FI63109C - STEGE ELLER LIKNANDE FACKVERKSKONSTRUKTION - Google Patents

Description

Ιΰδ? Π [Β] (idKULULUTUSJULKA.SU

jJSjft LJ 1 'UTLÄGGNINGSSKRIFT 6 6 I O 9 C (45) Γ' 'Λ r; "r; r: l iy 11 04 1983 ^ ^ ^ (51) κ * .ιΐι.3 / ι« .α.3 E 06 C 7/08 ENGLISH — Fl N LAN D pi) ht ^ tiw ^ -NeKwaw * , 3313/72 (22) Hak «nl« pUvi — .Ameknlngidai 23.11.72 ^ ^ (23) Allcuptlvt — GlM | h «nyt | 23.11.72 (41) Tullut julklului - Bllvlt offMtlig 2k .05.73

National Board of Patents and Registration NihUvilulp ^ on | «ku ^ kteun p * m.- 31 12 82

Patent- and Register-Register 'Amök »n utlagd och utLskrtfUn pubiioirad * (32) (33) (31) Pyrit» y «υο ^ .- Βη ** prtortut 23 -11.71

Switzerland-Switzerland (CH) 17018/71 (71) Ah Carl Keijser & Co, Tunhytorpsgatan 1, Västeräs, Sweden-Sweden (SE) (72) Erik Arne Engvall, Västeras, Sweden-Sweden (SE),

Thomas Ritscher, Adlisvil, Switzerland-Schweiz (CH) (7 ^) Oy Kolster Ah (5U) Ladders or similar truss structure - Stege eller liknande fackverkskonstruktion

The invention relates to support structures, i. mechanically stable and load-bearing arrangements comprising at least two longitudinal beams substantially parallel and connected to each other by a plurality of support members, preferably spaced at regular intervals. Such support structures are well known in the mechanical field and are used for purposes such as scaffolding, railings, guardrails, electric cable supports, ladders and the like.

The beams of previous support structures in the art are generally made of various structural materials, such as wood or metal, and have a substantially circular or rectangular cross-section. For metal beams, profiles or cross-sectional shapes resembling I, H, or double T shapes are commonly used. In such beam profiles, the cross-sectional shape comprises two flanges arranged in parallel, which are connected together by a transverse piece or a web. Previous support structures, such as ladders made of structurally light metals or metal alloys and having beams or beams with such a profile, have satisfactory flexural stiffness and torsional strength of 63109 over relatively small cross-sectional areas. However, the lateral stiffness is generally unsatisfactory. However, the latter requirement is important not only for ladders, especially fairly long, light ladders, but also for said types of support structures where the load does not act primarily in the longitudinal direction of the beams, i. not vertically in relation to the supporting parts, as is the case with guardrails, fences or railings, etc. When relatively light, good quality and therefore relatively expensive structural materials such as aluminum alloys are used in all these cases, supporting structures parallel or vertically to the longitudinal direction of the beams.

It has been found that simply increasing the cross-sectional area of the beams in general or in certain areas of stress stress cannot generally provide a sufficient improvement in bending and torsional strength to justify the resulting higher weight and structural material cost, and that a particularly important area is between the joints of the beams. structure. The closest remedy that comes to mind, e.g., welding support parts to beams with inert gas, is too expensive for commercial production, although it helps to increase overall strength.

It is known from Swedish publication 308 182 for ladders consisting of I-shaped beams and hollow rectangular support parts to attach the support parts to the web part of the beam by inserting the ends of the support parts into the openings in the web and pushing the ends into flanges.

It has been found that increasing the overall mechanical stability of light metal such as aluminum alloy ladders or similar truss structures can be achieved without substantially increasing weight and without expensive fabrication methods by using a new type of beam profile and attaching the ends of support members to a specific location.

