Process for continuous production of stable silicone emulsions

What is claimed is: 1. A continuous process for production of emulsions which comprise polyorganosiloxanes (A), emulsifiers (B), water (C) and optionally further components (D), wherein the process comprises: continuously feeding components (A) through (D) into a cylindrical mixer comprising two or more rotor-stator mixing elements providing axial flow therethrough, wherein the rotor and stator elements are each arranged with an axial offset, and the cylindrical mixer contains at least one feedpoint upstream from the mixing elements of the cylindrical mixer and at least one further feedpoint along the mixer between mixing elements, supplying the polyorganosiloxanes (A) via a feedpoint at the entry to the mixer, optionally in the form of a premix with a portion of one or more of emulsifiers (B), water (C), further components (D) and mixtures thereof, and supplying emulsifiers (B) and water (C), optionally portions of polyorganosiloxanes (A), and optionally further components (D), separately or as a premix at one or more feedpoints upstream from the mixing elements and/or at one or more feedpoints between the mixing elements, wherein the admixture of the total amounts of components (A) to (D) is in each case effected independently of one another via one feedpoint or across two or more feedpoints, where the central particle size D(50) of the emulsions is greater than 1 μm, and controlling the central particle size D(50) of the emulsions by splitting the proportions of components (A) to (D), which are imported at the further feedpoints between the mixing elements along the mixer, and continuously withdrawing a product emulsion from the cylindrical mixer, where the central particle size relates to the D(50) value of the volume distribution as measured by the principle of Fraunhofer diffraction corresponding to ISO 13320 and the parameters for measurement assume a spherical model having a refractive index of 1.33 for the continuous phase, of 1.39 for the disperse phase, and an absorption of 0.01. 2. The continuous process of claim 1 , wherein the central particle size D (50) is controlled by importing one or more components (B) and (C) at the further feed points. 3. The continuous process of claim 1 , wherein the central particle size D (50) is controlled by importing one or more components (C) at the further feed points. 4. The continuous process of claim 1 , wherein the polyorganosiloxanes (A) are fed at the point of entry to the mixer and the admixture of the total amount of emulsifiers (B) and water (C) is effected, independently of each other, separately or as a premix, at a feedpoint upstream of the mixing elements of the mixer or divided across a feedpoint upstream and further feedpoints between the mixing elements of the mixer. 5. The continuous process of claim 1 , wherein the polyorganosiloxanes (A) are supplied at the point of entry to the mixer, emulsifiers (B) are admixed at a feedpoint upstream of the mixing elements and the admixture of the total amount of water is effected at a feedpoint upstream of the mixing elements or divided across the further feedpoints between the mixing elements. 6. The continuous process of claim 1 , wherein emulsifiers (B) and water (C) are admixed as a premix at a feedpoint upstream of the mixing elements. 7. The continuous process of claim 6 , wherein further water (C) is mixed at one or more further feedpoints between the mixing elements. 8. The continuous process of claim 1 , wherein the mixer contains 3 to 60 rotor-stator mixing elements. 9. The continuous process of claim 1 , wherein the mixer contains 5 to 40 rotor-stator mixing elements. 10. The continuous process of claim 1 , wherein the mixer has 1 to 10 further feedpoints along the mixer between the mixing elements. 11. The continuous process of claim 1 , wherein the mixer has 1 to 5 further feedpoints along the mixer between the mixing elements. 12. The continuous process of claim 1 , wherein 2 to 10 mixing elements, are situated between the feedpoints and also between the last feedpoint in the mixer and the point of outlet from the mixer. 13. The continuous process of claim 1 , wherein 2 to 5 mixing elements, are situated between the feedpoints and also between the last feedpoint in the mixer and the point of outlet from the mixer. 14. The continuous process of claim 1 , wherein at the mixing elements, the axial gap between rotor and stator is 0.1 to 15 mm, and the radial gap between the rotor of the mixing elements and the housing of the mixer is 0.1 to 10 mm. 15. The continuous process of claim 1 , wherein at the mixing elements, the axial gap between rotor and stator is 1 to 5 mm, and the radial gap between the rotor of the mixing elements and the housing of the mixer is 0.5 to 5 mm. 16. The continuous process of claim 1 , wherein the rotational speed of the rotors in the mixer is 10 to 50,000 revolutions/min, and the circumferential speed of the outside surface of the rotors is 0.1 to 30 m/s. 17. The continuous process of claim 1 , wherein the rotational speed of the rotors in the mixer is 50 to 3,000 revolutions/min, and the circumferential speed of the outside surface of the rotors is 0.5 to 15 m/s. 18. The continuous process of claim 1 , wherein the emulsions obtained contain high viscosity polyorganosiloxanes having a viscosity of 10,000 to 2,000,000 mPa·s at 25° C., as measured according to DIN ISO 53019. 19. The continuous process of claim 1 , wherein the emulsions obtained have central particle sizes D(50) of 5 to 50 μm. 20. The continuous process of claim 1 , wherein two or more mixers are connected in series, at least one of the one or more mixers connected in series being a cylindrical mixer. 21. The continuous process of claim 1 , wherein the (A) polyorganosiloxanes are produced in a continuous manner beforehand and then in their as-obtained state are used directly for producing the emulsions.