KR20210049658A - Over speed and converse driving prevention aparatus of escalator - Google Patents

Abstract

The present invention relates to an overspeed and reverse driving prevention device for an escalator. A pole and a connecting part are installed to be connected by a tension spring. Thus, when a pawl is inserted into gears of a ratchet and the pawl is pressed by the ratchet, the tension spring is tensioned and fully inserted into the ratchet and can be applied to escalators of various sizes. By installing a braking member on the inner peripheral surface of a brake arm installed on the outside of a ratchet part or a rotation shaft or the external peripheral surface of a device facing the brake arm, an additional braking force is applied to an escalator rotation shaft to prevent damage to a brake lining installed on the ratchet part. Even if the brake lining is damaged and the braking force cannot be properly exerted, it is possible to prevent overspeed and reverse rotation of an escalator. Because the device of the present invention can be installed without a separate drilling work on the escalator rotation shaft and an escalator support frame. Thus, it is possible to reduce the installation costs and installation periods and prevent deterioration of durability caused by a drilling work.

Description

Over speed and converse driving prevention aparatus of escalator}

The present invention relates to a device for preventing overspeed and reverse running for an escalator, and in detail, an escalator rotating shaft that moves steps of an escalator using a pole and a ratchet prevents overspeed or reverse rotation, and It relates to an overspeed and reverse running prevention device for an escalator capable of increasing a braking force by additionally installing a braking member in contact with an outer circumferential surface.

An escalator is a means of transport that automatically moves people or cargo to the upper and lower floors by moving stairs with power.

Such an escalator is widely used in public facilities such as subways and department stores, and has an advantage that many people can use it at once because the speed is slow but can be operated continuously.

In general, in the escalator, the electric chain moves through a rotating shaft rotated by a drive motor, and a plurality of steps are sequentially moved along an inclined surface to move up or down. Such an escalator rides a large number of people at once, and when operated for a long time, reverse rotation or speeding occurs due to mechanical or electronic defects or malfunctions.

In order to solve this problem, Korean Patent Registration No. 10-1888950 (name of invention: reverse rotation prevention device for escalator) (hereinafter referred to as “conventional technology”) was developed.

1 is a perspective view of the prior art, and FIG. 2 is an exploded perspective view of FIG. 1.

As shown in Figs. 1 and 2, the prior art 100 supports the escalator rotating shaft 5 on which the driving sprocket 6, which is the driving means of the escalator, is installed, and the escalator, which is an internal structure already installed in the escalator. It is installed on the frame 7.

The prior art 100 is a ratchet gear module 110 fastened and fixed on the escalator rotation shaft 5, and is selectively connected to the ratchet gear module 110 to reverse the escalator or rotate at a speed exceeding the normal running speed ( Hereinafter referred to as'overspeed') is detected, by limiting the rotation of the ratchet gear module 110, the driving module 120 stopping the rotation of the escalator rotation shaft 5, and the reverse rotation and speeding of the escalator rotation shaft 5 It consists of a solenoid unit 130 that operates the driving module 120 by a signal from a sensing unit (not shown) that senses it.

The ratchet gear module 110 is formed in a cogwheel shape and is coupled to the outer side of the escalator rotation shaft 5 and rotates, and is formed in a ring shape, and is coupled to both left and right sides of the ratchet wheel 111, respectively. The ratchet fixing flanges 112 and 112 ′, which are in contact with the outer surfaces of the ratchet fixing flange 112, respectively, the brake linings 113 and 113 ′, and the brake linings 113 and 113 ′. ) And the side flanges 114 and 114 ′, which are located outside the ratchet wheel 111 and the protrusions 1141 inserted into the inside of the ratchet fixing flange 112, are formed in a ring shape, and are formed in a ring shape, and the ratchet wheel ( It consists of a bushing 115 inserted between the 111 and the side flange 114, and main brackets 116 and 116' located outside of the side flanges 114 and 114'.

The ratchet wheel 111 is formed in a cogwheel shape and rotates by being coupled to the outside of the escalator rotation shaft 5, and the escalator rotates in reverse or overspeed due to engagement with the stopper unit 121 of the driving module 120 to be described later. When it occurs, the rotation is stopped, thereby stopping the rotation of the escalator rotation shaft 5.

The brake lining 113 is in contact with the outer surface of the ratchet fixing flange 112, respectively, and when the rotation of the ratchet wheel 111 is restricted by the stopper portion 121 to be described later, the ratchet is fixed in combination with the ratchet wheel 111 By stopping the rotation of the ratchet wheel 111 by friction with the outer surface of the flange 112, the rotation of the escalator rotation shaft 5 is stopped.

The side flange 114 is formed in a hollow cylindrical shape, is located outside the brake lining 113 and is coupled with the escalator rotation shaft 5 to integrally rotate the ratchet gear module 110 by the rotation of the escalator rotation shaft 5 To be able to do it.

At this time, the side flange 114 includes a side flange body 1141 formed in a hollow cone shape, and a flange 1142 extending outward to the outer circumferential surface of the side flange body 1141 and to which the brake lining 113 is coupled to the inner surface. Done.

