FI20215264A1 - Connection arrangement - Google Patents

Abstract

A connection arrangement for connecting a vertical element and a beam (31) to each other, which connection arrangement comprises a beam part attachable to the end of the beam (31) which has an end plate (41) with an open slot (48) at the bottom which has a abutment surface (58), and a pillar part attachable to the vertical element having a tongue part (40) with a support surface (62) against which the abutment surface (58) of the notch (48) is arranged to be supported. The tongue part (40) has upper support surfaces (66) on opposite sides, and the notch (48) has upper abutment surfaces (54) on opposite sides, one of which is arranged to be supported against the upper support surface (66) of the tongue part (40) when the beam part is mounted on the column part and the beam part is subjected to a torque. The tongue part (40) has lower support surfaces (67) on opposite sides, and on the rear surface of the end plate (41), on both sides of the notch (48), a cover (50) is fixed inside which the lower support surfaces (67) of the tongue part are arranged then the beam part is mounted on the column part. The inner side surface (68) of the cover (50) is arranged to be supported against the lower support surface (67) of the tongue part (40) when the beam part is subjected to a torque. The tongue part (40) has on its side an inclined side support surface (61) which is enclosed by the cover (50) when the beam part is mounted on the pillar part, and the connection arrangement includes a wedge (64) which can be arranged against the inclined side support surface (61) and the cover (50) inner surface (68) to support the tongue part (40) against the inner side support surface (68) of the cover (50).

Description

CONNECTION ARRANGEMENT The object of this invention is a connection arrangement according to claim 1 for connecting a vertical element, such as a pillar or a wall element, and a horizontal element, such as a beam. The subject of the invention is also a joint comprising a vertical element, such as a pillar or a wall element, and a beam. The beam-column joints of concrete structures have been manufactured for tens of years using special hidden console technology. With the help of a hidden console, the connection can be hidden inside the beam and column, and thus does not hinder the use of the building. Hidden consoles are an established part of the element system of concrete structures. Concealed consoles were initially developed only for concrete elements, but they have also started to be used in joint column-joint beam frame joints and also in so-called mixed frame joints, where the material of the beam and column varies depending on the building. Significant product development of consoles took place in the 1990s and early 2000s, after which they have not been updated much, even though frame construction has developed. The first hidden console that gained a wide market position was based on the patent FI83358, which has been used in concrete structures' hidden console applications. Another hidden console that has achieved commercial success is described in patent EP1334244. The console described in patent F189193 is based on a completely different solution, where the tongue part of the console is pushed during installation — from the beam into the column. Even this console did not solve the problems caused by the torque of the beam S 25, and no torque was allowed for the practical application of the console. The console described in patent FI72369 transfers only the vertical load of the beam, not the torque. There are other patents related to hidden consoles, E but their success in commercial applications has been limited.

DS > 30 As a structure, the hidden console is very demanding because it has to transfer very large loads from beam to column in a very small space. The cantilever joint transfers the vertical load of the beam to the column. This load has a different magnitude in different construction phases. The direction of the load is usually downwards, but in the installation situation it can momentarily also be directed upwards. The cantilever joint is also subjected to the longitudinal horizontal load of the beam, which can affect in opposite directions. In addition, the cantilever joint is affected by the torque tending to rotate the beam. The bending moment of the end of the beam is usually not transferred with hidden consoles, because it forms a very demanding structure for which a functional application has not yet been developed. The hidden console structure usually has three parts, which form the connection between the beam and the column. A concrete column usually has a column part cast into the column, which — transfers and attaches the forces coming from the beam to the column. A beam part is cast into the beam, which transfers the loads of the beam to the tongue part of the column part. The tongue part forms the most demanding structure of the joint, because it bears the greatest loads and is required to have several functional properties, especially during the installation phase of the joint.

