System for and method of heating objects in a production line

The invention claimed is: 1. A system for heating objects (O) during a thermal treatment process in a production line (P) comprising: a transport system for transporting the objects (O) in a transport direction (OT) along the production line (P), a mirror arrangement comprising a first mirror surface and a second mirror surface arranged at opposite sides along at least a section of the production line (P), so that the objects (O) may be transported between the mirror surfaces along the production line (P), a radiation device comprising a number of lasers for generating light (L), wherein the radiation device and the mirror arrangement are constructed such that the main direction (R) of light (L) that enters the mirror arrangement is directed towards the first mirror surface at an angle to the production line (P), wherein the radiation device and the mirror arrangement are constructed such that the light (L) subsequently undergoes multiple reflections between the mirror surfaces so that a series of multiple reflections of the light (L) travels in the transport direction (OT) along at least a section of the mirror surface and also travels against the transport direction (OT) along at least a section of the mirror surface; thereby heating the objects (O) being transported between the mirror surfaces. 2. A system according to claim 1 , wherein the objects (O) being transported are at least partially transparent to the generated light (L), and the light (L) is partially absorbed by a plurality of the objects (O) between the mirror surfaces while the objects (O) are transported through the mirror arrangement. 3. A system according to claim 1 , wherein the mirror arrangement is arranged such that the multiple reflections of the light result in a predefined intensity profile of the light (L) in a direction (LT) of travel of the light downstream from a point of entry (PE) of the light (L) into the mirror arrangement. 4. A system according to claim 1 , wherein the mirror arrangement is arranged such that the distances (D) between points of incidence (PI 1 , PI 2 ) of a ray of light (L) on an individual mirror surface of the mirror arrangement decrease in a direction of travel (LT) of the light downstream from a point of entry (PE) of the light (L) into the mirror arrangement. 5. A system according to claim 1 , wherein the mirror arrangement is arranged such that the first mirror surface and the second mirror surface approach one another over at least a section of the mirror arrangement along a direction of travel (LT) of the light downstream from a point of entry (PE) of the light (L) into the mirror arrangement. 6. A system according to claim 5 , wherein the first mirror surface and the second mirror surface are planar along the direction of transport (OT) and are positioned at an angle to one another. 7. A system according to claim 5 , wherein at least one of the mirror surfaces is curved so that at least a section of the mirror surface downstream from a point of entry (PE) of the light is curved inwards towards the objects (O) traveling on the production line (P). 8. A system according to claim 1 , wherein the mirror arrangement is constructed such that the light (L) entering the mirror arrangement first travels in a first direction of travel (LT) of the light downstream from a point of entry (PE) of the light, and the direction of travel (LT) of the light is reversed after a certain distance in the mirror arrangement downstream from the point of entry (PE) of the light. 9. A system according to claim 8 , wherein the mirror arrangement comprises a mirror surface region that is arranged to reflect the light (L) essentially in the opposite direction. 10. A system according to claim 1 , wherein the first mirror surface and/or the second mirror surface are curved laterally with respect to the direction of transport (OT). 11. A system according to claim 1 , wherein the mirror arrangement comprises a plurality of stages along the production line, wherein each stage comprises a first mirror surface and an opposite second mirror surface along a section of the production line (P); and, wherein for each of a plurality of the stages, a light entry opening of the mirror arrangement enables the light (L) to enter. 12. A system according to claim 1 , wherein the light (L) of at least a group of the lasers of the radiation device is focused to direct the light (L) into the mirror arrangement such that the light is focused in or near a light entry opening of the mirror arrangement. 13. A system according to claim 1 , wherein the radiation device comprises a plurality of Vertical-Cavity Surface-Emitting Lasers. 14. A system according to claim 12 , wherein the light entry opening has a length; wherein the radiation device comprises a lens arranged such that beams of light from the lasers are made parallel and formed into a strip of light approximately of the same length as the length of the light entry opening. 15. A system according to claim 14 , wherein each of the objects rests upon a top surface of the production line and each has approximately the same height above the top surface; wherein the length of the light entry opening is approximately equal to the height. 16. A method for heating objects (O) during a thermal treatment process in a production line (P) wherein the objects (O) are transported in a transport direction (OT) along the production line (P) between a first mirror surface and a second mirror surface of a mirror arrangement, which first mirror surface and second mirror surface are arranged at opposite sides along at least a section of the production line, wherein light is generated by a number of lasers of a radiation device, wherein the generated light (L) is directed into the mirror arrangement such that the main direction (R) of light (L) that enters the mirror arrangement is directed towards the first mirror surface at an angle to the production line (P), and the mirror arrangement is constructed such that the light (L) subsequently undergoes multiple reflections between the mirror surfaces so that a series of multiple reflections of the light (L) travels in the transport direction (OT) along at least a section of the mirror surface or travels against the transport direction (OT) along at least a section of the mirror surface and heats the objects (O) being transported between the mirror surfaces.