Method and connector set for connecting beams of wood material

Abstract

The invention relates to a method and to a connector set for connecting beams from wood material, in particular solid wood, glued laminated wood, laminated veneer wood, or plywood board, in particular for connections that are under a compressive as well as a tensile load, wherein a connector has at least one plate-shaped portion for insertion into prefabricated slots in the beam or the beams, wherein at least the plate-shaped portion of the connector is composed of synthetic resin densified wood, wherein the synthetic resin densified wood is composed of a plurality of hardwood layers disposed on top of one another and synthetic resin, and wherein wood screws for fixing the connector are provided.

Claims

1. A method for connecting beams from solid wood or glued laminated wood, comprising the steps of: producing slots in the beams; introducing a connector made from synthetic resin densified wood into the slots; and fixing the connector in the slots by means of wood screws driven through each beam and the connector.

2. The method as claimed in claim 1, wherein the wood screws when fixing the connector are screwed into the beams and the connector without pre-drilling the beams and the connector.

3. The method as claimed in claim 1, wherein wood screws having drill tips are used.

4. The method as claimed in claim 1, wherein wood screws having a full thread are used.

5. The method as claimed in claim 1, wherein wood screws having at least one thread-free portion are used.

6. The method as claimed in claim 5, wherein the wood screws are arranged such that the connector in the finally assembled state is penetrated by a thread-free portion of the wood screws.

7. A connector set for beams of wood material, in particular for connections that are under a compressive as well as a tensile load, wherein the connector set has at least one connector with at least one plate-shaped portion for insertion into prefabricated slots in the beam or the beams, wherein at least the plate-shaped portion of the connector is composed of synthetic resin densified wood, and wherein the synthetic resin densified wood is composed of a plurality of hardwood layers disposed on top of one another and synthetic resin, wherein the connector set has a plurality of wood screws which are driven through each beam and the connector for fixing the at least one connector in the beams.

8. The connector set as claimed in claim 7, wherein the plurality of wood screws have in each case one drill tip.

9. The connector set as claimed in claim 7, wherein the wood screws are configured as fully-threaded screws.

10. The connector set as claimed in claim 7, wherein the wood screws have at least one thread-free portion.

11. The connector set as claimed in claim 10, wherein at least one thread-free portion is disposed between two threaded portions.

12. The connector set as claimed in claim 7, wherein the synthetic resin is a duromeric synthetic resin.

13. The connector set as claimed in claim 7, wherein the synthetic resin densified wood has an embedded strength, at the plurality of wood screws fixing the at least one connector in the beams, of at least 150 N/mm.sup.2.

14. The connector set as claimed in claim 7, wherein the synthetic resin densified wood has a tensile strength parallel with the hardwood layers between 100 N/mm.sup.2 and 150 N/mm.sup.2.

15. The connector set as claimed in claim 7, wherein the synthetic resin densified wood has a compressive strength parallel with the hardwood layers between 110 and 150 N/mm.sup.2.

16. The connector set as claimed in claim 7, wherein the synthetic resin densified wood has a compressive strength perpendicular to the hardwood layers between 250 and 310 N/mm.sup.2.

17. The connector set as claimed in claim 7, wherein the synthetic resin densified wood, when flexurally stressed, has an elasticity modulus perpendicular to the hardwood layers between 15,500 and 18,500 N/mm.sup.2.

18. The connector set as claimed in claim 7, wherein the synthetic resin densified wood, when compressively stressed, has an elasticity modulus perpendicular to the hardwood layers between 2250 and 2850 N/mm.sup.2.

19. The connector set as claimed in claim 7, wherein the synthetic resin densified wood, when compressively stressed, has an elasticity modulus parallel with the hardwood layers between 5500 and 6500 N/mm.sup.2.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Further features and advantages of the invention are derived from the claims and from the description hereunder of a preferred embodiment of the invention in conjunction with the drawings. Individual features of the various embodiments herein can be combined in an arbitrary manner without departing from the scope of the invention. In the drawings:

(2) FIG. 1 shows a view from obliquely above of a beam connection having a connector according to the invention;

(3) FIG. 2 shows a front view of the beam connection of FIG. 1;

(4) FIG. 3 shows a lateral view of the beam connection of FIG. 1;

(5) FIG. 4 shows a plan view of the beam connection of FIG. 1;

(6) FIG. 5 shows a view from obliquely above of the connector;

(7) FIG. 6 shows a plurality of lateral views of wood screws for the connector set according to the invention; and

(8) FIG. 7 shows a plurality of lateral views of further wood screws for the connector set according to the invention.

DETAILED DESCRIPTION

(9) The illustration of FIG. 1 shows a connection between a first beam 10 and a second beam 12, wherein the second beam 12 is placed onto the end side of the first beam 10 such that a T-shaped arrangement results. The beams 10, 12 are configured either as solid wood beams or as glued laminated wood beams.

