DE10121615A1 - Elastic yield and spring constant determination for an assembly of components connected together by one or more connection elements by application of loads to the components joined together - Google Patents

Abstract

Method for determining the elastic yield of components joined together by one or more connection elements in which the length alteration of the connection element or elements is determined dependent on the application of additional loads to the joined together components as well as determination of the elastic yield of the components in conjunction with a tensioning diagram.

Description

The invention relates to a method for determining the elastic Flexibility of one another by means of at least one connecting element the components to be connected.

In mechanical engineering, in many cases you have to rely on that for production one required for mainly dynamic load cases of an assembly Securing the connection of two or more components of the assembly is required to determine the bias of the connecting element (s), in particular in industrial production with optimal process reliability economical use of materials and labor.

It can generally be assumed that the material properties and the spring constant of the connecting element or elements with sufficient Ex act known or in a simple manner, for example by known Meßver drive or can also be calculated, while those for securing the Connection against loosening important elastic compliance or spring constant the components of an assembly to be connected to one another are generally not included sufficient certainty can be determined. In particular, the mentioned Kri teries of the components to be connected to each other, mostly due to their mostly complicated geometry not by calculation or simple experimental Measurements can be determined.

A known measuring arrangement which can be carried out in the laboratory exists, for example in that on the components to be connected in the local area of the future term arrangement of the connecting element to be preloaded first a de defined force, compressive or tensile force, and then the right resulting local compression or elongation of the assembly is measured, wor from then on furthermore the slope of the spring constants corresponding to the sought  Characteristic curve of the components of the component group can be determined. On fundamental disadvantage based on such laboratory measurements Elastic compliance or spring constants are determined by that these sizes are never on site, i. H. at the real place of use of the respective Connection of components can be determined. They also require this Laboratory measurements always extensive preparations mainly related Lich the adaptation of the measuring equipment to the respective geometry of the components and the local boundary conditions if a reasonably accurate result should be achieved.

Based on this state of the art, the object of the invention reasons, a procedure for determining the elastic compliance of to be connected to one another by means of one or more connecting elements Specify components that provide a precise representation of the spring constant characteristic curve of the components under the respective operating conditions of the connecting element or elements and which both in the form of a single determination as well as in the form of a series determination.

This object is achieved by determining the change in length or the pretension of the used and selectable pretensioned Connection elements (s) depending on the application of an additional Load on the components to be connected to each other solved.

Such an indirect measuring method avoids the other known methods the inherent inaccuracies in that it is necessary to obtain a ver Directly on site, d. H. at the real place of use of the respective connection of components that correspond to one another as precisely as possible and thus an accurate determination of the spring constant of the ver binding components leads. At the same time, the method according to the invention is distinguished by way of saying that neither on the components nor on the connecting elements  preparatory measures must be taken whatever the use area of the procedure expanded considerably.

In an advantageous embodiment, it is also provided that the additional Bela Stung concentric to the connecting element and preferably in the immediate vicinity Proximity of the contact surfaces of the connecting element on the component surfaces is applied.

Basically, it is for the application of the procedure according to the invention completely irrelevant whether the additional burden on the interconnected Components is applied as a compressive force or as a tensile force. The additional Bela stung can be chosen either as parallel to the axis of the connecting element directed pressure force on the outer surfaces of each other components to be connected or as also to the axis of the connecting element parallel compressive force on the inner surfaces of each other components to be connected are applied.

The given prestressing force depends on the application an additional load on the components to be connected The resulting change in length of the connecting element (s) results from the fact that the elastic compliance or characteristic of the Connecting element (es) is previously known, a measurement result from the using the relationships of the tension diagram, the elastic Resilience or the spring characteristic of the components can be determined.

A preferred embodiment of the method according to the invention is characterized by the use of a tool having a plurality of components, a first component of the tool being associated with the generation and possibly the control of the prestressing force in the connecting element,
a second component of the tool is associated with the application of an additional load to the components to be connected to one another
a third component of the tool is assigned to the determination of the change in length of the connecting element or its pretension and finally
a fourth component is formed by an evaluation system, which determines the elastic compliance of the components according to the mathematical relationships of the stress diagram and, if necessary, displays them.

In most applications it can be assumed that the components to be connected to each other behave almost like a spring, where is to be expected that with regard to the elastic compliance or be a degree with respect to the spring constant of the components to be connected linear curve of the characteristic curve in the stress diagram results. With some Groupings and load cases of components are therefore also a problem Radial course of the characteristic curve for the elastic compliance or the spring cone to the components to be connected to each other in the tension diagram expect. While with the expected straight course of the elastic Resilience or the spring constant of the characteristic curve assigned to the components in Stress diagram a single measurement of the elastic compliance of the Components is sufficient to have a usable for the entire range of characteristics never getting a valid result, it can be expected when the odd The course of the characteristic may be expedient or even necessary, a series of measurements solutions.

To determine the course of a non-rectilinear characteristic curve, follow the inventive method provided that in the course of a change tion, in particular an increase in the bias in the connecting element the elastic compliance of the components is continuously determined. Favorable become wise for this with continuous increase of the preload in the connection the additional loads pulsating on the components brings and the associated changes in length of the connecting element continuously determined and displayed as well as recorded.  

