FR2972536A1 - METHOD AND DEVICE FOR NON-DESTRUCTIVE MEASUREMENT OF FERMETE WITH POSITIVE DRIVE CONTROLLED BY ACCELEROMETER - Google Patents

Abstract

The invention relates to a method and a device for measuring the firmness of objects (9) such as fruits or vegetables in which a probe (14) is brought into contact with an object, an accelerometer (30) delivers signals acceleration, a bidirectional motor device (4) positively drives a contact arm (21) bearing the feeler in the forward direction (71) and in the back direction (72) and, on detection of acceleration signals of a higher value in absolute value at a predetermined threshold value, said stopping threshold, the motor device is controlled in the return direction. Application to a device for conveying objects.

Description

The invention relates to a method and a device for measuring the firmness of objects such as fruits or vegetables, without deterioration of these objects.

It extends to an object conveying device comprising at least one such device for measuring the firmness of the objects. Such devices for measuring the firmness of objects, comprising a feeler mounted on a movable contact arm so as to come into contact with an object, and a piezoelectric sensor mounted on the contact arm for transmitting signals, are already known. a data processing unit adapted to develop a value representative of the firmness of the objects according to these signals. Such a piezoelectric sensor provides effort signals representative of the reaction of the object resulting from the shock imparted by the probe. For this reason alone, it is necessary to exert a certain effort on the object, an effort that may have the effect of damaging it locally, particularly in the case of soft or delicate objects, for example apricots, peaches, kiwis ... In practice, this effort is generally imparted by a pneumatic cylinder and / or a spring driving the contact arm towards the object. Moreover, these known devices must generally be calibrated according to the expected firmness of the objects, which must be relatively homogeneous, and according to their expected size. Otherwise, the firmness measures they provide are unreliable and independent of the size of the objects. Now, the measurement of the firmness of objects must precisely make it possible to reliably detect soft objects in a lot of harder objects or, on the contrary, very hard objects in a batch of normally soft objects. In addition, this measurement must be able to be performed on objects of different dimensions, particularly on objects transported by a conveying device located upstream of a sorting unit or calibration of objects. Indeed, the firmness measurement can be a criterion for selecting and sorting objects, for example by a sorting unit as described by EP670276.

The invention aims to overcome these disadvantages by providing a method and a device for measuring firmness that are compatible with objects whose size can be variable over a wide range and which provide reliable measurements independent of the size of objects. The invention also aims at providing such a method and such a device which are compatible on the one hand with objects whose firmness can be variable over a wide range, including with soft objects (such as apricots, peaches, kiwifruit or other), and on the other hand that do not cause any deterioration of the objects, including when they are very soft.

The invention also aims at providing such a method and such a device that makes it possible to carry out firmness measurements on the fly at high speed on a device for conveying objects. The invention also aims at providing such a method and such a device that are simple to install and implement, in particular that do not require specific adjustment to each batch of objects to be processed, which are inexpensive, long life, compatible with aggressive environments such as agricultural environments, and energy efficient. The invention therefore relates to a method for measuring the firmness of objects such as fruits or vegetables without deterioration of these objects, in which: a feeler mounted on an arm, said contact arm, is brought into contact with a object in a direction towards and away from the object in a return direction, - a sensor integral with the movements of the probe transmits signals to a data processing unit adapted to develop a value representative of the firmness of the objects as a function of said signals, characterized in that: - said sensor is an accelerometer delivering signals, called acceleration signals, representative of values of the probe acceleration, - the contact arm is positively driven in the forward direction and in the return direction by a bidirectional motor device controlled by a control unit, - the control unit receives the acceleration signals transmitted during a movement of the contact arm in the all direction er, and on detecting a value of the acceleration signals higher in absolute value than a predetermined threshold value, called the stopping threshold, the control unit controls the motor device in the return direction. When the probe comes into contact with an object, it undergoes a deceleration (negative acceleration) which increases, and the value of the acceleration signals delivered by the accelerometer increases in absolute value. Throughout the text, the term "acceleration" generally refers to the derivative of velocity over time, which can be positive when the velocity increases and negative when the velocity decreases (and thus corresponds to a deceleration). The stopping threshold is determined to detect with certainty the presence of a probe contact with an object, regardless of its firmness. From this stopping threshold, the control unit reverses the driving direction of the motor device so that the contact arm ceases to be driven in the forward direction and is driven in the reverse direction. The invention thus simultaneously makes it possible to guarantee that the objects can not undergo any deterioration and to obtain a measurement of firmness that is perfectly reliable and accurate regardless of the size of the object, since the contact between the feeler and the object is obtained, and this in contrast to prior devices and methods providing firmness measurements that can vary considerably depending on the individual dimension of each object. In a method according to the invention, the displacement of the contact arm, and therefore also that of the probe, is continuously monitored and over its entire displacement stroke by the motor device, in terms of direction of movement and speed. In particular, it is thus possible to guarantee perfect control of the impact speed of the probe on an object in the forward direction, whatever the size of the object. However, the accuracy of control of this speed at impact is critical for the accuracy of the firmness measurement. Thus, advantageously and according to the invention, the contact arm is driven in the direction of going at a predetermined constant speed. Advantageously and according to the invention, a bidirectional motor device consisting of a bidirectional linear electric motor is used. Indeed, such a motor can drive the contact arm at a speed determined very accurately, and has a large control dynamics, especially when changing direction after impact on an object. The control law of the contact arm in the return direction can be more complex and different from that in the forward direction.

