CH640591A5 - Wooden trussed girder - Google Patents

Abstract

The girder has a single-part, transversely lying upper flange and lower flange (1, 2) and at least one sloping-member row which runs between said flanges and comprises individual sloping members (4, 5, 4') running at an angle with respect to one another. In order to connect the sloping members (4, 5, 4') to the flanges (1, 2) in the joints, wedge-shaped tenons (9) at the ends of the sloping members can be glued to wedge-shaped mortises (10) on the flanges (1, 2). In this arrangement, the wedge tenons (9) and the wedge mortises (10) of the flanges (1, 2) can extend over the entire length. In order to reinforce the wedge tenon/wedge mortise connection (9, 10), the invention provides, for each joint, at least one plate-shaped connecting part (11) which consists of sheet metal, plastic or plywood and engages simultaneously in slots (13; 14; 15) in the flange (1, 2) and in the sloping members (4, 5, 4'). The connection of the sloping members (4, 5, 4') to the flanges (1, 2) may also be produced by such plate-shaped connecting parts (11) alone. In addition to a sloping-member connection by the plate-shaped connecting parts (11), the sloping members (4, 5, 4') may also be connected to the flanges (1, 2) by a parallel tenon/mortise connection (9', 10'). In this arrangement, the connecting parts (11) are in each case considerably longer than the surface on which two sloping members (4, 5, 4') are connected to a flange (1, 2). The connecting parts (11) may be located outside and/or inside the tenons (9'). The joint of the trussed girder is considerably reinforced by the connecting parts (11). <IMAGE>

Description

       

  
 

** WARNING ** beginning of DESC field could overlap end of CLMS **.

 



   PATENT CLAIMS
1. Timber framework made of wood with one-piece, transverse upper and lower chords 2) and at least one strut train running between them, the strut train being composed of individual struts (4, 5, 4 ') running at an angle to one another, each of which at a node Connect the strut ends of two struts (4, 5; 4, 5 ') to a common inner connection surface of the upper or lower flange (1, 2), characterized in that for connecting two strut ends to the upper or

  Lower flange (1, 2) at least one plate-shaped connecting part (11) made of sheet metal, plastic or plywood is provided, which is partly in a belt slot (13) running in the longitudinal direction of the beam, and partly in two strut slots (14, 15) which are aligned with one another and extend in the longitudinal direction of the beam ) engages firmly in the strut ends, the connecting part being glued on the one hand to the strut ends and on the other hand to the belt.



   2. Truss according to claim 1, characterized in that the longitudinal extent of the connecting part (11) is substantially larger than the longitudinal extent of the connection surface.



   3. truss according to claim 1, characterized in that in addition to the connecting part (13) the strut ends and the belt (1, 2) each at a node with parallel pin (9 ') or parallel grooves (10') of the same pitch and the same profile interlock and are glued together, with both the depth of the strut slots (14, 15) and the depth of the belt slot (13) significantly projecting beyond the parallel pins (9 ') (FIGS. 4-9).



   4. truss according to claim 1, characterized in that the strut ends and the belt (1; 2) at a node with wedge-shaped prongs (9) or wedge-shaped grooves (10) of the same pitch and the same profile interlock and are glued together. (Fig. 1-3a).



   5. Truss girder according to claim 4, characterized in that for the tine length essentially the relationship applies: 7.5 mmz tine length '30 mm.



   6. truss according to claim 4, characterized in that the connecting part (11) partially in the parallel with the grooves (10) belt slot (13) and partially in the two with the prongs (9) parallel strut slots (14, 15) in the Strut ends engages firmly, both the depth of the strut slots (14, 15) in the strut ends and the depth of the belt slot (13) in the belt (1; 2) significantly exceeding the tine length and the connecting part (11) on the one hand with the strut ends and on the other hand is glued to the belt (1; 2) (Fig. l-3a).



   7. truss according to claim 1 or 4, characterized in that the straps (1, 2) each have un weakened belt sections on both sides of the nodes (Fig. 1, 3a, 4, 5).



