Method for producing fiber webs and production line for producing fiber webs

We claim: 1. A method for producing a hemicelluloses containing fiber web, comprising the steps of: forming a paper web in a forming section using a wet process; drying the fiber web in a dryer section wherein the fiber web leaves the dryer section with the fiber web in a plastic regime of hemicelluloses; cooling the fiber web in a cooling module by applying liquid to the fiber web with a first cross directional row of liquid nozzles at a first location and drawing air from the fiber web with at least one first cross directional suction opening near the first row of liquid nozzles, followed by blowing gas on to the liquid on the fiber web and evaporating the liquid at a second location spaced from the first location to cool and dry the fiber web, followed by repeating the foregoing steps at least once by applying liquid to the fiber web with a second cross directional row of liquid nozzles at a third location and drawing air from the fiber web with at least one second cross direction opening near the second row of liquid nozzles, followed by blowing gas on to the liquid on the fiber web and evaporating the liquid at a fourth location spaced from the first location to cool and dry the fiber web until the fiber web is cooled to below the plastic regime of hemicelluloses into an elastic regime of the hemicelluloses; and after cooling the fiber web, calendering the fiber web in a hard nip calender with a thermo roll, which has a surface temperature of at least 100° C., such that an outer portion of the fiber web is heated to the plastic regime of hemicelluloses, and an inner portion of the fiber web remains in the elastic regime of the hemicelluloses. 2. The method of claim 1 wherein the step of cooling the fiber web in a cooling module by evaporating the liquid is over a time period of 10-500 ms. 3. The method of claim 1 wherein the liquid is water, and wherein the fiber web has two sides; and wherein the step of cooling the fiber web in a cooling module by cooling the fiber web in a cooling module by applying water to the fiber web with a first cross directional row of water nozzles at a first location and drawing air from the fiber web with openings near the first water nozzles, followed by blowing gas on to the water on the fiber web and evaporating the water at a second location spaced from the first location to cool and dry the fiber web, followed by repeating the foregoing steps at least once by applying water to the fiber web with a second cross directional row of water nozzles at a third location and drawing air from the fiber web with second openings near the second water nozzles, followed by blowing gas on to the water on the fiber web and evaporating the water at a fourth location spaced from the first location to cool and dry the fiber web until the fiber web is cooled to below the plastic regime of hemicelluloses into an elastic regime of the hemicelluloses is applied to both of the two sides of the fiber web. 4. The method of claim 3 wherein the fiber web is a board web, which is cooled by evaporating at least 1-20 g/m 2 water per side of each of the two sides of the board web. 5. The method of claim 3 wherein the fiber web is a board web, which is cooled by evaporating at least 1-25 g/m 2 water per side of each of the two sides of the board web. 6. The method of claim 3 wherein the fiber web is a board web, which is cooled by evaporating at least 5-20 g/m 2 water per side of each of the two sides of the board web. 7. The method of claim 1 wherein the step of cooling the fiber web is by cooling the fiber web in a cooling module and is repeated at least three times, such that liquid and gas are dosed alternately so that the liquid on the surface of the fiber web is dried by the gas dosage before the next liquid dosage and thus preventing the liquid from absorbing into the fiber web while the fiber web is cooled to below the plastic regime of hemicelluloses into the elastic regime of the hemicelluloses. 8. The method of claim 1 wherein temperature of the fiber web is at least 55° C. when the cooling is started. 9. The method of claim 1 wherein moisture content of the fiber web before the cooling by moisturizing evaporating cooling is 5-15% and after addition of moisture and evaporating cooling the moisture content of the fiber web remains in the range of 5-15%. 10. A production line for producing hemicelluloses containing board webs comprising: a head box; a wire section after the head box; a press section after the wire section; a drying section after the press section; a cooling module after the drying section, the cooling module having a first cross direction row of liquid applicators arranged to supply liquid to a board web at a first location in the machine direction and at least one first cross directional suction opening arrayed in the cross direction and connected to a source of suction, the first opening positioned near the first row of liquid applicators and positioned near the board web for drawing gases from the board web though the first openings, the first row of liquid applicators followed by a first row of directional gas nozzles directed at the board web and spaced in a machine direction at a second location from the first row of liquid applicators and arranged to blow gas onto the liquid on the board web and evaporate the liquid, a second cross direction row of liquid applicators arranged to supply liquid to the board web at a third location spaced in the machine direction from the first row of gas nozzles and at least one second opening arrayed in the cross direction and connected to the source of suction, the second opening positioned near the second row of liquid applicators, and positioned near the board web for drawing gases from the board web though the second opening, the second row of liquid applicators followed by a second row of directional gas nozzles directed at the board web and spaced in the machine direction from the second row of liquid applicators and arranged to blow gas onto the liquid supplied by the second row of liquid applicators on the board web and evaporate the liquid; a hard nip calender after the cooling module, the hard nip calender having a thermo roll, which has a surface temperature of at least 100° C.; and a reel-up after the hard nip calender. 11. The production line of claim 10 wherein the liquid applicators are liquid water applicators. 12. The production line of claim 10 wherein the production line further comprises: a coating section after the hard nip calender and before the reel-up, the coating section comprising a first coating unit and a second coating unit; and a final calender after the coating section and before the reel-up. 13. The production line of claim 10 wherein the production line further comprises: a coating section after the hard nip calender and before the reel-up, the coating section comprising a first coating unit, which is a blade coating unit or a curtain coating unit; a second coating unit, which is a curtain unit; and a third coating unit which is a blade coating unit; and a final calender after the coating section and before the reel-up. 14. The production line of claim 10 wherein the cooling module is located at a position where a board web leaving the dryer section will have a temperature of at least 55° C. 15. The production line of claim 10 wherein the cooling module comprises at least three cross directional liquid nozzle rows, at least three sets of openings arrayed in the cross direction and connected to a source of suction and at least three cross directional gas nozzle rows. 16.