AT9360U1 - METAL DETECTION DEVICE FOR DETECTING METAL PARTS FROM A DIELECTRIC FABRIC - Google Patents

Abstract

In a metal detection device for detecting metal parts from a material flow of dielectric materials, which is transported in translation with a belt conveyor, the material flow is guided between a transmitting coil and two receiving coils and the receiving coils are arranged in an electromagnetic alternating field of the transmitting coil. In order to reduce the influence of electromagnetic interference fields, a closed on at least two opposite sides with metallic side walls (1.1) housing (1) is arranged between the transmitting coil, the receiving coil and the conveyor belt of the belt conveyor, which projects over the entire width of the belt conveyor, and the housing (1) on its underside with a metallic lid (2) is closed, wherein the lid (2) is formed so that it prevents leakage of electromagnetic alternating fields of the transmitting and / or receiving coil to the outside.

Description

2 AT 009 360 U1

The invention relates to a metal detection device for the detection of metal parts from a material flow of dielectric materials, which is transported in translation with a belt conveyor. In this case, such a good flow may have been formed in particular for plastic waste intended for recycling, but also waste from wood processing. 5

The optionally prepared material stream is usually transported by means of belt conveyors translationally to further processing or mechanically comminuting processing machines. Often, relatively sensitive mechanical elements, e.g. for the shredding cutting elements, available, which can be damaged or even destroyed by metal parts contained in such a good flow io, which then leads to cost-driving downtime and required repair work on such machines.

For these reasons, metal detectors are used on such belt conveyors, 15 with their help in the respective material flow possibly contained metal parts can be detected and after the detection of a metal part, a signal is generated. Such signals can be, for example, acoustic or optical signals, which can then lead to a manual separation of metal parts contained in the good stream. However, such a signal generation can also be an automatic triggering of a separation device for metal parts 20.

For this purpose it is known to use so-called "double-layer metal detectors". At such metal detections, a transmitting coil is present, which is acted upon by a predetermined high-frequency alternating voltage, so that with the aid of such a transmitting coil, an electro-magnetic alternating field can be formed. Furthermore, two receiving coils are arranged within the electromagnetic alternating field formed by such a transmitting coil in addition to the good current. In this case, both the one transmitting coil, as well as the two receiving spools can be wound as required in a different design and also have corresponding suitable numbers of turns. 30

In the operation of such known metal detectors, however, disturbances occur as a result of electromagnetic Störfeldem, which can then influence, for example, the signals of the receiving coils also. For these reasons, a so-called "metal-free zone" is required in an area around such a metal detector. This means that in such a surrounding area, no stationary or movable parts should be arranged on the respective belt conveyor. As a result, at least the critical area around such a metal detector of a belt conveyor has to be formed by a shape 40 deviating from the standard configurations normally used. This increases at least the procurement costs for such modified belt conveyors.

But particularly critical are metallic moving parts, which are arranged within the electromagnetic alternating field formed by a transmitting coil, as for example the bearings, rollers or shafts over which the respective conveyor belt of a belt conveyor is / are. From such moving parts can temporally fluctuating electromagnetic alternating fields go out, which influence the signals of the receiving coils in an undesirable form and it can lead to the triggering of false signals. So With appropriate storage this disadvantage can only be avoided by costly ceramic bearings. Rollers or shafts should be made entirely of dielectric materials, which is problematic for the required strength and wear.

Proceeding from this, it is therefore an object of the invention to provide a metal detection device for the detection of metal parts from a material flow, in which the influence of electromagnetic interference fields on the transmission and reception coils can be reduced cost-effectively.

According to the invention this object is achieved with a metal detection device having the features 5 of claim 1. Advantageous embodiments and further developments of the invention can be achieved with the features described in the subordinate claims.

The metal detection device according to the invention is designed so that the respective material flow, ie preferably pre-shredded plastic waste is transported translationally on a conveyor belt of a belt conveyor, wherein the respective material flow is arranged between a transmitting coil and two receiving coils and simultaneously within an electromagnetic alternating field formed by the transmitting coil. For the formation of the electromagnetic alternating field, the transmitting coil is applied with a suitable predetermined frequency 15.

