CN209669801U - Building block and slope protection unit for rope networking - Google Patents

Abstract

The utility model relates to a kind of building block for rope networking and slope protection units.The convex block for having interlock function or the technical problem that groove locks caused processing, transport is inconvenient and formation slope protection arrangement mode is single are relied on to solve existing building block, the utility model provides a kind of building block for rope networking, it is provided with the left bridle port and right bridle port for mutually locking between building block in building block, is additionally provided with the implantation hole for fixing sandy soil for planting vegetation in building block.The utility model additionally provides a kind of slope protection unit for rope networking, including four above-mentioned building blocks, and four building blocks collectively constitute a square on one side, and the bridle port direction of four building blocks is consistent, convenient for forming slope protection.The utility model applies to hydraulic engineering field.The utility model is capable of forming diversified slope protection, can adapt to different environment, and building block processing cost and transportation cost are low；Vegetation can also be planted, sandy soil are further fixed, building block is light-weight.

Description

Building block and slope protection unit for rope networking

Technical field

The utility model relates to a kind of building block for rope networking and slope protection units.

Background technique

In recent years, with the increasing that country invests water conservancy construction, occur many novel ecologicals in hydraulic engineering Slope protection and Ecological Retaining Wall building block.Novel ecological slope protection and novel ecological barricade are due to its landscape, ecological and quick construction etc. Advantage is widely promoted and applied.

Existing building block usually requires that corresponding convex block or groove is arranged, and when being spliced to form slope protection, passes through adjacent block Convex block and groove between body are mutually matched to reach the function of slope protection locking.It is this by block structure into the way of line-locked Special bulk shape dependent on slope-protection block, it is especially desirable to design special convex block or groove with interlock function.Excessively The presence in complicated lock function region, production and processing and transportational process to slope-protection block propose higher requirement.And The shape in specific lock function region determines that the generation type of this slope protection is very single, it is difficult to adapt to different topography environment Diversified demand.

Utility model content

Processing, transport caused by convex block or groove locking with interlock function are relied on not to solve existing building block Just and the single technical problem of slope protection arrangement mode is formed, the utility model provides a kind of building block and shield for rope networking Slope unit.

The technical solution of the utility model is: a kind of building block for rope networking is characterized in that the building block Three splicing control points be A, B, C；A, B, C constitute isosceles right triangle, and AB is long side；Running through in the building block has Left bridle port and right bridle port；The central axis of the left bridle port is parallel with DE, and the central axis of right bridle port is parallel with FG, D is located at a quarter of AB, and F is located at 3/4ths of AB；Angle between DE and AB is 45 ° ± 20 °, between FG and AB Angle be 45 ° ± 20 °.

Further, DE is parallel with FG.

Further, the angle between DE and AB is 45 °.

Further, the profile of the cross section of the building block is triangle, trapezoidal, semicircle, T shape.

Further, at least one implantation hole is provided in the building block.

A kind of slope protection unit for rope networking, is characterized in that

Including four building blocks；

Three splicing control points of the building block are A, B, C, and A, B, C constitute isosceles right triangle, and AB is long side；Institute It states to run through in building block and has left bridle port and right bridle port；The central axis of the left bridle port is parallel with DE, in right bridle port Mandrel line is parallel with FG；D is located at a quarter of AB, and F is located at 3/4ths of AB；Angle between DE and AB is 45 ° ± 20 °, the angle between FG and AB is 45 ° ± 20 °；The isosceles right angle three that described four building blocks splicing control point A, B, C are constituted Angular long side AB constitutes square.

Further, DE is parallel with FG.

Further, the angle between DE and AB is 45 °.

Further, the profile of the cross section of the building block is triangle, trapezoidal, semicircle, T shape.

Further, at least one implantation hole is provided in the building block.

The utility model has the beneficial effects that:

1, the building block of the utility model is in building block by being arranged parallel left bridle port and right bridle port so that building block it Between locking be no longer dependent on the interlocking structure of building block itself, can so that blockhouse is capable of forming diversified slope protection Different environment is adapted to, and reduces the processing cost and transportation cost of building block；

2, the building block of the utility model in building block by being arranged implantation hole, so that building block may be used also while fixed sandy soil To plant corresponding vegetation, to further fix sandy soil, and the weight and materials of building block are alleviated；

3, the slope protection unit of the utility model is by the intercombination of building block, so that the arrangement mode of building block is more various, Further improve the ability that building block adapts to different use environments.

