FR2881068A1 - METHOD FOR DETECTOR MATERIAL CHANGE - Google Patents

Abstract

The method is applied to detect a change of material during a machining operation by a tool in which the current and / or the power absorbed by a drive motor (1) of the tool is measured and positioned thresholds for detecting each change in current and / or power measurement. According to this method, the thresholds are set on the derivative of the current and / or the power absorbed.

Description

The invention relates to the technical sector of measurement means of the

  current and / or power absorbed by a drive motor of a tool, including a machine tool.

  It is known to produce various products in several materials having different thicknesses and hardnesses. For example, three materials of different structures can be superimposed by performing a stack, without knowing the thickness of the different layers. However, it is important, during a machining operation such as drilling, to be able to detect the changes and transitions of materials in order to adapt the machining conditions to the specific characteristics of the material concerned. For example, it is important to be able to modulate the feedrate and the rotational speed of the tool, that is to say of a drive motor.

  Of course, the current absorbed and / or the power absorbed by the drive motor of the tool, may depend directly on the hardness of the thickness of the material layer considered: a thickness and / or a high hardness generates a significant power consumption.

  Reference is made to the graph of FIG. 1 which represents the work of a tool (0), for example a drill bit, for drilling the various layers of material constituting the product, namely an aluminum layer (Al), a layer of carbon (C), a layer of titanium (Ti). On this graph is represented, on the ordinate, the power absorbed by the tool, while on the abscissa is carried the time.

  A solution to this graph may be to set thresholds to detect each change in power level, ie (Pc) the detection threshold between the aluminum layer and the carbon layer. This solution can be regarded as satisfactory as long as the tool is new, as can be seen from the solid line curve of FIG. 2 representing machining with a new tool. By cons, in case of wear of the tool as shown in phantom in Figure 2, the detection threshold (Pc) is not crossed, so that the change of material is not detected.

  To try to remedy these drawbacks, we can try to use the relative threshold, the power absorbed being measured at a given time when the tool is machined in full material. The detection threshold is then set in relative relation to the measurement made in full matter at time (Te). We refer to the graph of Figure 3.

  This solution, however, has certain disadvantages, given a large number of constraints.

  When the thicknesses to be machined are very thin, the definition of the instant of measurement of the power in full material necessary for the calculation of the relative threshold, is very delicate to establish. It is difficult to determine the moment (To) since the stability of the measurements is very short. As a result, the detection threshold is poorly defined, so that the detection of the material change is very random.

  It is also observed that the graphical representation of the relative thresholds is very delicate since the thresholds are different for each machining. It is impossible to represent the entire lifespan of a tool with the material change threshold. Relative thresholds require very long focus.

  Finally, it has been observed that for machining in materials where the thickness varies in large proportion (from 1 to 5 for example), the setting of the relative thresholds does not always work. Indeed, the measurement of machining power and the calculation of the material change detection threshold must be compatible with the lowest thickness to be machined. As a result, if the power does not remain constant, depending on the depth of the machining, the relative threshold can no longer detect the change of material.

  Referring to Figure 4 where the solid line curve represents the machining in a small thickness, while the curve in phantom represents the same machining with a thickness, for the first material, more important. From a certain piercing thickness, the absorbed power increases steadily. Detection with the relative threshold no longer works.

  The object of the invention is to remedy these disadvantages in a simple, safe, efficient and rational manner.

  The technical problem to be solved by the invention is to be able to set the material change threshold, even with very thin machining thicknesses, to overcome the state of wear of the tool and to be able to to cross this threshold, even when the thicknesses of materials to be machined vary significantly.

  To solve such a problem, it has been conceived and developed a method according to which the current or the power absorbed by a drive motor of the tool is measured and detection thresholds are positioned at each change of current measurement. or power. According to this method, the thresholds are positioned on the derivative of the current and / or the power absorbed.

  For the implementation of the method, the device comprises a module traversed by the three motor supply phases and integrating the components able to measure the active current and / or the active power absorbed by the motor, said module being connected to a differentiating module of the current and / or power signal, said signal being sent in a comparison module of its derivative with a reference threshold.

  The invention is described below in more detail with reference to the figures of the accompanying drawings, in which: FIGS. 1, 2, 3 and 4 are graphs showing in particular the power curves as a function of time in the case of a product resulting from a stack of three layers of different materials, the different graphs showing the limits obtained according to the solutions of the prior art; FIG. 5 shows, by a graph, the positioning of the thresholds on the derivative of the power or the current absorbed according to the invention in correspondence with machining curves, illustrated in FIG. 4, one of which represents the machining in a low thickness, while the other represents the same machining with a thickness for the first larger material.

