JP2020506318A - Drainage blocks for embankments or urban environments - Google Patents

Abstract

Drainage blocks used as road pavements for embankments or urban environments have drainage and water buffering properties. The drain block has a porous / water permeable pavement or clinker with drainage and water buffering properties and can be used as a pavement in urban areas or as a foundation or substructure under road layers. The drain block has four sides, a base, and a single stem connecting the slab and the base. The stem has a cross-sectional area smaller than the cross-sectional area of the slab and the cross-sectional area of the base, thereby forming a water buffer space between the slab and the base. Also, each of the four sides of the slab includes a single spacing protrusion.

Description

  The present invention relates to drain blocks, and more particularly to drain blocks for use in urban environments. The invention also relates to a drain block for use on a dike.

  Drainage blocks are known from US Pat. No. 6,037,037, which discloses a drainage body with a base unit and a top unit. The base unit and the top unit are connected via a truncated cone or truncated pyramid spacer. However, such drain blocks are not suitable for use on paved roads in urban environments. This is because the top unit is formed as a hollow mesh with many openings, which are dangerous for pedestrians and cyclists on paved roads and other users in urban environments. In addition, these blocks do not meet some government standards for pavement due to such openings.

US Patent Application Publication No. 2012/0255624

  An object of the present invention is to provide a drainage block for embankment as a road pavement having drainage and water buffering properties. Another object of the present invention is to provide a drain block that can be used in urban areas as a pavement having drainage and water buffering properties.

  According to one embodiment of the present invention, there is provided a drain block for use in an embankment or urban environment, the drain block comprising four sides, a base, and a single stem connecting the slab and the base. The stem has a cross-sectional area smaller than the minimum cross-sectional area of the slab and the minimum cross-sectional area of the base, thereby forming a water buffer space between the slab and the base. ing. Also, each of the four sides of the slab includes a single spacing protrusion. As used herein, the terms "smallest" and "minimum" are used interchangeably. As used herein, the term "cross-sectional area" means the cross-sectional area included in a horizontal plane or planes perpendicular to the central longitudinal axis of the block. “Central longitudinal axis” means herein a central axis along the longest dimension of the block.

  The spacing protrusion may be configured in any number of ways, for example, a single spacing protrusion may include a plurality of sub-protrusions. Preferably, the spacing projection has a surface, which extends on a plane parallel to a plane along the surface of the side surface. Thereby, when the two blocks are arranged adjacent to each other, the single spacing projection on one side of the slab of the first block is connected to one of the slabs of the second block. Touching the single spacing protrusion on the side. As a result, slab drain openings are formed between the two slabs of the two blocks on both sides of the contacting spacing protrusion. Such drainage gaps on both sides of the spacing projection have a substantially longitudinal cross section. The hollow space between the slab and the base is for buffering by receiving surface water and slowly discharging the water to the ground, or for redirecting the received surface water. is there. As used herein, “surface water” means any fluid generated from rainfall or waves from a body of water (natural or artificial).

In an exemplary embodiment, the drain block may have a height between 20 cm and 60 cm. The water buffer capacity of the drain block is 0.10 m ³ / m ² (or 100 l / m ² ) for a 20 cm block to 0.42 m ³ / m ² (or 420 l / m ^{2 for} a 60 cm block). ² ). Each of these dimensions, and the water buffering capacity, may be smaller or larger without departing from the scope of the present invention. The hollow space between the drain blocks is large enough to be inspected and cleaned by commonly used sewer inspection and cleaning equipment.

  In one embodiment, the single spacing protrusion on each side of the slab forms or defines two recesses on the side, and a surface defined along a surface of the two recesses. Are parallel to a plane defined along the surface of the spacing protrusion, so that when the four blocks are connected to each other in a substantially square array, they have a substantially cruciform cross-section A slab drain opening is formed between the four blocks. The recess is formed by a portion of the side surface that does not include a spacing protrusion. The size of the drainage space (or gap) is such that pedestrians and bicycles can safely pass over the slab when the block is used as a pavement in an urban environment.