Moreover, in a method according to the invention, the dynamics of the contact between the probe and an object is permanently perfectly controlled, and can be adjusted to avoid any deterioration. Indeed, in a method according to the invention, the motor device is controlled in the return direction from a detection of an absolute value of acceleration greater than the stop threshold whose value may be in practice sufficiently low to avoid any deterioration of the objects, while being sufficient to ensure the effective detection of an impact of the probe on an object. This acceleration of the contact arm results from the cooperation of the probe with an object, cooperation which causes a braking of the contact arm and therefore an increase in the absolute value of the acceleration signals delivered by the accelerometer. The inventors have determined that the absolute value of acceleration corresponding to the stopping threshold may be sufficiently low to be compatible with particularly soft objects such as apricots, peaches, kiwis or other. Furthermore, advantageously and according to the invention, the data processing unit generates a firmness value of the objects from a time elapsing between a first instant at which the stopping threshold is reached and a second subsequent moment. to which the acceleration signals reach a predetermined value, called the calculation threshold, greater than the stop threshold. Indeed, the inventors have found that, from the moment when the control unit controls the motor device in the return direction, given the unavoidable response times and inertia, the contact arm continues its movement in the one-way direction. for a certain duration, the acceleration signals continuing to increase (in absolute value) beyond the stopping threshold very rapidly and at least substantially linearly, before stabilizing and then decreasing when the contact arm begins its displacement in the return direction. However, it turns out that the measurement of the slope of the curve representative of the absolute value of the acceleration signals as a function of time from the stopping threshold is possible (since sampling at a sufficiently important frequency is used) and provides an excellent measure of the firmness of objects. The invention applies in particular to the measurement of the firmness of objects driven in horizontal displacement. Thus, a method according to the invention is advantageously characterized in that the objects are driven in horizontal displacement relative to a chassis by a conveying device, in that the contact arm is rotatably mounted relative to the chassis and is driven in rotation in the forward direction and in the return direction by said bidirectional motor device. More particularly, a method according to the invention is also advantageously characterized in that the objects are driven at a constant speed with respect to the chassis, in that the passage of the objects at a predetermined point relative to the chassis is detected by a presence sensor. whose signals are transmitted to the control unit, and in that the control unit triggers a displacement in the forward direction of the contact arm at a predetermined time after detection of an object by said presence sensor. This instant can be predetermined so that the probe comes into contact with an object whose passage has been previously detected, regardless of the size of this object. As such, it should be noted that it is possible to adjust the release of the drive of the contact arm and its speed to ensure such contact of the probe with an object regardless of its size. Indeed, if the driving speed of the contact arm is fast enough, the size of the object has little influence on the moment and the area of contact between the probe and the object. In any case, since this contact is ensured, the accuracy and reliability of the firmness measurement are ensured by the very fact of the principle of measurement carried out by a method according to the invention. Furthermore, advantageously and according to the invention the bidirectional motor device applies on the contact arm a drive force of limited value by an elastic device interposed between the bidirectional motor device and the contact arm. This elastic device may be simply formed of a spring interposed between a first arm integral with the contact arm and a second arm secured to an actuating member of the motor device, so that the force transmitted because device is limited to a predetermined value. The invention also extends to a device for implementing a method according to the invention. The invention therefore also relates to a device for measuring the firmness of objects such as fruits or vegetables without deterioration of these objects, comprising: - a feeler mounted on an arm, said contact arm, so that it can be brought to the contact of an object in a forward direction, and away from the object in a return direction, - a sensor integral with the movements of the probe adapted to transmit signals to a data processing unit capable of developing a value representative of the firmness objects according to said signals, characterized in that: - said sensor is an accelerometer adapted to deliver signals, called acceleration signals, representative of values of the acceleration of the probe, - the contact arm is coupled to a bidirectional motor device adapted to drive positively in the forward direction and in the return direction, said motor device being connected to a control unit so as to 20 to be able to be controlled by the latter, - the control unit is adapted to be able to receive the acceleration signals transmitted during a displacement of the contact arm in the forward direction, and, to control the motor device in return direction on detection an absolute value of the acceleration signals greater than a predetermined threshold value, said stopping threshold. Advantageously and according to the invention the data processing unit is adapted to develop a firmness value of the objects from a time elapsing between a first instant at which the stopping threshold is reached and a second subsequent moment at which the acceleration signals reach a predetermined value, called the calculation threshold, greater than the stopping threshold.

