EP0870929A2 - Hydraulic cable lift - Google Patents

Abstract

The lift has a differential ram (1) with two working chambers in a circuit containing a fluid pump (15). The circuit can be partly-closed and contain a fluid-storage tank (20). Each working chamber (23,24) can be preceded by a stop valve regulating the flow, these typically holding the load and forming a lowering brake (25,28), while a separate non-return valve (26,29) can be provided for each of these valves. The latter can be contained in a pipe (27) connecting the two working chambers of the ram (1). A further stop valve (32), particularly a (2/2-way) one, can be included, through which fluid is returned to the tank.

Description

The invention relates to a hydraulic rope elevator, comprising a drive device with a differential cylinder to which a working fluid can be applied for movement a load, in particular a load-bearing cabin.

aktiver" Bewegungsbetrieb, allein durch den Differentialzylinder gesteuert, für eine Abwärtsbewegung nicht möglich ist. Auch die erforderliche Fluidmenge, die für eine Bewegung des Kolbens zwischen den beiden Endpositionen erforderlich ist, ist sehr groß, was in einer entsprechend großdimensionierten Auslegung der Anlage resultiert.The working principle of previously known hydraulic rope hoists with differential cylinders is such that the load to be moved is coupled to the cylinder piston rod, possibly with the interposition of a counterweight. To move the load, a working fluid is pressed in under pressure in a working chamber of the differential cylinder, which is formed by the upper ring cylinder chamber, in order to convey the cylinder piston downwards and thus the load upwards. Working fluid is drawn out of the working area for an opposite movement, the movement being effected solely by the downward pulling weight of the load, for example a backpack-guided delivery basket. Such a construction shows a number of disadvantages. Firstly, the engine power required for operation is very large, since the load to be compensated for by the working fluid pressure largely corresponds to the total load that has to be moved. Another disadvantage is that with a counterweight this load can only be compensated for to a limited extent, since the load itself is responsible for the downward movement thereof, since a

active "movement operation, controlled solely by the differential cylinder, is not possible for a downward movement. The amount of fluid required for a movement of the piston between the two end positions is also very large, which results in a correspondingly large-sized design of the system.

The invention is therefore based on the problem of specifying a hydraulic rope elevator, which improves especially with regard to the performance required for operation is and enables more economical operation.

To solve this problem, the above-mentioned is the case with a hydraulic rope hoist Provide type according to the invention that the differential cylinder in a funding is integrated for the fluid circuit having working fluid and has two work rooms, both depending on the required movement are exposed to working fluid.

A cylinder is therefore used in the hydraulic rope elevator according to the invention, in which both working spaces, namely the piston-side space and the ring-shaped one Fluid is applied to the piston rod space. That way it is particularly possible to work actively in both directions of movement, depending on the required movement, the fluid accordingly is fed to or removed from the respective work area. As a result the fluid circuit is therefore a much lower power requirement for the given movement. Another notable advantage is that the Downward movement of the load also takes place actively in the elevator according to the invention, namely, in that fluid is pressed into the lower piston working space becomes. As a result, it is advantageously possible to also adjust the counterweight accordingly to be interpreted more precisely, since in this case this balances the entire load can, which is also a significant reduction in the required Performance is an advantage.

According to the invention, the fluid circuit can be a partially closed circuit, in which a reserve fluid reservoir is integrated. This advantageous training enables it is only to convey the working fluid between the two work rooms and the respective required difference quantity, which is either during the transfer is supplied, or must be removed, in a reserve fluid container to lead, which advantageously leads to only a small amount of differential oil be present in the correspondingly small sized reserve fluid container must, because this is the maximum resulting from the different working space volumes resulting difference.

In order to ensure efficient operation, the invention further sees before that each work area at least one fluid flow regulating barrier is connected upstream, each with a blocking element as a load holding valve or Lowering brake valve can be formed, each of which is a separate one Check valve can be assigned. At least one blocking member, optionally a load holding valve or lowering brake valve in a fluid line connecting both work spaces. In a further design of the invention can be provided that a further blocking member, in particular a 2/2-way valve is provided, via which, depending on the Fluid delivery working fluid is feasible in the reserve fluid container. In the fluid line between the funding and the reserve fluid container itself can at least a blocking member, in particular a check valve, may be provided in order to prevent accidental fluid flow.

