KR101239403B1 - double type safety device for elevator - Google Patents

Abstract

The present invention relates to a safety device for elevators that can brake the elevator during sudden operation of the elevator to improve the stability and reliability in the elevator, and by using a link structure, the braking force can be increased in proportion to the number of moving pulleys. A body installed on one side of the elevator so that the guide rail passes, a lifting wire for generating tension according to the operation of the elevator, and the lifting wire passing through the lower portion and fixed to the body; A fixed pulley and a lifting pulley passing through the first fixing pulley so as to surround the upper part, and a lifting pulley for elevating in accordance with the occurrence of tension of the elevating wire, and an elevating guide for guiding the movement of the moving pulley. Is connected to an end of the elevating wire via the movable pulley and simultaneously lifted in the opposite direction with the movable pulley. The first guide member and the first braking means for determining whether the braking is determined according to the rotation direction while rotating in accordance with the lifting operation of the first guide member.

Description

Safety device for elevators {double type safety device for elevator}

The present invention relates to a safety device for an elevator, and more particularly, to a safety device for an elevator applying a braking force by compressing a guide rail for guiding the movement of the elevator.

In general, elevators that move people or cargo to the desired floor in high-rise buildings and apartments should be designed with attention to braking safety and braking reliability. In particular, if the power supply connecting the elevator is not supplied, or if the elevator is abnormally operated, such as when the rope breaks down due to breakage of the elevator is forced to stop the elevator is an important element of the design. To this end, in the related art, a brake for stopping the movement of a wire rope connected to an elevator and a load for operating the elevator in a vertical direction is installed so as to stop the elevator when the elevator operates abnormally.

Another prior art has also used a braking device that restrains a guide rail guiding the elevator with a jaw to brake it when the elevator is running abnormally. This braking device is used to prevent overspeed caused by the descent of the elevator. When detecting, it had a configuration that cuts off the motor power and applies braking force to the guide rail.

These prior arts operate only during abnormal operation of the elevator, such as descent, and there is a problem in that the brake cannot be effectively applied to the elevator in the case of slipping at a low speed in a stationary state and rapidly rising above the normal speed.

In addition, in the case of an elevator that applies a braking force by compressing a conventional guide rail, there is a limit of braking force because it is a structure in which the brake is released and operated by the elevator weight.

The present invention is to solve the above problems, it is possible to brake the elevator during the sudden operation of the elevator to improve the stability and reliability to the elevator, by using a double braking link structure, the braking force in proportion to the number of moving pulleys In addition, even if the safety device is configured as a double, the probability of the two links can be reduced to ensure the independent operation, and even if one braking means is broken, the other braking means can operate to ensure stability. The purpose is to provide a safety device for an elevator.

The present invention for achieving the above object is to apply a braking force by compressing the guide rail for guiding the movement of the elevator, the body is installed on one side of the elevator to pass the guide rail, one side end to the elevator A lifting wire which is connected and generates tension in accordance with the operation of the elevator, the lifting wire passing through the lifting wire, the first fixing pulley fixed to the body, and the elevating via the first fixing pulley. A moving pulley which is routed so as to surround the upper part, the lifting pulley which moves up and down according to the tension generation of the lifting wire, a lifting guide for guiding the movement of the moving pulley, and an end of the lifting wire passing through the moving pulley; A first guide member connected to the movable pulley and simultaneously lifting in the opposite direction, the first guide member having an eccentric rotation shaft, and the first guide member It provides a safety device for an elevator including a first braking means for applying a braking force in a manner of pressing or releasing the guide rail in accordance with the direction of rotation while rotating about the axis of rotation in accordance with the lifting operation of the ash.

As described above, the safety of the elevator is further improved because it has a configuration that can be easily braked at the time of elevator sudden operation by a simple operation.

In addition, unlike the prior art, which has a structure in which the brake is lifted and operated by the lifter's own weight, the braking force is limited. By using the link structure, the braking force can be increased in proportion to the number of the moving pulleys.

In particular, even if the safety device is configured as a double, the probability between the two links can be reduced to ensure independent operation, even if one braking means is broken, the other braking means can operate, thereby ensuring stability.

1 is a side view showing a braking state of a safety device for an elevator according to the present invention;
Figure 2 is a side view showing a state in which the brake of the elevator safety device is canceled in accordance with the present invention;
3 is a partially enlarged view of FIG. 1;
4 is an enlarged view of a part of FIG. 2;
5 is a perspective view of a safety device for an elevator according to the present invention;
6 is a partially enlarged view showing a braking state of a safety device for an elevator according to another embodiment of the present invention;
7 is a partially enlarged view showing a state in which the brake of the elevator safety device is canceled according to another embodiment of the present invention.