In a preferred form, such a transmission coil is arranged above the transported with the conveyor belt of the belt conveyor material flow and the two receiving coils are then immediately below the conveyor belt, on which the material flow rests arranged. 20

In an alternative form but also the transmitting coil can be arranged below the conveyor belt and the two receiving coils above the crop flow.

On the metal detection device according to the invention also a closed at least two sides with metallic side walls housing is arranged, which forms a shield for electromagnetic fields, which do not emanate from transmitting and receiving coils. The two metallic side walls of the housing are over the entire width of the belt conveyor over, so that the width of the housing in the transport direction of the crop flow is correspondingly larger than the width of the belt conveyor. 30

It is also closed, even the bottom of such a housing. For the lower-side closure, a metallic cover is provided on the housing, which preferably has been releasably flanged to the housing and fastened to the housing according to suitable connecting elements. This cover is designed in this way and can also be so angeord-35 net that it prevents leakage of electromagnetic alternating fields of the transmitting and / or Empfangsspulein), but at least significantly hindered.

Through the housing, the material flow can be passed between the two metallic side walls, so that the transported material flow can be passed continuously through the influence area of the electromagnetic alternating field formed by the transmitting coil.

Depending on the selected arrangement of transmitting and receiving coils advantageously the transmitting or the two receiving coils within the lid, immediately below the conveyor belt, on which rests the respective material flow, arranged and enclosed by the cover or the transmitting or the Both receiving coils can also be integrated directly into the respective metallic lid, wherein in the latter case, such a lid should be made of a composite component, the only partially outwardly facing metal and the standing in direct contact with the respective coil part so from a dielectric Material should exist.

The metal side walls of the housing to be used on a metal detection device according to the invention can be formed in a wide variety of geometric shapes. However, it has been found that a side wall shape with a trapezoidal cross-section seen in the transport direction, is advantageous, with such a housing in 4 AT 009 360 U1 extends its width, starting from top to bottom.

The upper lid of such a housing can then be carrier for the one transmitting or the two receiving coils. 5

The transmitting coil is connected to a frequency generator, which is preferably controllable. Accordingly, the respective frequency with which the transmitting coil is applied, can be adjusted specifically, so that, for example, the spatial conditions, the arrangement and electrical and electromagnetic parameters of the two receiving coils with respect to the io detection sensitivity can be considered and so an optimization can be achieved.

It is also advantageous to connect the transmitting and receiving coils to an electronic evaluation and control unit to which the already mentioned frequency generator can be connected. But it is also possible to connect the controllable frequency generator 15 also to this electronic evaluation and control unit. As a result, inter alia, a time reference between the formation of the electromagnetic alternating fields from the transmitting coil to the output signals of the two receiving coils can be produced. It is advantageous if the two receiving coils are formed identically, which applies to their electrical and electromagnetic properties and these are also arranged symmetrically within the formed by the transmitting coil electromagnetic alternating field, so that they are influenced by the respective electromagnetic alternating field in the same way by induction , This leads to the fact that the two signals of the receiving coils 25 are fed to a differentiating unit and subsequently the respective signal of the two transmitting coils in the periods in which no metal parts have been detected in the material flow and at least approximately the signal value is then at "0".

If, however, at least one metal part is carried along with the material flow, this metal part 30 causes the signal values of the two receiving coils to deviate from one another, such that a positive or a negative signal value is present after the differentiating element, which generates the already mentioned generation of corresponding signals lead to the separation of the respective metal part from the material flow. Below, the invention will be explained in more detail by way of example.

Showing:

FIG. 1 shows an example of a metal detection device according to the invention in a side view.

FIG. 1 shows a side view of an example of a metal detection device according to the invention, wherein the transport direction of the material flow can be aligned horizontally either from left to right or vice versa. 45

The product stream carrying the conveyor belt (not shown), ie the upper strand is thereby passed between the two metallic side walls 1.1 of here right and left, so in the transport direction at least partially open housing 1, so that the transported material flow continuously through the sphere of influence of a Transmitting coil outgoing so electromagnetic alternating field passes.