   8. truss according to claim 4, characterized in that the wedge-shaped grooves (10) of the straps (1, 2) extend over the entire length of the straps (Fig. 3).



   9. truss according to claim 3, characterized in that the connecting part (11) in the strut ends outside the parallel pin (9 ') and in the belt outside the parallel grooves (10') (Fig. 4-7a, 12).



   10. truss according to claim 3, characterized in that the connecting part (11) in the strut ends within a pin (9 ') and in the belt 2) within a groove (10') (Fig. 8, 10-12).



   11. Truss according to claim 3, characterized in that the connecting part (11) in the strut ends at least partially outside a pin (9 ') and in the belt (1; 2) at least partially outside a groove (10') (Fig. 9).



   12. truss according to claim 1, characterized in that at least two plate-shaped connecting parts (11) made of metal or plastic outside the belt (1; 2) are connected to each other like a bow (Fig. 7a, 10, 1 1).



   The invention relates to a timber truss with one-piece, transverse upper and lower chords and at least one strut train running between them, the strut train being composed of individual struts running at an angle to one another, of which the end faces of two struts meeting at a node meet firmly connect a common inside connection surface of the upper and lower chord.



   Trusses of the above type have become known, in which the straps have been weakened relatively strongly by grooves in order to connect the struts to the straps. To compensate for this weakening, it was necessary to make the belts particularly thick-walled, but this led to heavy and expensive carriers.



   The object of the invention is to provide a truss of the type mentioned, in which the straps for connecting the struts are subjected to comparatively less weakening than was previously considered necessary to carry a certain load.



   This object is achieved according to the invention with the characterizing feature of claim 1. Advantageous embodiments according to the invention result from the subclaims.



   Finger joints have been known for a long time, in which two boards or planks or beams engage at their ends with wedge-shaped tines of the same pitch and the same profile and are glued together.



   In the known finger joint connections between two wooden parts to be glued together, there is no comparable weakening problem as with the belts of the wooden beams. However, this problem is of particular importance when evaluating a wooden beam with a high load-bearing capacity and minimal belt cross-sections. It was all the more surprising that this problem, which has been open for a long time, can be solved in a particularly simple manner by using the finger joint connections, which have also been known for a long time. It is thus the particular merit of the inventor in the present case to have recognized that only the use of the known finger joint allows the connection of two angularly abutting strut ends to the inside of a belt with a comparatively very slight weakening of the belts.

 

   The tine lengths can be approximately between 7.5 mm and 30 mm, preferably between 7.5 mm and 20 mm. The smaller the tine length, the greater the number of tines across the width of the struts. The number of tines also depends on the flank angle selected. The choice of tine number and flank angle of the tines depends on the required connection strength of the struts to the belts. The straps are less weakened the shorter the tine length and the smaller the tine number. On the other hand, the connection strength increases with increasing glue area between the strut and belt tines. Small belt weakenings therefore require a correspondingly large number of relatively short tines and therefore relatively wide struts for a sufficiently strong strut connection.



  Larger belt weakenings with longer tines allow a smaller number of tines and thus relatively narrower



  Strive. It is clear that here the optimal conditions for the respective wearer can be determined from the construction and the cost side, all of which have a relatively low weakening of the belts in comparison with the prior art at comparable loads.



   The straps can have the same width as the struts, preferably the straps are wider than the struts, so that the straps have weakened strap sections on both sides of their central connecting surfaces in the longitudinal direction of the carrier.



   The splines or splines of the straps can be limited to the respective connection surfaces for the struts, but they can also extend over the entire length of the straps. In this way, the connection points of the struts on the belts can be freely selected. This means belts with finger tines extending over their entire length or



  Keyways on their surfaces facing the struts can be used for wooden beams that have different distances between the strut connection surfaces.



