JP2007269434A - Elevator device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an elevator device with a compact constitution of equipment such as a winding-up machine and accomplishing space-saving of a hoistway. <P>SOLUTION: In the elevator device, a car 1 hung by a rope 5 in the hoistway and a balance weight 2 are driven by the winding-up machine 11. The elevator device is provided with a sash hanger 8 provided on an upper part of the car 1; a rope-stop 3 provided on the car 1; a sash hanger 13 provided on an upper part of the balance weight 2; and a rope-stop 15 provided on the upper part of the balance weight 2. The rope 5 is wound on a drive sheave 10 of the winding-up machine 11 at a winding angle of 360° or more. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an elevator apparatus in which a car and a counterweight move along a guide rail in a hoistway.

  2. Description of the Related Art Conventionally, as a method for improving traction capability, an elevator apparatus in which a rope wrap angle with respect to a drive sheave of a hoisting machine is 180 ° or more has been proposed.

  For example, Patent Document 1 below describes an elevator apparatus in which a rope is wound around a driving sheave of a hoisting machine at a winding angle of 360 ° or more.

JP-A-61-282285 (FIG. 1 etc.)

  However, in the elevator apparatus described in Patent Document 1, no consideration is given to the size of the elevator equipment including the hoisting machine. Actually, the rope is directly fixed to the car and the counterweight of the above-mentioned Patent Document 1, and is suspended by 1: 1 roping. Accordingly, the hoisting machine requires a large torque, and as a result, the entire configuration of the hoisting machine becomes large, so that the space saving of the hoistway is not easy.

  An object of the present invention is to provide an elevator apparatus that realizes space saving of a hoistway by reducing the configuration of a device such as a hoisting machine.

  In order to achieve the above object, the present invention provides an elevator apparatus in which a car and a counterweight suspended by a rope in a hoistway are driven by a hoist, and a suspension car provided at an upper part of the car. A rope stopper provided on the car, a suspension car provided on an upper portion of the counterweight, and a rope stopper provided on an upper portion of the counterweight, and the rope is used as a drive sheave of the hoisting machine. On the other hand, it was made to wind at a winding angle of 360 ° or more.

  ADVANTAGE OF THE INVENTION According to this invention, the structure of apparatuses, such as a hoisting machine, can be made small and the elevator apparatus which implement | achieved space saving of a hoistway can be provided.

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 is a diagram showing how to hang a rope 5 of an elevator apparatus according to a first embodiment of the present invention, and FIG. 2 is a plan sectional view of a hoistway in the elevator according to the present embodiment. In the elevator apparatus of the present embodiment, the car 1 moves up and down in the hoistway along the car guide rails 16a and 16b, and the counterweight 2 moves in the hoistway along the counterweight guide rails 17a and 17b. It is configured to move up and down. The car 1 and the counterweight 2 are suspended by a rope 5 and driven by a hoisting machine 11. Here, the hoisting machine 10 has a trunk length whose axial length is larger than the diameter of the drive sheave 11.

  Further, a suspension car 8 is provided at the upper part of the car 1, a rope stopper 3 is provided at the lower part of the car 1, and a suspension car 4 is provided at the side of the lower part of the car 1. Yes. On the other hand, a suspension wheel 13 and a rope stopper 15 are provided on the upper part of the counterweight 2.

A first drive sheave side return wheel 9, a second drive sheave side return wheel 12, and a drive sheave 10 of the hoisting machine 11 are installed at the upper part of the hoistway. Further, the first drive sheave return wheel 9, the second drive sheave return wheel 12, and the drive sheave 10 are all located at substantially the same height, and as shown in FIG. Are almost parallel. Further, two passenger car side return wheels 6 and 7 and a counterweight side return wheel 14 are installed in the upper part of the hoistway. Here, the car-side return cars 6 and 7, the counterweight-side return car 14 and the suspension car 8,
The vertical projections 13 are substantially parallel to each other, and the vertical projections are substantially perpendicular to the first drive sheave return wheel 9, the second drive sheave return wheel 12, and the drive sheave 10 described above. ing.

  The hoisting machine 11 is arranged such that its axis is substantially parallel to the opening / closing direction of the landing door and is located within the vertical projection of the car 1. The counterweight 2 is disposed on the back of the car 1. Here, the back part of the car 1 means a rear part of the car 1 when viewed from the landing side.

