METHOD OF MONITORING A MILLING PROCESS

专利摘要:
The invention relates to a method of monitoring a milling method of a milling machine equipped with a milling cutter (3) comprising cutting teeth (5), characterized in that it comprises the following steps: measurement values of a first parameter corresponding to a bending of the cutter (3) as a function of a second parameter corresponding to the angle of rotation of the cutter (3) in a rotating reference of the cutter (3), - and the measurement values are analyzed according to at least one monitoring criterion.
公开号:FR3034693A1
申请号:FR1500755
申请日:2015-04-13
公开日:2016-10-14
发明作者:Patrice Laurent；Roger Busi
申请人:Centre Technique Des Ind Mec Et Du Decolletage；
IPC主号:

专利说明:

[0001] The present invention is in the field of machining and more particularly in the field of milling. Milling involves the removal of material in the form of chips resulting from the combination of two movements: the rotation of the cutting tool on the one hand, and the advancement of the workpiece or tool cut on the other hand. A milling machine nowadays is equipped with a numerical control unit which makes it possible to produce all types of shapes, even complex ones. In an industrial milling process, a large number of parts are produced with a single cutter. In the interest of productivity and quality, it is important to know when to replace the cutter because it no longer has the required characteristics in terms of cutting and or symmetry for example to obtain parts with a quality of surface and dimensions defined in advance. Even when replacing a milling cutter with a new one, it may have a manufacturing defect that prevents the production of good parts, that is, parts having the required dimensions with an acceptable surface condition. Today, the replacement of the milling cutter is done according to the experience of the milling machine operator. However, for safety, it is necessary to change the cutter for safety well before it is worn and produce defects on the machined parts. This is detrimental to overall productivity, because of the cost of a new milling cutter, and because the replacement of a milling cutter requires a downtime of the milling machine, which lowers the production rate. BRT1493 3034693 2 In addition, when a new cutter has a defect, it is often only discovered after the manufacture of a number of parts which must then be discarded. This also has a cost which reduces the productivity of the industrial process.
[0002] If a cutter is worn and replaced too late, the parts produced may have defects, but also the electrical energy consumption of a milling machine with a worn cutter increases significantly. To overcome these drawbacks, it has been proposed to monitor the milling processes in real time, for example using a Kistler type measuring plate (trade mark) which makes it possible to measure the cutting forces in three directions. a Cartesian coordinate system: x- the axis of the advance, y- the axis perpendicular to the advance and z-the axis of rotation of the cutter.
[0003] However, the analysis of the measurements is complex and difficult and generally does not allow to detect for example a dissymmetry of the strawberry. According to another approach described in DE 9014037 or US 8,113,066, the milling head of an adapter is equipped to measure the torque of the cutter to monitor the milling cutter. However, no simple method of analysis to deduce a wear of the cutter requiring the change thereof is proposed. The present invention aims to provide an optimized method of monitoring a milling process.
[0004] To this end, the subject of the invention is a method of monitoring a milling method of a milling machine equipped with a milling cutter comprising cutting teeth, characterized in that it comprises the following steps: measurement values of a first parameter corresponding to a bending of the milling cutter according to a second parameter corresponding to the angle of rotation of the milling cutter in a rotating reference mark of the milling cutter, and analyzing the measured values according to at least one monitoring criterion.
[0005] In fact, the inventors of the present invention have discovered that the wear or defect of a milling cutter results in a change in the measurement values of the bending moment of the milling cutter. Monitoring of a parameter related to the bending moment of the cutter thus makes it possible to quantitatively detect the wear of a cutter during operation. In going further, it is possible to define thresholds that must not be exceeded so as not to compromise the good quality of the workpieces and thus to alert for example an operator to change the milling cutter or to order the automatic milling cutter change in a milling machine. equipped with an automatic strawberry change module. The machining method according to the invention may furthermore have one or more of the following aspects, taken alone or in combination. In one aspect, in a range of angular values corresponding to a cutter tooth in a rotating reference of the cutter, the maximum measurement value of the first parameter is determined and a monitoring criterion comprises the time evolution of the measured value. maximum of the first parameter. In another aspect, the maximum measurement value is determined for each cutting tooth of the cutter.