   The already achieved connection strength of the struts finger-galvanized with the straps is significantly increased with a comparatively slight further weakening of the straps through the use of at least one plate-shaped connecting part made of sheet metal, plastic, wood-based material or plywood. Here the plate-shaped connecting part engages like an auxiliary pin, partly in a belt slot parallel with the belt tines and partly in two mutually aligned strut slots parallel with the strut tines. Both the strut slots and the belt slot are advantageously much deeper than the length of the tines. It is also particularly advantageous if the connecting part extends in the slots in the vertical direction on both sides of the connecting surface substantially beyond the length of the prongs.

  Finally, it can be essential that the longitudinal extent of the connecting part is also substantially greater than that of the connecting surface of a belt.



   The plate-shaped connecting part located in the slots is glued to the belt and in the associated struts. It can also be nailed up. It is particularly advantageous here that the slot in the belt and the slots in the two associated strut ends are relatively narrow and, as a result, the beam, but also the strut ends, are only slightly weakened, while the comparatively large area of the connecting part means that the composite in the area a node point is significantly increased. In particular, sheets can have a low thickness and, accordingly, the thicknesses of the slots into which a sheet is to be inserted are very small.



   The combination of the wedge jointing between the struts and the straps with at least one plate-shaped connecting part per connection surface is particularly advantageous because a strut connection to the straps, which is chosen relatively weakly with regard to minimal belt weakening, already leads to a considerable improvement in the connection strength due to a plate-shaped connecting part per node . The belt weakenings caused by the slots for the plate-shaped connecting parts are in no way related to the increase in connection strength achieved by the plate-shaped connecting parts.

  A galvanizing of the strut ends with the belts with relatively small tine lengths, which is chosen with a view to a largely minor weakening of the straps, is therefore significantly improved in its connection strength by the use of a plate-shaped sheet without having to accept a significant additional weakening of the belts.



   In the case of a wooden girder of the type mentioned at the outset, at least one plate-shaped connecting part made of sheet metal, plastic, wood-based material or plywood is provided for connecting two strut ends to the upper or lower flange, which partly in a belt slot running in the longitudinal direction of the girder and partly in two in each case in alignment, in Strut slots extending in the longitudinal direction of the carrier firmly engage in the strut ends, the connecting part being glued on the one hand to the strut ends and on the other hand to the belt and optionally additionally nailed.



   It has been found that the connection of two struts to a belt can be achieved by means of at least one flat, plate-shaped connecting part, without the need for additional galvanizing.



   On the other hand, it can be advantageous if, in addition to at least one connecting plate, the strut ends and the strap in the area of the strut connection surface engage and are glued together with parallel spigots of the same pitch and the same profile, both the depth of the strut slots and the depth of the strap slots making the spigot length essential towered over.



   The parallel pins differ from the above-mentioned finger tines in that the pins are delimited by parallel sides and engage in grooves with correspondingly parallel walls, while the finger tines and the associated key grooves have a wedge-shaped more or less tapering cross-section.



   Due to the parallel mortise-tenoning of the struts with the straps, the straps are weakened to a relatively great extent, since the strut pins protrude relatively deeply and frequently beyond the substantial depth of the strap. This relatively deep mortise stands in contrast to the fact that, in contrast to the multi-pronged connections of the struts to the belts described above, there are often only two relatively narrow tenons in a node point.



   In order to keep the weakening of the straps as small as possible, the pin thicknesses are kept as small as possible. The loss of connection strength of the struts to the straps can be compensated for by a plate-shaped connecting part. The effect of a plate-shaped connecting part is also particularly favorable here if its longitudinal extension is significantly greater than the longitudinal extension of the connecting surface to a belt and here too there is the particular advantage that the narrow slots in the belts for engaging the plate-shaped connecting parts are only comparatively large represent very little weakening of the belt. It is thus understandable that the combination of at least one plate-shaped connecting part with a parallel pin connection of two struts to a belt can be particularly advantageous.