Since the partially closed fluid circuit advantageously only transports of the working fluid is required, sees an appropriate further development of the inventive concept before that the funding is a motorized reversible Screw pump is. The drive especially this reversible Screw pump expediently takes place by means of a frequency-controlled Electric motor, which the funding comprises according to the invention. The usage a frequency-controlled drive has compared to known hydraulic rope hoists with conventional control the advantage that the state of the art Bypass control is no longer required because the excess volume flow is no longer in the acceleration and deceleration phases must be transported into the fluid tank against system pressure.

To realize the possibility of a rapid traverse, in both directions the screw pump at the same speed the cylinder piston speed is the same, is provided in a further embodiment of the invention, that the differential cylinder has a gear ratio of 2: 1 because in this case, the volume flows flowing when the working fluid is conveyed around stand in such a relationship that the piston speed is the same is made possible both with upward and downward movement.

As already described, the reserve fluid container is in the invention Hydro rope elevator can be dimensioned much smaller due to the smaller Amount of fluid that has to be absorbed. In this context, an im Alternative of the invention chosen with a view to optimizing the size of the overall system before that the size of the reserve fluid reservoir depending of the maximum differential volume of the two work rooms is selected. Since the Reserve fluid container in comparison to the known prior art is small, it can be outside the shaft in which the Hydro rope elevator is arranged, may be provided, for example in a corresponding Control room or control cabinet. Of course there is parallel the possibility of also arranging the fluid container inside the shaft. Of the Hydro rope hoist itself is advantageously a 1: 2 elevator where the movement distance of the cylinder piston corresponds to twice the distance of the moving load.

In addition, the invention relates to a method for operating a hydraulic rope elevator with a differential cylinder for moving a load coupled thereto, in particular a payload-receiving cabin, the differential cylinder with a working fluid. The method according to the invention draws is characterized in that the one in a funding for the working fluid Fluid circuit integrated differential cylinder two work rooms has, which are both acted upon by working fluid, which is dependent the required movement to the respective work area or is carried away from the respective work area.

Fig. 1

eine Prinzipskizze des erfindungsgemäßen Hydroseilaufzugs, und

Fig. 2

eine prinzipielle Schaltskizze des Fluidkreislaufs des erfindungsgemäßen Hydroseilaufzugs.

Further advantages, features and details of the invention result from the exemplary embodiment described below and from the drawings. Show:

Fig. 1

a schematic diagram of the hydraulic rope elevator according to the invention, and

Fig. 2

a schematic diagram of the fluid circuit of the hydraulic rope elevator according to the invention.

1 shows a hydraulic rope hoist according to the invention comprising a differential cylinder 1, to the piston rod 2 of which a counterweight 3 is coupled. The counterweight 3 is assigned a first deflection roller 4, around which a rope 5, which hangs at the end at a fastening point 6, is guided and runs to a second deflection roller 7. The rope 5 is attached at the other end to an attachment point 8 on the frame 9 of a cabin which is only partially shown. This 1: 2 system shown enables operation in such a way that when the piston rod 2 of the differential cylinder 1 is moved by a distance x, the frame 9 and thus the cabin, ie the load, is moved 2x by a distance. The differential cylinder 1 has two working spaces, as can be seen from FIG. 2. A fluid inlet or outlet 10, 11 is provided at each work space, to each of which a feed line 12, 13 is connected. The lines 12, 13 are connected to a control block 14, the Inner life "is explained in more detail with reference to FIG. 2. As FIG. 1 further shows, a conveying means 15 with a reversible screw pump 16, which is driven by a frequency-controlled electric motor 17, is also integrated in the fluid circuit. The motor is controlled by a frequency control 18 , which is followed by the elevator control 19. The fluid circuit also shows a reserve fluid container 20, which is likewise connected to the control block 14 via corresponding lines 21, 22. To move the load, fluid is now conveyed within the fluid circuit depending on the direction of movement. If, for example, the load is to be raised, that is to say the piston rod 2 has to be moved downward, working fluid is fed into the upper working space via the inlet 10, while at the same time working fluid is correspondingly drawn off from the lower working space, since there is more fluid from the lower working space expires as above z The excess working fluid is supplied to the reserve container 20 due to the differently sized differential volumes. In the opposite case, the working fluid is supplied to the lower working space in order to move the piston upwards, with fluid flowing out of the upper working space and additionally the difference quantity being pressed in from the reserve fluid container 20.

