RU2109113C1 - Connecting unit for components of spatial framework of buildings - Google Patents

Abstract

FIELD: construction engineering. SUBSTANCE: this can be used in joining wooden components in framework of building. Connecting unit for components of spatial framework of building has vertical post with orthogonally located slots made in its body. Installed in aforesaid slots are connecting strips with holes for locks. Also provided are horizontal and inclined beams. Connecting strips are made in the form of flat rectangles in which at least one angle is cut off, and holes for locks are made in each of remaining angles of strip. Slots are created in horizontal and/or inclined beams in places of their adjoining to posts. Installed in each of aforesaid slots is one of angles of connecting strips secured in beam by means of horizontal lock which is inserted into through-passage and into hole made in angle of connecting strip. Made in base of slots are cylindrical holes and dowel is inserted there. In another version, U-shaped cramp iron is seated in slot. Heads of posts and beams can be configurated as truncated four-face pyramids. EFFECT: higher efficiency. 8 cl, 13 dwg

Description

 The invention relates to the construction and can be used in the construction of low-rise buildings and structures with a wooden frame.

 A butt joint of stoics with beams is known, having vertically oriented slots at the ends of the beams that are aligned with each other and the axial plane of the beam, containing a connecting plate fixed to the beam slit with a downward L-shaped protrusion of a rectangular outline at the end, and a support element interacting in the rack slot on the contact surface with the protrusion of the connecting plate [1]. This compound has insufficient bearing capacity.

 Also known is the nodal connection of the rods of the spatial frame, including the core in the form of a hexahedron with holes in the faces and the ends of the rods connected with them by bolts. The core is made hollow and at least one face is missing in it, and part of the remaining lateral faces are provided with slots. The ends of the rods are made with threaded holes and bolts installed in them [2]. The disadvantage of this assembly design is the location of adjacent beams that is rigidly determined by the core and does not allow varying the angles of inclination of the beams.

 The closest analogue to be taken as a prototype of the present invention is the butt connection of the beam with the building element, made in the form of a rack with slots orthogonally located in its upper part, into which flat connecting plates with grooves and holes for the pins are inserted. The connecting plates are equipped with an upwardly directed protrusion extending beyond the protrusions of similar plates mounted in grooves of beams in contact with the strut [3]. The described butt joint allows you to collect frame elements located at a small angle to the horizontal. Using this unit, it is impossible to dock the racks vertically, and the load on the beams is transmitted only through the pins, which puts forward increased demands on the strength of the supporting part of the beam.

 The aim of the invention is to simplify the configuration of the connecting plates, providing the possibility of joining the beams with the racks at different angles to the horizontal and providing the necessary strength of the supporting parts of the beams.

The goal is achieved in that the junction of the elements of the spatial frame of the building contains a vertical rack with slots orthogonally located in its body, into which connecting plates with holes for the clips, and horizontal and inclined beams are inserted. The connecting plates are made in the form of flat rectangles, in which at least one of the corners is cut off, and the holes for the clips are made in each of the remaining corners of the plate and on both sides of the axes passing through the corners. In horizontal and / or inclined beams at their places of contact with the uprights, slots are formed, in each of which one of the corners of the connecting plate is mounted, fixed in the beam by means of a horizontal clamp passed through the through channel formed in the beam and through the hole in the corner of the connecting plate. At the base of one of the slots of the rack, a cylindrical through hole with a diameter larger than the width of the slot and an axis parallel to the base of the slot into which the cylindrical element congruent to the hole is inserted can be formed. In the through slots of the horizontal and inclined beams, cylindrical through holes with a diameter larger than the width of the slot of the beam can be formed with an axis parallel to the base of the slot into which the cylindrical elements are congruent to the hole. In the slots of the uprights and / or beams, a connecting element can be mounted, made in the form of a “P” -shaped bracket, open towards the end of the rack or beam, and with a shelf resting on the end of the slot; the distance between the shelves of the bracket “in the light” is greater than the thickness of the connecting plate, and the connecting element is fixed to the rack or beam by means of a latch installed in a through hole formed perpendicular to the bracket in the body of the rack or beam, in the shelves of the bracket and in the connecting plate. In the node of the frame can additionally be mounted a vertical stand, at the base of which are made orthogonal grooves congruent to the connecting plates, and horizontal holes are formed for the latches. In addition, at the base of one of the connecting plates mounted in the rack, an element congruent to the through hole made in the base of the slot in the rack can be rigidly fixed. The upper part of the racks with the connecting plates inserted into them can be made in the form of two figures articulated by their bases, the upper of which is formed by a rectangular beam, and the lower one is a truncated tetrahedral pyramid with lateral sides inclined at an angle of 45 ^o to the base; Beams adjacent to the rack have heads, congruent configurations of the upper part of the rack in the zone of their adjacency.

 The latches can be made in the form of cylindrical pins with a broadening of one of the ends and longitudinal radially arranged protruding ribs of a triangular section formed at this end, either in the form of bolts with nuts or in the form of screws. The connecting plates may have vertical through-cuts, the walls of which are located tangentially to the holes made in the corners of the connecting plates, which are the base of the slot.

