The invention relates to a self-climbing elevator machine room for use during the construction of a building.
Elevators are needed in the construction stage of especially high-rise buildings to transport constructors and/or equipment to the floors in the building. Mechanics working on completed floors and constructors working on floors to be completed should be able to use the elevator.
A prior art jump-lift may be used in the construction stage of the building. The hoisting height of the elevator may be increased in steps of one or more floor levels each time the building has reached a predetermined height above the previous jump. The elevator machine room may be transported upwards in steps. The shaft must, however, be provided with special interfaces in this prior art arrangement. The elevator machine room is anchored to special anchoring points made beforehand to the walls of the shaft along the height of the shaft.
An object of the present invention is to present a novel self-climbing elevator machine room for use during the construction of a building.
The self-climbing elevator machine room for use during the construction of a building is defined in claim 1.
Prior art jump-lift concepts used in high-rise buildings are complex and expensive. The number of floors that cannot be serviced with the elevator car in prior art jump-lifts may be 4-5. Prior art jump-lift concepts further use intermediate platforms (crash decks) above the installation platform and below the deflection deck (provided by the building constructor) in order to prevent objects and material from falling in the shaft.
The novel arrangement will render some of the crash decks redundant. A crash deck is not needed between the two decks in the elevator machine room. The position of the deflection deck may be raised as the slip casting of the shaft proceeds.
The novel arrangement reduces the number of floors that cannot be serviced to a minimum by integrating some key functions. The self-climbing elevator machine room requires only a limited space in the vertical direction in the shaft. The self-climbing elevator machine room may thus be installed into the shaft at an early stage of the construction of the shaft and the building. The self-climbing elevator machine room may also be used near the top of the already constructed shaft. An elevator supported on the self-climbing elevator machine room may operate to a height of two landings below the top of the already constructed shaft.
The self-climbing elevator machine room may be prefabricated and assembled into a transportable module at factory premises. The produced module may then be transported to the construction site with conventional transport methods. The module may be lifted into the pit in an early stage of the construction of the shaft and the building. The use of the module may be started when the shaft has reached a height in which the elevator is needed.
There is no need for special interfaces in the walls of the shaft when the self-climbing elevator machine room according to the invention is used. The self-climbing elevator machine room may climb on the guide rails already installed. The self-climbing elevator machine room may also be locked in place in the shaft only through the guide rails and/or through fish plates associated with the guide rails in the shaft. There is no need for pockets in the shaft for the climbing and/or suspension process. The invention may be used in connection with any floor to floor distance in the building.
The self-climbing elevator machine room is re-usable. The self-climbing elevator machine room may be removed and transported to another construction site when the self-climbing elevator machine room is not any more needed at the first site.
The invention will in the following be described in greater detail by means of preferred embodiments with reference to the attached drawings, in which:
The self-climbing elevator machine room 100 is shown in a shaft 20 with guide rails 25 supported with brackets 26 on the walls 21 of the shaft 20. The guide rails 25 may be formed of guide rail elements. The opposite ends of two consecutive guide rail elements may be connected with guide rail fixing means. The guide rail fixing means may be formed of connecting elements, e.g. fish plates 27. The guide rail elements may have a certain length e.g. 5 meters. The guide rail elements may be attached with guide rail fixing means e.g. brackets 25 to the walls 21 in the shaft 20. There may be brackets 25 near both ends of the guide rail elements. The figure shows only a bottom portion of the shaft 20.
The self-climbing elevator machine room 100 may comprise two decks 110, 120. The two decks 110, 120 may be positioned upon each other in a vertical direction S1.
The lower deck 110 may be provided with upwards extending support means 140 and the upper deck 120 may be provided with downwards extending support means 150. The upwards extending support means 140 are firmly attached to the lower deck 110 and the downwards extending support means 150 are firmly attached to the upper deck 120. The support means 140, 150 extend around the guide rails 25. The support means 140, 150 may be provided with guide means 160 acting on the guide rails 25. There may be several guide means 160 along the height of the support means 140, 150. The use of several guide means 160 along the height of the support means 140, 150 will stabilize the deck 110, 120 horizontally on the guide rails 25. The outer ends of the support means 140, 150 are adjacent to each other when the vertical distance between the two decks 110, 120 is at a minimum L1 and move apart from each other when the vertical distance between the two decks 110, 120 is at a maximum L2. The support means 140, 150 may be formed of beams having a U-shaped cross-section.
