Method and system for joining two components of a meltable material

The invention claimed is: 1. A system for joining a first component and a second component of a meltable material, the system comprising: at least one energy source, a pair of separating guides, and a pair of pressure rollers, wherein the system is configured to place the second component relative to the first component on opposed sides of the separating guides so as to form an overlap between a first border region of the first component and a second border region of the second component under a gap between the first border region and the second border region, for heating the first border region and the second border region through the at least one energy source placed in the gap at least partially, for relatively moving the at least one energy source along the first border region and the second border region in the gap, and for pressing already heated sections of the first border region and the second border region onto each other by the pressure rollers, and wherein a first separating guide of the pair of separating guides engages an inner surface of the first component within the gap without engaging the second component and a second separating guide of the pair of separating guides engages an inner surface of the second component within the gap without engaging the first component. 2. The system according to claim 1 , wherein the at least one energy source comprises a single laser and a laser splitter, and wherein the laser splitter is configured to separate a main laser beam emitted by the laser into a first laser beam and a second laser beam for heating the first border region and the second border region. 3. The system according to claim 2 , wherein the laser splitter comprises a prism arrangement. 4. The system according to claim 2 , wherein the laser splitter comprises a partially reflecting mirror. 5. The system according to claim 2 , wherein the laser splitter comprises a wedge shaped mirror, which comprises two wedge surfaces at an angle to each other and wherein the main laser beam is directed onto a common edge of the mirror. 6. The system according to claim 1 , wherein the pair of pressure rollers comprises a first pressure roller positioned to the first component opposite, and a second pressure roller opposite the first pressure roller forming a constriction therebetween, the second roller positioned to engage the second component. 7. The system according to claim 6 , wherein the inner surface of the first component is directly bonded to the inner surface of the second component within the first and second border regions, and wherein the first pressure roller engages an outer surface of the first component and the second pressure roller engages an outer surface of the second component. 8. The system according to claim 1 , wherein the at least one energy source comprises a first laser for emitting a first laser beam, a second laser for emitting a second laser beam and at least one deflecting device, which is arranged in the gap, and wherein the at least one deflecting device is configured to direct the first laser beam onto the first border region and the second laser beam onto the second border region. 9. A system for joining an inner surface a first component and an inner surface of a second component of a meltable material in face-to-face relationship, the system comprising: at least one energy source, a pair of separating guides, and a first pressure roller positioned to engage an outer surface of the first component opposite the inner surface of the first component, a second pressure roller opposite the first pressure roller forming a constriction therebetween, the second roller positioned to engage an outer surface of the second component opposite the inner surface of the second component, and wherein the system is configured to place the second component relative to the first component on opposed sides of the separating guides so as to form an overlap between a first border region of the first component and a second border region of the second component under a gap between the first border region and the second border region, for heating the first border region and the second border region through the at least one energy source placed in the gap at least partially, for relatively moving the at least one energy source along the first border region and the second border region in the gap, and for pressing already heated sections of the first border region and the second border region onto each other by the pressure rollers, wherein the inner surface of the first component is directly bonded to the inner surface of the second component within the first and second border regions, wherein a first separating guide of the pair of separating guides engages an inner surface of the first component within the gap without engaging the second component and a second separating guide of the pair of separating guides engages an inner surface of the second component within the gap without engaging the first component.