JP6153218B2 - Metal foreign object detection device - Google Patents

Description

  The present invention relates to a metal foreign object detection device.

The metal foreign object detection device is one of the inspection devices, and is used to check whether there is an accidentally mixed metal foreign object that should not be mixed in a part of the manufacturing process.
In addition, metal foreign object detection devices are frequently used in food production so that consumers do not accidentally ingest metal, and this inspection is performed on most processed foods.

  There are various methods of metal foreign object detection devices, but since a large number of inspection items can be processed quickly, the inspection object being conveyed by the belt conveyor is detected by an eddy current sensor, and the presence or absence of metal (See, for example, Patent Document 1).

Eddy current sensor includes, in a normal non-metallic material, which metal is to check whether or not contaminated, it from the sensor information, also leaving calculate the distance to the metal foreign substance.

JP 2001-91662 A

However, the device using the eddy current sensor is used to check whether there is a metal foreign object in a device that does not contain metal, and detects a metal portion and a portion that does not contain metal. It is not a thing.
In addition, when using a plurality of sensors at the same time, the eddy current sensor has an interference distance between the sensors, and it is necessary to install the eddy current sensors apart from each other. If a part to be inspected enters, the meaning of performing the inspection disappears.

An object of this invention is to provide the metal foreign material detection apparatus which can perform a metal foreign material detection even if it has a metal part and the part which does not contain a metal originally.
The present invention also aims to provide a plurality of even arranging an eddy current sensor, metal foreign object detection apparatus capable of performing a leaktight metal foreign object detection knowledge.

The present invention relates to the following.
(1) An eddy current sensor arranged to face a surface of the friction material not fixed to the washer, an informing means for informing the detection result of the eddy current sensor, and a movement of the friction material transfer means or the eddy current sensor The eddy current sensor is provided with a coil in a head portion, a high frequency magnetic field is generated in the coil to change impedance, the eddy current sensor detects a fluctuation width of an impedance transmission state, and the friction A metal foreign object detection device that calculates the average value of each sampling by increasing the number of times of sampling of the overcurrent sensor per unit time so that the metal fiber used as a constituent material of the material is not recognized as a metal foreign object.
(2) The metal foreign object detection device according to (1), wherein the eddy current sensor is disposed so as to be able to face a surface of the friction material fixed to the washer opposite to the surface on which the washer is fixed.
(3) a plurality of eddy current sensors arranged with separation, an informing means for informing a detection result of the eddy current sensor, a friction material transferring means or an eddy current sensor moving means; The current sensor crosses the straight line connecting adjacent eddy current sensors at an angle that is not orthogonal to the direction of friction material transfer or the direction of movement of the eddy current sensor, and the adjacent eddy current sensor The metal foreign matter detection device according to (1) or (2), wherein the metal foreign matter detection device is installed so that parts of the measurement range overlap each other.
(4) The metallic foreign matter detection device according to (3), wherein the means for transferring the friction material is a non-metallic belt, and an eddy current sensor is disposed on the back surface of the non-metallic belt.

According to the metal foreign object detection device of the present invention, it is possible to detect a metal foreign object even if it has a metal part and a part that does not originally contain metal.
In addition, according to the metal foreign object detection device of the present invention, even when a plurality of eddy current sensors are arranged, metal foreign object detection without leakage can be performed.

The arrangement | positioning relationship figure of an eddy current sensor is shown. BRIEF DESCRIPTION OF THE DRAWINGS It is a metal foreign material detection apparatus which is an Example of this invention, (a) is a schematic plan view, (b) shows a schematic side view. FIG. 3 shows a detailed arrangement of the eddy current sensor shown in FIG. 2.

<Friction material>
The friction material to be inspected in the present embodiment is not particularly limited as long as it exerts a braking force by being pressed against the counterpart material (rotor, drum, etc.).
More specifically, generally known materials are used, for example, fiber shapes such as steel fibers, brass fibers, copper fibers, aramid fibers, acrylic fibers, phenol fibers, ceramic fibers, rock wool, potassium titanate fibers, carbon fibers and the like. The substance is molded from a thermosetting resin such as a phenol resin, an epoxy resin, a melamine resin, or a cashew resin.
The blending ratio of the friction material varies depending on the friction characteristics and is appropriately determined.

