DE102008028672A1 - Constructional element for building i.e. transportable building, has connecting element inserted between homogeneous profiles, and bar interconnecting set of side pieces into level spaced to common level of another set of side pieces - Google Patents

Abstract

The element has homogeneous profiles, and profile cross sections are arranged in a mirror-image manner. A connecting element is inserted between the profiles. The profile cross sections of the profiles consist of two rectangular brackets (10) mirror-imaged to each other. A set of side pieces of the brackets is arranged parallel to each other, and another set of side pieces is arranged in a common level. A bar interconnects the former set of side pieces into a level spaced to the common level of the latter set of side pieces.

Description

The The invention relates to construction elements for buildings, including transportable Buildings consisting of similar first and second profiles, whose profile cross-sections are arranged mirror-inverted, as well as at least one connecting element inserted between the profiles.

to Creation of building structures by type of structures often prefabricated profiles used, z. B. steel beams. To reduce costs for production, Transport and storage is sought, as uniform as possible To use profiles, and if possible for both the vertical Construction elements of the structure, so its supports, such as also for the horizontal construction elements of the structure, so its Trusses or cross members, use. In practice, however, this is difficult connected because the static requirements, for example, to a Crossbeams stressed on bending loads are different from those at a vertical support, which is usually designed to absorb pressure loads is.

Of the Invention is based on the object, one for buildings including transportable Buildings suitable design element to develop, which high level Unification of the items used with the advantage of easy adaptation to the vertical and horizontal elements combines different load conditions.

to solution is in a construction element of the type specified proposed that the profile cross-section of each profile is composed from two mirror-inverted rectangular angles, each of which first legs are arranged parallel and spaced from one another and their respective second legs are arranged in a common plane are, at least one web, which in one to the plane of the second leg spaced plane connects the first leg with each other.

advantageous Embodiments of the construction element that used for it similar profiles and the possible uses in vertical Support and horizontal cross members are in the subclaims specified.

The The invention as well as further details and advantages are described below based on the associated Drawings described. Show:

1 a perspective view of a composed of vertical and horizontal beams supporting structure for the construction of buildings, including transportable buildings;

2 a horizontal cross section through a vertical support of the structure;

3 a vertical cross section through a horizontal cross member of the structure;

4 a cross section through a single profile, which is used in the supports and cross beams;

5 a cross section through a differently shaped, single profile, which is used in the supports and cross members;

6 an exploded perspective view in the region of a node between the vertical support and horizontal cross member and

7 a longitudinal section through the node-side end of the in 6 illustrated horizontal cross member.

1 shows the node region of a structure, which is composed of carriers described in more detail below steel profiles. At the illustrated node is a connection of a vertical support bracket 1 with up to four horizontal cross members 2 instead of. The truss node is a central crosshead 3 ,

The structural elements used in the structure support and cross member are in the 2 and 3 reproduced individually and in sectional views. It can be seen that both the in 2 illustrated support 1 as well as in 3 illustrated cross member 2 from two profiles each 5 consist. These are in the transverse direction R, ie, to each other, via one or more connecting elements 6 supported against each other and screwed. All individual profiles 5 ie both the two profiles 5 the prop 1 as well as the two profiles 5 of the crossbeam 2 , are identically designed. This simplifies the carrier system in terms of manufacturing costs, transportation and warehousing.

The 2 and 3 show that in both cases the same first and second profiles 5 with respect to the plane of symmetry S are mirror images of each other. In one case, namely that of the support 2 , results in a substantially compact, cross-shaped cross section for high pressure and buckling loads, whereas in the other case after 3 a rather open cross-section in the form of a horizontal H is achieved, which shows a good load behavior against bending forces.

In 4 is a single one for the Kon Structural elements Support and cross members used profiles 5 shown. The profile cross section produced from an extruded profile consists of two rectangular angles 10 , a bridge connecting them 15 as well as short ribs 20 at the rectangle angles 10 , All of these profile sections are integrally formed, for example by rolling the profile 5 in a suitable cold rolling process. The preferred material is steel, but the profile can be 5 also z. B. from light metal alloys, or produce in continuous casting.

Each of the two rectangular shaped L-shaped cross-section 10 the profile cross-section is made up of a first leg 11 and a rectangular, same length second leg 12 together. Both thighs 11 . 12 So they have the same width B. The arrangement of the two rectangular angles 10 is further such that their respective second leg 12 are arranged in a common plane E. The first leg each 11 are arranged parallel to each other and at a distance A.

