JP4786121B2 - Elevator equipment - Google Patents

Description

TECHNICAL FIELD The present invention relates to an elevator apparatus in which a plurality of cars are raised and lowered in a common hoistway.
BACKGROUND ART Conventionally, for example, Japanese Utility Model Laid-Open No. 1-132660 discloses an elevator apparatus in which one counterweight is used for two cars and two cars are lifted and lowered in different hoistways. ing. However, this elevator apparatus requires a large hoistway space for arranging two cars and one counterweight in a plane.
Further, for example, Japanese Patent Application Laid-Open No. 59-153773 shows an elevator apparatus in which two cars are arranged vertically in a common hoistway. However, in this elevator apparatus, the upper car is suspended by 1: 1 roping, the lower car is hung by 2: 1 roping, and two counterweights are required, so that the apparatus configuration is complicated.
Furthermore, since the rope penetrates the counterweight, it takes time to arrange the rope, and the rope may interfere with the counterweight due to shaking. Furthermore, since the weight of the counterweight is reduced by providing the through hole of the rope, the outer dimensions of the counterweight are increased to compensate for it.
DISCLOSURE OF THE INVENTION The present invention has been made in order to solve the above-described problems, and is an elevator that can efficiently arrange two cars in one hoistway and can be configured compactly as a whole. The object is to obtain a device.
The elevator apparatus according to the present invention includes a hoistway, an upper car that is raised and lowered in the hoistway, a lower car that is arranged below the upper car, and is raised and lowered independently of the upper car, and the hoistway. A counterweight to be lifted and a drive sheave for the upper car, and disposed at the upper part in the hoistway. The main rope body which is arranged on the upper part of the car and is wound around the upper car drive sheave and the lower car drive sheave for raising and lowering the lower car, and suspends the upper car, the lower car and the counterweight. It is provided.
BEST MODE FOR CARRYING OUT THE INVENTION Preferred embodiments of the present invention will be described below with reference to the drawings.
Embodiment 1 FIG.
1 is a side view showing an elevator apparatus according to Embodiment 1 of the present invention, and FIG. 2 is a plan view showing the elevator apparatus of FIG.
In the figure, a pair of car guide rails 2 and a pair of counterweight guide rails 3 are installed in a hoistway 1. The upper car 4 and the lower car 5 are guided by the car guide rail 2 and are raised and lowered independently in the hoistway 1. The counterweight 6 is raised and lowered in the hoistway 1 while being guided by the counterweight guide rail 3.
A support base 7 is disposed in the upper part of the hoistway 1. The support 7 is supported by the car guide rail 2 and the counterweight guide rail 3. The support 7 supports an upper car drive device 8 for raising and lowering the upper car 4 and a lower car drive device 9 for raising and lowering the lower car 5. The upper car drive device 8 has an upper car drive sheave 8a. The lower car drive device 9 has a lower car drive sheave 9a.
The counterweight 6 is disposed behind the upper car 4 and the lower car 5 and is a pair of counterbalances with respect to a straight line connecting the rotation centers of the upper car drive sheave 8a and the lower car drive sheave 9a. The center line of the weight guide rail 3 is parallel.
A set of main rope bodies 11 composed of a plurality of main ropes 10 made of synthetic fiber rope are wound around the upper car drive sheave 8a and the lower car drive sheave 9a. The upper car 4, the lower car 5 and the counterweight 6 are suspended in the hoistway 1 by the main rope body 11. The upper car drive sheave 8 a and the lower car drive sheave 9 a are arranged with their positions in the height direction shifted from each other in order to avoid interference with the main rope body 11.
The support table 7 is supported by an upper car deflector 12, first and second counterweight deflectors 13, 14, first and second lower car deflectors 15, 16 and a horizontal deflector 17. Has been.
