EP0451616A1 - Scaffold platform - Google Patents

Abstract

The profile (100) of the longitudinal beams (38...) of scaffolding platforms (26) has, in the lower outer corner (109), a semi-cylindrical centring rib (110) which can engage in a centring space (135) on the upper side of the respective underlying longitudinal beam (38.3) and thus secure against lateral displacement. Inner stub-guiding ribs (125.1, 125.2) serve for holding an insertion stub (50) of a supporting hook. <IMAGE>

Description

The invention relates to a scaffolding floor with a frame-like support structure composed of profile parts, which contains longitudinal spars which are formed from sections of light metal extruded profile parts and wherein the profile has a vertical inner wall, a vertical outer wall, a horizontal lower wall, a horizontal upper wall and has further support, support and reinforcement means, under which a lower rounded support rib and inner reinforcement ribs are provided, and wherein a plate forming the running surface of the scaffold floor is fastened to the support formation.

From DE-OS 35 39 507 A1 scaffold floors with such longitudinal spars are known. Two lower ribs are provided for the purpose of stack centering, and the ribs located inside the profile serve only for reinforcement, but not for guiding purposes. In addition, the spar profile requires a laterally cantilevered support leg for riveting the plate. This very advantageous construction is connected to a steel-sheet cross bar to form a frame and is useful for many applications. However, there are other applications and efforts to improve and simplify the manufacture of such scaffolding floors, which cannot all be met with the known profile for the spars.

The invention has for its object to provide an improved spar profile for inexpensive manufacture, assembly and use.

According to the invention it is provided that the profile of the longitudinal spars has only a lower, in the area of the outer corner, serving for reinforcement, support and centering, approximately semi-cylindrical centering rib and in the area of the upper, outer corner for support reinforcement at least 3 times is formed of the remaining wall thickness material accumulation, which extends to a lower lying fold, delimited by a folded wall, in which one Support surface for the plate is formed, and wherein the vertical fold wall extends to the upper edge of the profile, under which a displacement limiting rib and an adjoining, outward and upward stacking centering fold a centering space are formed so that when stacking the Centering rib of the overhead longitudinal spar in the centering space inserts the scaffolding floors to prevent lateral displacement.

A free space is now created on the upper side, in which the fastening of the plate can be accommodated without problems, for example with rivets. The scaffolding floors are only centered on one another with the two outer position-centering ribs of the two spaced-apart longitudinal spars of a scaffolding floor and in each case a centering space above a thick-walled upper area, which is delimited by a small, upward, displacing displacement rib and serves for stacking. Otherwise you can stack on rivet heads. A profile designed in this way fulfills optimizing manufacturing, assembly and usage conditions.

The expedient position of the inner stop and guide ribs makes it possible to receive and hold support hooks with their insertion pins in a well-guided manner on the face side without incurring additional costs on the profile. So easy Riveting the plug-in pins is sufficient for further securing the position and fastening. Securing ribs on the support surface can serve to better hold the entire scaffold floor together.

Further details, advantages and features of the invention also result from the claims and the following description part, which is dealt with on the basis of the drawings.

An embodiment of the invention is explained below.

Fig. 1

Die Schrägansicht eines kleinen Teiles eines Gerüstes mit Tragriegel und dem einen Endteil eines an diesem mittels Auflagehaken abgestützten Gerüstbodens;

Fig. 2

die Schrägansicht des Gerüstbodens in teilweise aufgebrochener Darstellung;

und

Fig. 3

einen Vertikalschnitt durch die Längsholme zweier übereinander gestapelter Gerüstböden mit angrenzenden Bereichen, wobei die Schnittebene des unteren Holmes durch den Einsteckzapfen eines Auflagehakens verläuft und die Scnittebene des oberen Holmes weiter zurückliegt.

Show it:

Fig. 1

The oblique view of a small part of a scaffold with a support bar and the one end part of a scaffold floor supported thereon by means of support hooks;

Fig. 2

the oblique view of the scaffold floor in a partially broken representation;

and

Fig. 3

a vertical section through the longitudinal spars of two stacked scaffolding floors with adjacent areas, the cutting plane of the lower spar passing through the insertion pin of a support hook and the cutting plane of the upper spar further back.