The jetty 15 connects the two first legs 11 together. The level in which the jetty 15 between the first thighs 11 extends, is significantly spaced from that plane E, in which the second leg 12 extend. This way is located between the first thighs 11 , separated by the jetty 15 , a first rectangular channel 16 and a second rectangular channel 17 , The channels 16 . 17 are therefore open in opposite directions and they have the same depth T. This means at the same time that the jetty 15 there on the first leg 11 meets where the middle of its width B is located. The length of the bridge 15 is equal to the distance A of the two first legs 11 to each other.

The jetty 15 is at regular intervals with openings, preferably holes 23 for passing screws or other fasteners provided. The holes 23 extend parallel to the first legs 11 ,

From the outside 21 every other thigh 12 stands one rib each 20 outwards. The rib 20 in this case sits on the middle of the outer width B of the respective second leg 12 , The height H of the rib 20 is at most equal to half the distance A, the outer sides of the first leg 11 to each other.

When using the construction element as a support, as in 2 shown, the two profiles 5 so arranged in mirror image, that in each case the second leg 12 their square angle 10 facing each other. Here are the channels at the same time 16 ( 4 ) facing each other, whereby each connecting element 6 with his ends 7 into the channels 16 put into it. By means of screws 24 passing through the holes 23 ( 4 ) are put through, the webs 15 with the connecting element 6 screwed. Alternatively, a continuous screw can be used, which both the connecting element 6 as well as the footbridges 15 both profiles 5 interspersed.

When using the structural element as a vertical support can be a mutual, frontal contact 26 the at the two profiles 5 molded ribs 20 be beneficial. This juxtaposition increases the strength of the column cross-section.

When using the construction element to form a cross member according to 3 become the two profiles 5 arranged in mirror image in such a way that in each case the second leg 12 their square angle 10 turned away from each other, and the legs 12 extend horizontally. In this version, each of the channels stand 17 ( 4 ) open opposite, leaving the ends 7 the connecting elements 6 in these channels 17 to sit. Again, by means of appropriate screws 24 the screw connection of the connecting elements 6 with the jetties 15 the profiles. In order to avoid excessive heat transfer in the plane of symmetry S, a single screw connection is to be striven for in this case, ie each connecting element 6 is about first screws 24 with the one footbridge 15 , and about other screws 24 with the other jetty 15 screwed.

Also, to avoid thermal bridges over the plane of symmetry S over the connecting element 6 consist of a material with low thermal conductivity, z. B. from a cuboid block of insulating hard plastic. This is particularly advantageous if the cross member described carries a floor ceiling of a terrain, and a high level of heat dissipation of the projectiles is sought. A direct heat transfer between the existing metal profiles 5 is prevented by the profiles 5 one by the length of the connecting elements 6 given distance A1 to each other and therefore a heat conduction exclusively via the connecting elements 6 , but not directly from profile to profile.

5 shows one opposite 4 modified profile 5 with a total of two between the first thighs 11 extending and mutually parallel ridges 15 , The depth T of the two channels 16 . 17 is therefore lower.

6 shows similar to the 1 the vertical support 1 and one of the crossbeams 2 in the node area. The crosshead 3 of the knot sits on the stut ze 2 on, wherein the positive connection by a vertical cross connector 30 is reached. This sticks out in the 2 recognizable, cross-sectionally shaped central channel of the support 1 , The cross connector 30 corresponds materially to the already described fasteners 6 , In particular, the connecting elements 6 , deviating from the illustration in 2 and 3 , also have a four-armed cross-section. By means of another cross connector 31 can be another vertical support for the realization of another building floor 1 on top of the crosshead 3 put on.

For leveling or for adjusting the floor level of the upper floor one can through the cross connector 30 . 31 centered cross plate 32 between crosshead 3 and prop 1 to be ordered. The four tails 33 the cross plate 32 have such a width B1 that they are in the assembled state between the two ribs 20 of the crossbeam 2 add, and so the orientation of the respective cross member 2 to the crosshead 3 improve.

To connect to the node is in accordance with the 6 and 7 in the end of the crossbeam 2 a connection plate 35 can be inserted in the longitudinal direction. This is one with positive locking elements 37 provided vertical plate which extends partially longitudinally into the end of the cross member, and with its remaining length freely from the front side 36 the cross member protrudes. On this free length are at the connection plate 35 as positive locking elements 37 formed two superimposed, each open down hook. The hooks can be in horizontal bolts 39 of the crosshead 3 hang so as to cross the beam 2 positive fit on the crosshead 3 to fix.