The upper car deflecting wheel 12 guides the main rope body 11 from the upper car driving sheave 8 a to the upper car 4. The first balancing weight deflector 13 guides the main rope body 11 from the upper car drive sheave 8 a to the balancing weight 6. The second balancing weight deflector 14 guides the main rope body 11 from the lower car drive sheave 9 a to the balancing weight 6.
The main rope body 11 is distributed in two directions so as to pass through both sides of the upper car 4 on the way from the lower car driving device 9 a to the lower car 5. One of the distributed main rope bodies 11 is guided to the lower car 5 by the first lower car deflecting wheel 15. The other of the distributed main rope bodies 11 is guided to the lower car 5 by the second lower car deflecting wheel 16 and the horizontal deflecting wheel 17.
On the upper part of the counterweight 6, a counterweight suspension wheel 18 around which the main rope body 11 is wound is provided.
One end of the main rope body 11 is connected to the upper center of the upper car 4. The main rope body 11 includes, from one end, an upper car deflector 12, an upper car drive sheave 8 a, a first counterweight deflector 13, a counterweight suspension car 18, and a second counterweight deflector. 14, the lower car drive sheave 9a is wound in order and distributed in two directions. The other end portion of the distributed main rope body 11 is connected to the lower portions on both sides of the lower cage 5.
In this way, the upper car 4 and the lower car 5 are respectively suspended by the 1: 1 roping method with respect to the upper car driving sheave 8a and the lower car driving sheave 9a, and the counterweight 6 is the 2: 1 roping method. It is suspended by.
On the upper part of the lower car 5, an interference detection switch 19 for detecting interference with the upper car 4 and an inter-car buffer 20 for buffering an impact when the upper car 4 collides should be mounted. In the pit (bottom part) 1 a of the hoistway 1, a plurality of shock absorbers 21 are installed to buffer an impact when the lower car 5 collides with the pit 1 a.
A waiting space 1b in which the lower car 5 waits is secured in the pit 1a. A pair of left and right balancing ropes 22 are suspended from the lower part of the upper car 4, the lower car 5 and the counterweight 6.
3 is an enlarged side view showing the main part of FIG. 1, and FIG. 4 is a plan view showing the main part of FIG. A pair of return wheels 23 around which a balancing rope 22 is wound are provided at the lower part of the balancing weight 6. The pit 1a includes a pair of first upper car tension wheels 24, a pair of second upper car tension wheels 25, a pair of first lower car tension wheels 26, and a pair of second lower car tension wheels. A tension wheel 27 is arranged.
The balancing rope 22 has one end connected to the lower part of the upper car 4 and the other end connected to the lower part of the lower car 5. The intermediate portion of the balancing rope 22 includes a first upper car tension wheel 24, a second upper car tension wheel 25, a return wheel 23, a first lower car tension wheel 26, and a second lower car. Wrapping wheels 27 are wound around in this order.
A fixed cable suspender 28 is fixed in the hoistway 1. The fixed side cable suspension 28 is fixed to the car guide rail 2. The upper car 4 and the lower car 5 are provided with upper car side and lower car side cable suspenders 29 and 30, respectively. A flexible upper car control cable 31 is connected between the fixed side cable hanger 28 and the upper car side cable hanger 29. A flexible lower car control cable 32 is connected between the fixed cable hanger 28 and the lower car cable hanger 30.
Next, FIG. 5 is an enlarged side view showing the upper part in the hoistway of FIG. The upper car drive device 8 is fixed to the support base 7 by a support bracket 33. A plurality of elastic bodies 34 are interposed between the support bracket 33 and the upper car drive device 8. The support structure of the lower car drive device 9 is the same as that of the upper car drive device 8.
FIG. 6 is a perspective view showing the structure of the main rope 10 of FIG. In the figure, an inner strand layer 44 having a plurality of inner strands 42 and filled strands 43 arranged in a gap between these inner strands 42 is disposed around the core wire 41. Each inner strand 42 is composed of a plurality of aramid fibers and an impregnating material such as polyurethane. The filling strand 43 is made of polyamide, for example.