Hereinafter, the elevator safety device according to the present invention according to the accompanying drawings in more detail.

1 is a side view showing a braking state of the safety device for an elevator according to the present invention, Figure 2 is a side view showing a state in which the braking of the safety device for an elevator according to the present invention is terminated, Figure 3 is an enlarged portion of FIG. 4 is a partially enlarged view of the above Figure 2, Figure 5 is a perspective view of a safety device for an elevator according to the present invention.

Elevator safety device 100 according to the present invention is to apply a braking force in a manner to compress the guide rail 20 for guiding the movement of the elevator 10, the elevator 10 to pass through the guide rail 20 Body 110 is installed on one side of the, one end is connected to the elevator 10, the lifting wire 120 is generated tension according to the operation of the elevator 10, and the lifting wire 120 ) Is passed to surround the lower portion, and the first fixing pulley 130 fixed to the body 110 and the lifting wire 120 passing through the first fixing pulley 130 are routed to surround the upper portion. By moving, the lifting pulley 140, the lifting guide 150 for guiding the movement of the moving pulley 140, and the moving pulley 140 in accordance with the tension generation of the lifting wire 120 It is connected to the end of the elevating wire 120 in the opposite direction at the same time as the movable pulley 140 It has a first guide member 160 to move up and down, and an eccentric rotation shaft, and the guide rail 20 is crimped according to the rotation direction while rotating about the rotation shaft in accordance with the lifting operation of the first guide member 160. Or the first braking means 170 for applying the braking force in a releasing manner.

First, the body 110 is installed on one side of the elevator, the guide rail 20 is disposed in the running direction along the wall of the passage through which the elevator 10 passes the first braking means 170 and the first It is installed to be located between the first braking plate 171 disposed on one side of the braking means (170). Therefore, when braking, the first braking means 170 compresses the guide rail 20 to brake the sudden rise or fall of the elevator 20 by the frictional force between the guide rail 20 and the first braking means 170. To do that.

Lifting wire 120 is a tension is generated according to the operation of the elevator 10, one end is connected to the elevator 10, the other end is wrapped around the lower portion of the first fixing pulley 130 After passing through, while passing through the upper portion of the moving pulley 140, it is fixed to the first guide member 160.

That is, the elevating wire 120 is tensioned when the elevator 10 operates, the tension is released when the elevator does not operate. Accordingly, the elevating wire 120 forms a 'S' shape, and the movable pulley 140 located at the bent portion of the elevating wire 120 is in accordance with the presence or absence of tension of the elevating wire 120. It is going up and down.

The first fixing pulley 130 is passed through the lifting wire 120 to surround the lower part and is fixed to the body 110, and serves to change the direction of the lifting wire 120.

The moving pulley 140 passes through the lifting wire 120 so as to surround the upper portion, and moves according to the tension generation of the lifting wire 120 to act as a moving pulley. That is, when tension is generated in the elevating wire 120, the elevating wire 120 is lowered. When the tension applied to the elevating wire 120 is released, the elevating wire 120 is increased by its own weight. The central shaft 141 of the movable pulley 140 is guided by being inserted into the long hole 151 formed in the longitudinal direction of the lifting guide 150. Therefore, the lifting guide 150 fixed to the body 110 serves to guide the movable pulley 140 to be lifted in a straight line.

The first guide member 160 is connected to the movable pulley 140 and simultaneously lifts in the opposite direction with the movable pulley 140, and an end of the elevating wire 120 via the upper portion of the movable pulley 140. In connection with the moving pulley 140 is raised when the descending, the moving pulley 130 is lowered and rises.

The first braking means 170 has an eccentric rotation shaft, and rotates about the rotation shaft according to the lifting operation of the first guide member 160 to press or release the guide rail 20 according to the rotation direction. By applying a braking force in a manner, the movement of the guide rail 20 located between the first braking plate 171 is braked. That is, when braking, the first braking means 170 is squeezed on the guide rail 20 to brake the sudden rise or fall of the elevator 10 by the friction force between the guide rail 20 and the first braking means 170. do.

The first braking plate 171 is fixedly coupled to one side of the body 110, the first braking plate 171 should always be maintained at a constant distance with the guide rail 20 at a certain position by the same pressing force It will have the same braking force. On the other hand, the first braking means 170, the friction surface 173 for pressing the guide rail 20 is made of a material with a large friction force, the teeth may be formed in the friction surface 173 is pressed. . Therefore, the guide rail 20 is prevented from sliding in close contact with the first braking means 170 and the first braking plate 171, thereby providing sufficient friction braking force when the elevator 10 suddenly rises or falls. .