The shape of the friction material is not particularly limited, but when a washer is used, it should not protrude from at least the adhesive surface of the washer described above.
One or more grooves can be provided on the surface of the friction material, and further, a taper can be provided on the side surface of the friction material. By providing such a groove and a taper, noise during braking may be reduced.

  The friction material may be fixed to the washer. In such a case, an eddy current sensor described later is disposed so as to face the surface opposite to the surface to which the washer of the friction material is fixed. When the friction material fixed to the washer is transferred by a non-metallic belt, which will be described later, and an eddy current sensor, which will be described later, is arranged on the back surface of the non-metallic belt, the friction material contacts the non-metallic belt with the washer facing up. Place it like this.

The washer is made of metal and can be suitably used as long as it has a plurality of torque receiving portions.
The overall shape is not particularly limited and can take various shapes. However, when used when sandwiching the rotor, a part of the side surface has an arc shape so as to follow the outer shape of the rotor. It is preferable.
The material of the washer is not particularly limited as long as it is made of metal, and specifically, a hot rolled steel plate or a cold rolled steel plate can be suitably used.
The size and thickness of the washer are appropriately selected depending on the size of the rotor used, the surface pressure, and the required braking force.

  Moreover, when the friction material has a shape pressed against the inner peripheral surface of the cylindrical drum, it can also be an inspection object.

<Eddy current sensor>
The eddy current sensor in the present embodiment is not particularly limited as long as it uses a high-frequency magnetic field, and a commercially available sensor can be used.
The principle of the eddy current sensor is to generate a high-frequency magnetic field by conducting a high-frequency current to a coil provided in the head portion of the sensor, and detect a metal in the high-frequency magnetic field. The metal in the high-frequency magnetic field causes an eddy current perpendicular to the direction of magnetic flux to flow on the metal surface due to electromagnetic induction, thereby changing the impedance of the coil described above. The eddy current sensor can calculate the distance to the metal based on the fluctuation width in the transmission state accompanying the change in impedance.
A place where the distance to the metal part to be inspected should be constant by calculating the distance to the metal from the data from the eddy current sensor placed on the opposite side of the metal part to be inspected. If there is a metal in the metal, it can be detected that a metal foreign object is mixed.

Note that when metal fibers are used as the constituent material of the friction material, the eddy current sensor may detect the metal fibers that are not foreign matter, but in reality, the friction material and the eddy current sensor By adjusting the relative speed and the number of samplings, the metal fiber can be prevented from being recognized as a foreign object.
More specifically, for example, by increasing the number of samplings of the eddy current sensor per unit time and calculating the average value of each sampling, the sudden sampling value of a minute metal fiber is smoothed, so that Only foreign objects such as large screws and bolts can be detected.
However, when such adjustment is performed, even if a metal foreign object finer than the metal fiber used is mixed, it cannot be detected.

In this embodiment, when an inspection object has a metal part, an eddy current sensor is arrange | positioned on the opposite side of the metal part.
The eddy current sensor may be fixed so that the inspection object passes through a fixed position of the eddy current sensor by a transfer means such as a belt. The inspection object is stopped and the eddy current sensor is moved by the moving means. You may make it pass a stationary position.

It is preferable to arrange a plurality of eddy current sensors with a distance from each other so that the inspection can be performed only by passing the inspection target or the eddy current sensor once, and the inspection can be performed in a short time.
The separation distance should just be longer than the interference distance of an eddy current sensor, and it is preferable to install it as close as possible without causing interference.

