Method and arrangement for monitoring characteristics of a furnace process in a furnace space and process monitoring unit

The invention claimed is: 1. A method for monitoring characteristics of a furnace process in a furnace space limited by a furnace shell of a metallurgical furnace comprising: a first providing step for providing a furnace aperture extending through the furnace shell, a second providing step for providing a process monitoring unit comprising a frame, a plurality of linearly movable monitoring devices each configured to move linearly with respect to the frame, wherein each of said plurality of linearly movable monitoring devices is configured to monitor a respective characteristic of said furnace process in the furnace space, a plurality of first moving means each configured to linearly move one linearly movable monitoring device of said plurality of linearly movable monitoring devices with respect to the frame, and second moving means for moving each of said plurality of first moving means between a first position and a second position with respect to the furnace shell, a mounting step for mounting the process monitoring unit on the metallurgical furnace outside the furnace space and on at least one of a furnace roof or a furnace steel structure above the furnace roof of the furnace shell, a first moving step for moving one first moving means of said plurality of first moving means by means of the second moving means with respect to the furnace shell from the first position into the second position, where said one first moving means of said plurality of first moving means is able to move one linearly movable monitoring device of said plurality of linearly movable monitoring devices linearly through the furnace aperture in the furnace shell, a second moving step for moving said one linearly movable monitoring device of said plurality of linearly movable monitoring devices by means of said one first moving means of said plurality of first moving means in said second position vertically through the furnace aperture in the furnace shell at least partly into the furnace space, a monitoring step for monitoring characteristics of the furnace process in the furnace space by means of said one linearly movable monitoring device of said plurality of linearly movable monitoring devices, a third moving step for moving said one linearly movable monitoring device of said plurality of linearly movable monitoring devices by means of said one first moving means of said plurality of first moving means in said second position linearly through the furnace aperture in the furnace shell out of the furnace space, and a fourth moving step for moving said one first moving means of said plurality of first moving means by means of the second moving means with respect to the furnace shell from the second position into a third position, where said one first moving means of said plurality of first moving means is unable to linearly move said one linearly movable monitoring device of said plurality of linearly movable monitoring devices linearly through the furnace aperture in the furnace shell. 2. The method according to claim 1 , further comprising a third providing step for providing a hatch mechanism for closing the furnace aperture, and a first connecting step for functionally connecting the hatch mechanism with the process monitoring unit so that the hatch mechanism is configured to open the furnace aperture when the second moving means of the process monitoring unit moves the first moving means into the second position and so that the hatch mechanism is configured to close the furnace aperture when the second moving means of the process monitoring unit moves the first moving means from the second position. 3. The method according to claim 1 , wherein moving the second moving means between the first position and the second position is by rotating. 4. The method according to claim 1 , wherein said plurality of linearly movable monitoring devices of the process monitoring unit that is provided in the second providing step comprises a linearly movable monitoring device comprising a thermometer or optical pyrometer configured to measure the temperature of the furnace melt in the furnace space, and the monitoring step comprises a temperature measuring step for measuring the temperature of the furnace melt in the furnace space. 5. The method according to claim 1 , wherein said plurality of linearly movable monitoring devices of the process monitoring unit that is provided in the second providing step comprises a linearly movable monitoring device comprising a sampling chamber configured to measure the liquidus temperature of the furnace melt in the furnace space, and the monitoring step comprises a liquidus temperature measuring step for measuring the liquidus temperature of the furnace melt in the furnace space. 6. The method according to claim 1 , wherein said plurality of linearly movable monitoring devices of the process monitoring unit that is provided in the second providing step comprises a linearly movable monitoring device comprising a sounding rod configured to measure the level of the furnace melt in the furnace space, and the monitoring step comprises a melt level measuring step for measuring the level of the furnace melt in the furnace space. 7. The method according to claim 1 , wherein said plurality of linearly movable monitoring devices of the process monitoring unit that is provided in the second providing step comprises a linearly movable monitoring device comprising a camera configured to take pictures inside the furnace space, and the monitoring step comprises a picture taking step for taking pictures inside the furnace space. 8. The method according to claim 1 , wherein said plurality of linearly movable monitoring devices of the process monitoring unit that is provided in the second providing step comprises a linearly movable monitoring device configured to take dust samples from the furnace space, and the monitoring step comprises a dust sampling step for taking dust samples from the furnace space. 9. The method according to claim 1 , wherein said plurality of linearly movable monitoring devices of the process monitoring unit that is provided in the second providing step comprises a linearly movable monitoring device configured to take melt samples from the furnace melt inside the furnace space, and the monitoring step comprises a melt sampling step for taking samples from the furnace melt inside the furnace space. 10. The method according to claim 1 , wherein said plurality of linearly movable monitoring devices of the process monitoring unit that is provided in the second providing step comprises a linearly movable monitoring device configured to take gas samples from the furnace space, and the monitoring step comprises a gas sampling step for taking gas samples from gas inside the furnace space. 11. The method according to claim 1 , wherein the process monitoring unit that is provided in the second providing step comprises a linearly movable injection device configured to inject at least one additive selected from the group consisting of coke, pulverized coal, concentrate mixture, silica, lime, and limestone into the furnace melt inside the furnace space, and an injection step for injecting additives into the furnace melt inside the furnace space. 12. An arrangement for monitoring characteristics of a furnace process in a furnace space limited by a furnace shell of a metallurgical furnace comprising: a process monitoring unit having a frame mounted on the metallurgical furnace outside the furnace space of the furnace shell wherein the process monitoring unit comprises a plurality of linearly movable monitoring devices each configured to move linearly