In addition, a plurality of fastening grooves 1143 are formed in the side flange body 1141, so that the side flanges 114 and 114' are in contact with each other by the wrench bolts 1144. Are combined.

The bushing 115 is formed in a ring shape, and is inserted and installed between the assembly of the ratchet wheel 111 and the ratchet fixing flange 112 and the side flange 114 to prevent abrasion due to friction, and the ratchet wheel 111 and The combination of the ratchet fixing flange 112 and the side flange 114 are completely in close contact so as not to be spaced apart.

The main bracket 116 is connected to the driving module 120 to maintain a fixed state without being rotated, and a first bracket 1161 having an arc-shaped fixing part 1162 with an open one side, and an open ring shape It is formed of a second bracket (1163) that is coupled to the fixing portion (1162) of the first bracket (1161).

At this time, the main bracket 116 has the fixing part 1162 of the first bracket 1162 and the inner circumferential surface of the second bracket 1163 on the outer circumferential surface of the side flange body 1141 of the side flange 114 and a roller (not shown). It is contacted by, and is connected to the driving module 120 to maintain a fixed state without rotating, so it absorbs the shock generated when the rotation of the escalator rotation shaft 5 is stopped.

The driving module 120 is a stopper unit 121 that is caught by the ratchet wheel 111 to limit the rotation of the ratchet gear module 110, and a driving unit connected between the stopper unit 121 and the solenoid unit 130 ( 122 and a supporter unit 123 that is installed on the escalator support frame 7 already installed on the escalator so that the prior art 100 can be fixedly supported.

The stopper unit 121 is rotatably coupled to the front end of the driving unit 122, and the front end of the escalator is caught by the ratchet wheel 111 by the driving unit 122 when the escalator is overspeed and reversed to rotate the ratchet gear module 110 The pole 1211 to limit the pole, and a connector 1212 protruding from the top of the pole 1211 to allow the pole 1211 to be connected to the driving unit 122, and a pole installed through the center of the pole 1211 It comprises a pole shaft (1213) to be able to rotate (1211).

The driving unit 122 has a circular rod shape, one end is connected to the connector 1212 of the stopper unit 121 and the other end is connected to the solenoid unit 130.

At this time, the driving unit 122 rotates the stopper unit 121 as it moves forward or backward by the solenoid unit 130, so that the pawl 1211 of the stopper unit 121 is caught by the ratchet wheel 111 and the ratchet gear module Limit the rotation of (110).

The supporter part 123 is connected to the pre-installed escalator support frame 7 and serves to allow the prior art 100 to be fixedly supported, and the first support frame 1231 and the second support frame ( 1235).

The first support frame 1231 includes a front plate 1232 coupled with the main bracket 116, a rear plate 1233 fixedly installed in front of the escalator support frame 7, a front plate 1232 and a rear plate. It is made of a connecting piece 1234 connecting the 1223, and supports the ratchet gear module 110 and the driving module 120.

The second support frame 1235 is installed at the rear of the first support frame 1231 and the escalator support frame 7, and supports the solenoid part 130.

At this time, a long hole into which the driving unit 122 of the driving module 120 is inserted is formed in the center of the front plate 1232 and the rear plate 1233 and the escalator support frame 7.

In the prior art 100 configured as described above, when the reverse rotation of the escalator rotation shaft 5 is detected by the reverse rotation detection unit, the driving unit 122 of the driving module 120 is moved forward by the solenoid unit 130. , Accordingly, the pole 1211 of the stopper part 121 rotates around the pole shaft 1213, and the end of the pole 1211 is caught by the ratchet wheel 111, thereby limiting the rotation of the ratchet wheel 111 to the escalator. Can prevent reverse driving.

However, in the prior art 100, the length of the driving unit 122 is not variable, and the distance that the driving unit 122 can move forward from the solenoid unit 130 is limited, so that the driving unit 122 has installation errors and solenoids. When the distance that the driving unit 122 moves forward decreases due to a cause of a malfunction of the unit 130, the rotation angle of the pole 1211 that is connected to the driving unit 122 and moves circularly decreases. As the pawl 1211 is partially inserted between the gears of the ratchet wheel 111, the contact area becomes smaller and the braking force is reduced.

In addition, in the prior art 100, a through hole (not shown) is drilled in the escalator support frame 7 to install the supporter part 123, thereby increasing the installation time and reducing the strength of the escalator support frame 7 As a result, there is a problem in that the escalator support frame 7 is damaged by an impact generated in the process of preventing the escalator from running in reverse.

In addition, in the prior art 100, a fixing hole (not shown) is drilled in the escalator rotation shaft 5 to fix the side flange 114 installed on the escalator rotation shaft 5, thereby reducing installation time and cost. Increasing and decreasing the strength of the escalator rotating shaft 5 has a problem in that the rotating shaft 5 of the escalator may be damaged.