The guide means 160 may be positioned within the support means 140, 150 and/or outside the support means 140, 150. Each deck 110, 120 is thus supported with guide means 160 on the guide rails 25 in the shaft 20. Each deck 110, 120 is movable in the vertical direction S1 along the guide rails 25. The guide means 160 support the decks 110, 120 on the guide rails 25 so that only movement in the vertical direction S1 along the guide rails 25 is possible.
The guide means 160 may be formed of a roller arrangement, whereby the rollers roll on the guide surfaces of the guide rails 25. The roller arrangement may correspond to a roller arrangement used in elevator cars for guiding the elevator car on the guide rails. The guide means 160 may on the other hand be formed of glide arrangement, whereby glide means glide on the guide surfaces of the guide rails 25. The glide arrangement may correspond to a glide arrangement used in elevator cars for guiding the elevator car on the guide rails.
Lifting means 130 may extend between the two decks 110, 120 in order to move the two decks 110, 120 along the guide rails 25 in relation to each other. The lifting means 130 may be formed of hydraulic actuators, e.g. telescopic cylinder means extending between the upper deck 120 and the lower deck 110. The two decks 110 are thus movably supported in relation to each other with the hydraulic actuators. The hydraulic actuators provide only the lifting force between the two decks 110, 120. Each deck 110, 120 is kept horizontally in position by the guide means 160. The telescopic cylinder means 130 may comprise two telescopic cylinders 130. The hydraulic actuators may be positioned at opposite sides of the self-climbing elevator machine room 100.
Each deck 110, 120 may further be provided with locking means 170 on opposite vertical sides of the deck 110, 120. The locking means 170 may be attached to the deck 110, 120 and act on the guide rails 25 and/or on guide rail fixing means. The guide rail fixing means may be formed of fish plates attaching the ends of guide rail elements together and/or of brackets attaching the guide rails to the walls of the shaft. The locking means 170 may grip the guide rails 25 and/or the fish plates 27 and/or the brackets 26. The locking means 170 may lock the deck 110, 120 to the guide rails 25 in the shaft 20. Embodiments of locking means 170 will be explained more in detail in connection with
The self-climbing elevator machine room 100 may further comprise a power source 200. The power source 200 may provide power to the lifting means 130, e.g. a hydraulic actuator being arranged to operate the lifting means 130. The power source 200 may be formed of a hydraulic power unit. The hydraulic power unit may comprise an electric motor driving a hydraulic pump pumping fluid from a tank. The hydraulic power unit may supply pressurized fluid to the hydraulic actuators 130. Electric power to the electric motor may be supplied with cables from the electric power network of the construction site. Another possibility would be to arrange batteries on the self-climbing elevator machine room 100.
The self-climbing elevator machine room 100 may comprise two hydraulic power units 200. A first hydraulic power unit may be positioned on the lower deck 110 and a second hydraulic power unit may be positioned on the upper deck 120. The first hydraulic power unit and the second hydraulic power unit may be connected in parallel. Each of the two hydraulic power units may thus provide pressurized fluid to the hydraulic actuators in the lifting means 130.
The self-climbing elevator machine room 100 may further comprise a safety brake attached to each deck 110, 120. The safety brake may be formed of a continuously activated one-way brake. The safety brake allows upward movement of the deck 110, 120, but prevents downward movement of the deck 110, 120. Any commercial one-way safety brake may be used.
The self-climbing elevator machine room 100 may further comprise elevator machinery 30 and all other equipment needed in an elevator on the lower deck 110.
The self-climbing elevator machine room 100 may climb stepwise along the guide rails 25 by alternatingly locking and unlocking the lower deck 110 and the upper deck 120 to the guide rails 25 with the respective locking means 170 and thereafter raising the unlocked deck 110, 120 with the lifting means 130.
The climbing procedure may start from a situation in which both decks 110, 120 are locked to the guide rails 25 with the locking means 170.
