Method for making tissue paper

The invention claimed is: 1. A method of making tissue paper in which a fibrous web (W) is formed in a forming section ( 2 ) and transferred to a Yankee drying cylinder ( 12 ) in a non-dewatering transfer nip (TN) formed between the Yankee drying cylinder ( 12 ) and a shoe roll ( 14 ), the Yankee drying cylinder ( 12 ) having a cylindrical outer surface ( 13 ) and being configured to be rotatable about an axis of rotation (A), the shoe roll ( 14 ) comprising a shoe ( 15 ) that is configured to act against the Yankee drying cylinder ( 12 ), and the shoe roll ( 14 ) further comprising a rotatable flexible jacket ( 16 ) that is configured to run in a loop around the shoe ( 15 ), in which method a carrier fabric ( 10 ) runs in a loop around the shoe roll ( 14 ) and follows the fibrous web (W) into the transfer nip (TN), the carrier fabric ( 10 ) having a structured surface facing the fibrous web (W) such that a three-dimensional pattern can be imprinted into the fibrous web (W) by the carrier fabric ( 10 ) and the structured surface of the carrier fabric ( 10 ) having land areas ( 29 ) and open areas ( 30 ), wherein the method comprises forming the transfer nip (TN) between the shoe ( 15 ) and the cylindrical outer surface ( 13 ) of the Yankee drying cylinder ( 12 ), wherein the length (L) of the transfer nip (TN) in the circumferential direction of the Yankee drying cylinder ( 12 ) is in the range of 30 mm-100 mm, wherein the method further comprises application of a chemical coating on the cylindrical outer surface ( 13 ) of the Yankee drying cylinder ( 12 ) and creping the fibrous web (W) from the cylindrical outer surface ( 13 ) of the Yankee drying cylinder ( 12 ), wherein the land areas ( 29 ) of the structured surface of the carrier fabric ( 10 ) constitute 15%-90% of the total surface area of that side of the carrier fabric ( 10 ) that faces the fibrous web (W), and wherein the linear load in the transfer nip is selected such that the peak pressure in the transfer nip (TN) is in the range of 2 MPa-8MPa when the pressure in the transfer nip (TN) is influenced by a relationship between a force of the linear load in the transfer nip (TN) and a sum of the land areas ( 29 ) of that part of the carrier fabric ( 10 ) that is in the transfer nip (TN) in a given moment. 2. The method according to claim 1 , wherein the peak pressure in the transfer nip (TN) does not exceed the average pressure in the transfer nip (TN) by more than 75%. 3. The method according to claim 1 , wherein the peak pressure in the transfer nip (TN) does not exceed the average pressure in the transfer nip (TN) by more than 60%. 4. The method according to claim 1 , wherein the peak pressure in the transfer nip (TN) does not exceed the average pressure in the transfer nip (TN) by more than 50%. 5. The method according to claim 1 , wherein: the fibrous web (W) is first dried on at least one through-air drying cylinder ( 8 , 9 ) and subsequently transferred to the Yankee drying cylinder ( 12 ), and the linear load in the transfer nip (TN) is in the range of 35 kN/m -45 kN/m. 6. The method according to claim 1 , wherein: the Yankee drying cylinder ( 12 ) is the first drying cylinder on which the fibrous web (W) is dried, and the linear load in the transfer nip (TN) is in the range of 65 kN/m -95 kN/m. 7. The method according to claim 1 , wherein: the Yankee drying cylinder ( 12 ) is the first drying cylinder on which the fibrous web (W) is dried, and the linear load in the transfer nip (TN) is in the range of 70 kN/m -90 kN/m. 8. The method according to claim 1 , wherein: the pressure in the transfer nip (TN) is so distributed that the pressure follows a pressure curve from an entry point ( 21 ) of the transfer nip to an exit point ( 22 ) of the transfer nip, and the pressure curve has a saddle point ( 23 ) located between two points ( 24 , 25 ) where the pressure is higher than in the saddle point ( 23 ). 9. The method according to claim 1 , wherein the tissue paper has a basis weight in the range of 12 g/m 2 -30 g/m 2 when it leaves the Yankee drying cylinder ( 12 ). 10. The method according to claim 1 , wherein the shoe ( 15 ) of the shoe roll ( 14 ) is a deformable shoe ( 15 ) that can adapt to the shape of the cylindrical outer surface ( 13 ) of the Yankee drying cylinder ( 12 ).