  In one embodiment, the spacing protrusion has a depth or thickness relative to a recess (ie, a portion of the side that does not include the spacing protrusion). This depth or thickness is such that when the blocks are placed adjacent to each other, a drainage gap of sufficient size to form the required volume within a predetermined time is formed. Is the thickness. In an exemplary embodiment, the spacing protrusion has a depth or width of 4 mm and the drainage gap formed by two adjacent spacing protrusions is 8 mm. This advantageously allows drainage to take place while maintaining the spacing dimensions so that pedestrians and bicycles (and other types of traffic) can safely and safely pass over the slab. To

  In one embodiment, the base has four sides, each of the four sides of the base includes a single spacing protrusion, whereby the two blocks are arranged adjacent to each other Sometimes the single spacing protrusion on one side of the base of the first block contacts the single spacing protrusion on one side of the base of the second block, Thereby, the base drainage opening is formed on both sides of the contacting spacing protrusion. The single spacing protrusion on each side of the base defines two recesses on the side, and a surface defined along a surface of the two recesses defines a surface of the spacing protrusion. Parallel to the plane defined along the surface, when the four blocks are connected to each other in a substantially square array, a drain opening having a substantially cruciform cross section is formed by the four blocks. Formed between

  The spacing protrusion preferably has a length equal to the length of the side surface. The length of the spacing protrusion may be, for example, 25% or 50% of the length of the side surface.

  In one embodiment, the spacing protrusion of the slab is aligned with the spacing protrusion of the base. That is, the surface of the spacing protrusion of the slab and the surface of the spacing protrusion of the base are included in the same plane. This facilitates drainage of the fluid. This is because the discharge opening formed by the slab is aligned with the discharge opening formed by the base.

  In an alternative embodiment, the spacing protrusion on the slab does not match, ie is not aligned with, the spacing protrusion on the base. For example, the spacing protrusion may be inserted into the stem. This is the case for block applications where increased cushioning or capacity is desired (since fluid needs to flow a greater distance from the slab area to reach the drainage gap formed by the base). Is advantageous.

  In one embodiment, the stem has a circular cross-section throughout its extension (defined as being included in a horizontal plane or planes perpendicular to the central longitudinal axis of the stem), Has a greater maximum length toward the slab and toward the base, thereby defining a curved surface between the slab and the base. In the case of a stem having a circular cross-section, said maximum cross-sectional length is equal to the diameter. This advantageously makes the flow of fluid through the block smoother. This is because the smooth curved shape of the buffer space reduces turbulence. This curved shape also has the advantage that fluid is guided downward from the drainage space of the slab to the drainage space of the base by the action of surface tension.

  In one embodiment, the stem has an elliptical cross-section (defined as being included in a horizontal plane or planes perpendicular to the central longitudinal axis of the stem) over its extension, The profiled section has a maximum length, which is greater towards the slab and towards the base, thereby defining a curved surface between the slab and the base. ing. An elliptical cross-section advantageously provides greater and better support, especially when the block is manufactured as a half-block, because it has more body in the stem.

  In one embodiment, the stem has a rectangular cross-section throughout its extension (defined as being included in a horizontal plane or planes perpendicular to the central longitudinal axis of the stem), with a maximum cross-section A length, wherein the maximum length is greater toward the slab and toward the base, thereby defining a curved surface between the slab and the base. A rectangular cross-section advantageously allows for easier and more cost-effective manufacture of blocks or half-blocks.

  In one embodiment, the diameter of the cross section of the stem or the maximum length of the cross section is greatest towards the slab. This allows the drain block to accommodate more stress from traffic loads when used in urban areas. Additionally or alternatively, the cross-section of the stem is smaller (as small as possible) towards the base to provide space for inspection and / or cleaning equipment. .