The present invention therefore relates to a ladder or similar truss structure comprising two longitudinally integral and substantially parallel beams of a lightweight metal alloy and spaced apart and substantially perpendicularly perpendicularly perpendicularly hollow support members extending substantially perpendicular thereto. in the cross-sectional shape, wherein the beams have a web located between flanges extending substantially perpendicular to the web 63109 and the web having openings for securing the support members by pushing said support members into flanges abutting the edges of the openings in the web substantially on each side of the web, of uniform thickness and from the middle part extending towards the flanges, the thickness of which gradually increases from the middle part and the total length of the side parts being at least 1/5 of the total length of the web. The structure according to the invention is characterized in that at least one of the flanges located around the edges of the openings extends against the web part, pressing towards the flanges of the beam in the transition between the middle part and the side parts of the web.

Comparative experiments between the structure according to the invention and the structure of the Swedish publication 308 182 have shown (a) a considerable improvement in flexural strength (as measured by measuring the deformation of a structure same structure as above, but load only on the second beam) and (c) torsional strength generally improved. As an example, the lateral bending stiffness of the structure according to the invention turned out to be eight times higher than that of the reference structure. The tests complied with Danish industry standards (DS 2069.0), which are considered to be the most stringent of the official testing regulations in this field.

The increase in width or thickness of the web side portions is substantially uniform and can be either linear or geometric, as explained in more detail below. Preferably, the thickness of the side portions increases in a wedge-like manner, with the opposite side surfaces of each side portion containing an angle 2d of about 10 ° to about 35 °, preferably 14 ° to 24 °.

In addition to improving the above-mentioned lateral bending and torsional stability without increasing the weight of the structure and without expensive manufacturing processes, in a preferred embodiment of the invention the gradually increasing side portions can be used to flanges so as to extend against the side members. In this embodiment, one or both of the flanges extend overlapping the side portions.

The invention will be described in detail with reference to the accompanying drawings, in which: Figure 1 shows a semi-schematic, fragmentary perspective view of an embodiment of a new beam of a support structure according to the invention; Fig. 2 shows a schematic, fragmentary cross-sectional view of a side part of a web and an adjacent flange in an embodiment of a new beam of support structures according to the invention; Fig. 3 shows a schematic / broken cross-sectional view of another shape of the side part of the web and the adjacent flange in the new beam of the support structures according to the invention; Fig. 4 shows a diagram of the general shape of the H-beam showing the aspect ratios of the preferred beams according to the invention; Fig. 5 shows a schematic, fragmentary cross-sectional view of an embodiment of a locking relationship between a beam and a support part in a structure according to the invention; and Figure 6 shows a fragmentary sectional view of the locking relationship of the beam and the support part in the preferred structure according to the invention.

Figure 1 shows a beam 11 comprising a web 12 consisting of a central portion 13 and two side portions 14, 15. The central portion 13 of the web has a substantially uniform width, while the width of each side portion 14, 15 of the web increases from the central portion of the web to adjacent flanges 17,19. That is, the side portions 14, 15 of the web taper from the area adjacent to the flanges 17, 19 towards the center portion 13 of the web. As will be explained in more detail below, the conical shape shown in Fig. 1 is slightly exaggerated for ease of understanding, i. it shows a cone of about 40 ° instead of the preferred cone shape with an angle of about 10 ° to about 35 °, with the preferred range being 14 ° -24 °.

The central part 13 of the web is provided with a plurality of openings 6, three of which are shown in the drawing. It will be appreciated that the actual number of openings, their spacing, shape and size will depend on the desired number of support members per unit length of the particular structure, the overall length of the structure and the cross-sectional shape of the support members. The 16 square shapes of the openings are considered the best. The flanges 17, 19 adjacent the side portions 14, 15 of the web can be shaped as shown, i. so that the ends of the flanges 18, 20 are bent inwards towards the center of the web, but other shapes, e.g. arcuate, straight, etc., are equally suitable. Thus, the exact shape of the flanges is not a critical feature. .

The support structure according to the invention thus comprises at least two substantially identical beams of this type oriented substantially in parallel, as described above. In practice, e.g. in a ladder, two such beams are placed so that the inner side surface 131 of the web portion is parallel to the corresponding inner side of the web portion of the second beam. The positions, shapes and distances of the openings 16 are also substantially the same in the two beams, since the pair of beams must be connected together by means of supports. However, more than two beams can be placed in a support structure, e.g. cable supporting structures, etc.

The beams are preferably made of an extrudable light metal, e.g. an aluminum alloy, the type of which is discussed in more detail below.

