EP4001543B1 - Block step - Google Patents

Description

The invention relates to a block stage.

From the DE 1 961 254 U1 a plate-shaped building element, in particular serving as a block step, is known, wherein the plate mass of the building element comprises a hollow chamber arrangement which is open to the outside on a suitable plate side, wherein the plate side faces away from the visible surfaces of the plate.

Furthermore, the DE 19 61 254 U a plate-shaped building element, in particular serving as a block step, is known, wherein the plate mass of the building element comprises a hollow chamber arrangement which is open to the outside on a suitable plate side facing away from the visible surface of the plate.

From the EP 1 018 581 A1 a stair step is known with a tread that is essentially horizontal in the installed state and front and rear outer surfaces that are approximately vertical in the longitudinal direction of the step in the installed state, the stair step having the shape of an inverted U in side view, the two U-legs extending over the full height of the step in the installed state of the step, both outer surfaces being designed as visible surfaces that differ from one another and at least one visible surface having a projection.

From the US 3 007 283 A is an improved

Concrete staircase construction in disassembled form, in which the essential components, namely the associated stringers, the separate prefabricated step units and the foundation or Footplates are designed and adaptable so that they can be quickly handled and transported from the source of production to the site of use and then erected and installed at the desired doorway or other location with a minimum of labour, time and cost.

Finally, the EN 10 2006 055 690 A1 a block step is known, comprising a front side surface, a rear side surface, a left side surface, a right side surface and a ceiling surface, wherein the block step comprises a signal element in an area in which the front ceiling surface merges into the ceiling, wherein the signal element extends in a longitudinal extension of the block step over its length and wherein the signal element differs in material and/or color from the front side surface and the ceiling surface, wherein the signal element has the shape of an elongated cuboid-like rod, wherein this rod comprises a bevel extending over an entire length of one of its longitudinal edges, wherein a first side surface of the rod designed as an end surface of the signal element and a second side surface of the rod designed as a tread surface adjoin the bevel, wherein the end surface, the bevel and the tread surface together form a visible surface of the rod, wherein the rod comprises a left end section, a middle section and a right end section.

It is the object of the invention to propose a block step whose manufacture is simplified and which has a high level of stability. Furthermore, it is the object that this block step meets the safety requirements for construction in public spaces and/or also allows for length adjustment without significantly impairing its stability.

This task is solved by the features of the claim 1. Advantageous and expedient further developments are specified in the subclaims.

The block step according to the invention comprises a front side wall, a rear side wall, a left side wall, a right side wall and a ceiling, wherein between the front side wall, the rear side wall, the left side wall, the right side wall and the ceiling at least one cavity is formed, wherein the cavity is accessible in particular through a bottom surface of the block step and wherein the cavity has the shape of a truncated pyramid and the front side wall, the rear side wall, the left side wall and the right side wall each have a thickness that increases from the bottom surface towards the ceiling in the direction of the cavity. Such a design of the block step simplifies production, since the truncated pyramid-shaped design of the cavity creates demolding slopes on all side surfaces, so that a core of a production mold that keeps the cavity of the block step free can be easily removed. Furthermore, the truncated pyramid-shaped design of the cavity also ensures the stability of the block step, since the side walls, which are parallel to each other in pairs with their outer surfaces, have thicknesses that increase towards the ceiling, so that buckling failure of the side walls is effectively prevented.

Furthermore, the invention provides that the block step comprises a signal element in an area in which the front side wall merges into the ceiling, wherein the signal element extends in a longitudinal extension of the block step over its length and wherein the signal element differs in material and/or color from the front side wall and the ceiling. By designing the block step in this way, it can meet the safety regulations applicable to public spaces.

It is also provided according to the invention that the signal element of the block step has the shape of an elongated cuboid-like rod, wherein this rod comprises a bevel extending over the entire length of one of its longitudinal edges, wherein a first Side surface of the rod and a second side surface of the rod designed as a tread surface adjoin, wherein the end face, the bevel and the tread surface together form a visible surface of the rod, wherein the rod comprises a left end section, a middle section and a right end section, wherein the middle section extends laterally beyond a longitudinal extent of the cavity, wherein the rod has a constriction extending beyond this middle section and wherein the constriction is formed on at least one further side surface of the rod and is opposite the visible surface. As a result, the block step can comprise a signal element with conventional dimensions without the stability of the block step being critically weakened by the signal element, since the signal element is adapted to the shape of the cavity in such a way that a minimum wall thickness of a concrete body of the block step is ensured in all areas. Furthermore, this ensures that the signal element adheres to the concrete body of the block step over a large area in a left and a right edge area of the block step. This also makes it possible to machine the block step in the left and right edge areas to adjust the length without the risk of the signal element being separated from the concrete body as a result of the machining.