The first step in the climbing procedure comprises unlocking the upper deck 120. The second step comprises lifting the upper deck 120 upwards in the shaft along the guide rails 25. The third step comprises locking the upper deck 120 when the upper deck 120 has reached the desired destination above the lower deck 110. The fourth step comprises unlocking the lower deck 110. The fifth step comprises lifting the lower deck 110 upwards in the shaft 20 along the guide rails 25. The sixth step comprises locking the lower deck 110 when the lower deck 110 has reached a desired destination below the upper deck 120. The climbing procedure could then be repeated starting from the first step.
The vertical distance between the decks 110, 120 may vary between a minimum L1 and a maximum L2 during the climbing procedure. The vertical distance between the maximum and the minimum defines the maximum climbing step of the elevator machine room 100. The maximum climbing step may reach between two consecutive floors or between several consecutive floors in the shaft. The maximum climbing step depends on the lifting means 130.
The self-climbing elevator machine room 100 is in the figure shown in a situation in which the distance between the two decks 110, 120 is at a minimum L1. The upper position of the upper deck 120 is shown with broken lines, whereby the maximum distance L2 between the two decks 110, 120 is achieved.
Installation may be done from the upper deck 120 and maybe to a limited extent also from the lower deck 110.
The self-climbing elevator machine room 100 comprises two decks 110, 120 positioned vertically above each other. Lifting means 130 may extend between the decks 110, 120 for moving the two decks 110, 120 in the vertical direction S1 in relation to each other. Each deck 110, 120 may further comprise locking means 170 for locking and unlocking the deck 110, 120 to the guide rails and/or to the guide rail fixing means.
Each deck 110, 120 may further comprise guide means 160 for supporting the deck 110, 120 movably on the guide rails 25. The guide means 160 may be formed of roller means or glide means attached to the deck 110, 120. The roller means may roll on the guide surfaces of the guide rails 25. The glide means may glide on the guide surfaces of the guide rails 25.
The self-climbing elevator machine room 100 may further comprise elevator machinery 30 and other equipment needed in an elevator. The elevator machinery may comprise a drive, a motor, a traction sheave, a machinery brake, and hoisting ropes. The figure shows further a cable drum 31 for the electrical cable of the elevator car and rope drums 32 for the hoisting ropes of the elevator.
The self-climbing elevator machine room 100 may further comprise two hydraulic power units 200. A first hydraulic power unit 201 may be positioned on the lower deck 110 and a second hydraulic power unit 202 may be positioned on the upper deck 120. The first hydraulic power unit 201 and the second hydraulic power unit 202 may be connected in parallel. Each of the two hydraulic power units 201, 202 may thus provide pressurized fluid to the lifting means 130 i.e. to both telescopic cylinders 130.
The self-climbing elevator machine room 100 may further comprise a safety brake 500 attached to each deck 110, 120. The safety brake 500 may be formed of a continuously activated one-way brake. The safety brake 500 allows upward movement of the deck 110, 120, but prevents downward movement of the deck 110, 120. Any commercial one-way safety brake 500 may be used.
The self-climbing elevator machine room 100 may also be used during the installation of the elevator in the shaft. The upper deck 120 may be used as an installation deck. The installation may be done manually and/or automatically from the upper deck 120. Mechanics and/or robots may work on the upper deck 120.
The figure shows a portion of the lower deck 110, the first hydraulic power unit 201 and the cable drum 31 on the first deck 110. The cable drum 31 is needed in order to provide lengthening of the car cable as the machinery room climbs stepwise upwards in the shaft.
The figure shows further a safety brake 500 attached to each deck 110, 120. The safety brake 500 may be formed of a continuously activated one-way brake. The safety brake 500 allows upward movement of the deck 110, 120, but prevents downward movement of the deck 110, 120. Any commercial one-way safety brake 500 may be used.
The figure shows further a further safety brake 510 attached to each deck 110, 120. The further safety brake 510 may also be formed of a continuously activated one-way brake. The further safety brake 510 allows upward movement of the deck 110, 120, but prevents downward movement of the deck 110, 120. Any commercial one-way further safety brake 510 may be used. The further safety brake 510 could be chain blocker type safety brake.
