JP2019131320A - Elevator balance weight and elevator comprising the same - Google Patents

Abstract

To provide an elevator balance weight that reduces a vertical frame of a frame body of a balance weight.SOLUTION: There is provided an elevator balance weight 800 comprising a plurality of weights 850 and vertically moving in a hoistway, in which a balance frame for attaching the weights 850 includes an upper frame 810 arranged above the balance frame, a lower frame 820 arranged below the balance frame, a first vertical frame 830 and a second vertical frame 840 that connect the upper frame 810 and the lower frame 820, and a stopper 890 for dispersing force added in a horizontal direction, the stopper 890 being attached at each dividing position when the first vertical frame 830 and the second vertical frame 840 are divided into three or more vertically.SELECTED DRAWING: Figure 3

Description

  The present invention relates to an elevator counterweight and an elevator including the same.

  In recent years, elevators have been required to have a structure that is not easily damaged during a disaster such as an earthquake. Conventionally, when an earthquake occurs, the weight frame may fall off the guide rail and the counterweight may be damaged.

  One cause of this is that the counterweight is deformed by the rolling of the earthquake (seismic force).

  Therefore, a thick steel material that takes into account the case of an earthquake is used for the weight frame of the counterweight.

  Generally, the counterweight is provided with guide devices at the upper and lower horizontal ends. In order to disperse the seismic force applied from the weight frame to the guide rail in the event of an earthquake roll, a stopper is provided between the guide device provided above and below the counterweight and the guide device. .

  In order to more effectively distribute the seismic force, the stopper is provided within the range of the center height position of the counterweight block (weight) and the vertical intermediate position of the guide devices provided above and below. .

  Patent Document 1 discloses that a stopper is provided in the vertical direction of a frame of an elevator counterweight.

  Specifically, it is described that a plurality of stopper mounting holes are provided in the vertical frame of the counterweight so that the position of the stopper can be adjusted in accordance with the increased number of weight blocks (weights).

JP 2001-19318 A

  However, in the event of an earthquake, the rolling seismic force is dispersed, but due to the inertial force of the counterweight generated by the seismic rolling, the guide device provided at the upper and lower ends of the weight frame and the stopper provided at the center portion A load is applied to the portion, and the vertical frame of the weight frame is deformed.

  In order not to deform the vertical frame, the size of the vertical frame has to be large enough not to be deformed even at a predetermined seismic intensity.

  An object of the present invention is to reduce the size of the vertical frame of the counterweight frame.

  Another object of the present invention is to reduce the exclusive area of the counterweight in plan view.

An elevator counterweight according to a first aspect of the present invention is an elevator counterweight that includes a plurality of weights and moves up and down in a hoistway,
A weight frame for attaching the weight,
An upper frame disposed above the weight frame;
A lower frame disposed below the weight frame;
A first vertical frame and a second vertical frame connecting the upper frame and the lower frame;
A balance weight for an elevator, including a stopper for dispersing a force applied in a horizontal direction, which is attached to each division position when dividing the first vertical frame and the second vertical frame into three or more in the vertical direction. is there.

  If it is such, the force (for example, seismic force) applied to a counterweight in the horizontal direction (x-axis direction or y-axis direction in this embodiment) will be disperse | distributed also to the vertical frame of a stopper part.

  And since a stopper is attached to each division | segmentation position when dividing a 1st vertical frame and a 2nd vertical frame into 3 or more by the vertical direction (this embodiment z-axis direction), for example, a 1st vertical frame and a 1st vertical frame When a stopper is attached to each division position when dividing the two vertical frames into three in the vertical direction, the number of stoppers is two in the first vertical frame and two in the second vertical frame.

  Therefore, there are a plurality of stoppers, and the force applied in the horizontal direction is distributed to each stopper portion, so that the force applied to the vertical frame of each stopper portion can be reduced.

  Therefore, it is not necessary to scale up the first vertical frame and the second vertical frame in consideration of an earthquake, and as a result, the sizes of the first vertical frame and the second vertical frame can be reduced.

  That is, the area occupied by the counterweight in plan view (xy plan view in the present embodiment) can be reduced.