An outer strand layer 46 having a plurality of outer strands 45 is disposed on the outer periphery of the inner strand layer 44. Each outer strand 45 is composed of a plurality of aramid fibers and an impregnating material such as polyurethane, like the inner strand 42.
Between the inner strand layer 44 and the outer strand layer 46, there is a friction reducing coating layer 47 for avoiding wear of the strands 42, 45 due to friction between the strands 42, 45 in the winding around the drive sheaves 8a, 9a. Has been placed. A protective coating layer 48 is disposed on the outer periphery of the outer strand layer 46. Such a synthetic fiber rope has a high coefficient of friction and excellent flexibility compared to a steel rope.
In such an elevator apparatus, since the upper car 4 and the lower car 5 are lifted and lowered independently in the common hoistway 1, the transportation capacity can be increased without increasing the area of the hoistway 1, Two cars 4 and 5 can be arranged efficiently. Further, since the upper car drive device 8 and the lower car drive device 9 are arranged in the upper part in the hoistway 1, the whole can be configured compactly.
Further, the upper car 4 and the lower car 5 are respectively suspended by the 1: 1 roping method with respect to the upper car driving sheave 8a and the lower car driving sheave 9a, and the counterweight 6 is suspended by the 2: 1 roping method. Since it is lowered, only one counterweight 6 is required, and the configuration can be simplified.
Furthermore, the upper car drive device 8 and the lower car drive device 9 are horizontally arranged, and the upper car drive sheave 8a and the lower car drive sheave 9a are connected to the upper car 4 and the lower car in the upper part of the hoistway 1. Since the plurality of deflecting wheels 12 to 17 for guiding the main rope body 11 to the car 5 and the counterweight 6 are arranged, the whole can be configured compactly.
Further, since the upper car drive device 8, the lower car drive device 9 and all the deflecting wheels 12 to 17 are supported by the common support base 7, the number of parts can be reduced and the whole can be made compact. it can.
Furthermore, since the support base 7 is supported by the guide rails 2 and 3, the load applied to the support base 7 can be received by the pit 1a via the guide rails 2 and 3. However, the support base 7 may be directly supported by a building. In this case, the load applied to the guide rails 2 and 3 is reduced, and the cross-sectional area of the guide rails 2 and 3 can be reduced.
Furthermore, since a plurality of elastic bodies 34 are interposed between the upper car driving device 8 and the lower car driving device 9 and the support base 7, vibrations of the driving devices 8, 9 are transmitted to the building side. Is prevented.
Further, the plurality of main ropes 10 are distributed so as to pass through both sides of the upper car 3 on the way from the lower car driving device 9 to the lower car 5, so that the lower car 5 can be stably suspended. Can do.
Further, the pit 1a of the hoistway 1 has a waiting space 1b in which the lower car 5 waits, so that the upper car 4 can be stopped at the lowest landing and when the amount of use of the elevator device is small The lower car 5 may be made to stand by in the standby space 1b and only the upper car 4 may be operated, so that the operation efficiency can be improved.
Furthermore, since the control cables 31 and 32 are arranged outside the moving area of the upper car 4, the lower car 5 and the counterweight 6, the control cables 31 and 32 are arranged in the upper car 4, the lower car 5 and the counterweight. 6 is not interfered with.
Moreover, since the main rope 10 made of a synthetic fiber rope having a high friction coefficient and excellent flexibility is used, the diameters of the drive sheaves 8a and 9a and the deflecting wheels 12 to 17 can be reduced, and the whole is further compact. Can be configured.
In the first embodiment, the upper car 4 is hung at the center of the upper part, but a plurality of main ropes 10 may be distributed and hung on both sides as in the lower car 5.
In the first embodiment, one counterweight 6 is used for the two cars 4 and 5, but two counterweights may be used.
Embodiment 2. FIG.