The connection is affected by various load situations during construction and use, such as installation, use, accident and fire situations. The requirements set by different situations differ from each other and the requirements must be met in all situations. Especially the installation situation of the beam is very demanding for the hidden con- — Sol's structure, because all the concrete castings of the structures have not yet been made in the installation situation and the operation of the joint therefore differs significantly from other dimensioning situations. — After the beginning of the 21st century, the frame systems of buildings have developed considerably, and the trend is increasingly towards the use of so-called mixed frames. This places new demands on the cantilever structure, because the cantilever must - fit into frame structures, in the joints of which the material of the beam and column can change even inside the building and even at different ends of the same beam. The hidden console system must therefore adapt to the requirements of the building frame. Therefore > 30 — it has become a general requirement that the beam part of the cantilever joint must 3 be fitted to the concrete, composite and steel column without changing the structure of the beam part. Current commercial console systems do not meet this requirement, and they are bound to the frame material. In known solutions, the joints must be shaped according to the material of the beam or column, and the material of the frame structure cannot be changed without changing the joint structure of the beam or column. In one embodiment of this invention, a connection arrangement is presented, with which it is possible to connect either a concrete beam or a composite beam to a concrete column with the same connection arrangement. In the following, we will examine what functional properties the loads from the beam impose on the cantilever structure. The vertical load of the beam is transferred from the end plate of the beam part to the tongue part of the column part, which is a metal projection arranged on the surface of the column, usually a rectangular plate, on which the end plate of the beam part rests. This design usually works quite well, transferring vertical loads reliably to the column. In well-known console applications, the beam part is always installed from top to bottom on the tongue part. The beam part is usually not attached to the tongue part in any way, but the weight of the beam and the protruding parts of the tongue part keep the beam part in place. In new frame structures, the continuity of the beams creates a situation where lifting forces are also applied to the end of the beam during installation. The lifting force is eliminated by the installation support. In one embodiment of this invention, the locking of the console is presented by wedging also the end of the beam to the lifting force.

Transmitting the torque of the beam to the column is the most demanding feature of the hidden cantilever connection. In the installation situation of the cantilever joint, there must be an installation gap between the beam part and the tongue part. The installation clearance is required because the contact surfaces of the beam part must match the tongue part when installing the beam part from above to the support surfaces of the tongue part S 25. Beams, pillars and console parts usually have small manufacturing inaccuracies, so the parts are not completely in their designed dimensions. Therefore - there must be an installation gap between the contact surfaces of the joint, which compensates for these E inaccuracies and allows the joint to be installed.

DS > 30 The torque of the beam is transmitted precisely by these same connecting parts, which 3 requires that the connecting parts are in contact with each other. If there is a gap in the connection, it can still transfer torque, but the gap causes the beam to twist at the same time, which is often not allowed or desired.

The requirements are thus mutually exclusive, because transferring the torque requires contact between the joint parts and installing the joint requires clearance between the same parts. In one application form of this invention, a solution is presented, with which the clearance of the response parts of the joint and the transmission of the torque are solved in such a way that the joint has sufficient mounting clearance in the installation situation, but at the end of the installation, the joint parts come into contact with each other, which is necessary to transfer the torque, so that there is no more space between them small clearance. There is thus no harmful twisting in the joint in the final situation and it is also locked to the torque.

All three of these power transfers have not been solved in the same joint in known consoles. If no torque is allowed for the cantilever joint during beam installation, or if the cantilever joint twists too much under the influence of the torque due to the gap in the joint, the beams have to be installed using a temporary installation support. Installation support is an expensive measure that slows down construction and is therefore an additional cost. Builders want to eliminate this extra cost. In one application form of this invention, a cantilever structure is formed, with which the beam-column connection can be made with a hidden cantilever, which does not need an installation support that removes the torque and at the same time it transfers the torque without harmful twisting of the beam. In the following, we will look at how the transfer of torsion in the joint is solved in known consoles. Patent F183358 presents a rectangular tongue part, where there are vertical contact surfaces S 25 between the tongue part and the end plate of the beam part, which, according to the patent, transmit the torque. This is how g really happens, but only theoretically, if the contact surfaces of the beam part and the support surfaces of the string part are in close contact with each other. However, the patent has not solved the installation tolerance problem, i.e. how the contact surfaces of the beam part hallo and the string part 3 can be installed closely opposite each other, when there is > 30 — manufacturing inaccuracy in the structures.

In the commercial cantilever application of S Patent F183358, there was a clearance between the vertical torsion-transmitting contact surfaces of the tongue member and beam member end plate.

