NL7900127A - Inductive heating and demagnetisation of roller bearing - is connected as sec. winding of transformer circuit with variable inductance in primary - Google Patents

Abstract

An inductive heating and demagnetisation system is described where the object is placed in an electromagnetic alternating field until it reaches the required temperature. The bearing is ring-shaped and forms the secondary winding around the yoke of a transformer. The current is supplied to the prim. until the required temp. is reached. The alternating current is reduced gradually to zero when the ring has reached the required temperature. This will prevent the formation of the residual magnetism. The primary circuit of the transformer contains a variable choke. It consists of a coil with a core of magnetisable material with a winding. The alternating current is reduced by increasing the value of the variable self-inductance.

Description

1 _ * N.O. 26 665 Wed.

SEE1 Industrial Trading and Development Company B.7.

Wieuwegein

Method and device for inductive heating and demagnetizing.

The invention relates to a method for heating a body of electrically conductive and magnetizable material, wherein this body is placed in an alternating electromagnetic field generated by an alternating current until this body has the desired temperature as a result of the electric current induced therein. reached.

More particularly, the invention relates to a method of heating an annular body, wherein this body is applied as a secondary winding around the yoke of a transformer and then an alternating current is passed through the primary winding of the transformer until the body has reached the desired temperature.

The invention relates to a torch for performing these methods.

In this description, an annular body is understood to mean a body which has at least one opening which communicates on two opposite sides with the space surrounding the body and which is further surrounded by the mass of the body. Such an annular body can be, for example, a plate with a hole of a round or other shape, a circumferential wire, the two ends of which are welded together, a sphere pierced through a center channel, and so on.

More particularly, however, the invention relates to a special kind of annular bodies, namely roller bearings. 25

From the brochure "SKI" Product Information 300, Methods and Tools for mounting and dismounting rolling bearings, published in 1978, p. 62 to 65, the working methods indicated in the preamble are known for the inductive heating of annular bodies and more particularly of rolling bearings. As a rolling bearing to be heated in this manner is made of a magnetizable material, if heating has not continued above the Curie point, the bearing will retain residual magnetism after the primary current has been turned off, which is undesirable because ferromagnetic particles are attracted and retained by the bearing, which may lead to damage to the bearing, or more generally adversely affect the operation of the bearing

It is known to first place an inductively heated bearing before mounting on a shaft in a demagnetization installation in which the residual magnetism present is nullified. However, this is an additional complication, because not only the heated bearing must first be placed in an additional device for mounting on a shaft, but also because the cooling that occurs in the demagnetization installation must be taken into account when heating. demagnetization installation must be provided with means that prevent or reduce cooling during magnetization. 20

The invention is based on the insight that a body of magnetizable material, which is in a magnetic alternating field, will retain a residual magnetism if the alternating magnetic field is suddenly switched off, but that this is not the case if the intensity of the magnetic alternating field is gradually approaching zero.

The object of the invention is to provide a method and a device with which it is possible to heat a body of electrically conductive and magnetizable material inductively such that no residual magnetism is present in the body after heating.

This object is achieved with the method indicated in the preamble, which according to the invention is characterized in that, in order to prevent residual magnetism from occurring in the heated body, the alternating current is gradually reduced to zero when the desired temperature is reached. .

7900127 B.C.

»3

More specifically, this object is achieved with the method just described, further characterized in that the reduction of the alternating current is caused by increasing the value of an adjustable inductance through which this alternating current flows. 5

In a preferred embodiment of the method according to the invention, the controllable self-induction consists of a coil with a core of magnetizable material, around which core also a winding connected to a direct current is arranged, and the value of the controllable self-induction is increased by the winding a smooth direct current, which is initially so strong that the magnetizable core is magnetically saturated, such that the magnetic saturation is canceled.

The invention further provides a device for carrying out the above-mentioned methods, which device consists of a transformer with a yoke of magnetizable material, which yoke can be opened and is provided with a primary winding which, according to the invention, is connected in series with means by which the alternating current is gradually reduced to zero by the primary winding. 20

In a preferred embodiment of this device, the primary winding of the transformer is connected in series with an adjustable self-induction, while in another preferred embodiment this adjustable self-induction consists of a coil with a core of magnetizable material, around which core a winding is also arranged. which is connected with a controllable recto ombr on.