Figure 2 shows a cross-sectional shape of the tapered side part 6 of the web, in which the width of the side part 6 of the web increases non-linearly from the region 4, i. from the end of the central part 2 of the web, towards the adjacent flange 3. The surfaces 1a, 1b of the side part 6 of the web follow approximately the shape of logarithmic coils extending to the "inwards" bent ends 5a, 5b of the flange 3. Although the shape of the logarithmic helix is well suited for the side portions of the beam web, one skilled in the art can easily devise various variations of the "ideal" curvature depending on parameters such as beam size, support member size, and alloy properties. However, the curved shape of the side surfaces of the beam in the region of the side portions of the web is not critical to the invention. It is clear that only half of the beam profile is shown in Figure 2.

Figure 3 shows a cross-sectional shape of the beam which can be considered as closely resembling the shape shown in Figure 2. The modification here is essentially due to the practical requirements for the manufacture of such beams, e.g. when light metal alloys are pressed through a die. In Fig. 2, the transition between the flange 31 and the web side 22 begins with an arcuate shape, generally indicated by the number 42, which is the end of the web side and the beginning of the web center 21 having a length S ^. wedge-shaped "and is characterized by a wedge angle twice the angle CK shown in Figure 3. In practical embodiments and in the forms described in more detail below, the value of the wedge angle (2 x oi) is generally 10 ° -35 °, preferably 15 ° -30 ° , and an angle of 14 ° -24 ° is preferred.

The diagram shown in Figure 4 will now explain some of the preferred dimensions of the beam profiles suitable for the invention.

The ratio of the total length SGL of the web 22 to the length SML of the central part of the web is generally in the range 1.0-2.5, preferably in the range 1.2-2.2. The width or thickness of the central portion 21 of the web 6 63109 is substantially uniform and the increase in width in the side portion S.TT of the web 22, which portion may be termed wedge-shaped, begins at SD indicated by the number 50. Both sides S..T of the web generally have the same length. It is also preferred that the ratio of the total length of the web S ^ T to the size of the two side portions of the web

VjJLi to the sum of the lengths, i.e. the ratio S „T: 2S, rT, is 1-4 preferably 1.9-3.4

VjLi between VLi.

The ratio of the total length of the web 22 to the length of the flanges 31, i. the ratio S „T: BT, is preferably in the range 1.2-2.0 and most preferably 1.4 and

VjLi Li 1.9 between. The ratio of S_T to the width (S ^) of the central portion 21 of the web 22, i.

\ jLi D

the ratio is preferably between 15 and 40, most preferably between 20 and 37. For practical evaluation, the inverse ratio S_: S ^ T is used for general characterization and this ratio is preferably in the range 0.04-0.02.

The ratio of the width SQ of the web to the width BQ of the flanges 31 is preferably 2.0-0.5, most preferably 1.7-0.6, with a lower limit of about 1 being suitable for most purposes.

The preferred ratios described above in connection with Figure 4 are particularly advantageous for beams made of compressible light metal alloys on an aluminum base, e.g. by extrusion through a die. The support parts are preferably made of the same materials and can also be of the extrusion type known per se. Typical examples of such alloys are AlMgSi alloys as defined in U.S. Pat. Standards No. 6351/6 or the corresponding Swedish Standards No. 4212-6. The strength (tensile strength) of the aluminum alloys used for the beams and support members should generally be at least about 25 kp / mm (corresponding substantially to a Webster B hardness of at least about 16). The strength of the alloy should not be more than 10% lower than the values just mentioned.

As mentioned above, the dimensions of the support part are proportional to the length of the central part of the web. The center portion of the web generally has substantially the same length or is slightly less than the spacing of the contact surfaces of the rectangular support portions. The term "contact surface" means that part of the ends of the support parts which contacts the side of the web of the beam. This contact surface is generally part of the flange portion of the support member, e.g., a bent bulge or edge formed around the circumference of the support member, and is usually similar but slightly larger than the cross section of the support member.

In general, the preferred cross-sectional shape of the support members 7 63109 is substantially rectangular, and a square cross-section is even more preferred. The edges can be rounded as needed.