  An elevator counterweight according to a second aspect of the present invention is the elevator counterweight according to the first aspect, wherein the first vertical frame and the second vertical frame are equally divided into three or more in the vertical direction. It is an elevator counterweight to which the stopper is attached at each division position when dividing.

  By attaching a stopper to each division position when the first vertical frame and the second vertical frame are equally divided into three or more in the vertical direction, the force applied to each stopper is likely to be equal.

  Therefore, when a force is applied in the horizontal direction due to an earthquake or the like, the force applied to each stopper is equalized, and it is possible to suppress a burden on the vertical frame of one stopper portion.

  Therefore, it is not necessary to scale up the first vertical frame and the second vertical frame in consideration of an earthquake, and as a result, the sizes of the first vertical frame and the second vertical frame can be reduced.

  That is, the area occupied by the counterweight in plan view (xy plan view in the present embodiment) can be reduced.

  The balance weight for elevators according to the third aspect of the present invention is the balance weight for elevators according to the first aspect, wherein the first vertical frame and the second vertical frame are positioned at the center of gravity in the vertical direction of the balance weight. Is a counterweight for an elevator in which the stopper is attached to each of the divided positions when divided into three or more.

  That is, the distance may be used as a reference instead of the distance. With such a configuration, the force applied in the horizontal direction with respect to the counterweight is more accurately distributed to the positions of the stoppers.

  Therefore, when a force is applied in the horizontal direction due to an earthquake or the like, the force applied to each stopper is equalized, and it is possible to suppress a burden on one stopper portion of the vertical frame, and to easily prevent the vertical frame from being deformed.

  Therefore, it is not necessary to scale up the first vertical frame and the second vertical frame in consideration of an earthquake, and as a result, the sizes of the first vertical frame and the second vertical frame can be reduced.

  That is, the area occupied by the counterweight in plan view (xy plan view in the present embodiment) can be reduced.

  The elevator which concerns on the 4th aspect of this invention is an elevator provided with the counterweight for elevators which concerns on a 1st aspect, a 2nd aspect, or a 3rd aspect.

  If it is such, since the size of the 1st vertical frame and the 2nd vertical frame can be made small, the exclusive area in planar view of the counterweight in a hoistway can be made small.

  If the exclusive area in the plan view of the counterweight in the hoistway decreases, the exclusive area in the plan view of the car can be increased, or the area in other planar views can be increased.

The perspective view of the general elevator which concerns on this embodiment. The side view schematic diagram of the elevator which concerns on this embodiment. The side view of the counterweight of the elevator which concerns on this embodiment. The AA fragmentary sectional view of the counterweight of the elevator which concerns on this embodiment. The BB partial sectional view of the counterweight of the elevator concerning this embodiment. The side view of the counterweight of the elevator which concerns on this embodiment.

  Hereinafter, an embodiment of an elevator balancing weight 800 according to the present invention will be described with reference to the drawings.

(Elevator 100)
As shown in FIGS. 1 and 2, in the elevator 100, a hoisting machine 200 is installed at the lower part of the hoistway.

  One end portion of the main rope 220 wound around the drive sheave 210 of the hoisting machine 200 is fixed in the hoistway via the first car sheave 232 and the second car sheave 233 attached to the car 230. Yes.

  The other end of the main rope 220 is fixed in the hoistway via a counterweight sheave 860 attached to the counterweight 800.

  When the drive sheave 210 is rotationally driven by a motor (not shown) of the hoisting machine 200, the main rope 220 travels accordingly. Accordingly, the car 230 to which the first car sheave 232 and the second car sheave 233 are attached is guided by the car guide rail 300 and moves up and down in the hoistway.

  Similarly, as the main rope 220 travels, the counterweight 800 to which the counterweight sheave 860 is attached is guided by the counterweight guide rail 242 and moves up and down in the hoistway.

  The direction of travel of the main rope 220 varies depending on the first sheave 211 and the second sheave 212.

  The elevator 100 is provided with a speed governor 400 that mechanically detects that the ascending / descending speed of the car 230 exceeds a predetermined speed. An endless governor rope 600 is wound between the governor sheave 410 of the governor 400 and the tension sheave 500 positioned below the governor sheave 410.

  The governor rope 600 is stretched while being tensioned in parallel with the main rope 220 by the tension sheave 500. A part of the governor rope 600 is fixed to an emergency stop lever 250 that operates an emergency stop device 231 provided on the car 230 side.

