High temperature pump unit with magnetic coupling

The invention claimed is: 1. A pump unit ( 300 ) with at least one impeller ( 340 ), comprising a magnetic coupling ( 100 , 200 ), wherein the coupling is mechanically connected to the at least one impeller via an inner rotor and where an outer rotor is connected to an electrical machine arranged to produce a rotational torque, said pump being arranged to circulate a fluid by the impeller, the magnetic coupling comprising an outer rotor including a plurality of permanent magnets ( 101 , 201 ) arranged to form a plurality of magnetic poles ( 105 , 205 ); an inner rotor ( 110 , 210 ); the outer rotor and the inner rotor being located coaxially to one another around an axis ( 130 , 230 ) and spaced apart from one another by an air gap ( 150 , 250 ); a rotor can ( 330 , 662 ) arranged in the air gap ( 250 , 150 ), between the inner rotor and the outer rotor, so to make a dividing section between the inner and outer rotor; the outer rotor has a cylindrical structure surrounding ( 120 , 220 ) the plurality of magnetic poles ( 105 , 205 ), the cylindrical structure being made of a magnetic susceptible material for conducting a magnetic flux between the plurality of magnetic poles ( 105 , 205 ); and the inner rotor ( 110 , 210 ) being made of a magnetic susceptible material and free of permanent magnetic material, wherein the inner rotor is formed with multiple radial projections ( 111 , 210 ) acting as salient inner rotor poles distributed around the axis ( 130 , 230 ) of the inner rotor; characterized in that, each of the plurality of magnetic poles, comprising at least a section with a radial magnetic direction in respect of the axis ( 130 , 230 ) and at least a section with a magnetic direction angled between a radial direction and a tangential direction in respect of the axis ( 130 , 230 ), wherein the combined length of the sides of the plurality of permanent magnets cover less than 75% of the circumference of the cylindrical structure. 2. The pump unit according to claim 1 , wherein at least some of the plurality of permanent magnets ( 101 , 102 , 104 ) are covered fully or partly with a thermal protection layer. 3. The pump unit according to claim 1 , wherein the plurality of permanent magnets are magnetized with sinusoidal magnetization. 4. The pump unit according to claim 1 , wherein each of the plurality of magnetic poles are arranged as a Halbach array. 5. The pump unit according to claim 1 , wherein the direction angled between a radial and a tangential direction is with an angle in the range of 20 to 70 degrees in respect of the radial direction. 6. The pump unit according to claim 1 , wherein the inner rotor is made of a non-laminated material. 7. The pump unit according to claim 1 , wherein the inner rotor ( 660 ) is encircled by a rotor sleeve ( 661 ). 8. The pump unit according to claim 1 , wherein the rotor can ( 662 ) comprises a temperature-insulating layer. 9. The pump unit according to claim 1 wherein the permanent magnets ( 101 - 104 ) are fixated fully or partly by supporting material ( 260 ) placed in between two neighboring magnets ( 605 a , 605 b ) in a place where no permanent magnetic material is present. 10. The pump unit according to claim 9 wherein the supporting material ( 260 ) placed in between two neighboring magnets is made of an electrical conducting and non-magnetic material. 11. The pump unit according to claim 9 wherein the supporting material is made of a first layer ( 261 ) and a second layer ( 262 ), wherein the first layer ( 261 ) is made of an electrical conducting and non-magnetic material and the second layer ( 262 ) is made of a magnetic susceptible material. 12. The pump unit according to claim 1 , wherein a space ( 140 , 240 ) between each of the multiple projections ( 111 , 210 ) of the inner rotor is filled with an electrical conducting and non-magnetic material forming a plurality elongated fillings, each of the elongated fillings are electrically connected to one another in both ends. 13. The pump unit according to claim 1 , suitable for operating the inner rotor in a high temperature environment above 300 degrees Celsius and less than 500 degrees Celsius. 14. The pump unit according to 1 , wherein the outer rotor comprises between two and eight magnetic poles, preferably four or six magnetic poles. 15. The pump unit according to 1 wherein the number of magnetic poles of the outer rotor is different from the number of salient inner rotor poles. 16. The pump unit according to claim 1 wherein the inner rotor has four radial projections ( 111 ), and where each projection has a length in radial direction that is longer than the width of the projection, and where each projection protrudes from the axis ( 130 , 230 ) in a direction towards the outer rotor and defines a mechanical angle of 90 degrees with each of two neighboring projections. 17. A magnetic coupling ( 100 , 200 ) comprising an outer rotor including a plurality of permanent magnets, arranged to form a plurality of magnetic poles, each magnetic pole having a plurality of sections; an inner rotor made of a magnetic susceptible material and free of permanent magnetic material, wherein the inner rotor is formed with multiple radial projections acting as salient inner rotor poles distributed over a circumference of the inner rotor; the outer rotor ( 120 , 220 ) and the inner rotor ( 210 , 110 ) being located coaxially to one another around an axis ( 230 , 130 ) and spaced apart from one another by an air gap ( 250 , 150 ); a rotor can ( 330 , 662 ) arranged in the air gap ( 250 , 150 ), between the inner rotor and the outer rotor, so to make a dividing section between the inner and outer rotor; the outer rotor has a cylindrical structure ( 120 , 220 ) surrounding the plurality of magnetic poles, the cylindrical structure being made of a magnetic susceptible material for conducting a magnetic flux between the plurality of magnetic poles; each of the plurality of sections, comprising at least a section ( 101 , 201 ) with a radial magnetic direction in respect of the axis ( 130 , 203 ) and at least a section ( 102 , 202 ) with a magnetic direction angled between a radial direction and a tangential direction in respect of the axis ( 130 , 203 ); and wherein the combined length of the sides of the plurality of permanent magnets cover less than 75% of the circumference of the cylindrical structure. 18. The pump unit according to claim 10 wherein the electrical conducting and non-magnetic material includes copper or aluminum. 19. The pump unit according to claim 12 , wherein the electrical conducting and non-magnetic material includes copper or aluminum.