A comparative analysis of the present invention with the prototype shows that it differs in the implementation of the connecting plates in the form of flat rectangles, in which at least one of the corners is cut off, and the holes for the clamps are made in each of the remaining corners of the plate on both sides of the axes passing through the corners, moreover, in horizontal and / or inclined beams in the places of their adjacency to the uprights, through slots are formed, in each of which one of the corners of the connecting plate mounted in the beam is mounted m horizontal fastener passed through the beam formed in the through-passage and through an opening in the corner of the connecting plate. The difference also lies in the formation of cylindrical holes in the bases of the slots, in excess of the diameter of these holes in the width of the slots, in the placement of cylindrical elements in the holes, in the placement of racks and beams of the connecting element in the slots and in the form of its execution and fastening, in the presence of an additional rack, as well as in the form of execution of the heads of racks and beams. This analysis allows us to conclude that there is novelty in the invention. Comparison of the proposed site with other known technological solutions for a similar purpose shows that
the form of execution of the connecting plates, in addition to being easy to manufacture, allows you to install the beams at any angle to the horizon and, as a special case, mount an additional rack;
- the formation of cylindrical through holes with a diameter larger than the width of the slot, the location of these holes, the placement of cylindrical elements in them, as well as the presence of a U-shaped bracket allows you to increase the bearing capacity of the frame elements;
- the execution form of the heads of the racks and beams allows you to increase the area of bearing beams on the rack, and also improves the operation of the node;
- the implementation of vertical through-slots along the tangent and the holes formed in the corners of the connecting plates, facilitates the Assembly of the frame.

 This comparison allows us to conclude that the proposed invention exceeds the existing level of technology.

 Figure 1 shows a General view of the site, the installation of frame elements on the head of the column; in FIG. 2 - the same, the installation of frame elements on the body of the column; in FIG. 3 - the same, the implementation of the connecting plate of the T-shaped section; in FIG. 4 - the same, the execution of the column head and beams with bevels; in FIG. 5 - the same, option, frame assembly; in FIG. 6 - embodiments of the connecting plates; in FIG. 7 is an embodiment of a connecting plate in the form of a three-beam star; in FIG. 8 is an embodiment of a connecting plate with through slots; in FIG. 9 is an embodiment of a connecting plate integral with a cylindrical support element; in FIG. 10 is an embodiment of a connecting plate in the form of overhead elements; in FIG. 11 - an installation option of the connecting element in the form of a three-ray star on the head of the rack; in FIG. 12 is an installation option of a supporting cylindrical element; in FIG. 13 - installation option of a U-shaped connecting element.

In the upper part 1 of the rack 2 of the frame, vertical slots 3 are formed, into which the connecting plates 4 are inserted. These plates are made in the form of flat rectangles in which at least one of the corners is cut at an angle of 45 ^o . A groove 6 is made perpendicular to this slice 5 in the plate body. On top of this plate, the same connecting plate 8 is inserted into the slot 7 of the upper part of the rack perpendicularly to it so that the grooves of both plates fit into each other. Holes 9 are drilled in the connecting plates: one in each corner 10 and a pair on both sides of the axes 11 passing through the corners. In the design position, the holes 11 coincide with the holes 12 formed in the body of the rack. The latches 13 are passed through these holes. The latches are cylindrical pins with a broadening 14 of one of the ends and longitudinal, radially extending protruding ribs 15 of a triangular section formed at the broadened end of the nagel. The latch can also be made in the form of a bolt with a nut or in the form of a screw (not shown in the drawings). Depending on the configuration of the frame, the connecting plates will have one or more trimmed corners: the corners of the connecting plates are cut from the side where no beam adjoins the rack. In all other cases, the corners 10 stand for the dimensions of the rack. To better distribute the loads falling on the rack at the places of installation of the connecting plates, a through hole 16 is formed at the base of one of the slots of the rack, wider than the width of the slot 7, and an axis parallel to the base of the slot, into which the element 17 is congruent to the hole. Alternatively, this element can be cylindrical and rigidly fixed (for example, molded as a single body) at the base of one of the connecting plates 18.

 Horizontal 19 and inclined 20 beams in places of their adjacency to the rack have slots 21, which include the corresponding angle of the connecting plate. The fastening of the connecting plate to the beam is made similarly to the fastening of the plate to the rack - using a horizontal pin 22, passed through the holes 23 in the body of the beam and the holes 9 in the connecting plate. To increase the area of bearing and, consequently, to reduce the specific load on the zone of bearing in the slot of the struts or beams, the connecting elements 24 can be mounted in the form of a U-shaped bracket, open towards the end of the rack or beam and with a shelf 25 resting on the end cut through. The distance between the shelves of the bracket of the connecting element "in the light" is greater than the thickness of the connecting plate. The connecting element is fixed to the rack or beam by means of a bolt 22 mounted in the through hole 23 formed perpendicular to the bracket in the body of the rack or beam, in the shelves of the bracket and in the connecting plate. The U-shaped bracket in its functional purpose replaces the through hole 16 and the element 17.

