HUT74203A - Method and apparatus for stabilizing modulus of elasticity of cabels - Google Patents

Abstract

The present invention relates to a method for stabilizing the modulus of elasticity of a cable harness. The process according to the invention is characterized by repeating the tensile or tensile hair of a variable size before repeating the operation of the cord rope (2). The invention also relates to an apparatus according to the invention. The device according to the invention is characterized by the fact that the drum rope (2), which is a non-slip conveyor (3, 4) and a rope rope section repeatedly known as the rope rope section of the drums (3, 4), which is known to be used in the manufacturing device of the rope cable (2), is repetitive. unit (j> C, Fig. 1)

Description

The present invention relates to a method and apparatus for stabilizing a modulus of elasticity of a rope.

It is known that ropes are stretched under load. The degree of elongation during the initial loading period of new ropes is significant. As the load repeats, the degree of elongation decreases and the residual elongation reaches zero.

Wire rope is usually used as a structural element that, in addition to material properties, can be dimensioned in the ru • · ·

the constructor would also need a modulus of elasticity. However, such information is not provided by the companies manufacturing and distributing the rope, as it is not specified. The stranding rope is not a homogeneous body, but has many variables depending on the structure of the strand and the technology used for the stranding. Accordingly, there is no straight line in the curve describing tensile stress versus specific elongation, so that there is no range of tensile stress in which the Hooke law would apply.

Due to the conditions outlined above, the strap is re-loaded and unloaded once the structural element has been permanently assembled into a structural member and attempts to stabilize the structure of the strand and its condition important for strength. This is also reflected in the relevant literature. so e.g. L. Spel: Das Stahlseil als Constructive Element c. (Berlin, VEB VErlag für Bauwesen, 1975) also describes the strength stabilization of already existing wire ropes.

Similarly, dr. István Barkóczi's work: Determination of the mechanical properties of wire ropes (Doctoral dissertation, Technical University of Heavy Industry, Miskolc, 1982) can only provide guidance for the tests that are required for the stabilization of the wire ropes already in place.

Therefore, due to the known state of the art, which is excellent from the foregoing, the constructor does not receive data on the specific elongation and modulus of elasticity of the strand to be incorporated as a structural element. For this reason, you must provide structures that can follow the elongation of the wire rope after installation, allowing it to be adjusted or adjusted. Creating such a structure, however, is cumbersome and additional cost due to the uncertainty of design.

The object of the method and apparatus according to the invention was to lead a wire rope which, even before use, has a practically stable modulus of elasticity so that designers and machine designers can carry out exact work on the wire rope.

In order to achieve the intended purpose of the process according to the invention, the rope is subjected to a pulsating tensile force varying before the plant is installed, preferably during the manufacturing process, and this stress is repeatedly repeated.

The magnitude of the loading load is selected in the range between the expected maximum and minimum operating load.

The process of the present invention was realized by recognizing the fact that the variable modulus of elasticity does not change when the variable pulsating load is repeated, increasing the number of repetitions beyond a repetition number that depends on the structure and method of manufacture of the rope. The rope is then practically considered to be a homogeneous wire or rod. It was found in our tests that the pulsating stress should not be continued after 6-12 repetitions, because in this case the change in the elongation of the elongation at the tested rope can be reduced to less than 2.10 ".

The device of the present invention achieves its object by providing a non-slip passage of bit ropes and a load unit for repeated mechanical stressing of the rope section between drums. Drum actuators can be used for example. to put a pulsating load on the rope. Drum motors can be driven by electric motors. However, there may also be a load unit comprising a roller fitted to the drum rope section between the drums and a hydraulic cylinder pressed with varying force.

Preferably, the transfer drums and the load unit are part of the rope manufacturing equipment. In the apparatus according to the invention, it is expedient to employ a control device for controlling the load unit, the control signals of which are provided by a sensor of certain parameters of the rope.

Thus, the process of the present invention involves subjecting the rope to a varying amount of tensile or tensile stress before it is operationally installed.