Throughout the text, the term "accelerometer" means any accelerometric sensor, that is to say any sensor capable of providing signals representative of the acceleration it undergoes along at least one axis (in absolute value or in value relative, in one way or another). Advantageously and according to the invention, said accelerometer is an integrated circuit (in particular of the MEMS (electromechanical microsystem) type) mounted on the contact arm near the probe. Such an accelerometric integrated circuit provides real acceleration measurements. In addition, advantageously and according to the invention, said accelerometer is a monodirectional accelerometer whose axis is oriented at least substantially orthogonal to the contact surface of the probe, and in the middle part thereof. However, there is nothing to prevent the use of a multidirectional accelerometer, that is to say providing signals along several axes, for example a three-dimensional accelerometer providing signals along three orthogonal axes, although the signals delivered according to other directions do not not normal to the contact surface are actually useless. In addition, advantageously and according to the invention the motor device comprises a bidirectional linear electric motor adapted to drive the contact arm at a predetermined speed. In a preferred embodiment that is particularly advantageous in the case of objects driven in horizontal displacement, the contact arm is rotatably mounted relative to a frame, in particular around a horizontal pivot axis, and is rotated in the one-way direction. and in return direction relative to the frame by said bidirectional motor device. Advantageously and according to the invention, the feeler has a contact face with the objects which is convex curve, in particular in the form of a spherical cap, so as to come into normal contact with the objects at a point of contact. Nothing prevents, however, to provide any other form suitable for the contact face, including a contact surface at least substantially flat. Advantageously and according to the invention, the probe is mounted immobile with respect to the contact arm. In addition, advantageously and according to the invention the linear electric motor comprises an actuating rod movable relative to the frame and mounting the motor relative to the frame and the actuating rod relative to the contact arm is adapted so that in the absence of power supply 5 of the engine, the actuating rod being moved by gravity, the contact arm is returned in return direction. Thus, in case of power failure of the bi-directional motor device, the contact arm is automatically replaced (in return direction) by the gravity in a position in which it no longer interferes with the objects. Furthermore, advantageously a device for measuring firmness according to the invention comprises an elastic device interposed between the bidirectional motor device and the contact arm adapted to limit the training effort imparted by the bidirectional motor device on the contact arm. . The invention also extends to a device for conveying objects such as fruits or vegetables comprising at least one conveying line capable of driving the objects in horizontal displacement with respect to a frame, and at least one measuring device. the firmness of the objects carried by said conveyor line characterized in that it comprises at least one device for measuring the firmness of the objects according to the invention. In a preferred embodiment, advantageously and according to the invention: the contact arm is rotatably mounted relative to the chassis, the bidirectional motor device being adapted to positively drive the contact arm in rotation in the forward direction and in the reverse direction, a presence sensor is mounted relative to the frame so as to detect the passage of the objects at a predetermined point relative to the frame, said presence sensor being connected to the control unit to transmit signals representative of the passage of an object, the control unit is adapted to trigger a displacement in the forward direction of the contact arm at a predetermined time after detection of an object by said presence sensor.

The invention also relates to a method and a device for measuring firmness and a device for conveying objects characterized in combination by all or some of the characteristics mentioned above or below.

