An operation locking device for a climb-free system includes a locking assembly, a fixing block and a triggering assembly. The fixing block is mounted on a climb-free system trolley. The locking assembly is connected to the fixing block by the triggering assembly. The triggering assembly is configured to control the locking assembly to be switchable between a locked state and an unlocked state. When the climb-free system trolley is out-of-control, the triggering assembly triggers the locking assembly to switch to the locked state and to be clamped in a sliding rail, such that the climb-free system trolley stops operating. When the climb-free system trolley needs to adjust a working position by sliding up and down, the triggering assembly triggers the locking assembly to switch to the unlocked state and to be disengaged from the sliding rail.

An operation locking device for a climb-free system includes a locking assembly, a fixing block and a triggering assembly. The fixing block is mounted on a climb-free system trolley. The locking assembly is connected to the fixing block by the triggering assembly. The triggering assembly is configured to control the locking assembly to be switchable between a locked state and an unlocked state. When the climb-free system trolley is out-of-control, the triggering assembly triggers the locking assembly to switch to the locked state and to be clamped in a sliding rail, such that the climb-free system trolley stops operating. When the climb-free system trolley needs to adjust a working position by sliding up and down, the triggering assembly triggers the locking assembly to switch to the unlocked state and to be disengaged from the sliding rail.

An overspeed safety braking mechanism for lift cars and elevator systems is described herein. The safety mechanism may comprise a safety kit secured to an overhead portion of a lift car, and configured to engage a cable to prevent a downward movement of the lift car. Engagement of the cable may occur when a threshold speed is reached. The overhead portion of the lift car is detachable upon a predetermined upward force resulting from an engagement of the safety cable from the safety kit. A primary brake system may be positioned beneath the safety kit, on or near a lift platform, configured to engage the safety cable in response to an activation of the safety kit and a detection of the threshold speed.

An overspeed safety braking mechanism for lift cars and elevator systems is described herein. The safety mechanism may comprise a safety kit secured to an overhead portion of a lift car, and configured to engage a cable to prevent a downward movement of the lift car. Engagement of the cable may occur when a threshold speed is reached. The overhead portion of the lift car is detachable upon a predetermined upward force resulting from an engagement of the safety cable from the safety kit. A primary brake system may be positioned beneath the safety kit, on or near a lift platform, configured to engage the safety cable in response to an activation of the safety kit and a detection of the threshold speed.

Systems, apparatuses, and methods are described for a stairlift overspeed safety system are disclosed. The overspeed safety system may include a centripetal cam assembly, a trigger assembly, and a jammer assembly. The centripetal cam assembly may include a spring-loaded plate and a plurality of centripetal cams connected to the spring-loaded plate, configured to move to an extended position when the rail speed exceeds the speed threshold. The trigger assembly may include a trigger plate configured to be pushed by at least one of the centripetal cams when moved to the extended position. Pushing the trigger plate may cause a switch to open to shut off power to the motorized stairlift. The jammer assembly may include a jammer configured to wedge between teeth of a rack and pinion of the motorized stairlift to initiate a deceleration to stop movement of the motorized stairlift.

An elevator system consisting in a platform steel floor fixed to four bogeys guiding the descent or ascension of the platform onto the two steel H beam or steel linear motion track profiles. The elevator is operated by a remote or pad control transmitting signals with a wire or with a wireless frequency signals to a motorised mechanical engine or electric winch at the ground level of structure, if not being manually operated and controlled. The motorised mechanical engine or electric winch unrolls one or a set of normal operation cables to allow the descent of the elevator platform and the sliding o f t he bogeys along the lateral guiding tracks. The motorised mechanical engine or electric winch rolls the set of normal operation cables to allow the ascension of the elevator platform and the sliding of the bogeys along the lateral guiding tracks. The set of operating cables drives a fixed pulley on a driving steel shaft at the top of the structure or elsewhere on the elevator system. On the driving steel shaft is also there one or many steel drums or pulleys to allow unrolling and rolling of a second independent steel cable standing for a first emergency safety brake device activated by one or many inertia brakes which stops rotation on steel shaft at excessive speed rotation of steel shaft if a fracture or breaking happens on the set of operating cables and engage the free falling of the elevator platform. The set of safety cables is attached to steel hooks fixed to the shock-proof steel plate attached underneath the elevator platform by compression springs and guided by steel rods inserting steel bushings. The shock-proof safety steel plate is retained by two fixed steel cables attached to elevator platform and to a steel hook half ring or U-Bolt mounted on the shock-proof safety steel plate.