Detailed description of the invention

Fig. 1 is that control point schematic diagram is spliced in the utility model building block；

Fig. 2 is one cross-sectional view of the utility model block embodiments；

Fig. 3 is the utility model block embodiments one to 15 first side schematic diagram of embodiment；

Fig. 4 is two cross-sectional view of the utility model block embodiments；

Fig. 5 is three cross-sectional view of the utility model block embodiments；

Fig. 6 is four cross-sectional view of the utility model block embodiments；

Fig. 7 is five cross-sectional view of the utility model block embodiments；

Fig. 8 is six cross-sectional view of the utility model block embodiments；

Fig. 9 is seven cross-sectional view of the utility model block embodiments；

Figure 10 is eight cross-sectional view of the utility model block embodiments；

Figure 11 is nine cross-sectional view of the utility model block embodiments；

Figure 12 is ten cross-sectional view of the utility model block embodiments；

Figure 13 is 11 cross-sectional view of the utility model block embodiments；

Figure 14 is 12 cross-sectional view of the utility model block embodiments；

Figure 15 is 13 cross-sectional view of the utility model block embodiments；

Figure 16 is 14 cross-sectional view of the utility model block embodiments；

Figure 17 is 15 cross-sectional view of the utility model block embodiments；

Figure 18 is 16 cross-sectional view of the utility model block embodiments；

Figure 19 is one structure of the utility model slope protection unit embodiment intention；

Figure 20 is two structure of the utility model slope protection unit embodiment intention；

Figure 21 is three structure of the utility model slope protection unit embodiment intention；

Figure 22 is the utility model slope protection unit example IV structure intention；

Figure 23 is five structure of the utility model slope protection unit embodiment intention；

Figure 24 is six structure of the utility model slope protection unit embodiment intention；

Figure 25 is seven structure of the utility model slope protection unit embodiment intention；

Figure 26 is eight structure of the utility model slope protection unit embodiment intention；

Figure 27 is nine structure of the utility model slope protection unit embodiment intention；

Figure 28 is ten structure of the utility model slope protection unit embodiment intention；

Figure 29 is 11 structure of the utility model slope protection unit embodiment intention；

Figure 30 is 12 structure of the utility model slope protection unit embodiment intention；

Figure 31 is 13 structure of the utility model slope protection unit embodiment intention；

Figure 32 is 14 structure of the utility model slope protection unit embodiment intention；

Figure 33 is 15 structure of the utility model slope protection unit embodiment intention；

Figure 34 is 16 structure of the utility model slope protection unit embodiment intention；

Figure 35 is 17 structure of the utility model slope protection unit embodiment intention；

Figure 36 is 18 structure of the utility model slope protection unit embodiment intention；

Figure 37 is 19 structure of the utility model slope protection unit embodiment intention；

Description of symbols:

The top surface 1-, the bottom surface 2-, 3- first side, the left bridle port of 4-, the right bridle port of 5-, 6- implantation hole, 7- symmetry axis.

Specific embodiment

It elaborates below in conjunction with attached drawing to the utility model.

As shown in Figure 1, three splicing control points of building block are A, B, C, splicing control point A, B, C constitute isosceles right angle trigonometry Shape, and AB is long side；Running through in building block has left bridle port 4 and right bridle port 5；The central axis of left bridle port 4 is parallel with DE, right The central axis of bridle port 5 is parallel with FG, and D is located at a quarter of AB, and F is located at 3/4ths of AB；Between DE and AB Angle be 45 ° ± 20 °, the angle between FG and AB is 45 ° ± 20 °.

DE is parallel with FG, and the angle between DE and AB is 45 °.

Block embodiments one:

As shown in Figure 2 and Figure 3, the building block cross section in the present embodiment is triangle.In the present embodiment, the three of triangle A point is corresponding with splicing A, B, C point at control point respectively, and the first side 3 of building block and the intersection of top surface 1 coincide with splicing control The side AB of point is made, projection of the central axis of the left bridle port 4 of building block on top surface 1 is overlapped with DE, the right bridle port 5 of building block Projection of the central axis on top surface 1 is overlapped with FG, and left bridle port 4 and the parallel setting of right bridle port 5 are in top surface 1 and bottom surface 2 Between, building block is symmetrical about symmetry axis 7.

