DE19649387A1 - Steel connecting system for connecting vertical and horizontal supports - Google Patents

Abstract

The horizontally aligned supports (60,70) are connectable flush with each other through engaging coupling plates (601, 701) on the end sides. The coupling plates can serve at the same time for the keyed connection of the vertically aligned stays (50a,50b). The supports have a double T-profiled section and the coupling plates are rectangular in outline and connected with the supports so that each covers half the support profile. With engagement of the coupling plates two long sides of the plates correspond with each other.

Description

The present invention relates to a Steel construction connection system for vertical connection aligned supports with horizontally aligned beams, the supports and / or the beams made of double-T profiles or C-profiles and the supports and / or beams have coupling plates on the face.

Such a steel construction connection system is from DE-OS 29 00 477 known. The vertical supports or horizontal beam using additional knot elements are screwed together. This solution therefore shows the Disadvantage that the screwing of the node elements on the Construction site assembly difficult and extended.

In CH 536 401 a steel construction connection system presented, with vertical supports at the front Have coupling plates and horizontal C-profiles by means of Coupling plates are screwable. Here too there is Disadvantage that in the formed by the supports and beams A final connection by means of nodes Bolt must be done, which the assembly effort on the Construction site increased accordingly.

The invention is therefore based on the object Steel construction connection system of the type mentioned above develop where work on the construction site can be largely simplified and shortened.

This task is characterized by the characteristics of Claim 1 solved. According to the invention it is provided that the horizontally aligned beams are engaged over located coupling plates in alignment with each other are connectable and that the coupling plates simultaneously to positive connection of the vertically aligned supports can serve.

It is through the steel construction connection system according to the invention thus very quickly and easily without much installation effort  possible on the construction site by simply assembling or Laying appropriately prepared carriers or Realize supports connecting points.

The steel construction structure of the building construction arbitrarily in the preselected grid dimension after all desired Directions to be expanded. In a first Spatial direction (main beam direction) a desired Extension of the steel skeleton by adding another Beam to a predetermined connection point easily accomplished. Likewise, an additional floor can easily by adding another prop to one Connection point can be changed. When attaching straps and / or supports at a connection point also change the type of connection point. The desired change of the steel skeleton in a further spatial direction (Main clamping direction) can now be easily determined by a kind Auxiliary construction take place, the z. B. from spacers can exist which z. B. also the grid dimension of the carrier can have. Extending the steel skeleton into the said spatial direction changed by the spacers but not the type of connection points.

It is useful if the carrier has a double-T profile and the coupling plates in the plan in an approximately rectangular shape have and are connected to the carriers such that is covered in about half of the carrier profile. This allows the beams and supports in the connection point quasi a continuous beam with high stability will be realized.

Another expedient embodiment of the invention provides before that when the coupling plates engage two Long sides of the coupling plates correspond to each other, being on the long side of a coupling plate, namely a small adjustment tab on each side of the carrier web is molded on and further out each one approximately  cuboid overlap flange is attached, which with about half of his body over the long side protrudes and with the long side of the other coupling plate, namely a recess on both sides of the carrier web having. It is also expediently provided that the Recesses and the adjustment tabs in their layout approximately are rectangular and have approximately the same shape. Hereby can easily form locking between the correspond coupling plates can be achieved.

A sensible further development of the inventive idea sees before that not when engaging the coupling plates corresponding long sides on the outside An adjustment lug is formed on each end, the Adjusting lugs are roughly rectangular in shape and only the two adjustment lugs completely over the edge of the Protruding legs of the double T-profile on the beam side. Another expedient embodiment of the invention can also provide that at the engagement of the coupling plates non-corresponding long sides approximately in the middle an adjustment lug is formed, which is roughly in its outline is quite angular and the one provided with the adjustment nose Long side over the edge of the legs of the double-T profile protrudes. This makes it a more lightweight form-fit Connection of the supports possible, these quasi on the Leg of the double-T profiles on the support side can.

If appropriate in the assembled state, the carrier the coupling plates interlock positively, the Adjusting tabs of a coupling plate in the cutouts of the grab the other coupling plate and the overlap flanges grab a coupling plate over the other coupling plate, so is a reliable form fit between the coupling plates and thus a stable connection between the carriers guaranteed.  