Other objects, features and advantages of the invention will become apparent on reading the following non-limiting description which refers to the appended figures in which: FIG. 1 is a diagrammatic representation in perspective of two measuring devices of firmness according to the invention, each mounted within a conveying device according to the invention, - Figure 2 is a schematic representation from another perspective of a mechanical portion of a device according to the invention according to Figure 1, - Figure 3 is a schematic representation of a profile of a device according to the invention according to Figure 1, - Figure 4 is a functional block diagram showing the different steps of a measuring method according to the invention, FIG. 5 is a schematic representation of a firmness measurement result obtained by a measuring method according to the invention implemented by a measuring device of FIG. according to the invention. A firmness measuring device according to the invention advantageously comprises a contact arm 21 pivotally mounted relative to a fixed frame 10 around a horizontal pivot shaft 6. The contact arm 21 has a proximal end and a distal end 16 with respect to the pivot shaft 6. The distal end 16 of the arm 21 of contact carries a probe 14 intended to come into contact with the objects 9 whose firmness is measured. The probe is attached to the contact arm so as to be integral with the movements of the distal end 16 of the arm 21 contact. Such a probe 14 may have different shapes. In particular, the probe 14 has a contact face 13 with objects 9 such as fruits or vegetables which can be adapted according to the type of objects 9 which one wishes to measure the firmness. The shape of the contact face 13 of the probe 14 is in particular chosen to be non-destructive during its contact with the object 9, the firmness of which is measured. Advantageously, in the embodiment shown in FIGS. 1 to 3, the feeler 14 has a convexly shaped contact face 13, slightly curved, in particular in the form of a spherical cap. Nothing prevents on the contrary to provide that the contact face 13 is at least substantially flat. Furthermore, the feeler 14 and the contact face 13 have a high hardness, greater than that expected for the objects 9. An acceleration sensor, or accelerometer 30, is attached to the arm 21 of contact, near the distal end 16 on which is mounted the probe 14. The mounting of the accelerometer 30 is adapted so that the accelerometer 30 is integral in displacement of the probe 14, so that the accelerometer 30 can deliver signals representative of the The accelerometer 30 is advantageously in the form of an electronic component, in particular an integrated circuit, more particularly of the electromechanical microsystem (MEMS) type. The accelerometer 30 is advantageously chosen so as to be able to measure accelerations in a range of values greater than 10 g (g being the terrestrial gravitational acceleration), in particular of several tens of g. The accelerometer 30 has at least one measurement axis, preferably one-way that is to say having a single measurement axis, and the accelerometer 30 mounted on the arm 21 of contact so as to measure the normal acceleration to the contact face 13 of the probe 14. Thus, the accelerometer 30 is mounted on the arm 21 of contact with a normal measurement axis and secant with the middle portion of the contact face 13 of the probe 14 intended to come into contact with the 9. In the case of a contact face 13 in the form of a spherical cap, the accelerometer 30 is mounted with its secant measuring axis with the top of the spherical cap and oriented according to the normal to the spherical cap in this vertex .

The accelerometer 30 sends the signals it delivers to a data processing unit 12 to which it is connected. At this end, the accelerometer 30 is electrically connected to the data processing unit 12 formed of a computing device including computing means (microprocessors) and memories. As shown in FIGS. 1 to 3, an electric connection circuit 31 integrated in the contact arm 21 extends from the accelerometer 30 (at the end 16 distal of the contact arm 21 carrying the probe 14) to the proximal end of the arm 21 of contact where it is articulated around the shaft 6 of pivoting. This electrical connection circuit 31 comprises a flexible ribbon 32 at the proximal end of the contact arm 21 to allow the electrical connection and the transmission of the signals through the mechanical articulation of the contact arm 21 around the shaft 6. pivoting. The contact arm 21 is positively driven to pivot about the pivoting shaft 6 by a bidirectional motor 4, which, in the example shown, is a bidirectional linear electric motor. The contact arm 21 is driven by the linear bidirectional motor 4 in rotation about the pivoting shaft 6 in the direction 71 to the controlled acceleration and speed until it comes into contact with an object 9, and is driven by the motor 4 rotating around the shaft 6 of pivoting in direction 72 return after detection of such a contact. In FIG. 3, the forward direction 71 corresponds to the counterclockwise (or direct) direction, and the backward direction 72 to the clockwise direction. Since the contact arm 21 is positively driven, it is not free to move inertia over part of its travel. According to the invention, it is instead continuously guided and driven by the motor 4, in one direction or another, at a speed controlled by the motor 4. Thus the speed of the probe 14 at the moment of impact with an object 9 is perfectly determined, and is always the same regardless of the size of the object 9. The reliability of the firmness measurements obtained is thus greatly improved. The linear motor 4 is mounted vertically fixed relative to the frame 10 and has a movable actuating rod 41 extending vertically downwardly relative to the body of the linear bidirectional motor 4. The lower end of the actuating rod 41 is connected to a connecting rod assembly 23 and crank 22. The crank 22 has the form of an arm, said arm 22 of the crank, rotatable about the pivot shaft 6. The distal end of the crank arm 22 with respect to the pivot shaft 6 is coupled by a first pivot connection to the connecting rod 23 which is itself coupled by a second pivot connection with the end of the rod 41 of actuation. The arm 22 crank is rotatably coupled to the arm 21 of contact. Thus, a vertical translation of the actuating rod 41 of the motor is transformed into rotations of the arm 21 of contact around the pivot shaft 6. In addition, the contact arm 21 and the crank arm 22 are arranged on either side of the pivot shaft and a resilient device 5 is interposed between the two arms 21, 22. the rotations of the crank arm 22 to the contact arm 21. However, in the direction 71 go, that is to say in the direction of rotation in which the probe 14 is approached by an object 9, the kinematic transmission rotation is within the limit of a threshold torque.