[0006] In yet another aspect, a monitoring criterion includes the difference in the maximum measurement value of a cutting tooth with respect to the other teeth. Another monitoring criterion may include the time offset of the maximum measurement value of the first parameter of at least one cutting tooth from the second parameter. It can be provided that in a range of angular values corresponding to a cutting tooth in a rotating reference of the milling cutter, the minimum measurement value of the first parameter is determined and a monitoring criterion comprises the time evolution of the milling cutter. minimum measurement value of the first parameter. According to yet another aspect, the minimum measurement value is determined for each cutting tooth of the cutter.
[0007] Yet another monitoring criterion may include the dispersion of the measurement values over several raster turns of the first parameter for at least one value of the second parameter.
[0008] For example, at least one monitoring criterion is compared to a predefined threshold and an alert signal is generated if the threshold is exceeded. The predefined threshold can be defined by a learning process.
[0009] The first parameter is for example a bending moment of the cutter. The second parameter is for example an angular position of the cutter. The invention also relates to an automatic milling method with a milling machine equipped on the one hand with a milling cutter with cutting teeth and on the other hand with an automatic milling change module, characterized in that one implements a monitoring method as defined above and controls an automatic strawberry change if exceeding at least a predefined threshold of a monitoring criterion. The invention furthermore relates to a device for monitoring a milling method of a milling machine equipped with a milling cutter comprising cutting teeth for carrying out a monitoring method as defined hereinabove. characterized in that it comprises: at least one measuring sensor of a first parameter corresponding to a bending of the cutter according to a second parameter corresponding to the angle of rotation of the cutter in a rotating reference mark of the cutter, 10 - and a unit for analyzing the measurement values according to at least one monitoring criterion. The monitoring device comprises for example a milling mandrel incorporating at least one measuring sensor, in particular a strain gauge 15. Other advantages and features will become apparent upon reading the description of the invention, as well as the appended drawings in which: FIG. 1 shows a block diagram of a monitoring device according to the invention for the implementation of a method according to the invention, - Figure 2 is an explanatory diagram of a rotating reference of the cutter, - Figure 3 is a first example of a polar diagram showing measurement values of a first parameter corresponding to a bending of the cutter according to a second parameter corresponding to the angle of rotation of the cutter, - Figure 4 is a two-dimensional diagram of Figure 3 showing measurement values of a first BRT1493 3034693 6 parameter corresponding to a bending of the cutter according to a second parameter corresponding to the angle of rotation of the cutter, - Figure 5 is a second example of a polar diagram showing measurement values of a first cutter. arameter corresponding to a bending of the cutter according to a second parameter corresponding to the angle of rotation of the cutter, - Figure 6 is a two-dimensional diagram of Figure 5 showing measurement values of a corresponding first parameter. at a bending of the cutter according to a second parameter corresponding to the angle of rotation of the cutter, - Figure 7 is a third example of a polar diagram showing measurement values of a first parameter corresponding to a bending of the cutter according to a second parameter corresponding to the angle of rotation of the cutter; - FIG. 8 is a fourth example of a polar diagram showing measurement values of a first parameter corresponding to a bending of the cutter according to a second parameter corresponding to the angle of rotation of the milling cutter; - FIG. 9 is a fifth example of a polar diagram showing measurement values of a mill first parameter corresponding to a bending of the cutter according to a second parameter corresponding to the angle of rotation of the cutter, BRT1493 3034693 7 - Figure 10 is a two-dimensional diagram of Figure 9 showing measurement values of one first parameter corresponding to bending of the cutter according to a second parameter corresponding to the angle of rotation of the cutter. In the figures, the identical elements are identified by the same references. The following achievements are examples. Although the description refers to one or more embodiments, this does not necessarily mean that each reference relates to the same embodiment, or that the features apply only to a single embodiment. Simple features of different embodiments may also be combined to provide other embodiments.
[0010] In the description it is possible to index certain elements or parameters, such as for example first element or second element as well as first parameter and second parameter, or first criterion and second criterion, and so on. In this case, it is a simple indexing to differentiate and name elements or parameters 20 near but not identical. This indexing does not imply a priority of one element, parameter or criterion with respect to another, and it is easy to interchange such denominations without departing from the scope of the present description. This indexing does not imply either an order in time for example to appreciate such or such criteria.