The harmful twisting effect in the beam caused by the gap was removed with an installation support and wedging of the joint. However, the polishing method between the vertical contact surfaces of the tongue and beam part did not work reliably, because vertical surfaces cannot be wedged with an oblique wedge to make them tight and non-rotating in a reliable way. The torsional transmission capacity described in the patent could not be solved in practical application without the support of the beam's installation situation for torsion. The vertical contact surfaces of the joint were able to receive the torque in the final use situation, because the rotation of the beam was no longer critical after the concrete casting. Due to the defects in the patent, the torque could not — be transmitted reliably in the most critical installation situation without the installation support of the beam. The practical application of patent F183358 thus did not reliably solve the torsion/twisting problem of the console. Patent EP1334244 has a rectangular tongue section (as does patent F183358), but this bracket is not designed to transmit torque. The commercial applications of the patent and its console do not allow torque for the console, and no torque-receiving contact surfaces have been formed on it due to the large clearances of the connecting surfaces of the console. The commercial application of the patent uses an installation support that removes the torque.

The purpose of this invention is to provide an improved connection arrangement for connecting a vertical element, such as a pillar or a wall element, and a horizontal element, such as a beam. = The goal according to the invention is achieved with a connection arrangement according to claim 1, which connection arrangement comprises a beam part that can be attached to the end of the beam, which comprises an end plate with a bottom-open frame with a contact surface at the bottom, and a pillar part that can be attached to the vertical element, I which comprises a tongue part with a support surface, against which the hahlo's response surface is arranged to rest in order to receive a vertical load. The opposite & 30 — sides of the tongue section have upper support surfaces and the upper part of the hallo has = upper contact surfaces on the opposite sides, one of which is arranged to rest against the top surface of the tongue section when the beam part is mounted on the pillar part and the torque is applied to the beam part. There are bottom support surfaces on the opposite sides of the string part, and a case is attached to the back surface of the end plate on both sides of the slat, with the bottom support surfaces of the inside string part arranged; when the beam part is installed on the column part. The inner side surface of the case is arranged to rest on the lower support surface of the string part when a torque is applied to the beam part. On the side of the tongue part there is an inclined side support surface, which is inside the case when the beam part is installed on the pillar part. In addition, the connection arrangement comprises a wedge that can be fitted against the slanted side support surface and the inner surface of the case to support the tongue part on the inner side surface of the case.

With the help of the invention, considerable advantages are achieved. The connection arrangement according to the invention has the normal installation clearances required during installation.

— At the end of the installation, the connection arrangement can be locked with the torque-transmitting connection surfaces without harmful twisting of the beam. Installation tolerances and joint clearance in the installation situation, i.e. in a situation where the joint arrangement is not locked non-slip, are achieved in such a way that the shape of the string part of the column part and the shape of the beam part form the joint clearance required at the beginning of the installation, when the beam part is installed from above on the pillar part. The width of the lower part of the beam part's slat is greater than the width of the upper part of the string part, so the string part has horizontal space inside the slat at the beginning of installation. When the beam part is placed on top of the string part, the clearances in the joint are removed due to the shape of the string part and the shape of the beam part's beam, and the support surfaces of the string part and the contact surfaces of the string part are placed against each other or at a distance of the installation clearance from each other at the end of the installation and thus allow the transfer of torque and prevent the beam part from rotating around the beam pi - around the axis of rotation.

S 25 N The tongue part comprises a support surface on which the beam part rests. The support surface receives the vertical load of the S beam. The end plate of the beam part has a groove, the width of which increases - downwards. This design creates a loose structure at the start of installation, E: when the beam part is lowered down onto the tongue part. The support surfaces that transfer the string part's torque > 30 — and the beam part's torsion response surfaces only support each other at the moment when the beam part is placed on top of the string part. In this way, there is no need to create an additional installation clearance for the connection, but the installation clearance is provided by the structural shape of the beam section that widens downwards.