  Next, how to hang the rope 5 in the elevator apparatus of the present embodiment will be described with reference to FIG. Basically, the elevator apparatus of the present embodiment employs a 3: 1 roping method in which the car 1 and the counterweight 2 are suspended using the rope stoppers 3 and 15 and the suspension cars 8 and 13. . Specifically, as shown in FIG. 1, first, one end of the rope 5 is fixed to the rope stopper 3 at the lower part of the car 1, and the rope 5 extends in a substantially horizontal direction from the rope stopper 3, and the suspension vehicle 4. It is turned upward through Thereafter, the rope 5 extends upward and extends substantially horizontally from the car-side return wheel 6 to another car-side return wheel 7, and is turned downward by the car-side return wheel 7. Further, the rope 5 is turned upward through a suspension wheel 8 at the top of the car 1, and is wound around a drive sheave 10 through a first drive sheave side return wheel 9, and this drive sheave. 10 is rotated approximately 360 °. Next, the rope 5 is turned downward via the second drive sheave side return wheel 11 and then turned upward via the suspension wheel 13 above the counterweight 2. Thereafter, the rope 5 is turned downward by the counterweight return wheel 14 to reach the rope stopper 15 at the top of the counterweight 2, and the other end of the rope 5 is fixed to the rope stopper 15.

  Here, the method of winding the rope 5 around the drive sheave 10 in the present embodiment is as shown in FIG. 9, and the three ropes 5 are spirally wound around the drive sheave surface 10a approximately 360 °. Even in this case, the wrapping start position and the wrapping end position are shifted in the axial direction, so that the rope 5 does not come into contact. In addition, the rope 5 is wound around the drive sheave 10 via the first drive sheave return pulley 9 and rotated about 360 ° by the drive sheave 10, and then the second drive sheave return pulley 12 is moved. That is, the direction of winding of the rope 5 around the drive sheave 10, the first drive sheave side return wheel 9 and the second drive sheave side return wheel 12 is the same direction, that is, the rope 5 The winding method is forward winding.

  According to the present embodiment as described above, since the winding angle of the rope 5 with respect to the drive sheave 10 is approximately 360 °, sufficient traction can be secured and the diameter of the drive sheave 10 of the hoisting machine 11 can be reduced. As a result, the torque of the hoisting machine 11 can be reduced. Further, since the 3: 1 roping is used, the suspension load is distributed into three, and as a result, the torque of the hoisting machine 11 can be reduced. In this way, in this embodiment, since the torque of the hoisting machine 11 can be small, the hoisting machine 11 itself can be miniaturized and space saving of the hoistway can be expected.

  Further, since the wrap angle of the rope 5 with respect to the drive sheave 10 is approximately 360 °, the position of the drive sheave 10 is increased to obtain sufficient traction, or a return wheel is separately provided near the lower portion of the drive sheave 10. There is no need to do. Here, the fact that there is no need to increase the position of the drive sheave 10 suppresses the height of the hoistway and contributes to space saving of the hoistway. And the fact that there is no need to install an extra pulley also contributes to space saving of the hoistway.

  Furthermore, the fact that it is not necessary to install an extra pulley leads to suppression of the number of times the rope 5 is bent, and as a result, has an effect of extending the life of the rope 5. Moreover, since the winding method of the rope 5 around the drive sheave 10, the first drive sheave side return wheel 9 and the second drive sheave side return wheel 12 is forward winding, even if the sheave diameter is reduced. The life of the rope 5 can be kept long.

  FIG. 3 is a diagram showing how the rope 5 of the elevator apparatus according to the second embodiment of the present invention is hung, and FIG. 4 is a plan sectional view of a hoistway in the elevator according to the present embodiment. In the elevator apparatus of this embodiment, unlike the first embodiment, a pair of suspension vehicles 8 and 8a are provided on the side of the floor under the floor of the car 1, and the car 1 Rope stoppers 3 and 5 are provided at places where the counterweight 2 does not interfere with traveling. That is, in this embodiment, 2: 1 roping is adopted, and the torque of the hoisting machine 11 can be smaller than that of 1: 1 roping, so that the hoisting machine 11 can be expected to be downsized. Space saving of hoistway can be expected.