In addition, in the prior art 100, when the pawl 1211 is inserted into the ratchet wheel 111, the outer surface of the ratchet fixing flange 112 in which the brake linings 113 and 113 ′ are combined with the ratchet wheel 111 The rotation of the escalator shaft 5 is stopped by applying frictional force to the ratchet wheel 111, but when the escalator floor height increases and the load on the escalator increases, the brake linings 113, 113' It is not only difficult to secure sufficient braking force with only the frictional force of the motors, but also the braking torque increases and the brake linings 113 and 113' are damaged, so that the function of preventing overspeed and reverse running of the escalator may be lost. .

The present invention is to solve this problem, and the problem of the present invention is to install a tension spring between the pole and the connection part that rotates the pole by the operation of the driving part, so that the rotation angle of the pole is limited due to installation errors, etc. It is to provide a device for preventing overspeed and reverse running for an escalator in which the tension spring is tensioned so that the pawl can be completely inserted into the inside of the ratchet.

In addition, another problem of the present invention is to apply an additional braking force to the escalator rotation shaft by installing a braking member on the inner circumferential surface of the brake arm installed outside the ratchet part or the rotation shaft or the outer circumferential surface of the device facing the brake arm. It is to prevent damage to the lining, and to provide an overspeed and reverse running prevention device for an escalator that can prevent overspeed and reverse rotation of the escalator even if the brake lining is damaged and the braking force is not properly exerted. It is to increase the braking force applied to the rotating shaft of the escalator by installing a braking member on the inner circumferential surface of the device or the outer circumferential surface of the rotating shaft.

In addition, another problem of the present invention is to reduce the working time by making it possible to install the escalator's rotating shaft and support frame without perforating work, and to prevent the durability of the escalator's rotating shaft and support frame from being deteriorated by perforating work. It is to provide an overspeed and reverse running prevention device for an escalator.

In addition, another problem of the present invention is that the connection part that rotates the pole by the operation of the driving part is connected using a spring member, so even if the rotation angle or length of the pole is limited due to installation errors, the length of the connection part is reduced by the spring. It is to provide a device for preventing overspeed and reverse running for an escalator that is variable so that the pole can be completely inserted into the inside of the ratchet.

Although a number of undescribed solutions exist in the present invention, they will be described in the course of describing the embodiments.

The solution of the present invention for solving the above problem is a ratchet wheel that is rotatably installed on an escalator rotation shaft, and a friction unit that is installed on both sides of the ratchet wheel and in friction contact with the ratchet wheel and is coupled to the rotation shaft to rotate together. Made ratchet; A detection sensor that detects rotation of the rotation shaft; A support frame for supporting other objects as a structure installed inside the escalator; A support part installed on the support frame; A rotation limiting unit installed on the support and inserting a locking means into the ratchet wheel to limit rotation of the ratchet wheel, and the support unit is coupled to the support frame; It includes a friction movable body that is coupled to one side of the support and is installed to be spaced apart from the ratchet part.

According to the present invention having the above problems and solutions, when the pole and the connection part are installed to be connected by a tension spring, when the pole is pressed by the ratchet when the pawl is inserted into the gears of the ratchet, the tension spring is tensioned to the inside of the ratchet. It is fully inserted and can be applied to various standard escalators.

In addition, according to the present invention, by installing a braking member on the inner circumferential surface of the brake arms installed on the outside of the ratchet part or the rotation shaft or the outer circumferential surface of the device facing the brake arms, an additional braking force is applied to the rotating shaft of the escalator to damage the brake lining installed in the ratchet part. In addition, it is possible to prevent the escalator from overspeeding and reverse rotation even if the brake lining is damaged and the braking force cannot be properly exercised.

In addition, according to the present invention, by installing a braking member on the inner circumferential surface of the device facing the rotating shaft or on the outer circumferential surface of the rotating shaft, it is possible to prevent damage to the brake lining installed in the ratchet by applying additional braking force to the rotating shaft of the escalator. Even if the braking force is not properly exercised, the escalator can be prevented from overspeeding and reverse rotation.

In addition, according to the present invention, since it is possible to install the escalator rotating shaft and the escalator support frame without additional drilling, it is possible to reduce the installation cost and the installation period, as well as to prevent the deterioration of durability caused by the punching work.

1 is a perspective view of the prior art.
2 is an exploded perspective view of FIG. 1.
3 is a perspective view showing an apparatus for preventing speeding and reverse running for an escalator according to a first embodiment of the present invention.
4 is an exploded perspective view of FIG. 3.
5 is an exploded perspective view of the ratchet portion of FIG. 3.
6 is an exploded perspective view of the support portion of FIG. 3.
7 is a cross-sectional view of FIG. 3.
8 is a cross-sectional view illustrating a process in which the rotation limiting unit of FIG. 7 operates.
9 is a perspective view of an escalator speeding and reverse running prevention device according to a second embodiment of the present invention.
10 is a perspective view of the pole support of FIG. 9.
11 is a cross-sectional view of a device for preventing speeding and reverse running for an escalator according to a third embodiment of the present invention.
12 is a perspective view of the ratchet wheel of FIG. 11.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

3 is a perspective view showing an escalator speeding and reverse running prevention device according to a first embodiment of the present invention, and FIG. 4 is an exploded perspective view of FIG. 3.