It is expediently provided that the supports Have coupling plates, which when connected to the carrier form-fitting with the coupling plates on the carrier side correspond. This is a simple positive connection of the supports to the beams possible.

The supports advantageously have a double-T profile and whose coupling plates are roughly square in plan Shape and are connected to the supports at the front, that they largely cover their cross-section. The Coupling plates each have two opposite, to the web of the connected with them Double-T profile parallel sides two recesses on and these are approximately in the middle of the pages and have an approximately rectangular shape. Leave the coupling plates are easy to manufacture and can still be used in excellent way for positive connection of the supports serve.

If in the assembled state the coupling plates on the support side with its floor plan on the legs of the carrier side Double-T profiles rest and the adjustment lugs of the carrier-side coupling plates in the recesses of the protruding coupling plates, so a reliable connection between supports and beams created.

Another useful embodiment of the invention can provide that the supports are out with their backs to each other horizontal, parallel C-profiles and the C-profiles each with two roughly rectangular in plan Coupling plates are screwed together, which are between the back of the C-profiles are located in the Range of their ends. Here are the coupling plates expediently approximately parallel to each other and to Aligned longitudinal extension of the C-profiles and the outer Long sides of the coupling plates are roughly aligned with the Outer edges of the back of the C-profiles, so that between the  Coupling plates a groove-shaped recess is created. This means that supports made of C-profiles can easily be made can be realized, the coupling plates being very inexpensive are to be manufactured. It also creates favorable conditions created for connecting the supports to the beams.

If appropriate in the assembled state the over the Legs of the double T-profiles protruding from the beam Long sides of the carrier-side coupling plates each in one formed by the coupling plates on the support side The gap between the C-profiles and the adjustment lugs protrude completely into the coupling plates on the support side Grip formed groove-shaped recess, will reliable positive connection between beams and Supports created.

Another object of the present invention is in realizing a steel skeleton structure simplify. This task is characterized by the Features of claim 18 solved.

A steel skeleton structure is understood in Building construction a storey building, its supports and beams in steel are manufactured and the loads except for the Foundations transferred, while the walls only the task of Take over space closure and therefore with proportion light and only self-supporting in floors Building materials are fillable. The supports and beams can correspond to a predetermined grid dimension. this leads to multiple advantages of this design over the Solid construction with load-bearing walls and also opposite other construction methods and is therefore often used in multi-storey buildings applied. Taking advantage of the possibly quite long time for necessary foundation work, the steel profiles in usually pre-processed as far as possible (cutting to length, introduction of Bores, etc.) that only the necessary connections by riveting, welding, gluing or Screws must be made. The making of this  Connections such as B. by welding, screwing or riveting however, still requires a relatively large amount of time and stress the workers on site especially when this work in the cold Season. Furthermore, this can Workload may also decrease Quality of work, e.g. B. lead with welded connections what can affect the statics of the steel skeleton.

If according to the characterizing features of claim 18 the Steel skeleton structure at least one Steel construction connection system according to one of claims 1 to 17 contains the creation of the steel structural skeleton structure already relieved in the corresponding connection point.  

The following is the inventive Steel construction connection system explained using drawings, the drawings preferred different Embodiments or variants of the invention clearly do. It means:

Fig. 1 steel skeleton construction using the example of a one or two-story storey building to explain the field of application of the invention;

Fig. 2 is an exploded view of a possible embodiment of the steel connection system;

Fig. 3 frontal view of the right connector according to Fig. 2;

FIG. 4 frontal view of the left connecting element according to FIG. 2;

FIG. 5 shows sectional view of the lower connection element on the section line in Fig. 2;

FIG. 6 assembly drawing of the connection system according to FIG. 2;

Fig. 7 sectional view of the connection system according to the section in Fig. 6;

Fig. 8 is an exploded view of another embodiment of the connection system;

FIG. 9 front view of the right connecting element according to FIG. 8;

FIG. 10 frontal view of the left connecting element according to FIG. 8;

FIG. 11 is sectional view of the lower connecting member in accordance with section line in Fig. 8;

FIG. 12 assembly drawing of the connection system according to FIG. 8;

Fig. 13-sectional view of the connection system in accordance with section line in Fig. 12.