  Also, as shown in FIG. 4, in this embodiment, unlike the first embodiment, the first drive sheave side return wheel 9, the second drive sheave side return wheel 12, and the drive sheave 10 are used to open and close the landing door. Inclined with respect to direction. However, with this arrangement, even with 2: 1 roping, the hoisting machine 11 can be arranged in the vertical projection of the car 1 and the counterweight 2 can be arranged on the back of the car 1. It becomes possible.

  Further, in the present embodiment, as in the first embodiment, the first drive sheave side return wheel 9 and the second drive sheave side return wheel 12 are arranged in a substantially straight line, and the drive sheave 10 and the windings are disposed therebetween. Since the upper machine 11 is arranged, the suspension load hardly acts on the drive sheave 10 as in the first embodiment, and the position of the drive sheave 10 is moved upward to wrap around the rope 5. There is no need to adjust the corners. Therefore, the effect of saving the hoistway space, in other words, the effect that the hoisting machine 11 can be arranged even in the hoistway of a limited layout can be expected.

  Further, the shape of the drive sheave surface 10a in the present embodiment is as shown in FIG. 10, and the radius of the drive sheave 10 is small at the end in the axial direction and large at the center in the axial direction. Further, the drive sheave surface 10a is formed as a curved surface, and specifically, has a substantially rotating ellipse shape or a substantially rotating arc shape. By using such a drive sheave 10, the side on which the rope 5 enters the drive sheave surface 10a is easily slid toward the anti-winding machine 11 and the side from the drive sheave surface 10a is easily slid toward the hoisting machine 11. Therefore, it becomes difficult for the ropes 5 to come into contact with each other, and an effect of preventing abnormal wear of the ropes 5 can be expected.

  FIG. 5 is a diagram illustrating how the rope 5 of the elevator apparatus according to the third embodiment of the present invention is hung, and FIG. 6 is a plan sectional view of a hoistway in the elevator according to the present embodiment. The elevator apparatus of the present embodiment basically employs 3: 1 roping as in the first embodiment, but a specific method of hanging the rope will be described with reference to FIG.

First, one end of the rope 5 is fixed to the rope stopper 3 at the lower part of the car 1, and the rope 5 extends in a substantially horizontal direction from the rope stopper 3 and is turned upward through the suspension wheel 4. Thereafter, the rope 5 extends upward and extends substantially horizontally from the car-side return wheel 6 to another car-side return wheel 7, and is turned downward by the car-side return wheel 7. Further, the rope 5 is turned upward through a suspension wheel 8 at the top of the car 1, wound around the drive sheave 10 through a drive sheave return wheel 18, and is substantially removed by the drive sheave 10. It turns 450 ° and turns downward. Next, the direction of the rope 5 is changed upward via the suspension wheel 13 on the upper part of the counterweight 2. Thereafter, the rope 5 is turned downward by the counterweight return wheel 14 to reach the rope stopper 15 at the top of the counterweight 2, and the other end of the rope 5 is fixed to the rope stopper 15.

Thus, the drive sheave side return wheel 18 is located between the car suspension wheel 8 and the drive sheave 10, and the drive sheave 10 is the second drive sheave side return wheel in the first embodiment described above. It works as a 12th. Accordingly, it is possible to reduce the overhead space by reducing the number of return wheels, and the first drive sheave side return wheel 9 and the second drive sheave side return wheel 12 as in the first embodiment. This embodiment is particularly effective when the drive sheave 10 cannot be physically disposed between the two. Moreover, unlike the first embodiment described above, the wrap angle of the rope 5 with respect to the drive sheave 10 is approximately 450 °, so that more sufficient traction can be obtained. Note that the vertical projection of the hoisting machine 11 in this embodiment is arranged so as to overlap both the car 1 and the counterweight 2.

Further, the radius of the drive sheave 10 in this embodiment is small on the main body side of the hoisting machine 11 and large on the non-main body side. Specifically, as shown in FIG. 11, the drive sheave surface 10a having a substantially truncated cone shape is formed. Have. For this reason, when it is assumed that the surface pressure with respect to the drive sheave surface 10a of the rope 5 is substantially constant, the rope 5 becomes more slippery toward the main body side of the hoisting machine 11, so the ropes 5 are less likely to contact each other, The effect of preventing abnormal wear can be expected.

