JP7144905B1 - Elevator for lift extension type construction - Google Patents

Abstract

A lift extension type construction elevator capable of balancing the tension of a plurality of suspension bodies and suppressing damage to the suspension bodies or equipment supporting the suspension bodies is provided. A lifting height extension type construction elevator includes a machine room unit 3 lifted against a building, a plurality of rope drums 6 mounted on the machine room unit 3, and a plurality of ropes 5 wound around, a second diverting pulley 13 that is lifted independently of the machine room unit 3, each of the plurality of ropes 5 being wound on a corresponding one of the plurality of rope drums 6; , Each rope drum 6 is provided with a rotation suppressing device 21, and each rotation suppressing device 21 allows the rotation of the rope drum 6 when the rotational torque acting on the rope drum 6 exceeds a set value. , the rotation of the rope drum 6 is suppressed when the rotational torque is equal to or less than a set value. [Selection drawing] Fig. 1

Description

TECHNICAL FIELD The present disclosure relates to a lifting height extension type construction elevator.

Patent Literature 1 discloses a rope feeding device for a construction elevator. The rope payout device includes a frame and a plurality of drum holders mounted on the frame. Each drum holder holds a drum wound with a rope for suspending the cage. A stopper bolt is provided between the frame and the drum holder to prevent rotation of the drum holder and the drum. When the rope is paid out, the stopper bolt is removed. When the required amount of rope has been paid out, a stopper bolt is installed to prevent rotation of the drum.

Patent Literature 2 discloses a lift extension type construction elevator different from the construction elevator described above. This lift extension type construction elevator has a machine room unit capable of ascending and descending a hoistway. A machine room unit is equipped with a hoist and a plurality of rope drums. The ropes let out from each rope drum pass through a plurality of turn-changing pulleys and are wound around the hanger of the cage. Each rope is wrapped around a cage sling and then a hoist sheave. Each rope is wrapped around the sheave of the hoist and then around the wheel of the counterweight. Each rope is connected to the machine room unit after being wrapped around a counterweight sling.

One diverting pulley of the plurality of diverting pulleys is vertically movable in the hoistway independently of the machine room unit. When extending the car lift stroke, only the one diverting pulley is lifted before the machine room unit and the car are lifted. When only the one diverting pulley is raised, the rope is paid out from the rope drum. Thereafter, the machine room unit and the car are raised, thereby extending the lift stroke of the car.

JP 2005-82256 A Japanese Patent No. 6750754

Assuming that the rope feeding device of Patent Document 1 is applied to the lift extension type construction elevator of Patent Document 2, it is conceivable that the following procedure is performed when extending the lifting stroke of the car.

First, the stopper bolt is removed from each of the plurality of drum holders. This allows rotation of each rope drum. The diverting pulley is then lifted before the machine room unit and car are lifted. Thereby, the rope is let out from each rope drum. A stopper bolt is then attached to each drum holder. This prevents rotation of each rope drum. The machine room unit and car are then lifted.

However, when the machine room unit is lifted, if each rope drum is blocked from rotating as described above, the tension in the multiple ropes will not be balanced and one rope of the multiple ropes will be unbalanced. Some of the tension of other ropes may be transferred. In this case, since the tension of one rope increases, there is a problem that the rope or the equipment supporting the rope may be easily damaged.

The present disclosure has been made in order to solve the above-described problems, and is a lifting extension construction method that can balance the tension of a plurality of suspension bodies and suppress damage to the suspension bodies or equipment that supports the suspension bodies. Intended to provide an elevator.

A lifting height extension type construction elevator according to the present disclosure includes a machine room unit that lifts against a building, a plurality of suspension drums mounted on the machine room unit, and a plurality of suspensions wound around, a turning device that is lifted independently of the machine room unit, each of said plurality of suspensions being wrapped around a corresponding one of said plurality of suspension drums; The suspension drum is provided with a rotation suppressing device, and each of the rotation suppressing devices allows the suspension drum to rotate when the rotational torque acting on the suspension drum exceeds a set value. and, when the rotational torque is equal to or less than the set value, the rotation of the suspension drum is suppressed.

ADVANTAGE OF THE INVENTION According to this disclosure, the tension of a plurality of suspension bodies can be balanced, and damage to the suspension bodies or equipment supporting the suspension bodies can be suppressed.

1 is a schematic diagram showing a configuration of a lift extension type construction elevator according to Embodiment 1. FIG. FIG. 2 is a perspective view showing the configuration of the rope drum and the rotation suppressing device of the lift extension type construction elevator according to Embodiment 1; 1 is an exploded perspective view showing a configuration of a rotation suppressing device for a lift extension type construction elevator according to Embodiment 1. FIG. FIG. 2 is a front view showing a structural example of a machine room unit of the lift extension type construction elevator according to Embodiment 1; 5 is a partial side view of the machine room unit shown in FIG. 4; FIG.

