, other types of connections may be used, such as a rounded connection or additional slotted connections where a connector is slid into slots formed in each of the wall block 210 and the tail block 340.

As shown in Figures 18-22, different courses or layers 360, 362 of a segmented wall may include linear shapes, non-linear shapes, or combinations thereof formed using the wall blocks 210 and the tail blocks 340 in accordance with embodiments of the disclosure. In Figure 18, a portion of a straight/linear segmented wall with two courses 360, 362 is shown. In some examples, the straight/linear shape of the segmented wall 100 may cause the front and rear portions of a tail block 340 of the course or layer 362 to at least partially overlap with the front and rear portions, respectively, of adjacent tail blocks 340 of the course or layer 360 to form a column of vertically- supported rear portions.

Figure 19 depict a portion of a curved (e.g., concave) segmented wall with part of two courses 360, 362. The courses or layers 360, 362 may include at least one respective tail block 340 attached to (e.g., interlocked with) with a rear side of one or more of the respective set of wall blocks 210. The curvature of the wall in Figure 19 may be uniform and have a radius and an angle A degrees from a center of a wall block 210 to a space between the wall blocks 210, and an angle of 2 times A degrees between the centers of the wall blocks 210. With the angle between the centers of the wall blocks 210 being at least A degrees, an additional tail block 340* not connected to any wall blocks 210 may be interleaved between tail blocks 340 attached to the wall blocks 210 to provide lateral support between the tail blocks 340. The interleaved tail block 340* may provide vertical support for the tail block 340 placed on top in the course or layer 362. In some examples, A degrees is based on a width of the wall blocks 210. In some examples, A degrees is between and including 8 and 20 degrees.

Figures 20 and 21 depict a portion of a curved (e.g., convex) segmented wall, with part of two courses 360, 362. The courses or layers 360, 362 may include at least one respective tail block 340 attached to (e.g., interlocked with) with a rear side of one or more of the respective set of wall blocks 310. The curvature of the wall in Figures 20 and 21 may be uniform, each having a respective radius and a respective angle of B (Figure 20) or A (Figure 21) degrees between opposing edges of a wall block 210. With the angle of B degrees, only every other wall block 210 is attached to a tail block 340 and the rear portions line up to provide support of the upper course or layer 362 wall block by the lower course or layer 460 wall block 410. With the angle of not more than A degrees and the rear portions line up to provide support of the upper course or layer 362 wall block by the lower course or layer wall block 360.

Figure 22 depicts a portion of a 90 degree comer segmented wall (perpendicular sides 390 and 392), with part of two courses 360, 362. The courses or layers 360, 362 may include at least one respective tail block 340 attached to (e.g., interlocked with) with a rear side of one or more of the respective set of wall blocks 310 in an alternating fashion between the sides 390 and 392 due to a space conflicts that arise in perpendicular wall construction. For example, starting from the adjoining comer, the first wall block 410 of the side 390 in the first course or layer 360 may be attached to a tail block 340, while the first wall block 410 of the side 392 in the first course or layer 362 may not be attached to a tail block 340. Conversely, starting from the adjoining comer, the first wall block 410 of the side 392 in the second course or layer 362 may be attached to a tail block 340, while the first wall block 410 of the side 390 in the second course or layer 362 may not be attached to a tail block 340. Similar alternating arrangements between the sides 390 and 392 in the courses or layer 360 and 362 may be implemented for tail blocks 340 further away from the adjoining comer. The stacking of the tail blocks 340 in this way may add additional stability to the segmented wall by adding additional interlocking structure between courses or layers 360, 362 of the different sides 390, 392. As the tail blocks 340 are covered with fill material, the interlocking between courses or layers 360, 362 may be further strengthened.

In some examples, the wall system may further include use of reinforced earth techniques such as geogrid reinforcement, geosynthetic reinforcement, or the use of inextensible materials such as steel matrices. After placement of a course or layer of the wall, a geogrid material may be placed over the course or layer before placement of a next course or layer. The weight of the upper course or layer on the geogrid material sandwiched between two layers may hold the geogrid material in place. In some examples, additional pins, stakes, or other connectors in the wall block 310, the tail block 340, or the fill material may be use to penetrate the apertures of the geogrid material to further hold it in place. The use of the geogrid material may form a lateral interlocking connection between wall blocks and tail blocks of a course or layer, which may further fortify the segmented wall.

The segmented walls depicted in Figures 17-24 are exemplary. Thus, while Figures 17-24 depict the segmented wall with not more than two courses or layers 360, 362; it is appreciated that the segmented wall may include more or fewer than two courses or layers. It is also appreciated that the segmented wall may include more or fewer than a number of wall blocks 210 and tail blocks 340 in each course or layer than depicted. It is also appreciated that a segmented wall may be constructed in a different shape than depicted without departing from the scope of the disclosure. Finally, it is appreciated that some courses or layers may of the segmented wall may include no tail blocks 340, a single row of tail blocks 340, or more than two rows of wall blocks without departing from the scope of the disclosure.

Figures 25-33 depict a fourth embodiment of a segmented wall system with tail blocks, in accordance with an embodiment of the present disclosure. The segmented wall system of Figures 25-33 may be formed using a combination of wall blocks 410 and tail blocks 440. Figures 25 depicts examples of various perspective views of part of a course or layer of wall blocks 410 connected to tail blocks 440, with an additional tail block 440* between the two tail blocks 440, in accordance with embodiments of the disclosure. Figures 26A-30 depict different segmented wall shapes with various arrangements of the wall blocks 410 and tail blocks 440, in accordance with embodiments of the disclosure. Figure 31 A depicts an example pallet layout of wall blocks 410 in accordance with embodiments of the disclosure. Figure 3 IB depicts an example pallet layout of tail blocks 440 in accordance with embodiments of the disclosure. Figure 32 depicts various perspective views of the wall block 410, in accordance with embodiments of the disclosure. Figure 33 depicts various perspective views of the tail block 440, in accordance with embodiments of the disclosure.

Figure 25 identifies detailed elements of the wall blocks 410 and the tail blocks 440 using reference numbers. Many of those reference numbers are not repeated in Figures 26-33 in the interest of clarity and brevity. One of skill in the art would appreciate that those common elements exist as described with reference to Figure 25.

The wall blocks 410 may each have a uniform size and shape, and the tail blocks 440 may each have a uniform size and shape that is different than the size and shape of the wall blocks 410. In some examples, the wall blocks 410 and the tail blocks 440 may have a same, as installed, vertical height H. In some examples, a length of the tail blocks 440 may be greater than a length of the wall blocks 410. The wall blocks 410 and the tail blocks 440 may be made of a rugged, weather resistant material, such as pre-cast concrete (e.g., dry cast or wet cast). Other suitable materials are plastic, reinforced fibers, wood, metal and stone.