  FIG. 6 is a schematic diagram of the means for implementing the method according to the invention; FIG. 7 represents a machining curve in the context of an automatic drilling of an aluminum / carbon / titanium structure; FIG. 8 shows, in correspondence with FIG. 7, the positioning of the detection thresholds on the derivative of the power; FIG. 9 shows an operating diagram of an automatic drilling corresponding to the curve of FIG. 7.

  FIG. 6 illustrates a motor (1) for driving a machine tool tool for example. In the three supply phases (a), (b), (c) of the motor (1), a module (2) integrating the components able to measure the active current and / or the active power absorbed by said motor (1). ). The sensor is connected to a differentiation module of the current and / or power signal. The signals of the module (3) are sent to a module (4) for comparing the current or the power absorbed with a reference threshold. It therefore appears that, according to the invention, the reference thresholds are positioned on the derivative of the power or the current absorbed (e).

  Reference is made to the graph of FIG. 5 which shows the positioning of the thresholds on the derivative of the power absorbed in correspondence with the machining curves illustrated in FIG. 4.

  The advantages of the process according to the invention are described below.

  - The device can operate with very thin machining thicknesses, since there is no power measurement to achieve to set the material change threshold.

  - The values of the material change thresholds are independent of the wear state of the tool, so that it is possible to display a complete life of the tool at material change detection thresholds. Settings can be made graphically, very easily.

  - The threshold of change of material detected is crossed even when the thicknesses of materials to be machined vary significantly.

  FIGS. 7 and 8 illustrate the application of the method and the device according to the invention to the automatic drilling of a structure composed of an aluminum layer, a carbon layer and a layer of titanium.

  Figure 7 shows the power curve absorbed at the aluminum layer (Al), the carbon layer (C) and the titanium layer (Ti). On this curve, (A) represents the forward speed change, (B) the change of material, (M) the stopping of advances, (D) the change of speed of the drive motor, (E) the drive motor speed reached, (F) feed rate, (G) material change, (H) feed stop, (1) motor speed change, (J) speed achieved engine, and (K) advance work.

  In FIG. 8, the positioning of the detection thresholds on the derivative of the absorbed power corresponding to the different material changes, and to the different drive speeds of the motor are represented. Thus, (S1) corresponds to a piece tool contact detection, (S2) corresponds to the carbon aluminum detection threshold, (S3) to the titanium carbon detection threshold, and then (S4) to the material output detection threshold.

  Referring to Figure 9 which shows the operating flow diagram of the automatic drilling of the aluminum structure, carbon, titanium, according to the graphs of Figures 7 and 8.

  Without departing from the scope of the invention, the method finds an advantageous application for milling operations. As indicated, the principle is independent of the wear of the tool and is also independent of machining thickness variations in the case of milling operations. Whatever the variations in thickness and machining differences, the material changes considered at the level of the derivatives are always identical.

  It is also observed that the method finds an application for detecting the piece tool contact, as well as for detecting the output of the material.

  Without departing from the scope of the invention, the derivative of the power can also be calculated numerically. In this case, to amplify the material variations with respect to the machining mode, it may be advantageous to calculate the derivative at the instant (tn), as the difference between two non-consecutive power samples. This pseudo-derivative is advantageous when the differences between the material hardnesses are small.

  The advantages are apparent from the description.

Claims (1)

8 claims   -1- Method for detecting a change of material during a machining operation by a tool according to which the current and / or the power absorbed by a drive motor (1) of the tool is measured and positioning of thresholds for detecting each measurement change of current and / or power, characterized in that the thresholds are set on the derivative of the current and / or the power absorbed.   -2- Method according to claim 1, characterized in that one calculates the derivative numerically.   -3- Method according to claim 1, characterized in that one calculates the derivative at a significant time interval.   -4- Device for implementing the method according to any one of claims 1 to 3, characterized in that it comprises a module (2) traversed by the three feed phases (a), (b), (c) the motor (1) and integrating the components able to measure the active current and / or the active power absorbed by the motor, said module (2) being connected to a differentiation module (3) of the signal of current and / or power, said signal being sent in a module (4) for comparing its derivative with a reference threshold.