  For this reason, the governor rope 600 travels at the same speed as the car 230 in synchronization with the raising and lowering of the car 230. At this time, the speed governor 400 detects the rotational speed of the governor sheave 410 that is rotated at the same speed as the traveling speed of the governor rope 600, thereby detecting an overspeed of the car 230 being lifted and lowered.

  When the ascending / descending speed of the car 230 reaches a first speed exceeding the rated speed (predetermined speed), a brake (not shown) constituting the hoisting machine 200 of the main rope 220 is applied.

  If the car 230 does not stop even when the motor (not shown) is braked, a movable grip (not shown) by the trip lever (not shown) of the governor sheave 410 is reached when the predetermined second speed exceeds the first speed. The support is released, and the travel of the governor rope 600 is stopped by the movable grip.

  The emergency stop lever 250 fixed to the governor rope 600 is pulled up by the governor rope 600 and is pulled up relative to the car 230. As a result, the emergency stop device 231 operates and the car 230 stops.

  If the car 230 does not stop even when the emergency stop device 231 is activated, the car 230 collides with a first oil buffer 700a that is an oil buffer 700 disposed below. The first oil buffer 700a absorbs the impact of the car 230 and stops the car 230.

  A second oil buffer 700b, which is an oil buffer 700, is also disposed below the counterweight 800. When the counterweight 800 falls, the second oil buffer 700b absorbs an impact caused by the drop of the counterweight 800 and stops the counterweight 800.

(Balance weight 800)
As shown in FIGS. 3 to 5, the counterweight 800 includes an upper frame 810 that is disposed on the z-axis positive direction side and extends in the x-axis direction,
a lower frame 820 arranged on the negative z-axis side and extending in the x-axis direction;
A first vertical frame 830 that connects the upper frame 810 and the lower frame 820 and is disposed on the x-axis negative direction side;
A second vertical frame 840 that connects the upper frame 810 and the lower frame 820 and is disposed on the x-axis positive direction side;
A weight 850 disposed in a region surrounded by the upper frame 810, the lower frame 820, the first vertical frame 830, and the second vertical frame 840;
A counterweight sheave 860 attached to the upper frame 810;
A counterweight spacer 870 attached to the lower frame 820;
And a guide device 880 attached to the upper and lower ends of the first vertical frame 830 and the second vertical frame 840.

  The upper frame 810 is disposed above the counterweight 800 and is connected to the first upper end 831 of the first vertical frame 830 and the second upper end 841 of the second vertical frame 840.

  The upper frame 810 is firmly fixed to the first upper end 831 of the first vertical frame 830 and the second upper end 841 of the second vertical frame 840 with bolts.

  A counterweight sheave 860 is rotatably connected to a substantially central portion of the upper frame 810 in the x-axis direction.

  Specifically, the upper frame 810 includes a first upper frame 811 and a second upper frame 812 that is disposed on the y-axis positive direction side of the first upper frame 811.

  Between the first upper frame 811 and the second upper frame 812, the first upper end 831 of the first vertical frame 830, the second upper end 841 of the second vertical frame 840, and the counterweight sheave 860 are sandwiched.

  Between the first upper frame 811 and the second upper frame 812, sheave brackets 813 for preventing the main rope 220 from coming off from the counterweight sheave 860 are attached to both ends of the counterweight sheave 860 in the x-axis direction. It has been.

  In addition, a sheave cover 862 that covers a part of the counterweight sheave 860 is attached to substantially the center of the first upper frame 811 and the second upper frame 812 in the x-axis direction.

  The lower frame 820 is disposed below the counterweight 800 and is connected to the first lower end 832 of the first vertical frame 830 and the second lower end 842 of the second vertical frame 840.

  A counterweight spacer 870 that adjusts the distance between the counterweight 800 and the oil buffer 700b is attached to the lower frame 820 at substantially the center in the x-axis direction.

Specifically, the lower frame 820 includes a first lower frame 821,
A second lower frame (not shown) disposed on the positive side of the y-axis from the first lower frame 821;
A bottom surface portion 823 disposed between the first lower frame 821 and the second lower frame (not shown).