The installation of a plurality of eddy current sensors will be described below as an example in which the inspection object is transferred by a belt. As shown in FIG. 1 (c), a straight line 3 connecting the adjacent eddy current sensors 2 and 2 intersects at an angle that is not orthogonal to the traveling direction of the belt 1, and the measurement range of the adjacent eddy current sensors 2 and 2 is measured. A plurality of eddy current sensors are installed so that a part of each overlaps with the traveling direction of the belt 1.
In FIG. 1A, the straight line 3 connecting the adjacent eddy current sensors 2 and 2 is orthogonal to the traveling direction of the belt 1, but in this way, the eddy current sensors 2 and 2 are connected. When the inspection object passes through (the gap portion between the eddy current sensors), a region where metal cannot be detected occurs.
1B shows a part of the adjacent eddy current sensors 2 and 2 although the straight line 3 connecting the adjacent eddy current sensors 2 and 2 is not orthogonal to the traveling direction of the belt 1. There is a region in which the metal is not detected when the inspection object passes between the eddy current sensors 2 and 2 (the gap portion between the eddy current sensors). Occur.

  Even when only one eddy current sensor is arranged, the time required for the inspection becomes long. However, the inspection can be performed by moving the inspection object or the eddy current sensor so that a region where metal cannot be detected does not occur. For example, after the inspection object passes through the fixed position of one eddy current sensor, the inspection object is shifted on the transfer surface in a direction orthogonal to the transfer direction by a distance that does not cause a region where metal cannot be detected, The inspection can be performed by repeatedly passing the fixed position of the eddy current sensor a plurality of times.

<Transfer belt>
The metal foreign object detection device of the present embodiment can be a system in which a friction material is placed on a belt and transferred to pass the position where the eddy current sensor is disposed. In this case, since a complicated mechanism is not required, it is difficult for the apparatus to malfunction.
The material of the belt for transferring the friction material is not particularly limited, and a metal or non-metal material can be used.
When using a metal belt as the belt for transferring the friction material, place the eddy current sensor at a position having a predetermined distance from the upper surface of the belt so that the friction material passes under the eddy current sensor. To do.
When using a non-metallic belt for transferring the friction material, it can be arranged in the same way as using a metallic one, but an eddy current sensor should be placed on the back of the belt. Is also possible.
As the material of the non-metallic belt, polyurethane, vinyl chloride, polyolefin, or the like can be used.
In addition, it is preferable to insert a core material for the non-metallic belt so that it is difficult to meander. It is preferable to do.

<Informing means>
The notification means in the present embodiment may be any means capable of notifying a metal foreign object when it is detected. Specifically, the notification means is a visual notification such as a light or a rotating light, or an auditory notification such as a siren or a buzzer. Or a combination thereof, can be notified.
However, the notification means does not perform notification when a metal part that is normally included is detected. This is a measure necessary for detecting a metallic foreign object in a state in which the friction material is fixed to a metal washer.
Therefore, the distance to the washer is input in advance, and notification is made when metal detection is performed at a distance shorter than that distance.

What is notified by the notification means needs to be removed.
This removal may be performed manually, but is preferably performed by an automatic machine. Specifically, for example, in the case of a system in which the friction material is transferred by a belt, when the friction material to be removed flows, it is played by a metal arm or the like, or the friction material to be removed flows downstream of the friction material. It can be branched to the discharge line only when it comes.
Further, the belt can be stopped simultaneously with the notification by the notification means or in synchronization with the notification.

Hereinafter, examples of the present invention will be described in detail with reference to the drawings. However, the present invention is not limited to the following examples.
FIG. 2 is a schematic plan view and a schematic side view showing an embodiment of the metal foreign object detection device of the present invention.
The metal foreign object detection device 4 includes a belt 1 that conveys the friction material 5 to be inspected in this embodiment, and a friction material alignment mechanism 6 is disposed on the upstream side, and a friction material discharge mechanism 7 is disposed on the downstream side. The eddy current sensor 2 is installed between the material alignment mechanism 6 and the friction material discharge mechanism 7. In this embodiment, the friction material 5 is fixed to the washer 11.

In this embodiment, the belt 1 is a non-metallic belt in which a polyurethane sheet-like material is looped, and a polyester core is placed directly above the eddy current sensor 2 in order to prevent the occurrence of surface undulation and meandering. In order to avoid this, it is embedded near both ends.
Further, the belt 1 forms a space in which the eddy current sensor 2 is disposed, and a part of the return portion is pushed downward by the direction changing roll 8.