First, reference is made to FIG. 1. From FIG. 1, a possible application of the steel connection system according to the invention is schematically indicated on a one- or two-storey house. The steel structure of the house has a rectangular shape in its outer layout. The steel structure also forms a cuboid, the second floor being only hinted at. In the example of the two-story apartment building, this cuboid is made up of twelve smaller cuboids, which form the grid elements of the steel structure, so to speak. The rectangular steel structure has vertically extending supports 20, horizontally and at the same time parallel to the transverse side of the cuboid extending support 10 horizontally and at the same time parallel to the longitudinal side of the cuboid extending spacers 40. The carrier 10 and the supports 20 are connected to each other by external connection points 30 a, 30 b and by internal connection points 31 a, 31 b. The girders 10 form a main girder direction H lying parallel to the transverse side of the cuboid formed by the entire steel structure. The spacers 40 form a main clamping direction S lying parallel to the longitudinal side of the cuboid formed by the entire steel construction. The spacers are no longer considered in the following, since they are immaterial to the invention. Each inner connection point 31 a connects two beams 10 with two supports 20 . Each inner connection point 31 b connects two beams 10 with a support 20th Each outer connection point 30 a connects a beam 10 with two supports 20 . Each outer connection point 30 b connects a support 10 with a support 20th The spacers 40 and the carriers 10 each have a grid dimension A and thus form a grid surface F of each grid block formed by the supports 20 , the carriers 10 and the spacers 40 .

In the remaining figures, different embodiments for the steel construction connection system according to the invention are shown, with which the different connection points 30 a, 30 b, 31 a, 31 b that occur in a steel construction structure can be realized according to FIG. 1.

Fig. 2 shows the possible execution of an inner connection point 31 a in the not yet assembled state. The connection system consists of an upper support 50 a, a lower support 50 b and two beams 60 and 70 . The upper support 50 a in turn consists of a commercially available double-T profile 501 a and an end coupling plate 502 a. The lower support 50 b likewise consists of a commercially available double T profile 501 b and an end coupling plate 502 b. As can be seen from Fig. 5, the coupling plate 502 b has an approximately square shape in its outline and is welded to the end facing the upper support 50 a end of the double-T profile 501 b, so that the entire cross section of the Double T profile 501 b is covered by the coupling plate 502 b. As shown in Fig. 2 and Fig. 5 can be seen, the coupling plate 502 b on two opposite, to the web of the double T-profile 501 b parallel sides two recesses 5020 b which are approximately at the centers of the sides. The floor plan is roughly rectangular in shape. In the same way, the double-T profile 501 a of the upper support 50 a is connected at the end to the coupling plate 502 a, which has the same shape as the coupling plate 502 b. The carrier 60 shown on the left in FIG. 2 likewise consists of a double-T profile 602 and a coupling plate 601 connected to the end face thereof. The right-hand support 70 shown in FIG. 2 also consists of a double-T profile 702 and a coupling plate 701 connected to the end face thereof. The coupling plates 601 and 701 are each connected to the mutually facing ends of the double-T profiles 602 and 702, respectively, so that the coupling plate 601 in cross-section the lower T of the left double-T profile 602 , and the Coupling plate 701 in cross section covers the upper T of the right double T profile 702 . The coupling plate 601 has an approximately rectangular shape in plan view, two longitudinal adjustment tabs 6011, which are approximately square in their plan view, being integrally formed on one longitudinal side, namely at the respective outer ends. On the opposite side there are two small recesses 6013 lying in the center, which have approximately the shape of a U in their plan and divide this side of the coupling plate 601 into approximately three sections of equal size. The coupling plate 601 is welded to the double T profile 602 in such a way that only the two adjustment lugs 6011 protrude beyond the edge of the legs of the double T profile 602 located below. The coupling plate 701 also has a rectangular shape in plan, with two adjustment lugs 7011 being integrally formed on one of its longitudinal sides, similarly to the coupling plate 601, at the ends lying on the outside in each case. On the opposite long side of the coupling plate 701 , two small adjustment tabs 7013 are integrally formed, which have an approximately rectangular shape in plan and are large enough to fit into the cutouts 6013 of the coupling plate 601 . They also divide the long side of the coupling plate 701 into approximately three equally large sections. Furthermore, in the area of the adjustment tabs 7013 , only more outwardly offset from the edge of the coupling plate 701 and aligned with their longitudinal side in each case parallel to the web of the double-T profile 702 , two approximately rectangular overlap flanges 7012 are attached. These are roughly half the size of the adjustment lugs 7011 and 6011 , with about half of their body projecting beyond the side of the coupling plate 701 on which the adjustment tabs 7013 are also located.