  In one embodiment, the blocks are monolithic. That is, the entire block is manufactured as a monolithic element. This can be achieved by using a mold. Monolithically or integrally formed blocks are advantageous because they reduce the assembly time on the area or terrain to be covered or paved by the block. As used herein, "monolithic" refers to a block formed from a single piece of material.

  In another embodiment, the slab and the base have the same height. The height of the slab and the base may be, for example, 40 cm or 45 cm. The slab and the base may have different thicknesses, for example, the slab may have a height of 45 cm and the base may have a height of 40 cm. Such an embodiment would be particularly suitable for an urban environment. In an urban environment, it is not subject to waves and wave forces, and the resistance provided by the block need not be so high. In an urban environment, blocks characterized by approximately equal weights of the base and the slab are sufficiently stable.

  In one embodiment, the height of the base is higher than the height of the slab. This advantageously provides a block with greater resistance (especially resistance suitable for use in embankments or any other area that may be subject to waves and wave forces). This is also advantageous if greater resistance to displacement is required, taking into account the slope or slope of the terrain.

  In one embodiment, the base has a circumferential groove dividing the base into an upper base portion (upper base section) and a lower base portion (lower base section). This groove advantageously enhances the fixation of the block when packed with small split stones. Such an embodiment would be particularly suitable for use on embankments. The subsections are not completely separated from each other.

  In a further embodiment, the upper base (as formed by the circumferential groove) has a spacing protrusion that may have the same height as the upper subsection. This advantageously facilitates the assembly of the blocks in the area to be covered, as they serve as indicators of alignment between the blocks. Further, particularly, when the spacing protrusion (s) of the upper base portion has the same depth as the spacing protrusion of the slab, the space is provided on the slab. Helps to be formed by spacing protrusions.

  According to another aspect of the present invention, a strip drain block is provided. The strip drain block includes a slab, a base, and a plurality of stems connecting the slab and the base, each of the plurality of stems having a cross-sectional area smaller than a minimum cross-sectional area of the slab and the base. Having. The slab and the base each include two longitudinal surfaces, each longitudinal surface including a plurality of spacing protrusions. Such blocks are advantageous because the larger dimensions facilitate assembly or paving of a given area. The plurality of stems can include any number of stems, for example, can include at least two stems. Alternatively, the plurality of stems may include at least three stems. Preferably, the plurality of stems may include at least four to five stems. This advantageously reduces the time required to assemble the drain block pavement. In particular, blocks (or half-blocks) with five or at least five stems are stronger and easier to manufacture.

  In one embodiment, each of said plurality of stems of said strip drain block has a circular cross-section throughout its extension (where "cross-section" is a horizontal plane perpendicular to the central longitudinal axis of said stem). (Defined as included in one or more), wherein the diameter of the circular cross section is larger towards the base and towards the slab, whereby the slab and the base And a curved surface is defined between them. This advantageously makes the flow of fluid through the block smoother. This is because the smooth curved shape of the buffer space reduces turbulence. This curved shape also has the advantage that fluid is guided downward from the drainage space of the slab to the drainage space of the base by the action of surface tension.

  In an alternative embodiment, each of the plurality of stems of the strip drainage block has an elliptical cross-section (herein "cross-section" with respect to a central longitudinal axis of the stem) throughout its extension. Defined in the vertical horizontal plane or planes), the elliptical cross-section having a maximum length, wherein the maximum length is toward the base and toward the slab. Larger, thereby defining a curved surface between the slab and the base. The curved shape efficiently directs the load applied to the slab. This is because the pressure applied to the block is dispersed, which is such that in the higher pressure areas the material is saved as much as possible while maintaining the material.

  In a further embodiment, each of the plurality of stems has a rectangular cross-section (here, “cross-section” refers to a horizontal plane (one or more) ), Wherein the rectangular cross-section has a maximum length, which is greater towards the base and towards the slab, , Defining a curved surface between the slab and the base. The curved shape efficiently directs the load applied to the slab. This is because the pressure applied to the block is dispersed, which is such that in the higher pressure areas the material is saved as much as possible while maintaining the material.

