Method and an arrangement for automatic elevator installation

The invention claimed is: 1. An arrangement for automatic elevator installation, comprising: downwards facing door reflectors, each door opening in an elevator shaft being marked with the downwards facing door reflectors positioned at opposite sides of the door opening; a robotic total station positioned at a bottom of the elevator shaft, whereby a reference coordinate system of the elevator shaft is created with the robotic total station, the position of the door reflectors in relation to the elevator shaft being measured with the robotic total station such that measurements thereof are provided; and straight door lines fitted to the measurements, said straight door lines forming virtual plumb lines for doors in the elevator shaft; wherein predetermined positions of the guide rails on the bottom of the elevator shaft are marked based on dimensions of the elevator shaft and an elevator car, wherein lowermost guide rails are installed manually to the elevator shaft based on the predetermined positions of the guide rails, wherein vertical guide rail lines are formed with the robotic total station based on the door lines, said vertical guide rail lines forming virtual plumb lines for the guide rails in the elevator shaft, wherein an upwards and downwards movable installation platform is provided in the elevator shaft, wherein downwards facing platform reflectors are positioned on a bottom of the installation platform, and wherein a position of the platform reflectors is measured in relation to the elevator shaft with the robotic total station, whereby an orientation and the position of the installation platform in relation to the elevator shaft is determined. 2. A method for automatic elevator installation, said method comprising the step of using the arrangement according to claim 1 . 3. A method for automatic elevator installation, comprising the steps of: marking each door opening in an elevator shaft with downwards facing door reflectors positioned at opposite sides of the door opening; positioning a robotic total station at a bottom of the elevator shaft and creating a reference coordinate system of the elevator shaft with the robotic total station; measuring the position of the door reflectors in relation to the elevator shaft with the robotic total station and providing measurements thereof; fitting straight door lines to the measurements, said straight door lines forming virtual plumb lines for doors in the elevator shaft; marking predetermined positions of guide rails on the bottom of the elevator shaft based on dimensions of the elevator shaft and an elevator car; installing a lowermost of the guide rails manually to the elevator shaft based on the predetermined positions of the guide rail; forming vertical guide rail lines with the robotic total station based on the door lines, said vertical guide rail lines forming virtual plumb lines for the guide rails in the elevator shaft; providing an upwards and downwards movable installation platform in the elevator shaft; positioning downwards facing platform reflectors on a bottom of the installation platform; and measuring a position of the platform reflectors in relation to the elevator shaft with the robotic total station, whereby an orientation and the position of the installation platform in relation to the elevator shaft is determined. 4. The method according to claim 3 , further comprising the step of providing support arms on opposite sides of the installation platform, said support arms being movable outwardly from the installation platform in order to support the installation platform on opposite side walls of the elevator shaft. 5. The method according to claim 4 , further comprising the step of providing an apparatus for aligning guide rails on the installation platform, said apparatus comprising: a positioning unit extending horizontally across the elevator shaft in a second direction and comprising a first attachment mechanism movable in the second direction at each end of the positioning unit for supporting the positioning unit on opposite wall structures of the elevator shaft; and an alignment unit extending across the elevator shaft in the second direction and being supported with support parts on each end portion of the positioning unit so that each end portion of the alignment unit is individually movable in relation to the positioning unit in a third direction perpendicular to the second direction, and comprising a second attachment mechanism movable in the second direction at each end of the alignment unit for supporting the alignment unit on opposite guide rails in the elevator shaft, said second attachment mechanism comprising grippers configured to grip on the guide rail. 6. The method according to claim 4 , further comprising the step of providing downwards facing top reflectors at a top of the elevator shaft, whereby the measurements of the robotic total station are corrected based on movement of the top reflectors corresponding to bending of the elevator shaft caused by wind during the measurements. 7. The method according to claim 4 , further comprising the step of aligning guide rails by an apparatus for aligning guide rails positioned on the installation platform. 8. The method according to claim 3 , further comprising the step of providing an apparatus for aligning guide rails on the installation platform, said apparatus comprising: a positioning unit extending horizontally across the elevator shaft in a second direction and comprising a first attachment mechanism movable in the second direction at each end of the positioning unit for supporting the positioning unit on opposite wall structures of the elevator shaft; and an alignment unit extending across the elevator shaft in the second direction and being supported with support parts on each end portion of the positioning unit so that each end portion of the alignment unit is individually movable in relation to the positioning unit in a third direction perpendicular to the second direction, and comprising a second attachment mechanism movable in the second direction at each end of the alignment unit for supporting the alignment unit on opposite guide rails in the elevator shaft, said second attachment mechanism comprising grippers configured to grip on the guide rail. 9. The method according to claim 8 , further comprising the step of providing downwards facing top reflectors at a top of the elevator shaft, whereby the measurements of the robotic total station are corrected based on movement of the top reflectors corresponding to bending of the elevator shaft caused by wind during the measurements. 10. The method according to claim 8 , further comprising the step of aligning guide rails by an apparatus for aligning guide rails positioned on the installation platform. 11. The method according to claim 3 , further comprising the step of providing downwards facing top reflectors at a top of the elevator shaft, whereby the measurements of the robotic total station are corrected based on movement of the top reflectors corresponding to bending of the elevator shaft caused by wind during the measurements. 12. The method according to claim 11 , further comprising the step of aligning guide rails by an apparatus for aligning guide rails positioned on the installation platform. 13. The method according to claim 3 , further comprising the step of aligning guide rails by an apparatus for aligning guide rails positioned on the installation platform. 14. The method according to claim 13 , further comprising the step of arranging a control unit for controlling the apparatus for aligning guide rails.