It is also intended that the signal element is adjacent to the cavity. This makes the signal element easily accessible for supplying electrical current or connecting light guides or backlighting via the cavity without reworking the block step.

Furthermore, it is also provided to arrange the signal element at a distance from the cavity such that between the signal element and the cavity the front side wall and/or the ceiling. This means that the signal element is subject to less stress and can therefore be implemented more cost-effectively.

It is also planned to form the constriction as a further bevel. This can be achieved with little effort in terms of production technology.

It is also intended that the bar has a polygonal cross-section or an L-shaped cross-section in the area of the constriction and that the bar has a rectangular cross-section in the area of the end sections. This enables both an optimal connection of the bar to the concrete body of the block step and an optimal guarantee of a sufficient distance to the cavity.

Furthermore, it is provided that the constriction extends over half the thickness of the left side wall and over half the thickness of the right side wall. This also ensures the presence of sufficient wall thickness in a first transition area in which the front side wall, the left side wall and the ceiling merge into one another, and in a second transition area in which the front side wall, the right side wall and the ceiling merge into one another.

It is also intended to oversize the left side wall and/or the right side wall of the block step with their thickness measured in the longitudinal extension of the block step so that the block step has the required static values even if the block step is shortened by up to 3 cm on the left side wall to reduce its length and/or right side wall is shortened by up to 3 cm. This makes it possible to work on the edges of the block step without compromising stability. This opens up a new market, as block steps with a hollow space can now also be selected for projects in which it must be possible to adjust the block step lengthwise.

Furthermore, it is provided that a contact surface is formed on the opposite inner surfaces of the left side wall and the right side wall in such a way that the block step can be gripped on these contact surfaces with an internal gripper, whereby the two contact surfaces are formed in particular by recesses formed in the left side wall and the right side wall. By forming the block step in this way, even large-dimensioned block steps can be easily handled by machine on the construction site.

It is also planned to design the signal element as a flat strip or as a strip with an L-shaped cross-section in the manner of a cold plastic marking, with the signal element being integrated flush into a concrete body of the block step. By using such signal strips, block steps can be easily customized in terms of color and/or day and night visibility and/or slip resistance without the concrete body having to be adapted in terms of its dimensions.

Finally, it is also intended to equip the block step with a second signal element in addition to the first signal element, the second signal element being designed as a flat strip in the manner of a cold plastic marking, the second signal element being flush with the concrete body is embedded and forms a front side surface of the front side wall. This allows the block steps to be easily customized in terms of color and/or day and night visibility and/or slip resistance without the need to adjust the dimensions of the concrete body.

Further details of the invention are described in the drawing using schematically illustrated embodiments.

This shows:

Figure 1:

a front view of a first embodiment of a block step according to the invention;

Figure 2:

a side view of the Figure 1 shown block step in direction of arrow II;

Figure 3:

a perspective view of the Figures 1 and 2 shown block level;

Figure 4:

a perspective view of a second embodiment of a block step according to the invention;

Figure 5:

a bottom view of the Figure 4 shown block level;

Figure 6-8:

a third embodiment of a block stage according to the invention;

Figures 9-11:

a fourth embodiment of a block stage according to the invention And

Figures 12a/b:

a fifth embodiment of a block stage according to the invention and

Figures 13a/b:

a sixth embodiment of a block stage according to the invention.

In the Figure 1 a first embodiment of a block stage 1 according to the invention is shown in side view. A dashed line L indicates the contour of a cavity 2 of the block stage 1.

The Figure 2 shows a sectional view from the left of the Figure 1 shown block level 1.

In the Figure 3 is the one in the Figures 1 and 2 Block level 1 shown in perspective view.

As can be seen from the summary of Figures 1, 2 and 3 As can be seen, the block step 1 comprises a cover surface 3, which is formed by a ceiling 4. Furthermore, the block step 1 comprises a front side surface 5, which is formed by a front side wall 6. The block step 1 also comprises a rear side surface 7, which is opposite the front side surface 5 and is formed by a rear side wall 8. The block step 1 also comprises a left side surface 9, which is formed by a left side wall 10, and a right side surface 11, which is formed by a right side wall 12. Finally, the block step 1 comprises a bottom surface 13, which is ring-shaped runs around the cavity 2. The cavity 2 is surrounded by the cover surface 3 and the walls 6, 8, 10, 12 supporting the cover surface 3. The block step 1 is made of concrete B. The cavity 2 opens towards the floor surface 13. The cover surface 3 has a bevel 3a with which it merges into the front side surface 5. This bevel 3a forms a bevelled front edge VK1 of the block step 1.

