JP7031781B1 - Elevator balance chain - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce an increase in bending radius in a balance chain 5 for reducing vibration and noise caused by contact between links 6a and 6b constituting a metal chain 6 to reduce the diameter when curved. It is possible to obtain a balance chain for elevators that enables space saving. SOLUTION: Flexible strings 8 and 9 are spirally wound around a metal chain 6 constituting a balance chain for an elevator connecting a cage and a balance weight provided at a position facing the cage. [Selection diagram] Fig. 2

Description

The present disclosure relates to a balance chain for an elevator, which is composed of a metal chain connecting a basket and a counterweight.

In the conventional elevator balance chain, a synthetic resin coating layer is provided on the metal chain body in order to prevent noise due to vibration between the links of the metal chains constituting the balance chain by a simple process. This coating layer is formed by spraying a synthetic resin onto a metal chain or by immersing the metal chain in a synthetic resin (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 11-287299

In the above-mentioned conventional elevator balance chain, the metal chain body is integrally covered with a synthetic resin coating layer, not for each link. When the balance chain is to be bent for packing or storage, the tension of the coating layer acts on the balance chain, so that the bending radius is larger than that of the balance chain not coated with the synthetic resin, and it becomes difficult to bend. Therefore, it is necessary to increase the diameter when the balance chain is curved, and there is a problem that it is difficult to save space, for example, a large storage space is required.

The present disclosure has been made in view of the above problems, and in an elevator balance chain that reduces vibration and noise due to contact between links constituting a metal chain, the diameter when curved is reduced. The purpose is to obtain a balance chain for elevators that can be used.

The balance chain for the elevator according to this disclosure is composed of a metal chain connecting the cage and the counterweight provided at the position facing the cage, so that the two flexible strings are staggered. With a metal chain spirally wound around the surface of the metal chain , the metal chain is composed of multiple annular links, the inner circumferences of the links are in contact with each other, connected to each other, and two flexible. The string is spirally wrapped around the outer circumference of the link, the two flexible strings are wound around the metal chain without penetrating the holes in the link, and the two flexible strings are. It is not connected by an engaging tool .

The balance chain for an elevator of the present disclosure includes a metal chain around which a flexible string is wound, so that the bending radius is reduced while reducing vibration and noise caused by contact between the links constituting the metal chain. In order to suppress the increase in the amount of noise, the diameter when curved can be reduced, which makes it possible to save space.

It is a side view of the elevator using the balance chain for an elevator in Embodiment 1. FIG. It is a front view of the balance chain for an elevator in Embodiment 1. FIG. It is a side view of the balance chain for an elevator in Embodiment 1. FIG. It is sectional drawing of the link in Embodiment 1. FIG. It is a state diagram at the time of action of the resin band used in Embodiment 1. FIG. It is a front view of the balance chain for an elevator in Embodiment 2. FIG. It is a side view of the balance chain for an elevator in Embodiment 2. FIG.

Embodiment 1.
The elevator balance chain according to the first embodiment will be described in detail below. The same reference numerals in the drawings represent the same or equivalent configurations. In the elevator shown in FIG. 1, a hoisting pulley 1 that is rotationally driven by a hoisting machine is installed, and a hoisting wire rope 2 is hung on the hoisting pulley 1 so as to hang down. A balancing weight 3 is connected to one end of the hoisting wire rope 2, and a basket 4 is connected to the other end. The balance weight 3 is provided at a position facing the basket 4.

As shown in FIGS. 2 to 5, the balance chain 5 is composed of a metal chain 6 and two resin bands 8 and 9 which are flexible strings, and a balance weight is provided at one end thereof. 3 is connected to the other end, and the car 4 is connected to the other end. The resin used for these bands 8 and 9 is, for example, a synthetic resin. Moreover, the cross-sectional shape is rectangular. The metal chain 6 is composed of a plurality of annular links 6a and 6b, and the inner circumferences 7a of the links are in contact with each other so that the links 6b are positioned perpendicularly to the links 6a and are connected to each other. The first resin band 8 and the second resin band 9 are spirally wound around the surface of the metal chain 6 so as to be in contact with the outer peripheral 7b of the link. The outer circumference 7b of the link referred to here refers to a surface including the longest circumference when the link 6a shown in FIG. 2 is viewed from the front and the link 6b shown in FIG. 3 is viewed from the side surface. FIG. 4 is a cross-sectional view of one link 6a, 6b. The outer circumference 7b of the link is a portion indicated by an arrow on the arc in FIG.

A mechanism for reducing the bending radius of the balance chain 5 configured in this way will be described. In the conventional balance chain, the metal chain body is covered integrally with the synthetic resin coating layer, not for each link, so when trying to bend the balance chain, it is pulled horizontally with respect to the axis of the balance chain. The tension of the coating layer acts. Therefore, the range of motion of each link is limited, and the bending radius of the balance chain becomes large. On the other hand, in the balance chain 5 of the present disclosure, the surface of the metal chain 6 and the resin bands 8 and 9 are not adhered to each other. Therefore, when the balance chain 5 is to be bent, the links 6a and 6b slide on the resin bands 8 and 9 and rotate, so that the bending radius of the balance chain 5 becomes small.