  In a further embodiment, two of the plurality of stems are outer stems defining two flat lateral ends of the block, the outer stems being semicircular, semielliptical, or semirectangular. (Depending on the type of strip drain block as described above, defined by the cross-sectional area of the plurality of stems). In the present specification, the “semicircular” cross section and the “semi-elliptical” cross section mean a half-circular cross-section and a half-elliptical cross-section. As used herein, a "semi-rectangular" cross-section means that the cross-sectional area of the outer stem is approximately half the cross-sectional area of the non-outer stem.

  If the block is provided in two parts (ie two half-blocks), the corresponding outer stem will have a wedge-shaped cross-section (corresponding to half a semicircle) or a quarter-shaped ellipse It will have a cross-section or a cross-section that is a quarter of a rectangle. These shapes depend on the type of strip drain block (defined by the cross section of the plurality of stems). The lateral end of the drain block, including the outer stem, is characterized by a flat surface that provides a surface for connecting an adjacent strip drain block. The lateral ends are preferably flat so that a more stable connection between two adjacent strip drain blocks is achieved.

  In one embodiment, the plurality of spacing protrusions define a recess along the slab and the base. As used herein, the term “recess” is used to indicate portions of the slab and the base that do not include spacing protrusions (ie, these portions are recessed with respect to the spacing protrusions). Can be Each of the plurality of spacing protrusions may have a length less than or equal to a minimum cross-sectional diameter or a maximum length of each of the plurality of stems. Alternatively or additionally, each of the plurality of spacing protrusions has a length defined as a ratio to a length of a longitudinal surface of the base and slab, for example, each spacing protrusion is , 15% of the length of the longitudinal face of the slab or base. Each of the plurality of spacing protrusions may have a depth (or thickness) of, for example, 3 mm relative to the base and the recess on the slab. The depth or thickness may be larger or smaller depending on the desired dimensions of the drainage gap or spacing. The larger the gap, the higher the drainage rate.

  In one embodiment, each of the plurality of spacing protrusions is aligned with one of the plurality of stems. Alternatively, the spacing protrusion may be arranged so as not to be aligned with the stem. For example, the spacing protrusion may be inserted into the stem. The number of the spacing protrusions may be related to the number of the stem. For example, in a strip drain block, as a whole, preferably two spacing projections are provided per stem, and in a strip drain block, as a half block, one spacing projection per stem is provided. Provided. This provides sufficient capacity to separate adjacent blocks.

  In one embodiment, the drain block according to the present invention is made from concrete, including geopolymer concrete. By manufacturing the block (and half-block) from concrete, a stronger block is obtained, specifically without the need for a top or cover layer (eg, drainage sand or other such top layer). A block is obtained that can be used as paving. When the drainage block is used as a foundation / substructure, the thickness of the top layer or cover layer covering the drainage block is much smaller than in the known block, thanks to the strength of the block according to the invention. Good. It is also possible to use other materials for producing the blocks and half blocks, for example, clay or plastic.

  In a preferred embodiment, the drain block comprises a half slab, a half stem, and a half base, and two half blocks each including one flat surface. The half blocks are arranged adjacent to each other along respective flat surfaces so as to be symmetric with respect to a central longitudinal plane of the drain block. Thus, by joining the two half drain blocks, one complete drain block is formed. As used herein, "joining two half blocks" refers to placing two half blocks adjacent to each other (with or without an adhesive such as cement) along their flat surfaces. Meaning. Preferably, the half blocks are adjacent without using an adhesive.

  According to a further aspect of the present invention there is provided a method for manufacturing a drain block as described above, comprising forming the drain block using a mold. This facilitates the manufacture of the block. Thus, a mold is prepared that complies with the physical and dimensional aspects described herein, and is filled with the material selected to form the drain block.

