BR102013011258A2 - erosion control blanket system - Google Patents

Abstract

erosion control blanket system. The invention relates to an erosion control blanket providing a plurality of concrete blocks. each block has an upper portion with a plurality of upper inclined sidewalls. each block has a lower bottom portion with a plurality of inclined lower side walls the block has an upper surface and a lower surface and a block periphery in the form of an edge where the upper and inner side walls meet. cables or ropes connect the blocks together to form a block matrix and erosion control blanket. each block has a boot affixed to the lower block portion, the boot having a plurality of inclined side panels. Each side panel has an upper edge. the boot has a lower panel, an inner boot surface and an inner urn that is receptive to at least part of the lower block portion. boot inclined side panels engage block inclined lower side walls. the bottom boot panel engages the bottom block surface. A plurality of anchor posts are attached to the inner surface of the boot, some of the anchor posts are attached to the side wall panels to allow a connection to be formed between the inclined boot side panels and the inclined lower block side walls. Some of the anchor posts are secured to the bottom boot panel to allow a connection to be formed between the bottom boot panel and the bottom block surface. as part of the method. The boot is first placed inside a mold. The slurry concrete is then added to the mold so that a connection is formed between the boot anchor posts and the concrete when the concrete hardens after a period of time.

Description

Report of the Invention Patent for "Erosion Control Mantle System".

CROSS REFERENCE TO REQUESTS

This is a non-provisional patent application from US Provisional Patent Application Serial Number 61 / 617,509, filed March 29, 2012; and US Provisional Patent Application Serial Number 61 / 721,337, filed November 1, 2012. The priority of US Provisional Patent Application Serial Number 61 / 617,509, filed March 29, 2012; and U.S. Provisional Patent Application Serial No. 61 / 721,337, filed November 1, 2012, each of which is hereby incorporated by reference is hereby claimed.

BACKGROUND OF THE INVENTION FIELD OF THE INVENTION The present invention relates to blankets used for erosion control, pipeline protection, intersections, and many other underwater uses, and methods for installing such blankets. More specifically, the present invention relates to an improved mat and a manufacturing method wherein a specially configured mold provides concave and convex sides, the concave side providing a plurality of inclined surfaces, each having one or more anchors and wherein the convex side provides hemispherically formed projections which extend over a bottom surface of the mold, the mold being configured to accept a cement fill to form a block and wherein the blocks may be connected with cables or ropes to form a blanket.

GENERAL BACKGROUND OF THE INVENTION

Erosion control blankets have been used for many years to protect soil surfaces such as banks of water bodies (lakes, rivers, etc.).

Another example of an erosion control blanket is Pilaar's patent (3,597,928). The Pilaar patent refers to an erosion control protective surface for a soil mass. The device includes a flexible support plate that can conform to the ground contour and blocks that are mounted on the support plate. The blanket provides drainage passages therethrough so that water can pass through the liner. Preferably, the liner includes a filter and the blocks are secured with the support plate. Nelson's patent (3,386,252) shows a twisting structure that employs concrete blocks connected together.

Cables are employed to secure the blocks together in Landry's patent (4,227,829) to form a matrix. Crow's patent (4,375,928) shows rows of blocks held together by a continuous cable which is embedded in each block. Waters patent (4,683,156) shows a segment erosion control blanket. The segments are said to be of concrete placed inside casings. The segments are attached together with a rope net. Openings in the enclosures provide entry points for the strings. Rudloff's patent (5,484,230) provides a concrete block coating system for preventing soil erosion. Rudloff's patent system provides concrete blocks that are interconnected by cable to form a matrix. The block matrix overlaps and holds in place a layer of permeable geotextile overlapping a protected soil area. Angel patent (6,027,285) entitled "Blanket Installation" shows cable-connected erosion control trunks that can be used over pipelines. Other patents issued to Angel include 5,722,795; 5,846,023; and 5,944. 449. Landry patent (4,486,120) provides an expander bar for the installation of soil erosion prevention blankets Daniel's patent (6,406,217) provides a lifting and placing device for seafloor blankets.

Other patents possibly relevant to the construction and use of erosion control blankets, pipeline protection, intersections, and many other underwater uses can be seen in the following table, the listing being chronological and otherwise meaningless. Each of the patents listed in the table is hereby incorporated by reference herein.

The following US Patents are incorporated herein by reference: BRIEF SUMMARY OF THE INVENTION The present invention provides an improved blanket for erosion control, pipeline protection, intersections, and many other underwater uses, which utilize a plurality of concrete blocks, each block having an upper portion with a plurality of inclined side walls and a lower portion with a plurality of inclined lower side walls. The block provides an upper surface and a lower surface and a block periphery in the form of a block edge where the upper and lower side walls meet.