In Fig. 1 only a small part of a scaffold is shown. In this case, the stems 20 carry a perforated disk 21, known per se, corresponding to the pitch of the scaffolding system. Between the stems 20, a support bolt 22 is fastened to the perforated disks 21 with the aid of connecting heads 30. The support bar 22 is designed as an upwardly open U-profile. The upper ends of the vertical legs 27.1 and 27.2 of the support bar 22 are designed as support edges 23 for the support hooks 25.1, 25.2 and 35 of the scaffold floor 26. The connection heads 30 are designed in a known manner with slots and plugged onto the perforated disks 21 and secured to them with wedges 34. In this or a similar way, many scaffolding days are realized in one scaffold. This section is only shown to illustrate how the longitudinal beam profiles according to the invention are arranged with their designs in the entire framework.

1 and 2 show, the scaffold floor 26 selected here as an example has three support hooks on each end face, of which the two outer support hooks 25.1, 25.2 are fastened in the two corners and a differently designed support hook 35 in the middle. The support hook 35 is fastened to a cross member 36 of the support formation 37 of the scaffold floor 26, preferably welded on. The cross bar 36 is between the two longitudinal bars 38.1 and 38.2 of the support formation 37 of the Scaffold floor 26 welded in the area of the corners so that the cut ends 39.1 and 39.2 of the longitudinal bars 38.1 and 38.2 remain open. This results in a stable frame, possibly provided with transverse reinforcements, not shown, which forms the support formation 37 of the scaffold floor 26. It has - as FIG. 3 shows - contact surfaces 41 which extend over approximately 2/3 of the width 145 of the profiles 100 of the longitudinal spars 38.1, 38.2, 38.3, 38.4 and each extend up to a vertical folding wall 42. Here the edge 43 of a plate 45 is placed. The plate 45 can be formed from heat-resistant glued plywood with an anti-slip layer or another material that is common in scaffolding. It has the running surface 46 of the scaffold floor 26 as the surface. With the aid of rivets 47 arranged at suitable intervals, for example hollow rivets or blind rivets, the edge 43 is riveted to the longitudinal bars 38.

3 shows the longitudinal spars 38.3 and 38.4 of a lower scaffold floor 26.1 and an upper scaffold floor 26.2, which correspond in their position to the longitudinal spar 38.2 lying on the left in FIGS. 1 and 2. To connect the longitudinal spars of each scaffold floor 26 on each side, a transverse spar 36.1 or 36.2 is shown, which is just cut off at its ends and welded directly onto it by means of weld seams 101 on the inner outer surface 113 of the inner wall 107 of the respective longitudinal spar 38 ... .

The profile 100 of each longitudinal bar 38 ... is a light metal extruded profile which is cut off at the ends 39.1, 39.2.

The profile 100 has a lower wall 105, an upper wall 106, an inner wall 107 and an outer wall 108. In the lower outer corner 109, a semi-cylindrical centering rib 110 is formed below the lower wall 105. It serves to reinforce and support the scaffold floor when it is placed on a support base and in particular to center the position when stacking, as shown in FIG. 3.

Otherwise, the bottom wall 105 is guided smoothly and horizontally on its outer surface 111. It merges with a rounded corner 112 into the smooth outer surface 113 of the vertical inner wall 107.