The results of one during the prestressing of a fastener measurements carried out on a random or continuous basis Solution of elastic compliance of the components can also be used for immediate Control of the compo causing the pretension in the connecting element the tool.

The means required to carry out the method according to the invention and Devices, in particular measuring methods, are known per se and as such not the subject of the invention. With regard to measuring the change in length the connecting element (s) during the application of an additional Chen load on the components is used to achieve the most accurate detection possible solution even the smallest sizes using a z. B. by the introduction of Ultrasonic waves in the or the connecting element (s) marked measurement method in which the ultrasonic waves at one end of each connecting element mentes into this and naturally from the opposite end of the connecting element are reflected and from the runtime of the Ultra the current length of the connecting element is determined, prefers.

For example to illustrate the method according to the invention this is based on a roughly schematic representation of an embodiment possibility explained.

In the drawing, the

Fig. 1 shows a section through means of a connecting element components to be connected;

FIG. 2 shows the characteristic curve for the elastic compliance of the components according to FIG. 1 determined in a tension diagram.

For the sake of simplicity and to be explained, the connection between two plate-shaped components 1 and 2 by means of a screw 3 has been selected as a connecting element for the sake of simplicity and without limitation. The screw 3 penetrates a bore 5 in the two plates 1 and 2 with its shaft part 4 . Furthermore, the screw 3 after application of an assembly bias on the one hand with its head 6 on the outer surface 7 of the plate 1 and on the other hand on the nut 8 on the outer surface 9 of the plate 2 on.

In the course of executing the method according to the invention, an assembly pretension is introduced into the screw 3 in a screw step device 11 present in a tool head 10 shown in a fragmentary manner in a first method step.

In a second method step, the first under this bias voltage is detected an entered elongation of the bolt 3 by 12, ultrasonic waves are introduced into the screw 3 by a contained in the tool head 10 stations which reflects naturally by the head 6 opposite end 13 of the screw 6 and be caught by a receiver 14 .

In a third step of the process, a pressure ring 15 surrounding the screw-rotating device 11 and an abutment 16 lying opposite it is used to apply a known additional load, directed parallel to the screw 3 , to the surfaces 7 and 9 of the two plates 1 and 2 , such that the screw 3 to is relieved to a certain amount, which of course causes a decrease in the pretension in the screw 3 , which of course at the same time leads to a change in the length of the screw 3 . In a fourth method step, the length of the screw 3 is now determined, with the additional load on the two components 1 and 2 acting simultaneously, in the same way if it is determined by measuring the transit time of ultrasonic waves introduced. In a last method step, the elastic compliance of the two components 1 and 2 is then determined by means of a computer 17 connected downstream of the tool head 10 on the basis of the mathematical relationships of the stress diagram from the measured values determined and the amount of the additional load.

The mathematical combination relevant for the execution of the method slopes result in the tension diagram as follows

From the first upon introduction of the assembly with a biasing force FM in the screw 3 follows a determined by measuring length of the screw fa. 3 At the intersection of the length application fa and the force application CFM, there is a point A from which the characteristic curve of the screw 3 can be derived. During the action of the additional load FA applied parallel to the screw 3 on the components 1 and 2 , the preload in the screw 3 is reduced to an amount FS, which at the same time leads to a shortening of the screw 3 by an amount fb, so that a new intersection point B can be determined on the characteristic curve of the screw 3 . At point B, the additional external force FA acting on the two components 1 and 2 is applied, resulting in a point C. If you now connect point C to point A and extend the straight line to the point of intersection with axis f of the diagram, you get the rise angle β for the spring characteristic of the two components 1 and 2 and thus the elastic flexibility.

Claims (7)

1. A method for determining the elastic compliance of at least one connecting element by means of at least one connecting element, characterized by determining the change in length of the inserted and selectively prestressed connecting elements (s) depending on the application of an additional load to the ver binding components as well as the determination of the elastic compliance of the components based on the relationships in the tension diagram of the connection. 2. The method according to claim 1, characterized in that the additional loading load usually concentric to the connecting element and preferably in the immediate vicinity of the contact surface of the connection's investment areas element is applied to the component surfaces. 3. The method according to claim 1 and 2, characterized in that the load as directed generally parallel to the axis of the connecting element Pressure force on the respective outer surfaces of the ver binding components is applied. 4. The method according to claim 1 and 2, characterized in that the load as directed generally parallel to the axis of the connecting element Compressive force on the inner surfaces of the interconnect the components is applied. 5. The method as claimed in one of the preceding claims 1 to 4, characterized by the use of a tool having at least four components, a first component of the tool being associated with the generation and, if appropriate, the control of the prestressing force in the connecting element,
a second component of the tool is associated with the application of an additional load to the components to be connected to one another;
a third component of the tool is assigned to the determination of the change in length of the connecting element and finally
a fourth component is formed by an evaluation system, which determines the elastic compliance of the components according to the mathematical relationships of the stress diagram and makes them available for processing. 6. The method according to any one of claims 1 to 5, characterized in that in The course of a change, in particular an increase or decrease in Preload in the connecting element continuously the elastic compliance of the components is determined. 7. The method according to any one of claims 1 to 6, characterized in that at continuous change in the preload in the connecting element additional stress applied to the components in a pulsating manner and both the additional loads as well as the associated changes in length of the connecting element are continuously determined and recorded.