  The slots for engaging the plate-shaped connecting parts in the strut ends can lie outside the strut pins or inside the strut pins or at least partially outside the strut pins. Correspondingly, the slots for engaging the plate-shaped connecting parts in the belts can be located inside the belt pins or outside the belt pins or at least partially outside the belt pins.

 

   If at least two plate-shaped connecting parts made of sheet metal or plastic are used for each connection, it may be advantageous to connect these parts to one another by means of a crosspiece that comes to rest on the outside of the belt. Of course, this also applies to the plate-shaped connecting parts in connection with or without finger jointing.



   The invention is described with reference to exemplary embodiments which are shown schematically in a drawing. Herein shows:
1 shows a longitudinal section through a first embodiment,
2 and 2a cross sections perpendicular to the longitudinal direction of the beam through the embodiment of FIG. 1,
3 and 3a two different belt sections in a perspective view,
4 shows a longitudinal section through a further exemplary embodiment,
5 and 6 a horizontal section and cross section according to FIG. 4 and
Fig. 7 to 13 cross sections transverse to the longitudinal direction of the beam through further embodiments.



   1 shows a wooden support according to the invention with the upper and lower chords 1 and 2 shown broken off, as well as two struts 4 and 5 adjoining the upper chord and two struts 5 and 4 'adjoining the lower chord. The strut ends are provided with relatively short finger prongs 9 which engage in corresponding keyways 10 in the belts. The number of finger joints can be lower, but also higher than the number shown, as described at the beginning. At each node point in the center in the longitudinal direction of the beam there is a relatively thin plate-shaped connecting element 11, which engages like an auxiliary pin in a correspondingly narrow slot 13 in the upper and lower flange and in correspondingly narrow slots 14 and 15 in the strut ends.

  Instead of a connecting element, two or more parallel connecting elements can also be present, which essentially or completely penetrate the belts and which can additionally be combined outside of the belts by U-shaped or T-shaped transverse strips.



   The plate-shaped connecting elements 11 are glued to belts and the struts and, in the example, additionally nailed. Instead of only one plate-shaped connecting element 11, two or more connecting elements running parallel to one another can also be present. The connecting elements can consist of sheet metal, plastic, wood material or plywood. The choice of material also depends on the way and with which gluing means the connecting element is firmly connected to the belt and the struts. Thin plywood panels are particularly cheap for gluing, but do not have the strength of metal sheets.



  Gluing metal sheets or plastic plates to wood does not pose any unsolvable problems. The struts 4, 5 or 5, 4 'are supported on a belt essentially only with the end faces of their finger prongs 9. As a result, the finger prongs of the struts have a maximum engagement length in the associated keyways of the belts 1 and 2.



   Fig. 2 shows a cross section along the lines II-II in Fig. 1. It is clear that the slot 13 for engaging the plate-shaped connecting element 11 penetrates the belt 1 completely. The connecting element 11 can thus also be inserted into the belt from above. FIG. 2a shows a similar cross section through a node point, in which only the slot 13 does not penetrate the belt completely, so that the connecting element 11 can only be inserted into the belt from below.



   Fig. 3 shows a belt section in perspective, in which the splines 10 over the entire
Length of the belt so that the connection points of the
Struts on the belt are advantageously freely selectable.



   3a shows a further belt section in perspective
Representation in which the keyways are only present in the connection areas of the struts. 3 and 3a are
Slots for the connecting elements 11 are not shown.



   4, 5 and 6 show in exemplary embodiments the strut connection to a belt by means of two parallel pins 9 'which engage in corresponding parallel grooves 10' in the belt 1.



  In addition, a continuous slot 13 is present in the belt 1 and there are slots 14 and 15 in the strut ends, which lie outside the pins. A plate-shaped connecting element 11 engages in the slots.



   Fig. 7 shows in cross section an embodiment in which, in addition to the plate-shaped connecting element 11 for further connection reinforcement, two additional connecting elements 11, 11 are provided, each of which engages laterally with a pin 9 'in a slot in the belt and in slots in the struts. In contrast to FIGS. 4 and 6, the connecting elements 11 from FIG. 7 do not protrude through the belts.