[0011] Figures 1 and 2 show a device 1 for monitoring a milling process of a milling machine equipped with a milling cutter 3 having cutting teeth 5, in this case for example four cutting teeth 5 ,, 52, 53 and 54. In addition, in Figure 2, there is shown the reference x ', y' of the cutter. This marker is fixed relative to the milling cutter and rotates with it during milling work. BRT1493 3034693 8 A workpiece 7 is clamped in a vise 8 and the cutter 3 rotates for example clockwise to remove material for example in a workpiece 7 to be machined, for example metal, advancing with a speed of Advance v, (Figure 1) and turning with a number of turns N 5 per minute. The cutter 3 is held in a chuck 9 equipped with at least one measurement sensor 11 making it possible to measure a first parameter corresponding to a bending of the cutter as a function of a second parameter corresponding to the angle of rotation of the cutter in a rotating marker of the cutter. More specifically, the first parameter is for example a bending moment of the cutter and the second parameter is the angular position of the cutter. Thus, at each rotation of 360 °, for each angular position of the mill 3 is provided a new measurement value 15 of the first parameter, that is to say, for example, the bending moment of the milling cutter 3. From In this way, the bending moment of the milling cutter 3 can be closely monitored, for example as a function of its angular position, and in particular the cutting / milling work of each tooth 5 of the milling cutter 3 can be individually followed. The measuring sensor 11 comprises, for example, one or more strain gauges 13. According to one embodiment shown in the figures, the sensor 11 comprises on the one hand a first set of four strain gauges 13, 132, 133 and 134 and secondly a second set of four strain gauges 13 ,,, 132 ,, 133, and 134 ,. The first set comprises two first strain gauges 133 and 133 disposed one 13, above the other 133 and two second strain gauges 132, and 134 offset by 180 °, the strain gauge 131 being in contact with each other. 30 to the strain gauge 132 and the strain gauge 133 facing the strain gauge 134. The second set of four strain gauges 131, 132, 133, and 134, is mounted similarly to the first set, but shifted 90 ° (see Figure 2). Thus, the second set comprises two first strain gauges 13 ,, and 133, disposed one 131, on top of the other 133, and two second strain gauges 132, and 134, offset by 180 °, the strain gauge 13f, being opposite the strain gauge 132, and the strain gauge 133, facing the strain gauge 134,. The strain gauges 131, 132, 133 and 134 of the first set 10 are electrically connected according to a Wheatstone measurement bridge to provide a first measurement signal. The strain gauges 13, 132, 133, and 134 of the second set are also electrically connected along a Wheatstone measurement bridge to provide a second measurement signal.
[0012] These strain gauges 13 are connected to a first wireless processing and transmission electronic unit 15 carried by the mandrel 9. Of course, other sensors than strain gauges can be used to measure a first parameter corresponding to a Stripping the cutter without departing from the scope of the present invention. It is also possible to increase the number of strain gauges of the measuring sensor 11. The first electronic unit 15 communicates the wireless measurement values to a second stationary electronic unit 17 for receiving and processing the measured values, in particular a point of view signal processing. The second electronic unit is connected to a unit 19 for analyzing the measurement values according to at least one monitoring criterion. Of course, these units 15, 17 and 19 can be made with microprocessors or ASICS and include memories and means of calculation and analysis. The monitoring device 1 and therefore the associated method of monitoring a milling method of a milling machine equipped with a milling cutter with cutting teeth function as follows: In a first step, the following are determined: measurement values of a first parameter corresponding to a bending of the cutter according to a second parameter corresponding to the angle of rotation of the cutter in a rotating reference of the cutter. Then, in a second step, the measurement values are analyzed according to at least one monitoring criterion. In FIG. 3 is shown on a polar diagram in the reference rotating at the coordinates x ', y' of the milling cutter a first example of measurement for a new milling cutter with four cutting teeth 5, (i = 1 to 4) without defect. of a polar diagram showing measurement values of a first parameter corresponding to a bending of the cutter, here a bending moment, as a function of a second parameter corresponding to the angle of rotation of the cutter, here the angular position of the strawberry.
[0013] The center of the polar pattern is marked with the reference C and the measurement values of the bending moments are represented by the distance from the center and as a function of the angular position. Thus we distinguish on the polar diagram four protrusions E1, E2, E3 and E4 of the same shape but angularly offset by 25 respectively 90 °. Each protrusion E. (i = 1 to 4) corresponds to the profile of the bending moment that leaves each tooth 5, of section (i = 1 to 4) of the milling cutter 3. To better distinguish in the diagrams and figures which follow the measurements corresponding to a particular cutting tooth 5, the measurements for the tooth 51 corresponding to the protrusion E, were plotted in solid line, the measurements for the tooth 52 corresponding to BRT1493 3034693 11 the protrusion E2 were plotted in trait-dashes, the measurements for the tooth 53 corresponding to the outgrowth E3 have been plotted in dot-dash line, and the measurements for the tooth 54 corresponding to the outgrowth E4 have been drawn in dashed line.
