Solar radiation receiver having an entry window made of quartz glass and method for producing an entry window

The invention claimed is: 1. A solar radiation receiver comprising: a chamber configured to pass a working gas to an absorber for solar radiation so as to cause thermal absorption; the absorber being supported in the chamber and a dome-shaped window of quartz glass transmitting solar radiation has a convexly curved inside surface that faces the absorber, and an outside that faces away from the absorber and is exposed during operation of the receiver to an ambient temperature Tu, wherein the window has a wall thickness d such that, when the convexly curved inside surface has a nominal internal temperature Ti of at least 950° C. during operation of the receiver, the outside of the window has a temperature Ta that is less than 850° C. and at least 150° C. less than the nominal internal temperature Ti, and wherein the window has a region wherein the internal temperature Ti is a maximum internal temperature Ti of the window during operation of the receiver, and the wall thickness d in the region of said maximum internal temperature Ti is at least 7 mm; wherein the wall thickness d has a maximum in a dome center of the window; and wherein the wall thickness d varies from a minimum thickness to a maximum thickness, and said maximum thickness is greater than the minimum thickness by at least 20%. 2. The solar radiation receiver according to claim 1 , wherein the wall thickness d is configured such that, when during operation of the receiver the internal temperature Ti is at least 950° C., the temperature Ta of the outside is less than 800° C. 3. The solar radiation receiver according to claim 1 , wherein the wall thickness d is at least 10 mm in the region of the maximum internal temperature Ti. 4. The solar radiation receiver according to claim 1 , wherein the wall thickness d in the region of the maximum internal temperature Ti is configured such that, when the internal temperature Ti is at least 950° C. during operation of the receiver, the wall thickness in said region conforms to the following dimensioning rule: d >λ( Ti−Ta )/α( Ta−Tu )  (1), where: λ=a heat conduction coefficient of transparent quartz glass; α=a heat transfer coefficient quartz glass/air; and Tu=25° C. 5. The solar radiation receiver according to claim 1 , wherein the quartz glass of the window has a mean hydroxyl group content of less than 100 ppm by wt. 6. The solar radiation receiver according to claim 1 , wherein the wall thickness d is configured such that, when during operation of the receiver the internal temperature Ti is at least 950° C., the outside has a temperature Ta of less than 750° C. 7. The solar radiation receiver according to claim 1 , wherein the wall thickness d is at least 20 mm in the region of the maximum internal temperature Ti. 8. The solar radiation receiver according to claim 1 , wherein the wall thickness varies from a minimum thickness to a maximum thickness, and said maximum thickness is greater than the minimum thickness by at least 50%. 9. The solar radiation receiver according to claim 1 , wherein the quartz glass of the window has a mean hydroxyl group content of less than 30 ppm by wt.