(10) The beams 10, 12 are illustrated so as to be transparent such that a connector 14 that is disposed between the beams 10, 12 can be seen. The connector 14 per se would not be visible and is therefore illustrated with dashed lines. Furthermore, a plurality of screws 16 which fix the connector 14 in relation to the beams 10, 12 are illustrated with solid lines. These screws are illustrated with solid lines even while said screws per se would be visible only in the region of their respective screw heads on that side of FIG. 1 that faces the observer.

(11) The connector 14 has the shape of a rectangular plate and is inserted in slots 18, 20 which are only indicated in the illustration of FIG. 1. A slot 18 is incorporated in the beam 10 so as to emanate from the upper end side of said beam 10, and a second slot 20 is incorporated in the beam 12. The two slots 18, 20 conjointly result in a clearance in the form of a rectangular plate which is only slightly larger than the connector 14.

(12) Once the slots 18, 20 have been incorporated into the beams 10, 12 the connector 14 is inserted, for example, into the slot 18 of the beam 10. The beam 12 is then placed onto the beam 10 such that the connector 14 is simultaneously guided into the slot 20 of the beam 12.

(13) By contrast to conventional beam connections in which steel plates are used as connectors, the connector 14 is composed of synthetic resin densified wood. The connector is composed of a plurality of hardwood layers disposed on top of one another and synthetic resin. The hardwood layers are adhesively bonded to one another by means of the synthetic resin and are at least in portions also penetrated by the synthetic resin. On account thereof, the connector 14 is extremely capable of bearing loads and above all can transmit the compressive and tensile loads which arise after the installation of the beams 10, 12 in a wooden framework structure of a building between the beams 10, 12. It is surprisingly possible herein for the forces that arise between the beams 10, 12 in the beam structure of a wood construction to be transmitted by means of the connector 14 which is composed of synthetic resin densified wood. The load bearing capability of the beam connection having the connector 14 herein is approximately identical to the load bearing capability of beam connections having conventional connectors from steel plates.

(14) Upon insertion into the slots 18, 20 the connector 14 is then fixed by means of a plurality of wood screws 16 in relation to the beams 10, 12. To this end, the wood screws 16 are screwed perpendicularly to the comparatively large surfaces of the connector 14 through the beam 10 and the connector 14, or through the beam 12 and through the connector 14, respectively. The screws 16 herein are screwed through the beams 10, 12 and the connector from the front side that in FIG. 1 faces the observer, as well as through the rear side of the beams 10, 12 that faces away from the observer. The particular advantage of the connector 14 according to the invention herein also lies in that conventional wood screws 16 can be used. The wood screws 16 can indeed be readily screwed into the beams 10, 12 composed of solid wood or glued laminated wood, and the screws are also configured such that said screws penetrate the connector 14 composed of synthetic resin densified wood without pre-drilling. The beams 10, 12 upon insertion of the connector 14 consequently do not have to be pre-drilled. Pre-drilling or partial pre-drilling of the beam and/or of the connector can be provided in the context of the invention, for example in order for the screwing-in torque required to be reduced.

(15) The connector 14 is fixed in relation to the beams 10, 12 after the screws 16 have been screwed in, and the connection between the two beams 10, 12 is capable of being fully stressed by loads.

(16) The illustration of FIG. 2 shows a front view of the connection of FIG. 1. The beams 10, 12 are again illustrated so as to be transparent such that the connector 14 lying within the beams 10, 12 can be seen.

(17) The connector 14 is fixed in relation to the beam 12 by a total of eight wood screws 16 and the connector 14 is also fixed in relation to the beam 10 by a total of eight wood screws 16. The wood screws 16 herein are mutually disposed in parallel rows of in each case four screws. Each second screw in each row is advantageously inserted from the opposite side. Thus, the screw on the extreme left in the topmost row of screws 16 in FIG. 2 would thus be inserted from the front side that faces the observer. The following screw on the right would then however be inserted from the rear side that faces away from the observer. An alternating insertion of the screws of this type can then be performed across the total of four rows of screws 16, wherein in the illustration of FIG. 2 the insertion direction of the screws can additionally also be alternated in the direction from top to bottom.

(18) The illustration of FIG. 3 shows the connection of FIG. 1 from the side, wherein the beams 10, 12 are again illustrated so as to be transparent such that the connector 14 and the screws 16 can be seen.

(19) The illustration of FIG. 4 shows the connection of FIG. 1 from above. The beams 10, 12 are again illustrated so as to be transparent such that the connector 14 and the screws 16 can be seen. Since a total of four screws are disposed on top of one another, or behind one another in the viewing direction of FIG. 4, respectively, the screws are drawn so as to be on top of one another. Each screw 16 however has a tip on one end and a head that is widened in relation to the tip at the opposite end.