  FIG. 7 is a diagram showing how the rope 5 of the elevator apparatus according to the fourth embodiment of the present invention is hung, and FIG. 8 is a plan sectional view of a hoistway in the elevator according to the present embodiment. The elevator apparatus of the present embodiment employs 2: 1 roping as in the second embodiment, but unlike any of the above-described embodiments, the counterweight 2 is disposed on the left side of the car 1. ing. Here, the left side of the car 1 means the left part of the car 1 when viewed from the elevator hall. The drive sheave 10 also functions as the first drive sheave side return wheel 9 in the first embodiment described above, and the hoisting machine 11 can be arranged by selecting a position where maintenance inspection is easy. There is.

  Further, the surface of the drive sheave 10 in this embodiment is subjected to shot blasting or knurling, or plating such as nickel plating or chrome plating. Of course, after performing the above-mentioned shot blasting process or knurling process, a plating process may be further performed.

  In the first to fourth embodiments described above, the case where the wrapping angle is approximately 360 °, the case where the wrapping angle exceeds 360 °, for example, the case where the wrapping angle is approximately 450 ° obtained by wrapping approximately 90 ° from 360 ° is shown. However, if it is at least approximately 360 ° or more, sufficient traction can be obtained even if the sheave diameter is reduced. If further traction is required, a rope 5 whose surface is covered with resin may be used.

  In addition, any of the first to fourth embodiments described above is a system in which the car 1 is hung by a suspension vehicle at the top or bottom of the car 1. Therefore, the overhead limit is less than that of the conventional system in which the rope end is fixed to the car via a vertical thimble rod as a rope stopper and is hung by 1: 1 roping. In the first and third embodiments described above, the rope stopper 3 is provided at the lower part of the car 1, but since this rope stopper 3 is disposed in the horizontal direction, the rope stopper 3 is arranged in the height direction of the hoistway. The increase in dimensions can be suppressed.

It is a figure which shows how to hang a rope in the elevator apparatus which shows the 1st Example of this invention. It is a plane sectional view of the hoistway of the elevator apparatus which shows the 1st example of the present invention. It is a figure which shows how to hook a rope in the elevator apparatus which shows the 2nd Example of this invention. It is plane sectional drawing of the hoistway of the elevator apparatus which shows the 2nd Example of this invention. It is a figure which shows how to hook a rope in the elevator apparatus which shows the 3rd Example of this invention. It is a plane sectional view of the hoistway of the elevator apparatus which shows the 3rd example of the present invention. It is a figure which shows how to hook a rope in the elevator apparatus which shows the 4th Example of this invention. It is a plane sectional view of the hoistway of the elevator apparatus which shows the 4th example of the present invention. It is a figure which shows how to wind the rope around the drive sheave in the elevator apparatus according to the first embodiment of the present invention. It is a figure which shows how to wind a rope around the drive sheave in the elevator apparatus which shows the 2nd Example of this invention. It is a figure which shows how to wind a rope around the drive sheave in the elevator apparatus which shows the 3rd Example of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Riding car, 2 ... Counterweight, 3, 15 ... Rope stop, 4, 8, 8a, 13 ... Suspension car, 5 ... Rope, 6, 7 ... Riding car side return wheel, 9 ... First drive sheave side Return wheel, 10 ... Drive sheave, 11 ... Winding machine, 12 ... Second drive sheave side return wheel, 14 ... Counterweight side return wheel, 16a, 16b ... Ride car guide rail, 17a, 17b ... Counterweight guide rail , 18 ... Drive sheave side return car.

Claims (18)

