The present application relates to an elevator system and a method of adapting an elevator system, the system being adapted to warn elevator users of the existence of a vertical misalignment between a floor of a lift car and a landing surface adjacent to which the lift car stops. The elevator system comprises facing parallel walls that depend vertically downwards from a leading edge of the lift car floor and a leading edge of the landing surface respectively. A luminaire is mounted on at least one of said walls at a distance below the edge of said wall so as to face the opposing wall irrespective of said vertical misalignment. Light from said luminaire illuminates said opposing walls to alert elevator users to the existence of said vertical misalignment.

The present application relates to an elevator system and a method of adapting an elevator system, the system being adapted to warn elevator users of the existence of a vertical misalignment between a floor of a lift car and a landing surface adjacent to which the lift car stops. The elevator system comprises facing parallel walls that depend vertically downwards from a leading edge of the lift car floor and a leading edge of the landing surface respectively. A luminaire is mounted on at least one of said walls at a distance below the edge of said wall so as to face the opposing wall irrespective of said vertical misalignment. Light from said luminaire illuminates said opposing walls to alert elevator users to the existence of said vertical misalignment.

Elevator systems are provided. The systems include an elevator car movable along an elevator shaft, the shaft having a pit floor, the elevator car having an elevator car door sill and a car apron assembly. The car apron assembly includes an apron frame movably mounted to the elevator car, the apron frame having a frame base, a winding mechanism mounted within the elevator car door sill, and a semi-rigid curtain attached to the winding mechanism and extending to the frame base. The semi-rigid curtain is configured to transition between a deployed state and a stowed state, wherein when in the deployed state the semi-rigid curtain extends below the elevator car to block an open landing door that is lower than the elevator car when the elevator car is positioned offset and above an adjacent landing, and when in the stowed state the semi-rigid curtain is wound about the winding mechanism.

A side of the seal member 35 is provided rotatably to a car-side door sill 31. The rotation of the side allows the side to be displaceable between a sealing position and an evacuation position. The link mechanism for rotating the seal member 35 releases an engagement with the car-side actuating member to rotate the seal member 35 to a sealing position and fixes the seal member 35 at the sealing position. The link mechanism engages with the actuating member and releases the fixing of the seal member 35 at a sealing position when the car door moves to the door-close end.

A side of the seal member 35 is provided rotatably to a car-side door sill 31. The rotation of the side allows the side to be displaceable between a sealing position and an evacuation position. The link mechanism for rotating the seal member 35 releases an engagement with the car-side actuating member to rotate the seal member 35 to a sealing position and fixes the seal member 35 at the sealing position. The link mechanism engages with the actuating member and releases the fixing of the seal member 35 at a sealing position when the car door moves to the door-close end.

Elevator systems are provided. The elevator systems include an elevator car movable along an elevator shaft having a pit floor and a shaft top, the elevator car having a car door lock arranged to enable opening of doors by a landing door lock mechanism when the elevator car is located at a landing and an elevator safety system. The elevator safety system includes a car door lock securing device arranged to prevent manual opening of the elevator car doors when in a first state and permits opening of the elevator car doors when in a second state and a car apron affixed to the car door sill and operable from a stowed state to a deployed state, wherein when the car apron transitions from the stowed state to the deployed state, the car door lock securing device is transitioned from the first state to the second state.

Elevator systems are described. The systems include an elevator car movable along an elevator shaft having a pit floor. A car apron assembly is provided that includes an apron frame movably mounted to the elevator car, the apron frame having a frame base, a support arm, and an apron stop at an end of the support arm opposite the frame base, and a semi-rigid curtain extending between a car sill and the frame base. A shaft stop is arranged within the elevator shaft to interact with the apron stop. The curtain transitions from a deployed state to a compressed state when the apron stop contacts the shaft stop, and when in the deployed state the curtain extends below the elevator car to block an open landing door that is lower than the elevator car when the elevator car is positioned offset and above an adjacent landing.

Elevator systems including an elevator car having a car door sill and car apron assembly movable along an elevator shaft having a pit floor, are provided. The car apron assembly includes a collapsible guard with at least one guard element that is moveable from a deployed state to a compressed state. In the compressed state the at least one guard element is positioned within the car door sill. A guard frame is fixedly connected to the at least one guard element by one or more reinforcement elements, a translating member is arranged at each end of the guard frame, and a guide member fixedly connected to the elevator car. The collapsible guard is urged from the deployed state toward the compressed state as the guard element contacts the pit floor, and when transitioning from the deployed state to the compressed state, the translating member translates along the guide member.

Elevator systems are provided. The systems include an elevator car movable along an elevator shaft, the shaft having a pit floor and a shaft top, the elevator car having an elevator car door sill, a plurality of landings arranged along the elevator shaft, wherein each landing has a landing door, and a car apron assembly. The car apron assembly includes a semi-rigid curtain attached to the elevator car door sill at a first end of the semi-rigid curtain. The semi-rigid curtain folds from a deployed state to a folded state when contacting the pit floor, and, when in the deployed state, the semi-rigid curtain extends below the elevator car to block an open landing door that is lower than the elevator car when the elevator car is positioned offset and above an adjacent landing.

Elevator systems are provided. The systems include an elevator car movable along an elevator shaft, the shaft having a pit floor and a shaft top, the elevator car having an elevator car door sill. A plurality of landings are arranged along the elevator shaft, wherein each landing has a landing door. A car apron assembly is provided that includes a car apron attached to the elevator car at the elevator car door sill, a first triggering element connected to at least one landing door, and a second triggering element operably connected to the car apron. The car apron is deployable from a stowed state to a deployed state when the first triggering element engages and actuates the second triggering element.