The figure shows a portion of the lower deck 110 and the hoisting rope drums 32. The hoisting rope drums 32 may be driven by a worm screw and cogged wheels as is seen in the figure. The hoisting rope drums 32 are needed in order to provided lengthening of the hoisting ropes as the machine room climbs stepwise higher in the shaft.
The first locking means 170 is formed of brake means 180. The brake means 180 may comprise a frame 181 with a slit for the guide rail 25 and two wedge shaped brake shoes 182 positioned on opposite sides of the guide rail 25. The brake shoes 182 may be movably supported from the wedge surface with rollers 183 on the frame 181. A spring 184 may be positioned between a first end of the brake shoe 182 and the frame 181. A second opposite end of the brake shoe 182 may be supported on a slide 185 acting in a cylinder 186.
A hydraulic power unit 210 may provide power to the brake means 180. The hydraulic unit 210 may comprise an electric motor 211, a hydraulic pump 212 and a tank 250. The hydraulic pump 212 pumps oil from the oil reservoir 250 to the cylinders 186 in order to move the slides 185 in the cylinders 186.
Supplying pressurized fluid to the plungers 185 in the cylinders 186 will press the brake shoes 182 downwards in the figure against the force of the springs 184. The brake shoes 182 are thus moved away from the guide surfaces of the guide rail 25. The deck 110, 120 is thus free to move on the guide rails 25.
Extracting pressurized fluid from the cylinders 186 will allow the brake shoes 182 to move upwards in the figure due to the force caused by the springs 184 acting on the second end of the brake shoe 182. The brake shoes 182 are thus moved into contact with the guide surfaces of the guide rail 25. The deck 110, 120 will thus become locked to the guide rails 25.
The hydraulic unit 210 may be provided only for the brake means 180. Another possibility is to have a common main hydraulic unit on the self-climbing elevator machine room 100 for all equipment needing hydraulic power on the self-climbing elevator machine room 100. Hydraulic valves may be used to connect the different equipment to the common main hydraulic power unit.
The brake means 180 may as an alternative be operated electromechanically. An electromechanical device may be used to press the brake shoes 182 against the force of the springs 184. Deactivation of the electromechanical device will activate the brake shoes 182 against the guide rails 25.
The second locking means 170 is formed of anchoring means 190. The anchoring means 190 may comprise a frame 191 supported on the deck 110, 120 and two claws 192 positioned on opposite sides of the guide rail 25. The claws 192 may be supported via a first articulated joint J1 on the frame 191. An actuator may be attached to the claws 192 on an opposite side of the first articulated joint J1 (not shown in the figure). The actuator may rotate the claws 192 around the first articulated joint J1 between a locked position in which the claws 192 are seated on an upper support surfaces 27A of the fish plates 27 and an unlocked position in which the claws are rotated in a clockwise direction and thereby removed from contact with the fish plate 27.
The actuator may be formed of a hydraulic cylinder or of an electromechanical device. The claws 192 could be operated by an electric motor or by one or more electromechanical devices.
The deck 110, 120 becomes supported on the fish plate 27 in the locked position of the anchoring means 190. The support on the fish plate 27 eliminates downward movement of the deck 110, 120. The deck 110, 120 is free to move on the guide rails 25 in the unlocked position of the anchoring means 190.
The fish plates 27 are normally positioned in the joint between two consecutive guide rail elements. Additional fish plates 27 could be positioned along the length of the guide rail elements. The guide rail element could be provided with intermediate fish plates 27 attached to the guide rail elements already before the installation of the guide rail elements. A fish plate 27 could e.g. be positioned in the middle of a 5 m long guide rail element. The intermediate fish plates 27 could be left on the guide rails permanently after the installation. Another possibility would be to remove the intermediate fish plates as the installation proceeds upwards.
The fish plate 27 may be wider than the guide rail 25 so that the upper surface of the fish plate 27 forms an upper support surface 27A for the claw 192 on each side of the guide rail 25. The construction of the fish plates 27 may thus be adapted to work as support points for the claws 192 in the anchoring means 190.