Further, in the first embodiment, the counterweight 6 is arranged behind the cars 4 and 5, but the counterweight 6 is arranged on the side of the cars 4 and 5, for example, as shown in FIG. The present invention can also be applied to existing elevator apparatuses. In this case, the center line of the pair of counterweight guide rails 3 is perpendicular to the straight line connecting the rotation centers of the upper car drive sheave 8a and the lower car drive sheave 9a.
[Brief description of the drawings]
1 is a side view showing an elevator apparatus according to Embodiment 1 of the present invention;
FIG. 2 is a plan view showing the elevator apparatus of FIG.
3 is an enlarged side view showing the main part of FIG.
FIG. 4 is a plan view showing the main part of FIG.
FIG. 5 is an enlarged side view showing the upper part in the hoistway of FIG.
6 is a perspective view showing the structure of the main rope of FIG.
FIG. 7 is a plan view showing an elevator apparatus according to Embodiment 2 of the present invention.

Claims (9)

Hoistway,
An upper car that is elevated in the hoistway;
A lower car disposed below the upper car and lifted and lowered in the hoistway independently of the upper car;
A counterweight that is raised and lowered in the hoistway;
An upper car drive sheave having an upper car drive sheave and arranged in the upper part of the hoistway to raise and lower the upper car;
A lower-car drive sheave having a lower-car drive sheave and disposed at an upper part in the hoistway to raise and lower the lower car; and
A main rope body having a plurality of main ropes, which is wound around the upper car drive sheave and the lower car drive sheave, and suspends the upper car, the lower car and the counterweight. Elevator equipment,
The upper car and the lower car are respectively suspended by the 1: 1 roping method and the counterweight is suspended by the 2: 1 roping method with respect to the upper car driving sheave and the lower car driving sheave. And
The upper car drive device and the lower car drive device are arranged horizontally such that the rotation shaft of each drive sheave extends along the vertical direction,
The main rope body is distributed in two directions so as to pass through both sides of the upper car on the way from the lower car driving device to the lower car,
The upper part of the hoistway is provided with an upper car deflector, first and second counterweight deflectors, first and second lower car deflectors and a horizontal deflector,
The main rope body is guided from the upper car driving sheave to the upper car by the upper car deflecting wheel, and from the upper car driving sheave to the counter weight by the first balancing weight deflecting wheel. Led to the counterweight from the lower car drive sheave by the second counterweight deflector;
One of the distributed main rope bodies is guided to the lower car by the first lower car deflector, and the other of the distributed main rope bodies is the second lower car deflector and the above An elevator system that is guided to the lower car by a horizontal deflector . The upper car driving apparatus, the lower car driving apparatus and all of said deflector wheel is an elevator apparatus according to claim 1, wherein are supported on a common support platform disposed in an upper portion of the hoistway. The aforementioned hoistway, the upper car are installed a plurality of guide rails for guiding the vertical movement of the lower car and the counterweight, the support base, claim is supported by the guide rail 2 The elevator apparatus as described. The elevator apparatus according to claim 2 , wherein the support base is supported by a building. The elevator apparatus according to claim 2 , wherein a plurality of elastic bodies are interposed between the upper car drive apparatus, the lower car drive apparatus, and the support base.   In the hoistway, a pair of counterweight guide rails for guiding the raising and lowering of the counterweight are installed, and a straight line connecting the rotation centers of the upper car driving sheave and the lower car driving sheave is arranged. The elevator apparatus according to claim 1, wherein center lines of the pair of counterweight guide rails are parallel.   In the hoistway, a pair of counterweight guide rails for guiding the raising and lowering of the counterweight are installed, and a straight line connecting the rotation centers of the upper car driving sheave and the lower car driving sheave is arranged. The elevator apparatus according to claim 1, wherein a center line of the pair of counterweight guide rails is a right angle.   The elevator apparatus according to claim 1, wherein a waiting space for the lower car to wait is secured in a pit of the hoistway.   The elevator apparatus according to claim 1, wherein the main rope body has a main rope made of synthetic fiber rope.

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