[0014] For each protrusion E. (i = 1 to 4), one distinguishes a cutting edge FC, (i = 1 to 4) which represents how the tooth 5, between the rotation of the milling cutter 3 in the workpiece 7 of material which gradually increases the bending moment, until it reaches a maximum of the bending moment Max (1 = 1 to 4), then a return flank FR. (i = 1 to 4) when the tooth 5 comes out of the material which results in a sudden relaxation of the bending moment. As can be seen in FIG. 3, the bending moment never drops to zero (which would correspond to the fact that the measurement curve reaches the center C), but there are four minima of the bending moment Min, (i = 1 to 4). The min of the bending moment Min is reached just before the cutting tooth 5.41 enters the material of the workpiece 7. FIG. 4 is another representation of FIG. 3 in the form of a two-dimensional diagram showing Measuring values of the bending moment of the milling cutter as a function of the angular position of the milling cutter 3. In the present case, the measurements coming from the two Wheatstone measuring bridges are for example combined to obtain a bending resultant of the burr. 3. In this figure, each peak P1, P2, P3 and P4 corresponds to one of the four protuberances E1, E2, E3 and E4 and therefore to a particular tooth 5. The plot of each peak P corresponds to that of the corresponding excrescence E. We have also indicated the values Max, and Min, and by way of example some flanks FC, and FR., (1 = 1 to 4) which correspond between figure 3 and figure 4. BRT1493 3034693 12 So we retains that for a new strawberry 3 without flaws, the shape of each of the profiles of bending moments of the cutting teeth 5 is almost identical. Indeed, at the beginning of the milling job, the cutter with its teeth 5 is perfectly regular.
[0015] It is further noted that each cutting tooth 5 corresponds to a range of angular values in a rotating reference of the cutter. Thus, the tooth 51 corresponds for example to the range of 500 to 140 °, the tooth 52 corresponds for example to the range of 140 ° to 230 °, the tooth 53 corresponds for example to the range of 230 ° to 320 °, and tooth 54 corresponds for example to the range of 320 ° to 50 °. As and when milling work, the cutting teeth 5 will become dull and wear gradually little, or even some defects may appear. The inventors of the present invention have found that wear and tear on the cutter 3 can be translated in different ways and by analyzing the measured values according to at least one monitoring criterion, it is possible to quantify reliable wear of the cutter 3 or a defect which allows to proceed to the exchange of a bur 3 worn or failed in time.
[0016] FIG. 5 is a second example of a polar diagram showing measurement values of the bending moments of the mill 3 as a function of the angular position of the milling cutter 3. In this case, the milling cutter 3 has already carried out milling / machining for some time causing some wear of the cutter 3, for example by blunting of the cutting edges of the teeth 5. It is found that the maxima Maxi are farther from the center C because the bending moment has increased . The cutter 3 must therefore provide a greater effort to remove material in the piece 5. BRT1493 3034693 13 For comparison, there is shown in dotted line a circle 30 whose diameter corresponds to a circle passing through all the maxima Max , for a new strawberry without defects. It is therefore clearly seen that the circle 32 for a bur with a certain wear has increased by AR with respect to the circle 30. The same change in the profiles of the bending moments for each cutting tooth 5 is constant, when one passes in a two-dimensional representation in Figure 6, this representation being similar to that of Figure 4.
[0017] Thus, if one is placed in a range of angular values corresponding to a cutting tooth 5, in a rotating reference of the cutter, one can determine the maximum measurement value Maxi of the bending moment and a first criterion of monitoring is by for example, the time evolution of the maximum measurement value Maxi of the bending moment for at least one cutting tooth 5, or even all the cutting teeth 5. When for one or for all the teeth 5 a predefined threshold of wear is If the milling machine has an automatic milling module, the warning signal can trigger an order for the milling machine to be exchanged. automatic cutter changeover if at least one predefined threshold of a monitoring criterion is exceeded, such as, for example, a maximum value of the bending moment of the cutter 3 for one or all of the cutting teeth 5. In general, the predefined threshold of one of the monitoring criteria described in the present invention strongly depends on the tool-material pair, that is to say the milling cutter itself, its geometry, its surface coatings. to name only some parameters of the milling cutter and the material to be machined. To define a threshold, we can pass BRT1493 3034693 14 by a learning process, that is to say we start a milling process by determining the measured values until we find that the machined parts no longer have the required