Cables or ropes, more specifically copolymer rope, connect the blocks together to form a matrix. The cables or ropes may include multiple cables or ropes or a continuous cable / rope that is braided from a block row or a block column to the next block column.

Each block has a boot affixed to the lower block portion. The boot has a plurality of inclined side panels, each side panel having an upper edge. The boot has a bottom panel and an inner surface. The boot has an interior that is receptive to at least part of the lower block portion.

The inclined boot side panels engage the inclined lower block sidewalls. The bottom boot panel engages the bottom block surface. The boot has a plurality of anchor posts attached to the inner surface of the boot. These anchor posts include some anchor posts attached to the boot side wall panels. This first plurality of anchor posts allows a connection to be formed between one or more of the boot inclined side panels and the block lower side walls.

Some of the anchor posts are attached to the bottom boot panel. This second plurality of anchor posts allows a connection to be formed between the bottom boot panel and the bottom block surface.

This improved boot arrangement solves the detachment problem that may occur during the positioning of the blankets because they are often lowered to a pipeline resting on a seabed. Mechanical interaction between the blanket and the pipeline can dislodge the boots resulting in the end of complete pipeline protection.

In one embodiment, a plurality of anchor posts have central longitudinal geometric axes that are parallel.

In one embodiment, the bottom boot panel has a plurality of projections. In one embodiment, projections are hemispherically formed.

In one embodiment, there is a concavity over the inner surface of the bottom boot panel near each projection. Thus, when the boot is placed inside a mold and a slurry concrete added to the mold, the slurry concrete not only fills the interior of the boot but also the concavities behind each projection, thereby further reinforcing the projections during casting. use.

In one embodiment, at least some of the boot side panels have two or more anchor posts. In another embodiment, each side panel has two or more anchor posts.

In one embodiment, the anchor posts do not extend beyond the upper edges of the boot.

In one embodiment, the upper edges of the boot sidewall do not extend above the block edge.

In one embodiment, the upper boot edges are positioned below the cords / ropes. The present invention provides a method for constructing a blanket. The method includes providing a mold apparatus that includes multiple molds.

A boot is placed within each mold, each boot has a plurality of boot anchor posts, a plurality of inclined side panels, each side panel having an upper edge, the boot having a lower panel, an inner boot surface and a interior or boot cavity that is receptive to a slurry concrete that can be added to the interior of the mold after the boot is placed inside the mold.

In a preferred embodiment, the outer surface of the boot and the inner surface of the mold are correspondingly formed in at least the lower half of the mold.

As part of the method, the mold is filled with slurry concrete after the boot is placed into the mold. Pasted concrete hardens after a period of time to form a plurality of concrete blocks. Each block has an upper portion with a plurality of inclined side walls and a lower portion with a plurality of inclined lower side walls. The block has an upper surface, a lower surface and a block periphery in the form of a block edge where the upper and lower block side walls meet.

Before the time period expires, one or more cables / strings are placed into the molds so that after the time period expires, the cable / rope or cables / strings connect the blocks together to form a block matrix which forms a blanket.

A connection is formed from the boot to the slurry concrete after the time period has expired using a plurality of anchor posts that extend from the boot to the slurry concrete. The plurality of anchor posts are attached to the inner surface of the boot. Some anchor posts are attached to the sidewall panels to allow a connection to be formed between the boot inclined side panels and the inclined block bottom sidewalls.

Some of the anchor posts are attached to the bottom panel to allow a connection to be formed between the bottom boot panel and the bottom block surface. In a preferred method, the bottom boot panel has a plurality of projections.

In one embodiment, there is a concavity over the inner surface of the boot bottom panel in each projection. This concavity is filled with slurry concrete as part of the method.

BRIEF DESCRIPTION OF VARIOUS VIEWS OF DRAWINGS

For a further understanding of the nature, objects, and advantages of the present invention, reference should be made to the following detailed description, read in conjunction with the following drawings, wherein like reference numerals denote like elements and wherein: Figure 1 is a perspective view of a preferred embodiment of the apparatus of the present invention.