Above the corner 109, the outer wall 108 adjoins the lower wall 105, which has an outer wall lower part 114, an outer wall middle part 115 and an outer wall upper part 116. The outer wall lower part 114 and the outer wall upper part 116 are arranged in alignment with one another, while the outer wall middle part 115 is offset inwards by a small amount of, for example, 1 mm. This serves the purpose, among other things, of less damaging the outer surface, and above all of reinforcing the profile through structure formation, but on the other hand in particular also to create a vertical fitting surface 117 on the inside of the outer wall 108, which makes it possible, when using rounded corners 118 and 119, to insert a plug-in pin 50 of a support hook 25 smoothly cut off on the side surfaces 51.1 and 51.2. The thickness 52 of this plug-in pin 50 can be determined very precisely by cutting. The cutting leads to sharp-edged corners. The insertion pin 50 is firmly fixed against the inner fitting surface 117 of the outer wall 108 or by a lower pin guide rib 125.1 projecting inward from the lower wall 105 in the spar space 120 and a pin guide rib 125.2 projecting downward from the upper wall 106 in the direction of the interior of the scaffolding floor of the outer wall middle part 115 held against. Otherwise, the insertion pin 50 has an upper fitting surface 62.2 on the upper wall 56.2 and a lower fitting surface 62.1 below the lower wall 56.1, which fit on the wall surfaces 122.1 and 122.2 and the insertion pin 50 keeps the forces acting on it. Rivets 57 are guided through corresponding through-openings 55.1 and 55.2 in fastening eyes 58.1 and 58.2 of the insertion pin 50 and the correspondingly assigned openings in the outer wall lower part 114 and in the outer wall upper part 116 and thus secure the position of the insertion pin 50 of the support hook 25, so that in all Forces acting in directions can be transmitted between support hooks 25 and longitudinal bars 38. The Pin guide ribs 125.1 and 125.2 are located approximately in the middle of the bottom wall 105 and top wall 106, so that there is a space in the top wall 106 offset inwards, through which the rivet 47 can grip for fastening the plate 45, as illustrated in FIG. 3 .

The support surface 41, which is delimited by the fold wall 42, serves to support the plate 45, the support surface 41 taking up approximately 2/3 of the width of the top wall 106 of the profile 100 and the fold wall 42 with its top edge 124 slightly, for example by approximately 1 mm below the tread 46 of the plate 45 or the entire scaffold floor 26. Below the upper edge 124, as a top part of the rebate wall boundary, there is formed a displacement limitation rib 136 which limits a stack centering fold 130 which is open to the outside and which is formed in that the top wall region 131 is laid down by approximately 2 mm relative to the height of the upper edge 124 . This results - as can be seen in the middle of FIG. 3 - in a centering space 135, in which the centering rib 110 engages and can move against the displacement limiting rib 136 during lateral displacement without the scaffolding floors slipping apart. It is provided that the outer surface 111 of the lower wall 105 is supported on the top of the heads 47.1 of the rivets 47, as shown in FIG. 3 in the middle.

The formation in the area of the upper corner 140 with the correspondingly spaced wall surfaces results in a considerable accumulation of material 139, which benefits the section modulus of the entire longitudinal spar 38, even if it is in a not quite as favorable range with regard to the bending forces. However, since the longitudinal bars 38 also have to absorb torsional forces, the dimensioning of the section modulus with regard to the torsional forces is also of great importance. These are well absorbed by the rectangular profile 100 with a small wall thickness of, for example, only approx. 2 to 2.5 mm, by the favorable position of the various ribs and material accumulations, even if long lengths of scaffolding floors have to be carried out with few cross connections. For this purpose, for example, the outer width 145 has an amount of approximately 45 mm, while the outer height 146 from the lower surface 111 to the support surface 41 is approximately 62 mm. The bearing surface 41 is expediently provided with a suitable profiling, for example with longitudinally extending, pointed ribs, in order to hold the plate together with a few rivets, reinforcing the entire scaffolding floor to reinforce it even against rotation.

The cheaply designed and optimized in terms of manufacture, assembly and use profile 100 can be easily produced in the form shown in FIG. 3 without special technological effort and also with others for Part of higher dimensions can be designed cheaply to bridge longer lengths. It allows the quick assembly of stable scaffolding floors with support hooks.

The summary printed below is part of the disclosure of the invention:
The profile (100) of the longitudinal spars (38 ...) of scaffolding floors (26) has a semi-cylindrical centering rib (110) in the lower outer corner (109), which in a centering space (135) at the top of each intervene below the longitudinal bar (38.3) and thus secure against lateral displacement. Inner pin guide ribs (125.1, 125.2) serve to hold an insertion pin (50) of a support hook.