  In a further embodiment, the drain block is formed by adjoining two half blocks (as defined above), wherein the half blocks are formed by using a mold.

  Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

FIG. 4 is one of diagrams illustrating a drain block according to one embodiment of the present invention. FIG. 4 is one of diagrams illustrating a drain block according to one embodiment of the present invention. FIG. 4 is one of diagrams illustrating a drain block according to one embodiment of the present invention. It is a figure of the state where a plurality of drain blocks by one mode of the present invention were arranged. FIG. 4 is one of the drawings showing a drain block according to another aspect of the present invention. FIG. 4 is one of the drawings showing a drain block according to another aspect of the present invention. FIG. 4 is one of the drawings showing a drain block according to another aspect of the present invention. It is a figure of the state where a plurality of drainage blocks by the present invention were arranged. 1 is one of the drawings showing a strip drain block according to one embodiment of the present invention. 1 is one of the drawings showing a strip drain block according to one embodiment of the present invention. FIG. 4 is one of the drawings showing a strip drain block according to the present invention. FIG. 4 is one of the drawings showing a strip drain block according to the present invention. FIG. 6 is one of the drawings showing a strip drain block according to another aspect of the present invention. FIG. 6 is one of the drawings showing a strip drain block according to another aspect of the present invention. FIG. 6 is one of the drawings showing a strip drain block according to another aspect of the present invention. FIG. 6 is one of the drawings showing a strip drain block according to another aspect of the present invention.

  FIG. 1A shows an axonometric view of a drain block 100 according to one embodiment of the present invention. The drain block 100 includes a slab 102, a single stem 104, and a base 106. FIG. 1B shows a side view of the drain block 100. FIG. 1C shows another side view and section II-II of the drainage block 100. Cross section of the stem. Block 100 has a height H1. The slab 102 has a height H2 and the base 106 has a height H3. In the illustrated embodiment, the slab and the base have the same height (ie, H2 = H3). The stem 104 has a semi-elliptical cross-section characterized by a length D and a width R, where D is greater than R. The semi-elliptical cross-section increases from a substantially central region toward both the base 106 and the slab 102. However, the increase is greater towards slab 102.

  FIG. 2 shows an arrangement 200 of a plurality of blocks 100. As can be seen, when the four blocks 100 are abutted in a generally square array, a generally cross-shaped drainage gap or space 202 is formed. The blocks are adjacent such that the spacing protrusion of one block is adjacent to the spacing protrusion of another block. In this case, the spacing protrusions of both the base and slab of one block are adjacent to the respective spacing protrusions of the base and slab of another block.

  FIG. 3A shows an axonometric view of a block 300 for use on a dike. The block 300 includes a slab 302, a single stem 304, and a base 306. The base 306 is divided into an upper base 306a and a lower base 306b by a circumferential groove 308. Upper base portion 306a has spacing protrusions 310 on two of the four surfaces.

  FIG. 3B shows a side view of the block 300. FIG. 3C shows another side view and a cross-sectional view along the plane II-II. The block 300 has spacing protrusions 310 on two of the four surfaces of the upper base 306a. Block 300 has a height H5 and the slab has a height H6. The base has a height H7, the upper base has H7a, and the lower base has height H7b. The stem has a height H8. The circumferential groove has a height H9 and a depth D. Stem 304 is symmetrical about a central horizontal plane, with equally increasing dimensions from the central region toward slab 302 and base 306.

  FIG. 4 shows a state where a plurality of blocks 300 are arranged. As can be seen, when the four blocks 300 are adjacent in a generally square array, a generally cross-shaped drainage gap or space 402 will be formed by the spacing protrusions of the slab. The blocks are adjacent such that the spacing protrusion of one block is adjacent to the spacing protrusion of another block. In this case, the base of each block has only two spacing protrusions 310, and these protrusions 310 are arranged on the facing surface of the upper base portion 306a.