  In an elevator apparatus in which a car and a counterweight suspended by a rope in a hoistway are driven by a hoisting machine, a suspension car provided on the upper part of the car, a rope stopper provided on the car, A suspension wheel provided at the upper portion of the counterweight and a rope stopper provided at the upper portion of the counterweight, and the rope is wound around a driving sheave of the hoisting machine at a winding angle of 360 ° or more. The elevator apparatus characterized by being made.   In an elevator apparatus in which a car and a counterweight suspended by a rope in a hoistway are driven by a hoisting machine, a suspension car provided on the upper part of the car and a suspension car provided on the upper part of the counterweight And, one end is fixed to the rope stop of the car, extending upward from this rope stop, turning downward via the car return car, turning upward via the car suspension, It is wound up above the drive sheave of the hoisting machine via the drive sheave side return wheel, rotates 360 ° or more with this drive sheave, turns upward through the suspension wheel of the counterweight, and the counterweight side An elevator apparatus comprising a rope that changes direction downward through a return wheel and has the other end fixed to the rope stop of the counterweight.   In an elevator apparatus in which a car and a counterweight suspended by a rope in a hoistway are driven by a hoisting machine, a suspension car provided on the upper part of the car and a suspension car provided on the upper part of the counterweight And, one end is fixed to the rope stop of the car, extending upward from this rope stop, turning downward via the car return car, turning upward via the car suspension, It is wound around the drive sheave of the hoisting machine via the first drive sheave side return wheel, rotates approximately 360 ° with this drive sheave, and turns downward through the second drive sheave side return wheel. The counterweight is turned upward via the counterweight suspension wheel, the direction is changed downward via the counterweight-side return wheel, and a rope having the other end fixed to the counterweight rope stopper is provided. Axial length of the machine is, the elevator apparatus being greater than the diameter of the drive sheave.   In Claim 3, The said 1st drive sheave side return wheel, the 2nd drive sheave side return wheel, and a drive sheave are located in the substantially same height, and the perpendicular projection of each other is substantially parallel, It is characterized by the above-mentioned. Elevator equipment to do.   In an elevator apparatus in which a car and a counterweight suspended by a rope in a hoistway are driven by a hoisting machine, a suspension car provided on the upper part of the car and a suspension car provided on the upper part of the counterweight And, one end is fixed to the rope stop of the car, extending upward from this rope stop, turning downward via the car return car, turning upward via the car suspension, Turn downward through the drive sheave side return wheel and drive sheave, change upward through the counterweight suspension wheel, change downward through the counterweight side return wheel, and change the counterweight A rope fixed at the other end to the rope stopper, and the winding direction to the driving sheave side return wheel and the winding direction to the driving sheave are the same direction, and the rope with respect to the driving sheave A of wrapping angle approximately 450 °, elevator apparatus axial length of the hoisting machine, and greater than the diameter of the drive sheave.   6. The elevator apparatus according to claim 5, wherein the drive sheave return wheel and the drive sheave are positioned at substantially the same height, and their vertical projections are substantially parallel to each other.   7. The elevator apparatus according to claim 5, wherein the drive sheave side return wheel is located between the car suspension and the drive sheave.   The elevator apparatus according to any one of claims 2 to 7, wherein the car-side return wheel has two return wheels.   9. The rope stop of the car according to claim 1, wherein the rope stop of the car is installed at a lower part of the car, and the rope having one end fixed to the rope stop extends in a substantially horizontal direction, An elevator apparatus characterized in that the direction is changed upward via a suspension car provided on a side.   In an elevator apparatus in which a car and a counterweight suspended by a rope in a hoistway are driven by a hoisting machine, a pair of suspension vehicles provided at the lower part of the car and an upper part of the counterweight. An elevator apparatus comprising a suspension wheel, wherein the rope is wound around a driving sheave of the hoisting machine at a winding angle of 360 ° or more.   11. The elevator apparatus according to claim 1, wherein a surface of the rope is covered with a resin.   11. The elevator apparatus according to claim 1, wherein a radius of the drive sheave is small in an axial end portion and large in an axial center.   The elevator apparatus according to claim 12, wherein a sheave surface of the drive sheave has a substantially rotating ellipse shape or a substantially rotating arc shape.   11. The elevator apparatus according to claim 1, wherein a radius of the drive sheave is small on a main body side of the hoist and large on a non-main body side.   The elevator apparatus according to claim 14, wherein a sheave surface of the drive sheave has a substantially truncated cone shape.   11. The elevator apparatus according to claim 1, wherein the sheave surface of the drive sheave is subjected to shot blasting or knurling.   The elevator apparatus according to any one of claims 1 to 10, wherein a sheave surface of the drive sheave is subjected to a plating process such as nickel plating or chrome plating. 11. The elevator apparatus according to claim 1, wherein a sheave surface of the drive sheave is subjected to a shot blasting process or a knurling process and then a plating process such as nickel plating or chrome plating.

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