EP0065212A1 - Connecting element for web profiles, in particular for those used in steel constructions, preferably I-beams - Google Patents

Abstract

A connecting element for web profiles, in particular for structural steel web profiles used in steel constructions, preferably I-beams which, for example, can be connected to one another at the joints by the connecting element and form columns and horizontal members of a rigid supporting frame of a hall construction which consists of a plurality of supporting frames, mountable one behind the other and connected to one another by purlins, and can be lined with a wall and roof skin. According to the invention, the connecting element is designed as a bracket, the free ends of which can be connected in each case to the webs of mutually facing ends of the web profiles. Preferably, two brackets arranged parallel to one another are arranged at each joint, the ends of which brackets receive the respectively assigned webs of the web profiles between them. Fig. 1 illustrates the inventive concept with connecting elements arranged at the joints. <IMAGE>

Description

. The invention relates to a connecting element for web profiles, in particular for shaped steel web profiles which can be used in steel construction, preferably I-beams, which, for example, connected to one another at the nodes by the connecting element, supports and bolts of a rigid supporting frame which can be set up from a plurality of one behind the other and connected by greases Form the supporting frame of the existing hall structure, which can be clad with a wall or roof skin.

Hall structures made of rigid supporting frames are known. Cut supports are used for the supports and transoms of the support frames and for the purlins that connect the erected support frames. After appropriate preparation, they are assembled on site and placed on a foundation.

Hall structures of the aforementioned type are mainly used in agriculture, preferably for poultry farming. The construction with a rigid supporting frame has the advantage that relatively low construction costs are incurred per m ^{2 of} built-up area. All components can be prepared for final assembly and the entire structure disassembled in the form of a set of components to be transported to the installation site, where it is then placed in front can also be erected easily by unskilled workers.

Since the transport costs have a significant impact on the final construction costs, the aim is to keep the weight and volume of a component set as low as possible in order to reduce the transport costs.

However, it is important to note that the statics of the building to be erected are not adversely affected by lighter or smaller components. Endangered cross sections within the rigid supporting frame can be reinforced by attaching gusset plates, struts, etc., but the assembly of these parts increases the construction effort and the transport volume. Since the rigid supporting frames are clad inside and outside with a wall or roof skin, between which insulating material can also be introduced, the arrangement of protruding struts and gusset plates is further disadvantageous for such cladding, since this involves the attachment of the cladding, e.g. Aluminum sheets, complicate because corresponding projections have to be provided for the projections, and moreover the gusset plates and struts disadvantageously form cold or heat bridges between a converted interior of the barn and the surroundings.

The invention has for its object to provide a connecting element for web profiles, which with sufficient static strength of the support frame thus formed low weight and transport volume of all components and a Easy assembly on site guaranteed.

This object has been achieved according to the invention by a connecting element which is designed as a tab, the free ends of which can each be connected to the webs of mutually facing ends of the web profiles.

The connecting element designed as a tab connects e.g. Support and transom of a rigid support frame in the area of the frame corner as well as the two transoms in the ridge area. This has the advantage that web profiles, for example I-beams, can only be cut to length for supports and transoms, but can otherwise remain unprocessed. The connection of the tabs with the webs of the respective web profiles also has the advantage that no protruding components occur in the rigid support frame, so that a smooth cladding wall or roof skin, e.g. made of aluminum, can be easily attached.

Preferably, two lugs arranged parallel to each other are provided at each node, the ends of which accommodate the respectively assigned webs of the web profiles between them. This increases the static strength of the rigid support frame, because the loads on the frame corner and ridge are absorbed by two brackets each. The tabs and the webs of the web profiles received between them are joined with through screws. The screw connection facilitates assembly, since such work can also be carried out by non-trained assistants. The arrangement of the holes required for the screw connection in the webs of the web profiles to be connected to one another can also be carried out beforehand in a workshop. However, it is also possible to use the already drilled tabs as drilling templates and to drill the holes in the webs on the construction site.

For the screw connections, high-strength screws are preferably used, which can be tightened to such an extent that a high static friction arises between the webs and the ends of the respective tabs covering them on both sides, which prevents excessive stress on the holes and screws, since these alone can cause shear forces to occur the given perforation ratio can not accommodate.