quality, especially in terms of surface condition or dimensions and the threshold is set a little below this value. According to another approach, the predefined threshold corresponds, for example, to a variation of 30%, 40% or 50% (depending on the safety range that the operator wishes to set up) of the measurement values of the considered monitoring criterion. Thus, if the maximum bending moment increases by 50%, it is known that the wear of the cutter 3 is too great and the cutter 3 must be changed. The inventors have also found that not only the maximums Max, move away from the center C testifying to a greater moment of flexion, but they have discovered a second criterion of monitoring which is the time lag of the measurement value maximum of the bending moment of at least one cutting tooth with respect to the angular position. In fact, in FIG. 4, the maximum bending moment Max 1 for the cutting tooth 5 is about 120 ° while in FIGS. 5 and 6 the maximum bending moment Max 1 for the cutting tooth 5 , is about 140 °. It can thus be seen that the angular ranges corresponding to each tooth have shifted in this case from / Xa of about 20 ° (reference 33) counterclockwise to the polar diagram of FIG. explain 25 by additional effort of the cutter 5 to enter the material 7. This offset 33 is also a monitoring criterion and therefore a value to quantitatively attest the wear of a cutter 5. When this shift 33 exceeds a predefined threshold, for example 10 ° or 15 ° or 20 °, an alarm is triggered for the operator or, for a milling machine with an automatic change module, a cutter change command 5 is triggered. FIG. 7 is another example of a polar diagram showing measurement values of the bending moments of the mill 3 as a function of the angular position of the milling cutter 3. In this example, FIG. case at ssi, the cutter 3 has already performed a milling / machining work for some time causing some wear of the cutter 3, for example by blunting the cutting edges of the teeth 5.
[0018] This time it is noted that the minima Min, are further from the center C. By way of comparison, a dotted line is represented by a circle 34 whose diameter corresponds to a circle passing through all the minima Min for a new milling cutter. flawless. It is therefore clearly seen that a circle 36 for a bur with some wear has increased in relation to the circle 34. Consequently, the analysis of the evolution of the measurement values of the bending moment can consist in determining the minimum measurement value of the bending moment for one or all of the cutting teeth 5 and a third monitoring criterion is, for example, the time evolution of the minimum measurement value of the bending moment for one or all the cutting teeth 5 When this value exceeds a predefined threshold for one or all the cutting teeth 5, an alarm is triggered or according to the milling machine, an automatic change of the worn mill is made.
[0019] FIG. 8 is a fourth example of a polar diagram showing measurement values of a bending moment on several turns of the cutter as a function of the angular position of the cutter. Another monitoring criterion is, for example, the dispersion of the measurement values over several raster turns of the first parameter BRT1493 3034693 for at least one value of the second parameter. This dispersion is representative of instability in the bending behavior of the milling cutter during machining and constitutes a criterion for evaluating the machined surface and its machining-related defects (corrugation phenomenon on sidewall milling). . The dispersion can be evaluated for example in the form of a standard deviation 38 or a variance. When for example the standard deviation exceeds a certain threshold, an alert is given to the operator to change the tool or else in a fully automated milling machine, a cutter change command is triggered. FIG. 9 is a fifth example of a polar diagram showing measurement values of a bending moment of the mill 3 as a function of its angular position and FIG. 10 is a two-dimensional diagram of FIG. 9.
[0020] FIGS. 9 and 10 show that the maximum Max 2 of the second cutting tooth 52 is smaller than the maximum Max (i = 1, 3, 4) of the other cutting teeth 5i (i = 1, 3, 4). This is a strawberry dysmetry 3 which can have adverse consequences in terms of milling surface quality and induce significant instability of the cutter 3.
[0021] Another monitoring criterion may therefore be the difference in the maximum measurement value of a cutting tooth with respect to the other teeth. As soon as there is such a dissymmetry, which can also result from a manufacturing defect or a partial breakage of a cut tooth during the machining, an alert is given to change the cutter or to order strawberry change. It is therefore understood that the method according to the invention makes it possible to quantitatively determine the wear or the defect of a milling cutter 3 and to proceed with its exchange.
[0022] One advantage of this quantitative process is that the milling cutter 3 is not exchanged too soon or too late. BRT1493 3034693 17 In fact, if the cutter 3 is changed too early for safety, there is a cost for changing the cutter itself on one side and a lower production rate on the other side. If one changes too late, one has to put a part of machined parts 5 scrapped as they do not have the required dimensions or a prescribed surface quality. By applying the method according to the invention in a milling machine having a change module, productivity is increased. BRT1493