In addition, the first braking means 170 is located on the opposite side of the first braking plate 171 with respect to the guide rail 20, and the body 110 is rotatably coupled around the hinge point 172. .

According to a preferred embodiment of the present invention, the second fixed pulley 230 mounted on the upper end of the lifting guide 150 to be located above the movable pulley 140, and the central axis 141 of the movable pulley 140 The auxiliary wire 220 passing through the second fixing pulley 230 to surround the upper portion of the second fixing pulley 230 and the end of the auxiliary wire 220 passing through the second fixing pulley 230. A second braking means (2) which rotates according to the lifting operation of the second guide member 260 and the second guide member 260 lifting up and down in the opposite direction at the same time as the pulley 140; 270).

First, the second fixing pulley 230 is mounted on the upper end of the lifting guide 150 to be located above the moving pulley 140, and serves to change the direction of the auxiliary wire 220. The auxiliary wire 220 has one side end connected to the central axis 141 of the movable pulley 140, and passes through the upper portion of the second fixing pulley 230 to pass through the second guide member 260. ) The second guide member 260 is disposed in parallel with the first guide member 160 and is connected to the end of the auxiliary wire 220 via the second fixing pulley 230 so that the movable pulley 140 is disposed. And at the same time ascend in the opposite direction.

That is, the second guide member 260 is connected to the central shaft 141 of the movable pulley 140 and simultaneously moves up and down in the opposite direction with the movable pulley 140. As with the first guide member 160, When the moving pulley 140 rises and falls, the moving pulley 130 descends and rises.

The second braking means 270 is rotated according to the lifting operation of the second guide member 260 and the braking is determined according to the rotation direction thereof. The second braking means 270 has a structure similar to that of the first braking means 170.

That is, the second braking means 270 is rotated in accordance with the lifting operation of the second guide member 260, and the braking force is generated in accordance with the rotational direction thereof and then released. Braking the movement of the guide rail 20 is located. That is, when braking, the second braking means 270 is pressed against the guide rail 20 to brake the sudden rise or fall of the elevator 10 by the frictional force between the guide rail 20 and the second braking means 270. do. The second braking plate 271 is fixedly coupled to one side of the body 110, the second braking means 270 is a friction surface 273 for pressing the guide rail 20 is made of a material of high friction To be manufactured, a tooth or the like may be formed on the pressed friction surface 273. Therefore, the guide rail 20 is prevented from sliding in close contact with the second braking means 270 and the second braking plate 271, thereby providing sufficient friction braking force when the elevator 10 suddenly moves up or down. .

In addition, the second braking means 270 is located on the opposite side of the second braking plate 271 around the guide rail 20, and the body 110 is rotatably coupled around the hinge point 272. .

According to a preferred embodiment of the present invention, the first and second guide members 160 and 260 are first and second moving guides 161 to guide the lifting operation of the first and second guide members 160 and 260, respectively. 261).

First, each of the first and second guide members 160 and 260 moves up and down in a direction opposite to the moving pulley 140 according to the lifting operation of the moving pulley 140. In this case, the first and second moving guides 161 and 261 serve to guide the first and second guide members 160 and 260 to move up and down in a straight line. That is, the first and second moving guides 161 and 261 may be transport spaces corresponding to the sizes of the first and second guide members 160 and 260 in the moving direction of the first and second guide members 160 and 260. 162 and 262 to provide the first and second guide members 160 and 260 fitted into the transfer spaces 162 and 262 to be guided up and down by the first and second moving guides 161 and 261. .

According to a preferred embodiment of the present invention, the first and second guide pulleys 180 and 280 mounted on the body 110 to be positioned below the first and second guide members 160 and 260, and one side of the first and second guide pulleys 180 and 280. The first and second guide members 160 and 260 are fixed to each other, and the other side is fixed to the first and second braking means 170 and 270 after passing through lower portions of the first and second guide pulleys 180 and 280. When the first and second guide members 160 and 260 are elevated, the first and second power transmission means 191 and 291 rotate the first and second braking means 170 and 270.

First, the first and second guide pulleys 180 and 280 are mounted to the body 110 to be located below the first and second guide members 160 and 260, respectively, and the first and second power transmission means. It serves to change the direction of (191, 291). The first and second power transmission means (191, 291) may be provided by a variety of known means such as wire or chain, one side is fixed to the first, second guide member (160, 260), the other side The direction is changed via lower portions of the first and second guide pulleys 180 and 280, and then fixed to the first and second braking means 170 and 270, so that the first and second guide members 160 and 260 are fixed. ) Is pulled up and rotates by pulling the first and second braking means 170 and 270.