According to a variant not shown, it is also provided to equip the block step with a signal element by coloring the bevel in a signal color or by applying a strip in a signal color to the bevel. So that the presence of a block step is clearly indicated to a user.

From a comparative analysis of the Figures 1 and 2 It can be seen that the side surfaces 5, 7, 9, 11 located on the outside of the block step 1 are each opposite inner side surfaces 5a, 7a, 9a, 11a and these delimit the cavity 2.

All four side walls 6, 8, 10, 12 have an increasing thickness D6, D8, D10, D12 from the floor surface 13 towards the ceiling 4 for increased static stabilization of the block stage 1. As a result, the cavity 2 has the shape of a truncated pyramid PS1. The truncated pyramid PS1 is in all three Figures 1 to 3 indicated by dashed lines.

The block step 1 has a length L1 in the longitudinal direction, namely in the direction of the bevel 3a. Other external dimensions are a width B1 and a height H1. From a comparative analysis of the Figures 1 and 2 It can be seen that the left side wall 10 and the right side wall 12 of the block stage 1 with their longitudinal extension the thicknesses D10 and D12 measured on block step 1 are oversized in such a way that block step 1 has the required static values even if block step 1 is shortened by up to 3 cm on the left side wall 10 and/or shortened by up to 3 cm on the right side wall 12 to reduce its length L1. Figure 1 a shortening on the left side wall 10 is indicated with a cutting line K10 and a shortening on the right side wall 12 is indicated with a cutting line K12. By shortening the block step 1 on both sides, its length is reduced from length L1 to length L1'.

The front side wall 6 and the rear side wall 8 have the thicknesses D6, D8. For all side walls 6, 8, 1, 12, the thickness D6, D8, D10, D12 is indicated in the figures at the level of the floor surface. As mentioned, the thicknesses D6, D8, D10, D12 increase steadily in the direction of the ceiling 4. Even after shortening the block step 1, the left and right side walls 10, 12 each have thicknesses D10, D12 which correspond at least to the thicknesses D6, D8 of the front side wall 6 and the rear side wall 8.

In the Figures 4 and 5 a second embodiment of a block step 101 according to the invention is shown. A cavity 102 of the block step 101 is designed as a truncated pyramid PS101, as in the first embodiment.

In an area in which a front side wall 106 merges into a ceiling 104, the block step 101 comprises a signal element 114, wherein the signal element 114 extends in a longitudinal extension of the block step 101 over its length L101 and wherein the signal element 114 differs in material and color from the front side wall 106 and the ceiling 104. The signal element 114 is designed as an elongated insert body 115 formed and arranged such that it is spaced from the cavity 102 such that the front side wall 106 and the ceiling 104 extend between the signal element 114 and the cavity 102.

According to an embodiment variant not shown, it is also provided that the signal element is adjacent to the cavity.

From the Figure 5 , which shows the block step 101 from below, it can be seen that in this case - as in the first embodiment - a left side wall 110 and a right side wall 112 are oversized, so that the block step 101 can be shortened on the right side and/or left side by a cut running parallel to a left side surface 109 or a right side surface 111, without the required static values being undercut.

A contact surface 109b, 111b is formed on each of the opposing inner surfaces 109a, 111a of the left side wall 110 and the right side wall 112. The block step 101 can be gripped on these contact surfaces 109b, 11b using an internal gripper (not shown). The contact surfaces 109b, 111b are each formed by a recess 116, 117 formed in the left and right side walls 110, 112.

In the Figures 6 to 8 a third embodiment of a block step 201 according to the invention is shown in two sectional views and a perspective view. Regarding the basic design of the block step 201 with a cavity 202 opening to a base surface 213 in the form of a truncated pyramid PS201, which is bordered by a front side wall 206, a rear side wall 208, a left side wall 210, a right side wall 212 and a ceiling 204, Please also refer to the description of the first two versions. The Figure 6 represents a section according to the section line VI-VI in Figure 8 The Figure 7 represents a section along the line VII-VII in Figure 8 represents.

The block step 201 comprises a concrete body 230 and a signal element 214. The signal element 214 is designed in the form of an elongated cuboid-like rod 231.