Embodiment 1.
A lift extension type construction elevator according to Embodiment 1 will be described. A lifting height extension type construction elevator is an elevator in which the ascending/descending stroke of a car is sequentially extended in accordance with the progress of construction work. FIG. 1 is a schematic diagram showing the configuration of a lifting height extension type construction elevator according to the present embodiment. FIG. 1 shows the interior of a hoistway in a building under construction. The up-down direction in FIG. 1 represents the vertical up-down direction.

The first elevator 1 is one of an elevator car and a counterweight. The second elevator 2 is the other of the elevator car and the counterweight. FIG. 1 illustrates a case where the first lifting body 1 is a car and the second lifting body 2 is a counterweight. In this case, the first elevator 1 can ascend and descend the hoistway along a pair of car guide rails (not shown). In this case, the second elevator 2 can ascend and descend the hoistway along a pair of counterweight guide rails (not shown).

The load of the second elevator 2 can be supported in the lower part of the hoistway. The second lifting body 2 is placed, for example, on a shock absorber provided in the pit. The second lifting body 2 may be adapted to be fixed to the guide rail for the car or the guide rail for the counterweight. The second lifting body 2 may be adapted to be fixed to a building-side structure under construction.

The machine room unit 3 is a temporary machine room arranged above the first lifting body 1 and the second lifting body 2 . The machine room unit 3 is lifted with respect to the building by the first lifting device 12 . By being lifted by the first lifting device 12, the machine room unit 3 can ascend and descend the hoistway along at least one of the car guide rail and the counterweight guide rail. The machine room unit 3 can be fixed to a car guide rail, a counterweight guide rail, or a structure on the side of the building under construction. The machine room unit 3 is equipped with a hoist 15 , a control panel (not shown), and a plurality of rope drums 6 . A plurality of ropes 5 are wound around the sheave 4 of the hoist 15. - 特許庁

The machine room unit 3 is provided with, for example, two or more turning devices. In this embodiment, a first direction change pulley 8, a second direction change pulley 13, a third direction change pulley 14, and a fourth direction change pulley 9 are provided as four direction change devices. Each of the first direction change pulley 8 , the second direction change pulley 13 , the third direction change pulley 14 , and the fourth direction change pulley 9 is provided above the hoist 15 . A plurality of ropes 5 are wound around each of the first diverting pulley 8 , the second diverting pulley 13 , the third diverting pulley 14 , and the fourth diverting pulley 9 .

In this embodiment, a pulley is used as the direction changing device. It doesn't have to be.

Each of the multiple ropes 5 is wound around a corresponding one of the multiple rope drums 6 . Each rope drum 6 is configured to let out a rope 5. - 特許庁The number of rope drums 6 corresponds to the number of ropes 5 used in the elevator. For example, if six ropes 5 are used in the elevator, six rope drums 6 are provided. The ropes 5 preliminarily wound around each rope drum 6 have a length that can correspond to the lifting stroke of the car when the building is completed. Each rope drum 6 is provided with a rotation suppressing device 21, which will be described later.

The machine room unit 3 is provided with a coupling device 7 and a rope gripping device 10 . The connecting device 7 and the rope gripping device 10 are installed, for example, at positions overlapping the first lifting body 1 when viewed in the vertical direction. When viewed in the vertical direction, the coupling device 7 and the rope gripping device 10 are installed, for example, near the car guide rail or the counterweight guide rail.

The connecting device 7 can suspend the first lifting body 1 . The coupling device 7 is, for example, a device having a lifting function such as a chain block or a winch. The load of the first lifting body 1 is supported by the machine room unit 3 while the first lifting body 1 is suspended by the connecting device 7 .

The rope gripping device 10 can grip, for example, the rope 5 in a sandwiched manner. The rope gripping device 10 can grip at least the same number of ropes 5 as the number of rope drums 6, one at a time or a plurality of ropes simultaneously.

The 1st direction change pulley 8 is provided near the rope drum 6, for example, and receives the rope 5 let out from each rope drum 6 initially. The 1st direction change pulley 8 may be arranged to the rope drum 6 anywhere above, below, left and right. In the example shown in FIG. 1 , the first direction change pulley 8 is arranged above the rope drum 6 . The first diverting pulley 8 is fixed, for example, to the framework of the machine room unit 3 .