That is, when the elevator 10 is operated to generate tension in the elevating wire 120, the movable pulley 130 is lowered and the first and second guide members 160 and 260 are raised, by the force. As the first and second braking means 170 and 270 rotate clockwise, the braking force is released.

On the contrary, when the lifting wire 120 for raising the elevator 10 is broken or the tension is removed, the moving pulley 130 is raised and the first and second guide members 160 and 260 are lowered by their own weight. The first and second braking means 170 and 270, which are forcibly pulled and rotated in the clockwise direction, generate a braking force while rotating in the counterclockwise direction.

According to a preferred embodiment of the present invention, the first and second braking means (170, 270) are respectively rotated by the first and second power transmission means (191, 291) and resilient to return to the position where the braking force is released It is connected to the body 110 through the first and second elastic members 190 and 290 to be pulled out.

That is, each of the first and second braking means 170 and 270 is connected to the first and second power transmission means 191 and 291, and the other side is connected to the first and second elastic members 190 and 290, respectively. Connected. The first and second elastic members 190 and 290 may be provided as coil springs, one side of which is fixed to the body 110 and the other side of the first and second elastic members 190 and 290 through connecting means 192 and 292 such as a wire or a chain. And two braking means (170, 270).

Therefore, when rotated clockwise by the pulling force of the first and second power transmission means (191, 291), when the force is removed, by the elastic restoring force of the first and second elastic members (190, 290) It automatically rotates counterclockwise to return to the position where the braking force is released.

Hereinafter, the operating state of the elevator safety device according to the present invention.

When the elevator 10 is in an operating state and tension is generated in the elevating wire 120, the movable pulley 140 is lowered, and at the same time, the first and second guide members 160 and 260 are raised. The first and second power transmission means 191 and 291 connected to the first and second guide members 160 and 260 pass through the first and second guide pulleys 180 and 280, respectively, and then the first and second braking means 170, respectively. It is fixed to the 270, the braking force is released when the first and second power transmission means (191, 291) made of a chain or wire rotates the first and second braking means (170, 270) clockwise.

On the contrary, when the elevating wire 120 for elevating the elevator 10 is broken or the tension is removed, the first and second elastic members 190 and 290 connected to the first and second braking means 170 and 270 may be the first. The braking force is applied by rotating the second braking means 170 and 270 counterclockwise.

In this case, the braking method may include a first and second braking means 170 and 270 and a guide rail 20 passing between the first and second braking means 170 and 270 and the adjacent first and second braking plates 171 and 271. The first and second braking means (170, 270) is made in a manner that is pressed.

On the other hand, Figure 6 is a partially enlarged view showing a brake state of the elevator safety device according to another embodiment of the present invention, Figure 7 is a partial enlarged view showing a state in which the brake safety device for a lift according to another embodiment of the present invention is terminated 6 and 7, one end is fixed to one edge of the first braking means 170, and the other end is fixed to the second braking means 270. Fixed to the other side edge of the first and second braking means (170, 270) when the rotation, the return force to the position where the braking force is applied to the first and second braking means (170, 270) by the elastic restoring force It may further include an elastic means 300 to increase the braking performance. The elastic means 300 has a simple structure and may use a long tension spring, and is provided to improve braking operability of the first and second braking means 170 and 270.

That is, the elastic means 300 is the first and second braking means (170, 270) is applied to the braking force is applied to the rotation of the clockwise rotation of the braking force is released in the process of increasing the length and decrease, on the contrary the first, The second braking means (170, 270) is rotated counterclockwise in a state in which the braking force is terminated and is fixed at a point where the length increases and decreases even in the process of applying the braking force.

That is, when the first and second braking means 170 and 270 rotate clockwise, the elastic means 300 includes first and second braking means 170 and 270 in which the elastic means 300 is fixed. As the distance between the fixing point (P1, P2) of the) increases the length of the elastic means 300 and the force pulling in the opposite direction, that is, counterclockwise rotation of the first and second braking means (170, 270) is rotated In the second half, the length of the elastic means 300 that is increased as the distance between the fixed points P1 and P2 that are moved closer to each other decreases, and the first and second braking means 170 and 270 pull clockwise to rotate. The force acts to assist the rotation of the braking means 160 so that the braking force can be more surely released.