  FIG. 5A illustrates a strip drain halfblock 500 according to one embodiment of the present invention. Block 500 includes four spaced stems 506 disposed between slab 502 and base 504. The base and slab have spacing protrusions 510 and 512, respectively, aligned with stem 506. The slab has two longitudinal surfaces 502 and the base has two longitudinal surfaces 504. FIG. 5B shows the other side of block 500. Block 500 has a height HS1 and a length LS1.

  FIG. 6A shows a strip drain halfblock 600 having a slab 606 and a base 608, wherein the slab 606 has two longitudinal surfaces 614 and the base 608 has two longitudinal surfaces 616. A plurality of stems 603 are disposed between slab 606 and base 608. In this embodiment, the strip block has two outer stems 604a, 604b, and has two flat lateral ends 602. Slab 606 has spacing protrusions 612 along one of its longitudinal surfaces, and base 608 has spacing protrusions 610 along one of its longitudinal surfaces. FIG. 6B shows the other side of the strip half block 600.

  FIG. 7A shows a strip drain block 700 having a base 706 and a slab 702. A plurality of stems 704 are disposed between the slab 702 and the base 706. The slab has two longitudinal surfaces 712 and the base has two longitudinal surfaces 714. A plurality of spacing protrusions 710 and 708 are disposed along the longitudinal plane. FIG. 7B shows the other side of block 700.

  FIG. 8A shows a strip drain block 800 having a base 806 and a slab 802. A total of five stems 804 are located between the slab 802 and the base 806. The slab has two longitudinal surfaces 812 and the base has two longitudinal surfaces 814. A plurality of spacing protrusions 810 and 808 are disposed along the longitudinal plane. FIG. 8B shows the other side of block 800.

  The invention has been described with respect to a number of exemplary embodiments as shown in the drawings. Modifications and alternative implementations of some parts or elements are possible, which fall within the protection scope defined in the appended claims.

REFERENCE SIGNS LIST 100 drain block 102 slab 104 stem 106 base 300 block 306a upper base 306b lower base 308 circumferential groove 310 spacing protrusion 502 slab 504 base 602 lateral end 604a outer stem 604b outer stem

Claims (26)