Beyond this threshold torque, if the motor continues to drive the crank arm 22 in the forward direction while the probe 14 is already in contact with an object and thus immobilized in rotation by this object, the elastic device stores the energy corresponding to the difference in displacement between the crank arm 22 and the arm 21 of contact, and thus prevents this energy is absorbed by the object. The elastic device 5 thus makes it possible to avoid the crushing of the object, in particular at the time of the first contact with it, while the motor still drives the crank arm 22 in the forward direction. In the embodiment shown in FIGS. 1 to 3, such an elastic transmission device 5 is - as shown in FIG. 2 - made up of: a first arm 51 orthogonal to the pivot shaft 6 and mounted integral with the arm 21 of contact, the first arm 51 being equipped, near a distal end (relative to its proximal attachment point near the pivot shaft), of a rod 511 mounted substantially orthogonally to the first arm 51 and to the axis of the pivot shaft 6, said rod 511 being terminated by a stop 512, - a second arm 52 at right angles, orthogonal to the pivot shaft 6 and mounted integral with the arm 22 of crank, the second arm 52 partially covering the first arm 51, and being pierced with a through-light for passing the rod 511 of the first arm 51, - a compression coil spring 53 mounted between the end stop 512 of the rod 511 of the first arm 51, and periphery 521 of the second arm light 52. Thus, at rest, the compression coil spring 53 maintains the first arm 51 and the second arm 52 in contact. The elastic transmission device 5 makes it possible to transmit completely any rotational movement of the crank arm to the contact arm in the return direction. Indeed, in the return direction, the second arm 52 comes, in its square portion, in solid-solid mechanical contact with the first arm 51. The elastic transmission device 5 makes it possible to transmit any rotational movement of the crank arm to the contact arm in the direction of going within the limit of a threshold torque (determined by the compression coefficient and the compression at rest of the spring). Indeed, the compression coil spring 53 is advantageously compressed between the abutment 512 end of the first arm 51 and rim 521 forming abutment of the second arm 52, so that below the threshold torque 20 any rotational movement of the crank arm go direction is fully transmitted to the contact arm, as if the contact arm and the crank arm were solid. If the crank arm 22 drives the contact arm 21 past the threshold torque, the coil spring 53 compresses as shown in FIG. 3 and stores the energy corresponding to the relative movement of the crank arm relative to the threshold torque. to the contact arm. This is for example the case when the contact arm is locked in rotation in the direction 71 go through an object 9 and the crank arm continues its movement in the forward direction because of the response times and inertia of the device according to the invention. Also, the rod 511 of the first arm 51 may advantageously be curved according to a curvature defined by its distance from the axis of the pivoting shaft 6 in order to facilitate the rotational movements between the second arm 52 and the first arm 51. In sum, thanks to the elastic device, a rotation of the crank arm 22 in the direction 71 to move relative to the contact arm 21 is possible, and a rotation of the contact arm 21 in the direction 71 to move relative to the crank arm 22 is prohibited. The ratio between the lengths of the crank arm 22 and the contact arm 21 makes it possible to determine exactly the speed at which the probe 14 is driven by the motor 4.

It should be noted that in the absence of power supply to the motor 4, the actuating rod 41 tends to descend relative to the chassis 10 under the effect of gravity, which tends to move the contact arm 21 in the return direction, corresponding to a safety setting of the entire device (probe 14 in the high position).

As represented in FIGS. 1 and 3, a conveying device according to the invention comprises at least one conveying line 11, for example a roller conveyor, adapted to transport fruits or vegetables 9 step by step in a translation direction 73. Such a device advantageously comprises a sensor 8 for the presence of an object such as a fruit or a vegetable on a conveyor line 11, upstream of the firmness measuring device and in any case upstream of the contact arm 21 for this purpose. line 11 conveying. This sensor 8 for the presence of an object 9 is connected to the data processing unit 12 to which it sends its detection signals for the presence of an object. In addition, the motor body and the pivot shaft 6 are fixedly mounted relative to the frame 10. In addition, in a conveying device according to the invention, the frame 10 of the firmness measuring device, the body of the Bidirectional linear motor 4 and the mounting bearing of the pivot shaft 6 of the contact arm 21 are stationary in the translation direction 73 of the conveyor line 11. In addition, in a conveying device according to the invention, the chassis 10 of the firmness measuring device is vertically movable relative to a conveying line 11. Thus, its height can be adjusted and it can be set high when no measure of firmness is achieved and thus not interfere with the passage of bulky objects, machines (eg a cleaning machine), or people . A presence sensor 8 according to the invention can be of different types: for example a photoelectric cell, a camera connected to the data processing unit for performing shape and / or color recognition, a mechanical probe, a device In particular, in the embodiment shown in FIGS. 1 to 3, the presence sensor 8 is advantageously a photoelectric cell. It should be noted that the purpose of this presence sensor is to make it possible to control the tripping of the linear motor 4 in the forward direction of the contact arm 21. In a variant, there is nothing to prevent a device that is devoid of a presence sensor and that operates at a predetermined frequency as a function of the speed of the conveying device, the contact arm 21 being displaced in the forward direction, even in the absence of a sensor. 'object.

