RU2250475C1 - Device for local magnetization of ferromagnetic articles - Google Patents

Abstract

FIELD: arrangements or instruments for measuring magnetic variables.

SUBSTANCE: device comprises stator made of a two-pole U-shaped magnet made of a magnetically soft material and cylindrical rotor made of a magnetically soft material. The device is provided with an additional cylindrical rotor made of a magnetically soft material. Each of the rotors has a longitudinal slot, which receives the permanent magnet. The base of the stator is provided with the slot opening, which divides it into two parallel arms, each of which is provided with the cylindrical opening for receiving the corresponding rotor. The rotor is set into the opening for permitting rotation around its axis.

EFFECT: enhanced precision of magnetizing.

3 cl, 1 dwg

Description

The invention relates to the field of devices for the magnetization and demagnetization of bodies and can be used to create magnetic fields of the desired magnitude and direction in composite closed magnetic circuits for magnetic measurements and non-destructive testing of product quality by the magnetic properties of the substance.

At present, magnetic control devices for the physicomechanical properties of materials and products have been used, which use various devices for full or local magnetization and magnetization reversal of the tested products or their sections [1]. Moreover, the work of most modern devices is based on measuring the magnetic properties of the body [1-3]. This is due to the great simplicity of measuring such properties. However, there is a fundamental difference between the magnetic properties of the body and the substance of ferromagnets, not only in terms of magnetic measurements, but also in terms of the structural sensitivity of these properties. Measurement of the properties of a substance makes it possible to get rid of the influence of the shape and size of controlled products on the results of control and to obtain more reliable information about the structure and physico-mechanical properties of controlled objects. This makes the task of developing small-sized autonomous magnetization devices providing measurement of the magnetic properties of the substance of the tested products very urgent.

Devices are well known, the most common of which are solenoids and attachment magnets that use electric current to magnetize [1-5]. A common drawback of such devices is the need for powerful sources of electrical energy, which makes it impossible to use them in portable portable systems. The use of solenoids in measuring systems is also limited by the difficulties associated with the inhomogeneous magnetization of complex bodies and the difference between the external and internal magnetic fields of finite-size ferromagnets, which makes it difficult to determine the properties of a substance and to obtain sufficiently large magnetic fields in products. Another disadvantage of electric magnetizing devices is their heating during operation and the associated difficulties of stabilizing magnetizing currents and compensating for the additional temperature error of the measuring transducers located near the magnetizing windings.

Known devices for non-electric magnetization of products, including stationary permanent magnets of various configurations [6-8].

A common drawback of these devices is that with their help it is impossible to achieve a smooth change in the magnitude and direction of the magnetic field in the composite closed circuit "magnetizing device - product" without changing the position of the magnetizing device relative to the product, i.e. without breaking the magnetic circuit. The uncontrolled redistribution of magnetic fluxes in the product that occurs when the circuit breaks leads to the uncertainty of its magnetic state, which does not allow the use of these devices as part of measuring transducers in determining the magnetic properties of substances of controlled products. In addition, at high values of magnetic fluxes in the composite circuit due to the pondermotor effect, considerable efforts are required to break the circuit, and a significant amount of residual magnetization of the product requires special measures to demagnetize it.

A device for magnetizing ferromagnetic products is known, which is a latch with a rotary magnet, the principle of which is based on changing the traction force of the magnet by shunting its working stream [7]. The latch consists of a rotor in the form of a diametrically magnetized cylinder of soft magnetic material and pole pieces, rigidly interconnected and forming the stator of the latch. In the working position, the magnetic flux branches out into two parts: one attracts the fixed object, and the other attracts the fixator stator to a fixed ferromagnetic support. Rotation of the rotor by a small angle leads to magnetic flux bypassing by pole tips, the weakening of the attractive forces, and rotation of 90 ° leads to a short circuit and the locking mechanism.