In this example, the transmission coil forming the electromagnetic alternating field is accommodated within an upper cover part 4 and enclosed in a further metallic housing part 5 at least radially encircling it. 55

Claims (6)

AT 009 360 U1 The housing 1 here has two side walls 1.1, wherein the side walls 1.1 are formed in this example in a trapezoidal shape. As a result, the two side walls 1.1 of the housing 1, starting from top to bottom in their width, formed in the transport direction of the crop flow enlarging. As a result, the housing 1 projects beyond the respective coils (here the two receiver coils) in its lower region at least 5. The two side walls 1.1 of the housing 1 are made of a ferromagnetic metal and connected gap-free with the lid 2. io The housing 1 is closed from below with a metallic lid 2 and also forms in this direction a shield for electromagnetic alternating fields to the outside. The cover 2 is designed and dimensioned such that it projects beyond the extent of the respective received or integrated receiving coils (in this example) or optionally also the transmitting coil, at least in the transport direction of the good current. The lid portion 2.1 protruding beyond it should be at least 1/3, preferably at least 1/2, as long as the lid portion 2.2 occupied by the respective coil (s). Immediately below the upper cover element 4, a plate-shaped cover 8 made of a dielectric material, ie between the transmitting coil (not visible here) and the two metallic side walls 1.1 of the housing 1 is arranged. The attached below by screw on the housing 1 cover 2 has been deformed so that the receiving coils are arranged in its interior. 25 The already mentioned in the general part of the description electronic evaluation and control unit may have been attached to a side wall of the housing 1, wherein in the event that such electronic evaluation and control unit has been mounted inside the housing 1, this within a fully enclosed metallic additional housing should be included. At the here shown a metallic trapezoidal side wall of the housing, a small display with a control panel 6 is externally mounted in this example, which can then be connected to the not recognizable in Figure 1 electronic evaluation and control unit. 35 The control panel 6 is here at an additional cover 7, which is gap-free and releasably connected to the side wall 1.1 of the housing 1 and at the back (not visible here) then attached the electronic evaluation and control unit, so that when required maintenance - And repair work easy access into the interior of the housing 1, after removal me 40 of the lid 7 is possible. The two receiver coils are arranged inside the lid 2 in this example, the arrangement taking into account symmetrical relationships with respect to the electromagnetic alternating field formed by the transmitter coil and, moreover, as already mentioned in general part of the description, the two receiver coils identical, as regards their electrical, electromagnetic properties, including the number of turns and the geometric design and their dimensioning of the coils. Claims: 1. Metal detection device for the detection of metal parts from a material flow of dielectric substances, which is transported in translation with a belt conveyor; while the good current between a transmitting coil and two receiving coils is guided and 55, the receiving coils in an alternating electromagnetic field of the transmitting coil, which is acted upon with ρ ΑΤ 009 360 U1 predetermined frequency, are arranged, characterized in that between the transmitting coil, the receiving coil and the conveyor belt the belt conveyor is arranged on at least two opposite sides with metallic side walls (1.1) closed housing (1) which projects over the entire width of the belt conveyor 5 rers and forms a shield for electromagnetic fields and the housing (1) on its underside with a metallic lid (2) is closed; wherein the lid (2) is formed so that it prevents leakage electromagnetic alternating fields of the transmitting and / or receiving coils to the outside. 10 2. Apparatus according to claim 1, characterized in that within the lid (2) arranged the transmitting coil or the two receiving coils or in the lid (2) is / are integrated. 3. Apparatus according to claim 1 or 2, characterized in that the two side walls (1.1) of the housing (1) have a trapezoidal cross-section in the transport direction of the crop stream. 4. The device according to claim 1, characterized in that the transmitting coil at the top of the housing 20 (1) and the receiving coils below the conveyor belt, on which the product flow is transported, are arranged. 5. Device according to one of the preceding claims, characterized in that the receiving coils are formed identically and are arranged symmetrically to each other within the aus¬ formed by the transmitting coil 25 electromagnetic alternating field. 6. Device according to one of the preceding claims, characterized in that the transmitting coil is connected to a controllable frequency generator and together with the receiving coils to an electronic evaluation and control unit / are. 30 For 1 sheet of drawings 35 40 45 50 55