Temperature sensor and a method for assembling such a temperature sensor

What is claimed is: 1. A temperature sensor, comprising: a temperature sensing element transducing a sensed temperature into an electrical output signal and having a plurality of electrically conductive leads; a mineral insulated cable having a plurality of conductor wires enclosed by a metal outer sheath, the conductor wires are insulated with respect to each other inside the cable and extend beyond the outer sheath at a terminal end of the cable, the electrically conductive leads are connected to the conductor wires extending beyond the outer sheath at a junction region; and an electrically insulating element insulating the conductor wires extending beyond the outer sheath at least partially with respect to each other and with respect to the outer sheath, the electrically insulating element having a first opening receiving the conductor wires extending beyond the outer sheath and a second opening at least partially receiving the temperature sensing element, the junction region is located within the electrically insulating element and the electrically insulating element has an aperture extending up to the junction region. 2. The temperature sensor of claim 1 , wherein the electrically insulating element has an essentially elongate cylindrical shape and has the first opening at a first and the second opening at an opposite longitudinal end. 3. The temperature sensor of claim 2 , wherein the aperture extends perpendicularly to a longitudinal axis of the electrically insulating element. 4. The temperature sensor of claim 2 , wherein the first opening extends towards the junction region and has a partition wall insulating the conductor wires extending beyond the outer sheath with respect to each other. 5. The temperature sensor of claim 1 , wherein an inner surface of the electrically insulating element has a plurality of grooves at the junction region, a plurality of terminal ends of the conductor wires extending beyond the outer sheath are positioned in the grooves. 6. The temperature sensor of claim 1 , wherein the electrically conductive leads extending beyond the outer sheath each overlap one of the conductor wires in the junction region. 7. The temperature sensor of claim 1 , wherein a connection between the temperature sensing element and the cable is laser welded in the junction region. 8. The temperature sensor of claim 1 , wherein the cable and the temperature sensing element are partially nested and retained in the first opening and the second opening of the electrically insulating element by force fit, press fit or friction fit connection. 9. The temperature sensor of claim 1 , wherein a portion of the cable nested in the electrically insulating element has a geometric shape preventing a rotation between the cable and the electrically insulating element by a form-fit connection. 10. The temperature sensor of claim 1 , wherein the electrically insulating element is manufactured from a ceramic material. 11. The temperature sensor of claim 1 , wherein the electrically insulating element integrally formed in one piece. 12. A temperature sensor, comprising: a temperature sensing element transducing a sensed temperature into an electrical output signal and having a plurality of electrically conductive leads; and a mineral insulated cable having a plurality of conductor wires enclosed by a metal outer sheath, the conductor wires are insulated with respect to each other inside the cable and extend beyond the outer sheath at a terminal end of the cable with a predetermined length, the electrically conductive leads are connected to the conductor wires extending beyond the outer sheath at a junction region, the conductor wires extending beyond the outer sheath are at least partially curved or folded in a zigzag shape in a non-expanded state of the temperature sensor, the predetermined length of the conductor wires extending beyond the outer sheath is smaller in the non-expanded state than in an expanded state of the temperature sensor. 13. The temperature sensor of claim 12 , wherein a connection between the temperature sensing element and the cable is formed by an intermediate wire having a first end connected to the electrically conductive leads and an opposite second end connected to a plurality of terminal ends of the conductor wires extending beyond the outer sheath. 14. The temperature sensor of claim 12 , wherein a connection between the temperature sensing element and the cable is formed directly between each electrically conductive lead and one of the conductor wires. 15. The temperature sensor of claim 14 , wherein one junction region is formed between each electrically conductive lead and one of the conductor wires. 16. A method for assembling a temperature sensor, comprising: providing a temperature sensing element transducing a sensed temperature into an electrical output signal, the temperature sensing element having a plurality of electrically conductive leads; providing a mineral insulated cable having a plurality of conductor wires enclosed by a metal outer sheath, the conductor wires are insulated with respect to each other inside the cable and extend beyond the outer sheath at a terminal end of the cable; providing an electrically insulating element having a first opening and a second opening; inserting the cable in the first opening such that the conductor wires extending beyond the outer sheath are positioned inside the electrically insulating element; inserting the temperature sensing element in the second opening such that the electrically conductive leads are positioned inside the electrically insulating element and overlap the conductor wires at a junction region; and connecting the electrically conductive leads to the conductor wires at the junction region through an aperture of the electrically insulating element extending up to the junction region. 17. The method of claim 16 , wherein the inserting step of the cable includes positioning the conductor wires in a plurality of grooves of an inner surface of the electrically insulating element. 18. The method of claim 16 , wherein the connecting step includes laser welding the electrically conductive leads to the conductor wires by directing a laser beam towards and injecting an inert gas through the aperture. 19. The method of claim 16 , wherein the inserting steps include holding the cable and the temperature sensing element in position in the first opening and the second opening by a force fit connection, a press fit connection, a friction fit connection and/or a form-fit connection.