In some examples, the wall block 410 may include at least one opening 418 formed between a front portion 412 having the front side 420 and a rear portion 414 having the rear side 422, with opposing neck portions 416 extending between the front portion 412 and the rear portion 422 on opposing sides of the opening 418. The outer surfaces of the opposing neck portions 416 may form sides 424 and 426 of the wall block 410. A top and bottom of the wall block 410 may include a flat surface to facilitate stacking of other wall blocks on top of one another.

The tail block 440 may include a front portion 442 having a first end 450 configured to connect to the wall block 410 and a rear portion 444 having a second opposing end 452, with the front portion 442 and the rear portion 444 being connected via one or more neck portions 446. In some examples, the front portion 442 and the rear portion 444 may include wing portions that are configured to interlock with and/or contact adjacent tail blocks. In some examples, the tail block 440 may include two opposing neck portions 446 that form an opening 448 between the front portion 442 and the rear portion 444. The outer surfaces of the opposing neck portions 446 may form sides 454 and 456 of the tail block 440. A top and bottom of the tail block 440 may include a flat surface to facilitate stacking of other tail blocks 440 on top of one another.

In some examples, the opposing neck portions 446 of the tail block 440 may have a nonparallel relationship from the front portion 442 to the rear portion 444 (e.g., the first distance between the opposing neck portions 446 at the front portion 442 is greater than the second distance between the opposing neck portions 446 at the rear portion 444). In some examples, the opposing neck portions 446 merge together at or near the rear portion 444.

In some examples, the front portion 442 of the tail blocks 440 may connect to the wall blocks 410 (or to another tail block 440) using a connection system 423 and 451 formed in the wall block 410 and the tail block 440, respectively. For example, the tail block 440 may connect to the wall block 410 (or to another tail block 440) using a vertical (e.g., extending from an, as-installed, top side to a bottom side of the wall block 410) dovetail connection (e.g., using connectors 423 and 451). In some examples, the wall block 410 (and the second end of the tail block 440) may include the male dovetail connection 423 protruding from the rear side 422 of the wall block 410 and the tail block 440 may include a female dovetail connection 451 formed in the first side 450 of the tail block 440. The dovetail connection (using connectors 423 and 451) between the tail block 440 and the wall block 410 (or another tail block 440) may extend an entire height of the rear side 422 of the wall block 410 (or the second side 452 of the tail block 440). In some examples, male dovetail connection 423 on the wall block 410 may extend more than half of the width of the rear side 422 of the wall block 410. As previously described, the second end 452 of the rear portion 444 of the tail blocks 440 may be configured to attach to another tail block 440 such that multiple tail blocks 440 to could be attached together in a chain-like manner. While the connection shown in Figures 25-34 includes a dovetail connection, other types of connections may be used, such as a rounded connection or additional slotted connections where a connector is slid into slots formed in each of the wall block 410 and the tail block 440.

As shown in Figures 26A-30, different courses or layers 460, 462 of a segmented wall may include linear shapes, non-linear shapes, or combinations thereof formed using the wall blocks 410 and the tail blocks 440 in accordance with embodiments of the disclosure. Figures 26A and 26B depict a portion of a curved (e.g., concave) segmented wall, with part of two courses 460, 462 with near vertical setback (26A) and full setback (26B). The courses or layers 460, 462 may include at least one respective tail block 440 attached to (e.g., interlocked with) with a rear side of one or more of the respective set of wall blocks 410. The curvature of the wall in Figures 26A and 26B may be uniform and have a radius and an angle A degrees from a center of a wall block 410 to a space between the wall blocks 410, and an angle of 2 times A degrees between the centers of the wall blocks 410. With the angle between the centers of the wall blocks 410 being at least A degrees, an additional tail block 440* not connected to any wall blocks 410 may be interleaved between tail blocks 440 attached to the wall blocks 410 to provide lateral support between the tail blocks 440. The interleaved tail block 440* may provide vertical support for the tail block 440 placed on top in the course or layer 462. In some examples, A degrees is based on a width of the wall blocks 410. In some examples, A degrees is between and including 8 and 20 degrees. Figures 27A and 27B depict a portion of a straight or linear segmented wall, with part of two courses 460, 462 with near vertical setback (27 A) and full setback (27B). In some examples, the straight/linear shape of the segmented wall may cause a neck portion of a tail block 440 of the course or layer 462 to at least partially overlap in a vertical direction with a neck portion of a tail block 440 of the course or layer 460 to form a column of vertically-supported neck portions.

Figures 28 and 29 depict a portion of a curved (e.g., convex) segmented wall with part of two courses 460, 462. The courses or layers 460, 462 may include at least one respective tail block 440 attached to (e.g., interlocked with) with a rear side of one or more of the respective set of wall blocks 410. The curvature of the wall in Figures 28 and 29 may be uniform, each having a respective radius and a respective angle of B (Figure 28) or A (Figure 29) degrees between opposing edges of a wall block 410. With the angle of B degrees, only every other wall block 410 is attached to a tail block 440 and the rear portions line up to provide support of the upper course or layer 462 wall block 410 by the lower course or layer 460. With the angle of not more than A degrees, a neck portion of a tail block 440 of the course or layer 462 to at least partially overlap in a vertical direction with a neck portion of a tail block 440 of the course or layer 460 to form a column of vertically-supported neck portions.

Figure 30 depicts a portion of a 90 degree comer segmented wall (perpendicular sides 490 and 492), with part of two courses 460, 462. The courses or layers 460, 462 may include at least one respective tail block 440 attached to (e.g., interlocked with) with a rear side of one or more of the respective set of wall blocks 410 in an alternating fashion between the sides 490 and 492 due to a space conflicts that arise in perpendicular wall construction. For example, starting from the adjoining comer, the first wall block 410 of the side 490 in the first course or layer 460 may be attached to a tail block 440, while the first wall block 410 of the side 492 in the first course or layer 462 may not be attached to a tail block 440. Conversely, starting from the adjoining comer, the first wall block 410 of the side 492 in the second course or layer 462 may be attached to a tail block 440, while the first wall block 410 of the side 490 in the second course or layer 462 may not be attached to a tail block 440. Similar alternating arrangements between the sides 490 and 492 in the courses or layer 460 and 462 may be implemented for tail blocks 440 further away from the adjoining comer. The stacking of the tail blocks 440 in this way may add additional stability to the segmented wall by adding additional interlocking structure between courses or layers 460, 462 of the different sides 490, 492. As the tail blocks 440 are covered with fill material, the interlocking between courses or layers 460, 462 may be further strengthened.