Block embodiments two:

As shown in Figure 3, Figure 4, the building block cross section in the present embodiment is triangle.In the present embodiment, the three of triangle A point is corresponding with splicing A, B, C point at control point respectively, and the first side 3 of building block and the intersection of top surface 1 coincide with splicing control The side AB of point is made, cuts the small angle of a triangle at the three angle A points and C point of building block, a small angle of square, building block are cut at C point Projection of the central axis on top surface 1 of left bridle port 4 be overlapped with DE, the central axis of the right bridle port 5 of building block is in top surface 1 On projection be overlapped with FG, left bridle port 4 and the parallel setting of right bridle port 5 are between top surface 1 and bottom surface 2, and building block is about right Claim axis 7 symmetrical.

Block embodiments three:

As shown in figs. 3 and 5, the building block cross section in the present embodiment is triangle.In the present embodiment, the three of triangle A point is corresponding with splicing A, B, C point at control point respectively, and the first side 3 of building block and the intersection of top surface 1 coincide with splicing control The side AB of point is made, projection of the central axis of the left bridle port 4 of building block on top surface 1 is overlapped with DE, the right bridle port 5 of building block Projection of the central axis on top surface 1 is overlapped with FG, and an implantation hole 6 similar with 1 shape of building block top surface is provided in building block, left Between top surface 1 and bottom surface 2, building block is symmetrical about symmetry axis 7 for bridle port 4 and the parallel setting of right bridle port 5.

Block embodiments four:

As shown in Fig. 3, Fig. 6, the building block cross section in the present embodiment is triangle.In the present embodiment, the three of triangle A point is corresponding with splicing A, B, C point at control point respectively, and the first side 3 of building block and the intersection of top surface 1 coincide with splicing control The side AB of point is made, projection of the central axis of the left bridle port 4 of building block on top surface 1 is overlapped with DE, the right bridle port 5 of building block Projection of the central axis on top surface 1 is overlapped with FG, and 7 two sides of symmetry axis are respectively arranged with a triangular planting hole 6 in building block, left Between top surface 1 and bottom surface 2, building block is symmetrical about symmetry axis 7 for bridle port 4 and the parallel setting of right bridle port 5.

Block embodiments five:

As shown in Fig. 3, Fig. 7, the building block cross section in the present embodiment is triangle.In the present embodiment, the three of triangle A point is corresponding with splicing A, B, C point at control point respectively, and the first side 3 of building block and the intersection of top surface 1 coincide with splicing control The side AB of point is made, projection of the central axis of the left bridle port 4 of building block on top surface 1 is overlapped with DE, the right bridle port 5 of building block Projection of the central axis on top surface 1 is overlapped with FG, is provided with a triangular planting hole 6, left rope in building block on the left of symmetry axis 7 Hole 4 and the parallel setting of right bridle port 5 are between top surface 1 and bottom surface 2.

Block embodiments six:

As shown in Fig. 3, Fig. 8, the building block cross section in the present embodiment is triangle.In the present embodiment, the three of triangle A point is corresponding with splicing A, B, C point at control point respectively, and the first side 3 of building block and the intersection of top surface 1 coincide with splicing control The side AB of point is made, projection of the central axis of the left bridle port 4 of building block on top surface 1 is overlapped with DE, the right bridle port 5 of building block Projection of the central axis on top surface 1 is overlapped with FG, is provided with a triangular planting hole 6, left rope in building block on the right side of symmetry axis 7 Hole 4 and the parallel setting of right bridle port 5 are between top surface 1 and bottom surface 2.

Block embodiments seven:

As shown in Fig. 3, Fig. 9, the building block cross section in the present embodiment is triangle.In the present embodiment, the three of triangle A point is corresponding with splicing A, B, C point at control point respectively, and the first side 3 of building block and the intersection of top surface 1 were splicing control Three sections of lines of A, B two o'clock of point, projection of the central axis of the left bridle port 4 of building block on top surface 1 are overlapped with DE, the right side of building block Projection of the central axis of bridle port 5 on top surface 1 is overlapped with FG, and 7 two sides of symmetry axis are respectively arranged with a triangle in building block Between top surface 1 and bottom surface 2, building block is symmetrical about symmetry axis 7 for implantation hole 6, left bridle port 4 and the parallel setting of right bridle port 5.