A drain block for use as a pavement or substructure for embankments or urban spaces,
A slab having four sides for connecting to other blocks;
Base and
A single stem connecting the slab and the base, the stem having a smaller cross-sectional area than the minimum cross-sectional area of the slab and the base, whereby the slab and the base are smaller. And each of the four sides of the slab includes a single spacing protrusion, such that when the two blocks are positioned adjacent to each other, The single spacing protrusion on one side of the slab of one block contacts the single spacing protrusion on one side of the slab of a second block, thereby draining the slab. A drain block, wherein an opening is formed between the two slabs on both sides of the contacting spacing protrusion.   The single spacing protrusion on each side of the slab defines two recesses on the side, and a surface defined along a surface of the two recesses defines a surface of the spacing protrusion. Parallel to the plane defined along the surface, so that when the four blocks are connected to each other in a substantially square array, a slab drainage opening having a substantially cross-shaped cross-section is formed by the four blocks. The drain block according to claim 1, formed between the drain blocks.   The base has four sides, each of the four sides of the base includes a single spacing protrusion, so that when the two blocks are positioned adjacent to each other, the first The single spacing projection on one side of the base of the second block contacts the single spacing projection on one side of the base of the second block, thereby providing a base drain opening Parts are formed between the two bases of the two blocks on both sides of the contacting spacing protrusion, and the single spacing protrusion on each side of the base is 2 Defining two recesses on the side surface, the surface defined along the surface of the two recesses being parallel to the surface defined along the surface of the spacing protrusion, By the four blocks URN when connected to one another in square arrangement, drain openings having a generally cruciform cross-section is formed between the four blocks, drainage block according to any of claims 1-2.   4. The drain block according to claim 3, wherein the spacing protrusion of the slab is aligned with the spacing protrusion of the base.   4. The drain block according to claim 3, wherein the spacing protrusion on the slab is not aligned with the spacing protrusion on the base.   The stem has a circular cross-section throughout its extension, the circular cross-section having a maximum length, wherein the maximum length is greater towards the slab and towards the base; The drain block according to any one of claims 1 to 5, wherein a curved surface is defined between the slab and the base.   The stem has an elliptical cross section throughout its extension, the elliptical cross section having a maximum length, wherein the maximum length is greater toward the slab and toward the base; The drain block according to claim 1, wherein a curved surface is defined between the slab and the base.   The stem has a rectangular cross-section throughout its extension, the rectangular cross-section having a maximum length, wherein the maximum length is greater toward the slab and toward the base; The drain block according to any one of claims 1 to 5, wherein a curved surface is defined between the slab and the base.   The drain block according to any one of claims 6 to 8, wherein the maximum length of the cross section is maximum toward the slab.   The drain block according to any one of claims 1 to 9, wherein the block is monolithic.   The drain block according to any one of claims 1 to 10, wherein the slab and the base have the same height.   The drain block according to claim 1, wherein the base has a height greater than the slab.   14. The drain block according to claim 13, wherein the base has a circumferential groove dividing the base into an upper base portion and a lower base portion.   14. The drain block of claim 13, wherein the upper base has four sides, and has spacing protrusions on two of the four sides. A strip drainage block for use as a pavement or substructure for embankments or urban spaces,
A slab, a base, and a plurality of stems connecting the slab and the base, each of the plurality of stems having a cross-sectional area smaller than a minimum cross-sectional area of the slab and the base; A strip drain block wherein the bases each include two longitudinal surfaces, each longitudinal surface including a plurality of spacing protrusions.   Each of the plurality of stems has a circular cross-section throughout its extension, the circular cross-section having a maximum length, wherein the maximum length is toward the base and toward the slab. The strip drain block of claim 15, wherein the strip drain block increases in size, thereby defining a curved surface between the slab and the base.   Each of the plurality of stems has an elliptical cross-section over its extension, the elliptical cross-section having a maximum length, wherein the maximum length is toward the base and toward the slab. 16. The strip drain block of claim 15, wherein the strip drain block is larger and thereby defines a curved surface between the slab and the base.   Each of the plurality of stems has a rectangular cross-section over its extension, the rectangular cross-section having a maximum length, wherein the maximum length is toward the base and toward the slab. The strip drain block of claim 15, wherein the strip drain block increases in size, thereby defining a curved surface between the slab and the base.   19. The strip drain block according to any of claims 15 to 18, wherein the plurality of stems includes at least five stems.   16. The strip drain block of claim 15, wherein two of said plurality of stems are outer stems, said two outer stems defining two flat lateral ends of said block.   The plurality of spacing protrusions define a recess along the slab and the base, and each of the plurality of spacing protrusions has a length, the length being the plurality of stems. 21. The strip drain block according to any of claims 15 to 20, wherein the length is less than or equal to the maximum length of each minimum cross-section.   The strip drain block of any of claims 15 to 21, wherein each of the plurality of spacing protrusions is aligned with one of the plurality of stems.   A drain block according to any of the preceding claims, wherein the block is made from concrete.   The block is composed of a half slab, a half stem, and a half base, and two half blocks each including one flat surface, and the half blocks are arranged along the respective flat surfaces so that a central longitudinal portion of the drain block is formed. 24. The drain block according to any of the preceding claims, wherein the drain blocks are arranged adjacent to each other so as to be symmetric with respect to the direction plane.   25. A method for manufacturing a drain block according to any of the preceding claims, comprising forming the drain block using a mold.   26. The method of claim 25, wherein the drain block is formed by adjoining two half blocks and the half blocks are formed using a mold.

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