Figure 2 is a side sectional view of a preferred embodiment of the apparatus of the present invention taken along lines 2-2 of Figure 1;

Figure 3 is a side sectional view of a preferred embodiment of the apparatus of the present invention taken along lines 3-3 of Figure 1;

Figure 4 is a top view of a preferred embodiment of the apparatus of the present invention;

Figure 5 is a side view of a preferred embodiment of the present invention;

Figure 6 is a fragmentary side elevation view of a preferred embodiment of the apparatus of the present invention;

Figure 7 is a fragmentary side elevation view of a preferred embodiment of the apparatus of the present invention;

Figure 8 is a perspective view of another embodiment of the present invention;

Figure 9 is a bottom view of the embodiment of Figure 8;

Figure 10 is a top view of an alternative embodiment of the apparatus of the present invention;

Figure 11 is a side view of an alternative embodiment of the apparatus of the present invention taken along lines 11-11 of Figure 10;

Figure 12 is a side sectional view of an alternative embodiment of the apparatus of the present invention taken along lines 12-12 of Figure 10;

Figure 13 is a perspective top view of an alternative embodiment of the apparatus of the present invention;

Figure 14 is a fragmentary perspective view of a preferred embodiment of the apparatus of the present invention showing the mold;

Figure 15 is a fragmentary perspective view of a preferred embodiment of the apparatus of the present invention showing the mold;

Figure 16 is a fragmentary perspective view of a preferred embodiment of the apparatus of the present invention showing the mold;

Figure 17 is a fragmentary perspective view of a preferred embodiment of the apparatus of the present invention showing the mold;

Figure 18 is a fragmentary perspective view of a preferred embodiment of the apparatus of the present invention showing the mold;

Figure 19 is a perspective view of a preferred embodiment of the apparatus of the present invention showing interconnecting blocks and ropes;

Figure 20 is a perspective view of a preferred embodiment of the apparatus of the present invention showing interconnecting blocks and ropes;

Figure 21 is a perspective view of a preferred embodiment of the apparatus of the present invention showing interconnecting blocks and ropes;

Figure 22 is a top view of another alternative embodiment of the apparatus of the present invention;

Figure 23 is a side view of another alternative embodiment of the apparatus of the present invention taken along lines 23-23 of Figure 22;

Figure 24 is a side cross-sectional view of another alternative embodiment of the apparatus of the present invention taken along lines 24-24 of Figure 22; and Figure 25 is a perspective top view of another alternative embodiment of the apparatus of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

Figures 1-7 show a preferred embodiment of the apparatus of the present invention which is generally designated by the number 10. Blanket apparatus 10 employs a boot 11a which may be placed within a mold 50 prior to the addition of a wet concrete mixture. or in folder. Once the concrete mix cures or hardens, the blocks are formed. The mold 50 provides halves 51, 52 and rope or cable opening 53. Openings 53 allow a rope or cable, such as a copolymer rope, a steel cable or any other selected rope or connecting cable, to be used. for connecting the concrete or cast blocks 43. The blocks 43 are preferably of a concrete material which is initially a paste added to the molds 50 and allowed to harden with the connecting rope 42 in place (see Figure 18). After the concrete hardens, an erosion control mat 10 is formed of individual blocks 43 connected by rope 42 (see Figures 19-21). Boot 11 is a liner that is placed within lower half 52 of mold 50. Boot 11 then becomes a cover, liner or boot for a lower part of block 43 after the concrete or cement filler has hardened or heal. As seen in Figure 17, the rope or cable 42 runs through each block 43 in two directions, each such rope or cable perpendicular to the other within a given block 43. Mold 50 may include multiple mold cavities 58, one cavity forming a block 43. An upper opening 54 allows slurry or wet concrete to enter. The rope or cable 42 may be of any material such as a steel rope, a polymeric rope, a copolymer rope, or any other elongated traction material.

In Figures 1-5, boot 11 has a panel 12 which may be characterized with a bottom panel. The boot can be approximately 25.2 cm -25.7 cm (9 15/16 "-10 1/8") in length approximately 25.2 cm -25.7 cm (9 15/16 "-10 1/8") ") wide and approximately 7.6 cm (3") high. Panel 12 can be approximately 15.9 cm (6 1/4 ") wide and approximately 15.9 cm (6 1/4") The bottom surface of the panel 12 is provided with a plurality of projections 13 which are disposed in a web Projections 13 may be hemispherically formed projections as seen in Figures 2-3, 5. The projection network or projections The hemispherical 13 may thus include a plurality of projection rows 14 and a plurality of projection columns 15. In Figures 1-5, six projection rows 14 and six projection columns 15 can be seen to form the projection network 13. Projections 13 may be located approximately 2.5 cm (1 ”) apart from each other on panel 12. Projections 13 located closest to edges of panel 12 may be located approximately 1.6 cm (5/8 ") from the edge of panel 12. Projections 13 may extend approximately 0.6 cm (1/4") from the bottom surface of panel 12 and may be approximately 1/2 "(1.3 cm) wide. Boot 11 includes a plurality of inclined side walls 24, 25, 26, 27. As shown in Figures 1-5, each inclined side wall 24, 25, 26, 27 is joined to panel 12 and the other side walls. The combination of bottom panel 12 and slanted side panels 24, 25, 26, 27 may be a one piece plastic boot 11 such as an integral injection molded part.