As shown in FIG. 3, the escalator overspeed and reverse running prevention device 1 includes an escalator rotating shaft 5 on which a driving sprocket 6, which is a driving means of an escalator, is installed, and an escalator supporting other objects as an internal structure of the escalator. It is installed on the support frame (7).

At this time, for convenience of explanation, a direction from the escalator support frame 7 toward the rotation shaft 5 will be defined as a front, and a direction from the rotation shaft 5 toward the escalator support frame 7 will be defined as rear.

As shown in FIGS. 3 and 4, the escalator overspeed and reverse running prevention device 1 includes a ratchet part 10 installed on the rotating shaft 5, a support part 20 installed on the escalator support frame 7, It is installed on the support part 20 and is inserted into the ratchet part 10 when necessary, and consists of a rotation limiting part 30 that restricts the rotation of the ratchet part 10.

In addition, a detection sensor (not shown) that detects reverse rotation or overspeed of the escalator rotation shaft 5 is installed on one side of the driving sprocket 6 of the escalator, and the detection sensor detects reverse rotation or overspeed of the escalator rotation shaft 5. At this time, a detection signal is output to the rotation limiting unit 30.

At this time, the components constituting the ratchet part 10 are separated into two pieces forming a semicircular shape, and a semicircular groove is formed inside each of the separated semicircular pieces, so that the bolt without separating the escalator rotation shaft 5 It is configured to be easily coupled using a fastening means such as.

5 is an exploded perspective view of the ratchet portion of FIG. 3.

The ratchet part 10 includes a ratchet wheel 11 that is rotatably installed on the escalator rotation shaft 5, and a disk 12, 12' formed in a hollow disk shape and coupled to both sides of the ratchet wheel 11, respectively. And a stopper installed to be spaced apart from the outer surfaces of the brakes 13 and 13', respectively, and the brakes 13 and 13' which are in contact with the outer surfaces of the disks 12 and 12' Base (15) installed between the (14), (14') and the outer circumferential surface of the escalator rotating shaft (5) and the ratchet wheel (11) and the disk (12), the braking part (13), and the inner circumferential surface of the stopper (14) Consists of

The ratchet wheel 11 is installed so that gears in the shape of a toothed wheel are formed on the outside, and a shaft insertion hole is formed therein so that the inner circumferential surface is in contact with the outer circumferential surface of the base 15.

At this time, since the ratchet wheel 11 is not coupled to the base 15, it rotates separately from the base 15.

The disk 12 is formed in the shape of a hollow disk, and is rotated integrally with the ratchet wheel 11 by being bolted to and coupled to both sides of the ratchet wheel 11.

The braking part 13 is installed on both sides of the disks 12 and 12', and includes a brake lining 131 and a lining cover 132.

The brake lining 131 is formed in the shape of a hollow disk, and is made of a material having a high coefficient of friction.

The lining cover 132 is a cover body 1321 in the shape of a hollow disk, an insertion hole 1322 into which the brake lining 131 is inserted, and a pressing bolt 144 is fastened to the outer surface of the cover body 1321 Bolt fastening grooves 1323 are formed.

At this time, the brake lining 131 is inserted into the insertion groove 1322 of the lining cover 132 and is coupled by bolting, and since the thickness is thicker than the depth of the insertion groove 1322, it protrudes from the lining cover 132.

In addition, in the brake lining 131, a portion protruding from the lining cover 132 is in contact with the outer surfaces of the disks 12 and 12' to generate friction.

The stopper 14 includes a stopper body 141 having a hollow cylindrical shape, pressing bolt fastening holes 142 formed at regular intervals by drawing a circular path on both sides of the stopper body 141, and the stopper body 141. It consists of fixing bolt fastening grooves 143 formed at regular intervals on the outer circumferential surface and communicated to the inner circumferential surface.

At this time, the pressure bolt fastening holes 142 are formed in positions corresponding to the pressure bolt fastening grooves 1323 formed in the lining cover 132, and the lining cover 132 and the stopper 14 are pressure bolt fastening holes 142 Are coupled by the pressure bolts 144 that are fastened to the pressure bolt fastening grooves 1323.

At this time, the pressing bolts 144 apply a pressing force inward to the braking part 13 so that the brake lining 131 is in close contact with the disk 12, and between the brake lining 131 and the disk 12 according to the magnitude of the pressing force. The friction force will change.

In addition, the stopper 14 is the fixing bolts 145 are fastened to the fixing bolt fastening grooves 143, and the ends of the fastened fixing bolts 145 press the base 15 and the outer circumferential surface of the rotation shaft 5 (15) and the stopper 14 are rotated together with the escalator rotation shaft 5 by the pressing force.

At this time, since the braking part 13 is coupled with the stoppers 14 by the pressing bolts 144, the braking part 13, the stopper 14, and the rotation shaft 5 rotate together.