Reference symbol list:

20th

stalk

21

Perforated disc

22

Support bolt

23

Support edge

25th

Support hook

25.1

"

25.2

"

26

Scaffolding floor

26.1

lower scaffold floor

26.2

upper scaffold floor

27.1

vertical leg

27.2

"

30th

Connection head

34

wedge

35

Support hook

36

Querholm

36.1

"

36.2

"

37

Support training

38.1

Longitudinal spar

38.2

"

38.3

"

38.4

"

39.1

End of 38

39.2

"

41

Contact surface

42

Folding wall

43

edge

45

plate

46

Tread of 26

47

rivet

47.1

Head of 47

50

Plug-in spigot

51.1

Side area of 50

51.2

"

52

Thickness of 50

56.1

Bottom wall

56.2

Top wall

56.3

Back wall

57

rivet

58.1

Mounting eye

58.2

"

62.1

lower fitting surface

62.2

upper fitting surface

100

profile

101

Weld

105

Bottom wall of 100

106

Top wall of 100

107

Inner wall of 100

108

Outer wall of 100

109

lower outer corner

110

Centering rib

111

Outside area of 105

112

rounded corner

113

Outside area of 107

114

Outer wall lower part

115

Outer wall middle section

116

Outer wall top

117

Vertical mating surface

118

corner

119

"

120

Holmraum

122.1

Wall surface

122.2

"

124

Upper edge of 42

125.1

Pin guide rib

125.2

"

130

Stack centering fold

131

Top wall area

135

Centering room

136

Limitation rib

139

Material accumulation

140

upper corner

145

Outside width

146

Outside height

Claims (6)

Scaffolding floor with a frame-like support structure composed of profile parts, which contains longitudinal spars, which are formed from sections of light metal extruded profile parts and wherein the profile has a vertical inner wall, a vertical outer wall, a horizontal lower wall, a horizontal upper wall and further support, Has support and reinforcement means, under which a lower rounded support rib and inner reinforcement ribs are provided and a plate forming the running surface (46) of the scaffold floor (26) is fastened to the support formation,
characterized,
that the profile (100) of the longitudinal spars (38 ..) has only a lower, in the area of the outer corner, serving for reinforcement, support and position centering, approximately semi-cylindrical centering rib and in the area of the upper, outer corner for support reinforcement at least 3 times the remaining wall thickness material accumulation (139) is formed, which extends to a lower lying fold, delimited by a folded wall (42), in which a bearing surface (41) for the plate (45) is formed, and wherein the vertical fold wall (42) extends to the upper edge (124) of the profile (100), under which a displacement-limiting rib (136) and a subsequent stacking centering fold (130) open to the outside and upward delimit a centering space (135) are formed so that when centering the centering rib (110) of the overhead longitudinal spar (38.4) in the centering space (135) the scaffolding floors (26) against lateral displacements si inserted in a cautious manner. Scaffolding floor according to one of the other claims,
characterized,
that in each case a support hook (35) with insertion pin (50) in the open end (39.1, 39.2) of the longitudinal spar (38 ...) on the inside of the outer wall (115) in the profile (100) formed fitting surface (117) is inserted and for its lateral fixing, pin guide ribs (125.1, 125.2) at a distance corresponding to the thickness (52) of the insertion pin (50) from the mating surface (117) from the top of the bottom wall (105) and the bottom of the top wall (106) protrude into the spar space (120) of the profiles (100). Scaffolding floor according to one of the other claims,
characterized,
that the distance between the pin guide ribs (125.1, 125.2) from the vertical fitting surface (117) is approximately 17 mm. Scaffolding floor according to one of the other claims,
characterized,
that the running surface (46) is about 1 to 2 mm above the upper edge (124) of the folded wall (42) or the profile (100). Scaffolding floor according to one of the other claims,
characterized,
that on the support surface (41) for the plate (45) preferably triangular prismatic locking ribs are formed. Scaffolding floor according to one of the other claims,
characterized,
that the outer wall (105) of the profile (100) has a slight, about 1 mm recessed outer wall middle part (115).

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