A plurality of generally cylindrically formed posts or anchors 16 are attached to the inner surface of panel 12 as seen in Figures 1-4. Each of the posts or anchors 16 (see Figure 7) may provide a generally cylindrically formed sidewall 17 (approximately 1 1/4 ") in length, an upper end portion 22 (approximately 1.0 cm (3/8 ”) wide) and a lower end portion 23 (approximately 2.7 cm (1 1/16") wide). The lower end portion 23 may be flat and circular where the anchor or post 16 is joined to panel 12. The upper end portion 22 of each post 16 may provide a recess or concavity 18, a projecting portion 19, and curved surfaces in 20 (which has a radius of curvature of 0.3 cm (1/8 ")), 21 (which has a radius of curvature of 0.6 cm (1/4")). Figure 6 shows a post or anchor 28. A post or anchor 28 is attached to a slanted wall or side panel 24, 25, 26, 27. In a preferred embodiment, multiple of panels 24, 25, 26, 27 have posts 28 Each post 28 has a generally cylindrically formed sidewall portion 29, a diagonally or inclined extending surface 36, and end portions 34, 35. The end portion 35 provides the diagonally or inclined extending surface 36. pole or anchor 28 may be approximately 1.3 cm (1/2 ") wide. End portion 34 may be approximately 0.6 cm (1/4") wide.

As with post 16, post 28 provides end portion 34 having a recess or concavity 30, a projecting portion 31, and curved surfaces at 32 (having a radius of curvature of 0.2 cm (1/16 ") ), 33 (which has a radius of curvature of 0.5 cm (3/16 ")). In the embodiment shown, each of the posts 16 has a central longitudinal geometrical axis that forms a right angle or 90 degrees with the panel 12 as shown in Figures 4, 7. The central longitudinal geometrical axes of the poles 16, 28 may be parallel.

In the embodiment shown in Figures 1 and 4, panel 12 provides five posts 16. Each of the slanted side walls or panels 24, 25, 26, 27 provides a pair of posts 28. Each post or anchor 28 has a central longitudinal geometrical axis. which forms an acute or obtuse angle with the panel 24, 25, 26, 27 to which it is attached. Post 28 may be approximately 1.3 cm (1/2 ") in diameter and approximately 4.3 cm (11/16") in length. Post 16 may be approximately 1/4 "(1.9 cm) in diameter and approximately 1/4" (3.2 cm) in length.

Each sloping wall or side panel 24, 25, 26, 27 provides an upper edge which defines the top of the boot 11. These edges can be seen in Figure 4 as edges 37, 38, 39, 40. The edges 37, 38, 39.40 may be approximately 25.2 cm - 25.7 cm (9 15/16 "- 10 1/8") in length. In a preferred embodiment, the top of each post or anchor 16, 28 is at or below the edges 37, 38, 39, 40. Boot 11 provides a cavity 41 which is receptive to wet or slurry concrete or other filler. which fills cavity 58 of mold 50 to form a final block 43 of erosion control mat 10.

In Figures 14-19, the mold or molds 50 may be shown in more detail. Lugs 55 may be used to lift and transport the molds 50. Each mold 50 may provide an upper mold half 51 and a lower mold half 52. The mold halves 51, 52 each provide semicircular openings such that when the two mold halves 51, 52 are mounted, a rope opening 53 is provided. Preferably, there are four rope openings 53 spaced an equal distance around the periphery of mold cavity 58 as shown. In Figures 16-18, the rope or other cable 42 may be shown inserted through the rope openings 53 and interconnecting the blocks 43. Since the molds 51, 52 are filled with concrete in their slurry or wet form the ropes 42 are encapsulated with concrete. Connection members 57 may be used to help keep molds 50 at the correct spacing. Each mold 50 thus provides a mold cavity 58 which defines the overall shape of each block 42, the final block shape 42 seen in Figures 19-21. Figures 17-19 show the mold cavities 58 and the multiple cavity mold assembly 56. Each block 43 has a periphery 44 and an upper block section 45 and a lower block section 46. The boot 11 would thus be placed in. of the lower half 52 of the mold 50 before the slurry in its wet form is added to the mold 50 through the upper opening concrete inlet 54. The concrete not only fills the mold cavity 58 but also fills the cavity 41 of the boot 11 Hemispherically formed concavities 59 may be provided, one for each projection or hemispherical projection 13. These hemispherically formed concavities 59 would also be filled with concrete when the slurry or liquid concrete mixture is added to the interior or cavity 58 of the mold 50. 11 including the panel 12, the panels 24, 25, 26, 27, the post 16, the posts or anchors 28, and the projecting hemispheric projections 13 may be a movable member. Injection by one piece injection.

