UA57625C2 - Device for revealing ferromagnetic foreign bodies, in particular those for protecting working elements of harvesters - Google Patents

Abstract

A device for revealing ferromagnetic foreign bodies for protecting the working elements of feed and grain harvesters includes magnetic poles 1 of the same polarity are placed along all the width of a technological product stream in the middle of a cylinder and are embraced with the measurement reels 2, which sensor the disturbance of the magnetic field of permanent magnets by the ferromagnetic bodies, moving in relation to the magnets. The distinction of the device is a direction of the magnetization of the permanent magnets themselves under an angle of to the plane of distribution of the polarity of the magnets and of placement of the measurement reels in the same plane.

Description

Description of the invention

The invention relates to devices for detecting ferromagnetic foreign bodies, in particular for protecting working bodies of harvesting machines, for example, forage harvesters, field shredders, etc.

Known devices for the detection of ferromagnetic foreign bodies, in particular for the protection of the working bodies of the harvesting machine, containing a system for creating a magnetic field across the entire width of the flow of the technological product of the harvesting machine, which includes permanent magnets installed in a row perpendicular to the flow of the technological product, while at least part of of magnets is covered by measuring coils connected to each other 70 in series and connected to the evaluation unit (1) - Ib).

The principle of operation of such devices is based on the appearance of an emf pulse. in the receiving coils due to the change in flux coupling of the magnetic field of the coils during the movement of ferromagnetic bodies in the space of action of the magnetic field of permanent magnets.

In the known analog devices (|1), (2), ИЗ), the change in the polarity of the poles of the permanent magnets coincides with the 72 direction of the flow of the technological product (perpendicular to the shaft axis of the harvesting machine).

At the same time, over the entire width of the product flow, the magnitude of the magnetic induction vector at equal distances from the surface of the magnetic poles is close to a constant value, and the magnetic induction vectors are closed in planes perpendicular to the roll. This topology of the magnetic field of the permanent magnet system allows to obtain the maximum uniform sensitivity over the entire width of the product flow. However, if the size of the diameter of the roll, inside which the magnetic system with measuring coils is located, is limited (by design considerations), the width of one pole (or the width of two alternating poles) in the direction of the product is limited accordingly. Since the width of the magnetic poles determines the degree of attenuation (decrease) of the magnetic induction as it moves away from the surface of the poles (and the roll), the sensitivity of the device (11, (21, (3)) according to the height of the product layer decreases accordingly.

In analogous devices |41, (5), I6Y, the increase in the sensitivity zone in terms of the height of the technological product flow in Ge) compared to devices |11, (21, IZII is achieved due to an increase in the width of the poles of permanent magnets, the polarity of which alternates along the axis of the shaft, i.e. the magnetic induction vectors are closed mainly perpendicular to the direction of the product flow. Since the length of the shaft is usually much greater than its diameter, it becomes possible to increase the width of the magnet poles and, accordingly, to increase the sensitivity of the device in terms of the height of the product layer. However, such a system of magnets, increasing the height of the "emission" " of the magnetic field above the surface of the shaft, inevitably, firstly, it increases the interaction of magnets with ferromagnetic structural parts of forage harvesting machines (which introduces additional obstacles to the measuring coils), and secondly, it fundamentally determines the non-uniformity of the size of the magnetic induction along the axis of the shaft and the corresponding unevenness of the sensitivity of the device along this same axis.To reduce each other in the case of magnets with ferromagnetic parts located at the ends of the shaft, part of the pole of the permanent magnets at the end of the shaft is not covered by the measuring coils (5), which inevitably reduces both the use of the magnets themselves and the sensitivity of the device in the product direction zones close to the ends of the shaft.

The closest in terms of technical essence of all the listed analog devices |1...6|) is device 1, which is accepted as a prototype. With 50 The magnetic system of the prototype |1) consists of two rows of permanent magnets of polarity M-5, alternating with the direction of movement of the product and located along the axis of the harvester roll. With limited sizes

The diameter of the shaft is also limited by the distance between the magnetic axes of the poles of different polarities, determined by the length of the chord of the roll along the surface of the poles facing the moving product flow. An increase in the distance between the poles of M-5 requires a corresponding increase in the length of the chord, and an increase in the length of the chord determines the distance of the surface of the poles from the surface of the roll and, therefore, an increase in the distance from the surface of the magnets to the i-th detectable moving ferromagnetic bodies. -I Thus, the intensity of the magnetic field of the permanent magnet system of the prototype as it moves away from the surface sharply decreases due to the limited distance between the poles of M-5, which means, accordingly, the sensitivity of the device to the detection of foreign ferromagnetic bodies by the height of the layer is also limited product ka 20 The invention is based on the task of creating such a device for the detection of ferromagnetic foreign bodies, in particular for the protection of the working bodies of harvesting machines, which provides an increase in sensitivity along the height of the interlayer of the flow of the technological product at the specified dimensions of the magnetic system, while simultaneously achieving uniform sensitivity across the entire width of the product .