权利要求:
Claims (15)
[0001]
REVENDICATIONS1. A method of monitoring a milling method of a milling machine equipped with a milling cutter (3) having cutting teeth (5), characterized in that it comprises the following steps: measuring values of one first parameter corresponding to a bending of the cutter (3) as a function of a second parameter corresponding to the angle of rotation of the cutter (3) in a rotating reference of the cutter (3), and the measured values are analyzed according to at least one monitoring criterion.
[0002]
Monitoring method according to claim 1, characterized in that in a range of angular values corresponding to a cutting tooth (5) in a rotating reference mark of the bur, the maximum measurement value of the first parameter is determined and in that a monitoring criterion includes the temporal evolution of the maximum measurement value of the first parameter.
[0003]
3. Monitoring method according to claim 2, characterized in that the maximum measurement value is determined for each cutting tooth (5) of the cutter (3).
[0004]
4. Monitoring method according to claim 3, characterized in that a monitoring criterion comprises the difference in the maximum measurement value of a cutting tooth (5) relative to the other teeth (5).
[0005]
5. Monitoring method according to any one of claims 1 to 4, characterized in that a monitoring criterion comprises the time shift of the value of BRT1493 3034693 19 maximum measurement of the first parameter of at least one tooth of cut (5) with respect to the second parameter.
[0006]
6. A method of monitoring according to any one of claims 1 to 5, characterized in a range of angular values corresponding to a cutting tooth (5) in a rotating reference of the cutter, the minimum measurement value of the first one is determined. parameter and in that a monitoring criterion comprises the temporal evolution of the minimum measurement value of the first parameter.
[0007]
7. Monitoring method according to claim 6, characterized in that the minimum measurement value is determined for each cutting tooth of the cutter (3). 15
[0008]
8. Monitoring method according to any one of claims 1 to 7, in that a monitoring criterion comprises the dispersion of the measurement values over several milling cycles of the first parameter for at least one value of the second parameter.
[0009]
9. Monitoring method according to any one of claims 1 to 8, characterized in that at least one monitoring criterion is compared to a predefined threshold and in that a warning signal is generated in case exceeding the threshold.
[0010]
10. Monitoring method according to claim 9, characterized in that the predefined threshold is defined by a learning process. 30
[0011]
11. Monitoring method according to any one of claims 1 to 10, characterized in that the first parameter is a bending moment of the cutter (3). BRT1493 3034693 20
[0012]
12. Monitoring method according to any one of claims 1 to 11, characterized in that the second parameter is an angular position of the cutter (3). 5
[0013]
13.A method of automatic milling with a milling machine equipped on the one hand with a milling cutter (3) having cutting teeth (5) and on the other hand with an automatic milling module for the milling cutter, characterized in that A monitoring method according to any one of claims 9 to 12 is implemented and an automatic change of milling cutter is controlled if at least one predefined threshold of a monitoring criterion is exceeded. 15
[0014]
14. A device for monitoring a milling method of a milling machine equipped with a milling cutter (3) having cutting teeth (5) for carrying out a monitoring method according to any one of claims 1. at 13, characterized in that it comprises: at least one measuring sensor (11) of a first parameter corresponding to a bending of the cutter (3) as a function of a second parameter corresponding to the angle of rotation the milling cutter (3) in a rotating reference mark of the milling cutter (3), and a unit (19) for analyzing the measured values according to at least one monitoring criterion.
[0015]
15. Monitoring device according to claim 14, characterized in that it comprises a milling mandrel (9) incorporating at least one measuring sensor (11), in particular a strain gauge (13). BRT1493

