JP2008273650A - Counterweight of elevator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a counterweight for preventing derailment when lateral swinging vibration is caused in a guide rail, for example, by an earthquake. <P>SOLUTION: An upper sliding surface 15c formed on the weight body 14 side of the counterweight 1, is seated on a lower sliding surface 13a formed on the frame 6 side. A weight body 14 is slidably supported in the horizontal direction by a frame 6. When relatively strong lateral swinging vibration is caused in the frame 6 via the guide rail 2, for example, by the earthquake, vibration of the weight body 14 is reduced by actively slidingly moving the weight body 14 to the frame 6. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an elevator counterweight, and more particularly to an elevator counterweight that prevents a rail from being removed due to rolling vibration caused by an earthquake or the like.

As this type of counterweight, for example, a technique described in Patent Document 1 has been proposed. In the technique described in Patent Document 1, an inner frame that houses a weight body is provided in a substantially rectangular outer frame that moves up and down along a guide rail, and a rubber member is interposed between the inner frame and the outer frame. When the rolling vibration on the building frame due to an earthquake or the like is transmitted to the outer frame via the guide rail, the rolling vibration of the inner frame is absorbed by the rubber member, so that the guide rail The horizontal load applied is reduced to prevent the counterweight from coming off the rail.
Japanese Patent Laid-Open No. 3-88689

  In the technique described in Patent Document 1, roll vibration due to an earthquake or the like is absorbed by a rubber member, so that the counterweight caused relatively weak roll vibration as the elevator moved up and down during normal operation of the elevator. In this case, there is a possibility that the stable lifting and lowering movement of the counterweight may be hindered due to the inner frame swinging in the outer frame.

  The present invention has been made in view of the above problems, and in particular, when a relatively weak roll vibration occurs during normal up-and-down movement, the relative displacement of the weight body with respect to the frame is regulated, for example, by an earthquake or the like. When the frame generates relatively strong roll vibration, the weight body is positively displaced relative to the frame to reduce the horizontal load applied to the guide rail and prevent the counterweight from coming off the rail. The purpose is to do.

  According to the first aspect of the present invention, in an elevator counterweight in which a weight body is supported by a frame that moves up and down along a guide rail, an upper slip surface formed on the weight body side is formed on the frame side. It is characterized by being seated on the surface and supporting the weight body so that it can slide in the horizontal direction relative to the frame.

  Therefore, according to the first aspect of the present invention, for example, when the frame is subjected to relatively weak rolling vibration during normal operation of the elevator, the sliding movement of the weight main body with respect to the frame is caused by the static frictional force between both sliding surfaces. On the other hand, the weight body slides relative to the frame when the frame causes a relatively large roll vibration due to, for example, an earthquake, and the force to slide the sliding surfaces overcomes the static friction force. In addition, the rolling vibration transmitted to the weight body is reduced.

  More preferably, when the frame and the weight main body are connected via the elastic member as in the invention described in claim 2, when the weight main body slides relative to the frame, the weight is restored by the restoring force of the elastic member. The main body can be pulled back to the position before the sliding movement.

  Further, as in the invention according to claim 3, a plurality of weight pieces are laminated on a slide plate having an upper slide surface, and the slide plate and each weight piece are inserted through the slide plate and each weight piece. If the weight body is formed by integrally connecting the counterweight, it is desirable to simplify the structure of the counterweight.

  Furthermore, as in the invention described in claim 4, a plurality of weight main bodies are provided, and a plurality of lower sliding surfaces corresponding to the respective weight main bodies are formed on the frame side. If each formed upper slip surface is seated on the corresponding lower slip surface, the surface pressure between each lower slide surface and the upper slip surface can be reduced, especially when the weight body is heavy. it can.

  According to the first aspect of the present invention, when the frame generates a relatively weak roll vibration, the frame causes a relatively strong roll vibration while the sliding movement of the weight body with respect to the frame is prevented. In this case, the weight main body slides relative to the frame, and the rolling vibration transmitted to the weight main body is reduced. When strong roll vibration is generated, the horizontal load applied to the guide rail can be reduced to prevent the counterweight from coming off the rail.