In addition, since the stopper 14 is coupled to the rotation shaft 5 by pressing the fixing bolts 145 on the outer circumferential surface of the escalator rotation shaft 5, it can be installed without performing a separate drilling work on the escalator rotation shaft 5.

The base 15 is formed in a hollow cylindrical shape, the inner circumferential surface is in contact with the outer circumferential surface of the escalator rotation shaft 5, and the outer circumferential surface is the ratchet wheel 11 and the disk 12, the braking part 13, the inner circumferential surface of the stopper 14 It is installed to be in contact with.

The base 15 prevents the ratchet wheel 11, the disk 12, the braking part 13, and the inner circumferential surface of the stopper 14 from being in direct contact with the outer circumferential surface of the escalator rotating shaft 5 and being worn by friction.

At this time, the base 15 is preferably made of a material having excellent elasticity and abrasion resistance.

In the ratchet part 10 configured as described above, the ratchet wheel 11 and the disk 12 are rotated in the same direction as the rotation shaft 5 by the frictional force with the brake lining 131 in normal times, but the speed of the rotation shaft 5 Alternatively, when reverse rotation occurs, the poles 31 of the rotation limiting part 30 are inserted between the gears of the ratchet wheel 11 by the rotation limiting part 30 to rotate the ratchet wheel 11 and the disk 12. This is limited.

At this time, since the disc 12 and the braking part 13 are in frictional contact by the brake lining 131, a frictional force acts on the braking part 13 in a direction opposite to the rotational direction of the rotation shaft 5.

In addition, since the braking part 13, the stopper 14, and the rotation shaft 5 are in a coupled state, the rotational speed of the rotation shaft 5 gradually decreases due to the frictional force acting on the braking part 13, and eventually the escalator rotation shaft ( 5) rotation is stopped.

In addition, since the stopper 14 is fixed to the escalator rotation shaft 5 by the pressing force of the fixing bolt 145, the ratchet part 10 does not need to drill a separate fixing hole in the escalator rotation shaft 5, so the installation time is reduced. , It is possible to prevent the strength of the rotating shaft 5 from decreasing by the fixing hole.

6 is an exploded perspective view of the support of FIG. 3, and FIG. 7 is a cross-sectional view of FIG. 3.

The support part 20 includes a friction movable body 21 and a support 22 installed at the rear of the friction movable body 21 and coupled to the escalator support frame 7.

In addition, the friction movable body 21 is composed of brake arms 211 formed in a “⊂” shape, and a pole support 212 that is coupled to the ends of the brake arms 211 and is installed with a rotation limiting unit 30. .

The brake arm 211 is installed on the inner circumferential surface of the curved portion 2111 in a semicircular ring shape, extension portions 2112 extending parallel from both ends of the curved portion 2111, and the curved portion 2111 and the extended portion 2112 It consists of a braking member (2113).

At this time, for convenience of explanation, it has been described as an example that the braking member 2113 is installed on the inner circumferential surfaces of the curved part 2111 and the extension part 2112, but the installation position and shape of the braking member 2113 are not limited thereto, It may be installed on the outer circumferential surface of the stopper 14 or the like.

In addition, the curved portion 2111 has a diameter of an inner circumferential surface larger than that of an outer circumferential surface of the stopper 14.

In addition, the braking member 2113 installed on the inner circumferential surfaces of the curved portion 2111 and the extended portion 2112 also has a diameter of the inner circumferential surface larger than the diameter of the outer circumferential surface of the stopper 14.

In addition, the extension parts 2112 are coupled to the pole support 22 by bolting at the rear end thereof. At this time, the brake arm 211 is installed so that the stopper 14 is located therein.

The pole support 212 is made of a pair of flat plates 2121 and 2121 ′ that are installed to be spaced apart from each other, and a connecting plate 2122 connecting the flat plates 2121 and 2121 ′.

The flat plates 2121 and 2121 ′ are formed with flanges 2123 extending outwardly at the upper and lower ends, respectively, and bolt holes penetrating the upper and lower surfaces are formed in front of the flanges 2123 to form brake arms 211. And bolted together.

In addition, an insertion hole 2124 into which the rotation limiting part 30 is inserted is formed in the plates 2121 and 2121'.

In addition, first bolt insertion holes 2125 into which bolts (not shown) are inserted into the rear of the insertion hole 2124 are formed in the flat plates 2121 and 2121′.

The first bolt insertion holes 2125 are formed of long holes formed in a horizontal direction, and a plurality of first bolt insertion holes 2125 are formed in a vertical direction.

The pole support 212 is coupled with the support 22 by bolts inserted into the first bolt insertion holes 2125, and since the first bolt insertion holes 2125 are formed of long holes formed in the horizontal direction, the support ( 22) can be adjusted to the front and rear.

For this reason, when the support part 20 is installed on escalators having different distances between the rotating shaft 5 and the support frame 7 of the escalator, the support part 20 is separately installed by changing the installation position of the support base 22 installed on the pole support 212. Installation is possible without performing any welding work, etc.