  The bottom surface portion 823 is disposed below the first lower frame 821 and the second lower frame (not shown). A counterweight spacer 870 is connected to the bottom surface portion 823.

  The first vertical frame 830 is disposed on the x-axis negative direction side from the second vertical frame 840, and the upper frame 810 is connected to the first upper end 831 disposed on the z-axis positive direction side, and is disposed on the z-axis negative direction side. A lower frame 820 is connected to the first lower end 832.

  A first guide device 881 that is a guide device 880 is connected to the first upper end 831 of the first vertical frame 830.

  A second guide device 882 that is a guide device 880 is connected to the first lower end 832 of the first vertical frame 830.

  A first stopper 891 and a second stopper 892 that are stoppers 890 are connected between the first upper end 831 and the first lower end 832 of the first vertical frame 830.

  The second vertical frame 840 is disposed on the x-axis positive direction side from the first vertical frame 830, the upper frame 810 is connected to the second upper end 841 disposed on the z-axis positive direction side, and is disposed on the z-axis negative direction side. A lower frame 820 is connected to the second lower end 842.

  A third guide device 883 that is a guide device 880 is connected to the third upper end 841 of the second vertical frame 840.

  A fourth guide device 884 that is a guide device 880 is connected to the second lower end 842 of the second vertical frame 840.

  A third stopper 893 and a fourth stopper 894 which are stoppers 890 are connected between the second upper end 841 and the second lower end 842 of the second vertical frame 840.

  The first vertical frame 830 and the second vertical frame 840 have a structure in which both ends in the y-axis direction protrude toward the weight 850 in the xy plan view (for example, C-shaped steel).

  With such a structure, the weight 850 is partially covered by the first vertical frame 830 and the second vertical frame 840 and is difficult to come off.

  A plurality of weights 850 are installed in a weight frame composed of the upper frame 810, the lower frame 820, the first vertical frame 830, and the second vertical frame 840.

  The number of weights 850 is not limited. In the present embodiment, the weight 850 includes a main weight 851 and a subweight 852.

  The main weight 851 is thicker than the subweight 852 and is heavier than the subweight 852.

  The subweight 852 is thinner than the main weight 851 and lighter than the main weight 851. The subweight 852 makes it easy to adjust the overall weight.

  In the present embodiment, the plurality of weights 850 are pressed and fixed by a first fixing member 853 and a second fixing member 854 that are fixing members for fixing the weight 850.

  The first fixing member 853 is disposed on the first vertical frame 830 side, and is connected to the first vertical frame 830 by the first bracket 855.

  The second fixing member 854 is disposed on the second vertical frame 840 side, and is connected to the second vertical frame 840 by a second bracket 856.

  Specifically, the first fixing member 853 is fastened to fastening means (welded nut or the like) provided on the first bracket 855, so that one end abuts on the weight 850 and holds the weight 850. .

  Similarly, the second fixing member 854 is fastened to fastening means (welded nut or the like) provided on the second bracket 856, so that one end abuts on the weight 850 and holds down the weight 850.

  The counterweight sheave 860 is a sheave on which the main rope 220 travels. As the main rope 220 travels on the counterweight sheave 860, the counterweight 800 moves up and down.

  The counterweight sheave 860 is circular in the xz plan view and has a shaft 861 at the center.

  The shaft 861 is connected to the first upper frame 811 and the second upper frame 812 so that a counterweight sheave 860 can rotate. The counterweight sheave 860 rotates about the shaft 861.

  The counterweight spacer 870 is attached to the lower frame 820. Specifically, the counterweight spacer 870 is connected to the bottom surface portion 823 of the lower frame 820.

  In the present embodiment, the number of counterweight spacers 870 is 1, but a plurality of counterweight spacers 870 may be attached.

  The guide device 880 is for the counterweight 800 to move along the counterweight guide rail 242.

  A first guide device 881 that is a guide device 880 is attached to the first vertical frame 830, and a second guide device 882 that is a guide device 880 is attached to the first lower end 832.

  A third guide device 883 that is a guide device 880 is attached to the second upper end 841, and a fourth guide device 884 that is a guide device 880 is attached to the second lower end 842 of the second vertical frame 840.

  The stopper 890 is disposed between the first guide device 881 and the second guide device 882 and between the third guide device 883 and the fourth guide device 884.