It should be noted that the support parts may have a grooved outer surface or may be provided with other means of improving adhesion, e.g. pavements, especially if the structure forms a ladder.

The following describes the locking relationship between the support members and the beams with reference to Figures 5 and 6. In the semi-schematic cross-sectional view shown in Fig. 5, the end 60 of the support member 61 comprises an inner flange 62 and an outer flange 63 which firmly engage the web center portion 65 at the outer ends 621, 631 of the flanges 62, 63 in contact with the web side portions 641, 642.

In practice, this can be achieved, e.g., as shown in Fig. 6, by first providing the end 481 of the support member 48 with a bent edge 49 which forms an inner flange. The remaining free end is then placed in the opening (16, Fig. 1) in the central portion 52 of the neck (13 in Fig. 1) so that it extends therethrough. A second bent edge 51 is now formed at the end 481, e.g. by pressing and according to the ductility of the material used. By supporting the bent edge 49 against the pressure applied laterally at the head 481 to form the bent edge 51 and to press both edges 49, 51 even further toward the center portion 52 of the web, a very strong locking engagement can be provided between the support portion and the beam web. It is generally preferred that the edges 49, 51 be compressed and twisted to such an extent that the flanges thus formed extend over the side portions 46 of the web so as to form a wedged connection due to the increasing width of the side portions 46 of the web. With said types of pressable light metals, the locking connection thus obtained between the support part and the beam considerably contributes to the bending and torsional strength of the support structure.

It is understood that in the Figures the second side 5 and 6 shown the structure of the support member / bar-connection is repeated or are prepared at the same time the second group at a site or sites as required. When making ladders, it is preferred that the joint be made at both ends of each support member at the same time.

Comparative experiments with the support structures according to the invention, e.g. as shown in Figure 6, where the support structures had the same basic structure but the beam was normal (i.e. the width of the web side parts did not increase as shown here), have shown that a) flexural strength is significantly improved ( where 8 63109 deformation has been measured in a structure consisting of two substantially parallel beams and several support members connecting the beams at regular intervals and the test load is applied to both beams), b) the lateral bending strength is significantly improved (structure as above, load applied to only one beam), and (c) torsional strength has generally improved. For example, the side bending strength of the structure according to the invention was about eight times higher than that of the comparable structure. The test methods used were in accordance with Danish industry standards (DS 2069.0), which are considered to be the most stringent official tests in this field.

Although the above explanation mainly concerns support structures for ladders made of compressible lightweight hiles, it is clear that many changes are possible in terms of the use of the structures, the materials used in their construction, the specified shapes, dimensions and shapes. According to the invention, it is possible, for example, to develop structures which contain more than two beams, e.g. by moving the support parts between the two beams against the support parts of the second beam and the next beam. In addition, other structural materials can be used for both beams and support parts, e.g. artificial polymers, e.g. thermoplastics, whether or not reinforced with e.g. glass fibers.

Claims (2)

9 63109 A ladder or similar truss structure comprising two longitudinal beams (11) of one-piece and substantially parallel, preferably compressible light metal alloy, and evenly spaced and substantially perpendicularly hollow support members (48) between the beams, which are also an extrudable light metal alloy and substantially rectangular in cross-sectional shape, the beams having a web (12) located between flanges (17, 19) extending substantially perpendicular to the web and having openings (16) in the web for securing the support members by pushing the support members 51) resting on the edges of the openings in the web on both sides of the web, the web (12) consisting of a central portion (13) which is substantially uniform in thickness and side portions (14,15) extending from the central portion towards the flanges (17, 19), the thickness of which gradually increases from the middle and where the p the total length (2 x SVL) of the webs (14, 15) is at least 1/5 of the total length (S „T) of the web (13), characterized in that at least one of the flanges (49, 51) located around the edges of the openings u-slots the web portion (12) pressing against the beam flanges (17, 19) at least at the overhang between the central part (13) of the web and the side parts (14, 15). Ladder according to Claim 1, characterized in that the thickness of the side parts (14, 15) increases in a wedge-like manner and that the opposite side surfaces of each side part contain an angle (2 ° C) of about 10 ° to about 35 °, preferably 14 ° to 24 °.