Perforated plug for a control valve

The invention claimed is: 1. A method for manufacturing ( 440 ) a perforated plug ( 150 ; 200 ; 300 ) for a control valve ( 100 ), the control valve ( 100 ) being capable of controlling the flow of a fluid, wherein the perforated plug ( 150 ; 200 ; 300 ) is cup-shaped and has a lateral wall forming a plurality of openings ( 170 ; 220 ) through which the fluid is able to flow; wherein the plurality of openings ( 170 ; 220 ) are arranged on at least one helical line on the lateral wall of the perforated plug ( 150 ; 200 ; 300 ); wherein each opening ( 170 ; 220 ) of the plurality of openings ( 170 ; 220 ) on the lateral wall through which the fluid is able to flow has substantially the same shape; wherein the plurality of openings ( 170 ; 220 ) and the at least one helical line are arranged such that a ratio between a maximum web width and a minimum web width between adjacent openings of the plurality of openings ( 170 ; 220 ) is greater than or equal to 1 and less than or equal to 1.5; wherein an arrangement of the plurality of openings ( 170 ; 220 ) and the at least one helical line is chosen to minimize a number of helical lines; and wherein the following boundary conditions are given: a predefined inner diameter of the perforated plug ( 150 ; 200 ; 300 ); a predefined diameter of each of the plurality of openings ( 170 ; 220 ); and a predefined minimum web width between the adjacent openings ( 170 ; 220 ), the method comprising: determining at least one opening ( 170 ; 220 ) of the perforated plug ( 150 ; 200 ; 300 ) that is to be omitted during the manufacture ( 440 ) such that the perforated plug ( 150 ; 200 ; 300 ) exhibits an equal percentage course of a flow characteristic of the control valve ( 100 ); and manufacturing ( 440 ) the perforated plug ( 150 ; 200 ; 300 ) with the determined plurality of openings ( 170 ; 220 ) on the at least one helical line. 2. The method according to claim 1 , wherein the equal percentage course of the flow characteristic of the control valve ( 100 ) is produced by: determining a maximum number of openings that can be arranged on the at least one helical line on the lateral wall of the perforated plug ( 150 ; 200 ; 300 ) according to claim 1 ; determining a required number of openings to obtain a total area of the openings for the flow of the fluid; and determining a difference between the maximum number of openings and the required number of openings to determine the number of openings ( 170 ; 220 ) of the perforated plug ( 150 ; 200 ; 300 ) that are to be omitted. 3. The method according to claim 1 , wherein the plurality of openings ( 170 ; 220 ) are arranged on at least two helical lines. 4. The method according to claim 1 , wherein the plurality of openings ( 170 ; 220 ) are arranged on at most 20 helical lines. 5. The method according to claim 1 , wherein the plurality of openings ( 170 ; 220 ) are uniformly arranged along one helical line. 6. The method according to claim 5 , wherein the plurality of openings ( 170 ; 220 ) are arranged equidistantly along one helical line. 7. The method according to claim 1 , wherein each of the plurality of openings ( 170 ; 220 ) has one of the following cross-sectional shapes: circular; square; rectangular; hexagonal; or star. 8. The method according to claim 1 , wherein the number of helical lines is determined using an iterative method ( 500 ) comprising the following steps: step (i): the plurality of openings ( 220 ) are first distributed on N=2 helical lines with a minimum height h=πD tan(α), step (ii): where sin(α)=N cos(30°)(d+s)/(πD), D is the predefined inner diameter of the perforated plug ( 150 ; 200 ; 300 ), d is the predefined diameter of each of the plurality of openings ( 220 ) and s is the predefined minimum web width between the adjacent openings ( 220 ); step (iii): the number of openings ( 220 ) on each helical line is first given by an integer value of a ratio: πD/(d+s); and step (iv): then incrementally increasing the number of openings ( 220 ); step (v): until an orthogonal projection of a position of a first opening of the plurality of openings on a first helical line of the at least one helical line onto a nearest helical line falls into an intermediate region of adjacent openings ( 220 ), wherein the intermediate region is defined as a distance of the orthogonal projection to the adjacent openings ( 220 ) of at least 30% of the distance between the adjacent openings ( 220 ); step (vi): increasing the number of helical lines N if the web widths do not comply with the predefined minimum web width or a maximum ratio of two web widths between adjacent openings is greater than 1.5; and step (vii): repeating steps (iii) to (vi) until the web widths comply with the predefined minimum web width and the maximum ratio is greater than or equal to 1 and less than or equal to 1.5. 9. The method according to claim 8 , wherein the number of openings ( 170 ; 220 ) to be omitted on the helical lines around the lateral wall of the perforated plug ( 150 ; 200 ; 300 ) are determined by means of a loop-like method ( 600 ); wherein a maximum possible number of openings ( 170 ; 220 ) around the perforated plug ( 150 ; 200 ; 300 ) is determined according to claim 8 ; wherein a total number of openings ( 170 ; 220 ) to be omitted is determined; wherein the number of openings ( 170 ; 220 ) is determined that is necessary to obtain a predefined maximum total area of the openings ( 170 ; 220 ); and wherein the number of openings ( 170 ; 220 ) that is necessary to obtain a predefined maximum total area of the openings ( 170 ; 220 ) is subtracted from the maximum possible number of openings ( 170 ; 220 ) around the perforated plug ( 150 ; 200 ; 300 ) that is determined according to claim 8 to obtain a difference r; wherein the difference r is used to determine the number of openings ( 170 ; 220 ) to be omitted on each helical line in a loop starting at the Nth helical line and ending at the first helical line, where the value N is assigned to a counting variable i in the first step and the integer value of the ratio 3r/(2i−2) is determined and additionally reduced by 1, and r is subsequently lowered by this value, and the procedure is repeated for a next helical line, such that the number of openings ( 170 ; 220 ) to be omitted does not increase and does not become greater than r. 10. The method according to claim 1 , wherein a maximum total area of the plurality of openings ( 170 ; 220 ) is predefined as a boundary condition. 11. A perforated plug ( 150 ; 200 ; 300 ) for a control valve ( 100 ) obtained by the method according to claim 1 . 12. A perforated plug ( 150 ; 200 ; 300 ) for a control valve ( 100 ), the control valve ( 100 ) being capable of controlling the flow of a fluid, wherein the perforated plug ( 150 ; 200 ; 300 ) is cup-shaped and has a lateral wall forming a plurality of openings ( 170 ; 220 ) through which the fluid is able to flow; wherein each opening ( 170 ; 220 ) of the plurality of openings ( 170 ; 220 ) on the lateral wall through which the fluid is able to flow has substantially the same shape; wherein the plurality of openings ( 170 ; 220 ) are arranged on at least one helical line on the lateral wall of the perforated plug ( 150 ; 200 ; 300 ); wherein the plurality of openings ( 170 ; 220 ) and the at least one helical line are arranged such that a ratio between a maximum web width and a minimum web width between adjacent openings of the plurality of openings ( 170 ; 220 ) is greater than or equal to 1 and less than or equal to 1.5; wherein the perforated plug ( 150 ;