Block embodiments eight:

As shown in Fig. 3, Figure 10, the building block cross section in the present embodiment is triangle.In the present embodiment, the three of triangle A point is corresponding with splicing A, B, C point at control point respectively, and the first side 3 of building block and the intersection of top surface 1 were splicing control The circular arc line of A, B two o'clock of point, projection of the central axis of the left bridle port 4 of building block on top surface 1 are overlapped with DE, the right side of building block Projection of the central axis of bridle port 5 on top surface 1 is overlapped with FG, and 7 two sides of symmetry axis are respectively arranged with a triangle in building block Between top surface 1 and bottom surface 2, building block is symmetrical about symmetry axis 7 for implantation hole 6, left bridle port 4 and the parallel setting of right bridle port 5.

Block embodiments nine:

As shown in Fig. 3, Figure 11, the building block cross section in the present embodiment is semicircle.In the present embodiment, semicircular circle For arc by connecing 3 points of A, B, C of control point, the first side 3 of building block and the intersection of top surface 1 coincide with the side AB at splicing control point, Projection of the central axis of the left bridle port 4 of building block on top surface 1 is overlapped with DE, and the central axis of the right bridle port 5 of building block exists Projection on top surface 1 is overlapped with FG, and between top surface 1 and bottom surface 2, building block is closed for left bridle port 4 and the parallel setting of right bridle port 5 It is symmetrical in symmetry axis 7.

Block embodiments ten:

As shown in Fig. 3, Figure 12, the building block cross section in the present embodiment is semicircle.In the present embodiment, semicircular circle For arc by connecing 3 points of A, B, C of control point, the first side 3 of building block and the intersection of top surface 1 coincide with the side AB at splicing control point, An implantation hole 6 similar with 1 shape of building block top surface is provided in building block, the central axis of the left bridle port 4 of building block is on top surface 1 Projection be overlapped with DE, projection of the central axis of the right bridle port 5 of building block on top surface 1 is overlapped with FG, left bridle port 4 and the right side For the parallel setting of bridle port 5 between top surface 1 and bottom surface 2, building block is symmetrical about symmetry axis 7.

Block embodiments 11:

As shown in Fig. 3, Figure 13, the building block cross section in the present embodiment is semicircle.In the present embodiment, semicircular circle For arc by connecing 3 points of A, B, C of control point, the first side 3 of building block and the intersection of top surface 1 coincide with the side AB at splicing control point, 7 two sides of symmetry axis are respectively arranged with a fan-shaped implantation hole 6 in building block, and the central axis of the left bridle port 4 of building block is on top surface 1 Projection is overlapped with DE, and projection of the central axis of the right bridle port 5 of building block on top surface 1 is overlapped with FG, left bridle port 4 and right rope For the parallel setting in rope hole 5 between top surface 1 and bottom surface 2, building block is symmetrical about symmetry axis 7.

Block embodiments 12:

As shown in Fig. 3, Figure 14, the building block cross section in the present embodiment is trapezoidal.In the present embodiment, trapezoidal two waist prolongs Long line meets at C point, and trapezoidal bottom coincides with the side AB at splicing control point with the first side 3 of i.e. building block and the intersection of top surface 1, Projection of the central axis of the left bridle port 4 of building block on top surface 1 is overlapped with DE, and the central axis of the right bridle port 5 of building block exists Projection on top surface 1 is overlapped with FG, and between top surface 1 and bottom surface 2, building block is closed for left bridle port 4 and the parallel setting of right bridle port 5 It is symmetrical in symmetry axis 7.