The role of the first direction change pulley 8 is to change the direction of the rope 5 and to guide the rope 5 so as not to interfere with other equipment. When the rope 5 is let out from each rope drum 6 , the rope 5 reciprocates in the axial direction of the rope drum 6 . By providing a first diverting pulley 8 near the rope drum 6, the range of movement of the rope 5 is limited.

The second diverting pulley 13 is a movable diverting device. The second direction change pulley 13 is lifted independently of the machine room unit 3 by the second lifting device 30 . The second direction-changing pulley 13 is pulled up from the machine room unit 3 by being lifted by the second lifting device 30 . The second diverting pulley 13 is guided, for example, by at least one of a car guide rail and a counterweight guide rail. The second diverting pulley 13 can be fixed to the machine room unit 3 or to a structure within the hoistway. Structures within the hoistway include, for example, guide rails for cars, guide rails for counterweights, and structures on the side of a building under construction.

The role of the second diverting pulley 13 is to divert the ropes 5 and to allow the ropes 5 to be withdrawn from each rope drum 6 before the machine room unit 3 is lifted. That is, when extending the elevator stroke of the car, the second direction change pulley 13 is pulled up before the machine room unit 3 is pulled up.

If the provision of the second direction change pulley 13 prevents the rope 5 from interfering with other devices in the machine room unit 3 without the first direction change pulley 8, the first direction change pulley 8 is not provided. It does not have to be

The 3rd direction change pulley 14 is provided so that the rope 5 between the 2nd direction change pulley 13 and the 4th direction change pulley 9 may pass. The third diverting pulley 14 is fixed to the framework of the machine room unit 3, for example. For example, the third direction change pulley 14 is provided on the second lifting body 2 side with respect to the sling cable of the first lifting device 12 when viewed in the vertical direction.

The fourth direction-changing pulley 9 is installed, for example, at a position overlapping the first lifting body 1 when viewed along the vertical direction. The fourth direction-changing pulley 9 is installed, for example, in the horizontal direction near between a pair of car guide rails or between a pair of counterweight guide rails. The fourth diverting pulley 9 is fixed, for example, to the framework of the machine room unit 3 .

The role of the fourth direction change pulley 9 is to change the direction of the rope 5 and to determine the position where the rope 5 is lowered vertically toward the suspension wheel of the first lifting body 1 . The fourth diverting pulley 9 is mainly arranged above the hanging wheel of the first lifting body 1 . If the fourth direction change pulley 9 can also serve as the third direction change pulley 14, the third direction change pulley 14 may not be provided.

A rope 5 let out from each rope drum 6 is first wound around a first direction change pulley 8 . Each rope 5 is wound around a second direction change pulley 13 after being wound around a first direction change pulley 8 . Each rope 5 is wound around a second direction change pulley 13 and then wound around a third direction change pulley 14 . Each rope 5 is wound around a fourth direction change pulley 9 after being wound around a third direction change pulley 14 .

Each rope 5 is passed through a rope gripping device 10 after being wound around a fourth turning pulley 9 . Each rope 5 is passed through the rope gripping device 10 and then wound around the hanging wheel of the first lifting body 1 . Each rope 5 is wound around the hanging wheel of the first lifting body 1 and then around the sheave 4 of the hoisting machine 15 .

Each rope 5 is wound around the pulley 4 of the hoisting machine and then around the suspension wheel of the second lifting body 2 . Each rope 5 is connected to the machine room unit 3 after being wound around the hanging wheel of the second lifting body 2 . The ends of each rope 5 are connected to the machine room unit 3, for example, by individual shackles. The shackle-side rope terminal 11 is positioned at the lower end of the machine room unit 3, for example.

The rope gripping device 10 is capable of gripping the rope 5 located between the rope drum 6 and the sling wheel of the first lifting body 1 . When the first lifting body 1 is not suspended by the connecting device 7 and the rope 5 is gripped by the rope gripping device 10, the load of the first lifting body 1 and the second lifting body 2 is applied to the rope 5. . When the hoist 15 is driven in this state, the first elevator 1 and the second elevator 2 move in a range below the machine room unit 3 in the hoistway of the building under construction. This range is the lifting stroke of the first lifting body 1 and the second lifting body 2 at that time. The hoist 15 is controlled by, for example, a control panel mounted in the machine room unit 3 .

The elevating strokes of the first elevating body 1 and the second elevating body 2 are extended according to the progress of the construction work by repeating the lifting height extension operation described later.

(Rotation suppressing device)
The rotation suppressing device 21 provided on each rope drum 6 will be described. A rotational torque acts on the rope drum 6 due to the tension of the rope 5 . The rotation suppressing device 21 is configured to allow the rotation of the rope drum 6 when this rotational torque exceeds a set value, and to suppress the rotation of the rope drum 6 when this rotational torque is equal to or less than the set value. ing. The rotation suppressing device 21 is, for example, a torque applying device that applies braking torque to the rope drum 6 .