Another boot or alternative is shown in Figures 8-9, designated by the numeral 60. The boot 60 may be approximately 25.2 cm -25.7 cm (9 15/16 "- 10 1/8") long, approximately 25, 2 cm -25.7cm (9 15/16 "- 10 1/8") wide, and approximately 7.6 cm (3 ") high. In Figures 8-9, the boot 60 has a panel 60 has a panel 61 which may be characterized as a wall or back panel. Panel 61 may be approximately 6 1/4 "wide and approximately 15 1/4" long. The bottom surface of the panel 61 is provided with a plurality of projections 62 which are disposed in a net (see Figures 8-9) .The projections 62 may be hemispherically formed projections as seen in Figure 9. The projection network or hemispherical projections 62 may thus include a plurality of projection rows 63 and a plurality of projection columns 64. In Figures 8-9, six projection rows 63 and six columns can be seen 64 to form the projection net 62. Projections 62 may be located approximately 2.5 cm (1 ") apart from each other over panel 61. Projections 62 may extend approximately 0.6 cm (1/4" ) of the bottom surface of panel 61 and may be approximately 1.3 cm (1/2 ") wide. Boot 60 includes a plurality of inclined sidewalls 73-76. As shown in Figures 8-9, each inclined sidewall 73-76 is joined to panel 61 and the other sidewalls. The combination of bottom panel 61 and slanted side panels 73-76 may be a one piece plastic boot 60 such as an injection molded integral part.

A plurality of generally cylindrically formed posts or anchors 16 are secured to the inner surface of the panel 61 as seen in Figure 8. The posts or anchors 16 attached to the boot 60 may be configured as seen in Figure 7. One or more posts or anchors 28 are secured to a slanted wall or side panel 73-76. The posts or anchors 28 attached to the boot 60 may be configured as seen in Figure 6. In a preferred embodiment, multiples of panels 73-76 have posts 28.

In the embodiment shown in Figures 8-9, each of the posts 16 has a central longitudinal geometrical axis that forms a right angle or 90 degrees with the panel 61. The central longitudinal geometrical axes of the posts 16, 28 may be parallel.

In the embodiment shown in Figures 8-9, panel 61 provides five posts 16. Each of the sloping sidewalls or panels 73-76 provides a pair of posts 28 as seen in Figure 8. Each post or anchor 28 has a longitudinal geometric axis. that forms an acute or obtuse angle with the panel 73-76 to which it is attached. Posts 16 may be approximately 1.9 cm (3/4 ”) in diameter and approximately 3.2 cm (1 1/4") in length. Posts 28 in Figures 8-9 may be approximately 1.3 cm ( 1/2 ") in diameter and approximately 3.3 cm (1 5/16") in length.

Each sloping wall or side panel 73-76 provides an upper edge which defines the top of boot 60. These edges 86-89 can be seen in Figure 8 as edges 86-89. In a preferred embodiment, the top of each post or anchor 16, 28 is at or below the edges 86-89. The boot 60 provides a cavity 90 which is receptive of wet or slurry concrete or other suitable filler which fills the cavity 58 of the mold 50 and the cavity 90 to form a final block 43 of the mat 10. mold 58 is thus equipped with a boot 60 before the slurry concrete is added.

In Figures 8 and 9, there is provided a plurality of projecting lips projecting into the upper edges 86-89 of the inclined side walls 73-76. The inwardly extending lips 91-94 are spaced from recesses, concavities or corrugations 100, 101 which are on opposite sides of each corner 95, 96, 97, 98. Each corner 95-98 includes a curved sidewall 99 and is between two recesses, concavities or corrugations 100, 101. As seen in Figures 8 and 9, each of the recesses, concavities or corrugations 100, 101 has a larger upper end portion 102 and a smaller lower end portion 103. The cross section of each recess or concavity 100, 101 gradually decreases between the upper end portion 102 and the lower end portion 103 as shown in Figures 8 and 9.