Fig. 6 and Fig. 7 show the connection system in the assembled state. It is clear that the double-T profiles 602 and 702 are only separated from one another by the coupling plates 601 and 701 , the distance between them being very small and determined only by the thickness of only one coupling plate. A continuous beam is thus practically implemented. The distance between the upper and lower supports 501 a and 501 b, however, is much larger and is approximately determined by the web height of the double-T profiles 602 and 702 . From Fig. 6 it is also clear that the supports 501 a and 501 b are exactly at right angles to the double-T profiles 602 and 702 in the assembled state. The connection is now made in such a way that first the first carrier 60 is placed on the lower support 50 b, that the two adjusting lugs 6011 of its coupling plate 601 engage in the two recesses 5020 b of the coupling plate 502 b of the lower support 50 b and the double-T profile 602 rests with its lower legs on the coupling plate 502 b. As the next step, the second carrier 70 is placed on the lower support 50 b from above so that the adjustment tabs 7013 of its coupling plate 701 engage from above in the recesses 6013 of the coupling plate 601 and, moreover, the cuboid overlap flange 7012 of the coupling plate 701 is about half its length over the coupling plate 601 . Thus, the two carriers 60 and 70 are already secured against mutual translational displacement. A certain amount of security against rotational movements is also given due to the positive locking of the coupling plates 601 and 701 . Finally, the upper support 50 a is placed from above on the already connected steel beams 60 and 70 , so that the adjusting lugs 7011 of the coupling plate 701 , which project with their entire size upwards over the upper leg surface of the double-T profiles, into the Recesses 5020 a of the coupling plate 502 a of the upper support 50 a can engage. Thus, the upper support 50 a is secured against translational displacement and also against rotation about its longitudinal axis. A final stability of the connection system when used in a steel skeleton construction is of course only achieved if the entire steel skeleton according to FIG. 1 is filled with corresponding walls and / or corresponding spacers 40 provide mutual support for the construction elements in the main clamping direction S shown in FIG. 1 guarantee. Up to this point, temporary security measures are certainly still in place. B. conceivable by means of bolts or other retaining screws. For example, B. the adjustment lugs 7011 have through holes for receiving locking bolts. Likewise, the legs of the double-T profile 702 and the coupling plate 502 b could have through-bores in each case at identical locations for receiving a screw connection for the purpose of securing.

Furthermore, it should be pointed out that apart from the defined connection point 31 a (see FIG. 1), all other connection points such as 31 b, 30 a, 30 b can of course also be easily realized by the connection system shown in FIGS. 2 to 7. This will be briefly explained with reference to FIG. 6:

Thus, a connection point 31 b could be realized simply by omitting the upper support 50 a, which consists of double-T profiles 501 a and the front coupling plate 502 a. The slightly protruding adjustment tabs 7011 could be easily removed if necessary.

In order to realize a connection point 30 a, it was simply necessary to cut either the left double T profile 602 flush to the left outer edges of the coupling plates 502 a or 502 b. A cut to length of the right double T-profile 702 onto the right outer edges of the coupling plates 502 a or 502 could just as well be considered.

To create a connection point 30 b, the upper support 50 a would be omitted and either the left double T profile 602 or the right double T profile 702 cut to length in the manner already described. The cut double T-profile could in this case additionally with the lower coupling plate 502 b z. B. be secured by means of a screw connection.