FIG. 2 is a perspective view showing the configuration of the rope drum and the rotation suppressing device of the lift extension type construction elevator according to the present embodiment. FIG. 3 is an exploded perspective view showing the configuration of the rotation suppressing device for the lift extension type construction elevator according to the present embodiment.

Each rope drum 6 has a cylindrical portion 6a and a pair of drum flange portions 6b, 6c. A rope 5 is wound around the cylindrical portion 6a. The drum flange portion 6b is fixed to one axial end of the cylindrical portion 6a. The drum flange portion 6c is fixed to the other axial end of the cylindrical portion 6a. Each of the drum flange portions 6b and 6c is formed in a disc shape. Each of the drum flange portions 6b, 6c has a diameter larger than the diameter of the cylindrical portion 6a.

A rotating shaft 27 is fixed to the rope drum 6 . The rotating shaft 27 is a shaft member passing through the center of the rope drum 6 . The rotating shaft 27 rotates together with the rope drum 6 . The rotary shaft 27 has a supported portion 27a provided on one end side and a supported portion 27b provided on the other end side. Further, the rotary shaft 27 has an end portion 27c that extends further toward one end than the supported portion 27a.

A supported portion 27a of the rotating shaft 27 is supported by a bearing 29a. A supported portion 27b of the rotary shaft 27 is supported by a bearing 29b. The bearings 29 a and 29 b are fixed to the frame 28 . Thereby, the rotary shaft 27 is rotatably supported by the frame 28 via the bearings 29a and 29b. The frame 28 is fixed to the framework of the machine room unit 3 .

The end portion 27c of the rotating shaft 27 has a smaller diameter than the supported portion 27a. An annular step surface 27d is formed between the supported portion 27a and the end portion 27c. A male threaded portion 27e is formed on the end portion 27c.

A rotation suppressing device 21 is attached to the end portion 27 c of the rotating shaft 27 . The rotation suppressing device 21 has a first friction plate 23 a , a flange 22 , a second friction plate 23 b , a disc spring 24 and an adjustment nut 25 . The 1st friction board 23a, the flange 22, the 2nd friction board 23b, the disk spring 24, and the adjustment nut 25 are arrange|positioned in this order from the rope drum 6 side. Each of the first friction plate 23a, the flange 22, the second friction plate 23b, and the disc spring 24 is formed with a through hole through which the end portion 27c passes. A male threaded portion 27 e is fitted in the adjusting nut 25 .

The first friction plate 23 a faces one surface of the flange 22 . The second friction plate 23 b faces the other surface of the flange 22 . The first friction plate 23a and the second friction plate 23b are preferably made of a material having excellent wear resistance.

An arm 26 is fixed to the flange 22 . Arm 26 is in contact with upper surface 28 a of frame 28 . This restricts the rotation of the arm 26 and the flange 22 around the rotation shaft 27 .

The first friction plate 23 a , the flange 22 , the second friction plate 23 b and the disc spring 24 are sandwiched between the step surface 27 d and the adjustment nut 25 . When the adjusting nut 25 is tightened on the rotating shaft 27, the disc spring 24 is compressed. The amount of compression of the disc spring 24 is adjusted by an adjusting nut 25 .

The compressive load of the disk spring 24 acts on the first friction plate 23a, the flange 22 and the second friction plate 23b. As a result, the first friction plate 23 a is pressed against one surface of the flange 22 and a frictional force is generated between the first friction plate 23 a and the flange 22 . Also, the second friction plate 23b is pressed against the other surface of the flange 22, and a frictional force is generated between the second friction plate 23b and the flange 22. As shown in FIG. Further, the first friction plate 23a is pressed against the step surface 27d, and the second friction plate 23b is pressed against the disc spring 24. As shown in FIG.

When the rope drum 6 and the rotating shaft 27 rotate, the frictional force between the first friction plate 23a and the flange 22 and the frictional force between the second friction plate 23b and the flange 22 cause the rotating shaft 27 to move the flange 22 and Torque is transmitted to the arm 26 . Since the arm 26 is in contact with the upper surface 28 a of the frame 28 , the torque transmitted to the arm 26 is received by the frame 28 . A reaction force of this torque acts on the rotating shaft 27 . Thereby, braking torque always acts on the rotating shaft 27 and the rope drum 6 .