In some examples, the wall system may further include use of reinforced earth techniques such as geogrid reinforcement, geosynthetic reinforcement, or the use of inextensible materials such as steel matrices. After placement of a course or layer of the wall, a geogrid material may be placed over the course or layer before placement of a next course or layer. The weight of the upper course or layer on the geogrid material sandwiched between two layers may hold the geogrid material in place. In some examples, additional pins, stakes, or other connectors in the wall block 410, the tail block 440, or the fill material may be use to penetrate the apertures of the geogrid material to further hold it in place. The use of the geogrid material may form a lateral interlocking connection between wall blocks and tail blocks of a course or layer, which may further fortify the segmented wall.

The segmented walls depicted in Figures 25-33 are exemplary. Thus, while Figures 25-33 depict the segmented wall with not more than two courses or layers 460, 462; it is appreciated that the segmented wall may include more or fewer than two courses or layers. It is also appreciated that the segmented wall may include more or fewer than a number of wall blocks 410 and tail blocks 440 in each course or layer than depicted. It is also appreciated that a segmented wall may be constructed in a different shape than depicted without departing from the scope of the disclosure. Finally, it is appreciated that some courses or layers may of the segmented wall may include no tail blocks 440, a single row of tail blocks 440, or more than two rows of wall blocks without departing from the scope of the disclosure.

Figures 34-42 depict a fifth embodiment of a segmented wall system with tail blocks, in accordance with an embodiment of the present disclosure. The segmented wall system of Figures 34-42 may be formed using a combination of wall blocks 510 and tail blocks 540. Figures 34 depicts examples of various perspective views of part of a course or layer of wall blocks 510 connected to tail blocks 540, with an additional tail block 540* between the two tail blocks 540, in accordance with embodiments of the disclosure. Figures 35-39 depict different segmented wall shapes with various arrangements of the wall blocks 510 and tail blocks 540, in accordance with embodiments of the disclosure. Figure 40A depicts an example pallet layout of wall blocks 510 in accordance with embodiments of the disclosure. Figure 40B depicts an example pallet layout of tail blocks 540 in accordance with embodiments of the disclosure. Figure 41 depicts various perspective views of the wall block 510, in accordance with embodiments of the disclosure. Figure 42 depicts various perspective views of the tail block 540, in accordance with embodiments of the disclosure.

Figure 34 identifies detailed elements of the wall blocks 510 and the tail blocks 540 using reference numbers. Many of those reference numbers are not repeated in Figures 35-42 in the interest of clarity and brevity. One of skill in the art would appreciate that those common elements exist as described with reference to Figure 34.

The wall blocks 510 may each have a uniform size and shape, and the tail blocks 540 may each have a uniform size and shape that is different than the size and shape of the wall blocks 510. In some examples, the wall blocks 510 and the tail blocks 540 may have a same, as installed, vertical height H. In some examples, a length of the tail blocks 540 may be greater than a length of the wall blocks 510. The wall blocks 510 and the tail blocks 540 may be made of a rugged, weather resistant material, such as pre-cast concrete (e.g., dry cast or wet cast). Other suitable materials are plastic, reinforced fibers, wood, metal and stone.

In some examples, the wall block 510 may include at least one opening 518 formed between a front portion 512 having the front side 520 and a rear portion 514 having the rear side 522, with opposing neck portions 516 extending between the front portion 512 and the rear portion 522 on opposing sides of the opening 518. The outer surfaces of the opposing neck portions 516 may form sides 524 and 526 of the wall block 510. A top and bottom of the wall block 510 may include a flat surface to facilitate stacking of other wall blocks on top of one another.

The tail block 540 may include a front portion 542 having a first end 550 configured to connect to the wall block 510 and a rear portion 544 having a second opposing end 552, with the front portion 542 and the rear portion 544 being connected via one or more neck portions 546. In some examples, the front portion 542 and the rear portion 544 may include wing portions that are configured to interlock with and/or contact adjacent tail blocks. In some examples, the tail block 540 may include two opposing neck portions 546 that form an opening 548 between the front portion 542 and the rear portion 544. The outer surfaces of the opposing neck portions 546 may form sides 554 and 556 of the tail block 540. A top and bottom of the tail block 540 may include a flat surface to facilitate stacking of other tail blocks 540 on top of one another.

In some examples, the opposing neck portions 546 of the tail block 540 may have a nonparallel relationship from the front portion 542 to the rear portion 544 (e.g., the first distance between the opposing neck portions 546 at the front portion 542 is greater than the second distance between the opposing neck portions 546 at the rear portion 544). In some examples, the opposing neck portions 546 merge together at or near the rear portion 544.

In some examples, the front portion 542 of the tail blocks 540 may connect to the wall blocks 510 (or to another tail block 540) using a connection system 523 and 551 formed in the wall block 510 and the tail block 540, respectively. For example, the tail block 540 may connect to the wall block 510 (or to another tail block 540) using a vertical (e.g., extending from an, as-installed, top side to a bottom side of the wall block 510) dovetail connection (e.g., using connectors 523 and 551). In some examples, the wall block 510 (and the second end of the tail block 540) may include the male dovetail connection 523 protruding from the rear side 522 of the wall block 510 and the tail block 540 may include a female dovetail connection 551 formed in the first side 550 of the tail block 540. The dovetail connection (using connectors 523 and 551) between the tail block 540 and the wall block 510 (or another tail block 540) may extend an entire height of the rear side 522 of the wall block 510 (or the second side 552 of the tail block 540). In some examples, male dovetail connection 523 on the wall block 510 may extend more than half of the width of the rear side 522 of the wall block 510. As previously described, the second end 552 of the rear portion 544 of the tail blocks 540 may be configured to attach to another tail block 540 such that multiple tail blocks 540 to could be attached together in a chain-like manner. While the connection shown in Figures 35-42 includes a dovetail connection, other types of connections may be used, such as a rounded connection or additional slotted connections where a connector is slid into slots formed in each of the wall block 510 and the tail block 540.

As shown in Figures 35-39, different courses or layers 560, 562 of a segmented wall may include linear shapes, non-linear shapes, or combinations thereof formed using the wall blocks 510 and the tail blocks 540 in accordance with embodiments of the disclosure. Figure 35 depicts a portion of a straight or linear segmented wall, with part of two courses 560, 562. In some examples, the straight/linear shape of the segmented wall may cause a neck portion of a tail block 540 of the course or layer 562 to at least partially overlap in a vertical direction with a neck portion of a tail block 540 of the course or layer 560 to form a column of vertically-supported neck portions.