(20) FIG. 4 shows the connector 14 from obliquely above. A plurality of hardwood layers 22 which are connected by means of synthetic resin (not illustrated) and at least in portions are penetrated by the synthetic resin can be seen. The connector 14 after the pressing and curing of the synthetic resin is extremely capable of bearing a load and can be used instead of a conventional steel-plate connector.

(21) The connector 14 is usually cut out from already completed board material. This can be performed by means of conventional woodworking tools.

(22) FIG. 6 shows a plurality of wood screws 26, 28, 30, and 32, which can be used in the method according to the invention and can be part of the connector set according to the invention. All wood screws 26, 28, 30, and 32 have a drill tip 34 which can be configured either as a drill tip having a classic drill bit geometry or else as a rolled tip having scraper ribs. Each of the wood screws 26, 28, 30, and 32 is moreover provided with a screw head 36, wherein all screw heads 36 are configured as countersunk heads. The screw 26 is configured as a so-called fully threaded screw and with the exception of the drill tip 34 and of a very short cylindrical portion 38 directly below the screw head 36 has a continuous wood thread 40.

(23) The wood screw 28, apart from the drill tip 34 and the cylindrical portion 38 directly below the screw head 36, has two threaded portions 42 and 44 and a cylindrical thread-free portion having a smooth external face 46 that lies between the two threaded portions 42, 44. The threaded portion 42 herein lies between the portion 38 and the thread-free portion 46, and the threaded portion 44 lies between the thread-free portion 46 and the drill tip 34.

(24) The wood screw 28 can be used, for example, for fastening a connector that is disposed so as to be centric in a beam. The connector in the completely assembled state of the wood screw 28 is then penetrated by the thread-free portion 46. Fastening of the connector which largely corresponds to the fastening using a rod dowel is possible on account thereof.

(25) The wood screw 30 is provided with a threaded portion 48 emanating from the drill tip and with a thread-free portion 50 which extends from the head end of the threaded portion 48 up to the screw head 36.

(26) The wood screw 32 is provided with two threaded portions 52, 54, and two thread-free portions 56, 58. A thread-free portion 56 initially follows, so as to proceed from the screw head 36. The first threaded portion 52 adjoins the thread-free portion 56. A thread-free portion 58 again follows the threaded portion 52. A second threaded portion 54 which extends up to the drill tip 34 then follows the thread-free portion 58. The threaded portions, 52, 54 are of approximately identical lengths, and the thread-free portions 56, 58 are also of approximately identical lengths.

(27) The same thread is provided in the threaded portions in the case of all wood screws 26, 28, 30, 32, The wood screws 26, 32 having a plurality of threaded portions 42, 44, 52, 54 thus also always have the same wood thread having the same screw pitch.

(28) The illustration of FIG. 7 shows five further wood screws 60, 62, 64, 66, 68 which can be used in a method according to the invention and which can be part of a connector set according to the invention.

(29) The wood screw 60 has a disk-shaped head 70, the latter being adjoined by a thread-free portion 72. A router portion 74 having a steep thread follows the thread-free portion 72. A threaded portion 76 is then disposed from the router portion 74 up to the tip of the screw. Scraper ribs 78 that run in a manner opposed to the wood thread are disposed in the conically tapered tip of the screw 60.

(30) The wood screw 72 has a hexagonal head 80 which is followed by a thread-free portion 82. A router portion 84 having a steep thread is disposed between the thread-free portion 82 and a threaded portion 86. The threaded portion 86 extends up to the conically tapered tip of the screw, wherein in addition to the normal wood thread an opposed thread 88 is disposed on the conically tapered tip.

(31) The wood screw 64 has a countersunk head 90 which is provided with a plurality of router pockets 92. A thread-free portion 94 follows the countersunk head 90, said thread-free portion 94 again being adjoined by a router portion 96 having a steep thread. The router portion 96 is followed by a threaded portion 98 which extends up to the conically tapered tip of the screw. Scraper ribs 78 which are opposed to the actual thread are disposed on the tip of the screws.

(32) The screw 66 is configured as a fully threaded screw, and a threaded portion 100 extends between the screw head 90 which is configured having the router pockets 92. A drill tip 102 is disposed on that end of the wood screw 66 that is opposite the screw head 90. The drill tip 102 has a conventional drill geometry having two primary cutters and two secondary cutters. The drill tip 102 is produced by pinching, for example. The wood screw 68 differs from the wood screw 66 only in terms of the configuration of the screw head 104 thereof. The threaded portion 100 and the drill tip 102 are configured in a manner identical to that of the wood screw 66. The screw head 104 is configured so as to be approximately cylindrical, having a smooth external circumference.

(33) Individual features of the wood screws illustrated in FIGS. 6 and 7 can be mutually combined in an arbitrary manner without departing from the scope of the invention. All wood screws illustrated in FIGS. 6 and 7 are suitable for being screwed into beams without pre-drilling and also for penetrating the connectors.