FI80661C - Front switch at a cam controlled speed limiter for a lift - Google Patents

Description

1 80661

Elevator cam-controlled speed limiter front switch. -Frontavbrytare vid en nockstyrd hastighetsbegränsare för en hiss.

The invention relates to a device as a front switch for an elevator cam-controlled speed limiter having a switch on the limiter column for stopping the operation of the elevator and a device for actuating the switch when the elevator exceeds its normal driving speed by a predetermined speed less than the speed limiter tripping.

Lifts must be fitted with a gripping device whose speed limiter, at least in the downward direction, is triggered when the lift exceeds its normal speed by a certain amount. When the gripping device starts, the elevator car stops with a large opposite acceleration, which is uncomfortable for the passengers and also requires considerable effort to get the elevator back into operation. At low speeds, it is therefore advantageous to stop the speed of the elevator car by switching off the operation and releasing the brake. If the car speed increases despite the drive being switched off, the speed limiter will trip the gripper. In this case, the body remains on the guide rails. Cam-controlled speed limiters are often used to shut off operation at overspeeds and to trip the gripper as the speed continues to increase. They have a simple structure, are inexpensive and have less interference due to their simplicity.

The cam-controlled speed limiters operate with a two-pronged lever mounted to rotate on a column. The lever is made to oscillate by means of a roller. On the side opposite the roller, the lever is cam-shaped. The beak grips the web of the closing ring with the upper legs. For front cut-out, the lever has a switch actuating device.

Such a device is known from CH-PS 387 902. According to one of its embodiments, the front switch consists of a compression spring, a mass 2 80661 vista and a switch mounted on a column. The array is affected by the continuity force produced by the movement of the pendulum lever, the magnitude and direction of which change all the time. The dimensions of the compression spring and the array are chosen so that when a certain elevator speed is exceeded, the continuity force acting on the array is greater than the sum of its weight and the force of the compression spring. The resulting force moves the array from the rest position upwards, actuating the clutch on the column with the bolt. According to another embodiment, the device consists of a tension spring, a solid and a contact with a pendulum lever, and according to a third, a compression spring, a magnet and a pendulum lever contact. All three options work in basically the same way: the moving array is affected by the force of continuity, its own weight and the force of the spring, which moves it from the rest position if the elevator is driving at speed.

The disadvantage of this known device is the high mechanical wear and associated high manufacturing costs. An additional disadvantage is the constant need for setup and maintenance work. The tripping point of the electrical and mechanical shut-offs must be set separately and is not easy due to their interaction. A change or adjustment of the nominal speed of the elevator always also requires double equalization of the tripping paths. In this case, the setting for the power cut-off depends not only on the new speed, but also on the setting for the mechanical switch-off.

The front switch familiar from the DGM 7238999.2 is mechanically separated from the pendulum lever. This allows the trigger points to be set separately and independently. Except for simpler setup work, this unit has the same disadvantages as those with the CH-PS 387 902.

The biggest disadvantage of both devices is that the triggering occurs with the continuity force of directly moving parts. As the frictional forces of the moving parts increase, the force of continuity is no longer sufficient for a sure release. In addition, moving parts wear out quickly. High mechanical wear, the constant need for adjustment and maintenance work, as well as the increased susceptibility to disturbances and correspondingly lower safety are the significant disadvantages of the known front switches.

The object of the invention is to develop a front switch for the operation of an elevator machine which is simple in construction, not susceptible to interference and easy to install. The object is solved by the invention characterized in the characterizing part of claim 1, which describes a device with a speed limiter which operates according to the presented principle. The elevator car rotates the rope pulley and the connecting ring connected to it with a steel rope. The movement of the cam is transferred to the two-pronged pendulum lever by means of a roller. The end of the lever opposite the roller is cam-shaped. On top of it is an actuating device with a two-pronged actuating lever which is mounted for rotation on a pendulum lever and fixed by a retaining device.