On the contrary, when the first and second braking means 170 and 270 rotate in the counterclockwise direction, the fixed point P1 of the first and second braking means 170 and 270 to which the elastic means 300 is fixed at the beginning. As the distance between P2 increases, the length of the elastic means 300 fixed to the first and second braking means 170 and 270 increases, and the first and second braking means 170 and 270 rotate in opposite directions. That is, the force pulling in the clockwise direction acts, and in the second half, the length of the elastic means 300 that is increased as the distance between the fixed points P1 and P2 is closer to each other decreases, and the first and second braking means 170 and 270 are reduced. This rotating counterclockwise pulling force acts to assist the rotation of the first and second braking means 170 and 270 so that the braking force can be more reliably applied.

According to another embodiment of the present invention, two elastic means may be provided and may be separately mounted to the first and second braking means 170 and 270, respectively. In this case, one side of each elastic member is fixed to the edge of the first, second braking means (170, 270), the other side is fixed to the body 110, the first, second braking means (170, 270) When the rotation is performed, an individual elastic restoring force acts on the first and second braking means 170 and 270 to improve braking operability of the first and second braking means 170 and 270.

Advantages of the elevator stabilizer according to the present invention as described above are as follows. First, since it has a configuration that can be easily braked at the time of elevator sudden operation by simple operation, it is possible to further improve the stability of the elevator. By using the link structure, the braking force can be increased in proportion to the number of moving pulleys, and even if the safety device is doubled, the probability of the two links can be reduced to ensure independent operation. Another braking means is operable even if broken, there is an advantage to ensure the stability.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation and that those skilled in the art will recognize that various modifications and equivalent arrangements may be made therein. It will be possible. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

10: Lift
20: guide rail
100: elevator safety device
110: body
120: lifting wire
130, 230: 1st, 2nd fixed pulley
140: moving pulley
141: central axis
150: lifting guide
160 and 260: first and second guide members
161, 261: first and second movement guide
170, 270: first and second braking means
180, 280: 1st, 2nd guide pulley
191, 291: first and second power transmission means
190, 290: first and second elastic members
220: auxiliary wire
300: elastic means

Claims (9)

In a safety device for an elevator applying a braking force by pressing a guide rail for guiding the movement of the elevator,
A body installed at one side of the elevator to allow the guide rail to pass therethrough;
A lifting wire having one end connected to the elevator to generate tension depending on whether the elevator is operated;
A first fixing pulley having the lifting wire wrapped around the lower portion and fixed to the body;
A moving pulley having a lifting wire passing through the first fixing pulley so as to surround an upper part, and moving up and down depending on whether tension is generated in the lifting wire;
An elevating guide for guiding the movement of the movable pulley;
A first guide member connected to an end of the elevating wire via the movable pulley and simultaneously lifting in the opposite direction with the movable pulley;
A first braking means having an eccentric rotation shaft and applying braking force in a manner of pressing or releasing the guide rail according to the rotation direction while rotating in a forward and backward direction about the rotation shaft according to the lifting operation of the first guide member; Elevator safety device comprising a. The method of claim 1,
A second fixing pulley mounted on an upper end of the elevating guide to be positioned above the moving pulley;
An auxiliary wire connected to a central axis of the movable pulley and passing through an upper portion of the second fixed pulley;
A second guide member connected to an end of the auxiliary wire via the second fixing pulley and simultaneously lifting in the opposite direction with the movable pulley;
And second braking means for determining whether braking is determined according to the rotation direction while the second guide member rotates according to the elevating operation of the second guide member. The method of claim 1, wherein the first guide member
And a first moving guide for guiding the lifting operation of the first guide member. The method of claim 2, wherein the second guide member
And a second moving guide for guiding the lifting operation of the second guide member. The method of claim 1,
A first guide pulley mounted to the body so as to be positioned below the first guide member;
One side is fixed to the first guide member, the other side is fixed to the first braking means after passing through the lower portion of the first guide pulley, when the first guide member is lifted to rotate the first braking means Elevator power safety device comprising a; power transmission means. The method of claim 2,
A second guide pulley mounted to the body so as to be positioned below the second guide member;
One side is fixed to the second guide member, the other side is fixed to the second braking means after passing through the lower portion of the second guide pulley, when the second guide member is lifted to rotate the second braking means Elevator power safety device comprising a; 2 power transmission means. 6. The method of claim 5,
And the first braking means is connected to the body through a first elastic member which is rotated by the first power transmission means and elastically pulls back to a position where the braking force is released. The method according to claim 6,
And the second braking means is connected to the body via a second elastic member which is rotated by the second power transmission means and elastically pulls back to a position where the braking force is released. The method of claim 2,
One end is fixed to one edge of the first braking means, the other end is fixed to the other edge of the second braking means, when the first and second braking means rotate, the first and second braking by elastic restoring force Elevator means safety device further comprises a resilient means for improving the braking performance by increasing the return force to the position where the braking force is applied.

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