DEFLECTIONS OF REINFORCED AND NON-REINFORCED BEAMS OF RECTANGULAR SECTION OF GLUED WOOD
DOI:
https://doi.org/10.31650/2707-3068-2022-26-88-96Abstract
The dynamic development and distribution of glued timber structures in
construction predetermine their comprehensive study. The issue of increasing the load capacity of
such structures using reinforcement is also relevant. The reinforcing of timber elements using steel
reinforcement is more researched, but recent studies have shown good use of synthetic fiber-based
composites as reinforcement for timber structures. Our purpose was to combine these two types of
reinforcement and to investigate the stiffness change of the specimens in the form of glued timber
beams. Several series of beams with cross-sectional dimensions of 100x150 mm and 3000 mm length
were prepared for the research. The first series consisted of two glued unreinforced beams. They were
tested to determine the fracture load, to establish control deflections and to compare them with the
corresponding deflections of reinforced beams. The second series consisted of two glued timber
beams, which were reinforced with two 12 mm diameter steel rods in the compressed zone and with
Sika Carbo Dur S-512 carbon fiber tape reinforcement in the stretched zone. The third series included
two beams, which were reinforced with 16 mm diameter steel reinforcement in the compressed zone
and the Sika Carbo Dur S-512 carbon fiber tape reinforcement in the stretched zone. The fourth series
included one beam, which was reinforced with only steel reinforcement in the shape of two 12 mm
diameter rods in the compressed zone. The test specimens were loaded using a jack by two
concentrated loads. The deflections of all beams were measured using the deflection indicators. As a
result of experimental studies, comparative graphs of the variation of deflections versus bending
moment were constructed. The specimens of the second series with reinforcement of 12 mm diameter
in the compressed zone were the most rigid. The ultimate deflection for them was achieved at load,
which is 61% more than the average value for unreinforced samples. The ultimate deflection value
for the third series of beams was achieved at loading, on average, 39% higher than for unreinforced
beams. However, it should be noted that the carrying capacity of these samples was the highest. The
reinforcing of the beam of the fourth series did not increase the rigidity, since the ultimate deflection
was achieved at the same load values, as for the unreinforced glued timber samples.