Torque transmission requires that the joint has two vertical contact surfaces located horizontally on opposite sides of the joint. In addition, the surfaces must be located vertically at different heights. It is always more advantageous in terms of torque transfer, the greater the height difference between the contact surfaces in the vertical direction. The upper part of the string has a vertical upper support surface to transfer the torque. Likewise, the lower part of the string has a vertical lower support surface to transfer torque. Due to the symmetry of the structure, there are two symmetrical surfaces on both sides of the string part in both the upper and lower parts, of which only the other and the surfaces on the opposite sides of the string part transfer torque at the same time. In one application form of the invention, the horizontal distance between the upper contact surfaces of the upper part of the handle is smaller than the horizontal distance between the lower contact surfaces of the lower part of the handle. With this design, the joint gets the necessary installation clearance.

In one embodiment of the invention, all connecting parts of the beam part are connected together with the same housing structure. The housing of the beam part can be made from a steel plate bent into a U shape, which has been produced, for example, by roller rolling, in which case the manufacturing tolerances are very small. The U-shaped housing is — also the most economical solution in terms of manufacturing technology, which does not exist in known technology. The invention is described in more detail in the following by means of examples by referring to — the attached drawings, in which S 25 g figure 1 shows the connection arrangement according to one application form of the invention as viewed from the side and cut from the plane of the side surface of the string part, z 3 figure 2 shows the beam part of the connection arrangement of figure 1 as viewed > 30 and cut from the direction of the beam by the case,

Figure 3 shows the tongue part of the connection arrangement of Figure 1 as viewed from the side,

Fig. 4 shows the string part of Fig. 3 viewed from the right end of the string part, Fig. 5 shows the beam part and the tongue part of the joint arrangement of Fig. 1 as viewed from the direction of the beam and cut at the end of the string part, and Fig. 6 shows the hidden console structures of Fig. 1 combined and viewed from above and cut at the upper surface of the string part. Figures 1-6 show the connection arrangement according to one application form of the invention for connecting a vertical element, such as a pillar 2 or a wall element, and a beam 3 to each other. The connection arrangement is the so-called hidden console, where the joint is placed inside beam 3 and the vertical element. Beam 3 can be a concrete beam or a composite beam. The connecting beam comprises a box-like space delimited by steel plates, which is filled with concrete. The vertical element is concrete, for example a concrete pillar.

The connection arrangement comprises a column part attached to a vertical element, such as a concrete pillar 30, and a beam part attached to the end of a beam, such as a concrete beam 31. The pillar part comprises a tongue part 40, which is detachable from the pillar part. The column part without tongue part 40 and the beam part are installed in the casting mold before the concrete casting. After the concrete has hardened, a tongue part 40 is installed in the column part, on top of which the beam part is placed. The pillar part comprises a pillar housing 33, which comprises a front wall 37, which has a vertical - hahlo. The vertical hatch is closed at the bottom. In addition, the pillar housing 33 comprises two side walls arranged at a distance of 25 feet from each other, which are attached to the front wall 37, and a base 39 connecting the side walls. The vertical eaves are between the side walls. The pillar box 33 also comprises the back wall connecting the side walls and the roof E part 70. The pillar box 33 is made of sheet steel. In addition, the pillar part comprises 3 grips 32, 35, 36 for attaching the pillar part to a concrete pillar 30 or to another > 30 — vertical element. The grips also transfer the load coming from the tongue part 40 to the vertical element 3. The grips are made of brush bar and/or steel plate. The front wall 37 is on the surface of the vertical element and the rest of the pillar housing is inside the vertical element when the pillar part is mounted on the vertical element.

The beam part comprises an end plate 41, which has a bottom open slat 48. The bottom or end of the slat 48 has a counter surface 58. The tongue part 40 of the pillar part comprises a support surface 62, against which the slatted counter surface 58 rests to receive the vertical load when the beam part is placed against the column part.

In addition, the opposite sides of the hinge 48 form the upper contact surfaces 54. The upper contact surfaces 54 are in the upper part of the hinge 48.

Opposite top contact surfaces 54 can be parallel, for example vertical.

In the lower part of the hinge 48, the opposite sides of the hinge form the bottom contact surfaces 55. The bottom contact surfaces 55 are slanted so that the distance between the bottom contact surfaces 55 and thus the width of the hinge 48 increases downwards.

Opposite upper abutment surfaces 54 are symmetrical with respect to the vertical central axis of the shaft 48.

Opposite lower contact surfaces 55 are symmetrical with respect to the vertical central axis of the frame 48.

