1. R. Zaera, S. Sánchez-Sáeza, J.L. Pérez-Castellanos, and C. Navarro, “Modelling of the adhesive layer in mixed ceramic/metal armours subjected to impact”, Composites, 31, Part A: Applied Science and Manufacturing (2000): 823-833.
2. National Research Council, Opportunities in Protection Materials Science and Technology for Future Army Applications, (Washington D.C.: The National Academies Press, 2011).
3. G.F. Freeguard, and D. Marshall, “Bullet-resistant glass: A review of product and process
1. Adams R.D., Peppiatt N.A.: Effect of Poisson’s ratio strains in adherends on stresses of an idealized lap joint. Journal of Strain Analysis Vol. 8. No 2 (1974), pp. 134 - 139.
2. Adams R.D., Wake W.C.: Structural Adhesive Joints in Engineering. Elsevier Appl. Sci. Publ. Ltd. 1986
3. Ficarra Ch.H.: Analysis of adhesive bonded fiber-reinforced composite joints. Dissertation, North Carolina State University 2001. Adhesion & Adhesives 29 (2009) 331-341.
4. Fung Y.C.: Foundations of
, École Polytechnique Fédérale de Lausanne, Switzerland 2000.
4. Hamm J.: Development of timber-glass prefabricated structural elements, Innovative Wooden Structures and Bridges IABSE Conference 1, Lahti 2001, pp. 41-46.
5. Cruz P. and Pequeno J.: Timber-Glass Composite Beams: Mechanical Behaviour and Architectural Solutions, Proceedings of the Challenging Glass Conference, Delft 2008, pp. 439-449.
6. Blyberg L. et. al.: Glass, timber and adhesive joints - Innovative load bearing building components, Constr. Build. Mater
. Wydawnictwo Politechniki Poznańskiej, Poznań 2010.
19. Rapp P.: Mechanics of adhesive joints as a plane problem of the theory of elasticity. Part I: General formulation, Archives of Civil and Mechanical Engineering, 10, 2 (2010) 81-108.
20. Rapp P.: Mechanics of adhesive joints as a plane problem of the theory of elasticity. Part II: Displacement formulation for orthotropic adherends. Archives of Civil and Mechanical Engineering, 15, 2 (2015) 603-613.
21. Rapp P.: Stress equations for adhesive in two-dimensional adhesively
In the performance a variety of technological operations a human may come into contact with a variety of factors causing deterioration of safety at work. As an example of which is described in article, adhesive bonding operations are requiring use of specific chemicals, which are adhesives. They are produced on the basis of a variety of compounds, often hazardous to human health. Furthermore, adhesive bonding requires a series of preparatory operations such as degreasing or surface preparation with a specific structure and roughness and auxiliary operations such as measurement of the wettability of surface. In this paper are described examples of risks occurring during adhesive bonding, it is a simple way to estimate the risks associated with the performance of operations. The examples of the determination by the producers of chemicals are described which are used in adhesive bonding and fragment of international chemical safety card (ICSC), as a source of information important to the workplace organization and ensuring safety during adhesive bonding.
 Siemens Mobility GmbH. (2017). Electrified road freight traffic – the eHighway by Siemens. November 08, 2017. Retrieved October 18, 2019, from https://press.siemens.com/global/en/feature/ehighway-solutions-electrified-road-freight-transport .
 The Fraunhofer Institute for Production Technology and Applied Materials Research. Transrapid system, Adhesive bonding technology, Adhesive bonding in transportation construction.
 Buchner, S. (2019). Mercedes-Benz delivers electric eActros heavy-duty truck to Logistik Schmitt for testing
. “Mathematical formulation of the kinematic equations for the control of the robot system with application for the machining conical surfaces.” In: MM Science Journal. MM publishing , 2018, pp. 2158-2161, ISSN 1803-1269.
 G. Gerbert, and F. Sorge. „Full sliding adhesive-like contact of V-belts, Journal of Mechanical Design.” Transactions of the ASME , 124 (4), 2002, pp. 706-712, ISSN 1050-0472.
 K. Kim, H. Kim. „Axial forces of a V-belt CVT.” Theoretical analysis, KSME Journal, 3 (1), 1989, pp. 56-61. ISSN 1738-494X.
 A. Kot, W. Grzegozek, and W
by using additional braces and/or viscoelastic dampers. Earthquake Engineering & Structural Dynamics 40 , 155-174.
4. Kawak, BJ, Cabon, BH and Aglietti, GS 2017. Innovative viscoelastic material selection strategy based on dma and mini-shaker tests for spacecraft applications. Acta Astronautica 131 , 18-27.
5. Martinez-Agirre, M, Illescas, S and Elejabarrieta, MJ 2014. Characterisation and modelling of prestrained viscoelastic films. International Journal of Adhesion and Adhesives 50 , 183-190.
6. De Lima, AMG, Rade, DA, Lacerda, HB and
-resistant syntactic foams through binding hollow glass microspheres with phosphate adhesive. Materials Design, Vol. 95, 2016, pp. 32 - 38.
 RYZHENKOV, A. - LOGINOVA, N. - BELYAEVA, E. - LAPIN, Y. - PRISCHEPOV, A.: Review of binding agents in syntactic foams for heat-insulating structures in power industry facilities. Modern Applied Science, Vol. 9, 2015, pp. 96 - 105.
 GAO, J. - WANG, J. - XU, H. - WU, C.: Preparation and properties of hollow glass bead filled silicone rubber foams with low thermal conductivity. Materials Design, Vol. 46, 2013, pp. 491 - 496