Block embodiments 13:

As shown in Fig. 3, Figure 15, the building block cross section in the present embodiment is trapezoidal.In the present embodiment, trapezoidal two waist prolongs Long line meets at C point, and trapezoidal bottom coincides with the side AB at splicing control point with the first side 3 of i.e. building block and the intersection of top surface 1, An implantation hole 6 similar with 1 shape of building block top surface is provided in building block, the central axis of the left bridle port 4 of building block is on top surface 1 Projection be overlapped with DE, projection of the central axis of the right bridle port 5 of building block on top surface 1 is overlapped with FG, left bridle port 4 and the right side For the parallel setting of bridle port 5 between top surface 1 and bottom surface 2, building block is symmetrical about symmetry axis 7.

Block embodiments 14:

As shown in Fig. 3, Figure 16, the building block cross section in the present embodiment is trapezoidal.In the present embodiment, trapezoidal two waist prolongs Long line meets at C point, and trapezoidal bottom coincides with the side AB at splicing control point with the first side 3 of i.e. building block and the intersection of top surface 1, 7 two sides of symmetry axis are respectively arranged with a right-angled trapezium implantation hole 6 in building block, and the central axis of the left bridle port 4 of building block is in top surface 1 On projection be overlapped with DE, projection of the central axis of the right bridle port 5 of building block on top surface 1 is overlapped with FG, left 4 He of bridle port For the parallel setting of right bridle port 5 between top surface 1 and bottom surface 2, building block is symmetrical about symmetry axis 7.

Block embodiments 15:

As shown in Fig. 3, Figure 17, the building block cross section in the present embodiment is trapezoidal.In the present embodiment, trapezoidal two waist prolongs Long line meets at C point, and trapezoidal bottom coincides with the side AB at splicing control point with the first side 3 of i.e. building block and the intersection of top surface 1, A right-angled trapezium implantation hole 6 is provided in building block on the left of symmetry axis 7, the central axis of the left bridle port 4 of building block is on top surface 1 Projection is overlapped with DE, and projection of the central axis of the right bridle port 5 of building block on top surface 1 is overlapped with FG, left bridle port 4 and right rope The parallel setting in rope hole 5 is between top surface 1 and bottom surface 2.

Block embodiments 16:

As shown in Fig. 3, Figure 18, the building block cross section in the present embodiment is T shape.In the present embodiment, the long side of T shape with I.e. the first side 3 of building block and the intersection of top surface 1 coincide with the AB for splicing control point, the two sides of T shape long side and control point A, B Between there are the length equal with the most bond length of building block top surface 1, there are most short with building block top surface 1 between T shape top and control point C The equal length of edge lengths, projection of the central axis of the left bridle port 4 of building block on top surface 1 are overlapped with DE, the right rope of building block Projection of the central axis in rope hole 5 on top surface 1 is overlapped with FG, and the setting parallel with right bridle port 5 of left bridle port 4 is in top surface 1 Between bottom surface 2, building block is symmetrical about symmetry axis 7.

Slope protection unit embodiment one:

As shown in Fig. 2, Figure 19, the present embodiment is spliced by four pieces of building block in block embodiments one.The C of four building blocks In same point, the side AB forms a square for point splicing, and the left bridle port 4 of two building blocks up and down therein is with right bridle port 5 The bridle port being tilted to the right, the left bridle port 4 and right bridle port 5 of two building blocks in left and right are the bridle port being tilted to the left, so that spelling The bridle port direction for being connected into each building block after slope protection unit is consistent, convenient for being spliced into slope protection net.

Slope protection unit embodiment two:

As shown in Fig. 2, Figure 20, the present embodiment is spliced by four pieces of building block in block embodiments one.Four building blocks The side AB forms a square, wherein the C point of upper building block, left building block and right building block splices in same point, the C point of lower building block is located at Square outer, the placement position of other three building blocks can also be put with building block lower in the present embodiment in other embodiments Position is similar, as long as guaranteeing have the C point of a building block to be located at square outer, the left rope of two building blocks up and down therein Rope hole 4 and right bridle port 5 are the bridle port being tilted to the right, and the left bridle port 4 of two building blocks in left and right is to incline to the left with right bridle port 5 Oblique bridle port so that the bridle port direction for being spliced into each building block after slope protection unit it is consistent, convenient for being spliced into slope protection net.