In this embodiment, the rotation suppressing device 21 is attached to the rotating shaft 27 . Therefore, the structure can be simplified and stable braking torque can be applied to the rope drum 6 . However, the rotation suppressing device 21 may be attached to other portions of the rope drum 6 as long as the braking torque can be applied to the rope drum 6 . For example, the rotation suppressing device 21 may be attached to the drum flange portion 6 b or the drum flange portion 6 c of the rope drum 6 .

(Lift extension operation)
When extending the elevating stroke of the first elevating body 1 and the second elevating body 2, that is, the lifting height of the hoist 15, first, the first elevating body 1 and the machine room unit 3 are connected by the connecting device 7. Thereby, the load of the first lifting body 1 is supported by the machine room unit 3 via the connecting device 7 . The load of the second elevator 2 is supported at the bottom of the hoistway. That is, the elongation of the elevating stroke is performed in a state where the load of the first elevating body 1 and the second elevating body 2 is not applied to the rope 5 .

The lifting stroke is extended by lifting the machine room unit 3 and the first lifting body 1 using the first lifting device 12 while the rope 5 is not gripped by the rope gripping device 10 . The first lifting device 12 is, for example, a tower crane or a winch. The lifting of the machine room unit 3 and the first lifting body 1 is performed in a state in which the sling cable of the first lifting device 12 catches the center of gravity of the object to be lifted for safety reasons.

In this embodiment, when extending the lifting stroke, the second direction change pulley 13 is pulled up from the machine room unit 3 before the machine room unit 3 and the first lifting body 1 are pulled up. Pulling up of the second direction change pulley 13 is performed using a second lifting device 30 separate from the first lifting device 12 . The second lifting device 30 is, for example, a winch. The second lifting device 30 is installed above the position that is planned as the next fixing position of the machine room unit 3 . The second direction change pulley 13 is pulled up together with the plurality of ropes 5 wound around the second direction change pulley 13 .

Pulling up of the second direction change pulley 13 is performed while the plurality of ropes 5 are gripped by the rope gripping device 10 . When the second direction change pulley 13 is pulled up from the machine room unit 3 in this state, the ropes 5 are let out from the rope drums 6 . Each rope 5 passes through a first direction change pulley 8 and a second direction change pulley 13 and is let out by a predetermined length. The raised second diverting pulley 13 is fixed to a structure in the hoistway, for example, near the next fixed position of the machine room unit 3 .

After that, the gripping of the plurality of ropes 5 by the rope gripping device 10 is released. The machine room unit 3 and the first lifting body 1 are lifted using the first lifting device 12 while the plurality of ropes 5 are not gripped. As a result, the ropes 5 already unwound from the rope drums 6 pass through the third diverting pulley 14, the fourth diverting pulley 9, the suspension wheel of the first lifting body 1, and the sheave 4 of the hoisting machine 15. Go down to the lower part of the machine room unit 3.

The second elevator 2 remains supported at the bottom of the hoistway. The length of the rope 5 located below the machine room unit 3 increases according to the amount of elevation of the machine room unit 3 and the first lifting body 1 . The machine room unit 3 that has reached the destination floor is fixed to the guide rail for the car, the guide rail for the counterweight, or the structure on the building side. As a result, the lifting strokes of the first lifting body 1 and the second lifting body 2 are extended. Such lifting height extension operation is repeatedly performed during the construction period.

(Effect of rotation control device)
A first role of the rotation suppressing device 21 is to prevent the ropes 5 from falling while the machine room unit 3 and the first lifting body 1 are being lifted by the first lifting device 12 . When the rope drum 6 is installed in the machine room unit 3 , tension is generated on the rope drum 6 side due to the weight of the rope 5 . Part of the dead weight of the rope 5 becomes a tension component in the direction in which the rope 5 is let out from the rope drum 6 . The rest of the weight of the rope 5 becomes a tension component in the direction of pulling the end of the rope 5 opposite to the rope drum 6 . Portions of each of these tension components cancel each other out. The unbalanced tension component due to the weight of the rope 5 that is not canceled becomes the tension that acts on the rope drum 6 .

For this reason, if the rotation of the rope drum 6 is not suppressed, the rope 5 is excessively let out from the rope drum 6 and the rope 5 falls. Therefore, it is necessary to satisfy the condition that the rotation of the rope drum 6 is suppressed by the rotation suppressing device 21 even if the tension of the own weight of the rope 5 acts on the rope 5 .