The width of the groove 48 is greater at the lower contact surfaces 55 than at the upper contact surfaces 54.

The width of the Hahlo 48 is 10-50 mm larger, typically 20-40 mm larger at the bottom of the lower response surfaces 55 than at the upper response surfaces 54.

The beam part comprises a housing 50, which is attached to the back surface of the end plate 41, i.e. the surface of the end plate 41 towards the end of the beam.

The housing 50 is attached to both sides of the hahlo 48.

The housing 50 comprises two side walls and a back wall, which are formed, for example, from a steel profile sheet bent into a U shape.

The open side of the housing 50 faces the rear surface of the end plate 41.

The ends of the side walls of the housing 50 are attached to the end plate 41 on the opposite sides of the hinge 48.

Thus — hahlo 48 is between the ends of the side walls of the housing 50.

The housing 50 is open from the bottom.

S 25 — Casing 50 protects the joint parts inside the casing from concrete during casting. 3 —- The housing 50 comprises a top plate 43, which is attached to the rear surface E of the end plate 41 above the housing 50.

The upper plate 43 has an opening 51 for a wedge 64, with which the housing 50 and the 3 tongue part 40 are wedged or supported against each other in a non-twisting and torque-receiving structure.

The beam part can comprise grips 44, 46, 3, for example brush steels, in order to fasten the beam part to the concrete of the beam 31.

The grips 44, 46 are attached to the housing 50. The beam part transfers the load coming from the beam 31 through the end plate 41 to the tongue part 40 of the column part.

Figures 3 and 4 show the tongue part 40 of the pillar part, which comprises a support surface 62, against which the contact surface 58 of the hinge 48 is arranged to rest when the beam part is placed on the pillar part. In addition, there are upper support surfaces 66 on the opposite sides of the tongue part 40, against one of which the second upper contact surface 54 of the hinge 48 rests when the beam part is placed against the column part and the beam part is subjected to a torque tending to rotate around the longitudinal axis of the beam 31. The beam part can be subjected to a torque tending to rotate around the longitudinal axis of the beam 31 in a situation, for example, in an installation situation where the tongue part 40 is not supported by a wedge 64 on the inner side surface 68 of the housing 50. The longitudinal axis of the beam 31 is in the same direction as the normal of the back surface of the end plate 41. If the torque acts in the opposite direction, the opposite upper support surface 54 of the hook 48 rests against the upper support surface 66 on the opposite side of the tongue part 56. — On the opposite sides of the tongue part 40, there are lower support surfaces 67, which are inside the housing 50, when the beam part is placed against the pillar part. The inner side surface 68 of the housing 50 rests against the second lower support surface 67 when the beam part is placed on the pillar part and the beam part is subjected to a torque tending to rotate around the longitudinal axis of the beam 31, for example in an installation situation or in another situation where the tongue part 40 is not supported by a wedge 64 on the inner side surface of the housing 50

68. The lower support surfaces 67 are vertically at a distance from the upper support surfaces 66, i.e. the lower support surfaces 67 are at a different height than the upper support surfaces 66. If the torque acts in the opposite direction, the inner side surface 68 on the opposite side of the housing 50 rests on the opposite side of the string part 40, so that against the lower support surface 67. 3 —- The tongue part 40 comprises a frame plate 69, which can be a steel plate cut to shape. E The tongue part 40 comprises a support plate 56, which is attached to the frame plate 69. The upper surface of the support plate 3 56 forms a support surface 62. The support plate 56 can be rectangular in shape - > 30 — second and/or thicker than the frame plate 69. The opposite sides of the support plate 56 form the upper support surfaces 66.

In addition, the tongue part 40 can comprise an end support plate 57, which is attached to the front surface of the body plate 69 and/or the end of the support plate 56. The width of the end support plate 57 is greater than the thickness of the body plate 69 and the support plate 56. The end support plate 57 extends above the support surface 62. In this case, the end support plate 57 prevents the end plate 41 of the beam part from falling off the tongue part 40 when the beam part moves in the longitudinal direction of the beam. The end support plate 57 can be rectangular or slightly shaped in its upper part. In the lower part of the tongue part 57, on the opposite sides, there are lower support surfaces 67, against one of which the inner side surface 68 of the housing 50 rests, when the beam part is installed in place on the pillar part and the beam part is subjected to a torque tending to rotate around the longitudinal axis of the beam 31. The side surfaces of the end support plate 57 form the bottom support surfaces 67. The bottom support surfaces 67 can be vertical or oblique so that the bottom support surfaces 67 are symmetrical with respect to the vertical central axis of the end support plate 57. The upper support surfaces 66 of the tongue part 40 are higher than the lower support surfaces 67 of the end plate 57.