Figs. 8 to 13 describe a further possible embodiment for an internal connection point 31 a of FIG. 1. The essential difference from the described on the foregoing pages embodiment is that the upper and lower support 80 a and 80 b of a not Double-T profile, but each consist of two C-profiles and the steel beams have slightly different coupling plates.

Fig. 8 shows the essential elements of the connection system again in an exploded view. The connection system has an upper support 80 a, a lower support 80 b, a left support 90 and a right support 91 . As can also be seen from FIG. 8 and FIG. 11, the lower support 80 b consists of two parallel C-profiles 801 c, 801 d lying with their back walls to one another. The backs of these C-profiles are connected at their one end facing the upper support 80 a by two spacer plates 802 b. Each of the spacer plates 802 b has an approximately rectangular shape in plan and is provided with four through holes approximately along its center line. Corresponding through holes in the C-profiles 801 c, 801 d provided that the rear walls of the C-profiles can be easily screwed to the spacer plates 802 b by means of through-screw connections, which of course can be done in prefabrication away from the construction site.

As is particularly clear from FIG. 11 and FIG. 13, the spacer plates 802 a, b are aligned with their long sides parallel to one another and parallel to the longitudinal extent of the C-profiles, a distance remaining between the spacer plates.

As can be seen from FIG. 8, the upper support 80 a is designed accordingly and has two C-profiles 801 a, 801 b, which are connected to one another in parallel by means of a spacer plate 802 a. Carriers 90 and 91 , comparable to the exemplary embodiment of the invention described in FIGS . 2 to 7, also have a coupling plate 901 and 911 for realizing an inner connection point 31 a.

As is clear from FIGS. 9 and Fig. 10, 901 and 911 have the coupling plates as well as the coupling plates 601 and 701, rectangular in its plan view in approximately form. Furthermore, the coupling plate 901 , comparable to the coupling plate 601 , has two cutouts 9012 and the coupling plate 911 comparable to the coupling plate 701 has two adjustment tabs 9112 and two overlap flanges 9111 . The difference is that adjustment lugs 9011 and 9113 are integrally formed on the other long sides of the coupling plates 901 and 911, respectively, which are located approximately in the middle of this long side and also have a roughly rectangular shape in their plan, whereby they are approximately twice as large as the adjustment tabs 9112 .

From FIGS. 8 to Fig. 10 is further seen that the coupling plates 901 and 911 in a comparable manner, the end face with the mutually facing ends of the double-T-profile 902 and 912 connected as shown in Fig. 2 in the Connection of the coupling plates 601 and 701 with the double-T profiles 602 and 702 has been described. The coupling plates 901 and 911 , however, each protrude slightly beyond the legs of the double-T profiles 902 and 912 , respectively, with their side having the adjusting lug 9011 and 9113 , respectively. This protruding part of the coupling plates is approximately ¼ of the total size of the coupling plates and has approximately the shape of a shoulder in cross section, the adjusting lugs 9011 and 9113 forming the neck.

Fig. 12 and Fig. 13 show the connection system, in turn, in the assembled state. Here, too, it can be seen that, in the assembled state, the supports are in turn at right angles to one another.

The assembly of the connection system according to FIG. 8 shown in FIG. 12 is now carried out in a simple manner as follows: First, the first steel beam 90 is placed on the support 80 b from above, in such a way that the adjustment lug 9011 of the coupling plate 901 as in FIG Fig. 13 shown, engages in the recess located between the spacers 802 b. Further, 13 is apparent from FIG. That the coupling plate 901 with their shoulders on the upper end faces of the spacer plates rests b 802nd Then the second carrier 91 is placed from above on the lower support 80 b, so that the same positive connection between the coupling plates 911 and 901 results, as is the case with the coupling plates 601 and 701 according to FIG. 6. In this state, only the shoulder formed by a part of the coupling plate 911 and its adjusting nose 9113 and already mentioned points vertically upward from the upper legs of the double-T profiles 902 , 912 . Therefore Finally, the upper support 80 may be a top so to the carrier 902 and 912 are set such that the spacer plates 802 a of the upper support 80 a rest with their front side on the shoulders of the coupling plate 911 and the Justiernase 9113 as shown in Fig. 13 shown, engages in the groove-shaped recess located between the spacer plates 802 a. Due to this positive connection, the supports 80 a and 80 b are translationally fixed and non-rotatably connected to the supports 90 and 91 about the longitudinal axis. The ends of the supports 80 a, 80 b lie completely on the leg surfaces of the supports 90 , 91 . This is made possible by the fact that the spacer plates 802 a, 802 b are set back to the other end of the supports as the shoulders of the coupling plates 911 and 901 already described protrude from the respective leg plane of the supports 90 and 91 , respectively.