A second role of the rotation suppressing device 21 is to prevent an event in which the load concentrates on one rope 5 among the plurality of ropes 5 and the tension of the rope 5 increases significantly. When any of the sheaves through which multiple ropes pass is not independent for each rope, and traction is generated between that sheave and each of the multiple ropes, the tension of a rope is There is a possibility of transitioning to other ropes through The greater the traction between the sheave and the rope, the less slippage occurs between the sheave and the rope, and the greater the tendency for the sheave and rope to become integrated. Thus, the greater the traction between the sheave and each rope, the greater the load transferred from one rope to another. Here, the sheave includes the hoist sheave and a plurality of diverting pulleys. The power of the hoist is transmitted to each rope through the sheave. For this reason, a large amount of traction is ensured, particularly between the sheaves of the hoist and each rope.

It should be noted that which rope 5 among the plurality of ropes 5 the load concentrates depends on the amount of tension and slack of each rope 5 immediately before the machine room unit 3 is lifted, and the traction between each rope 5 and the sheave. The size of each rope 5, the difference in the route of each rope 5, the difference in the rotation tolerance of each rope drum 6, and other factors affect and determine it in a complex manner. For this reason, although it is possible to increase the occurrence rate of load concentration on an arbitrary rope to some extent at the site, it is difficult to adjust at the site so that load concentration does not occur.

National regulations for the safe use of elevator ropes specify rope safety factors. Although the value of the safety factor differs from country to country, generally the safety factor against the breaking load of the rope is 12 or more. That is, in order to keep each rope 5 in a safe state, the load of each rope 5 must not exceed a load with a safety factor of 12 at least. Therefore, when the load concentrates on a certain rope 5 and a load exceeding the load with a safety factor of 12 is applied to the rope 5, the rotation of the rope drum 6 corresponding to the rope 5 is allowed, It is necessary to ensure that the tension does not exceed the specified value.

As mentioned above, in each rope drum 6, the setting value of the braking torque which the rotation suppression apparatus 21 adds to the rope drum 6 is set in the range between the following lower limit values and upper limit values. The set value of the braking torque may be set to any value between the following lower limit and upper limit. The set value of the braking torque can be adjusted with an adjusting nut 25 . When the adjusting nut 25 is tightened, the braking torque set value increases, and when the adjusting nut 25 is loosened, the braking torque set value decreases.

The lower limit of the braking torque is a value equal to the rotational moment generated in the rope drum 6 by the unbalanced self weight of one rope 5 .

The upper limit of the braking torque is a value equal to the rotational moment generated in the rope drum 6 when a load that provides a safety factor defined by the laws of each country acts on one rope 5 . In addition, if there is a device that can be damaged before the rope 5, the upper limit of the braking torque is generated in the rope drum 6 when the limit tension that does not damage the device acts on one rope 5. It may have a value equal to the rotational moment.

When the second diverting pulley 13 is pulled up from the machine room unit 3 , a pulling force acts on the rope 5 and the pulling force is transmitted to the rope drum 6 . If the setting value of the braking torque of the rotation suppressing device 21 is within the above range, the rotational torque due to the pulling force exceeds the braking torque. Therefore, the rope drum 6 rotates and the rope 5 is let out from the rope drum 6. - 特許庁

On the other hand, when the machine room unit 3 and the first lifting body 1 are pulled up, basically the rotational torque acting on the rope drum 6 is equal to or less than the braking torque of the rotation suppressing device 21 . Therefore, the rotation of the rope drum 6 is suppressed by the rotation suppression device 21 and the rope 5 is held by the rope drum 6 .

However, when the machine room unit 3 and the first lifting body 1 are lifted, the load on one rope 5 may increase, and a rotational torque exceeding the braking torque may act on the corresponding rope drum 6 . In this case, the rope drum 6 rotates due to the rotation suppressing device 21 slipping. As a result, a small amount of rope 5 is let out from the rope drum 6. - 特許庁Therefore, the increased load is distributed to the other ropes 5, and the load acting on each rope 5 is balanced. The rotation of the rope drum 6 stops when the rotational torque acting on the rope drum 6 becomes equal to or less than the braking torque of the rotation suppressing device 21 .

Even when the machine room unit 3 and the first lifting body 1 are stopped in the middle of lifting to the next target floor, the load in the direction in which the rope 5 is let out from the rope drum 6 is due to the unbalanced weight of the rope 5. tension component only. Therefore, the rotational torque acting on the rope drum 6 is equal to or less than the braking torque of the rotation suppressing device 21 . Therefore, the rotation of the rope drum 6 is suppressed and the rope 5 is held by the rope drum 6 .

By providing the rotation suppressing device 21 on each rope drum 6, although the load increases when the rope 5 is let out from the rope drum 6, the rope drum 6 is prevented from continuing to rotate after the rope 5 is completely let out. be able to.