The width of the groove 48 of the end plate 41 at the point of the lower support surfaces 55 is greater, for example 10-50 mm greater, typically 20-40 mm greater, than the width of the tongue part 40 at the upper support surfaces 66. In this way, the hahlo 48 is easier to place on top of the string part 40 in the initial stage of installation.

The tongue part 40 can comprise a wedge plate 59, the front surface of which is attached to the back surface of the end support plate 57. The opposite sides of the wedge plate 59 have slanted side support surfaces 61. The wedge plate 59 tapers upwards. The wedge plate 59 is narrower than the — end support plate 57. In addition, the tongue part 40 can comprise a protective plate 65, the front surface S 25 — of which is attached to the back surface of the wedge plate 59, for example the upper and lower parts of the wedge plate 59. The protective plate 65 can be rectangular. The protective plate 65 is wider than the wedge plate 59. The protective plate 65 is narrower than the end support plate 57. E The protective plate 65 forms a control space for the wedge 64.

DS > 30 — The tongue part 40, for example the frame plate 69, comprises a shoulder 64 to hold the tongue part 40 in place in the column housing of the column part. A horizontal plate is attached to the roof part 70 of the pillar box, on which the shoulder 64 rests and prevents the tongue part 40 from rising up from the pillar part when lifting forces are applied to the beam part.

The tongue part 40 can be removed from the pillar housing when the beam part has been removed from the top of the pillar part. Figure 2 shows the beam part viewed from the direction of the end of the beam 31 and cut from the housing 50. The opposite sides of the upper part of the end plate 41 halve 48 form the top contact surfaces 54. The opposite top contact surfaces 54 can be parallel, for example vertical. The shape of the upper support surfaces 54 corresponds to the shape of the upper support surfaces 66 of the tongue part 40. When the beam part is installed on the column part, there is an installation clearance between each upper contact surface 54 and upper support surface 66, the size of which is typically 2-4 mm. Thus, the combined mounting gap between both upper support surfaces 66 and upper contact surfaces 54 is typically 4-8 mm. In addition, there is an installation gap between both lower support surfaces 67 of the tongue part and the side inner surface 68 of the case, the size of which is typically 2-4 mm. Thus, the combined installation clearance between both lower support surfaces 67 and inner side surfaces 68 is typically 4-8 mm. In the lower part of the hahlo 48, the opposite sides of the hahlo form the bottom contact surfaces

55. The bottom contact surfaces 55 are slanted so that the distance between the bottom contact surfaces 55 and thus the width of the groove 48 increases downwards. Opposite upper abutment surfaces 54 are symmetrical with respect to the vertical central axis of the shaft 48. Opposite bottom contact surfaces 55 are symmetrical with respect to the vertical central axis of the shaft 48. — In figures 1, 5 and 6, the beam part is mounted on the pillar part. In this case, the upper contact surface 58 of the hahlon 48 S 25 is against the support surface 62 of the tongue part 56. The end plate g 57 of the string part 40, the wedge plate 59 and the protective plate 65 are inside the housing 50. There is a wedge slot, E, which tapers downwards, between both of the oblique support surfaces 61 of the wedge plate 59 and the inner side surface 68 of the housing. The connection arrangement comprises a wedge 64 for supporting the tongue part 40 on the inner side surface 68 of the housing 50. The wedge 64 is fitted in the wedge slot at an angle > 30 — against the side support surface 61 and the inner side surface 68 of the housing 50. The bottom support surface 67 on the opposite side of the tongue part 40 with respect to the wedge 64 is against the inner side surface 68 of the housing 50. In this case, the tongue part 57 is supported by a wedge 64 on the inner side surfaces 68 of the housing 50.