In addition, second bolt insertion holes 2126 are formed above the first bolt insertion holes 2125 in the flat plates 2121 and 2121'.

The second bolt insertion holes 2126 are formed of long holes formed in a vertical direction, and a plurality of second bolt insertion holes 2126 are formed in a horizontal direction.

The pole support 212 is coupled with the driving unit 33 by bolts inserted into the second bolt insertion holes 2126, and the driving unit ( 33) can be adjusted vertically.

The support 22 includes a contact body 221 coupled with the support frame 7 and a protrusion body 222 protruding forward of the contact body 221.

The contact body 221 is formed in a “c” shape, and an opening may be additionally formed at the top so that the rear end of the driving unit 33 can be inserted.

In addition, the contact body 221 is formed with a plurality of third bolt insertion holes 2211 formed in the vertical direction.

Plate-shaped support plates 2212 are coupled to the third bolt insertion holes 2211 of the contact body 221 by bolting.

At this time, since the support plates 2212 are formed of long holes in which the third bolt insertion holes 2211 are formed in a vertical direction, the installation positions of the support plates 2212 can be adjusted in the vertical direction.

These support plates 2212 may be positioned so as to contact the upper and lower surfaces of the support frames having different heights for each escalator.

The protruding body 222 is formed to protrude forward of the contact body 221, and a plurality of bolt holes penetrating through both sides are formed.

This protruding body 222 is inserted into the flat plates 2121 and 2121' of the pole support 212, and the pole support 212 and the pole support 212 by bolts inserted into the first bolt insertion holes 2125 Are combined.

At this time, since the first bolt insertion holes 2125 formed in the pole support 212 are formed of long holes formed in the horizontal direction, the installation position of the support 22 can be adjusted to the front and rear.

The support part 20 configured in this way is the position of the contact parts of the support base 22 in contact with the escalator support frame 7 through the first bolt insertion holes 2125 and the third bolt insertion hole 2211 having a long hole shape. Because it can be adjusted, separate cost or time is not consumed when installing on escalators of different standards.

In addition, the support 20 is installed in contact with the escalator support frame 7 by the contact body 221 of the support 22, so that it can be installed without performing a separate drilling work on the escalator support frame 7 And it is possible to save time and at the same time prevent the strength of the support frame 7 from being reduced due to the perforation work.

In addition, since the support part 20 is coupled by bolts inserted into the first bolt insertion hole 2125 of a long hole shape, the friction movable body 21 and the support base 22 are coupled to each other, so when a force greater than the tightening force of the bolts acts, friction occurs. The fuselage 21 is moved forward or backward.

When the rotation of the ratchet wheel 11 is limited by the rotation limiting unit 30, the support 20 is formed by the rotational force of the ratchet wheel 11 applied to the rotation limiting unit 30 so that the friction movable body 21 is It is pressed and moves to the rear.

At this time, the brake arms 211 installed in front of the friction movable body 21 exert a friction force on the stopper 14 by contacting the braking member 2113 installed on the inner circumferential surface with the outer circumferential surface of the stoppers 14, and thereby, the escalator rotation shaft The braking force applied to (5) increases.

As shown in FIG. 7, the rotation limiting unit 30 is inserted between the gears of the ratchet wheel 11 to limit the rotation of the ratchet wheel 11, and the pawl 31 and the driving unit 33 ) And a driving part 33 that rotates the pole 31 by moving the connection part 32.

The pole 31 is rotatably installed with a pole body 311 having a hollow cylindrical shape, a hooking part 312 protruding from the outer circumferential surface of the pole body 311, and a pole body 311 or a hooking part 312 And it consists of a connector 32 and a connector 313 coupled by a hinge.

In addition, the pole 31 is installed through the pole shaft 314 to the inside of the pole body 311, and the pole shaft 314 is inserted into the insertion hole 2124 of the pole support 212 and thus the pole support 212 It is coupled to be rotatable.

At this time, the protrusion 3121 is formed at the end of the locking part 312 to increase the weight of the end, and as the weight increases, the speed at which the locking part 312 is inserted between the gears of the ratchet wheel 11 increases. do.

In addition, the pawl 31 is installed so as to be rotatable only within a preset angle, so that when it is inserted between the gears of the ratchet wheel 11, it is prevented from being over-rotated and separated from the gears.

The connection part 32 has a connector 313 of the pole 31 and a tension spring 321 at one end hinge-coupled, a connection rod 322 connected at the other end and one end of the tension spring 321, and a long plate shape. It is formed and consists of a connecting plate 323 to which the other end of the connecting rod 322 is vertically coupled, and a driving rod 324 that is coupled to both ends of the connecting plate 323 and the driving unit 33, respectively.

At this time, the connecting plate 323 is coupled by the connecting rod 322 and the driving rod 324 and nuts (not shown), and by adjusting the fastening positions of the nuts, the escalator rotation shaft 5 and the support frame 7 The distance of the connection part 32 can be adjusted according to the distance between them.