Figure 36 depicts a portion of a curved (e.g., concave) segmented wall, with part of two courses 560, 562. The courses or layers 560, 562 may include at least one respective tail block 540 attached to (e.g., interlocked with) with a rear side of one or more of the respective set of wall blocks 510. The curvature of the wall in Figure 36 may be uniform and have a radius and an angle A degrees from a center of a wall block 510 to a space between the wall blocks 510, and an angle of 2 times A degrees between the centers of the wall blocks 510. With the angle between the centers of the wall blocks 510 being at least A degrees, an additional tail block 540* not connected to any wall blocks 510 may be interleaved between tail blocks 540 attached to the wall blocks 510 to provide lateral support between the tail blocks 540. The interleaved tail block 540* may provide vertical support for the tail block 540 placed on top in the course or layer 562. In some examples, A degrees is based on a width of the wall blocks 510. In some examples, A degrees is between and including 8 and 20 degrees.

Figures 37 and 38 depict a portion of a curved (e.g., convex) segmented wall with part of two courses 560, 562. The courses or layers 560, 562 may include at least one respective tail block 540 attached to (e.g., interlocked with) with a rear side of one or more of the respective set of wall blocks 510. The curvature of the wall in Figures 37 and 38 may be uniform, each having a respective radius and a respective angle of B (Figure 37) or A (Figure 38) degrees between opposing edges of a wall block 510. With the angle of B degrees, only every other wall block 510 is attached to a tail block 540 and the rear portions line up to provide support of the upper course or layer 562 wall block 510 by the lower course or layer 560. With the angle of not more than A degrees, a neck portion of a tail block 540 of the course or layer 562 to at least partially overlap in a vertical direction with a neck portion of a tail block 540 of the course or layer 560 to form a column of vertically-supported neck portions.

Figure 39 depicts a portion of a 90 degree comer segmented wall (perpendicular sides 590 and 592), with part of two courses 560, 562. The courses or layers 560, 562 may include at least one respective tail block 540 attached to (e.g., interlocked with) with a rear side of one or more of the respective set of wall blocks 510 in an alternating fashion between the sides 590 and 592 due to a space conflicts that arise in perpendicular wall construction. For example, starting from the adjoining comer, the first wall block 510 of the side 590 in the first course or layer 560 may be attached to a tail block 540, while the first wall block 510 of the side 592 in the first course or layer 562 may not be attached to a tail block 540. Conversely, starting from the adjoining comer, the first wall block 510 of the side 592 in the second course or layer 562 may be attached to a tail block 540, while the first wall block 510 of the side 590 in the second course or layer 562 may not be attached to a tail block 540. Similar alternating arrangements between the sides 590 and 592 in the courses or layer 560 and 562 may be implemented for tail blocks 540 further away from the adjoining comer. The stacking of the tail blocks 540 in this way may add additional stability to the segmented wall by adding additional interlocking structure between courses or layers 560, 562 of the different sides 590, 592. As the tail blocks 540 are covered with fill material, the interlocking between courses or layers 560, 562 may be further strengthened.

In some examples, the wall system may further include use of reinforced earth techniques such as geogrid reinforcement, geosynthetic reinforcement, or the use of inextensible materials such as steel matrices. After placement of a course or layer of the wall, a geogrid material may be placed over the course or layer before placement of a next course or layer. The weight of the upper course or layer on the geogrid material sandwiched between two layers may hold the geogrid material in place. In some examples, additional pins, stakes, or other connectors in the wall block 510, the tail block 540, or the fill material may be use to penetrate the apertures of the geogrid material to further hold it in place. The use of the geogrid material may form a lateral interlocking connection between wall blocks and tail blocks of a course or layer, which may further fortify the segmented wall.

The segmented walls depicted in Figures 35-42 are exemplary. Thus, while Figures 35-42 depict the segmented wall with not more than two courses or layers 560, 562; it is appreciated that the segmented wall may include more or fewer than two courses or layers. It is also appreciated that the segmented wall may include more or fewer than a number of wall blocks 510 and tail blocks 540 in each course or layer than depicted. It is also appreciated that a segmented wall may be constructed in a different shape than depicted without departing from the scope of the disclosure. Finally, it is appreciated that some courses or layers may of the segmented wall may include no tail blocks 540, a single row of tail blocks 540, or more than two rows of wall blocks without departing from the scope of the disclosure.

Figures 43-46 depict a fourth embodiment of a segmented wall system with tail blocks and connector, in accordance with an embodiment of the present disclosure. The segmented wall system of Figures 43-46 may be formed using a combination of wall blocks 410 and tail blocks 440. Figure 43 depicts various perspective views of a wall block 410# connected to a tail block 440#, in accordance with embodiments of the disclosure. Figure 32 depicts various perspective views of the wall block 410#, in accordance with embodiments of the disclosure. Figure 33 depicts various perspective views of the tail block 440#, in accordance with embodiments of the disclosure.

Figures 43-46 may include elements that have been previously described with respect to Figures 25-33, Some of those elements have not been specifically identified in Figures 43-46 in the interest of clarity’ and brevity, and operation of the common elements is as previously described. Consequently, a detailed description of the operation of these particular elements will not be repeated in the interest of brevity.

Figure 43 identifies detailed elements of the wall blocks 410# and the tail blocks 440# using reference numbers. Many of those reference numbers are not repeated in Figures 44-46 in the interest of clarity and brevity. One of skill in the art would appreciate that those common elements exist as described with reference to Figure 43.

The wall blocks 410# and the tail blocks 440# may be similar to the wall blocks 410 and tail blocks 440 of Figures 25-33, with differences in a connection system at the rear portion 614 of the wall block 410# and at the front portion 642 of the tail block 440#.