It is easy to understand that, of course, the connection system according to FIGS. 8 to 13 for realizing all connection points 30 a, b; 31 a, b can be used. This is in particular to Fig. 8 and Fig. 12 easy to understand. To realize a connection point 31 b, only the upper support 80 a need be omitted. If you want to implement a connection point 30 a according to FIG. 1, you only need to cut one of the two double T profiles 902 and 912 flush to the longitudinal edges of the C profiles 801 a, c and 801 b, d.

A connection point 30 b according to FIG. 1 is realized by omitting the upper support 80 a and cutting one of the two double-T profiles 902 and 912 to length in the manner described. Here, too, the cut double T-profile could be additionally secured with simple means.

Claims (18)

1. Steel construction connection system for connecting vertically aligned supports with horizontally aligned supports, the supports and / or the supports consisting of double-T profiles or C-profiles and the supports and / or supports having end-face coupling plates, characterized in that the horizontal Aligned carrier ( 60 , 70 or 90 , 91 ) can be connected in alignment with one another via engaging end coupling plates ( 601 , 701 or 901 , 911 ) and that the coupling plates ( 601 , 701 or 901 , 911 ) simultaneously form-fit Connection of the vertically aligned supports ( 50 a, 50 b or 80 a, 80 b) can serve. 2. Steel construction connection system according to claim 1, characterized in that the carrier ( 60 , 70 , 90 , 91 ) a double-T profile ( 602 , 702 , 902 , 912 ) and the coupling plates ( 601 , 701 , 901 , 911 ) in Have a roughly rectangular shape and are connected to the beams in such a way that in each case approximately half of the beam profile is covered. 3. Steel construction connection system according to claim 1 and 2, characterized in that when the coupling plates ( 601 , 701 or 901 , 911 ) engage, two longitudinal sides of the coupling plates correspond to each other, with the longitudinal side of the one coupling plate ( 701 , 911 ), namely a small adjustment tab ( 7013 , 9112 ) is integrally formed on both sides of the carrier web, and an approximately cuboid overlap flange ( 7012 , 9111 ) is attached to the outside, which protrudes by about half of its body over the long side and the long side of the other coupling plate ( 601 , 901 ), namely on both sides of the carrier web , each has a recess ( 6013 , 9012 ). 4. Steel construction connection system according to claim 3, characterized in that the recesses ( 6013 , 9012 ) and the adjusting tabs ( 7013 , 9112 ) are approximately rectangular in their plan and have approximately the same shape. 5. Steel construction connection system according to claim 3 and 4, characterized in that an adjustment lug ( 6011 or 7011 ) is integrally formed on the longitudinal sides which do not correspond when the coupling plates ( 601 , 701 ) engage. 6. Steel construction connection system according to claim 5, characterized in that the adjusting lugs ( 6011 or 7011 ) are approximately quite angular in their layout and only the two adjusting lugs ( 6011 or 7011 ) completely over the edge of the legs of the double-T Protruding profiles ( 602 or 702 ). 7. Steel construction connection system according to claim 3 and 4, characterized in that on the engagement of the coupling plates ( 901 , 911 ) non-corresponding longitudinal sides each have an adjustment lug ( 9011 or 9113 ) formed approximately in the center. 8. Steel construction connection system according to claim 7, characterized in that the adjusting lug ( 9011 or 9113 ) is approximately quite angular in its plan and the provided with the adjusting lug ( 9011 or 9113 ) long side over the edge of the legs of the double-T Profile ( 902 or 912 ) protrudes. 