The connection arrangement can comprise a second wedge 64, which is fitted into the wedge slot against the second slanted side support surface 61 and the inner side surface 68 of the housing in order to change the rotation of the beam part and/or to support the tongue part 40 on the inner side surfaces of the housing 50

68. In this case, the tongue part 40 has a wedge 64 on both sides, with which the tongue part 40 is supported on the opposite inner side surfaces of the housing 68. When the beam part is subjected to a torque tending to rotate around the longitudinal axis of the beam, for example in an installation situation, the upper contact surface 54 of the tongue part 48 — rests against the upper support surface 66 of the tongue part 40. In addition, the housing 50 the inner side surface 68 rests against the lower support surface 67 of the tongue part 40. The lower support surface 67, against which the inner side surface 68 of the housing 50 rests, and the upper support surface 66, against which the upper support surface 54 of the end plate 41 rests, are on opposite sides of the tongue part 40. If the torque tending to rotate the beam part acts in the opposite direction, the inner side surface 68 rests against the second lower support surface 67 and the second upper support surface 54 rests against the second upper support surface 66. The second lower support surface 67 and the second upper support surface 66 are then on opposite sides of the tongue part 40. The installation situation refers to a situation where the tongue part 40 is not supported by means of a wedge 64 on the inner side surface 68 of the housing. The longitudinal axis of the beam 31 is in the same direction as the normal of the back surface of the end plate 41. The concrete material of the beam 30 poses a problem in terms of the torsional strength of the connection arrangement, because the end plate 41 of the beam part cannot transfer all the downward horizontal forces caused by the torque on the contact surfaces of the beam 48, because the concrete of the beam 30 S 25 — cannot receive very large forces at this point. Therefore, the structural parts that transfer the g torque in the lower part of the joint have been moved inside the concrete beam 31 in the beam part. The transfer of the torque from the beam part to the column part E is divided into two parts: the torque of the installation situation and the torque of the final use situation. In the final situation, i.e. when the joint arrangement is supported > 30 — with wedge 64, the joint must also be non-twisting for torsional forces.

S In the application form according to Figures 1-6, the parts of the joint that transfer the torque are placed in two places. The upper contact surface 54 of the Hahlo 48 rests on the upper support surface 66 of the tongue part 56 to receive the upper horizontal force of the torque of the beam part. This works in all situations for the upper horizontal forces of the torque. In the installation situation, the inner side surface 68 of the housing 50 rests on the lower bearing surface 67 of the end plate 57. In this case, the beam part can first rotate by the installation clearance between the inner side surface 68 and the lower bearing surface 67, after which the inner side surface 68 rests on the lower bearing surface 67. The lower bearing surface 67 also receives the downward horizontal force of the torsion. In the final situation, a wedge 64 is installed against the slanted side surface 61 of the wedge plate 59 of the string part, which also rests on the inner side surface 68 of the housing 50. The wedge 64 locks the joint arrangement into a non-rotational, non-rotating and/or torque-receiving structure. It is obvious to a professional in the field that the invention is not limited only to these solutions. The invention and its embodiments may therefore vary within the scope of the patent claims.

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Claims (15)