The exact method of operation is shown in Fig. 2. The differential cylinder is shown on the left 1 with its piston rod 2. The two work rooms can also be seen 23 (upper, ring-shaped work space) and 24 (lower work space). The thick dash-dotted line A gives the separation between the hydraulic rope elevator containing shaft and the cabinet from Fig. 1 again. As Fig. 2 can be seen, a first is in the supply line 13 to the lower working space 24 Load holding valve 25 and a check valve 26 associated therewith switched. The supply line 12 to the upper working space 23 is in a connecting line 27 between the two fluid lines 12, 13, a second load holding valve 28 and, in Extension of the feed line 12, a check valve 29 assigned to it upstream. Also shown is the reserve fluid container 20, the two check valves 30, 31 are assigned. Furthermore, the reversible screw pump 16 and their frequency-controlled electric motor 17.

Through the check valves 26, 29 and the load holding valve 28, the elevator Leakage-free when switched off. The load holding valves 25 and 28 serve the differential cylinder gently and without pressure peaks respectively Accelerate or decelerate pressure fluctuations. These load holding valves 25, 28 are determined by the return pressure, the flow pressure and accordingly the control ratio regulated. You yourself have no influence on that Cylinder speed. For example, the piston rod 2 should now be lowered the working fluid from the working space 24 via the load holding valve 25 sucked off by means of the screw pump 16 and via the check valve 29 fed to the upper work area 23. The load holding valve 28 is in this case blocked. As with a 2: 1 design of the differential cylinder 1, the upper work area 23 only half of the working fluid has to be supplied, the other half flows of the volume sucked in by the screw pump 16 via a 2/2-way valve 32 in the reserve fluid container 20. The valve 32 can be electrical or can be controlled hydraulically via a control line 33 shown in dashed lines. The flow volume flow to the work space 23 is controlled by the frequency of the electric motor 17 is determined since, according to the frequency at the motor 17th a speed is set from which the particular pump 16 is pumped Volume flow results.

In reverse operation, i.e. if the piston rod is to be raised, in turn, the working fluid via the reversible screw pump 16 conveyed, in which case fluid emerging from the working space 23 via the load holding valve 28 and the check valve 26 directly into the working space 24 is promoted. In this case, the required difference is calculated using the Check valve 31 is sucked by the pump 16 out of the reserve fluid container 20. The check valve 31 serves here as a suction valve.

From Fig. 2 it also follows that at a gear ratio of 2: 1 of Differential cylinder a rapid gear shift is possible. This is through the Load holding valve 28 in the connecting line 27 between the two work spaces 23 and 24 allows. Will work fluid from the work room 23 in the lead of the work space 24 is promoted in this case with a transmission ratio of 2: 1 the running volume flow of the working space 23 is equal to the pump delivery flow, since the drain flow is exactly half of the feed Fluid volume corresponds, thus delivered the other half by the pump 16 must become. The cylinder is required with the double volume flow supplied on the cylinder piston side and thus enables the same piston speed with the same pump flow as with the reverse direction of fluid flow, So with the opposite direction of cylinder movement. Fig. 2 shows and finally two further valves 34, 35, both of which serve as safety valves.