In lighter steel structures, each tab can also be a component made from sheet metal blanks, which e.g. by pressing in reinforcing beads or the like may meet the requirements regarding the static strength of a support frame formed with it.

For larger structures with a corresponding static strength, for which, for example, the use of I-beams for supports and transoms is necessary, for example in accordance with the form IPE 160, it is provided that each bracket has a respective node, the frame corner or the ridge with respect to the Angle at which the Stegpro file to each other, adapted casting is. high-quality castings are advantageously very rigid, so that the stresses occurring at the frame corner or the ridge can be easily absorbed, and yet the straps can be dimensioned somewhat smaller than an equivalent component made of steel.

For a hall structure, a large number of rigid support frames are set up one behind the other, each support frame always having the same brackets. Thus, a set of components comprising a few components can be offered, which advantageously consists of the same web profiles for transoms and supports and comprises the corresponding number of tabs for the connecting elements to be used on the frame corners and the ridge. The dimensioning of the cast parts depends on the dimensioning of the web profiles used; a smaller I-beam, smaller tabs are sufficient and vice versa.

To increase the static strength of a hall structure formed with the connecting elements according to the invention, it is provided that each bracket is formed approximately U-shaped by integrally formed reinforcing ribs. The reinforcing ribs have their largest elevation in the middle of the tab.

Since the brackets are symmetrical components, two identical brackets, for example for a frame corner, are put together so that they each have the webs of the web profiles to be connected to one another with the smooth undersides facing one another enclose between them, with the integrally formed, then outwardly projecting reinforcing ribs, the tabs, which are firmly screwed to the web profiles, again form an approximately I-shaped profile which can absorb the high loads in the frame corner or in the ridge.

In addition to the reinforcing ribs running longitudinally at the edges of the tabs, further transverse ribs can be provided in order to further reinforce the tab made of high-quality gray cast iron or cast steel.

The use of the connecting elements according to the invention enables the use of small web profiles, since the ends of the tabs cover and reinforce a relatively long area of the webs of the web profiles. If there is a support and transom e.g. made of a molded steel from the IPE 160 series, the ends of the tabs in the frame corner each cover a section of approx. 280 mm in length of the web of the support as well as the web of the transom, e.g. the endangered cross-section of the support is precisely offset by this 280 mm towards the base of the support and thus the lower load tapped in this offset area from the bending moment line of the support also enables the dimensions of the profiles to be reduced, namely, in the case of the design mentioned, an IPE 160, although an IPE 200 would actually be necessary after the maximum occurring in the bending moment line. The actual maximum of the bending moment line intercepts the connecting element according to the invention located in the corner of the frame.

. Es zeigen:

• Fig 1. eine schematische Seitenansicht eines starren Tragrahmens eines Hallenbauwerks,
• Fig. 2 einen Schnitt entlang der Linie II-II in Fig: 1 durch das am First des Tragrahmens die beiden Riegel verbindende Verbindungselemente,
• Fig. 3 den Firstbereich des Tragrahmens gem. Fig. 1 in vergrößerter Darstellung und
• Fig. 4 die linke Rahmenecke des Tragrahmens gem. Fig. 1 in vergrößerter Darstellung.

An embodiment of the invention, from which further inventive features result, is in the drawing

. Show it:

• 1 is a schematic side view of a rigid support frame of a hall structure,
• 2 shows a section along the line II-II in FIG. 1 through the connecting elements connecting the two bolts on the ridge of the support frame,
• Fig. 3 shows the ridge area of the support frame. Fig. 1 in an enlarged view and
• Fig. 4 shows the left frame corner of the support frame. Fig. 1 in an enlarged view.

In Fig. 1, a support frame for a hall structure is shown in side view. Several such support frames are placed one behind the other.

Each support frame consists of left support 1 and right support 2 as well as left lock 3 and right lock 4.

Supports 1, 2 and transoms 3, 4 are shaped steels cut to length, for example I-beams from the IPE 160 series. Supports 1, 2 and transoms 3, 4 are in the area of the frame corners 5 and 6 respectively as tabs 7 and 8 trained connecting elements connected to each other by the ends 9 and 10 or 11 and 12 of the tabs, which are at a predetermined angle to one another, being screwed to the webs of the I-beams of supports and bolts.

