KR0119661B1 - Hand-rail operation device of an elevator - Google Patents

Abstract

This apparatus comprises a coupling means(30), a bracket(29), a plate-spring(40) and a steel plate part(42). The coupling means(30) is screw-coupled with the end section of the fixed axis. In the bracket(29), a coupling block(33) is weld-attached to the upper face. The plate-spring(40) whose middle part is coupled with the bracket(29) to press a face of the hand rail(27). The steel plate part(42) is bolt-coupled with the bracket(29), and is closest to the lower face of middle portion of the plate-spring(40). Thereby, the maintenance and installation are easy with the user's convenience.

Description

Handrail Drive of Escalator

1 is a front view schematically showing the overall configuration of a handrail drive device of the escalator according to the present invention.

2 is a cross-sectional view taken along the line A-A of FIG.

3 is a rear view showing only the pressure roller device of FIG.

4 is a side view of FIG.

FIG. 5 is a front view showing a shape when the pressure roller device of FIG. 3 becomes a free-form shape before assembly.

* Explanation of symbols for main parts of the drawings

23: fixed shaft 25: handrail drive roller

27: hand rail 29: bracket

30: fastening means 31: mounting bar

32: horizontal bolt 33: fastening block

34: vertical bolt 40: leaf spring

41: pressure roller 40a: strip steel sheet

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a handrail driving device of an escalator, and in particular, a handrail frictionally driven by the handrail drive roller by linear contact with the outer circumferential surface of the handrail drive roller of the escalator is more closely adhered to the handrail drive roller. The present invention relates to a handrail driving device of an escalator used to increase driving force.

In general, the passengers hold the handrail installed at the top of the railing by hand to maintain the same speed and direction as the speed of the moving stairs so as to take a stable posture to the passengers who are occupied in a standing position when driving the escalator.

In this case, a separate handrail driving device is provided to drive the handrail to provide driving capability. The driving device is generally configured to be frictionally driven by frictional contact with the surface of the handrail, and the handrail is driven. There is a tension device in contact with greater pressure.

Among the above-mentioned tension apparatus, the drum type and the coil spring type are mainly used.

The drum type is configured to friction drive as the handrail passes between several small rollers in contact with the outer shell by the weight of the large fixed drum. This is because the drum and the roller are fixed so that foreign matter is attached to the surface of the handrail. The handrail surface was damaged in the process of entering between the drum and the roller, and after a certain time, the changed play between the drum and the roller should be adjusted from time to time, and the surface contact of the handrail touching the outer circumferential surface of the drum itself. Since it is possible to increase the friction force by using the area, the configuration was possible only when the size of the drum was large.

On the other hand, the coil spring method adjusts the effective length of the tension coil spring to apply a pressing force to the handrail, so that the tension coil spring is supported and fixed by screws. It has a very troublesome problem that needs to be readjusted, and it is difficult to adjust it by the unskilled person because it is necessary to adjust the pressing force of the pressure roller corresponding to each handrail drive roller which is composed of several parts. there was.

The present invention has been made to solve the above problems, it can occupy less installation space than the conventional drum method, does not damage the handrail even if foreign matters are introduced, and the clearance adjustment with the handrail drive roller There is no need to do this, and it is possible to prevent the adjustment of the adjustment screw as in the coil spring method, and to provide a handrail driving device of the escalator which can maintain the uniform pressing force of the pressure roller corresponding to the plurality of handrail drive rollers. The purpose is.

In order to achieve the object of the present invention, the handrail is in surface contact with the handrail of the escalator to press the handrail on the outer circumferential surface of the handrail drive roller installed on a plurality of fixed shafts so as to frictionally drive the handrail. In the handrail drive device of the escalator provided with a pressure roller, a mounting bar formed with a predetermined length on the end surface of the fixed shaft is abutted and screwed by a horizontal bolt and connected to each other, and the bottom of the mounting bar of the fastening means A fastening block screwed by a bolt is welded to an upper end, and a lower end thereof is bent and formed inwardly, and a center part is fixed to the bracket and both ends are fixed and installed on the family roller to press one side of the handrail. A leaf spring for applying an elastic force in a predetermined range, and the leaf Is in close contact with the bottom surface central portion of the spring is a handrail drive of the escalator consisting of steel plate member which is bolted to the bracket, is provided.