To position the signal element 214 in the Figure 8 In order to better delimit it from the cavity 202, the invisible edges of the signal element 214 are not shown as dashed lines, but as solid lines with a thin line width.

The rod 231 extends in the longitudinal extension of the block step 201 over an entire length L201 of the block step 201 and comprises a bevel 232 which extends over an entire length L233 of its longitudinal edge 233. The bevel 232 is adjoined by a first side surface 235 of the rod 231, designed as an end surface 234 of the signal element 214, and a second side surface 237 of the rod 231, designed as a tread surface 236. The end surface 234, the bevel 232 and the tread surface 236 together form a visible surface SF231 of the rod 231.

The rod 234 comprises a left end section 238, a middle section 239 and a right end section 240. The middle section 239 extends laterally to the right and left over a longitudinal extension of the cavity 202 of the block step 201. The rod 231 has a constriction 241 extending over this middle section 239. The constriction 241 is formed on side surfaces 242, 243 of the rod 231 and is diagonal to the visible surface SF231. arranged opposite one another. The constriction 241 is designed as a bevel 244 formed on the side surfaces 242, 243. The constriction 241 extends to approximately half the thickness D210 of the left side wall 210 and to half the thickness D212 of the right side wall 212. In the area of the end sections 238, 239, the rod 231 has a rectangular cross-section. In the area of the constriction 241, the rod 231 has a polygonal cross-section.

In the Figures 9 to 11 a fourth embodiment of a block step 301 according to the invention is shown in two sectional views and a perspective view. Regarding the basic design of the block step 301 with a cavity 302 opening to a base surface 313 in the form of a truncated pyramid PS301, which is bordered by a front side wall 306, a rear side wall 308, a left side wall 310, a right side wall 312 and a ceiling 304, reference is also made to the description of the three embodiments described above. The Figure 9 represents a section according to the section line IX-IX in Figure 11 The Figure 10 represents a section according to the section line XX in Figure 11 represents.

The block step 301 comprises a concrete body 330 and a signal element 314. The signal element 314 is designed in the form of an elongated cuboid-like rod 331.

To position the signal element 314 in the Figure 11 In order to better delimit it from the cavity 302, the invisible edges of the signal element 314 are not shown as dashed lines, but as solid lines with a thin line width.

The rod 331 extends in the longitudinal direction of the block step 301 over an entire length L301 of the block step 301 and comprises a bevel 332 which extends over an entire length L333 of its longitudinal edge 333. The bevel 332 is adjoined by a first side surface 335 of the rod 331, designed as an end surface 334 of the signal element 314, and a second side surface 337 of the rod 331, designed as a tread surface 336. The end surface 334, the bevel 332 and the tread surface 336 together form a visible surface SF331 of the rod 331.

The rod 334 comprises a left end section 338, a middle section 339 and a right end section 340. The middle section 339 extends laterally to the right and left over a longitudinal extension of the cavity 302 of the block step 301. The rod 331 has a constriction 341 extending over this middle section 339. The constriction 341 is formed on side surfaces 342, 343 of the rod 331 and is arranged diagonally opposite the visible surface SF331.

The constriction 341 is designed as a double bevel 345 formed on the side surfaces 342, 343. The constriction 341 extends to approximately half the thickness D310 of the left side wall 310 and to half the thickness D312 of the right side wall 312. Due to the double bevel 245, the rod 331 has an L-shaped cross-section in the region of the constriction 341. In the region of the end sections 338, 339, the rod 331 has a rectangular cross-section.

In the Figures 12a /b shows a fifth embodiment of a block step 401 according to the invention in side view and perspective view. The block step 401 comprises a concrete body 430, in which a first signal element 414 in the form of an L-shaped strip 460 and a second Signal element 470 in the form of a flat strip 471 are embedded flush. Here, both the first signal element 414 and the second signal element 470 extend over an entire length L401 of the block step 401. The second signal element forms a front side surface 405 of a front side wall 406. With regard to a cavity 402, the block step 401 is comparable to the Figures 1 to 11 described block stages. In this respect, reference is made to the description there.

In the Figures 13a /b shows a sixth embodiment of a block step 501 according to the invention in side view and perspective view. The block step 501 comprises a concrete body 530, in which a first signal element 514 in the form of a flat strip 561 is embedded flush. The first signal element 514 extends over an entire length L501 of the block step 501. With regard to a cavity 502, the block step 501 is comparable to the Figures 1 to 11 described block steps. In this respect, reference is made to the description there.