In some examples, the front portion 642 of the tail blocks 440# may connect to the wall blocks 410# (or to another tail block 440#) using a connection system that includes a slot (or channel) 682 formed in the rear portion 614 of the wall block 410#, a slot (or channel) 681 formed in the rear portion 642 of the tail block 440#, and a connector 680. For example, the tail block 440 may connect to the wall block 410 (or to another tail block 440) using a vertical (e.g., extending from an, as-installed, top side to a bottom side of the wall block 410) connector 680 that slides down into the slot 681 of the tail block 440# and the slot 682 of the wall block 410#. The slot or channel 682 may extend through the rear side 622 of the rear portion 614 of the wall block 410# and the slot or channel 681 may extend through the first side 650 of the front portion 642 of the tail block 440#. In some examples, the femal dovetail connector 451 of the tail block 440 of Figures 25-33 may be replaced with a regtangular shape 651. In other examples, the same female dovetail connection may be implemented. In some examples, the rear portion 644 of the tail block 440# may include slots 683 to form a part of a connection system to connect to another tail block (similar to connection of the wall block 410# to the tail block 440# using the slots 681, 682 and the connector 680).

The connector may include two opposing shafts connected by a bridge portion that is more narrow than the opposing shafts. The slots 681 and 682 may extend from a bottom side to a top side of the tail block 440# and wall block 410#, respectively. The slots 681 and 682 are configured to align with one another when the front portion 642 of the tail block 440# is abutted against the rear portion 614 of the wall block 410#, and are sized to receive the opposing shafts of the connector 680, which may secure the tail block 440# to the wall block 410#. The shape of the slots 681 and 682 may be square, triangular, circular, ovular, etc. The shape of the opposing shafts on the connector 680 may match a shape of the slots 681 and 682, in some examples. In other examples, the shape of the opposing shafts on the connector 680 may have a different than the slots 681 and 682.

The connection system using the connector 680 and the slots 681 and 682 depicted in Figures 43-46 is exemplary. It is appreciated that the connection system could be modified to include more or fewer than two connection points without departing from the scope of the disclosure. It is also appreciated that the embodiments depicted in Figures 1-24 and 34-42 could also be modified to implement a connection system similar to the example shown in Figures 43-46 without departing from the scope of the disclosure.

Figures 47-60 depict a fourth embodiment of a segmented wall system with tail blocks with inter-course or layer lug connections, in accordance with an embodiment of the present disclosure. The segmented wall system of Figures 47-60 may be formed using a combination of wall blocks 710 and tail blocks 740. The wall blocks 710 and the tail blocks 740 of Figures 47-60 include many similar features as the wall blocks 1 10 and 140 of Figures 1-7, Many of those reference numbers are not repeated in Figures 47-60 in the interest of clarity and brevity. One of skill in the art would appreciate that those common elements exist as described with reference to Figures 47- 60.

Figure 47 depicts examples of various perspective views of part of a course or layer of wall blocks 710 connected to tail blocks 740, with an additional tail block 740* between the two tail blocks 740, in accordance with embodiments of the disclosure. Figures 48-52 depict different segmented wall shapes with various arrangements of the wall blocks 710 and tail blocks 740 (and comer blocks 790/792), in accordance with embodiments of the disclosure. Figure 53 depicts various perspective views of the wall block 710, in accordance with embodiments of the disclosure. Figure 54 depicts various perspective views of the tail block 740, in accordance with embodiments of the disclosure. Figure 55 depicts various perspective views of a first version of the comer block 790, in accordance with embodiments of the disclosure. Figure 56 depicts various perspective views of a first version of the comer block 792, in accordance with embodiments of the disclosure. Figures 57-59 depict different segmented wall shapes with various arrangements of the wall blocks 710 and tail blocks 740 and capped with a cap block 794, in accordance with embodiments of the disclosure. Figure 60 depicts various perspective views of the cap block 794, in accordance with embodiments of the disclosure.

The wall blocks 710 may each have a uniform size and shape, and the tail blocks 740 may each have a uniform size and shape that is different than the size and shape of the wall blocks 710. In some examples, the wall blocks 710 and the tail blocks 740 may have a same, as installed, vertical height. In some examples, a length of the tail blocks 740 may the same or a greater than a length of the wall blocks 710. In some examples, a length of the tail blocks 740 may be less than a length of the wall blocks 710. The wall blocks 710 and the tail blocks 740 may be made of a rugged, weather resistant material, such as pre-cast concrete (e.g., dry cast or wet cast). Other suitable materials are plastic, reinforced fibers, wood, metal and stone.

In some examples, the wall block 710 may include at least one opening 774 formed between a front portion having the front side and a rear portion having the rear side, with opposing neck portions extending between the front portion and the rear portion on opposing sides of the opening. The outer surfaces of the opposing neck portions may form opposing sides of the wall block 710. A top and bottom of the wall block 710 may include a flat surface to facilitate stacking of other wall blocks on top of one another. However, in order to connect courses or layers of wall blocks together, each wall block may include a pair of engagement protrusions (e.g., lugs) 776 and 778 protruding from the top of the wall block 710. The pair of lugs 776 and 778 protruding from the top of the wall block 710 may be horizontally-aligned with the rear of the aperture and may be positioned on an outside edges of the wall block near where the rear portion meets the neck portions. The pair of lugs 776 and 778 may be configured to interface with the rear face of the aperture of a wall block 710 stacked on top of the wall block 710. Furthermore, the pair of lugs 776 and 778 may be offset from the rear face of the aperture 774, so as to result in a staggered incline as successive courses or layers of wall blocks 710 are formed.

In some examples, the front portion of the tail blocks 740 may connect to the wall blocks 710 (or to another tail block 740) using a connection system formed in the wall block 710 and the tail block 740, respectively. For example, the tail block 740 may connect to the wall block 710 (or to another tail block 740) using a vertical (e.g., extending from an, as-installed, top side to a bottom side of the wall block 710) dovetail connection.

As shown in Figures 48-52, different courses or layers 760, 762 of a segmented wall may include linear shapes, non-linear shapes, or combinations thereof formed using the wall blocks 710 and the tail blocks 740 in accordance with embodiments of the disclosure. Figure 48 depicts a portion of a curved (e.g., concave) segmented wall, with part of two courses 760, 762 with a setback. The courses or layers 760, 762 may include at least one respective tail block 740 attached to (e.g., interlocked with) with a rear side of one or more of the respective set of wall blocks 710. The curvature of the wall in Figure 48 may be uniform and have a radius and an angle from a center of a wall block 710 to a space between the wall blocks 710. With the angle depicted between the centers of the wall blocks 710, an additional tail block 740* not connected to any wall blocks 710 may be interleaved between tail blocks 740 attached to the wall blocks 710 to provide lateral support between the tail blocks 740. The interleaved tail block 740* may provide vertical support for the tail block 740 placed on top in the course or layer 762.

