Elevator

The invention claimed is: 1. An elevator comprising: an elevator car; at least one rope wheel including circumferential rope contact areas distributed in an axial direction of the at least one rope wheel; belt-shaped ropes connected to the elevator car, the belt-shaped ropes configured to pass over the at least one rope wheel such that each of the belt-shaped ropes passes against a respective one of the circumferential rope contact areas, the belt-shaped ropes each having a width larger than a thickness as measured in a transverse direction of the belt-shaped ropes; and a sensing arrangement configured to sense displacement of one or more of the belt-shaped ropes on the at least one rope wheel, the sensing arrangement including, a first sensing member configured to sense displacement of one or more of the belt-shaped ropes radially outwards from the at least one rope wheel, the first sensing member extending in the axial direction of the at least one rope wheel along a surface of the at least one rope wheel at a radial distance therefrom such that, when the belt-shaped ropes are not displaced, the first sensing member does not protrude between any portion of any two belt-shaped ropes among the belt-shaped ropes and the first sensing member extends along the surface of the at least one rope wheel at a radial distance therefrom with a gap between the first sensing member and each of the circumferential rope contact areas, a height of the gap being more than the thickness of the belt-shaped ropes and less than 2.2 times the thickness of the belt-shaped ropes, the first sensing member being displaceable by one of the belt-shaped ropes colliding into contact with the first sensing member, and the sensing arrangement being arranged to trigger one or more actions in response to displacement of one of the sensing members, and a second sensing member on an axially outer side of axially outermost one of the belt-shaped ropes, the second sensing member configured to sense displacement of one or more of the belt-shaped ropes axially outwards from the at least one rope wheel, the second sensing member being displaceable by one of the belt-shaped ropes colliding into contact with the second sensing member, the sensing arrangement being configured to trigger the one or more actions in response to displacement of the second sensing member, the second sensing member not protruding between any portion of any two belt-shaped ropes among the belt-shaped ropes when the belt-shaped ropes are not displaced. 2. The elevator according to claim 1 , wherein the second sensing member is connected to the first sensing member to sense displacement of one or more of the belt-shaped ropes radially outwards from the at least one rope wheel, the first sensing member and the second sensing member being displaceable together as one structure and the sensing arrangement being configured to trigger the one or more action in response to displacement of the first sensing member and the second sensing member. 3. The elevator according to claim 1 , wherein the at least one rope wheel is a drive wheel configured to move the belt-shaped ropes, and each of the circumferential rope contact areas is a contact area for transmitting traction from the at least one rope wheel to one of the belt-shaped ropes passing against the at least one rope wheel. 4. The elevator according to claim 3 , wherein each of the circumferential contact areas is cambered. 5. The elevator according to claim 4 , wherein each of the circumferential contact areas and a surface of each of the belt-shaped ropes resting against the circumferential contact areas are smooth. 6. The elevator according to claim 3 , wherein the one or more actions include stopping a rotation of the drive wheel of the elevator. 7. The elevator according to claim 3 , wherein the elevator further comprises: a motor configured to rotate the drive wheel, wherein the elevator is configured to control the motor. 8. The elevator according to claim 1 , wherein the height of the gap is more than 1.5 times the thickness of the belt-shaped ropes. 9. The elevator according to claim 1 , wherein the height of the gap is equal or less than 2 times the thickness of the belt-shaped ropes. 10. The elevator according to claim 1 , wherein the first sensing member is displaceable at least in a longitudinal direction of the belt-shaped ropes such that, when the belt-shaped ropes move in the longitudinal direction during elevator use and are displaced in a radial direction to collide into contact with the first sensing member, the first sensing member is configured to displace at least in the longitudinal direction of the belt-shaped ropes. 11. The elevator according to claim 1 , wherein the first sensing member is mounted pivotally displaceably around an axis parallel with the axial direction of the at least one rope wheel, and the sensing arrangement is configured to trigger the one or more actions in response to a pivoting displacement of the first sensing member. 12. The elevator according to claim 1 , wherein each of the belt-shaped ropes comprises: one or more continuous load bearing members the load bearing members being made of a composite material including reinforcing fibers embedded in a polymer matrix. 13. The elevator according to claim 1 , wherein each of the belt-shaped ropes comprises: one or more continuous load bearing members, the load bearing members being embedded in an elastic coating forming a surface of one of the belt-shaped ropes. 14. A sensor arrangement comprising: one or more sensors associated with at least one rope wheel, the one or more sensors including, a first sensor configured to sense displacement of belt-shaped ropes radially outward from the at least one rope wheel, the first sensor having a bottom side spaced apart from the at least one rope wheel such that, when the belt-shaped ropes are not displaced, the first sensor does not protrude between any portion of any two belt-shaped ropes among the belt-shaped ropes and the bottom side is spaced apart from the at least one rope wheel with a gap between the bottom side and the at least one rope wheel, a size of the gap being greater than a thickness of the belt-shaped ropes, and a second sensor configured to sense displacement of belt shaped ropes axially outward from the at least one rope wheel such that, when the belt shaped ropes are not displaced, the second sensor does not protrude between any portion of any two belt-shaped ropes among the belt shaped ropes. 15. The sensor arrangement of claim 14 , wherein the size of the gap is less than twice the thickness of the one of the belt-shaped ropes and more than 1.5 times the thickness of the one of the belt-shaped ropes. 16. The sensor arrangement of claim 14 , wherein the at least one rope wheel further comprises: circumferential rope contact areas such that one of the belt-shaped ropes passes against each of the circumferential rope contact areas. 17. The sensor arrangement of claim 16 , wherein the second sensor is connected to the first sensor such that the first and second sensors form one body, and the second sensor extends radially inward from the first sensor. 18. The sensor arrangement of claim 14 , wherein one of the al least one rope wheel is a drive wheel configured to move the belt-shaped ropes. 19. The sensor arrangement of claim 14 , wherein the sensors are arranged such that a space between a first one of the belt-shaped ropes immediately adjacent to a second one of the belt-shaped ro