The main disadvantage of the known device is that at any position of the rotor, the magnetic flux from the product is closed through the rotor material having a high magnetic resistance, which is equivalent to a break in the magnetic circuit and leads to uncontrolled redistribution and scattering of the magnetic flux from the magnetized product. Another disadvantage is the strong dependence of the magnetic field generated by the device on the angle of rotation of the rotor. In addition, with only one rotor, adjusting and setting the exact value of the field is difficult due to the action of the ponderomotive forces, which tend to set the rotor to the minimum flow position. These shortcomings do not allow the use of the known device when measuring the magnetic properties of the substance of ferromagnetic products.

Closest to the claimed technical essence and the achieved result is a device for the magnetization of ferromagnetic products, used as a magnetic lock [8].

The device includes a fixed part, a stator in the form of a U-shaped structure consisting of two permanent magnets, two poles and a magnetic shunt, and a movable part, a rotor in the form of a cylinder with an octagonal section, consisting of a permanent magnet with plates of soft magnetic material. This device is used to hold a ferromagnetic product by creating a magnetic flux in it, closed to the stator poles. In this device, the position of the rotor has two states. In the first state, the field between the poles is absent, which is achieved by selecting a permanent rotor magnet with such a magnetic mass that it equals the sum of the magnetic masses of the stator's permanent magnets. The magnetic masses of the pole magnets are selected equal. In the second state, the magnetic field is maximum.

However, using this device it is also impossible to measure the magnetic properties of the substance of ferromagnetic products due to the impossibility of obtaining by means of this device a continuously adjustable magnetic field.

The basis of the invention is the creation of a device for the local magnetization of ferromagnetic products, providing the ability to accurately control the magnitude of the magnetizing field in the product without breaking the magnetic circuit.

The problem is solved in that the device for the local magnetization of ferromagnetic products, including a stator in the form of a bipolar U-shaped magnet made of soft magnetic material and a cylindrical rotor made of soft magnetic material, is equipped with an additional cylindrical rotor made of soft magnetic material, a slot is made along each axis in each rotor which a permanent magnet is fixed to, a slit hole is made at the base of the stator, dividing it into two parallel arms, each of which is made cylindrical opening to the respective rotor mounted therein to be rotatable about its axis. Wherein:

- the diameter of the cylindrical hole exceeds the thickness of the shoulder;

- the diameters of the rotors can be selected different;

- Permanent magnets for different cases of magnetization can be selected with different residual induction of the magnetic field.

The supply of the claimed device with an additional rotor, similar to the existing one, the presence of a permanent magnet in the slot of each rotor and the location of the rotors in the stator holes with the possibility of rotation made it possible to change the magnitude and direction of the magnetizing field in the product due to this rotation and made it possible to use it to determine the magnetic properties of the substance of ferromagnetic products by obtaining a continuously adjustable field in a closed magnetic circuit.

The drawing shows a schematic diagram of the inventive device.

A device for local magnetization of ferromagnetic products includes a stator 1 in the form of a bipolar U-shaped magnet made of soft magnetic material. At the base of the stator 1, a slit hole 2 is made, dividing it into two parallel arms 3. A cylindrical hole 4 is made in each of the arms 3. The diameter of the hole 4 slightly exceeds the thickness of the arm 3. A cylindrical rotor 5 of soft magnetic material is placed in each of the holes 4, moreover the diameters of the rotors 5 are exactly equal to the diameters of the holes 4 and the surface of the rotors 5 and holes 4 are adjusted to each other by grinding. In each of the rotors 5 along the axis of its base, a slot 6 is made in which a flat permanent magnet 7 is fixed. The permanent magnets 7 located in the slots 6 of the rotors 5 are sources of magnetomotive force, and the soft magnetic segments of the rotors 5 serve to close the magnetic circuit. Changing the magnitude and direction of the magnetizing field in the product (not shown) is achieved by rotating the rotors 5 around their axes.

The diameters of the rotors 5 can be chosen different, as the permanent magnets 7, can be chosen with different residual induction of the magnetic field. The rotor 5 closest to the product has a larger diameter and it provides a “coarse” adjustment of the magnetizing field. The second rotor 5 is trimmer and provides "fine" adjustment.