The inwardly projecting lips 91-94 help strengthen or stiffen the sidewalls 73-76, preventing them from flexing. If the sidewalls 73-76 flex inwards, concrete can easily flow over the side of the boot 60 and compromise the protection that the boot provides.

Corners 95-98 are provided with recesses at 100, 101 to allow sidewalls 73-76 to bend in and out. The design of each corner 95-98 with recesses at 100, 101 provides some flexibility for the sidewalls if the height of the individual block 43 changes such as, for example, from 22.9 cm to 30.5 cm (9 " to 12 "). Thus, the angle assumed by each of the outer walls changes as the height of the block 43 changes. "Tuned" corners provide this flexibility.

Figures 10-13 show an additional embodiment of the apparatus of the present invention in the form of an alternate boot or block, designated by the numeral 104. The boot or block 104 may be used in place of the boot 11, together with the boot 11 to have both upper and lower surfaces of a non-abrasive nature, or boot or block 104 may be used at both the top and bottom to provide non-abrasive surfaces on both sides. Boot or block 104 is similar to boot 11, but does not have the sloped side walls of boot 11. Boot or block 104 may be approximately 22.2 cm (8 3/4 ") long and approximately 22.2 cm ( 8 3/4 ") wide. Boot or block 104 has a panel 105 with an upper surface 106 and a lower surface 107. The lower surface 107 may be approximately 21.6 cm (8 1/2 ") long and approximately 21.6 cm (8 1 / 2 ") wide. Panel 105 may have an edge portion 119 and a base portion 120 (see Figure 12). Edge portion 119 may be approximately 0.3 cm (1/8 ") thick. Base portion 120 may be approximately 0.3 cm (1/8") thick. Boot or block 104 has a periphery 108 including edges 109-112. Each edge 109-112 has a beveled or slanted surface. Edge 109 has a chamfered or inclined surface 113. Edge 110 has chamfered or inclined surface 114. Edge 111 has chamfered or inclined surface 115. Edge 112 has chamfered or inclined surface 116. Surface 106 has a plurality (e.g., five (5) as shown in Figure 10) of posts or anchors 16. The posts or anchors 16 may thus be configured as shown in Figure 7. In Figures 10-13, the four posts or anchors 16 which are located near the edges of the panel 105 may each be located approximately 2/8 "(6.0 cm) from the edges of panel 105. The posts or anchors 16 may extend approximately 3.5 cm (1 3/8") from the surface bottom 107 of panel 105. The bottom surface 107 has rows 117 and projection columns 118 (for example, six (6) projections 13 in each row 117 and six (6) projections 13 in each column 118). Projections 13 may be located approximately 2.5 cm (1 ”) apart from each other over panel 105. Projections 13 located closest to the edges of panel 105 may be located approximately 4.4 cm (1 3/4") projections 13 may extend approximately 1/4 "(0.6 cm) from the bottom surface of panel 105. As with the preferred embodiment and boot 11, the boot or block 104 is a liner that is It is placed within the lower half 52 of the mold 50. The boot or block 104 then becomes a cover, lining or boot for a lower part of the block 43 after the concrete or cement filler has hardened or cured. Optionally, boot 104 may be placed on upper half 51 of mold 50 and lower half 52. Optionally, boot 104 may be placed within upper half 51 of mold 50 when boot 11 is placed within lower half 52.