Also as shown in Figure 48, the aperture 774 of the wall block 710 in the upper course or layer 762 may engage with the lug 778 of the left wall block 710 of the lower course or layer 760 and may engage with the lug 776 of the right wall block 710 of the lower course or layer 760. That is, the wall block 710 of the upper course or layer 760 may be positioned such that the rear face of the aperture 774 engages with the lugs 778 and 776 of the wall blocks of the lower course of layer 760, which prevents the wall block 710 in the upper course or layer 762 from moving forward.

Figure 49 depicts a portion of a straight or linear segmented wall, with part of two courses 760, 762 with a setback. In some examples, the straight/linear shape of the segmented wall may cause a neck portion of a tail block 740 of the course or layer 762 to at least partially overlap in a vertical direction with a neck portion of a tail block 740 of the course or layer 760 to form a column of vertically-supported neck portions.

Similar to Figure 48, as shown in Figure 49, the aperture 774 of the wall block 710 in the upper course or layer 762 may engage with the lug 778 of the left wall block 710 of the lower course or layer 760 and may engage with the lug 776 of the right wall block 710 of the lower course or layer 760. That is, the wall block 710 of the upper course or layer 760 may be positioned such that the rear face of the aperture 774 engages with the lugs 778 and 776 of the wall blocks of the lower course of layer 760, which prevents the wall block 710 in the upper course or layer 762 from moving forward.

Figure 50 depicts a portion of a curved (e.g., convex) segmented wall with part of two courses 760, 762. The courses or layers 760, 762 may include at least one respective tail block 740 attached to (e.g., interlocked with) with a rear side of one or more of the respective set of wall blocks 710. The curvature of the wall in Figure 50 may be uniform, having a respective radius and a respective angle between opposing edges of a wall block 710.

Figure 51 depicts a portion of a 90 degree outer comer segmented wall, with part of two courses 760, 762. The courses or layers 760, 762 may include at least one respective tail block 740 attached to (e.g., interlocked with) with a rear side of one or more of the respective set of wall blocks 710 in an alternating fashion between adjoining sides of the segmented wall, with comer block 790 included in the adjoining comer of the wall in the upper course or layer 762 in a first orientation and comer block 792 included in the adjoining comer of the wall in the upper course or layer 760 in a second orientation. For example, the comer block 792 may be positioned such that the long side is aligned with a first one of the adjoining walls and the comer block 790 may be positioned such that the long side is aligned with a second one of the adjoining walls.

The comer blocks 790 and 792 may include a pair of apertures 780 and 781 separated by a middle neck portion. In addition, the comer blocks 790 and 792 may include engagement protrusions (lugs) 782 and 784 protruding from the tops of the comer blocks 790 and 792. When place side-by-side, the pair lugs 782 and 784 protruding from the top of the comer block 790 may mirror the pair lugs 782 and 784 protruding from the top of the comer block 790. The lug 782 protruding from the tops of the comer blocks 790 and 792 may be horizontally -aligned with the rear of a respective one of the apertures 780 or 781 and may be positioned on an outside edge of the wall block near where the rear portion meets an outer neck portions. The lug 784 protruding from the tops of the comer blocks 790 and 792 may be positioned on a rear portion of the comer blocks 790 and 792 near a location where the other respective aperture 780 or 781 meets the middle neck portion. In some examples, the pair of lugs 782 and 784 may have different sizes and shapes. The lug 784 may be configured to interface with the rear face of the aperture 774 of a wall block 710 stacked on top of the comer block 792 (e.g., as shown with respect to comer block 792). The lug 782 may be configured to interface with the rear face of the aperture 780 of the comer block 790 stacked on top of the comer block 792 (e.g., as shown with respect to comer block 792). The implementation of the comer blocks 490 and 492 in comer wall applications may improve stability of the wall by tying both adjoining walls together at the comers. As the comer blocks 790 and 792 are covered with fill material, the interlocking between courses or layers 760, 762 may be further strengthened.

Figure 52 depicts a portion of a 90 degree inner comer segmented wall, with part of two courses 760, 762. The courses or layers 760, 762 may include at least one respective tail block 740 attached to (e.g., interlocked with) with a rear side of one or more of the respective set of wall blocks 710 in an alternating fashion between adjoining sides of the segmented wall, with comer block 790 included in the adjoining comer of the wall in the upper course or layer 762 in a first orientation and comer block 792 included in the adjoining comer of the wall in the upper course or layer 760 in a second orientation. For example, the comer block 792 may be positioned such that the long side is aligned with a first one of the adjoining walls and the comer block 790 may be positioned such that the long side is aligned with a second one of the adjoining walls. The lugs 782 and 784 of the comer blocks 790 and 792 engage with upper course comer blocks 790 and 792 similar to the engagement described with reference to Figure 51.

As shown in Figures 57-59, atop courses or layer 766 a segmented wall may be capped with a cap block course 768 of cap blocks 794. The walls depicted in Figures 57-59 include linear shapes, non-linear shapes, or combinations thereof formed using the wall blocks 710 and the tail blocks 740 and cap blocks 794 in accordance with embodiments of the disclosure. Figure 57 depicts a portion of a curved (e.g., concave) segmented wall, with the top course or layer 766 is capped with a cap block layer 768. The curvature of the wall in Figure 57 may be uniform and have a radius and an angle from a center of a wall block 710 to a space between the wall blocks 710. The cap blocks 794 may have a uniform size and shape. In some examples, the cap blocks 794 have a smaller, as installed, vertical height than the wall blocks 710. In some examples, a length of the cap blocks 794 may the same as a length of the wall blocks 710. The cap blocks 794 may have a first longer side that is parallel with a second longer side, and two opposing shorter sides that have a non-parallel relationship from the first long side to the second longer side. The length of the first longer side is greater than a length of the second longer side, and the opposing shorter sides may have equal lengths. A bottom side of the cap blocks 794 may include a cavity formed between the opposing shorter sides such that the height of the cap block 794 at the first and second longer sides is greater than a height at a middle of one of the opposing shorter sides. The rearward face of the cavity of the cap block 794 may be configured to engage with one or more of the pairs of lugs 776 and 778 on top of the wall blocks 710 to retain the cap block 794 in place. The converging, non-parallel relationship between the opposing shorter sides of the cap block 794 may allow various wall shape configurations, such as positioning the first longer side toward a front of a concave wall (as shown in Figure 57), positioning the second longer side toward a front of a convex wall (as shown in Figure 59), and alternating the first longer side and the second longer side for straight walls (as shown in Figure 59). The cap blocks 794 may be made of a rugged, weather resistant material, such as pre-cast concrete (e.g., dry cast or wet cast). Other suitable materials are plastic, reinforced fibers, wood, metal and stone.