The task is solved by the fact that the device for detecting ferromagnetic foreign bodies, in particular for the protection of 29 working bodies of harvesting machines, containing a system for creating a magnetic field of constant polarity

HF) and intensity across the entire width of the flow of the technological product, which includes one continuous or composite permanent magnet, covered by one or several coils connected in series and connected to the electronic evaluation unit, permanent magnets are magnetized relative to the plane of separation of their polarity at an angle o, - 457 - 90", and the measuring coils are located in such a way that their plane is in the plane of 60 separation of the polarity of the magnets.

In the end zone of the device, the magnetic field of the permanent magnets is shielded by ferromagnetic plates from interaction with the magnetic parts of the assembly machine.

Part of the magnets on the side opposite to the detection zone of ferromagnetic foreign bodies of the device is not covered by the measuring coils. because the measuring coils are located on a ferromagnetic plate installed in the plane of separation of the polarity of the magnets.

Along the entire length of the device, the magnetic field of the magnets is screened by a plate screen on the side opposite to the zone of detection of ferromagnetic foreign bodies.

As a result of the use of permanent magnets in the device according to the invention, which are magnetized relative to the plane of division of their polarity at an angle сo; - 45" - 90", when the coils are arranged in such a way that their plane is in the plane of separation of the polarity of the magnets, the distance between the opposite poles of the magnets increases significantly with the same given (limited by design considerations) dimensions of the magnetic system of the device.

Thus, in the proposed device, the distance between the poles of the same name (M-5) of the magnetic system along the path 7/0 of the closure of their magnetic lines of force is much greater than the same distance in the prototype, which allows for a corresponding increase in the height of the "emission" of the magnetic field in the detection zone of ferromagnetic extraneous bodies, which means increasing the sensitivity of the device to detect ferromagnetic bodies along the height of the layer while maintaining uniform sensitivity of the device over the entire width of the product flow.

In the device according to the invention, a part of the magnets on the side opposite to the detection zone of ferromagnetic foreign bodies 75 may not be covered by the measuring coils, which reduces interference with the measuring coil by ferromagnetic bodies moving in undetected space. Ferromagnetic plates, installed in the end zone of the device and on the side opposite to the zone of detection of ferromagnetic foreign bodies, weaken the guidance of E.S. interference that increases the sensitivity of the device.

The essence of the invention is explained by the drawings, which show: Fig. 1 - a schematic section of the lower feed roll of the field shredder with a built-in device for detecting ferromagnetic foreign bodies; Fig. 2 is a drawing of the system for creating a magnetic field when using one measuring coil covering the entire magnet; Fig. 3 is a drawing of the system for creating a magnetic field when using two measuring coils, p

Connected in series; in Fig. 4 - the case of placing the measuring coil on the magnetic circuit connecting the assembled magnet into one whole; in Fig. 5 - a variant of the magnetic system, where the part of the magnet from the opposite side of the foreign body detection zone is not covered by the coils; Fig. 6 is a schematic section of a roll with a built-in device for detecting foreign ferromagnetic bodies and a magnetic screen along the entire length of the device from the opposite side of the detection zone; Fig. 7 is a drawing of the system for creating a magnetic field with magnetic screens on the ends; Ge) in Fig. 8 is a diagram of the recognition of M along the width B of the magnetic field creation system in accordance with the width E of the supply of the technological product. in

The device for detecting ferromagnetic foreign bodies, which includes a magnetic system 1 covered by a measuring coil 2, is fixed with the help of a bracket C on a shaft 4 inside the lower feed roll 5, made of non-magnetic stainless steel or plastic. The system for creating a magnetic field can be covered by one or more (in a separate case - two) measuring coils (fig. 2 and 3).