The driving unit 33 is installed on the pole support 212, and when overspeed or reverse rotation is detected by the detection sensor, the driving rod 324 of the connection unit 32 is moved forward.

8 is a cross-sectional view illustrating a process in which the rotation limiting unit of FIG. 7 operates.

8A is a process in which the locking part 312 is inserted into the ratchet wheel 11 by the driving unit 33 when an overspeed or reverse driving monitoring signal is output from the reverse rotation sensor, and (b) is a ratchet wheel. When the pole 31 inserted into (11) is pressed by the gears of the ratchet wheel 11, the tension spring 321 of the connection part 32 is tensioned so that the locking part 312 of the pawl 31 becomes the ratchet wheel. It is a process that is completely inserted into the inside of (11).

As shown in (a) of Figure 8, the escalator overspeed and reverse running prevention device 1 moves the driving rod 324 forward when the overspeed and reverse rotation detection signals are output from the reverse rotation detection sensor. The connecting plate 323 and the connecting rod 322 are linearly moved forward together.

At this time, the tension spring 321 has one end connected so as to be rotatable with the connecting rod 322 so that both linear and rotational movements are performed at the same time, and the other end is hinged with the connector 313 of the pole 31 As the tension spring 321 moves in a straight line and rotation, the pole 31 rotates, and the locking part 312 of the pole 31 is inserted into the gears of the ratchet wheel 11.

In addition, as shown in (b) of FIG. 8, the device 1 for preventing overspeed and reverse running for an escalator is a ratchet in which the locking part 312 of the pawl 31 is inserted into the gears of the ratchet wheel 11 to rotate backward. When pressed in contact with the gears of the wheel 11, the pawl 31 rotates so that the locking portion 312 of the pawl 31 is completely inserted into the ratchet wheel 11.

At this time, since the driving rod 324 coupled with the driving unit 33 has a limited distance that can be moved forward from the driving unit 33, the driving rod 324, the connecting plate 323, and the connecting rod 322 are Although the movement range is limited, this limited movement range is extended by tensioning the tension spring 321 of the connection part 32 by the rotational force of the ratchet wheel 11.

Through this, the engaging portion 312 of the pawl 31 is completely inserted into the gears of the ratchet wheel 11, and thus the contact area between the locking portion 312 of the pawl 31 and the gears of the ratchet wheel 11 As this increases and the braking force increases, the escalator overspeed and reverse running prevention device 1 can effectively prevent the escalator from running in reverse.

In addition, when the pawl 31 is inserted between the gears of the ratchet wheel 11, it is pressed backward by the rotational force of the ratchet wheel 11, and the friction movable body 21 coupled with the pawl 31 is also pressed backward. .

In addition, the friction movable body 21 moves backward when the rotational force of the ratchet wheel 11 is stronger than the tightening force of the bolts inserted into the first bolt insertion holes 2125 that couple the friction movable body 21 and the support 22 And, the braking member 2113 of the brake arm 211 installed in front of the friction movable body 21 is in contact with the stopper 14.

At this time, the braking member 2113 of the brake arm 211 is in contact with the stopper 14 to apply a frictional force in a direction opposite to the rotational direction of the stopper 14, thereby increasing the braking force applied to the escalator rotating shaft 5.

9 is a perspective view of an escalator speeding and reverse running prevention device according to a second embodiment of the present invention, and FIG. 10 is a perspective view of the pole support of FIG. 9.

The escalator overspeed and reverse running prevention device 2 of FIG. 9 is a second embodiment of the present invention, and includes the ratchet portion 10, the support portion 20, and the rotation limiting portion 30 of FIGS. 3 and 4 described above.

At this time, the support 20 is composed of a friction movable body 21 and a support 22 as described above.

In addition, the friction movable body 21 is made of the above-described brake arm 211, and further includes a pole support 411.

As described above, the pole support 411 is made of a connection plate (not shown) connecting the pair of flat plates 4111 and 4111' and the flat plates 4111 and 4111', but the flat plate 4111 ) And (4111') are formed with rear flanges 4112 extending outwardly at the rear ends of the rear flanges 4112, and auxiliary brake arms 4113 having a "⊂" shape are installed on the front side of the rear flange 4112, respectively.

The rear flange 4112 is formed to extend outwardly at the rear end of the flat plates 4111 and 4111', and the rear end of the auxiliary brake arm 4113 is coupled to the front.

The auxiliary brake arm 4113 includes a semicircular ring-shaped curved portion 4114, an extension portion 4115 extending from both ends of the curved portion 4114, and braking installed on the inner circumferential surfaces of the curved portion 4114 and the extended portion 4115. It consists of a member 4116.

At this time, for convenience of explanation, it has been described that the braking member 4116 is installed on the inner circumferential surface of the auxiliary brake arm 4113, but the installation position of the braking member 4116 is not limited thereto, and the auxiliary brake arm 4113 It may be installed on the outer peripheral surface of the escalator rotary shaft 5 in contact with the inner peripheral surface of.