Slope protection unit embodiment three:

As shown in Fig. 2, Figure 21, the present embodiment is spliced by four pieces of building block in block embodiments one.Four building blocks The side AB forms a square, wherein the C point splicing of upper building block, lower building block is located at square interior in same point, left building block with The C point of right building block is located at square outer, and the position of building block C point may be that upper building block, lower building block exist in other embodiments Square outer and including left building block and right building block, it is therein up and down two building blocks left bridle port 4 and right bridle port 5 be to the right Inclined bridle port, the left bridle port 4 and right bridle port 5 of two building blocks in left and right are the bridle port being tilted to the left, so that being spliced into The bridle port direction of each building block after slope protection unit is consistent, convenient for being spliced into slope protection net.

Slope protection unit example IV:

As shown in Fig. 2, Figure 22, the present embodiment is spliced by four pieces of building block in block embodiments one.Four building blocks The side AB forms a square, wherein the C point of upper building block, left building block and right building block is located at the outside of square, the C point of lower building block Positioned at the inside of square, the placement position of other three building blocks can also be with building block lower in the present embodiment in other embodiments Placement position it is similar, as long as guaranteeing there is the C point of a building block to be located at square interior, upper and lower two building blocks therein Left bridle port 4 and right bridle port 5 be the bridle port being tilted to the right, left and right two building blocks left bridle port 4 and right bridle port 5 For the bridle port being tilted to the left so that the bridle port direction for being spliced into each building block after slope protection unit it is consistent, convenient for being spliced into Slope protection net.

Slope protection unit embodiment five:

As shown in Fig. 2, Figure 23, the present embodiment is spliced by four pieces of building block in block embodiments one.Four building blocks The side AB forms a square, and the C point of each building block is respectively positioned on square outer, the left bridle port of two building blocks up and down therein 4 and right bridle port 5 are the bridle port being tilted to the right, and the left bridle port 4 and right bridle port 5 of two building blocks in left and right are tilted to the left Bridle port so that the bridle port direction for being spliced into each building block after slope protection unit it is consistent, convenient for being spliced into slope protection net.

Slope protection unit embodiment six:

As shown in Fig. 4, Figure 24, the present embodiment is spliced by four pieces of building block in block embodiments two.The C of four building blocks In same point, the side AB forms a square for point splicing, and the left bridle port 4 of two building blocks up and down therein is with right bridle port 5 The bridle port being tilted to the right, the left bridle port 4 and right bridle port 5 of two building blocks in left and right are the bridle port being tilted to the left, so that spelling The bridle port direction for being connected into each building block after slope protection unit is consistent, convenient for being spliced into slope protection net.

Slope protection unit embodiment seven:

As shown in Fig. 5, Figure 25, the present embodiment is spliced by four pieces of building block in block embodiments three.The C of four building blocks In same point, the side AB forms a square for point splicing, and the left bridle port 4 of two building blocks up and down therein is with right bridle port 5 The bridle port being tilted to the right, the left bridle port 4 and right bridle port 5 of two building blocks in left and right are the bridle port being tilted to the left, so that spelling The bridle port direction for being connected into each building block after slope protection unit is consistent, convenient for being spliced into slope protection net.

Slope protection unit embodiment eight:

As shown in Fig. 6, Figure 26, the present embodiment is spliced by four pieces of building block in block embodiments four.The C of four building blocks In same point, the side AB forms a square for point splicing, and the left bridle port 4 of two building blocks up and down therein is with right bridle port 5 The bridle port being tilted to the right, the left bridle port 4 and right bridle port 5 of two building blocks in left and right are the bridle port being tilted to the left, so that spelling The bridle port direction for being connected into each building block after slope protection unit is consistent, convenient for being spliced into slope protection net.

Slope protection unit embodiment nine:

As shown in Fig. 7, Figure 27, the present embodiment is spliced by four pieces of building block in block embodiments five.The C of four building blocks In same point, the side AB forms a square for point splicing, and the left bridle port 4 of two building blocks up and down therein is with right bridle port 5 The bridle port being tilted to the right, the left bridle port 4 and right bridle port 5 of two building blocks in left and right are the bridle port being tilted to the left, so that spelling The bridle port direction for being connected into each building block after slope protection unit is consistent, convenient for being spliced into slope protection net.