Figures 22-25 show an additional embodiment of the apparatus of the present invention in the form of another alternative boot or block designated by the numeral 130. The boot or block 130 may be used in place of the boot 11 or block 104 together with the boot 11 to have both upper and lower surfaces of a non-abrasive nature, or the boot or block 130 may be used at both the top and bottom to provide non-abrasive surfaces on both sides. Boot or block 130 is similar to boot 11 but does not have the slanted side walls of boot 11. Boot or block 130 can be approximately 6 1/4 "long and approximately 15.9 cm (6"). 1/4 ") wide. The boot or block 130 has a panel 131 with an upper surface 132 and a lower surface 133. The lower surface 133 may be approximately 13.3 cm (5 1/4 ") long and approximately 13.3 cm (5 1 / 4 ") wide. Panel 131 may have an edge portion 134 and a base portion 135 (see Figure 24). Edge portion 134 may be approximately 0.6 cm (1/4 ") thick. Base portion 135 may be approximately 0.3 cm (1/8") thick. Boot or block 130 has a periphery 136 including edges 137-140. Each edge 137-140 has a beveled or slanted surface. Edge 137 has a beveled or inclined surface 141. Edge 138 has a beveled or inclined surface 142. Edge 139 has a beveled or inclined surface 143. Edge 140 has a beveled or inclined surface 144. Surface 132 has a plurality (e.g., five (5) as shown in Figures 22, 25) of posts or anchors 147. Posts 147 have an upper end portion 148 and a lower end portion 150. The upper end portion 148 of each post 147 may provide a recess or recess 151, a projecting portion 152, and curved surfaces at 153 (which has a curvature radius of 0.9 cm (3/8 ")), 154 (which has a curvature radius of 0.6 cm (1/4 ")). In Figures 22-25, the four posts or anchors 147 that are located near the edges of the panel 131 can each be located approximately 1/8 "(2.9 cm) from the edges of the panel 131. Posts or anchors 147 in the Figures 22-25 may be approximately 4.4 cm (1 3/4 ") long and approximately 1.3 cm (1/2") wide. The upper end portion 148 of post 147 may be approximately 1.1 cm (7/16 ”) wide and the lower length 149 below the recess 151 of post 147 may be approximately 2.5 cm (1") long. The bottom surface 133 has rows 145 and projection columns 146 (for example, five (5) projections 13 in each row 145 and five (5) projections 13 in each column 146). The projections 13 may be located approximately 2.5 cm (1 ") apart from each other on the panel 131. The projections 13 located closest to the bottom surface edges 133 may be located approximately 1.6 cm (5/8") projections 13 may extend approximately 0.6 cm (1/4 ") from the bottom surface of panel 131. Panel 131 has a plurality (e.g., how much (4) as shown in Figures 22 and 25) of holes 155. The holes 155 extend through the panel 131 from the upper surface 132 to the lower surface 133 of block 130. As with the preferred embodiment and boot 11, the boot or block 130 is a liner that is placed within the lower half 52 of mold 50. Boot or block 130 then becomes a cover, lining or boot for a lower part of block 43 after the concrete or cement filler has hardened or cured. placed in half upper 51 of mold 50 and lower half 52. Optionally, block 130 may be placed within upper half 51 of mold 50 when boot 11 is placed within lower half 52. The following is a list of suitable parts and materials for use in the present invention.

LIST OF PIECES

PART NUMBER DESCRIPTION 10 blanket device 11 boot 12 panel / back wall 13 projection / hemispherical projection 14 projection row 15 projection column 16 post / anchor 17 cylindrical sidewall 18 recess / concavity 19 projecting surface 20 curved surface 21 curved surface 22 end portion 23 end portion 24 slanted wall / side panel 25 slanted wall / side panel 26 slanted wall / side panel 27 slanted wall / side panel 28 post / anchor 29 cylindrical side wall 30 recess / concavity 31 projecting position 32 curved surface 33 curved surface 34 end portion 35 end portion 36 diagonal / inclined surface 37 edge 38 edge 39 edge 40 edge 41 boot cavity 42 handle / rope / copolymer rope 43 block 44 periphery 45 upper block section 46 lower block section 50 mold 51 half mold 52 half mold 53 rope opening 54 top opening / tapping inlet creto 55 eyelet 56 multi-cavity mold assembly 57 connecting members 58 mold cavity 59 concavity 60 boot 61 panel / bottom wall 62 projection / hemispherical projection 63 projection row 64 projection column 73 wall / inclined side panel 74 wall / inclined side panel 75 inclined side panel 76 inclined side panel 76 inclined side panel 86 edge 87 edge 88 edge 89 edge 90 boot cavity 91 protruding lip in 92 protruding lip in 93 protruding lip in 94 protruding lip in 95 corner 96 corner 97 corner 98 corner 99 curved sidewall 100 recess / concavity / corrugation 101 recess / concavity / corrugation 102 major upper end of recess 103 lower upper end of recess 104 boot / block 105 panel 106 upper surface 107 lower surface 108 periphery 109 edge 110 edge 111 edge 112 edge 113 beveled / inclined surface 114 beveled / inclined surface 115 surface chamfered / inclined face 116 chamfered / inclined surface 117 projection row 118 projection column 119 edge portion 120 base portion 130 boot / block 131 panel 132 upper surface 133 bottom surface 134 edge portion 135 base portion 136 edge 137 edge 138 edge 139 edge 140 edge 141 beveled / inclined surface 142 beveled / inclined surface 143 beveled / inclined surface 144 beveled / inclined surface 145 projection row 146 projection column 147 post / anchor 148 upper end portion 149 lower post length 150 portion of lower end 151 recess / concavity 152 projecting portion 153 curved surface 154 curved surface 155 hole All measurements described herein are at standard sea level and pressure, unless otherwise stated. All materials used or intended for use in a human being are biocompatible unless otherwise indicated.