  The stopper 890 is for dispersing the force applied in the y-axis direction from the first vertical frame 830 and the second vertical frame 840 to the counterweight guide rail 242.

  This makes it difficult for the counterweight 800 to come off the counterweight guide rail 242 during an earthquake or the like.

  Specifically, the stopper 890 disperses the seismic force (earthquake load) applied from the first vertical frame 830 and the second vertical frame 840.

  Usually, the stopper 890 is arranged in the z-axis direction of the first vertical frame 830 and the second vertical frame 840 to disperse the seismic force applied to the counterweight guide rail 242 from the first vertical frame 830 and the second vertical frame 840. Installed in the approximate center.

  However, when rolling due to an earthquake or the like occurs, a load is applied to the portion provided with the stopper 890 of the first vertical frame 830 or the second vertical frame 840 due to the inertial force of the counterweight generated by the rolling of the earthquake, The first vertical frame 830 or the second vertical frame 840 is deformed.

  Even if the stopper 890 is provided only at one location near the center of the first vertical frame 830 and the second vertical frame 840 in the z-axis direction, the first vertical frame 830 and the second vertical frame are It will be deformed.

  Therefore, in the embodiment according to the present invention, four or more stoppers 890 are attached to the first vertical frame 830 and the second vertical frame 840. Specifically, the stopper 890 is attached to the first vertical frame 831 at two or more locations and the second vertical frame 832 at two or more locations.

  The stopper 890 is configured to cover a part of the counterweight guide rail 242 in the xy plan view.

  That is, as shown in FIG. 5, the stopper 890 has a shape along a part of the shape of the rail portion 242 a of the counterweight guide rail 242 in the xy plan view.

  Further, the stopper 890 has a substantially L shape in the xz plan view, and is fixed to the first vertical frame 830 or the second vertical frame 840 by a bolt 895.

  Due to such a shape, even when the counterweight 800 sways in the y-axis direction due to an earthquake roll or the like, the seismic force is further dispersed by the plurality of stoppers 890.

  Therefore, even if the first vertical frame 830 and the second vertical frame 840 are not thick (scaled up) so as not to be deformed, the first vertical frame 830 and the second vertical frame 840 are not easily deformed due to an earthquake roll or the like. .

  Therefore, as a result, the first vertical frame 830 and the second vertical frame 840 are smaller than the conventional one, and the weight frame is smaller.

  That is, the exclusive area of the counterweight 800 in the xy plan view can be reduced.

<First Embodiment>
In the present embodiment, the stopper 890 is provided at two locations on the first vertical frame 830 and at two locations on the second vertical frame 840.

  That is, the first vertical frame 830 is attached with the first stopper 891 that is the stopper 890 and the second stopper 892.

  The first stopper 891 is disposed closer to the z-axis positive direction than the second stopper 892.

  Similarly, a third stopper 893 that is a stopper 890 and a fourth stopper 894 are attached to the second vertical frame 840.

  The third stopper 893 is disposed closer to the z-axis positive direction than the fourth stopper 894.

  In the present embodiment, the first stopper 891 is attached to a position 2/3 from the bottom of the entire length of the first vertical frame 830 in the z-axis direction.

  FIG. 5 is a plan view of the fourth stopper 894, but the other stoppers 890 (the first stopper 891, the second stopper 892, and the third stopper 893) have the same structure.

  In addition, the second stopper 892 is attached to a position 1/3 from the bottom of the entire length of the first vertical frame 830 in the z-axis direction.

  Similarly, the third stopper 893 is attached at a position 2/3 from the bottom of the entire length of the second vertical frame 840 in the z-axis direction.

  Further, the fourth stopper 894 is attached to a position 1/3 from the bottom of the entire length of the second vertical frame 840 in the z-axis direction.

  Specifically, as shown in FIG. 3, a stopper 890 is attached at a position that equally divides the total length L in the z-axis direction of the first vertical frame 830 and the second vertical frame 840 into three.

  That is, the distance from the upper end of the first vertical frame 830 and the second vertical frame 840 to the first division position P1 is L1, the distance from the first division position P1 to the second division position P2 is L2, and from the second division position p2. When the distance to the lower ends of the first vertical frame 830 and the second vertical frame 840 is L3, the values of L1, L2, and L3 are the same.