Further, when the machine room unit 3 and the first lifting body 1 are pulled up, if the load of one rope 5 increases, the corresponding rope drum 6 is allowed to rotate. Therefore, the generation of excessive tension in a specific rope 5 is suppressed. This makes it possible to avoid damage to the rope 5 or the equipment supporting the rope 5 . Therefore, the lift extension operation can be safely performed.

The weight of the suspended rope 5 and the position of the rope 5 in the radial direction of the rope drum 6 change each time the lift extension operation is performed. In this embodiment, the setting value of the braking torque can be adjusted by tightening or loosening the adjusting nut 25 . Thereby, the set value of the braking torque can be appropriately set according to the variable factors such as the weight of the suspended rope 5 and the position of the rope 5 in the radial direction of the rope drum 6 .

(Structural example of machine room unit in Embodiment 1)
FIG. 4 is a front view showing a structural example of the machine room unit of the lift extension type construction elevator according to the present embodiment. 5 is a partial side view of the machine room unit shown in FIG. 4; FIG.

In the example shown in FIGS. 4 and 5, above the machine room unit 3, there are a first direction change pulley 8, a second direction change pulley 13, a third direction change pulley 14, a fourth direction change pulley 9, and six of rope drums 6 are arranged. Three rope drums 6 are shown in FIG. The three rope drums 6 not shown are arranged behind the three rope drums 6 shown.

A hoisting machine 15 , a shackle-side rope end 11 , a rope gripping device 10 and a control panel 16 are arranged in the machine room unit 3 . The control panel 16 is electrically connected to the hoisting machine 15 and the car equipment.

A rope 5 let out from each rope drum 6 is first wound around a first direction change pulley 8 . Each rope 5 is wound around a first diverting pulley 8, a second diverting pulley 13, a third diverting pulley 14, and a fourth diverting pulley 9 in this order, and then passes through the rope gripping device 10 for the first lifting and lowering. Go to body 1 suspension wheel.

A plurality of lifting hooks 17 are provided at the upper end of the machine room unit 3 . In order to lift the machine room unit 3 with the first lifting body 1 connected to it at a position close to the center of gravity, the plurality of lifting hangers 17 are arranged at the center of gravity of the connection of the first lifting body 1 and the machine room unit 3 . are arranged to surround the A lifting cable of the first lifting device 12 is connected to the lifting suspension base 17 .

In the example shown in FIGS. 4 and 5 , a balancer 32 is suspended from the suspension cable of the first lifting device 12 . A lifting device 33 having a tension balancing function is attached to each end of the balancer 32 . A chain 34 is hung on each of the lifting devices 33 . Both ends of the chain 34 are connected to the suspension base 17 for lifting. Thereby, the hoisting cable of the first hoisting device 12 is connected to the four hoisting bases 17 .

By suspending the first lifting body 1 and the machine room unit 3 substantially at the center of gravity, the first lifting body 1 and the machine room unit 3 can be stably lifted without generating excessive reaction force on the guide rails. be able to. The load on both ends of the chain 34 can be evenly distributed by using a lifting device 33 with a tension balancing function.

The first lifting body 1 may be suspended from the lower beam of the machine room unit 3 as shown in FIG. 1 or may be suspended from the upper beam of the machine room unit 3 . In the example shown in FIG. 5 , the first lifting body 1 is suspended from the upper beam of the machine room unit 3 . That is, in the example shown in FIG. 5, the lifting body suspension base 31 is attached to the upper beam of the machine room unit 3, and the first lifting body 1 is suspended from the lifting body suspension base 31 by the coupling device 7. there is When the first lifting body 1 is suspended from the upper beam of the machine room unit 3, a chain block, a winch, or the like may be installed between the lifting body suspension base 31 and the first lifting body 1 and inside the machine room unit 3. should be provided. As a result, the vertical position of the first lifting body 1 can be adjusted safely within the machine room unit 3 .

As described above, the first elevator 1 may be a car that moves along the car guide rails, or a counterweight that moves along the counterweight guide rails. When the first lift 1 is a car, the second lift 2 is a counterweight, and when the first lift 1 is a counterweight, the second lift 2 is a car.

The basket is lighter than the counterweight. Therefore, when the first lifting body 1 is used as a car and the second lifting body 2 is used as a counterweight, the load on the first lifting device 12 is reduced because the car is connected to the machine room unit 3. can.

As described above, the lift extension type construction elevator according to the present embodiment includes the machine room unit 3 , the plurality of rope drums 6 , and the second direction change pulley 13 . The machine room unit 3 is adapted to be lifted against the building. A plurality of rope drums 6 are mounted on the machine room unit 3 . A plurality of ropes 5 are wound around the second direction change pulley 13 . The second direction change pulley 13 is lifted independently of the machine room unit 3 . Here, the rope drum 6 is an example of a suspension drum. Rope 5 is an example of a suspension. The second diverting pulley 13 is an example of a diverting device.