In some examples, the wall system may further include use of reinforced earth techniques such as geogrid reinforcement, geosynthetic reinforcement, or the use of inextensible materials such as steel matrices. After placement of a course or layer of the wall, a geogrid material may be placed over the course or layer before placement of a next course or layer. The weight of the upper course or layer on the geogrid material sandwiched between two layers may hold the geogrid material in place. In some examples, additional pins, stakes, or other connectors in the wall block 710, the tail block 740, or the fill material may be use to penetrate the apertures of the geogrid material to further hold it in place. The use of the geogrid material may form a lateral interlocking connection between wall blocks and tail blocks of a course or layer, which may further fortify the segmented wall.

Figures 61-69 depict an eighth embodiment of a segmented wall system with tail blocks and inter-course or layer pin connections, in accordance with an embodiment of the present disclosure. The segmented wall system of Figures 61-69 may be formed using a combination of wall blocks and tail blocks, as shown. The wall blocks and the tail blocks of Figures 61 -69 include many similar features as the wall blocks 110 and 140 of Figures 1-7. Accordingly, a detailed description of the wall blocks and tail blocks are not included in the interest of brevity. Upon analysis of the Figures 61-69, one of skill in the art. would appreciate and understand the comrnone elements and the different elements in comparison to the wall and tail blocks described with reference to Figures 1-60.

Figures 70-82 depict method of manufacturing segmented wall blocks with lugs, in accordance with an embodiment of the present disclosure. In an example, the methods depicted in Figures 70-82 may depict a method of manufacturing the wall blocks with lugs depicted in Figures 47-59. The wall blocks being formed in Figures 70-82 include many similar features as the wall blocks of Figures 47-59. Many of those reference numbers are not repeated in Figures 70-82 in the interest of clarity and brevity. One of skill in the art would appreciate that those common elements exist as described with reference to Figures 47-59.

Typically, a wall block may be formed in a mold. Sidewalls of a mold may form the outer shape of the wall block. The sidewall portion of the mold may be positioned on a production pallet or board, and then filled with a material used to form the wall block (e.g., a concrete material, such as a dry-cast concrete material). A vertical cutoff bar may be pushed or pulled across a top portion of a mold to remove excess material. After the cutoff bar removes the excess material, a stripper shoe may be lowered onto the top of the mold to form a top surface of the block. The stripper shoe may apply a compression force to the top surface to compress the material within the mold to compact the material within the mold. After compression by the stripper shoe, the production pallet or board may be lowered to allow the formed block to slide out of the mold.

Figures 70-74 depict a cutoff bar 1220 progressively sliding across the top of a mold box 1206 for a first type of wall block. The cutoff bar 1220 pushes the excess material (e.g., depicted in brown color) across the top of the mold box 1206. Most of the bottom of the cutoff bar 1220 is straight and rigid, sliding across the top of the mold box 1206. However, the cutoff bar includes moveable portions 1222 that are configured to move over raised areas (e.g., lugs) to be formed in the top surface of the wall block. The movable portions 1222 may have a pivot points (e.g., shafts or pins) to allow the movable portion 1222 to be raised to allow material to be left for raised portions of the wall block. In addition, the movable portions 1222 may be weighted or may have tension mechanisms that apply downward force to allow the movable portion to push excess material across the top of the mold box 1206. The top of the mold box 1206 may include raised portions 1224 that allow excess fill material to be left behind for certain features to be formed in the top of the wall block, such as lugs or weight bearing pads. The movable portions 1222 of the cutoff bar 1220 and raised portions 1224 may be aligned such that when the cutoff bar 1220 is pushed or pulled across the top of the mold box 1206, the movable portions 1222 move over the raised portions 1224. It is appreciated that the example movable portions 1222 and the raised portions 1224 are exemplary, and that more or fewer of the movable portions 1222 and/or the raised portions 1224 may be included, the movable portions 1222 and/or the raised portions 1224 may be positioned, sized, or have different height than depicted, or any combination thereof, without departing from the scope of the disclosure. The movable portions 1222 of the cutoff bar 1220 may be segmented or split such that not all of the movable portion moves together.

The movable portions 1222 of the cutoff bar 1220 may have a different shape than the rounded shape. For example, the movable portions 1222 of the cutoff bar 1220 may have a polygon shape (e.g., triangle, rectangle, pentagon, hexagon, octagon, etc.). In another example, the movable portions 1222 of the cutoff bar 1220 may have a “T” or “Y” shape. In yet another example, the movable portions 1222 of the cutoff bar 1220 may have a hollowed-out area on one or both sides to form a sort of scoop to catch and remove material. In some examples, the movable portions 1222 of the cutoff bar 1220 may include a mechanism to apply downward force to return the movable portions 1222 of the cutoff bar 1220 to being in alignment with the fixed portion of the cutoff bar 1220 after a deflection, such as a spring or spring-like mechanism, ahydraulic, electrical, or pneumatic actuator, or any other type of mechanism capable of applying a downward force. In some example, the movable portions 1222 of the cutoff bar 1220 may also include a stopper or stopping mechanism to prevent the movable portions 1222 of the cutoff bar 1220 from rotating too far, such as setting a stopper to prevent the movable portions 1222 of the cutoff bar 1220 from rotating more than a predetermined height above the raised portions 1224.

In some examples, each of the movable portions 1222 of the cutoff bar 1220 may be configured to accommodate raised features on the wall block that are different heights and/or volumes. For example, as the cutoff bar 1220 moves across the top of the mold box and/or are discontinuous across the mold box 1206, a particular one of the movable portions 1222 may encounter a first one of the raised portions 1224 having a first height and may subsequently encounter a second one of the raised portions having a second height that is different than the first height. The first one of the raised features 1224 may correspond to a first raised feature of the wall block and the second one of the raised features 1224 may correspond to a second raised feature of the wall block that has a different corresponding volume or height when fully formed. The movable portions 1222 of the cutoff bar 1220 may encounter more than two raised features 1224 with more than two different heights without departing from the scope of the disclosure.