The above embodiments are given by way of example only; The scope of the present invention should be limited only by the following claims.

Claims (20)

1. Erosion control blanket comprising: a) a plurality of concrete blocks, each block having an upper portion with a plurality of upper inclined sidewalls, a plurality of corners, a lower portion with a plurality of lower sidewalls inclined, a block upper surface, a block lower surface and a block periphery in the form of a block edge where the upper and lower side walls meet; b) one or more cables or ropes that connect the blocks together to form a block matrix; c) each block having a boot affixed to the lower block portion, said boot having a plurality of inclined side panels, each side panel having an upper edge, the boot having a lower panel, an inner boot surface, and an interior which is receptive to at least part of the lower block portion; d) wherein the inclined boot side panels engage the inclined lower block side walls and the lower boot panel engaging the lower block surface; e) a plurality of anchor posts secured to the inner surface of the boot, some of the anchor posts secured to the side wall panels to allow a connection to be formed between the inclined boot side panels and the inclined lower block side walls; f) wherein some of the anchor posts are attached to the bottom panel to allow a connection to be formed between the bottom boot panel and the bottom block surface; and g) corrugations in one or more of said corners. Erosion control blanket according to claim 1, wherein a plurality of said anchor posts having central longitudinal geometric axes which are parallel. Erosion control mat according to claim 1, wherein the lower boot panel has a plurality of projections. Erosion control mat according to claim 1, wherein said matrix is comprised of a plurality of block rows and a plurality of block columns, each of said rows held together by said cables or ropes so queues are generally parallel. Erosion control mat according to claim 1, wherein said matrix is comprised of a plurality of block rows and a plurality of block columns, each of said columns held together by said cables or ropes so queues are generally parallel. Erosion control mat according to claim 3, wherein the projections are hemispherically formed. Erosion control mat according to claim 3, wherein there is a concavity in the inner surface of the bottom boot panel at each projection. Erosion control mat according to claim 1, wherein at least one of the boot side panels has a pair of said anchor posts. Erosion control mat according to claim 1, wherein each side panel has a pair of said anchor posts. Erosion control blanket according to claim 1, wherein said anchor posts do not extend beyond said upper edges. Erosion control mat according to claim 1, wherein said boot sidewall upper edges do not extend above the block edge. Erosion control mat according to claim 1, wherein the upper boot edges are positioned below the rails / ropes. A method for constructing an erosion control mat comprising the steps of: a) providing a mold apparatus which is comprised of a plurality of molds; b) placing a boot into each mold, said boot having a plurality of boot anchor posts, a plurality of inclined side panels, a plurality of corners, each side panel having an upper edge, the boot having a lower panel, an inner boot surface and a boot interior that is receptive to slurry concrete that may be added to the boot interior; c) filling each mold including the boot with paste concrete which hardens after a period of time to form a plurality of concrete blocks, each block having an upper portion with a plurality of inclined upper side walls, a lower portion with a plurality. of inclined lower side walls, a block upper surface, a block lower surface and a block periphery in the form of a block edge where the upper and lower block side walls meet the boot defining a lower portion of the block; d) before said time period expires, place one or more cables or ropes within the molds so that after said time period expires, the cable or rope or cables or ropes connect said blocks together to form a matrix of blocks; e) forming a boot connection with the slurry concrete before said time period expires with a plurality of said anchor posts extending from said boot to said slurry concrete; f) wherein in steps "b" and "e", said plurality of anchor posts are attached to the inner surface of the boot, some anchor posts attached to the side wall panels to allow a connection to be formed between the side panels. sloped boot and sloping block lower side walls; g) wherein in steps "b" and "e", some of the anchor posts are secured to the bottom panel to allow a connection to be formed between the bottom boot panel and the bottom block surface. The method of claim 13, wherein in step "b" the lower boot panel has a plurality of projections. The method of claim 14, wherein there is a concavity in the inner surface of the boot bottom panel at each projection and in step "c" the slurry concrete fills each said concavity. The method of claim 13, further comprising placing some of said anchor posts parallel to others of said anchor posts. The method of claim 13, wherein the boot in step "b" does not extend above the lower inclined block sidewalls. The method of claim 13, wherein step "b" includes providing multiple anchor posts over the boot side panels and multiple anchor posts over the bottom boot panel. The method of claim 18, wherein step "b" includes providing multiple anchor posts over each angled boot side panel. The method of claim 13, wherein in step "b" the anchor posts only connect with the lower boot portion.