Hereinafter, an embodiment of a handrail driving apparatus of an escalator according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a front view showing a state in which a pressure roller and a leaf spring according to the present invention are installed in a general handrail driving device, and coupled to the output shaft 11 of the main driving device 10 combined with a speed reducer and a block as shown in FIG. The rotational force generated from the sprocket 12 is transmitted to the handrail sprocket 14 through the chain A 13, and the rotational power of the handrail sprocket 14 is connected to the jack shaft through the chain B 15. 16), and the first tensioner 17 is configured to prevent the chain B 15 from sagging.

In addition, the rotational power transmitted to the jack shaft 16 is transmitted to the plurality of handrail drive sprockets 20 (6 in the illustrated example) through the chain C 18. As shown in FIGS. 1 and 2, idle sprockets 21 are provided between the 20, so that chain C 18 is placed on teeth 20a of the handrail drive sprocket 20. As shown in FIG. The second tensioner 19 is installed to prevent the chain C 18 from sagging.

In addition, the handrail drive sprocket 20 includes a plurality of fixed shafts (six in the illustrated example) welded to form a straight line on one side of the back plate 22 as shown in FIGS. 1 and 2 of the accompanying drawings. It is fitted to the outer ring 24a of the plurality of rolling bearings 24 (two in the illustrated example) fitted on the 23 so as to allow rotational movement freely, and on one end surface of each handrail drive sprocket 20, The rail drive roller 25 is fitted and coupled by a plurality of bolts 26 so as to rotate together with the handrail drive sprocket 20.

The plurality of handrail drive rollers 25 arranged in a line as described above are configured to contact the inner surface of the escalator handrail 27 so that the handrail 27 is friction driven, while the handrail 27 A plurality of pressure rollers 41 are provided to contact the bottom outer surface and press upwards so that the hand rail 27 is in close contact with the hand rail drive roller 25.

Mounting bar 31 formed in a predetermined shape and length on the end surface of the fixed shaft 23 is abutted and screwed by a horizontal bolt 32 connected to each other and the fastening means 30, A fastening block 33 screwed to the bottom of the mounting bar 31 by a vertical bolt 34 is welded to an upper end thereof, and a lower end thereof is bent and formed inward to form a bracket 29 having a C shape, and the bracket 29 The spring is fixed to the center portion and both ends are fixed and installed on the pressure roller 41 to apply an elastic force of a predetermined range to press one surface of the hand rail 27, and the leaf spring (40) Steel plate member 42 is in close contact with the bottom of the central portion of the) is fastened to the bracket (43) bolts (43).

In addition, the leaf spring 40 is composed of, for example, a leaf spring composed of a plurality of strip steel sheet 40a, as shown in Figures 3 to 5 of the accompanying drawings, the bending direction of the both ends of the It should be bent in a bow shape toward the handrail drive roller 25, and should be free-form before assembling as shown in FIG.

In addition, the leaf spring 40 is overlapped from the center of the bottom surface corresponding to the opposite side of the surface of the leaf spring 40 which is subjected to the elastic deformation force (indicated by the arrow T in the drawing) applied to both ends thereof in a form in which both ends are gradually shortened. A strip-steel plate 40a is laminated and formed, while both ends of the uppermost plate of the strip-steel plate 40a are cut to form a c-shaped foot 40c, which is cloud-coupled to the center of the pressure roller 41. On both sides of the roller shaft 47, the slits 48 are formed so that the feet 40c are inserted, and the feet 40c are inserted into the slits 48 thus formed so that the fixing pin 49 is fixed to the rollers. The leaf spring 40 is fixed to the pressure roller 41 by press-fitting the shaft 47.

On the other hand, the width of the trimming portion 40b to be cut in forming the foot 40c is formed larger than the width W2 of the pressure roller 41 so that the pressure roller 41 is inside the trimming portion 40b. In order to be rotated in the material it is preferable to form a width (W1) of the leaf spring 40 slightly wider than the width (W2) of the pressure roller (41).

Meanwhile, in order to fix the mounting bar 31 on the end surface of the fixed shaft 23, a tab hole 44 is formed at the end of the fixed shaft 23, and the mounting bar 31 has a horizontal through hole. Formed a plurality of (45) (for example, two places) to pass through the horizontal bolt 32 is configured to be screwed to each of the tab holes 44, the horizontal through hole 45 of the mounting bar 31 A vertical through hole 46 through which the vertical bolt 34 can penetrate is formed in the middle between the formed, so as to install the fastening block 33 welded to the upper end of the bracket (29).

In addition, the mounting bar 31 has a rectangular cross-sectional shape, as shown in FIGS. 1 and 2, and one mounting bar 31 is installed on two fixed shafts 23. Configured.