PATENT CLAIMS 1. A connection arrangement for connecting a vertical element, such as a column (30) or a wall element, and a beam (31), which connection arrangement comprises: - — a beam part that can be attached to the end of the beam (31), which comprises an end plate (41) with a bottom-open slat (48) with a contact surface (58) at the base, and - — a column part that can be attached to the vertical element, which comprises a tongue part (40) with a support surface (62) against which the slat (48)'s contact surface (58) ) is arranged to be supported in order to receive a vertical load, characterized by the fact that - on the opposite sides of the string part (40) there are upper support surfaces (66) and in the upper part of the hahlo (48) there are upper support surfaces (54) on the opposite sides, one of which is arranged to rest against the string part (40 ) the second upper support surface (66), when the beam part is mounted on the column part and the beam part is subjected to a torque tending to rotate around the longitudinal axis of the beam, - the opposite sides of the tongue part (40) have the lower support surfaces (67) and the end plate (41) a case (50) is attached to both sides of the halmo (48), inside which the lower support surfaces (67) of the tongue part are arranged, when the beam part is mounted on the column part, - the inner side surface (68) of the case (50) is arranged to rest on the lower support surface (67) of the tongue part (40) ), when the beam part is subjected to a torque tending to rotate N 25 around the longitudinal axis of the beam, N - the side of the tongue part (40) has an inclined side support surface (61), which is inside the housing (50) when the beam part is mounted on the pillar part, and - - connection arrangement comprises a wedge (64) that can be fitted against the inclined side support surface (61) and the inner surface (68) of the housing (50) to support the tongue part (40) & 30 on the inner side surface (68) of the housing (50). O N N 2. A connection arrangement according to claim 1, characterized in that the lower part of the shaft (48) has lower contact surfaces (55) on opposite sides, the horizontal distance between the lower contact surfaces (55) being greater than the horizontal distance between the upper contact surfaces (54). 3. A connection arrangement according to claim 1 or 2, characterized in that the upper support surfaces (66) of the tongue part (40) are at a different height than the lower support surfaces (67). 4. A connection arrangement according to one of the preceding claims, characterized by the fact that the upper support surface (66) and the lower support surface (67), against which the upper support surface (54) and the inner side surface of the housing (68) are arranged to rest when a torque is applied to the beam part, are the tongue part (40) on opposite sides. 5. A connection arrangement according to one of the preceding claims, characterized by the fact that the second side of the tongue part (40) has a second slanted side support surface (61) and the connection arrangement comprises a second wedge (64) which can be fitted to the second slanted side support surface (61) and the inner side surface of the housing ( 68) to change the twist of the beam part and/or to support the tongue part (40) on the opposite inner side surfaces (68) of the housing (50). 6. A connection arrangement according to one of the preceding claims, characterized by the fact that the lower support surfaces (67) of the tongue part (40) are vertical. — 7. A connection arrangement according to one of the preceding claims, characterized in that the horizontal distance between the slanted side support surfaces (61) of the tongue part (40) increases downwards. E 8. A connection arrangement according to one of the preceding claims, characterized in that the pillar part comprises a pillar housing (33), which comprises a front wall > 30 (37) with a vertical opening through which the tongue part (40) is fitted to the pillar housing. 9. A connection arrangement according to one of the preceding claims, characterized by the fact that the tongue part (40) can be removed from the pillar housing (33) when the beam part has been removed from the top of the pillar part. 10. A connection arrangement according to one of the preceding claims, characterized in that there is an installation gap between the upper contact surfaces (54) of the halve and the upper support surfaces (66) of the tongue part and/or there is an installation gap between the lower support surfaces (67) of the tongue part and the side inner surfaces (68) of the case. 11. The connection arrangement according to claim 10, characterized in that the size of the installation clearance between the upper support surface (66) and the upper contact surface (54) and/or between the lower support surface (67) and the inner side surface (68) is 2-4 mm. 12. Connection arrangement according to claim 2, characterized in that the width of the hinge (48) at the bottom of the lower contact surfaces (55) is larger, typically 10-50 mm larger, than the width of the tongue part (40) of the support surface (62) and/or the upper support surfaces (66) under. 13. A connection arrangement according to one of the preceding claims, characterized in that the upper contact surfaces (54) of the opposite sides of the hook (48) are symmetrical with respect to the vertical central axis of the hook (48) and/or the bottom contact surfaces (55) of the opposite sides of the hook (48) are symmetrical with respect to the hook (48) ) with respect to the vertical central axis. S 25 14. A joint comprising a vertical element (2), such as a pillar or wall element, and a beam (3), characterized in that the beam (3) is connected to the vertical element (2) according to one of the above claims 1-13 with a connection arrangement, E whose column part is attached to the vertical element and the beam part is attached to the end of the beam (3), and the beam part is mounted on the column part in such a way that the contact surface (58) of the beam part © 30 hinge (48) rests on the support surface O (62) of the tongue part (40) of the column part . 15. A joint according to claim 14, characterized in that a wedge (64) is fitted against the slanted side support surface (61) of the tongue part (40) and the inner surface (68) of the housing (50) to support the tongue part (40) on the inner side surfaces (68) of the housing (50) ). OF O OF O < Q I = < O OF LO OF O OF