The device operates as follows:

The device is installed on the surface of the workpiece. In the initial position (at α _i = 0), the magnetic flux created by the permanent magnets 7 is almost completely (except for some part of each of the fluxes closing through the opposite arm 3) are folded and closed through the part of the product located between the poles, magnetizing it to the state technical saturation. When one of the rotors 5 is rotated by a small angle, the magnetic circuit of the device-product closes through the soft magnetic segments of the rotor 5. At the same time, a part of the magnetic flux of the rotor 5 is shunted inside the arm 3 and, accordingly, the field magnetizing the product decreases. With an increase in the angle of rotation, the effective (transverse to the flow) area of the soft magnetic part of the rotor 5 increases, which leads to an even greater shunting of the magnetic flux and a decrease in the magnetic resistance of the arm 3. Thus, the magnetic circuit device-product is closed at all positions of the rotors 5, except the initial one. The magnetic flux (magnetizing field) in the product becomes equal to zero while the rotation angles of the rotors 5 are equal to π / ₂ . With a further increase in the angle of rotation of any of the rotors 5, the magnetizing field changes sign and begins to increase in magnitude. The smoothness of the magnetizing field adjustment is ensured by the fact that the flow of one of the rotors 5 is shunted by the magnetically soft segments of the other, and the generated flows can be added or subtracted. In addition, the diameters of the rotors 5 are different, and magnets 7 for different purposes (for example, for magnetizing massive products) can be set with different residual magnetic field induction. The rotor 5 closest to the product has the largest diameter and it provides a “coarse” adjustment of the magnetizing field. The second rotor provides “fine” adjustment.

Thus, the claimed device allows in a closed magnetic circuit without using an electric current to obtain a continuously adjustable magnetic field. This provides an increase in the information content and reliability of magnetic tests by determining the magnetic properties of the substance and allows you to expand the range of tested products by determining new control parameters. The use of two rotors allows to increase the accuracy of the field setting also by reducing the influence of the ponderomotive effect.

List of references

1. Scherbinin V.E., Gorkunov E.S. Magnetic quality control of metals. -M .: Nauka, 1993 .-- 250 p.

2. Chechernikov V.I. Magnetic measurements. - M.: Publishing House of Moscow State University, 1969 .-- 388 p.

3. Kiefer I.I. Tests of ferromagnetic materials. - M.: Gosenergoizdat, 1962 - 468 p.

4. Tikazumi S. Physics of ferromagnetism. The magnetic properties of the substance. - M .: Mir, 1983 .-- 302 p.

5. Zakharov V.A., Gorkunov E.S. Coercimeters with attached magnetic devices. - Defectoscopy, 1995, No. 8, pp. 69-88.

6. Preobrazhensky A.A., Bishard E.G. Magnetic materials and elements. -M .: Higher school, 1986.- 352 p.

7. Altman A.B., Gerberg A.N., Gladyshev P.A. etc. Permanent magnets. Directory. - M .: Energy, 1980 .-- 488 p.

8. Magnetic lock. - US Patent No. 4465993, 1983, H 01 F 7/20.

Claims (4)

1. A device for the local magnetization of ferromagnetic products, comprising a stator in the form of a bipolar U-shaped magnet made of magnetically soft material and a cylindrical rotor of magnetically soft material, characterized in that it is equipped with an additional cylindrical rotor of magnetically soft material, a slot is made along each axis along each axis, in which the permanent magnet is fixed to, a slit hole is made at the base of the stator, dividing it into two parallel arms, each of which has a cylindrical hole for the corresponding rotor installed in it with the possibility of rotation around its axis. 2. The device according to claim 1, characterized in that the diameter of the cylindrical hole exceeds the thickness of the shoulder. 3. The device according to claim 1 or 2, characterized in that the diameters of the rotors can be selected different. 4. The device according to claim 1, or 2, or 3, characterized in that the permanent magnets can be selected with different residual induction of the magnetic field.