The apparatus of the present invention comprises a load unit providing repetitive mechanical stress to the non-slip conveyor of the wire rope, preferably incorporated into the wire rope manufacturing apparatus, and to the wire rope between the drums.

The process and apparatus of the invention will be described in more detail with reference to the exemplary apparatus shown in the accompanying drawings.

In the drawings it is

Fig. 1 is a diagrammatic side elevation view of the apparatus according to the invention, a

Figure 2 is a top view corresponding to Figure 1,

Figure 3 is a side view of a detail of another example machine, a

Figure 4 is a diagram of the voltage-time function of

Figure 5 is a diagram of a voltage-specific elongation function relationship, a

Figure 6 is a diagram of a voltage-specific elongation function relationship.

1 and 2 as an example. The equipment is a wire rope manufacturer, known in the art as being inserted between the pull-through part and the winding part of the twisting machine. In the main direction of travel of the rope 2 during manufacture, the reel 3 is located after the reel 1 and then the reel 4. The wire rope 2 is wound several times on both the drum 3 and the drum 4, so that the wire rope 2 can be regarded as being held in the longitudinal direction in the longitudinal direction between the reels 3 and 4. There is a distance s between the vertical center lines of the drums 3 and 4. The drum 10 after the drum 4 serves to wind the rope 2.

The gear 5 is connected to the drum 3 and driven by the electric motor 6. The gear unit 5 is connected to the load unit 11 with the electric motor 6. The load unit 12 connected to the drum 4 comprises a gear unit 7 and an electric motor 8.

The sensor 9 is connected to the wire rope 2 between drum 3 and drum 4. 1 and 2 as an example. In the embodiment, the sensor 9 may be a roller for causing the rope 2 to bend. This roller is subjected to a crushing force proportional to the rope force exerted on the rope 2. This compression force, after converting into an electrical signal, can be used to control the load unit 11 and the load unit 12 by means of a control unit (not shown) which is not known per se. The load unit 11 and the load unit 12 are capable of driving the drum 3 with different degrees of torque.

by dropping the drum 4, a tensile stress is generated in the stranded rope section between the two drums.

The control unit of the device according to the invention can be used to preset the frequency and the voltage level required to operate the particular rope.

Figure 3 illustrates a further embodiment of the apparatus according to the invention. Here, between the drums 3 and 4, the roller 15 is pressed by the hydraulic cylinder 14 onto the rope 2. Here, the hydraulic cylinder 14 and the roller 15 belong to the loading unit 13. In this embodiment, a sensor 9 is included in the hydraulic system to control the load unit 13 by sensing the parameters present in the hydraulics.

The operation of the apparatus according to the invention and the method according to the invention will be described in more detail in the following description of the examples.

Before elaborating on the theoretical considerations leading to the development of the method and apparatus of the present invention, it should be noted that for the vast majority of structural materials, the modulus of elasticity in at least one of the range of stress in the material is precisely determined by:

R ^{E =} V .........

where

E - modulus of elasticity [kp / mm ² ]

R = voltage [kp / mm ² ] edge = specific elongation

The said voltage range, to which the formula I applies, is R @ @. straight line of the curve

equivalent to. (Hooke's Law applies to this section.)

As already mentioned, due to their special construction and manufacturing technology, there is no linear relationship between the stress and the elongation due to their special construction. Therefore, according to the invention, it is subjected to cyclic loading in the nominal voltage range of 87 to 260 MPa. This cyclic load is continued until the residual elongation at the wire rope drops below 2.10 ^-5 . In practice, this can be achieved with 6-12 repetition numbers.

1 and 2 for the apparatus according to the invention. In the embodiment, the tensioning rope 2 exiting the twisting machine 1 is subjected to varying torques by means of the load unit 11 and the load unit 12 via the drum 3 and drum 4 at different torques.