Slope protection unit embodiment ten:

As shown in Fig. 9, Figure 28, the present embodiment is spliced by four pieces of building block in block embodiments seven.The C of four building blocks In same point, the side AB forms a square for point splicing, and the left bridle port 4 of two building blocks up and down therein is with right bridle port 5 The bridle port being tilted to the right, the left bridle port 4 and right bridle port 5 of two building blocks in left and right are the bridle port being tilted to the left, so that spelling The bridle port direction for being connected into each building block after slope protection unit is consistent, convenient for being spliced into slope protection net.

Slope protection unit embodiment 11:

As shown in Figure 10, Figure 29, the present embodiment is spliced by four pieces of building block in block embodiments eight.Four building blocks For the splicing of C point in same point, the side AB forms a square, and the left bridle port 4 of two building blocks up and down therein is with right bridle port 5 The bridle port being tilted to the right, the left bridle port 4 and right bridle port 5 of two building blocks in left and right are the bridle port being tilted to the left, so that spelling The bridle port direction for being connected into each building block after slope protection unit is consistent, convenient for being spliced into slope protection net.

Slope protection unit embodiment 12:

As shown in Figure 11, Figure 30, the present embodiment is spliced by four pieces of building block in block embodiments nine.Four building blocks The C point of one square of the side AB formation, upper building block and lower building block meets at the inside for a little and being located at square, left building block and right block The C point of block is located at the outside of square, in other embodiments, the disposing way of upper and lower building block and left and right building block can on the contrary, But due to the special construction of semicircle building block, without other disposing ways in addition to this, the left rope of two building blocks up and down therein Rope hole 4 and right bridle port 5 are the bridle port being tilted to the right, and the left bridle port 4 and right bridle port 5 of two building blocks in left and right are to the left Inclined bridle port so that the bridle port direction for being spliced into each building block after slope protection unit it is consistent, convenient for being spliced into slope protection net.

Slope protection unit embodiment 13:

As shown in Figure 12, Figure 31, the present embodiment is spliced by four pieces of building block in block embodiments ten.Four building blocks The C point of one square of the side AB formation, upper building block and lower building block meets at the inside for a little and being located at square, left building block and right block The C point of block is located at the outside of square, in other embodiments, the disposing way of upper and lower building block and left and right building block can on the contrary, But due to the special construction of semicircle building block, without other disposing ways in addition to this, the left rope of two building blocks up and down therein Rope hole 4 and right bridle port 5 are the bridle port being tilted to the right, and the left bridle port 4 and right bridle port 5 of two building blocks in left and right are to the left Inclined bridle port so that the bridle port direction for being spliced into each building block after slope protection unit it is consistent, convenient for being spliced into slope protection net.

Slope protection unit embodiment 14:

As shown in Figure 13, Figure 32, the present embodiment is spliced by four pieces of building block in block embodiments 11.Four building blocks The side AB form a square, the C point of upper building block and lower building block meets at the inside for a little and being located at square, left building block and right For the C point of building block in the outside of square, other embodiments, the disposing way of upper and lower building block and left and right building block can phase Instead, but due to the special construction of semicircle building block, without other disposing ways in addition to this, a left side for two building blocks up and down therein Bridle port 4 and right bridle port 5 be the bridle port being tilted to the right, the left bridle port 4 and right bridle port 5 of two building blocks in left and right for Left-oblique bridle port so that the bridle port direction for being spliced into each building block after slope protection unit it is consistent, convenient for being spliced into slope protection Net.

Slope protection unit embodiment 15:

As shown in Figure 14, Figure 33, the present embodiment is spliced by four pieces of building block in block embodiments 12.Four building blocks The splicing of C point in same point, the side AB forms a square, the left bridle port 4 and right bridle port 5 of two building blocks up and down therein For the bridle port being tilted to the right, the left bridle port 4 and right bridle port 5 of two building blocks in left and right are the bridle port being tilted to the left, so that The bridle port direction for being spliced into each building block after slope protection unit is consistent, convenient for being spliced into slope protection net.

Slope protection unit embodiment 16:

As shown in Figure 15, Figure 34, the present embodiment is spliced by four pieces of building block in block embodiments 13.Four building blocks The splicing of C point in same point, the side AB forms a square, the left bridle port 4 and right bridle port 5 of two building blocks up and down therein For the bridle port being tilted to the right, the left bridle port 4 and right bridle port 5 of two building blocks in left and right are the bridle port being tilted to the left, so that The bridle port direction for being spliced into each building block after slope protection unit is consistent, convenient for being spliced into slope protection net.