According to further embodiments not shown, it is also provided in the described embodiments to form the block step with more than one cavity, in which case all cavities of the block step open towards the floor surface and all cavities have the shape of a truncated pyramid.

List of reference symbols:

1

Block stage (first design variant)

2

Cavity of 1

3

Cover area

3a

Phase of 3

4

Ceiling 4

5

front side surface

5a

Inner surface opposite 5

6

front side wall

7

rear side surface

7a

Interior surface opposite 7

8th

rear side wall

9

left side surface

9a

Interior surface opposite 9

10

left side wall

11

right side surface

11a

Inner surface opposite 11

12

right side wall

13

Floor area

VK1

Leading edge of 1

K10

Cutting line

K12

Cutting line

PS1

truncated pyramid

B1

Width of 1

D4

Thickness of 4

D6

Thickness of 6

D8

Thickness of 8

D10

Thickness of 10

D12

Thickness of 12

H1

Height H1 of 1.

L

dashed line

L1

Length of 1

L1'

shortened length of 1

101

Block step (second design variant)

102

cavity

104

Ceiling

106

front side wall

109

left side surface

109a

Inner surface

109b

Contact surface

110

left side wall

111

right side surface

111a

Inner surface

111b

Contact surface

112

right side wall

114

Signal element

115

Insert body

116, 117

Return

L101

length

PS101

truncated pyramid

201

Block stage (third variant)

202

cavity

204

Ceiling

206

front side wall

208

rear side wall

210

left side wall

212

right side wall

210

left side wall

212

right side wall

213

Floor area

214

Signal element

230

Concrete body

231

cuboid rod

232

chamfer

233

Longitudinal edge

234

Frontal area of 214

235

first side surface

236

Tread

237

second side surface

238

left end section

239

Middle section

240

right end section

241

Constriction

242, 243

Side area of 231

244

chamfer

D210

Thickness of 210

D212

Thickness of 212

L201

Length of 201

L233

Length of 233

PS201

truncated pyramid

SF231

Visible area

301

Block stage (fourth variant)

302

cavity

304

Ceiling

306

front side wall

308

rear side wall

310

left side wall

312

right side wall

310

left side wall

312

right side wall

313

Floor area

314

Signal element

330

Concrete body

331

cuboid rod

332

chamfer

333

Longitudinal edge

334

Frontal area of 314

335

first side surface

336

Tread

337

second side surface

338

left end section

339

Middle section

340

right end section

341

Constriction

342, 343

Side area of 331

344

double bevel

D310

Thickness of 310

D312

Thickness of 312

L301

Length of 301

L333

Length of 333

PS301

truncated pyramid

SF331

Visible area

401

Block stage (fifth design variant)

402

cavity

414

first signal element

430

Concrete body

460

L-shaped strip

470

second signal element

471

flat strip

405

front side surface

406

front side wall

L401

Length of 401

501

Block stage (sixth variant)

502

cavity

514

first signal element

530

Concrete body

561

flat strip

L501

Length of 501

Claims (10)

1. Block step (1; 101; 201; 301; 401; 501) comprising a front lateral wall (6; 106; 206; 306; 406), a rear lateral wall (8; 208; 308), a left lateral wall (10; 110; 210; 310), a right lateral wall (12; 112; 212; 312) and a top (4; 104; 204; 304), wherein configured between the front lateral wall (6; 106; 206; 306), the rear lateral wall (8; 208; 308), the left lateral wall (10; 110; 210; 310), the right lateral wall (12; 112; 212; 312) and the top (4; 104; 204; 304) is at least one cavity (2; 102; 202; 302; 402; 502), wherein the cavity (2; 102; 202; 302; 402; 502) is accessible in particular by way of a base area (13; 213; 313) of the block step (1; 101; 201; 301),

   - wherein the cavity (2; 102; 202; 302; 402; 502) has the shape of a truncated pyramid (PS1; PS101; PS201; PS301), and the front lateral wall (6; 106; 206; 306; 406), the rear lateral wall (8; 208; 308), the left lateral wall (10; 110; 210; 310) and the right lateral wall (12; 112; 212; 312) have in each case from the base area (13; 213; 313) in the direction of the top (4; 104; 204; 304) a thickness (D6; D8; D10; D12; D210; D212; D310; D312) that increases in the direction of the cavity (2; 102; 202; 302);

   - wherein the block step (1; 101; 201; 301; 401; 501) in a region in which the front lateral wall (6; 106; 206; 306; 406) transitions into the top (4; 104; 204; 304) comprises a signal element (114; 214; 314; 414; 514);