The maximum of these pulling forces is the maximum loading force expected from the installation of the rope in operation and the minimum is the minimum loading force under operating conditions. Taking the example of an elevator, the maximum load force is the value of the typical rope strength less the safety factor and the minimum is the empty weight of the cab. The varying tensile force applied to the wire rope causes a pulsating tension in the wire rope.

The time course of the alternating voltage can be well approximated by a sine curve. The graph of such a function relation is shown in

Figure 4, where the abscissa is the time t, while the ordinate is the pulsating voltage R _g .

The period of time for voltage fluctuations is defined by the following formula:

s tp = ......... II.

n · v where tp = period time [p] s = distance between the center line of two drums [m] n = number of repetitions v = transmission speed of the rope [m / p]

It follows from the above that the period number - [P ^_1 ] ...... III.

tp

The general formula for the relationship between tensile strength, stress, and cross-section is, of course, applicable to the present invention and is as follows:

P = A · R ...... IV.

where

P = force exerted on the strand [kp]

A = cross-section of the rope [mm ^]

The time course of the pulsating voltage and loading force, approximated by the sine function mentioned in Figure 4, is given by the following formulas:

27t · n v

R (t) = 0.5 (R _smax + R _sm i _n ) (1 + sin ------ t) ...... V.

s

2π · n · v

P (t) = 0.5 (P _max + P _min ) (1 + sin ------ t) ...... VI.

s where

R (t) = pulsating voltage [kp / mm ² ]

P (t) = Pulsation force [kp] ^R smax ⁼ Maximum pulsation voltage ^R smin ⁼ Minimum pulsation voltage

P _m ax ⁼ maximum force applied to ^the rope ^p min ⁼ minimum force applied to ^the rope The R diagram in Figure 5 typically illustrates the relationship between stress and specific elongation for the rope prior to the invention. It can be seen that the wire rope reflecting such a diagram cannot be scaled comfortably.

In contrast, in the diagram of FIG. 6, which is typical of a twine rope produced by the process and apparatus of the invention, the section of the curve between R _smax and R _sm i _n reflects a linear, i.e. linear, the general formula I, the Hooke's law.

In the exemplary embodiment illustrated in Fig. 3, the loading unit 13 having a hydraulic cylinder 14 transmits a transverse load on the rope via roller 15. The load is changed by means of hydraulics, therefore the sensor 9 can be connected to the hydraulic system for sensing the hydraulic parameters. Such a solution can be quite substantial in addition to the tensile stress and the bending stress in the rope, making the tension more complicated! condition develops in the rope. However, this circumstance does not affect the realization of the inventive idea.

It is also apparent from the examples that the twine rope produced by the method and apparatus of the invention has a constant modulus of elasticity. Such a rope facilitates the planning of the installation and, through its application, can simplify or eliminate installation test loads, post-assembly adjustments and corrections.

Claims (7)

PATENT CLAIMS A method for stabilizing a modulus of elasticity of a rope, characterized in that the rope (2) is subjected to a variable amount of tensile or tensile bending before being put into operation. Method according to claim 1, characterized in that the twine rope (2) is subjected to a pulsating stress in the manufacturing process after the end of twisting. Method according to claim 1 or 2, characterized in that the stress is varied in the range between the lower and upper limit of the expected stress of the rope (2). 4. A method according to any one of claims 1 to 4, characterized in that the known drums (3, 4) of the drum (2), which are known to be self-propelled and which are incorporated into the manufacturing device of the wire rope (2) a mechanical stress loading unit (11, 12, 13). Apparatus according to Claim 4, characterized in that a load unit (11, 12) is provided which comprises a gear unit (5, 7) connected to the electric motor (6, 8) in driving relationship with the drum (3, 4). Apparatus according to claim 4, characterized in that there is a load unit (13) which includes a roller (15) fitted to the rope section between the drums (3, 4) and a hydraulic cylinder (14) connected thereto. 7. Apparatus according to any one of claims 1 to 3, characterized in that the load unit (11, 12, 13) controls a sensor (9) for detecting at least some of the load parameters of the wire rope (2).