Each of the multiple ropes 5 is wound around a corresponding one of the multiple rope drums 6 . Each rope drum 6 is provided with a rotation suppressing device 21 . Each rotation suppressing device 21 is configured to allow rotation of the rope drum 6 when the rotational torque acting on the rope drum 6 exceeds a set value. Each rotation suppressing device 21 is configured to suppress rotation of the rope drum 6 when the rotational torque is equal to or less than a set value.

In this configuration, when extending the lift, the second direction change pulley 13 is lifted before the machine room unit 3 is lifted. At this time, the rotational torque acting on the rope drum 6 due to the tension of the rope 5 usually exceeds the set value. Therefore, the rope drum 6 is allowed to rotate, and the rope 5 is let out from the rope drum 6 .

On the other hand, when the machine room unit 3 is lifted, the rotational torque which acts on the rope drum 6 becomes below a set value, and rotation of the rope drum 6 is suppressed. As a result, the rope 5 is prevented from being excessively let out from the rope drum 6 and dropping.

However, when the load of a certain rope 5 increases and the rotational torque acting on the corresponding rope drum 6 exceeds the set value, the rope drum 6 is allowed to rotate, and a small amount of rope 5 is released from the rope drum 6. is rolled out. As a result, the load increased by one rope 5 can be distributed to the other ropes 5, so that the tension of the plurality of ropes 5 can be balanced. Therefore, damage to the rope 5 or equipment supporting the rope 5 can be suppressed.

In the lift extension type construction elevator according to the present embodiment, the rotation suppressing device 21 is configured to apply a braking torque corresponding to a set value to the rope drum 6 . According to this configuration, the set values can be easily set.

In the lift extension type construction elevator according to the present embodiment, the rotation suppressing device 21 is attached to the rotating shaft 27 of the rope drum 6 . According to this configuration, the structure can be simplified, and stable braking torque can be applied to the rope drum 6 .

In the lift extension type construction elevator according to the present embodiment, the rotation suppressing device 21 may be attached to the drum flange portion 6 b or the drum flange portion 6 c of the rope drum 6 .

In the lift extension type construction elevator according to the present embodiment, the above set values can be adjusted. According to this configuration, the set value can be appropriately set according to various variable factors such as the weight of the suspended rope 5 and the position of the rope 5 in the radial direction of the rope drum 6 .

Although the rope 5 is exemplified as the suspension in this embodiment, a belt can also be used as the suspension.

1 first elevating body, 2 second elevating body, 3 machine room unit, 4 sheave, 5 rope, 6 rope drum, 6a cylindrical portion, 6b, 6c drum flange portion, 7 coupling device, 8 first direction change pulley, 9 fourth direction change pulley, 10 rope gripping device, 11 shackle side rope end, 12 first lifting device, 13 second direction change pulley, 14 third direction change pulley, 15 hoist, 16 control panel, 17 lift Heavy suspension base 21 rotation suppressing device 22 flange 23a first friction plate 23b second friction plate 24 disc spring 25 adjusting nut 26 arm 27 rotating shaft 27a, 27b supported portion 27c end, 27d step surface, 27e male threaded portion, 28 frame, 28a upper surface, 29a, 29b bearing, 30 second lifting device, 31 lifting body suspension base, 32 balancer, 33 lifting tool, 34 chain.

Claims (5)

a machine room unit lifted against a building;
a plurality of suspension drums mounted on the machine room unit;
a direction changing device around which a plurality of suspension bodies are wound and lifted independently of the machine room unit;
with
each of the plurality of suspensions is wrapped around a corresponding one of the plurality of suspension drums;
Each suspension drum is provided with a rotation suppressing device,
Each of the rotation suppressing devices permits rotation of the suspension drum when the rotational torque acting on the suspension drum exceeds a set value, and allows rotation of the suspension drum when the rotational torque acting on the suspension drum is equal to or less than the set value. A lift extension type construction elevator configured to suppress rotation of a suspension drum. 2. The lift extension type construction elevator according to claim 1, wherein the rotation suppressing device is configured to apply a braking torque corresponding to the set value to the suspension drum. 3. The lift extension type construction elevator according to claim 2, wherein the rotation suppressing device is attached to the rotating shaft of the suspension drum. 3. The lift extension type construction elevator according to claim 2, wherein the rotation suppressing device is attached to a drum flange portion of the suspension drum. The lifting height extension type construction elevator according to any one of claims 1 to 4, wherein the set value is adjustable.

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