  The first stopper 891 is attached to the first vertical frame 830 with a bolt 895 at the position of the first division position P1.

  Similarly, the third stopper 893 is attached to the second vertical frame 840 by a bolt 895 at the position of the first division position P1.

  The second stopper 892 is attached to the first vertical frame 830 with a bolt 895 at the position of the second division position P2.

  Similarly, the fourth stopper 894 is attached to the second vertical frame 840 with a bolt 895 at the position of the second division position P2.

  By providing the first stopper 891, the second stopper 892, the third stopper 893, and the fourth stopper 894, the force applied in the horizontal direction (x-axis direction or y-axis direction) (for example, the seismic force of earthquake roll) , Dispersed in each stopper 890 portion.

<Second Embodiment>
In the second embodiment, a plurality of stoppers 890 are arranged based on the center of gravity of the counterweight 800 in the z-axis direction. Note that the same configuration as in the first embodiment may be omitted or briefly described.

  As shown in FIG. 6, the first center-of-gravity position P3 is the center-of-gravity position of the entire length L in the vertical direction (z-axis direction) of the counterweight 800.

  The second barycentric position P4 is a barycentric position of a distance L3 + L4 from the first barycentric position P3 to the upper ends of the first vertical frame 830 and the second vertical frame 840.

  The third barycentric position P5 is a barycentric position of a distance L5 + L6 from the first barycentric position P3 to the lower ends of the first vertical frame 830 and the second vertical frame 840.

  A stopper 890 is attached to the second centroid position P4 and the third centroid position P5 with respect to the first centroid position P3.

  Specifically, a fifth stopper 896 which is a stopper 890 is attached to the second center of gravity position P4 of the first vertical frame 830.

  A sixth stopper 897 that is a stopper 890 is attached to the third center of gravity position P5 of the first vertical frame 830.

  A seventh stopper 898 which is a stopper 890 is attached to the second center of gravity position P4 of the second vertical frame 840.

  An eighth stopper 899 that is a stopper 890 is attached to the third gravity center position P5 of the second vertical frame 840.

  By providing the fifth stopper 896, the sixth stopper 897, the seventh stopper 898, and the eighth stopper 899, a force applied in the horizontal direction (x-axis direction or y-axis direction) (for example, the seismic force of earthquake roll) , Dispersed in each stopper 890 portion.

  In this embodiment, the seismic calculation of the first vertical frame 830 and the second vertical frame 840 is performed at four locations, so that the size of the first vertical frame 830 and the second vertical frame 840 in the xy plan view can be suppressed.

  The present invention can be implemented in a mode in which various improvements, modifications, or variations are added without departing from the spirit of the present invention.

100 ... Elevator 200 ... Hoisting machine 230 ... Cage 242 ...
DESCRIPTION OF SYMBOLS 300 ... Guide rail 400 ... Speed governor 500 ... Tension sheave 600 ... Governor rope 700 ... Oil buffer 800 ... Balance weight 810 ... Upper frame 820 ... Lower frame 830 ... 1st vertical frame 840 ... 2nd vertical frame 850 ... Weight 860 ... Balance Weight sheave 870 ... Buffer 880 ... Guide device 890 ... Stopper

Claims (4)

A balance weight for an elevator having a plurality of weights and moving up and down in a hoistway,
A weight frame for attaching the weight,
An upper frame disposed above the weight frame;
A lower frame disposed below the weight frame;
A first vertical frame and a second vertical frame connecting the upper frame and the lower frame;
A balance weight for an elevator, including a stopper for dispersing a force applied in the horizontal direction, which is attached to each of the divided positions when the first vertical frame and the second vertical frame are divided into three or more in the vertical direction. The balance weight for an elevator according to claim 1, wherein the stopper is attached to each of the divided positions when the first vertical frame and the second vertical frame are equally divided into three or more in the vertical direction. 2. The elevator balance according to claim 1, wherein the stopper is attached to each of the divided positions when the first vertical frame and the second vertical frame are divided into three or more on the basis of the center of gravity in the vertical direction of the counterweight. Weight. An elevator provided with the counterweight for elevators according to claim 1.

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