  FIG. 1 is a front view showing a counterweight of an elevator as a more specific embodiment of the present invention, and FIG. 2 is a sectional view taken along line AA in FIG.

  As shown in FIGS. 1 and 2, a pair of guide rails 2 for guiding an elevator counterweight 1 is fixed to a horizontal support beam 3 on the building frame side via a rail bracket 4 and a rail clip 5 in the vertical direction. It is erected along.

  The frame 6 of the counterweight 1 includes left and right vertical frames 7 having a substantially channel cross section, an upper frame 8 that connects the upper ends of the vertical frames 7, and a lower frame 9 that connects the lower ends of the vertical frames 7. Are suspended by a plurality of (three in the illustrated example) main ropes 10 having one end fixed to the upper frame 8, and are driven up and down along the guide rail 2. ing.

  In the frame 6, guide shoes 11 having a substantially U-shaped cross section are provided at both upper and lower ends of both vertical frames 7, and the frame 6 is guided by the guide shoes 11 to both guide rails 2. In addition, an intermediate stopper 12 having a substantially fork shape in plan view that sandwiches the guide rail 2 is provided at an intermediate portion between the vertical frames 7.

  A lower sliding plate 13 is fixed to the upper surface of the lower frame 9, and a lower sliding surface 13 a is formed on the upper surface of the lower sliding plate 13 with a predetermined surface finish. The weight body 14 is accommodated in a substantially slot-shaped space between the vertical frames 7 and is seated on the lower sliding surface 13a.

  The weight main body 14 is configured by laminating a plurality of weight pieces 16 having the same shape in plan view with the upper slide plate 15 on the upper slide plate 15, and the upper slide plate 15 and each weight piece 16 are arranged in the longitudinal direction. There are wide portions 15a and 16a formed at the center portion, and narrow portions 15b and 16b formed at both ends in the longitudinal direction and engaged with both vertical frames 7 respectively. Further, the upper slide plate 15 and the weight pieces 16 are integrally coupled with through bolts 17 as fastening members that pass through the narrow portions 15b and 16b in the stacking direction.

  An upper sliding surface 15c having a predetermined surface finish is formed on the lower surface of the upper sliding plate 15, and the upper sliding surface 15c is seated on the lower sliding surface 13a on the frame 6 side, whereby the weight body 14 Is supported to be slidable in the horizontal direction with respect to the frame 6. Here, the coefficient of friction between the sliding surfaces 13a and 15c is set so that a slip occurs between the two when a relatively strong roll vibration occurs in the frame 6, and the friction coefficient of the frame 6 during normal operation is relatively high. For weak roll vibration, no slip occurs between the sliding surfaces 13a and 15c.

  That is, predetermined gaps G are provided in the horizontal direction, that is, in the front-rear and left-right directions, between the upper sliding plate 15 and the narrow portions 15b, 16b of the weight pieces 16 and the vertical frames 7, respectively. The weight body 14 is prevented from coming off from the frame 6 while positively allowing relative displacement in the horizontal direction with the weight body 14.

  Further, the frame 6 includes a cross beam 18 that connects the vertical frames 7 above the weight main body 14, and the weight block 16 and the cross beam 18 in the uppermost layer of the weight main body 14 are rubber blocks 19 that are elastic members. It is connected through.

  Therefore, in the elevator counterweight 1 configured as described above, the upper sliding surface 15c on the weight body 14 side is seated on the lower sliding surface 13a on the frame 6 side. When a relatively weak roll vibration is generated, the sliding movement of the weight body 14 with respect to the frame 6 is prevented by the static frictional force between both sliding surfaces, while the frame 6 is relatively moved to the frame 6 through the guide rail 2 due to an earthquake or the like. When the strong rolling vibration is generated and the sliding force between the sliding surfaces 13a and 15c overcomes the static frictional force, the weight body 14 slides with respect to the frame 6, and the dynamic frictional force between the sliding surfaces 13a and 15c. The rolling vibration of the weight main body 14 is reduced. In other words, for example, when a relatively large roll vibration is generated in the frame 6 due to an earthquake or the like, the weight main body 14 is actively slid relative to the frame 6, and the dynamic friction force generated during the sliding movement causes the frame 6 to move from the frame 6. The rail weight 1 is prevented from coming off by attenuating the vibration that is about to act on the weight body 14 and reducing the horizontal load and deflection acting on the guide rail 2.