Nevertheless, the use of such a presence sensor 8 makes it possible to avoid unnecessary movements of the contact arm 21. In addition, the measuring device is mounted so that the probe 14 is further downstream - with respect to the translation direction 73 of the fruits or vegetables - than the pivot shaft 6. Thus, in the profile view of FIG. 3, the conveying direction 73 is a right-to-left translation of an object 9, and the direction 71 going of the contact arm is a counterclockwise direction. The speed and the roundtrips of the bidirectional motor 4 are controlled by the data processing unit 12 which, in the embodiment shown, also functions as a control unit for the motor 4. It goes without saying, however, that alternatively not shown, the motor 4 can be controlled by a control unit separate from the data processing unit which determines the firmness of the objects. From the presence detection of an object, the data processing unit 12 calculates a motor trip delay to control the movement of the contact arm in the forward direction. This delay is a function of the conveying speed of the objects 9 on the conveying line Il. This is why the data processing unit 12 also comprises a memory in which it can record the presence or absence of objects for the maximum number of sites that can accommodate an object, on the conveying line, between the sensor 8 of the presence and the probe 14.

Thus, as shown in FIG. 4, in a measurement method according to the invention, in step 101, an object 9 is first detected by the presence sensor 8. This detection signal is sent to the data processing unit. On detection by the sensor 8 of the presence of an object, the data processing unit therefore triggers, in step 102, subsequent to step 101, a stopwatch having a predetermined time as a function of the conveying speed. objects on the conveyor line 11. Advantageously, the data processing unit is therefore in communication with the IT management unit of the conveying line. In particular, in the embodiment shown, the data processing unit is the same computer unit that manages the conveying line. At the end of the delay of step 102, the meter proceeds to steps 103 and 104. The delay of step 102 may be zero. In step 103, the data processing unit controls the bidirectional motor 4 so that the movable rod 41 of the bi-directional motor moves upwardly, so that the contact arm 21 moves in a forward direction. The bidirectional electric motor 4 is chosen so as to be able to reach a predetermined constant speed in a time much shorter than its travel time between an upper position of the probe 14, at the beginning of the displacement in the forward direction, and a low position of the probe 14, during the 9. The data processing unit controls the bi-directional motor 4 to positively drive the contact arm in a direction to a state change to be detected at step 105. step 104, triggered simultaneously at step 103, the data processing unit 12 acquires the data transmitted to it by the accelerometer 30. It compares these data continuously in absolute value with a threshold value S1 of stop, prerecorded in a memory of the data processing unit. As soon as a value detected by the accelerometer 30 is greater than that of the stop threshold value S1, the data processing unit proceeds to steps 105 and 106. In step 105, upon detection of an acceleration greater than the stop threshold value S1, the data processing unit controls the bidirectional motor 4 so that the movable rod 41 of the motor moves downwards, so that the crank arm 22 moves in sense 72 back. However there is a delay consisting of the response times and unavoidable inertia of the electronic and mechanical components during which the crank arm continues to move in the forward direction. The helical spring 53 of the elastic device 5 compresses during this time. In addition, the contact arm does not move in the return direction (otherwise because of the rebound on the object), as long as the spring has not returned to its rest position (second arm 52 of the elastic device 5 in contact with the first arm 51 of the elastic device 5). In step 106, triggered simultaneously at step 105, the data processing unit acquires the data transmitted to it by the accelerometer 30 and determines a fruit maturity factor based on these data. These data are acquired in a time interval well below the delays due to electronic response times and mechanical inertia. Indeed, the delay existing between the detection of an acceleration value greater than the stopping threshold S1 of stopping and the actual positive displacement of the contact arm in a return direction is far greater than the duration of the impact. between the probe 14 and an object 9.