The fish plate 27 is an example of a connection element that may be used to connect the ends of consecutive guide rail elements.
A similar anchoring means 190 could be used to lock the deck 110, 120 to the brackets 26 attaching the guide rails 25 to the walls 21 in the shaft 20. The claws 192 could then interact with brackets 26.
The second lifting means could be formed as an articulated jack 600. A middle portion of two support arms 610, 620 could be connected via an articulated joint J31. The upper end of each support arm 610, 620 may be supported via articulated joint J21, J22 on the upper deck 120. The lower end of each support arm 610, 620 may be supported via an articulated joint J11, J12 on the lower deck 110. Each of the articulated joints J11, J12 at the lower deck 110 and each of the articulated joints J21, J22 at the upper deck 120 should be arranged so that movement of the ends of the support arms 610, 620 in the horizontal direction is allowed, but movement in the vertical direction is prevented.
An actuator 630 may be provided on the lower deck 110. The actuator may be connected to a rod 640 passing in a horizontal direction along the lower deck 110. The rod 640 may be formed as a worm.
The lower end of the first support arm 610 could be attached via a shaft 640 to an actuator 630. The lower end of the first support arm 610 may be provided with articulated joint cooperating with the worm screw 640. The worm screw 640 may be attached via joint parts to the lower end portions of the support arms 610, 620. The outer ends of the worm screw 640 may be supported on the lower deck 110.
Rotation of the actuator 630 in a first direction will move the lower ends of the support arms 610, 620 towards each other, whereby the lower deck 110 and the upper deck 120 is moved in a direction away from each other. Rotation of the actuator 630 in a second opposite direction will move the lower ends of the support arms 610, 620 away from each other, whereby the lower deck 110 and the upper deck 120 is moved in a direction towards each other. The lower deck 110 and the upper deck 120 may thus be lifted alternatingly upwards with the actuator 630.
The lower deck 110 may be locked to the guide rails, whereby the unlocked upper deck 120 may be lifted by rotating the actuator 630 in the first direction. The upper deck 120 may thereafter be locked to the guide rails, whereby the lower deck 110 may be lifted by rotating the actuator 630 in the second direction.
The actuator 630 may be formed of a motor, e.g. an electric motor rotating the worm screw 640. A pair of articulated jacks 600 may be used i.e. one articulated jack 600 may be positioned at each side edge of the decks 110, 120.
The articulated jack 600 could as an alternative be operated by a hydraulic cylinder-piston apparatus. The cylinder-piston apparatus could extend between the lower deck 110 and an upper portion of either support arm 610, 620. The articulated jack 600 could also comprise several layers of crosswise running support arms stacked upon each other.
The third lifting means 700 could be realized with ropes and pulleys. Two parallel support structures 710, 720 may extend between the first deck 110 and the second deck 120. The two support structures 710, 720 may be positioned at a horizontal distance from each other. Each of the support structures 710, 720 may comprise an inner support bar 711, 721 and an outer support bar 712, 722. The inner support bar 711, 721 is positioned inside the outer support bar 712, 722. The inner support bar 711, 721 may be locked to the outer support bar 712, 722 with a form lock so that the inner support bar 711, 721 may move in the longitudinal direction in relation to the outer support bar 712, 722. The lower end of the outer support bar 712, 722 may be attached to the lower deck 110 and the upper end of the inner support bar 711, 721 may be attached to the upper deck 120.
A first shaft 731 may extend in a horizontal direction between the lower end portions of the inner support bars 711, 721. Each end of the first shaft 731 may be attached to a lower end of a respective inner support bar 711, 721. A second shaft 732 may extend in a horizontal direction between the lower end portions of the outer support bars 712, 722. Each end of the second shaft 732 may be attached to a lower end of a respective outer support bar 712, 722. The first shaft 731 and the second shaft 732 may be positioned on opposite sides of the two support structures 710, 720. A third shaft 733 may extend between the upper end portions of the outer support bars 712, 722. Each end of the third shaft 733 may be attached to an upper end of a respective outer support bar 712, 722.