The same task - increasing the area of support of the beams on the racks - is solved by changing the configuration of the mating surfaces of the frame elements. The upper part of the racks with the connecting plates inserted into them can be made in the form of two figures articulated by their bases, the top 26 of which are formed by a rectangular beam having a smaller cross section than the section of the rack, and the bottom 27 is a truncated tetrahedral pyramid with sides tilted under at an angle of 45 ^o to the base, while the beams adjacent to the rack have heads 28, congruent configurations of the upper part of the rack in the abutment zone: for example, for a horizontal beam, the head also has the shape of a a bounded tetrahedral pyramid with sides inclined at an angle of 45 ^o to the base.

 The connecting plate can be installed not only in the ends of the racks, but also in the body of the racks or beams: For this, longitudinal through grooves 29 are made into them, into which the connecting plate is inserted, fixed in the working position by the same techniques as described above. You can install intermediate racks 30 and struts 31 in the frame. This same technique allows you to mount cantilever protruding beams 32, strep, etc.

 To form a higher lying room, additional racks 33 can be mounted in the frame, at the base of which are made orthogonal grooves congruent to the connecting plates, and horizontal holes for the pins are formed similar to the grooves and holes of the main rack.

 The assembly of the frame can be facilitated by the fact that in the connecting plates are formed vertical through-slots 34, the walls of which are tangent to the holes made in the corners of the connecting plates, which are the base of the slot. In this case, the latches 13 are inserted into the holes of the beams before their installation and after that the beam together with the clamp are installed in the design position, while the latches are lowered into the slot 34, as in a "bed".

 In cases where three beams should adjoin the rack, the connecting plate is made in the form of a "star" 35 in plan, and in the head of the rack, cuts are made under this "star".

 For installation in the frame of the intermediate racks 30 and struts 31, not only connecting elements cut into the body of the racks and beams can be applied, but also overhead connecting elements 36 mounted on a rack or beam using screws 37 or bolts (not shown in the drawings).

 The pins for connecting the frame elements and to increase the supporting surface of the connecting elements can be made of metal, hardwood or plastic.

Claims (9)

 1. The connection node of the elements of the spatial frame of the building, containing a vertical pillar, horizontal and inclined beams with slots located in their bodies, and connecting plates with holes for retainers, characterized in that the connecting plates are made in the form of flat rectangles with at least one cut from the corners, and the holes for the clamps are made in each of the remaining corners of the plate and on both sides of the axes passing through the corners, and in horizontal and / or inclined beams in their places at Addi ctive to racks mounted one of the corners of the coupling plate, fixed in a slot of the horizontal beam by a retainer passed through the beam formed in the through-passage and through an opening in the corner of the connecting plate.  2. The assembly according to claim 1, characterized in that a cylindrical through hole with a diameter larger than the width of the slot and an axis parallel to the base of the slot into which the cylindrical hole is congruent is inserted is formed at the base of one of the slots of the rack.  3. The node according to claim 1, characterized in that in the through slots of the horizontal and inclined beams, cylindrical through holes are formed with a diameter larger than the width of the slot of the beam, with an axis parallel to the base of the slot, into which the cylindrical holes are congruent to the hole.  4. The node according to claim 1, characterized in that in the slots of the uprights and / or beams a connecting element is mounted, made in the form of a U-shaped bracket, open towards the end of the rack or beam and with a shelf resting on the end of the slot, and the distance between the shelves of the bracket in the light, more than the thickness of the connecting plate, and the connecting element is fixed to the rack or beam by means of a latch installed in a through hole formed perpendicular to the bracket in the body of the rack or beam, in the shelves of the bracket and in the connecting plate.  5. The node according to claim 1, characterized in that in the node of the frame is additionally mounted a vertical stand, at the base of which are made orthogonal grooves congruent to the connecting plates, and horizontal holes are formed for the latches.  6. The node according to claims 1 and 2, characterized in that at the base of one of the connecting plates mounted in the rack, an element is congruently fixed, congruent to the through hole made at the base of the slot in the rack. 7. The node according to claims 1 to 6, characterized in that the upper part of the racks with connecting plates inserted into them is made in the form of two figures articulated by their bases, the upper of which is formed by a rectangular beam, and the lower one is a truncated tetrahedral pyramid with lateral sides inclined at an angle of 45 ^o to the base, while the beams adjacent to the rack have heads, configurations of the upper part of the rack in the zone of their adjacency.  8. The node according to claims 1 to 7, characterized in that the latches are made in the form of cylindrical pins with broadening of one of the ends and longitudinal radially spaced protruding ribs of triangular section formed at this end, either in the form of bolts with nuts, or in the form of a screw .  9. The node according to claims 1 to 8, characterized in that the connecting plates have vertical through slots, the walls of which are tangent to the holes made in the corners of the connecting plates, which are the base of the slot.

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