In addition, the curved portion 4114 has an inner diameter larger than the outer diameter of the escalator rotating shaft 5. In addition, the braking member 4116 installed on the inner circumferential surfaces of the curved portion 4114 and the extension portion 4115 is also formed with a diameter of the inner circumferential surface larger than the outer diameter of the escalator rotation shaft 5.

In addition, the rear end portion of the extension part 4115 is coupled to the rear flange 4112.

In the escalator overspeed and reverse running prevention device 2 configured as described above, the pawl 31 is inserted into the gears of the ratchet wheel 11 and a rotational force is applied by the ratchet wheel 11 so that the friction movable body 21 moves backward. When moving, the braking member 2113 installed on the brake arms 211 comes into contact with the stoppers 14 to apply a frictional force to the stopper 14 and at the same time, the braking member 4116 installed on the auxiliary brake arms 4113 They are in contact with the rotating shaft 5 to apply frictional force to the rotating shaft 5, thereby increasing the braking force applied to the escalator rotating shaft 5.

Through this, the overspeed and reverse running prevention device 2 for the escalator increases the braking force than when the rotation of the escalator rotation shaft 5 is stopped only by the frictional force of the brake lining 131 and the braking member 223 installed on the brake arm 211. As a result, it is possible to more effectively prevent the escalator from running in reverse.

At this time, the escalator overspeed and reverse running prevention device 2 has been described as an example to be installed together with the brake arms 211 and the auxiliary brake arms 4113 for convenience of description, but the present invention is not limited thereto. Only the auxiliary brake arm 4113 may be installed.

11 is a cross-sectional view of a device for preventing overspeed and reverse running for an escalator according to a third embodiment of the present invention, and FIG. 12 is a perspective view of the ratchet wheel of FIG. 11.

The escalator overspeed and reverse running prevention device 3 of FIG. 11 is a third embodiment of the present invention, and includes the ratchet portion 10, the support portion 20, and the rotation limiting portion 30 of FIGS. 3 and 4 described above.

The ratchet part 10 is composed of the disks 12, 12', the brakes 13, 13', the stoppers 14, 14', and the base 15 as described above. And further includes a ratchet wheel (51).

Ratchet wheel 51 is formed with gears in the shape of a toothed wheel on the outside, and a shaft insertion hole is formed inside.

At this time, the inner diameter of the shaft insertion hole formed in the ratchet wheel 51 is formed larger than the outer diameter of the base (15).

In addition, braking members 511 and 511' are installed on the inner circumferential surface of the shaft insertion hole of the ratchet wheel 51.

The braking members 511 and 511' are formed in an arc shape, and are installed on the inner circumferential surface of the shaft insertion hole of the ratchet wheel 51.

In addition, the braking members 511 and 511' are made of a material having a high coefficient of friction.

In addition, when the ratchet wheel 51 is inserted into the base 15, the braking members 511 and 511′ generate friction because the inner circumferential surface contacts the outer circumferential surface of the base 15.

At this time, for convenience of explanation, it has been described as an example that two arc-shaped braking members are installed on the inner circumferential surface of the ratchet wheel 51, but the installation position, shape, and quantity of the braking members are not limited thereto, and the base 15 It can be installed on the outer circumferential surface, etc.

The escalator overspeed and reverse running prevention device 3 configured as described above is applied to the inner circumferential surface of the ratchet wheel 51 while frictional force acts by the brake lining 131 and the braking member 2113 when the escalator rotation shaft is reversed A frictional force acts between the installed braking members 511 and 511' and the base 15.

Through this, the escalator overspeed and reverse running prevention device 3 increases the braking force than when the rotation of the escalator shaft 5 is stopped only by the frictional force of the brake lining 131 and the braking member 2113 installed on the brake arm 211. As a result, it is possible to more effectively prevent the escalator from running in reverse.

1: Overspeed and reverse running prevention device for escalator of the first embodiment
2: Overspeed and reverse running prevention device for escalator of the second embodiment
3: Overspeed and reverse running prevention device for an escalator according to the third embodiment
5: escalator rotating shaft
6: drive sprocket
7: Escalator support frame
10: Ratchet
11: ratchet wheel 12: disk
13: braking unit 14: stopper
15: base
20: support
21: friction movable body 22: support
30: rotation limiting part
31: pole 32: connection
33: drive unit

Claims (1)

A ratchet part made of a ratchet wheel rotatably installed on an escalator rotation shaft, and a friction part installed on both sides of the ratchet wheel to frictionally contact the ratchet wheel and rotate with the rotation shaft;
A detection sensor that detects rotation of the rotation shaft;
A support frame for supporting other objects as a structure installed inside the escalator;
A support part installed on the support frame;
It is installed on the support and includes a rotation limiting unit for limiting the rotation of the ratchet wheel by inserting a locking means into the ratchet wheel,
The support part
A support coupled to the support frame;
A device for preventing overspeed and reverse running for an escalator, comprising a friction movable body coupled to one side of the support and installed spaced apart from the ratchet part.

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