EP1445229A1 - Elevator system including compensation of the hoist rope weight - Google Patents

Abstract

The lift installation has between the lift car (5) and shaft wall (2) a compensating strand (7) spatially next to the suspension cable strand (6), and is provided for the reducing in difference between the lift car side and counterweight (4) side of the load of the load cable strand (3). The mass of the compensating strand per meter together with mass of the suspension cable strand per meter comes to four times the load cable mass per meter.

Description

The invention relates to elevator system with a compensation of Lifting rope masses from central to very off-center ("backpack") suspended cars and a traction sheave drive, the in a shaft, in a shaft table or in a separate one Space is housed, the traction sheave of which Suspension rope strand either simple, with or without a deflector, or is wrapped twice, as well as with a direct one or indirect suspension of the car and a counterweight, as well as a supply car carried by the car and function control suspension harness and a mass balancer.

Elevator systems are often used for all conceivable Car full to empty, combined with the car position from top to bottom and one towed by the car Supply and function control pendant wiring harness, Compensating elements for the strand masses for the purpose of reduction until minimization of the rope force differences between the suspension rope on the car side and the suspension cable the counterweight side used.

The principle is as follows: With an upper car position is the suspension cable mass, calculated from the traction sheave, up to to the car small due to the short suspension rope length, therefore but the mass of the balancing strand due to its length large from the car to its lower turning point. At a The situation is reversed in the lower car position. The same applies to the counterweight. That way one significantly reduced based on half the payload maximum drive and braking power.

The usual suspension cable balancing is done in a known manner through a compensating element in the form of chains, weight-loaded Belts or realized by tensioned lower ropes (U.S. 4,716,989). The compensating element is on the one hand on the car and on the other hand attached to the counterweight. In the The shaft pit becomes the compensating element with or without clamping devices diverted. Tensioned compensation elements with or without a vibration-damped tensioning device are preferred for travel speeds of the elevator v> 2.5 m / s used.

However, this classic solution has disadvantages. In addition to the high Counterbalance counter space required in the elevator shaft it is often over due to the redirection in the shaft pit optically undesirable, especially with glass shafts, on a moving, forming a deflection and to see the balancing line that obstructs the free view. At higher speeds, an additional Require undervoltage, also become annoying Vibrations caused driving noises. In the shaft profile the vibration amplitudes must also be spatially taken into account that is, additional installation space is required.

From EP 1 234 796 A1 a compensation device is the Support rope masses through the interposition of compensating elements on the one hand between the car and the shaft wall and on the other hand between counterweight and shaft wall, combined in each case with a data transmission element.

From EP 0 653 372 A2 it is known a mass balancing line between the car floor and a fixed point in the shaft as well as another mass balance line between the counterweight base and another fixed point in the shaft. In the mass of the balancing strand for the The car also becomes the mass of the supply and function control hanging harness included.

A disadvantage of the latter compensation devices is likewise the high space requirement of the counterweight balance in the elevator shaft through the redirection in the shaft pit and the attachment and arrangement of the same in the shaft behind the Counterweight or in an inclined arrangement in front of it, without using the Car collide. In any case, that means bigger ones Shaft dimensions than usual.

Another disadvantage is that the additional masses at least consist of 2 strands, namely the strand for the car and the line for the counterweight, not counting the data transmission lines.

The invention is based on the object shown To avoid disadvantages and an elevator system at the beginning described genus with a space-saving, constructive extremely simple, optically acceptable and easy to use To create balancing mass arrangement.

This object is achieved by the in claim 1 specified features solved. After that is only on the car Compensation element provided that with the suspension cable harness in terms of mass and space, it is functionally combined in such a way that a ideal balancing takes place up to half the payload.

In conventional elevator systems, the mass of the hanging cable much smaller than the mass of the suspension cables. For one theoretically correct compensation would be in addition to compensation 50% of the nominal load with the counterweight also 50% of the very small suspension cable mass required anyway. In bills this fact is neglected in many cases because the influence is small and the error towards safe Side works. When accepting an elevator, the usual practical half-load test the influence of the weight balance but again practically considered, that is, the counterweight is slightly heavier than with 50% balance the nominal load.

According to the invention, on the other hand, the mass of the hanging cable becomes conscious together with the mass of the compensating element on the 1.75 times the cable mass per meter for partial load compensation and 4 times per meter for ideal compensation enlarged and with the counterweight mass as with the description of a conventional elevator system is taken into account. This means, for example, that with 4 times the cable rope mass Meters with full or empty car and car position in the bottom stop a rope force difference from the half the nominal load and thus the ideally smallest value. The compensation element together with the hanging cable acts this car position at all, but hangs fully the shaft wall. On the other hand, the car is in the top one Stop, the mass is fully attached to the car and is the same thus the suspension rope masses, which are now on the counterweight side are located. Together with the increased counterweight mass here again the ideal smallest result Rope force difference values for full or empty Car.

The solution is with all professional elevator computer programs, for which when calculating the counterweight mass Suspension cable mass is taken into account without changes to the computer program to calculate. Such computer programs are too Named for this application for government regulators Positions or Notified Bodies incontestable.