The second emergency safety brake device is engaged when the two spur gears collides together after the compression of the springs or of any other kind of shock absorber when the set of safety cables ask to stop the free felling of the shock-proof steel plate and because the two opposite spur gears are taking two different directions onto the steel gear track or gear rack with teeth and also having then two different rotation direction; one spur gear is going down and the other spur gear is stopping its rotation. When the emergency break is applied for the elevator to stop its free falling, the safety trap on elevator floor can be lifted manually and be blocked by engaging the retainer steel arm in the corner steel angle and sided steel plate to allow the person to evacuate by the ladder bars fixed on the structure and the ladder bar underneath safety trap.

An elevator system consisting in a platform steel floor fixed to four bogeys guiding the descent or ascension of the platform onto the two steel H beam or steel linear motion track profiles. The elevator is operated by a remote or pad control transmitting signals with a wire or with a wireless frequency signals to a motorised mechanical engine or electric winch at the ground level of structure, if not being manually operated and controlled. The motorised mechanical engine or electric winch unrolls one or a set of normal operation cables to allow the descent of the elevator platform and the sliding o f t he bogeys along the lateral guiding tracks. The motorised mechanical engine or electric winch rolls the set of normal operation cables to allow the ascension of the elevator platform and the sliding of the bogeys along the lateral guiding tracks. The set of operating cables drives a fixed pulley on a driving steel shaft at the top of the structure or elsewhere on the elevator system. On the driving steel shaft is also there one or many steel drums or pulleys to allow unrolling and rolling of a second independent steel cable standing for a first emergency safety brake device activated by one or many inertia brakes which stops rotation on steel shaft at excessive speed rotation of steel shaft if a fracture or breaking happens on the set of operating cables and engage the free falling of the elevator platform. The set of safety cables is attached to steel hooks fixed to the shock-proof steel plate attached underneath the elevator platform by compression springs and guided by steel rods inserting steel bushings. The shock-proof safety steel plate is retained by two fixed steel cables attached to elevator platform and to a steel hook half ring or U-Bolt mounted on the shock-proof safety steel plate.

The second emergency safety brake device is engaged when the two spur gears collides together after the compression of the springs or of any other kind of shock absorber when the set of safety cables ask to stop the free felling of the shock-proof steel plate and because the two opposite spur gears are taking two different directions onto the steel gear track or gear rack with teeth and also having then two different rotation direction; one spur gear is going down and the other spur gear is stopping its rotation. When the emergency break is applied for the elevator to stop its free falling, the safety trap on elevator floor can be lifted manually and be blocked by engaging the retainer steel arm in the corner steel angle and sided steel plate to allow the person to evacuate by the ladder bars fixed on the structure and the ladder bar underneath safety trap.

Systems, apparatuses, and methods are described for a stairlift overspeed safety system are disclosed. The overspeed safety system may include a centripetal cam assembly, a trigger assembly, and a jammer assembly. The centripetal cam assembly may include a spring-loaded plate and a plurality of centripetal cams connected to the spring-loaded plate, configured to move to an extended position when the rail speed exceeds the speed threshold. The trigger assembly may include a trigger plate configured to be pushed by at least one of the centripetal cams when moved to the extended position. Pushing the trigger plate may cause a switch to open to shut off power to the motorized stairlift. The jammer assembly may include a jammer configured to wedge between teeth of a rack and pinion of the motorized stairlift to initiate a deceleration to stop movement of the motorized stairlift.

A running system for an elevator. The running system comprises a car (21), running rails (1), and a driving mechanism, the car (21) is moved on the running mils by means of the driving mechanism, and the running system does not comprises a traction part. Further disclosed is a multi-car elevator running system: the running system is provided with a plurality of cats (21) and at least two set of running rails (1), and each set of running rails (1) can be used for the movement of line cars (21); the running system is further provided with at least one switching mechanism and driving mechanism, the car (21) is moved on the running rails (1) by means of the driving mechanism, different running rails (1) are connected by means of the switching mechanism, and the car (21) is switched to the different running rails (1) by means of the switching mechanism. By means of the configurations, the safety of the elevator during running can be enhanced, the high-speed running of the cars can be implemented, and the speed requirement of a high-rise elevator cart be satisfied.

A running system for an elevator. The running system comprises a car (21), running rails (1), and a driving mechanism, the car (21) is moved on the running mils by means of the driving mechanism, and the running system does not comprises a traction part. Further disclosed is a multi-car elevator running system: the running system is provided with a plurality of cats (21) and at least two set of running rails (1), and each set of running rails (1) can be used for the movement of line cars (21); the running system is further provided with at least one switching mechanism and driving mechanism, the car (21) is moved on the running rails (1) by means of the driving mechanism, different running rails (1) are connected by means of the switching mechanism, and the car (21) is switched to the different running rails (1) by means of the switching mechanism. By means of the configurations, the safety of the elevator during running can be enhanced, the high-speed running of the cars can be implemented, and the speed requirement of a high-rise elevator cart be satisfied.