In the drawings, reference numeral 50 denotes a stop ring for fixing the handrail drive sprocket 20 and a rolling bearing 24 for guiding rolling thereof, and 51 denotes the bolts 26, 32, 34, and 43. The spring washer to prevent loosening of the shown, 52 is a weld bead formed during welding between the fastening block 33 and the bracket 29, 53 is the back plate 22 is fixedly installed 54 shows a bolt for fixing a bar welded across the back plate 22 before welding to prevent bending of the back plate 22, and 55 indicates the idle bolt. The fixed shaft for freely supporting the rolling rotation of the sprocket 21, 56 is a rolling bearing for rolling coupling the idle sprocket 21 and the fixed shaft 55, 57 is the idle sprocket 21 ) Shows a stop ring for fixing the rolling bearing 56 to be fitted to, and 58 denotes a hard layer buried and fixed so that the handrail drive roller 25 is exposed on the friction surface of the handrail 27. 59 shows a reinforcing piece for reinforcing the handrail 27 that is embedded in the inside of the handrail 27 and is somewhat soft.

Actions and effects other than those of the present invention as described above will be described.

First, the process of driving the handrail 27 of the escalator, when the sprocket 12 of the main drive device 10 is rotated by its output shaft 11, as shown in FIG. Rotational power is transmitted to the handrail sprocket 14 via the chain A 13 so that the handrail sprocket 14 rotates.

At the same time, the power by the rotating handrail sprocket 14 is again transmitted to the jack shaft 16 through the chain B 15, and the power transmitted to the jack shaft 16 is again passed through the chain C 18. The handrail drive sprocket 20 is rotated by being transmitted to the plurality of handrail drive sprockets 20.

The handrail drive sprocket 20 which rotates as described above is integrally fixed with the handrail drive roller 25 as shown in FIG. 2 and attached by the rolling bearing 24 on the fixed shaft 23. Therefore, the handrail 27 rotates together with the plurality of handrail drive rollers 25, and at the same time, the handrail 27 which is in surface contact with the outer circumferential surface of the handrail drive roller 25 has a direction in which the handrail drive roller 25 rotates. Under the same direction, the handrail drive roller 25 receives a frictional force to perform a linear motion.

At this time, since the pressure roller 41 is coupled to both ends of the plate spring 40, the center portion of which is fixed to the bracket 29 installed on the fixed shaft 23, to rotate upward relative to the center of the plate spring 40 Tension is received.

That is, since the pressure roller 41 has a force directed toward the handrail drive roller 25, the handrail 27 positioned therebetween is pushed toward the handrail drive roller 25 so that the handrail 27 The hard insect 58 is in close contact with the outer circumferential surface of the handrail drive roller 25 so that the friction force is applied.

In addition, since the handrail 27 is made of a soft member, the surface contact force is considerably increased, thereby driving without slip.

In the present invention as described above, the pressure roller is capable of flowing as much as possible within the range of elastic motion allowed by the leaf spring, so that even if foreign substances are attached to the handrail being pressed, the pressure roller is lifted to prevent surface damage of the handrail. It eliminates the need for regular clearance adjustment like the conventional drum-type tensioning device, greatly reduces the installation space compared to the drum method, and does not require re-adjustment or adjustment of the effective length as in the conventional coil spring method. There is no need for uniform adjustment of the roller, so even beginners can easily install it.

Claims (2)

Handrail of an escalator having a pressure roller for pressing the handrail against the outer circumferential surface of the handrail drive roller which is surface-contacted with the handrail of the escalator and rotated on a plurality of fixed shafts so as to frictionally drive the handrail. In the driving device, a mounting bar 31 formed in a predetermined length on the end surface of the fixed shaft 23 is abutted by a fastening means 30 screwed by a horizontal bolt 32 and connected to each other; The fastening block 33 screwed to the bottom of the mounting bar 31 of the fastening means 30 by the vertical bolt 34 is welded to the upper end and the lower end is bent inward, bracket (29) and the bra A plate spring 40 having a center portion fixed to the cat 29 and both ends fixed and installed at the pressure roller 41 to apply an elastic force in a predetermined range to press one surface of the hand rail 27; Handrail driving device of the escalator, characterized in that the steel plate member 42 is in close contact with the bottom surface of the central portion of the leaf spring (40) is fastened to the bracket (43). According to claim 1, The leaf spring 40 is formed by overlapping a plurality of strip steel pipe (40a) and both ends of the upper band steel plate (40a) is cut in the middle portion 'c' shaped foot (40c) Handrail driving device of the escalator, characterized in that formed.