Housing with a rotational friction welding seam

The invention claimed is: 1. An explosion protected housing ( 10 ) for an electrical operating device ( 12 ) comprising: a first part ( 14 ) made of plastic having a first wall ( 22 ) with an outer wall surface ( 28 ) about an axis of said first part ( 14 ), a second part ( 18 ) made of plastic having a second wall ( 24 ) with an inner wall surface ( 30 ) about said axis, said first wall ( 22 ) and said second wall ( 24 ) have an overlap region ( 26 ), and said first part ( 14 ) and said second part ( 18 ) being connected to each other by a rotational friction welding seam ( 32 ) located in the overlap region ( 26 ) along circumferences of said wall surfaces ( 28 , 30 ) of said first and second walls ( 22 , 24 ) so as to form an explosion-proof enclosure for the electrical operating device satisfying the protection level of pressure-proof encapsulation (Ex-d) and/or the protection level of increased safety (Ex-e), said rotational friction welding seam ( 32 ) having at least one compact zone ( 48 ) formed of fully fused plastic material and one mixing zone ( 44 ) formed by partially fused plastic material that exhibits a higher resilience than the fully fused plastic material of said compact zone, and said mixing zone ( 44 ) being in an axial edge region ( 46 ) of the overlap region ( 26 ) where there is a transition from the overlap region ( 26 ) to a side wall surface of one of said parts. 2. The explosion protected housing ( 10 ) of claim 1 in which said rotational friction welding seam ( 32 ) has two of said mixing zones ( 44 ) that are separated by said compact zone ( 48 ) along said central axis (R) of the rotational friction welding seam ( 32 ). 3. The explosion protected housing ( 10 ) of claim 1 in which at least one of the first part ( 14 ) and the second part ( 18 ) has grooves ( 50 ) or pockets ( 50 ) in the wall surface ( 28 , 30 ). 4. The explosion protected housing ( 10 ) of claim 3 in which said grooves ( 50 ) or pockets ( 50 ) of the first part ( 14 ) and/or of the second part ( 18 ) are arranged peripherally along the circumference of the wall surfaces ( 28 , 30 ) in the overlap region ( 26 ). 5. The explosion protected housing ( 10 ) of claim 1 in which at least one of the first part ( 14 ) and the second part ( 18 ) is a cap or a stopper. 6. The explosion protected housing ( 10 ) of claim 1 in which at least one of the first wall ( 22 ) and the second wall ( 24 ) consists of amorphous plastic material. 7. The explosion protected housing ( 10 ) of claim 1 in which said first wall ( 22 ) and said second wall ( 24 ) consist of different materials. 8. The explosion protected housing ( 10 ) of claim 1 in which at least one of the first wall ( 22 ) and the second wall ( 24 ) consist of polycarbonate. 9. The explosion protected housing ( 10 ) of claim 1 in which at least one of the outer wall surface ( 28 ) of the first wall ( 22 ) and the inner wall surface ( 30 ) of the second wall ( 24 ) has a conical form within the overlap region ( 26 ). 10. The explosion protected housing ( 10 ) of claim 1 in which the first part ( 14 ) and the second part ( 18 ) are further welded to each other at one end surface ( 34 , 36 ) of the first part and one end surface ( 34 , 36 ) of the second part. 11. The explosion protected housing ( 10 ) of claim 1 in which the first part ( 14 ) and the second part ( 18 ) are connected to each other along their circumferences solely by a rotational friction welding seam ( 32 ) on the wall surfaces ( 28 , 30 ) having a cylindrical casing shape. 12. The explosion protected housing ( 10 ) of claim 1 in which said mixing zone ( 44 ) of said rotational friction welding seam ( 32 ) has first elastic modulus, and said compact zone ( 48 ) of said rotational friction welding seam ( 32 ) has a second different elastic modulus greater than said first elastic modulus. 13. The explosion protected housing ( 10 ) of claim 1 in which the compact zone ( 48 ) of the rotational friction welding seam ( 32 ) has a more homogeneous material distribution than that of the mixing zone ( 44 ). 14. The explosion protected housing ( 10 ) of claim 1 in which said compact zone ( 48 ) of said rotational friction welding seam ( 32 ) has a greater material density than that of the mixing zone ( 44 ). 15. The explosion protected housing of claim 1 in which at least one of said parts has an end wall, and said compact zone is adjacent said end wall and said mixing zone is separated from said end wall by said compact zone. 16. A method for manufacturing the explosion protected housing of claim 1 comprising the steps of: connecting the first wall ( 22 ) and the second wall ( 24 ) along their circumferential surfaces ( 28 , 30 ) by rotational friction welding through rotation of one of said parts relative to the other of said parts to form rotational friction welding seam ( 32 ) having said compact zone ( 48 ) and said mixing zone ( 44 ). 17. The method of claim 16 in which said rotational friction welding forms a rotational friction welding seam ( 32 ) having said compact zone ( 48 ) with a greater elastic modulus than the elastic modulus of said mixing zone ( 44 ). 18. The method of claim 16 in which said rotational friction welding forms a welding seam ( 32 ) having a compact zone ( 48 ) with a greater material density than the mixing zone ( 44 ).