The values of the acceleration (deceleration in fact) experienced by the probe 14 during the impact with an object make it possible to determine the firmness of the object and therefore its maturity in the case of fruits or vegetables. Step 106 ends when the values of the acceleration exceed in absolute value a threshold value, called the predetermined calculation threshold S2, stored in a memory of the data processing unit. 2972536 ls In step 107, subsequent to step 106, the data processing unit 12 calculates the firmness of the object from data of accelerations acquired between the exceeding of the stopping threshold value S1 and exceeding the calculation threshold value S2. A device according to the invention controlled by data processing unit for following a method according to the invention is therefore adapted to be able to measure the firmness of an object reliably regardless of the size and shape of the object. Indeed, the contact arm is positively driven in the direction 71 to the impact with the object and the speed of the probe 14 at the time of the impact with the object is always the same regardless of the geometric characteristics of the object. In addition, the invention makes it possible to achieve unrivaled measurement accuracies in a reproducible manner, without the need for complex and risky preliminary calibrations and adjustments. It follows in particular that a measure of firmness of fruits or vegetables by a process according to the invention makes it possible for the first time to consider determining, by this simple measure of firmness, a preferential or limiting consumption date. , which can then be indicated on a packaging of products. Figure 5 shows acceleration data acquired during an impact between a probe 14 and a fruit. The ordinates are represented by the successive values A of the acceleration of the probe 14 measured by the accelerometer 30, in absolute value, as a function of time t. These data are acquired at each time interval 8. The impact curve thus obtained has a linear portion whose slope P is representative of the firmness of the impacted object. The stop threshold value S1 is predetermined to always correspond to a portion of the curve always located after the beginning of the linear portion. Similarly, the calculation threshold value S2 is predetermined to correspond to a portion of the curve always located before the end of this linear portion. Thus, when the value A1 exceeds the threshold value S1, the data processing unit 12 goes from step 104 to steps 105 and 106. Then when the value A2 exceeds the calculation threshold value S2 the data processing unit 12 completes step 106 and proceeds to the calculation of the firmness (step 107). It should be noted that, advantageously, the accelerometer data measured by the accelerometer 30 can be acquired continuously, even before the point A1 and after the point A2. Since the values S1 and S2 are known from the data processing unit 12, it is sufficient to measure the duration OT between the instant T1 at which the value Al is acquired and the instant T2 at which the value A2 is acquired. Alternatively, the data processing unit 12 can simply count the number of points between Al 10 and A2, the time interval 8 between two points being known. The slope P is all the stronger (so small OT) that the object whose firmness is measured is firm. On the contrary, a riper fruit (or vegetable) has a softer slope during this measurement: the feeler 14 sinks further into the fruit, so it is stopped over a longer distance and duration; the impact 15 is longer. The invention can be the subject of many other embodiments not shown. Thus, provision can be made to have several firmness measuring devices in series, one after the other to make several measurements of each object, which makes it possible to obtain a more reliable measurement of the firmness measurement. Indeed, some fruits - such as peaches - mature much faster on the side exposed to the sun than on the side that is not. So a single random measurement at one point of the fruit surface is not always representative of the actual state of maturity of the fruit. Two (or more) measurements per object allow, statistically, to smooth out this variability. Arranging several - in particular at least two - firmness measuring devices one after the other on a conveyor line may also allow to provide a higher conveying speed, each firmness measuring device then measuring respectively the firmness of an object among 30 - including one out of two objects.

Nothing prevents the provision of wireless links between each accelerometer and each data processing unit. Similarly, wireless links can be provided between each data processing unit of a firmness measuring device according to the invention and a control computer of all the conveying devices. Furthermore, nothing prevents the probe from being freely rotatable relative to the contact arm by a hinge having at least one axis of articulation at least substantially parallel to the axis of pivoting of the contact arm and at least substantially orthogonal to the direction of movement of the objects.

Claims (1)