Each end of each tab is screwed to the associated web with four screws.

In the ridge area 13, the two bars 3 and 4 are of the same type by a connecting element formed from appropriately shaped tabs 14 Way also connected to each other by four screws.

15 designates Z-profile purlins, which connect the support frames that are set up one behind the other. The outside and inside of the support frame are covered with a wall or roof skin (not shown) throughout.

In FIG. 2, a section through the ridge region 13 of the support frame along the line II-II in FIG. 1 is shown enlarged. From this illustration it can be seen that a connecting element consists of two mutually opposing tabs 14 and 17 which clamp between them the web 18 of the I-beam of the bolt 4 and the web 19 of the I-beam for the bolt 3 and that the tabs 14 and 17 are pulled together by means of the through screws 20.

In a similar manner, two tabs are each arranged as a connecting element in each frame corner on the frame corners 5 and 6 between the bars 3, 4 and the supports 1, 2 in FIG. 1.

3 shows the ridge area 13 with the tab 14 connecting the two bars 3 and 4 in an enlarged side view. From this illustration it can be seen that the tab has longitudinal reinforcing ribs 21 and 22 at its upper and lower edges, as a result of which a connecting element composed of two tabs has approximately the shape of an assembled I-profile.

The reinforcing ribs are arranged such that, rising from the ends of the tab 14, they rise in the middle of the tab in the actual ridge Area between the two bars 3 and 4 have the maximum of their elevation, as indicated in the sectional profiling indicated by dashed lines.

4 the left frame corner 5 is shown in an enlarged view. The tab 7 and a similar, invisible tab arranged behind the plane of the drawing are screwed at the ends 9 and 10 to the webs of the I-beams for the support 1 and the latch 3, as shown in FIG. 2.

The tab 7 is also a component made of high-quality gray cast iron or cast steel and two tabs enclosing the webs of the support 1 and the latch 3 form a connecting element.

Just as the tab 14 acc. Fig. 3 also have the tabs 7 and 8 of the frame corners on the longitudinal edge formed reinforcing ribs 23, 24, the elevation of which also increases from the free ends 9 and 10 to the center. A transverse rib-like web 25 is arranged in this central area in the kink area of the tab, in which the highest load of the connecting elements also occurs.

Claims (7)

1.Connection element for web profiles, in particular for shaped steel web profiles which can be used in steel construction, preferably I-beams, which, for example, connected to one another at the nodes by the connecting element, supports and bolts of a rigid supporting frame of a supporting frame which can be set up in series and connected by purlins Form a hall structure that can be clad with a wall or roof skin,
characterized ,
that it is designed as a tab (7, 8, 14, 17), the free ends (9, 10, 11, 12) of which can be connected to the webs facing ends of the web profiles. 2. Connecting element according to claim 1, characterized in that two parallel tabs (7, 8, 14, 17) are provided at each node, the ends (9, 10, 11, 12) of the respective associated webs of the web profiles between them record, tape. 3. Connecting element according to one of the preceding claims, characterized in that tabs (7, 8, 14, 17) and webs of the web profiles received between them are drawn together with continuous screws (20). 4. Connecting element according to one of the preceding claims, characterized in that each tab (7, 8, 14, 17) a the respective Kno tenpunkt (frame corner 5 or ridge area 13) is adapted casting with respect to the angle at which the web profiles are to each other. 5. Connecting element according to one of claims 1-4, characterized in that each tab (7, 8, 14, 17) is formed by integrally formed reinforcing ribs (21, 22, 23, 24) similar to an approximately U-shaped shell. 6. Connecting element according to claim 5, characterized in that each reinforcing rib (21, 22, 23, 24) with respect to its elevation from the tab (7, 8, 14, 17) from the ends to the center of the tab is formed increasing. 7. Connecting element according to one of claims 5 and 6, characterized in that each tab (7, 8, 14, 17) between the longitudinally extending reinforcing ribs (21, 22, 23, 24) has further transverse ribs (25).

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