The advantages resulting from the structure according to the invention, both in terms of performance and the required amount of fluid, are shown in the table below. Opposite is an ordinary hydraulic elevator in a 1: 2 configuration and two according to the invention Energy-saving elevators "with different delivery heights and thus different differential cylinders. As can be seen from the table, the motor power for the known elevator is 28 kilowatts, whereas the power required for the hydraulic elevators according to the invention drops to 5.5 kilowatts. This is solely due to the pressurization of the working spaces on both sides. As the table also shows, the amount of oil required is only a fraction compared to the previously known elevator, for which the maximum amount to be taken up by the reserve fluid container is given here The hydraulic lifts according to the invention are considerably lower, and the cylinder pressures acting in each case are specified, the respective working chamber pressures (1st value for the piston-side work) for the differential cylinders according to the invention space, 2nd value for the work area on the ring surface) are listed as examples. Hydraulic elevator 1: 2 Hydraulics LZZ70 / 50 energy saving elevator Hydraulics LZZ85 / 70 energy saving elevator Load capacity (kg) 630 630 630 Speed (m / s) 1.0 1.0 1.0 Delivery head (m) 20th 12th 21 Engine power 28 5.5 5.5 Steadfastness 20.2 5.3 6.3 Acceleration performance 0.53 0.71 0.72 Power loss Σ (kW) 4.1 1.8 2.8 Amount of oil (l) 785 62 111 Weight drive (kg) in the shaft 550 240 460 Noise level [dB (A)] in the shaft 55 55 55 Pressure (bar) 36.5 21/41 17/33 Volume flow (l / min) 331 115 170

Claims (14)

Hydro rope elevator, comprising a drive device with one with Differential cylinder to which working fluid can be applied for moving a load, in particular of a cabin receiving a load, characterized in that that the differential cylinder (1) in a funding (15) is integrated for the working fluid fluid circuit and two Has work rooms (23, 24), both depending on the required Movement can be loaded with working fluid. Hydraulic rope elevator according to claim 1, characterized in that the fluid circuit is a partially closed circuit in which a reserve fluid container (20) is integrated. Hydraulic rope elevator according to claim 1 or 2, characterized in that each working area (23, 24) has at least one blocking member regulating the fluid flow is connected upstream. Hydraulic rope elevator according to claim 3, characterized in that in each case Locking element designed as a load holding valve (25, 28) or lowering brake valve , to which a separate check valve (26, 29) is assigned. Hydraulic rope elevator according to claim 3 or 4, characterized in that a Locking device, possibly a load holding valve (28) or lowering brake valve in a fluid line (27) connecting the two working spaces (23, 24) is arranged. Hydraulic rope elevator according to one of the preceding claims, characterized in that a further blocking element, in particular a 2/2-way valve (32) is provided, via which depending on the fluid delivery Working fluid in the reserve fluid container (20) is feasible. Hydraulic rope elevator according to one of the preceding claims, characterized in that in the fluid line between the conveyor and the Reserve fluid container at least one blocking element, in particular a check valve (31) is provided. Hydraulic rope elevator according to one of the preceding claims, characterized in that the funding (15) is a motor-operated reversible Screw pump (16) is. Hydraulic rope elevator according to one of the preceding claims, characterized in that the funding (15) is a frequency-controlled electric motor (17). Hydraulic rope elevator according to one of the preceding claims, characterized in that the differential cylinder (1) has a gear ratio of 2: 1. Hydraulic rope elevator according to one of claims 2 to 10, characterized in that the size of the reserve fluid container (20) depending on the maximum difference volume of the two work rooms (23, 24) selected is. Hydraulic rope elevator according to one of claims 2 to 11, characterized in that that the reserve fluid container outside the shaft in which the hydraulic rope hoist is arranged, is provided. Hydraulic rope elevator according to one of the preceding claims, characterized in that the hydraulic rope elevator is a 1: 2 elevator. Method for operating a hydraulic rope hoist with a differential cylinder for moving a coupled load, in particular a one Payload receiving cabin, the differential cylinder with a Working fluid is applied, characterized in that the in one a funding for the fluid circuit having working fluid Differential cylinder has two working spaces, both with working fluid be applied, depending on the required movement fed to the respective work space or from the respective work space is dissipated.

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