CLAIMS1 / - Method for measuring the firmness of objects (9) such as fruits or vegetables without deterioration of these objects, in which: - a probe (14) mounted on an arm, said arm (21) of contact, is brought into contact with an object in a direction (71) towards and away from the object in a return direction (72), - a sensor (30) integral with the movements of the probe (14) transmits signals to a unit (12). ) of data processing adapted to develop a value representative of the firmness of the objects according to said signals, characterized in that: - said sensor (30) is an accelerometer delivering signals, said acceleration signals, representative of values of the of the probe (14), the contact arm (21) is positively driven in the forward direction (71) and in the return direction (72) by a bidirectional motor device (4) controlled by a unit (12) of command, - the control unit (12) receives the acceleration signals n transmitted during a displacement of the arm (21) of contact in direction (71) go, and, on detection of a value of the acceleration signals higher in absolute value than a predetermined threshold value, said threshold stop , the control unit (12) controls the motor device (4) in the return direction. 2 / - Method according to claim 1, characterized in that the unit (12) of data processing develops a firmness value of the objects (9) from a time elapsing between a first moment at which the threshold of stopping is reached and a second subsequent instant at which the acceleration signals reach a predetermined value, called the calculation threshold, greater than the stopping threshold. 3 / - Method according to one of claims 1 or 2, characterized in that the arm (21) of contact is driven in direction (71) go to a predetermined constant speed.4 / - Method according to one of claims 1 at 3, characterized in that the objects (9) are driven horizontally relative to a frame (10) by a conveying device, in that the contact arm (21) is rotatably mounted relative to the frame and is rotated in forward direction (71) and backward direction (72) by said bidirectional motor device (4). 5 / - Method according to claim 4, characterized in that the objects (9) are driven at a constant speed relative to the frame (10), in that the passage of objects at a predetermined point relative to the frame is detected by a presence sensor (8) whose signals are transmitted to the control unit (12), and in that the control unit (12) triggers a displacement in the forward direction (71) of the contact arm (21) to a predetermined time after detection of an object by said presence sensor. 6 / - Method according to one of claims 1 to 5, characterized in that the device (4) bi-directional motor applies on the arm (21) a limited value of driving force by a device (5) elastic interposed between the bidirectional motor device and the contact arm. 7 / - Device for measuring the firmness of objects (9) such as fruits or vegetables without deterioration of these objects, comprising: - a feeler (14) mounted on an arm, said arm (21) contact, so able to be brought into contact with an object in a direction (71) and away from the object in a direction (72) return, - a sensor (30) integral with the movements of the probe adapted to transmit signals to a unit (12) for processing data capable of producing a value representative of the firmness of the objects as a function of said signals, characterized in that: said sensor (30) is an accelerometer adapted to deliver signals, called acceleration signals, Representative values of the acceleration of the probe (14), - the arm (21) of contact is coupled to a device (4) bi-directional motor adapted to drive positively in the direction (71) go and in the les (72) return, said device (4) motor being connected to a unit (12) to be controllable by the latter, - the control unit (12) is adapted to be able to receive the acceleration signals transmitted during a displacement of the contact arm (21) in the direction (71) to go, and, to control the device (4) in direction (72) return on detection of a value of the acceleration signals higher in absolute value than a predetermined threshold value, said stopping threshold. 8 / - device for measuring firmness according to claim 7, characterized in that the data processing unit (12) is adapted to develop a firmness value of the objects (9) from a time elapsing between a first instant at which the stopping threshold is reached and a second subsequent instant at which the acceleration signals reach a predetermined value, called the calculation threshold, greater than the stopping threshold. 9 / - Device for measuring firmness according to one of claims 7 to 8, characterized in that said accelerometer (30) is an integrated circuit mounted on the arm (21) of contact near the probe (14). 10 / - Device for measuring firmness according to one of claims 7 to 9, characterized in that the device (4) motor comprises a bidirectional linear electric motor adapted to drive the arm (21) contact at a predetermined speed. 11 / - Device for measuring firmness according to one of claims 7 to 10, characterized in that the arm (21) of contact is rotatably mounted relative to a frame (10) and is rotated in direction (71) forward and backward direction (72) relative to the frame by said bidirectional motor device 12 / - Firmness measuring device according to claims 10 and 11, characterized in that the linear electric motor comprises a rod (41) for mobile actuation relative to the frame (10) and in that the mounting of the motor relative to the frame and of this actuating rod relative to the arm (21) of contact is adapted so that in the absence of power from the engine , the actuating rod being moved by gravity, the contact arm is returned in direction (72) return.13 / - Firmness measuring device according to one of claims 7 to 12, characterized in that it comprises an elastic device (5) interposed between the device if (4) bi-directional motor and the contact arm (21) adapted to limit the training effort imparted by the bidirectional motor device on the contact arm. 14 / - Device for conveying objects (9) such as fruits or vegetables comprising at least one conveying line (11) capable of driving the moving objects (73) horizontal relative to a frame (10), and to less a device for measuring the firmness of the objects transported by said conveyor line (11), characterized in that it comprises at least one device for measuring the firmness of the objects according to one of claims 7 to 13. 15 / - Conveying device according to claim 14, characterized in that: - the arm (21) of contact is rotatably mounted relative to the frame (10), the device (4) bidirectional motor being adapted to positively drive the contact arm by rotation in forward direction (71) and in return direction (72), a presence sensor (8) is mounted with respect to the frame so as to detect the passage of objects at a predetermined point relative to the frame, said presence sensor being connected to the unit (12) of co Means for transmitting signals representative of the passage of an object, - the control unit (12) is adapted to trigger a displacement in the forward direction of the contact arm at a predetermined time after detection of an object by said sensor of presence.