9. Steel construction connection system according to one of claims 1 to 8, characterized in that in the assembled state of the carrier, the coupling plates ( 601 , 701 or 901 , 911 ) interlock positively, the adjusting tabs ( 7013 or 9112 ) of a coupling plate ( 701 or 911 ) into the recesses ( 6013 or 9012 ) of the other coupling plate ( 601 or 901 ) and the overlap flanges ( 7012 or 9111 ) of the coupling plate ( 701 or 911 ) over the other coupling plate ( 601 or 901 ) to grab. 10. Steel construction connection system according to one of claims 1 to 9, characterized in that the supports ( 50 a, 50 b or 80 a, 80 b) have coupling plates ( 502 a, 502 b or 802 a, 802 b), which at Connection to the carrier ( 60 , 70 or 90 , 91 ) corresponds positively to the coupling plates ( 601 , 701 or 901 , 911 ) on the carrier. 11. Steel construction connection system according to claim 10, characterized in that the supports ( 50 a, b) have a double-T profile ( 501 a, b) and their coupling plates ( 502 a, 502 b) in plan have an approximately square shape and are connected at the end to the supports ( 50 a, b) in such a way that they largely cover their cross sections. 12. Steel construction connection system according to claim 10 and 11, characterized in that the coupling plates ( 502 a, 502 b) each have two recesses on two opposite, parallel to the web of the double T-profile ( 501 a, 501 b) connected to them ( 5020 a, 5020 b) and these are approximately in the middle of the pages. 13. Steel construction connection system according to one of claims 10 to 12, characterized in that the recesses ( 5020 a, 5020 b) have an approximately rectangular shape. 14. Steel construction connection system according to one of claims 10 to 13, characterized in that in the assembled state, the support-side coupling plates ( 502 a, 502 b) rest with their plan area on the legs of the support-side double-T profiles ( 602 and 702 ) and the adjustment lugs ( 7011 or 6011 ) of the support-side coupling plates protrude into the recesses ( 5020 a or 5020 b) of the support-side coupling plates. 15. Steel construction connection system according to claim 10, characterized in that the supports ( 80 a, b) consist of mutually parallel C-profiles ( 801 a, 801 b or 801 c, 801 d) and the C-profiles are each screwed together by means of two coupling plates ( 802 a or 802 b) which are approximately rectangular in plan and which are located between the backs of the C-profiles, in each case in the region of their ends. 16. Steel construction connection system according to claim 15, characterized in that the coupling plates ( 802 a and 802 b) are aligned approximately parallel to one another and to the longitudinal extent of the C-profiles and the outer longitudinal sides of the coupling plates ( 802 a and 802 b) approximately aligned with the outer edges of the back of the C-profiles, so that a groove-shaped recess is created between the coupling plates ( 802 a and 802 b). 17. Steel construction connection system according to one of claims 15 and 16, characterized in that, in the assembled state, the longitudinal sides of the support-side coupling plates ( 901 , 911 ) projecting beyond the legs of the support-side double-T profiles ( 902 , 911 ) each in one through the support-side coupling plates ( 802 a or 802 b) formed space of the C-profiles protrude and the adjusting lugs ( 9011 , 9113 ) fully engage in the groove-shaped recess formed by the support-side coupling plates ( 802 a or 802 b). 18. Steel construction structure, comprising horizontally aligned beams and vertically oriented supports in a first spatial direction, the length of the horizontal beams always corresponding to a predetermined grid dimension A or an integral multiple thereof and the length of the vertical supports also a predetermined grid dimension, preferably a floor height or one corresponds to integer multiples thereof and an auxiliary construction is provided that keeps the horizontal beams at a distance in a direction perpendicular to the first spatial direction, and steel connection systems for the connection of a beam with one or two aligned supports to so-called external connection points ( 30 a, 30 b) and / or steel connection systems for the connection of two mutually aligned beams with one or two mutually aligned supports to so-called inner connection points ( 31 a, 31 b) are provided, thereby geke that the steel skeleton structure contains at least one steel construction connection system according to one of claims 1 to 17.