  7a shows a variant in which the connecting elements protrude through the straps and outside the straps T or



  Are connected to each other in a U-shape to form a one-piece component. Such a cross connection outside the belts can also be missing.



   Fig. 8 shows in cross section an embodiment in which one connecting element 11 engages in the belt and in the two struts through the two parallel pins. In Fig. 9, the two connecting elements 11 touch the pins 9 on the outside. In Fig. 10, the two connecting elements according to Fig. 8 outside the belt 1 are connected to each other and thereby form a one-piece U-shaped
Bracket, preferably made of metal or plastic. In Fig. 11, the bracket is T-shaped, the cross bar connecting the vertical Ver connecting leg with each other laterally protrudes beyond the leg.



   In Fig. 12, in addition to the end of the connecting elements 11, a further central connecting element 11 is provided, which engages outside the pin in the belt and in the struts. 13 finally shows a strut connection in which two strut ends are attached to the belt without a spigot or galvanization and the connection is preferably made solely by a plurality of parallel plate-shaped connecting elements 11 in the longitudinal direction of the carrier, which engage in slots in the belt and in the two struts. It is clear that more than two connecting elements according to FIG. 10 or 11 can be connected to one another.

  Individual connecting elements, preferably made of sheet metal or plastic, can also be angled L-shaped outside the belt slot in order to increase the connection strength of a connecting element in the belt, as is the case in the exemplary embodiments according to FIGS. 10 or 11. It is clear that these additional means for increasing the connection strength can be used accordingly in a wide variety of exemplary embodiments.

  For the rest, it is clear that the plate-shaped connecting elements with or without a strut joint can also be glued to the straps and the struts and, if necessary, additionally nailed, and that the choice of the gluing agent here also depends on the particular circumstances, with - as described in the introduction Embodiments - above all, the goal is to largely increase the load capacity of a belt with the same belt cross-section, in order to come to lighter and therefore cheaper wooden beams, in which the valuable material wood is used much better than that of the known comparable wooden beams the case is. It is also clear that the exemplary embodiments can be combined in a variety of ways. So instead of a strut train e.g. there are also two parallel struts between the belts.

  One or more connecting elements in the struts of a strut train can also be connected to one another in a T or U shape outside the straps with one or more connecting elements of an adjacent strut train.


    

Claims (12)