The invention achieves that the tripping tripping force is produced on the closing circumference, the actuator has no sliding parts, the structure of the coupling device is simpler than before and thus more cost-effective to manufacture, the tripping speed setting work is completely eliminated. there are fewer wearing parts, which significantly reduces the susceptibility to interference.

An example of the invention is shown in the accompanying drawings, which will be illustrated in more detail below.

Figure 1 shows a speed limiter with a front switch operating on the principle of the invention,

Figure 2 shows a schematic view of the speed limiter of Figure 1,

Fig. 3 shows a partial enlargement of the front switch of Fig. 1 with a retaining device consisting of a spring and a ball on it, 4 80661

Fig. 4 shows a partial enlargement of the front switch of Fig. 1 with a retaining device consisting of a biased return spring,

Figure 5 shows a detail of the retaining device of Figure 4.

Figures 1 to 5 show a column marked with the number 1, with a rope pulley 2 and its groove 2.1, a camshaft 3 and its cam 3.1 and a locking ring 4 and its toothing 4.1 with a groove 4.11 attached to each other rotatably mounted on the shaft 1.1. The second shaft 1.2 is pivotally mounted on the column 1 by a bifurcated pendulum lever 5, the second branch 5.1 of which has a rotating roller 5.11 and the second branch 5.2 has a cam 5.21.

The branch 5.2 carries the actuator 6. Reference numeral 7 denotes a retaining spring attached at one end to the column 1 and at the other end to the branch 5.1, the purpose of which is to press the roller 5.11 against the surface of the camshaft 3. The spring pressure of the spring 7 is set by means of a control device 7.1 attached to the column 1. The actuator 6 consists of a bifurcated lever 6.2 rotatably mounted on the shaft 6.1, with a V-shaped hook 6.21 at the upper end and a trigger cam 6.22 at the lower end. Between the actuating lever 6.2 and the pendulum lever 5 there is a retaining device 8, which in one embodiment consists of a spring and a ball placed on it. It is hereinafter referred to as the catcher. In another alternative, the retaining device 8 consists of a return spring 8.1 held by a fastening 8.1.1 and a screw 8.1.2, which together with the stop 8.2 on the pendulum lever 5. The operating position of the return spring 8.1 is described in 8.3. The switch device 9 attached to the column 1 includes a switch 9.1 and its end 9.11.

The device described above works as follows: the elevator car uses: · in a known manner, a steel rope with a rope pulley 2 and its locking ring 4 and a camshaft 3. The roller 5 follows the path of the camshaft 3. The retainer spring 7 is set so that the roller 5 follows the cam 3.1 of the camshaft 3 up to the nominal speed of the elevator. Cam 3.1 may roll

II

5 80661 5.11 for the oscillating movement of the pendulum lever 5, the direction of which varies. If the speed of the elevator exceeds a certain trigger value set by the retaining spring 7, the roller 5.11 rises from the camshaft 3. The moment of continuity of the pendulum lever 5 increases greater than the retaining torque of the retaining spring 7. The cam 5.21 remains on the track of the locking ring 4, which leads to the locking of the pulley 2. The friction in the groove 2.1 produces the force required to start the gripping device.

The operation of the elevator is switched off by the operating device 6. The holding device 8 keeps it in a rest position relative to the pendulum lever 5. In the rest position, the release cam 6.22 is closer to or deeper than the track 4 of the closing ring than the cam 5.21. In this implementation, both cams are always between the teeth of the two closing rings 4.1 when the roller 5.11 is on the cams 3.1. When the roller 5.11 is between the two cams 3.1, the pendulum lever 5 both raises the toothing 4.1 from the path, whereby the toothing moves past the cams 6.22 and 5.21 without affecting them. When the elevator is speeding, the roller 5.11 rises from the camshaft 3. The toothing 4.1 of the closing ring engages the trigger cam 6.22 and moves the actuating device 6 to the actuating position. In the rest position of the operating lever 6.2, the hook 6.21 does not touch the switch head 9.11, but only moves on it in the operating position and thus changes the state of the switch 9.1. When the bifurcated pendulum lever 5 moves, there is no danger of operation in the rest position of the actuating lever 6.2. In the first embodiment, the actuating lever 6.2 must be turned back to the position 8 in order to be put back into operation. In another alternative, the restraining device 8 automatically reverses it to the rest position. When the elevator is speeding upwards, the release cam 6.22 engages the groove 4.11 of the locking ring gear 4.1. As the closing ring 4 rotates to the left, the actuating lever 6.2 and the hook 6.21 turn clockwise, whereby the clutch head 9.11 and the clutch 9.1 stop operation.