A first pulley 741 may be positioned between the two support structures 710, 720. The first pulley 741 may be rotatably supported on the third shaft 733. The first pulley 741 is thus stationary in relation to the outer support bars 712, 722. A second pulley 742 may be positioned between the two support structures 710, 720. The second pulley 742 may be rotatably supported on the second shaft 732. The second pulley 742 is thus stationary in relation the outer support bars 712, 722.
A first end of a rope 750 may be fixed in a first fixing point P1 to the first shaft 731. The rope 750 may pass from the first fixing point P1 upwards to the first pulley 741. The rope 750 may then turn around the first pulley 741 and pass downwards to the second pulley 742. The rope 750 may then turn around the second pulley 742 and pass upwards through a lifting apparatus 760 supported on the lower deck 110. A second end of the rope 750 may be free.
The lifting apparatus 760 may be a man riding hoist. The lifting apparatus 760 may comprise traction rolls positioned on opposite sides of the rope 750. The traction rolls may be driven by one or more motors, e.g. electric motors. Rotation of the traction rolls in a first direction will pull the rope 750 upwards through the lifting apparatus 760. Rotation of the traction rolls in a second opposite direction will move the rope 710 in a second opposite direction downwards through the lifting apparatus 760. The traction rolls will thus control the movement of the rope 750 through the lifting apparatus 760.
The decks 110, 120 are shown in a position in which the vertical distance between the lower deck 110 and the upper deck 120 is at a minimum.
The lower deck 110 may first be locked to the guide rails, whereby the upper deck 120 is unlocked. The lifting apparatus 730 may now start to pull the rope 710 in the first direction upwards through the lifting apparatus 760. The first end of the rope 750 is attached to the first shaft 731, which is attached to the lower ends of the inner support bars 711, 721. The inner support bars 711, 721 will thus start to move upwards, whereby also the upper deck 120 starts to move upwards in relation to the stationary lower deck 110. The vertical distance between the lower deck 110 and the upper deck 120 will be at a maximum when the first shaft 731 is at a distance below the first pulley 741. The first shaft 731 may be raised to a position below the outer circumference of the first pulley 741. There should be overlapping between the inner support bars 711, 721 and the outer support bars 712, 722 also in the position in which the distance between the decks 110, 120 is at a maximum.
The upper deck 120 may then be locked to the guide rails, whereby the lower deck 110 is unlocked. The lifting apparatus may now start to pull the rope 750 in a second opposite direction downwards through the lifting apparatus 760. The lower deck 110 will start to move upwards, whereby the outer support bars 712, 722 move upwards along the inner support bars 711, 721. The lower deck 110 moves upwards until the first support point P1 is again in the position near the lower deck 110. We thus end up in the situation shown in the figure where the vertical distance between the decks 110, 120 is at a minimum.
The shafts 731, 732, 733 may be stationary and the pulleys 741, 742 may be rotatably attached to the shafts 732, 733.
The lifting means 800 is on the left hand side of
The lifting means 800 is formed of a support structure 805 comprising three support bars 810, 820, 830 that are movably supported on each other. The third support bar 830 may be supported with a first form locking within the second support bar 820. The second support bar 820 may be supported with a second form locking within the first support bar 810. The third support bar 830 may move in the longitudinal direction in relation to the second support bar 820. The second support bar 820 may move in the longitudinal direction in relation to the first support bar 810. The form locking of the support bars 810, 820, 830 is shown in
The movement of the support bars 810, 820, 830 in relation to each other is done with cogged belts or chains 851, 852 and cogwheels 841A, 841B, 842A, 842B, 843A, 843B, 844A, 844B, 845A, 845B. The cogged belts or chains 851, 852 may be driven by an actuator 860. The actuator 860 may be a motor, e.g. an electric motor.
A first cogged belt or chain 851 may be positioned on a first side of the support structure 805 and a second cogged belt or chain 852 may be positioned on a second opposite side of the support structure 805.