An elevator installation according to the invention can be particularly advantageous in the limit range for driving problems, more limited Number of rope grooves in the elevator machine, larger heads, higher speeds and can be used where Lower ropes, chains or other compensating devices are more common Arrangement between car and counterweight undesirable are. Reasons for this can be: lack of space, low Shaft pit, glass shaft in the lower shaft area without View restrictions due to usual compensation devices, Noises and other.

The deflection bend of the compensating element moves with the half driving speed at constant speed. This results physically for the moving system a uniform movement of the deflection curve and the same Deflection forces as for the usual compensation systems in the deflection bend in the pit for one at half speed moving elevator. This allows the compensation elements up to over twice the usual driving speeds about v = 8 m / s unstressed in analogy to a suspension cable harness be carried out.

For speeds v ~ 2.5-8 m / s, this results in general Advantages over conventional elevator systems in that an expensive lower cable tensioning device can be omitted. This also stresses the suspension cables due to their tension mass. Farther there is no unmistakable source of noise in the Shaft pit and near the main stop.

The safety gear on the car and, if necessary, the counterweight are sure to adapt to this fact, need less than the acceleration of gravity g decelerate and thus a long-term jumping of the car or counterweight safely prevent. The same applies to an electrical or mechanical Emergency stop of the drive machine.

The invention is intended to be explained in more detail using an exemplary embodiment to be discribed. In the associated single Fig. 1 is strongly traction drive 1 in the upper Area of a shaft 2 arranged. In the example there is a Set of suspension cables 3 in a single loop around the traction sheave 1 led. At one end of the suspension rope 3 is a counterweight 4 attached directly and on the other side a car 5. The suspension cable guide and suspension is for the invention is immaterial. For example, a double Wrapping may be provided or an additional deflection disc and car 5 and counterweight 4 can be in bulk Roll be hung. Other variants are conceivable. from Bottom of the car 5 is a suspension cable harness in a known manner 6 in a loop to a fixed point above the middle Shaft height led, for example to a shaft wall or a shaft installation. At the same time, the only one coming in Mass balancing element to car 5. This therefore requires no or only a negligibly small space in the Shaft 2. So that you alone with this mass balancing strand 7 comes out, according to the invention, the mass of the suspension cable harness 6 together with the mass of the balancing strand 7 each Meters to the 1.75 of the suspension cable rope mass per meter for one Partial load compensation and 4 times per meter for an ideal Compensation increased and when calculating the counterweight mass considered.

With 4-fold suspension rope strand mass per meter, it is at full or empty car 5 and a car stand in the bottom stop a cable rope force difference from the half the nominal load, which corresponds to the smallest possible value. However, if car 5 is in the top stop, the cable and compensating strand masses are fully dependent Car 5 and thus compensate for those suspension cable masses, which are now on the counterweight side. Together with the increased counterweight mass again result the smallest possible values for the suspension cable force difference for the full and empty car.

In a preferred embodiment, the mass of the compensating strand is 7 per meter together with the mass of the suspension cable harness 6 per meter therefore 4 times the mass of the suspension cable strand 3 per meter, with a mass greater than 4 times the compensating effect deteriorates again.

In a further embodiment of the invention there is the compensating strand 7 from one or more single strands.

To account for an increased load on the suspension cable strand 3 wear, a correspondingly suitable groove shape of the Traction sheave 1 selected, e.g. B. a reduced undercut width or generally, a groove shape with reduced Driving ability, and thus a disproportionately reduced Surface pressure between groove and rope.

For elevators with travel speeds up to approx. 8 m / s the Compensation line 7 can be carried out untensioned, in addition should he in a further embodiment of the invention in a Guided and if necessary by means of a roller tensioner to be excited.

reference numeral

1

Traction drive

2

shaft

3

Supporting cable strand

4

counterweight

5

car

6

Suspension Harness

7

compensation strand

Claims (6)

Elevator system with balancing of the suspension cable masses from cars suspended in the middle to very off-center and with a traction sheave drive, which is accommodated in a shaft, in a shaft niche or in a separate room, the traction sheave being single, with or without a sheave, or double wrapped by a suspension cable strand is, as well as with a direct or indirect suspension of the car and a counterweight, as well as a supply and function control suspension cable harness and a mass balancing device,
characterized by
that between the car (5) and a shaft wall (2) spatially next to the suspension cable harness (6) there is a compensating string (7) to reduce the difference between the car-side (5) and counterweight-side (4) loading of the suspension cable (3), the Mass per meter together with the suspension cable mass per meter is 1.75 to 4.5 times the suspension cable mass per meter. Elevator system according to claim 1,
characterized by
that the mass of the compensating strand (7) per meter together with the mass of the hanging cable harness (6) per meter is 4 times the suspension cable mass per meter. Elevator system according to claim 1 or 2,
characterized by
that the compensating strand (7) consists of one or more strands. Elevator installation according to one of claims 1-3,
characterized by
that the increased load on the suspension cable strand (3) is taken into account by a suitable groove shape of the traction sheave (1). Elevator installation according to one of claims 1-4,
characterized by
that the compensating strand (7) is guided in a guide and tensioned if necessary. Elevator installation according to one of claims 1-5,
characterized by
that the compensating line (7) for lifts with travel speeds up to approx. 8 m / s is not tensioned.

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