 PATENT CLAIMS 1. Timber framework made of wood with one-piece, transverse upper and lower chords 2) and at least one strut train running between them, the strut train being composed of individual struts (4, 5, 4 ') running at an angle to one another, each of which at a node Connect the strut ends of two struts (4, 5; 4, 5 ') to a common inner connection surface of the upper or lower flange (1, 2), characterized in that for connecting two strut ends to the upper or Lower flange (1, 2) at least one plate-shaped connecting part (11) made of sheet metal, plastic or plywood is provided, which is partly in a belt slot (13) running in the longitudinal direction of the beam, and partly in two strut slots (14, 15) which are aligned with one another and extend in the longitudinal direction of the beam ) engages firmly in the strut ends, the connecting part being glued on the one hand to the strut ends and on the other hand to the belt.  2. Truss according to claim 1, characterized in that the longitudinal extent of the connecting part (11) is substantially larger than the longitudinal extent of the connection surface.  3. truss according to claim 1, characterized in that in addition to the connecting part (13) the strut ends and the belt (1, 2) each at a node with parallel pin (9 ') or parallel grooves (10') of the same pitch and the same profile interlock and are glued together, with both the depth of the strut slots (14, 15) and the depth of the belt slot (13) significantly projecting beyond the parallel pins (9 ') (FIGS. 4-9).  4. truss according to claim 1, characterized in that the strut ends and the belt (1; 2) at a node with wedge-shaped prongs (9) or wedge-shaped grooves (10) of the same pitch and the same profile interlock and are glued together. (Fig. 1-3a).  5. Truss girder according to claim 4, characterized in that for the tine length essentially the relationship applies: 7.5 mmz tine length '30 mm.  6. truss according to claim 4, characterized in that the connecting part (11) partially in the parallel with the grooves (10) belt slot (13) and partially in the two with the prongs (9) parallel strut slots (14, 15) in the Strut ends engages firmly, both the depth of the strut slots (14, 15) in the strut ends and the depth of the belt slot (13) in the belt (1; 2) significantly exceeding the tine length and the connecting part (11) on the one hand with the strut ends and on the other hand is glued to the belt (1; 2) (Fig. l-3a).  7. truss according to claim 1 or 4, characterized in that the straps (1, 2) each have un weakened belt sections on both sides of the nodes (Fig. 1, 3a, 4, 5).  8. truss according to claim 4, characterized in that the wedge-shaped grooves (10) of the straps (1, 2) extend over the entire length of the straps (Fig. 3).  9. truss according to claim 3, characterized in that the connecting part (11) in the strut ends outside the parallel pin (9 ') and in the belt outside the parallel grooves (10') (Fig. 4-7a, 12).  10. truss according to claim 3, characterized in that the connecting part (11) in the strut ends within a pin (9 ') and in the belt 2) within a groove (10') (Fig. 8, 10-12).  11. Truss according to claim 3, characterized in that the connecting part (11) in the strut ends at least partially outside a pin (9 ') and in the belt (1; 2) at least partially outside a groove (10') (Fig. 9).  12. truss according to claim 1, characterized in that at least two plate-shaped connecting parts (11) made of metal or plastic outside the belt (1; 2) are connected to each other like a bow (Fig. 7a, 10, 1 1).  The invention relates to a timber truss with one-piece, transverse upper and lower chords and at least one strut train running between them, the strut train being composed of individual struts running at an angle to one another, of which the end faces of two struts meeting at a node meet firmly connect a common inside connection surface of the upper and lower chord.  Trusses of the above type have become known, in which the straps have been weakened relatively strongly by grooves in order to connect the struts to the straps. To compensate for this weakening, it was necessary to make the belts particularly thick-walled, but this led to heavy and expensive carriers.  The object of the invention is to provide a truss of the type mentioned, in which the straps for connecting the struts are subjected to comparatively less weakening than was previously considered necessary to carry a certain load.  This object is achieved according to the invention with the characterizing feature of claim 1. Advantageous embodiments according to the invention result from the subclaims.  Finger joints have been known for a long time, in which two boards or planks or beams engage at their ends with wedge-shaped tines of the same pitch and the same profile and are glued together.  In the known finger joint connections between two wooden parts to be glued together, there is no comparable weakening problem as with the belts of the wooden beams. However, this problem is of particular importance when evaluating a wooden beam with a high load-bearing capacity and minimal belt cross-sections. It was all the more surprising that this problem, which has been open for a long time, can be solved in a particularly simple manner by using the finger joint connections, which have also been known for a long time. It is thus the particular merit of the inventor in the present case to have recognized that only the use of the known finger joint allows the connection of two angularly abutting strut ends to the inside of a belt with a comparatively very slight weakening of the belts.  The tine lengths can be approximately between 7.5 mm and 30 mm, preferably between 7.5 mm and 20 mm. The smaller the tine length, the greater the number of tines across the width of the struts. The number of tines also depends on the flank angle selected. The choice of tine number and flank angle of the tines depends on the required connection strength of the struts to the belts. The straps are less weakened the shorter the tine length and the smaller the tine number. On the other hand, the connection strength increases with increasing glue area between the strut and belt tines. Small belt weakenings therefore require a correspondingly large number of relatively short tines and therefore relatively wide struts for a sufficiently strong strut connection.   Larger belt weakenings with longer tines allow a smaller number of tines and thus relatively narrower ** WARNING ** End of CLMS field could overlap beginning of DESC **.