Next, the operation of the first resin band 8 and the second resin band 9 in the balance chain 5 configured in this way will be described with reference to FIG. By spirally winding the resin bands 8 and 9 around the surface of the metal chain 6, a force F is applied to the link 6b. The force F is a resultant force applied in the horizontal direction and the vertical direction with respect to the axis of the metal chain. Therefore, the force F suppresses the link 6b from moving in the horizontal and vertical directions with respect to the axis of the metal chain 6. This makes it difficult for the inner circumferences 7a of the link to separate from each other, and even if the inner circumferences 7a of the link are separated from each other, vibration and noise due to recontact between the link 6a and the link 6b can be reduced. Further, by sandwiching the link 6b between the two bands 8 and 9, even if the link 6b moves and vibrates, the vibration can be suppressed, and further, the bands 8 and 9 absorb the vibration energy of the link 6b. Noise can be reduced.

At this time, since the resin bands 8 and 9 apply a force F symmetrically to the link 6b, the first resin band 8 is right-handed and the second resin band 9 is left-handed. It is preferable to spirally wind the metal chain 6 so that the two bands 8 and 9 are wound alternately.

Further, in the balance chain 5 in which the first resin band 8 and the second resin band 9 are spirally wound around the metal chain 6 in this way, the link 6a and the link 6a next to the link 6a are formed. Resin bands 8 and 9 are sandwiched between the spaces and between the link 6b and the link 6b next to the link 6b. As a result, the contact between the links 6a and the contact between the links 6b are prevented, so that the vibration and noise due to the contact between the links 6a and 6b can be reduced. At this time, in order to prevent all the links 6a and 6b from coming into contact with each other without leakage, it is preferable to cross the first resin band 8 and the second resin band 9 on all the links 6a.

Further, in the balance chain 5 in which the first resin band 8 and the second resin band 9 are spirally wound around the metal chain 6 in this way, the increase in the bending radius is suppressed. Since it is easy to bend, when the balance chain 5 is installed in the elevator, the suspension interval W between the car 4 and the balance weight 3 can be shortened. Further, when the balance chain 5 is stored, it has an effect that it can be stored in a small space.

If the widths of the resin bands 8 and 9 are wide enough to pass between the links 6a, the contact between the links 6a and the links 6b can be prevented more effectively, so that vibration and noise are generated. Contributes to reduction. Further, by winding the resin bands 8 and 9 around the metal chain 6 without penetrating the holes of the links 6a and 6b, it is possible to reduce the trouble of passing through the holes of the links 6a and 6b, and the balance chain 5 can be used. Contributes to improved productivity.

It has been explained that the metal chain 6 is composed of a plurality of annular links 6a and 6b, but the two plates are located so as to face each other, and the plates are arranged so as to be connected to each other in parallel. A roller chain made of metal may be used.

Embodiment 2.
The elevator balance chain according to the second embodiment will be described in detail with reference to FIGS. 6 and 7. In the elevator balance chain of the first embodiment, the resin bands 8 and 9 are wound around the metal chain 6. On the other hand, in the second embodiment, instead of winding the resin bands 8 and 9, a string obtained by twisting a plurality of thread-like members or a string 10 or 11 having a circular cross section is wound around the metal chain 6. The balance chain 5 is configured.

Even in the elevator balance chain configured in this way, the first string 10 and the second string 11 act on the link 6b as in the elevator balance chain shown in the first embodiment. Even if the inner circumferences 7a of the link are separated from each other, the vibration and noise caused by the recontact between the link 6a and the link 6b can be reduced. Further, since the strings 10 and 11 suppress the vibration of the links 6a and 6b and absorb the vibration energy, the vibration and noise of the balance chain for the elevator can be reduced.

When the strings 10 and 11 are used, the area in contact with the links 6a and 6b is smaller than that of the bands 8 and 9, so that the frictional force generated between the strings 6a and 6b is reduced. Therefore, when the balance chain 5 is bent, the links 6a and 6b slide on the strings 10 and 11 and easily rotate, so that the bending radius of the balance chain 5 becomes smaller.

By the way, in the first or second embodiment, an example using the bands 8, 9 or the strings 10 and 11 has been described, but the string is not limited to these, and the string is elongated and can be wound or tied to the metal chain 6. Anything can be used. Specifically, the cross-sectional shape of the elongated string-shaped resin is not limited to a rectangle and a circle, and may be any shape such as a polygon such as a triangle or a hollow pipe shape.

Further, the string is not limited to that made of synthetic resin as long as it is flexible so that the bending radius can be reduced, and any material such as natural resin or fiber such as hemp may be used.

3 Balanced weight, 4 basket, 5 Balance chain, 6 Metal chain, 6a link, 6b link, 7a link inner circumference, 7b link outer circumference, 8 1st resin band, 9 2nd resin Band, 10 first string, 11 second string

Claims (4)

In an elevator balance chain consisting of a metal chain that connects a basket, a counterweight provided at a position facing the basket, and a metal chain.
The metal chain is provided with the metal chain spirally wound around the surface of the metal chain so that the two flexible strings are staggered.
The metal chain is composed of a plurality of annular links, and the inner circumferences of the links are in contact with each other and are connected to each other.
The two flexible strings are spirally wound around the outer circumference of the link.
The two flexible cords are wrapped around the metal chain without penetrating the holes in the link.
The two flexible strings are not connected by an engaging tool
Elevator balance chain featuring that. The balance chain for an elevator according to claim 1 , wherein the two strings intersect every other on the plurality of annular links. The balance chain for an elevator according to claim 1 or 2 , wherein the two strings are made of a synthetic resin. The balance chain for an elevator according to claim 3 , wherein the two strings are strips made of synthetic resin.

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