Slope protection unit embodiment 17:

As shown in Figure 16, Figure 35, the present embodiment is spliced by four pieces of building block in block embodiments 14.Four building blocks The splicing of C point in same point, the side AB forms a square, the left bridle port 4 and right bridle port 5 of two building blocks up and down therein For the bridle port being tilted to the right, the left bridle port 4 and right bridle port 5 of two building blocks in left and right are the bridle port being tilted to the left, so that The bridle port direction for being spliced into each building block after slope protection unit is consistent, convenient for being spliced into slope protection net.

Slope protection unit embodiment 18:

As shown in Figure 17, Figure 36, the present embodiment is spliced by four pieces of building block in block embodiments 15.Four building blocks The splicing of C point in same point, the side AB forms a square, the left bridle port 4 and right bridle port 5 of two building blocks up and down therein For the bridle port being tilted to the right, the left bridle port 4 and right bridle port 5 of two building blocks in left and right are the bridle port being tilted to the left, so that The bridle port direction for being spliced into each building block after slope protection unit is consistent, convenient for being spliced into slope protection net.

Slope protection unit embodiment 19:

As shown in Figure 18, Figure 37, the present embodiment is spliced by four pieces of building block in block embodiments 16.Four building blocks The splicing of C point in same point, the side AB forms a square, the left bridle port 4 and right bridle port 5 of two building blocks up and down therein For the bridle port being tilted to the right, the left bridle port 4 and right bridle port 5 of two building blocks in left and right are the bridle port being tilted to the left, so that The bridle port direction for being spliced into each building block after slope protection unit is consistent, convenient for being spliced into slope protection net.

For convenience of the connection relationship between expression each building block of slope protection, the left bridle port 4, right bridle port 5 of each building block are equal in figure It is indicated by the solid line.

Claims (10)

1. a kind of building block for rope networking, it is characterised in that:

Three splicing control points of the building block are A, B, C, and A, B, C constitute isosceles right triangle, and AB is long side；The block Running through on block has left bridle port (4) and right bridle port (5)；The central axis of the left bridle port (4) is parallel with DE, right bridle port (5) central axis is parallel with FG, and D is located at a quarter of AB, and F is located at 3/4ths of AB；Folder between DE and AB Angle is 45 ° ± 20 °, and the angle between FG and AB is 45 ° ± 20 °.

2. the building block according to claim 1 for rope networking, it is characterised in that:

DE is parallel with FG.

3. the building block according to claim 2 for rope networking, it is characterised in that:

Angle between DE and AB is 45 °.

4. the building block according to claim 1 or 2 or 3 for rope networking, it is characterised in that:

The profile of the cross section of the building block is triangle, trapezoidal, semicircle, T shape.

5. the building block according to claim 4 for rope networking, it is characterised in that:

At least one implantation hole (6) is provided in the building block.

6. a kind of slope protection unit for rope networking, it is characterised in that:

Including four building blocks；

Three splicing control points of the building block are A, B, C, and A, B, C constitute isosceles right triangle, and AB is long side；The block Running through on block has left bridle port (4) and right bridle port (5)；The central axis of the left bridle port (4) is parallel with DE, right bridle port (5) central axis is parallel with FG；

D is located at a quarter of AB, and F is located at 3/4ths of AB；

Angle between DE and AB is 45 ° ± 20 °, and the angle between FG and AB is 45 ° ± 20 °；

The long side AB for the isosceles right triangle that described four building blocks splicing control point A, B, C are constituted constitutes square.

7. the slope protection unit according to claim 6 for rope networking, it is characterised in that:

DE is parallel with FG.

8. the slope protection unit according to claim 7 for rope networking, it is characterised in that:

Angle between DE and AB is 45 °.

9. the slope protection unit described according to claim 6 or 7 or 8 for rope networking, it is characterised in that:

The profile of the cross section of the building block is triangle, trapezoidal, semicircle, T shape.

10. the slope protection unit according to claim 9 for rope networking, it is characterised in that:

At least one implantation hole (6) is provided in the building block.