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法律状态:
2016-04-23| PLFP| Fee payment|Year of fee payment: 2 |

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2016-10-14| PLSC| Publication of the preliminary search report|Effective date: 20161014 |

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2017-05-02| PLFP| Fee payment|Year of fee payment: 3 |

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2018-04-26| PLFP| Fee payment|Year of fee payment: 4 |

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2019-04-23| PLFP| Fee payment|Year of fee payment: 5 |

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2020-04-03| PLFP| Fee payment|Year of fee payment: 6 |

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2021-04-06| PLFP| Fee payment|Year of fee payment: 7 |

优先权:

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申请号 | 申请日 | 专利标题

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FR1500755|2015-04-13|

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FR1500755A|FR3034693B1|2015-04-13|2015-04-13|METHOD OF MONITORING A MILLING PROCESS|FR1500755A| FR3034693B1|2015-04-13|2015-04-13|METHOD OF MONITORING A MILLING PROCESS|

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EP16720728.1A| EP3283929A1|2015-04-13|2016-04-13|Method for monitoring a milling method|

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CA2982496A| CA2982496A1|2015-04-13|2016-04-13|Method for monitoring a milling method|

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PCT/EP2016/058140| WO2016166173A1|2015-04-13|2016-04-13|Method for monitoring a milling method|

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US15/565,781| US20180117725A1|2015-04-13|2016-04-13|Method for monitoring a milling method|