Heat transfer tube and method for manufacturing a heat transfer tube

The invention claimed is: 1. A heat transfer tube for falling film evaporation of spent liquor, the heat transfer tube comprising: a heating medium surface configured to be heated by a heating medium; and a falling film surface opposite and facing away from said heating medium surface, which falling film surface is configured to have spent liquor containing lignin and other dissolved components from cellulosic material and/or inorganics from the cellulosic material and chemicals used passing over it as a falling film while evaporating solvent from the falling film and thus increasing the dry matter content; said heat transfer tube being made from a sheet metal material, wherein the falling film surface of the heat transfer tube is equipped with a multitude of wire bumps, each wire bump being spaced apart along the longitudinal axis of the heat transfer tube from a neighbouring wire bump by 3-300 mm; said wire bumps having a height in the range 0.3-5.0 mm; said wire bumps having a width in the range 0.3-5.0 mm; and said wire bumps having an inclination angle versus a plane orthogonal to a longitudinal axis of the heat transfer tube in a range of 0-70 degrees. 2. A heat transfer tube according to claim 1 wherein said wire bumps are formed by a multitude of wire portions located on the falling film surface, each wire portion having an extension on the falling film surface such that its projection onto a plane orthogonal to the longitudinal axis corresponds to at least a portion of a circle. 3. A heat transfer tube according to claim 1 wherein said wire bumps are welded onto the falling film surface by means of electric resistance welding. 4. A heat transfer tube according to claim 1 , wherein a distance along the longitudinal axis between adjacent wire bumps is in the range 3-50 mm. 5. A heat transfer tube according to claim 4 wherein a distance along the longitudinal axis between adjacent wire bumps is in the range 5-20 mm. 6. A heat transfer tube according to claim 1 , wherein the height of said wire bumps is in the range 0.5 to 2.0 mm. 7. A heat transfer tube according to claim 6 wherein the height of said wire bumps is in the range 0.7-1.7 mm. 8. A heat transfer tube according to claim 1 , wherein at least one wire bump is inclined in relation to said orthogonal plane. 9. A heat transfer tube according to claim 1 , wherein at least one wire bump extends within a plane orthogonal to the longitudinal axis of the heat transfer tube. 10. A heat transfer tube according to claim 1 , wherein at least one wire bump is applied on the heating medium surface of the heat transfer tube. 11. A heat transfer tube according to claim 1 wherein the sheet metal material comprises an iron based high alloy stainless steel material with an alloy content above 16.00% for Chromium and above 1% for Nickel. 12. A heat transfer tube according to claim 1 wherein the sheet metal material comprises AISI 316 or AISI 304 steel. 13. Method for manufacturing a heat transfer tube for falling film evaporation of spent liquor, which method comprises the step of assembling the heat transfer tube comprising: a heating medium surface arranged to be heated by a heating medium; a falling film surface opposite and facing away from said heating medium surface, which falling film surface is arranged to have spent liquor containing lignin and other dissolved components from cellulosic material and/or inorganics from the cellulosic material and chemicals used passing over it as a falling film while evaporating solvent from the falling film and thus increasing the dry matter content, said heat transfer tube being made from an iron based high alloy stainless steel material with an alloy content above 16.00% for Chromium and above 1% for Nickel, wherein the method comprises the step of applying a multitude of wire bumps to the falling film surface of the heat transfer tube and each wire bump being spaced apart along the longitudinal axis of the heat transfer tube from a neighbouring wire bump by 3 to 300 mm, said wire bumps having a height in the range 0.3 to 5.0 mm, said wire bumps having a width in the range 0.3 to 5.0 mm, and said wire bumps having an inclination angle versus a plane orthogonal to a longitudinal axis of the heat transfer tube in a range of 0-70 degrees. 14. Method for manufacturing a heat transfer tube according to claim 13 , which method comprises the step of applying the wire bumps on the falling film surface of the heat transfer tube while forming a planar steel strip into said heat transfer tube. 15. Method for manufacturing a heat transfer tube according to claim 14 which method comprises the step of applying the wires used to form the wire bumps by the use of a rolled up net provided with the wire portions and said net adapted to be rolled out and laid down on sheet metal material used to shape the heat transfer tube. 16. Method for manufacturing a heat transfer tube according to claim 13 , which method comprises the step of applying the wire bumps on the falling film surface of a planar steel strip before form shaping the strip to a tubular form and welding the edges of the steel strip together with a butt fusion weld. 17. Method for manufacturing a heat transfer tube according to claim 13 , which method comprises the step of applying the wire bumps on the falling film surface of an assembled heat transfer tube. 18. Method for manufacturing a heat transfer tube according to claim 13 , which method comprises attaching wires to an envelope surface of the heat transfer tube by electric resistance welding. 19. Method for manufacturing a heat transfer tube according to claim 13 , said heat transfer tube being made from AISI 316 or AISI 304 steel.