Nozzle element for introducing a liquid into a joint, and method for introducing a liquid into a joint

The invention claimed is: 1. A nozzle element for introducing a liquid into a joint, the nozzle element comprising: an outlet opening; at least one cover element curved outward and enclosing the outlet opening at least in sections, such that regions of a joint and/or joint edges adjacent to the outlet opening will be covered during introduction of liquid by the nozzle element; wherein the cover element contacts an inner surface of a side wall of the nozzle element; and wherein a first material of the cover element is arranged inside the cover element and a second material of the cover element is arranged on an outer surface of the cover element, the second material being different from the first material. 2. The nozzle element as claimed in claim 1 , wherein the cover element is configured as, or includes, a resilient element. 3. The nozzle element as claimed in claim 1 , wherein the at least one cover element protrudes from other components of the nozzle element. 4. The nozzle element as claimed in claim 1 , in combination with a housing, at least one cover element projecting from an end associated with the outlet opening. 5. The nozzle element as claimed in claim 1 , wherein the cover element is formed at least in sections from the first material, and the first material has an E modulus ≦30 MPa; and/or at least sections are formed from the second material, and the second material has an E modulus greater by at least 1.5 times than the E modulus of the first material. 6. The nozzle element as claimed in claim 1 , wherein the first material is a foam material, and/or the second material is a polymer. 7. The nozzle element as claimed in claim 1 , wherein a material forming a surface of the cover element has, at least in sections, a Shore D hardness ≧50, and/or has a friction coefficient ≦0.4. 8. The nozzle element as claimed in claim 1 , wherein the cover element is convexly configured; and/or the cover element is circular; and/or a cross section of the housing and/or of a liquid reception chamber is circular. 9. A system comprising: a nozzle element as claimed in claim 1 and a joint, wherein a surface of the cover element has a higher hardness than a surface of joint edges and/or has a lower friction coefficient. 10. The system as claimed in claim 9 , wherein a maximum diameter of the outlet opening is less than a maximum width of the joint; and/or a maximum diameter of the cover element is greater than a maximum width of the joint. 11. The nozzle element as claimed in claim 1 , in combination with a rigid housing, at least one cover element projecting from an end associated with the outlet opening. 12. The nozzle element as claimed in claim 1 , wherein the cover element is formed at least in sections from the first material, and the first material has an E modulus ≦5 MPa; and/or at least sections are formed from the second material, and the second material has an E modulus greater by at least 3 times than the E modulus of the first material. 13. The nozzle element as claimed in claim 1 , wherein the cover element is formed at least in sections from the first material, and the first material has an E modulus ≦1 MPa; and/or at least sections are formed from the second material, and the second material has an E modulus greater by at least 10 times than the E modulus of the first material. 14. The nozzle element as claimed in claim 1 , wherein the first material is a foam material, and/or the second material is a polymer with a high molecular weight. 15. The nozzle element as claimed in claim 1 , wherein a material forming a surface of the cover element has, at least in sections, a Shore D hardness ≧80, and/or has a friction coefficient of ≦0.3. 16. The nozzle element as claimed in claim 1 , wherein a material forming a surface of the cover element has, at least in sections, a Shore D hardness ≧90, and/or has a friction coefficient of ≦0.2. 17. The nozzle element as claimed in claim 1 , wherein a material forming a surface of the cover element has, at least in sections, a Shore D hardness ≧90, and/or has a friction coefficient of ≦0.1. 18. The nozzle element as claimed in claim 1 , configured to introduce an adhesive and/or sealant as the liquid. 19. The nozzle element as claimed in claim 1 , wherein the cover element is formed at least in sections from the first material, and the first material has an E modulus ≦30 MPa; and/or at least sections are formed from the second material, and the second material has an E modulus ≧100 MPa. 20. The nozzle element as claimed in claim 1 , wherein the cover element is formed at least in sections from the first material, and the first material has an E modulus ≦5 MPa; and/or at least sections are formed from the second material, and the second material has an E modulus ≧1000 MPa. 21. The nozzle element as claimed in claim 1 , wherein the cover element is formed at least in sections from the first material, and the first material has an E modulus ≦1 MPa; and/or at least sections are formed from the second material, and the second material has an E modulus ≧10,000 MPa. 22. A method for introducing a liquid into a joint, comprising: introducing an adhesive and/or sealant, into a joint via an outlet opening of a nozzle element; and enclosing, via at least one cover element curved outward, the outlet opening at least in sections, such that regions of the joint and/or joint edges adjacent to the outlet opening will be covered during introduction of liquid by the nozzle element; wherein the at least one cover element contacts an inner surface of a side wall of the nozzle element; and wherein a first material of the at least one cover element is arranged inside the at least one cover element and a second material of the at least one cover element is arranged on an outer surface of the at least one cover element, the second material being different from the first material. 23. A method for introducing a liquid, as an adhesive and/or sealant, via a nozzle element, into a joint, the method comprising: ejecting the liquid through an outlet opening of the nozzle element, in the direction of the joint, via at least one cover element curved outward, wherein the at least one cover element contacts an inner surface of a side wall of the nozzle element, and wherein a first material of the at least one cover element is arranged inside the at least one cover element and a second material of the at least one cover element is arranged on an outer surface of the at least one cover element, the second material being different from the first material; and at least partially covering regions of the joint and/or joint edges adjacent to the outlet opening.