Figures 75-78 depict a cutoff bar 1220 progressively sliding across the top of a mold box 1206 for a second type of wall block. The stripper shoe 1220 pushes the excess material (e.g., depicted in brown color) across the top of the mold box 1206. Most of the bottom of the cutoff bar 1220 is straight and rigid, sliding across the top of the mold box 1206. However, the cutoff bar includes moveable portions 1222 that are configured to move over raised areas (e.g., lugs) to be formed in the top surface of the wall block. The movable portions 1222 may have a pivot points (e.g., shafts or pins) to allow the movable portion 1222 to be raised to allow material to be left for raised portions of the wall block. In addition, the movable portions 1222 may be weighted or may have tension mechanisms that apply downward force to allow the movable portion to push excess material across the top of the mold box 1206. The top of the mold box 1206 may include raised portions 1224 that allow excess fill material to be left behind for certain features to be formed in the top of the wall block, such as lugs or weight bearing pads. The movable portions 1222 of the cutoff bar 1220 and raised portions 1224 may be aligned such that when the cutoff bar 1220 is pushed or pulled across the top of the mold box 1206, the movable portions 1222 move over the raised portions 1224. It is appreciated that the example movable portions 1222 and the raised portions 1224 are exemplary, and that more or fewer of the movable portions 1222 and/or the raised portions 1224 may be included, the movable portions 1222 and/or the raised portions 1224 may be positioned, sized, or have different height than depicted, or any combination thereof, without departing from the scope of the disclosure. The movable portions 1222 of the cutoff bar 1220 may have a different shape than the rounded shape. For example, the movable portions 1222 of the cutoff bar 1220 may have a polygon shape (e.g., triangle, rectangle, pentagon, hexagon, octagon, etc.). In another example, the movable portions 1222 of the cutoff bar 1220 may have a “T” or “Y” shape. In yet another example, the movable portions 1222 of the cutoff bar 1220 may have ahollowed-out area on one or both sides to form a sort of scoop to catch and remove material. In some examples, the movable portions 1222 of the cutoff bar 1220 may include a mechanism to apply downward force to return the movable portions 1222 of the cutoff bar 1220 to being in alignment with the fixed portion of the cutoff bar 1220 after a deflection, such as a spring or springlike mechanism, a hydraulic, electrical, or pneumatic actuator, or any other type of mechanism capable of applying a downward force. In some example, the movable portions 1222 of the cutoff bar 1220 may also include a stopper or stopping mechanism to prevent the movable portions 1222 of the cutoff bar 1220 from rotating too far, such as setting a stopper to prevent the movable portions 1222 of the cutoff bar 1220 from rotating more than a predetermined height above the raised portions 1224. In some examples, each of the movable portions 1222 of the cutoff bar 1220 may be configured to accommodate raised features on the wall block that are different heights and/or volumes. For example, as the cutoff bar 1220 moves across the top of the mold box and/or are discontinuous across the mold box 1206, a particular one of the movable portions 1222 may encounter a first one of the raised portions 1224 having a first height and may subsequently encounter a second one of the raised portions having a second height that is different than the first height. The first one of the raised features 1224 may correspond to a first raised feature of the wall block and the second one of the raised features 1224 may correspond to a second raised feature of the wall block that has a different corresponding volume or height when fully formed. The movable portions 1222 of the cutoff bar 1220 may encounter more than two raised features 1224 with more than two different heights without departing from the scope of the disclosure.

Figures 79 and 80 depict a stripper shoe 1010 configured to compress material 1004 in a mold box (not shown) for a first type of wall block. The stripper shoe 1010 includes multiple movable mechanical mechanisms that operate up and down by gravity with the compaction and stripping cycle of the production machine 1012 that are configured to form raised areas (e.g., lugs or other raised areas) on the top of the wall block. The movable mechanical mechanisms that operate up and down by gravity with the compaction and stripping cycle of the production machine 1012 include movable portions (e.g., red and yellow blocks) that slide along pins that to move a bottom surface (e.g., of the red block) in contact with the wall block material 1004 higher than the bottom surface of a main portion of the stripper shoe 1010 in contact with the wall block material during compression. The light pink block provides a stopper to set an upper limit for the movable portions. When the stripper shoe 1010 is raised after compression, the movable mechanical mechanisms that operate up and down by gravity with the compaction and stripping cycle of the production machine 1012 may slide down along the pins to lower the bottom portion to be in alignment with the rest of the stripper shoe 1010. The dark purple blocks provide a lower stop for the movable portions to align the bottom surfaces of the movable portion and the bottom surface of the stripper shoe 1010. In between block formation, the bottom portion of the stripper shoe may be scraped or brushed off to prevent material stuck on the stripper show from forming defects in subsequent blocks. The movable mechanical mechanisms that operate up and down by gravity with the compaction and stripping cycle of the production machine 1012 being able to move down for the cleaning may prevent material from being stuck up in the raised portion during this cleaning process.

Figures 81 and 82 depict a stripper shoe 1010 configured to compress material 1004 in a mold box (not shown) for a second type of wall block. The stripper shoe 1010 includes multiple movable mechanical mechanisms that operate up and down by gravity with the compaction and stripping cycle of the production machine 1012 that are configured to form raised areas (e.g., lugs or other raised areas) on the top of the wall block. The movable mechanical mechanisms that operate up and down by gravity with the compaction and stripping cycle of the production machine 1012 include movable portions (e.g., red and yellow blocks) that slide along pins that to move a bottom surface (e.g., of the red block) in contact with the wall block material 1004 higher than the bottom surface of a main portion of the stripper shoe 1010 in contact with the wall block material during compression. The light pink block provides a stopper to set an upper limit for the movable portions. When the stripper shoe 1010 is raised after compression, the movable mechanical mechanisms that operate up and down by gravity with the compaction and stripping cycle of the production machine 1012 may slide down along the pins to lower the bottom portion to be in alignment with the rest of the stripper shoe 1010. The dark purple blocks provide a lower stop for the movable portions to align the bottom surfaces of the movable portion and the bottom surface of the stripper shoe 1010. In between block formation, the bottom portion of the stripper shoe may be scraped or brushed off to prevent material stuck on the stripper show from forming defects in subsequent blocks. The movable mechanical mechanisms that operate up and down by gravity with the compaction and stripping cycle of the production machine 1012 being able to move down for the cleaning may prevent material from being stuck up in the raised portion during this cleaning process.

Although the detailed description describes certain preferred embodiments and examples, it will be understood by those skilled in the art that the scope of the disclosure extends beyond the specifically disclosed embodiments to other alternative embodiments and/or uses of the embodiments and obvious modifications and equivalents thereof. In addition, other modifications which are within the scope of the disclosure will be readily apparent to those of skill in the art. It is also contemplated that various combination or sub-combination of the specific features and aspects of the embodiments may be made and still fall within the scope of the disclosure. It should be understood that various features and aspects of the disclosed embodiments can be combined with or substituted for one another in order to form varying mode of the disclosed embodiments. Thus, it is intended that the scope of at least some of the present disclosure should not be limited by the particular disclosed embodiments described above.