The measuring coil 2 can also be placed on the magnetic conductor 8 in the form of a thin ferromagnetic plate connecting the assembled magnet into a single entity (Fig. 4). Magnet 1 can be covered by the measuring coil partially from the side of the detection zone of extraneous ferromagnetic bodies due to the separation of part of the magnet and 9, which reduces interference with the measuring coil by elements of the collecting machine (Fig. 5). "" E.R.S. attenuation interference is also achieved by installing magnetic screens 10 and 11 along the shaft 4 and on the ends of the magnetic system, respectively (fig. b, 7).

The device works as follows. When a foreign ferromagnetic object appears in the area of the system with the creation of a magnetic field, an emf pulse occurs in the measuring coils 2 due to a change in flux coupling, the magnitude of which depends on the distance of the foreign ferromagnetic body from the coils, on the mass and shape of this body. The received signal enters the evaluation unit, which issues a command to stop the supply of the field b-shredder system. The uniformity of the magnetic field across the supply width of the technological product makes it possible to obtain a 5o uniform recognition profile 12 (Fig. 8) in relation to the analog |b6| (diagram 14), and increasing the distance between the poles allows to increase the sensitivity of the device in relation to the prototype (diagram 13, Fig. 8). 4 To prove the superiority of the magnetic system of the proposed device in comparison with the magnetic system of the prototype (|1), the picture of the magnetic field of the magnetic systems being compared was calculated. The picture of the magnetic field is calculated by the computer program "EEISOT" and is depicted by the magnitude and direction of the magnetic induction vector, while the color of the image of the magnetic field indicates the magnitude of the magnetic induction vector. Fig. 9 shows a picture of the magnetic field of the prototype, and Fig. 10 shows the proposed device. The dimensions and iF) of the magnetic material of the magnets are the same. As can be seen from the comparison of the picture of the magnetic fields in Fig. 9 and Fig. 10, the magnetization of the permanent magnets in Fig. 9 is mainly "radial" in relation to the surface of the roll of the device, and the magnetization of the permanent magnets in Fig. 10 is mainly "tangential". The magnetization of the permanent magnets of the device proposed in the application at an angle of s - 457 - 907 (in Fig. 10, the angle is taken to be equal to s - 45") and the "tangential" direction of the M-5 axis relative to the surface of the roll provides (causes) a significantly larger magnitude of the magnetic induction vector (Fig. 10) in comparison with the magnitude of the vector of magnetic induction of the magnetic field of the prototype (Fig. 9) U, especially when comparing the magnitude of magnetic induction at the maximum distances from the surface of the roll, that is, in the zone of minimum sensitivity of the process of recognition 65 (detection) of ferromagnetic bodies, which move over the surface of the roll.Thus, the sensitivity of the proposed device is higher than the sensitivity of the prototype for the same (given) dimensions of the diameter of the roll and the dimensions of the magnetic system of the matching devices.

List of materials used: 1. US patent 3.889.249; 2. US Patent 3,896,608; 3. Patent ER 0666021; 4. Patent ER 0988782; 5. Patent of Ukraine 5751; 6. Patent of Ukraine 26843.

Claims (5)

The formula of the invention 1. A device for detecting foreign ferromagnetic bodies, in particular for protecting the working bodies of harvesting /5 machines, containing a system for creating a magnetic field of constant polarity and intensity across the entire width of the flow of a technological product, which includes one solid or composite permanent magnet covered by one or several measuring coils connected in series with each other and connected to the electronic evaluation unit, which is characterized by the fact that the permanent magnets are magnetized relative to the plane of separation of their polarity at an angle t -45-9d", while the measuring coils are located in such a way that their: plane is in the plane of separation polarities of magnets. 2. The device according to claim 1, which differs in that in the end zone of the device, the magnetic field of permanent magnets is shielded by ferromagnetic plates from interaction with ferromagnetic parts of the assembly machine. C. The device according to claim 1, which differs in that part of the magnets on the side opposite to the zone of detection of ferromagnetic foreign bodies is not covered by the measuring coils. with 4. The device according to claim 1, which is characterized by the fact that the measuring coils are located on a ferromagnetic plate, Ge) installed in the plane of distribution of the polarity of the magnets. 5. The device according to claim 1, which differs in that along its entire length the magnetic field of the magnets is shielded by a plate screen from the side opposite to the zone of detection of ferromagnetic foreign bodies. IF) with (Se) in I c) - and? 1 - and (o) name) sl name) 60 b5