For a play-free fit is the connection plate 35 on her in the end of the cross member 2 projecting part length with a lower slot 40a and an upper slot 40b Mistake. Every slot 40a . 40b Takes exactly one of the two bars 15 the profiles 5 on which the cross member 2 is composed. The slots 40a . 40b divide it into the end of the crossbeam 2 protruding part of the connecting plate 35 into a wider middle section 41 and narrower upper and lower sections 42 respectively. 43 , The width B2 of the sections 42 . 43 is preferably equal to the depth T of the channel 16 (see. 4 ), which are the hooks 37 having connecting plate 35 up and down not over the outsides 21 survives.

1

support

2

crossbeam

3

Phillips

5

profile

6

connecting element

7

The End

10

square angle

11

first leg

12

second leg

15

web

16

channel

17

channel

20

rib

21

outside

23

drilling

24

screw

26

Contact

30

cross connector

31

cross connector

32

cross plate

33

tail

35

connecting plate

36

front

37

Form-fitting element, hook

39

bolt

40a

slot

40b

slot

41

section

42

section

43

section

A

distance

A1

distance

B

external width

B1

width

B2

width

e

level

H

height

R

direction

S

plane of symmetry

T

depth

Claims (15)

Construction element for buildings, including transportable buildings, consisting of similar first and second profiles ( 5 ), whose profile cross-sections are arranged mirror-inverted, and at least one between the profiles ( 5 ) used connecting element ( 6 ), characterized in that - the profile cross-section of each profile ( 5 ) consists of two mirror-inverted rectangular angles ( 10 ), whose respective first legs ( 11 ) are arranged parallel to one another and at a distance (A) from each other and their respective second legs ( 12 ) are arranged in a common plane (E), - at least one web ( 15 ) which in one to the plane (E) of the second leg ( 12 ) spaced plane the first leg ( 11 ) connects to each other. Construction element according to claim 1, characterized in that the Verbindungse lement ( 6 ) with its ends ( 7 ) in each case in the distance (A) between the first legs ( 11 ). Construction element according to claim 2, characterized in that the connecting element ( 6 ) at the jetties ( 15 ) of both profiles ( 5 ) is supported. Construction element according to one of claims 1-3, characterized by two in the distance (A) between the first legs ( 11 ) and in opposite directions open channels ( 16 . 17 ). Construction element according to claim 4, characterized in that the channels ( 16 . 17 ) have the same depth (T). Construction element according to one of the preceding claims, characterized by the outer sides ( 21 ) of the second leg ( 12 ) outwardly projecting ribs ( 20 ). Construction element according to claim 6, characterized in that the ribs ( 20 ) on the middle of the outer width (B) of the second leg ( 12 ) to sit. Construction element according to claim 6 or 7, characterized in that the height (H) of the ribs ( 20 ) is at most equal to half the distance (A). Construction element according to one of the preceding claims, characterized by the web ( 15 ) of the profile ( 5 ) passing through holes, preferably holes ( 23 ). Construction element according to claim 9, characterized by in the bores ( 23 ) sitting screws ( 24 ) to connect the profile ( 5 ) with the connecting element ( 6 ). Construction element according to one of the preceding claims, characterized in that the connecting element ( 6 ) in the transverse direction (R) has a thermal conductivity which is less than the thermal conductivity of the profiles ( 5 ). Construction element according to one of claims 1-11, characterized in that the profiles ( 5 ) for forming a support ( 1 ) are arranged vertically and arranged in mirror image in such a way that in each case the second leg ( 12 ) of their rectangle angles ( 10 ) face each other. Construction element according to one of claims 1-11, characterized in that the profiles ( 5 ) to form a cross member ( 2 ) are arranged horizontally and mirror-inverted in such a way that in each case the second leg ( 12 ) of their rectangle angles ( 10 ) are facing away from each other. Construction element according to claim 13, characterized by a part length in the front end of the cross member ( 2 ) protruding connecting plate ( 35 ) outside the cross member ( 2 ) with form-locking elements ( 37 ) is provided for connection to a truss node. Construction element according to claim 14, characterized in that the connecting plate ( 35 ) on the crossbeam ( 2 ) projecting partial length with slots ( 40a . 40b ) for receiving the webs ( 15 ) is provided.