Filter element and method of manufacturing a filter element

What is claimed is: 1. A filter element comprising: a filter medium pack comprising a circumferential face extending in a longitudinal direction from a fluid inlet flow face to an opposing fluid outlet flow face; and a support arrangement comprising a shell member extending in the longitudinal direction, and wherein the shell member is circumscribing at least a part of the circumferential face of the filter medium pack; wherein at least a portion of the shell member is thermally welded to the circumferential face of the filter medium pack. 2. The filter element of claim 1 , wherein the filter medium pack comprises coiled layers of filter material, and wherein said circumferential face of the filter medium pack is an outer surface of an outer layer of said coiled layers of filter material. 3. The filter element of claim 2 , wherein the filter material comprises cellulose fibers, synthetic fibers, or a combination of both. 4. The filter element of claim 1 , wherein the filter medium pack comprises coiled layers of filter material, wherein an outer layer of the coiled layers is covered by a plastic wrap, and wherein an outer surface of said plastic wrap is forming said circumferential face of the filter medium pack. 5. The filter element of claim 1 , wherein the filter medium pack comprises fluted filter media, preferably wherein flutes are formed by securing a first corrugated sheet to a second non-corrugated sheet. 6. The filter element of claim 1 , wherein the thermally welded portion of the shell member is a circumferential portion forming a circumferential leak-tight joint between the shell member and the circumferential face of the filter medium pack. 7. The filter element of claim 6 , wherein a separation distance measured along the longitudinal direction from the fluid inlet flow face to the circumferential leak-tight joint is varying as function of an azimuthal angular position of the leak-tight joint on the filter medium pack, preferably said separation distance is varying between a minimum and a maximum separation distance. 8. The filter element of claim 6 , wherein said circumferential leak-tight joint is spaced from said fluid inlet flow face and spaced from said fluid outlet flow face with S IN >0.05× H and S OUT >0.05× H, preferably S IN >0.10× H and S OUT >0.10× H wherein S IN and S OUT is a separation distance measured along the longitudinal direction between the leak-tight joint and, respectively, the inlet and outlet flow face, and wherein His a filter medium pack height measured along the longitudinal direction between the inlet flow face and the outlet flow face. 9. The filter element of claim 1 , wherein an outer surface of the shell member comprises a welding circumferential imprint, a welding partly-circumferential imprint, one or more individual welding indentations, or a combination of one or more individual welding indentations with a welding circumferential imprint or with a welding partly-circumferential imprint. 10. The filter element of claim 1 , wherein the thermal welding of the portion of the shell member comprises: heating the portion of the shell member to be welded, pushing the heated portion or at least part of the heated portion against the circumferential face of the filter medium pack, and allowing the heated portion of the shell member to cool down. 11. The filter element of claim 1 , wherein the shell member or at least the portion of the shell member thermally welded to the circumferential face of the filter medium pack is made of a thermoplastic material, preferably the thermoplastic material is any the following list of materials or mixtures and combinations thereof: acrylonitrile butadiene styrene, polypropylene, polyamide, polyethylene terephthalate, polylactic acid, polyethylene, polycarbonate, polystyrene, or polyvinyl chloride. 12. The filter element of claim 1 , wherein the support arrangement is a seal arrangement and wherein the shell member or at least a part of the shell member is forming a seal carrier for supporting a seal member for sealing the filter element to a housing of a filter system. 13. The filter element of claim 1 , wherein the support arrangement is a moulded single-structure seal arrangement comprising said shell member and further comprising a seal member for sealing the filter element to a housing of a filter system, and wherein the shell member or at least a part of the shell member is forming a seal carrier for said seal member. 14. The filter element according to claim 13 , wherein the seal member comprises a first material and the shell member, or at least the portion of the shell member welded to the circumferential face of the filter medium pack, comprises a second material, and wherein the second material is different from the first material. 15. A method of manufacturing a filter element comprising a filter medium pack having a circumferential face extending in a longitudinal direction from a fluid inlet flow face to an opposing fluid outlet flow face, the method comprising: providing a support arrangement comprising a shell member configured for circumscribing the circumferential face or at least a part of the circumferential face of the filter medium pack; heating at least a portion of the shell member; positioning the shell member around the circumferential face of the filter medium pack; pushing the heated portion of the shell member or at least part of the heated portion of the shell member against the circumferential face of the filter medium pack; and allowing the circumferential portion of the shell member to cool down. 16. The method of claim 15 , wherein the heating of the portion of the shell member is performed prior to positioning the shell member around the circumferential face of the filter medium pack, or alternatively, wherein the heating of the portion of the shell member is performed after positioning the shell member around the circumferential face of the filter medium pack. 17. The method of claim 15 , wherein the heated portion is a circumferential portion of the shell member such that when pushing the heated portion of the shell member against the circumferential face of the filter medium pack, a circumferential spacing between the shell member and the circumferential face of the filter medium pack becomes sealed off. 18. The method of claim 17 , wherein the heated portion of the shell member corresponds to a circumferential edge of the shell member, and wherein said pushing the heated portion of the shell member or at least part of the heated portion of the shell member against the circumferential face of the filter medium pack comprises: providing a jig element comprising a circumferential chamfered edge configured for encircling the circumferential face of the filter medium pack; positioning the jig element with respect to the filter medium pack such that the circumferential chamfered edge of the jig element is encircling the circumferential face of the filter medium pack and is facing in the longitudinal direction towards the circumferential edge of the shell member; and relatively moving the shell member with respect to the jig element along the longitudinal direction until the chamfered edge of the jig element pushes against the heated circumferential edge of the shell member and at least a portion of the heated circumferential edge is guided towards the circumferential face of the filter medium pack and thereby fills up said circumferential spacing between the shell member and the circumferential face of the filter medi