   - wherein the signal element (114; 214; 314; 414; 514) in a longitudinal extent of the block step (1; 101; 201; 301; 401; 501) extends over the length (L1; L101; L201; L301; L401; L501) of the latter, and wherein the signal element (114; 214; 314; 414; 514) differs from the front lateral wall (6; 106; 206; 306) and the top (4; 104; 204; 304) in terms of material and/or colour;

   - wherein the signal element (214; 314) has the shape of an elongate cuboidal bar (231; 331);

   - wherein this bar (231; 331) comprises a chamfer (232; 332) extending over an entire length (L233, L333) of one of its longitudinal edges (233; 333);

   - wherein contiguous to the chamfer (232; 332) are a first lateral face (235; 335) of the bar (231; 331) that is configured as an end face (234; 334) of the signal element (214; 314), and a second end face (237; 337) of the bar (231; 331) that is configured as a tread (236; 336);

   - wherein the end face (234; 334), the chamfer (232; 332) and the tread (236; 336) conjointly form a visible face (SF231; SF331) of the bar (231; 331);

   - wherein the bar (231; 331) comprises a left end portion (238; 338), a central portion (239; 339) and a right end portion (240; 340);

   - wherein the central portion (239; 339) extends laterally beyond a longitudinal extent of the cavity (202; 302);

   - wherein the bar (231; 331) has a constriction (241; 341) extending over this central portion (239; 339); and

   - wherein the constriction (241; 341) is configured on at least one further lateral face (242, 243; 342, 343) of the bar (231; 331) and lies opposite the visible face (SF231; SF331).
2. Block step according to Claim 1, characterized in that the signal element is contiguous to the cavity.
3. Block step according to Claim 1 or 2, characterized in that the signal element (114; 214; 314; 414; 514) is spaced apart from the cavity (102; 202; 302; 402; 502) in such a manner that the front lateral wall (106; 206; 306; 406) and/or the top (104; 204; 304) runs between the signal element (114; 214; 314; 414; 514) and the cavity (102; 202; 302; 402; 502).
4. Block step according to Claim 1, characterized in that the constriction (241; 341) is configured as a further chamfer (244; 345).
5. Block step according to Claim 1 and/or 4, characterized in that the bar (231; 331) in the region of the constriction (241; 341) has a polygonal cross section or an L-type cross section, and in that the bar (241; 341) in the region of the end portions has a rectangular cross section.
6. Block step according to Claim 1 and/or 4 and/or 5, characterized in that the constriction (241; 341) extends beyond half a thickness (D210; D310) of the left lateral wall (210; 310) and beyond half a thickness (D212; D312) of the right lateral wall (212; 312).
7. Block step according to at least one of the preceding claims, characterized in that the left lateral wall (10; 110; 210; 310) and/or the right lateral wall (12; 112; 212; 312) of the block step (1; 101; 201; 301), by way of their thickness (D10; D12; D210; D212; D310; D312) measured in the longitudinal extent of the block step (1; 101; 201; 301) are oversized in such a manner that the block step (1; 101; 201; 301) has the required static values even when the block step (1; 101; 201; 301) for reducing its length (L1; L101; L1201; L301) on the left lateral wall (10; 110; 210; 310) is shortened by up to 3 cm and/or on the right lateral wall (12; 112; 212; 312) is shortened by up to 3 cm.
8. Block step according to at least one of the preceding claims, characterized in that configured on mutually opposite internal faces (109a; 111a) of the left lateral wall (110) and the right lateral wall (112) is in each case one contact face (109b; 111b) in such a manner that the block step (101) can be gripped with an internal gripping tool on these contact faces (109b; 111b), wherein the two contact faces (109b; 111b) are in particular formed by recesses (116; 117) integrally moulded in the left lateral wall (110) and in the right lateral wall (112).
9. Block step according to Claim 1 and/or 3, characterized in that the signal element (414; 514) is configured as a planar strip (561) or as a strip (460) which is L-shaped in cross section, in the manner of a cold plastic marking, wherein the signal element (414) is incorporated in a concrete member (430; 530) of the block step (401; 501) so as to be flush with the surface.
10. Block step according to Claim 9, characterized in that the block step (401) in addition to the first signal element (414; 514) comprises a second signal element (470), wherein the second signal element (470) is configured as a planar strip (471), in the manner of a cold plastic marking, wherein the second signal element (471) is embedded in the concrete member (430) so as to be flush with the surface, and forms a front lateral face (405) of the front lateral wall (406).

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