The first cogged belt or chain 851 may pass in a closed loop over cogwheels 841A, 842A, 843A, 844A and 845A on a first side of the support structure 805. The second cogged belt or chain 852 may pass in a closed loop over cogwheels 841B, 842B, 843B, 844B and 845B on a second side of the support structure 805. The cogwheels on opposite sides of the support structure 805 may be arranged in pairs. The cogwheels in each pair of cogwheels being positioned opposite each other so that the centre axis of the shafts of the cogwheels coincide. Each cogwheel may be rotatably supported on a shaft, whereby the shaft is stationary and attached to the support structure 805. The other possibility is that each cogwheel is fixed to the shaft and the shaft is rotatably attached to the support structure 805.
The first cogwheel 841A on the first side of the support structure 805 and the first cogwheel 841B on the second opposite side of the support structure 805 may be connected to each other with a first shaft 831. The first shaft 831 may further be connected to an actuator 860. The actuator 860 may be a motor, e.g. an electric motor. The motor 860 may drive the two cogged belts or chains 851, 852 in synchronism. The first shaft 831 may pass through a lower end portion 811 of the first support bar 810. The first shaft 831 may be rotatably supported on the lower end portion 811 of the first support bar 810. Said lower end portion 811 of the first support bar 810 may be attached to the lower deck 110. The upper end of the third support bar 830 may be attached to the upper deck 120.
The first pair of cogwheels 841A, 841B are thus stationary in relation to the first support bar 810. The second pair of cogwheels 842A, 842B are supported on the upper end of the second support bar 820. The third pair of cogwheels 843A, 843B are supported on the lower end of the second support bar 820. The fourth pair of cogwheels 844A, 844B are supported on the upper end of the first support bar 810. The fifth pair of cogwheels 845A, 845B are supported on the lower end 811 of the first support bar 810. The fifth pair of cogwheels 845A, 845B are thus stationary. A lower end of the third support bar 830 is further attached via a second shaft 832 to both cogged belts or chains 851, 852.
When the motor 860 is rotated in a first clockwise direction, then the second support bar 820 and the third support bar 830 will move upwards as shown on the left hand in
When the motor 860 is rotated in a second, counter clockwise direction, then the second support bar 820 and the third support bar 830 will move downwards and return to the position shown on the right hand in
This third lifting means 800 may be modified so that two parallel support structures 805 positioned at a distance from each other e.g. at opposite edges of the decks 110, 120 are used. Each support structure 805 may comprise three support bars 810, 820, 830. The two support structures 805 could be connected to each other with shafts or profiles. Corresponding cogwheels 841A, 842A, 843A, 844A, 845A could be provided on a middle portion of the shafts or profiles. The drive could then be realized with one cogged belt or chain.
The lifting means 130 could as a further alternative be realized with a screw mechanism operated by an actuator. The actuator could be a motor, e.g. an electric motor. Gear racks, pinions and worm screws could be used in the screw mechanism.
The decks 110, 120 may in each embodiment of the invention comprise guide means 160 for supporting the deck 110, 120 movably on the guide rails 25 and locking means 170 for locking and unlocking the deck 110, 120 to the guide rails 25 and/or to guide rail fixing means 26, 27.
The at least one power source 200 may be formed of a hydraulic power unit comprising an electric motor, a hydraulic pump and a tank. The at least one power source 200 may on the other hand be formed of one or more motors providing power via a rotating shaft, e.g. a hydraulic motor or an electric motor. The one or more motors may provide power to the lifting apparatus 130.
The use of the invention is not limited to any specific elevator type. The invention can be used in connection with any type of elevator e.g. also in elevators lacking a machine room and/or a counterweight. The counterweight could be positioned on the back wall of the shaft or on either side wall of the shaft or on both side walls of the shaft.
It will be obvious to a person skilled in the art that, as the technology advances, the inventive concept can be implemented in various ways. The invention and its embodiments are not limited to the examples described above but may vary within the scope of the claims.
Number | Date | Country | Kind |
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19206416.0 | Oct 2019 | EP | regional |
This application is a continuation of PCT International Application No. PCT/EP2020/080383 which has an International filing date of Oct. 29, 2020, and which claims priority to European patent application number 19206416.0 filed Oct. 31, 2019, the entire contents of both of which are incorporated herein by reference.
Number | Date | Country | |
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Parent | PCT/EP2020/080383 | Oct 2020 | US |
Child | 17709949 | US |