The eddy current sensor 2 is disposed in a space in which the belt 1 is pushed down. More specifically, as shown in FIG. 3, the eddy current sensor 2 is adjacent to the traveling direction of the belt 1 (see the arrow). A straight line 3 connecting the central portions of the sensor 2 is inclined.
In this embodiment, an eddy current displacement sensor having a sensor head diameter of 22 mm is used, and the eddy current sensors 2 are arranged with a separation distance of 20 mm, and 2 mm with respect to the traveling direction of the belt 1. Only overlap. As a result, in this embodiment, a detection area with a width of 62 mm and no gap is secured.

The friction material alignment mechanism 6 repositions the friction material 5 placed on the belt 1 within a width of 62 mm that can be detected by the eddy current sensor 2 described above. The friction material 5 is positioned at the center of the belt 1 so as to sandwich the material 5 from both sides.
The tip of the sandwiching body 9 is made of rubber having a thickness so that the friction material 5 is not damaged or damaged.
Moreover, the friction material alignment mechanism 6 has a friction material detection sensor (not shown), and measures the clamping timing of the clamping body 9 based on information from this sensor.

The friction material discharging mechanism 7 distinguishes the friction material 5 placed on the belt 1 from the NG work detected and inspected by the eddy current sensor 2 described above. To the outside of the line. If the discharge is difficult, the conveyor is stopped and the NG work is specified.
Also, when an NG work is generated, a buzzer notifies.

The metal foreign object detection device shown in FIG. 2 detects metal foreign objects such as screws and bolts with an eddy current sensor, but the sensor actually detects the distance to the metal foreign object. When the distance is shorter than the distance to the washer in each friction material, it is assumed that there is a metal foreign matter in the friction material, and a buzzer is notified, and the friction material is removed from the line by the friction material discharge mechanism described above. .
There is a possibility that the metal foreign matter may be mixed in the friction material in the step of stirring the raw material of the friction material and the step of forming, so that the inspection of the metal foreign matter is performed at least once after these steps. To do.

DESCRIPTION OF SYMBOLS 1 ... Belt, 2 ... Eddy current sensor, 3 ... Straight line which connects between adjacent eddy current sensors, 4 ... Metal foreign material detection apparatus, 5 ... Friction material, 6 ... Friction material alignment mechanism, 7 ... Friction material discharge mechanism, 8 ... Direction change roll, 9 ... clamping body, 10 ... discharge body, 11 ... washer

Claims (4)

An eddy current sensor disposed so as to be able to face a surface of the friction material not fixed to the washer; an informing means for informing a detection result of the eddy current sensor; and a friction material transferring means or an eddy current sensor moving means. The eddy current sensor is provided with a coil in a head portion, a high frequency magnetic field is generated in the coil to change impedance, the eddy current sensor detects a fluctuation width of an impedance transmission state, and further includes a configuration of the friction material. A metal foreign object detection device that calculates the average value of each sampling by increasing the number of overcurrent sensor samplings per unit time so that the metal fiber used as a material is not recognized as a metal foreign object. The metal foreign object detection device according to claim 1, wherein an eddy current sensor is disposed so as to face a surface of the friction material fixed to the washer opposite to a surface opposite to the surface to which the washer is fixed. A plurality of eddy current sensors arranged with separation, an informing means for informing a detection result of the eddy current sensor, and a friction material transferring means or an eddy current sensor moving means, the eddy current sensor comprising: The line connecting adjacent eddy current sensors intersects at a non-orthogonal angle with the direction of movement of the friction material or the direction of movement of the eddy current sensor, and the measurement range of the adjacent eddy current sensor The metal foreign object detection device according to claim 1, wherein the metal foreign object detection device is installed so as to partially overlap each other. Means for feeding transfer friction material is non-metallic belt, the eddy current sensor is arranged on the back surface of the non-metallic belt, metal foreign object detection apparatus according to claim 3.

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