Method for cutting to length a float glass strip having a normal or structured surface

The invention claimed is: 1. A method for cutting to length a float glass strip having a normal or structured surface, comprising: providing an installation for manufacturing normal float glass or float glass having a structured surface equipped with: a1) a lower cutting carriage ( 4 ) having a lower running rail ( 3 ) below a plurality of conveying rollers ( 2 ) adapted for supporting a glass strip ( 11 ), said lower cutting carriage ( 4 ) for making an undercut in the case of a structured surface, and a2) an upper cutting carriage ( 7 ) having an upper running rail ( 5 ) above the plurality of conveying rollers ( 2 ), said upper cutting carriage ( 7 ) for making an overcut in the case of a normal surface, wherein the lower and upper running rails ( 3 , 5 ) are arranged obliquely at acute inclination angles in relation to the conveying direction of the glass strip ( 11 ) and each of the inclination angles adjustable, b) a number of counterpressure rollers ( 8 ) above the conveying rollers, adapted to oppose a force exerted by the lower cutting carriage ( 4 ) when making an undercut in the class strip ( 11 ), c) a first hold-down unit ( 6 ) having a first fracture roller ( 20 ) and a front hold-down roller ( 21 ) for breaking the class strip( 11 ) along an undercut produced by the lower cutting carriage ( 4 ), d) a second hold-down unit ( 15 ) having a second fracture roller ( 14 ) and a rear hold-down roller ( 18 ) for an overcut produced by the upper cutting carriage ( 7 ), and e) units ( 10 , 11 , 12 ) for measuring the advancing speed of the glass strip ( 11 ) and its current length are provided; and cutting a float glass strip via at least one of the lower cutting carriage ( 4 ) and the upper cutting carriage ( 7 ). 2. The method as claimed in claim 1 , further comprising pressure wheels ( 8 , 18 , 21 ) which come into contact with the structured surface of a glass strip ( 11 ) are inflatable, wherein an air pressure of the pressure wheels is automatically adjusted to the depth of the roughness of the structured surface. 3. The method as claimed in claim 1 , adjusting the inclination angles of the lower or upper running rails ( 3 , 5 ) relative to the advancing speed of the glass strip ( 11 ) in order to produce a cut perpendicular to a running direction of the glass strip. 4. The method as claimed in claim 1 , adjusting the hold-down unit ( 6 ) and/or a fracture roller ( 14 ) and/or the hold-down unit ( 15 ) using position adjustments ( 22 , 19 , 16 ), wherein the adjustments are made using a thickness of the glass strip ( 11 ) and/or a composition of the molten glass and/or the structured surface of the glass strip ( 11 ) as adjustment parameters. 5. The method as claimed in claim 4 , detecting the adjustment parameters in part or collectively via corresponding sensors and by means of set point values, which are based on experience values or calculated values, are used for the automatic fine adjustment of the hold-down unit ( 6 ) and/or the fracture roller ( 14 ) and/or the hold-down unit ( 15 ). 6. The method as claimed in claim 1 , incorporating the float glass panels having structured surfaces into photovoltaic elements. 7. A non-transitory computer program having a program code for carrying out the method steps as claimed in claim 1 in the event that the program is executed in a computer. 8. A machine-readable carrier comprising a non-transitory program code of a computer program for carrying out the method as claimed in claim 1 in the event that the program is executed in a computer.