  When the frame 6 and the weight body 14 are relatively displaced in the horizontal direction, the rubber block 19 is elastically deformed, and the rubber block 19 pulls the weight body 14 back to the position before the relative displacement with a restoring force based on the elastic deformation. Become.

  That is, according to the present embodiment, when the frame 6 vibrates relatively weakly, the sliding movement of the weight main body 14 with respect to the frame 6 is prevented by the static frictional force between the sliding surfaces 13a and 15c. When a relatively strong vibration occurs, the weight main body 14 slides with respect to the frame 6, and the rolling vibration of the weight main body 14, which is a heavy object, is attenuated by friction between the sliding surfaces 13 a and 15 c. The horizontal load applied to the guide rail 2 is reduced when a relatively strong roll vibration occurs in the frame 6 due to, for example, an earthquake without hindering the smooth lifting and lowering movement of the counterweight 1 during normal operation. Thus, it is possible to prevent the counterweight 1 from coming off the rail.

  FIG. 3 is a front view showing a counterweight of an elevator as a second embodiment of the present invention.

  The second embodiment shown in FIG. 3 divides the internal space of the frame 6 vertically by an intermediate beam 20 having a lower slide plate 13 fixed to the upper surface and a rubber block 19 fixed to the lower surface. A weight main body 14 is provided on each lower sliding plate 13 provided on the frame 9. In other words, a plurality of (in the illustrated example, two) weight bodies 14 are provided, and a plurality of lower slide plates 13 corresponding to the respective weight bodies 14 are provided on the frame 6 side, and upper portions on the weight body 14 side are provided. The sliding surface 15c is seated on the corresponding lower sliding surface 13c on the frame 6 side.

  Therefore, in the second embodiment, particularly when the weight of the counterweight 1 is heavy, the surface pressure between the sliding surfaces 13a and 15c can be lowered by providing a plurality of weight bodies 14. There are benefits.

It is a figure which shows the 1st Embodiment of this invention, Comprising: The front view which shows the counterweight of an elevator. AA sectional drawing in FIG. It is a figure which shows the 2nd Embodiment of this invention, Comprising: The front view which shows the counterweight of an elevator.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Counterweight 2 ... Guide rail 6 ... Frame 13a ... Lower sliding surface 14 ... Weight main body 15 ... Upper sliding plate 15c ... Upper sliding surface 16 ... Weight piece 17 ... Through bolt (fastening member)
19 ... Rubber block (elastic member)

Claims (4)

In the elevator counterweight where the weight body is supported by a frame that moves up and down along the guide rail,
An elevator characterized in that the upper sliding surface formed on the weight body side is seated on the lower sliding surface formed on the frame side, and the weight body is supported so as to be slidable in the horizontal direction with respect to the frame. Counterweight.   The elevator counterweight according to claim 1, wherein the frame and the weight main body are connected via an elastic member.   A weight body is formed by laminating a plurality of weight pieces on a sliding plate having an upper sliding surface, and integrally connecting the sliding plate and each weight piece with a fastening member for inserting the sliding plate and each weight piece. The elevator counterweight according to claim 1 or 2, wherein the elevator counterweight is provided.   A plurality of weight main bodies, and a plurality of lower slide surfaces corresponding to the respective weight main bodies are formed on the frame side, and upper slide surfaces formed on the respective weight main body sides are respectively corresponding to the lower slides. The elevator counterweight according to any one of claims 1 to 3, wherein the elevator counterweight is seated on a surface.

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