In the first embodiment, the retaining device 8 may be an ordinary gripper, which operates as follows:

The pendulum lever 5 has a spring mechanism which includes a spring which presses the ball on it against the actuating lever 6.2. The diameter of the ball is smaller than that of the spring mechanism. On the actuating lever side, the spring mechanism is closed by a ring with an inside diameter such that the ball cannot pass through it. This allows the ball to reach only about half its diameter. With the delivery device 6 in the delivery position, the delivery lever 6.2 presses on the ball spring mechanism. An opening smaller than the diameter of the ball is in the rest position of the actuator 6 above the ball. The spring force pushes the ball so deep into the opening that the diameter of the inserting ball body is the same as the opening. The ball thus acts as an interconnector for the pendulum row lever 5 and the operating lever 6.2. The deviation of the operating lever 6.2 turns the opening away from the ball. The ball exits the opening and the actuating lever 6.2 presses it into the spring mechanism.

Instead of a gripper, the pendulum lever 5 could also have a small magnet. The operating lever 6.2 would then have a counter magnet instead of an opening.

As shown in the other alternatives in Figures 4 and 5, instead of a gripper, a self-returning device 8 of the actuating lever 6.2 can be used, which operates as follows: A U-shaped return spring 8.1 biased over the stop 8.2 holds the V-shaped actuating hook 6.21 at both ends in the rest position. When the elevator is driving downhill, turn the operating lever 6.2 and the hook 6.21 counterclockwise. In this case, the hook takes with it the second branch of the return spring 8.1 and turns it against the spring force to the operating position 8.3. When the toothing of the closing ring 4.1 no longer engages the release cam 6.22, in the operating position 8.3 the return spring 8.1 storing the spring energy returns the actuating device 6 to the rest position. When the elevator car is driven upwards, the branch of the second return spring 8.1 is turned in the same way and the actuator 6 is replaced.

Claims (4)

7 80661 A device as a front switch for an elevator cam-controlled speed limiter, with a switch (9.1) in the limiter column (1) for stopping the operation of the elevator and a device (6) on the pendulum lever (5) for actuating the switch (9.1) at a predetermined speed , which is less than the speed leading to the release of the speed limiter, characterized in that the actuating device (6) is a lever (6.2) located on a branch of the pendulum lever (5) having a cam (5.21) cooperating with the speed limiter closing ring (4), and that the lever (6.2) has a clamp (6.21) and a trigger cam (6.22) acting on the clutch, and that the lever (6.2) is held in the rest position by at least one retaining device (8) between it and the pendulum lever (5), whereby its trigger cam (6.22) ) is closer to the path of the closing ring (4) than the cam (5.21) of the pendulum lever (5), and that when the prescribed lift speed is reached the closing ring teeth (4.1) turn the trigger cam (6.22) against the holding force to the operating position. Device according to Claim 1, characterized in that the retaining device (8) is a gripper. Device according to Claim 1, characterized in that the retaining device (8) is a magnet. Device according to Claim 1, characterized in that the retaining device (8) has a U-shaped return spring (8.1) on the pendulum lever (5) prestressed over the stop (8.2), which automatically turns the actuator (6) back to the rest position - after turning and holds it there. 8 80661