The invention will now be further explained by the description of a special embodiment thereof with reference to the drawing, which shows an apparatus according to the invention for inductive heating and demagnetizing.

In the figure, 1 shows an annular body of electrically conductive and magnetizable material, more particularly a rolling bearing; 2 is a transformer consisting of a yoke 3> a core 4 and a primary winding 5 · The transformer contains two separable parts 3 and 4 »making it possible to use a 7900127 4 /

Jf annular body for mounting yoke 3.

If the primary winding 5 of the transformer 2 is connected to an alternating current source (not shown in the drawing), an alternating magnetic flux will be generated in the yoke 3 of the transformer 2, which in turn produces a very strong current the annular body 1 induces heating of this body.

Connected in series with the primary winding 5 of the transformer 2 is a variable self-induction 6, which consists of a coil 7, a core of magnetizable material 8 disposed therein and a winding 9 also arranged around this core. is connected to a variable DC power source 12.

During heating of the body 1, a direct current is passed through the winding 9, which is so large that the core 8 of the self-induction 6 is very magnetically saturated. As a result, relatively small magnetic field changes caused by the alternating current flowing through the coil 7 will hardly have any effect on the magnetization state of the core 8. Consequently, the value of the self-inductance 6 will be relatively be small. When the temperature of the body 1 has reached the desired value, which can for instance be observed with the temperature sensor 10, the direct current through the winding 9 is gradually reduced to auxiliary.

The magnetic saturation state of the core 8 of the self-induction 6 disappears as a result, and consequently the magnetization state of the core 8 will be significantly affected by the changes of the magnetic field caused by the alternating current passing through the coil 7 . The value of the inductance 6 therefore increases, and the magnitude of the current flowing through the inductance 6 and also through the primary winding 5 of the transformer 2 decreases accordingly. If the latter current has reached a very small value, it can be switched off without there being any danger of residual magnetism of any importance being present in the body 1. After the yoke 3 has been lifted from the core 4, the body 1, for example a rolling bearing, can be removed from the transformer 2 and placed directly on the desired location.

7900127 5

The primary winding 5 of the transformer 2 can for instance be connected to the mains voltage. The self-induction 6 has, if no direct current flows through the winding 9, for instance an impedance which is approximately fifty times greater than that of the primary winding 5 with closed yoke 3 · By flowing 3 a strong direct current through the winding 9 the value of the self-induction 6 reduced to a fraction of the value it has if no direct current flows through the winding 9.

When direct current flows through the winding 9, therefore, almost the entire mains voltage of 220 Tolt is connected to the primary winding 5 of the transformer 2. By switching off the direct current in the winding 9, the self-induction 6 obtains its maximum value, so that the primary Winding voltage 5 is reduced to approximately one-fiftieth of the mains voltage. With this, a decrease in the current through the primary winding 5 bluntly corresponds to a size approximately one-fiftieth of the original size.

The direct current through the winding 9 of the variable inductance 6 is controlled by a logic circuit 13 · Via three lines 15a, 15b and 15c, the logic circuit 13 can supply three signals to a control circuit 14, which in turn controls the DC source 12 which direct current source supplies the direct current flowing through the winding 9 of the variable inductance 6. A signal passes through the line 15a which increases the direct current 25 through the winding 9 to its maximum value, a signal passes through the line 15b which gradually decreases the direct current from the maximum value to zero, and a signal passes through the line 15c. the DC current decreases to zero very quickly. 30

Logic circuit 13 is activated by push button switch 16. By setting the switch 17 it can be effected that the device heats and demagnetizes (a), or only demagnetizes (b).

The temperature sensor 10 is so close to the body 1 to be heated that it can measure the temperature of this body. The temperature sensor 10 gives a signal to the temperature controller 18, which in turn sends a signal to the logic circuit 13. The operation of the temperature sensor 10, the temperature controller 18 and the logic circuit 13 is such that if the body 1 has reached a predetermined temperature, the direct current through the winding 9 of variable self-inductance 6 gradually decreases from the maximum value to zero. At the same time, a signal lamp 19 is lit, alerting the operating personnel that the body 1 has reached the desired temperature and can be removed from the device 10.

By lifting the yoke 3 of the core 4 of the transformer 2, the impedance of the primary winding 2 decreases very sharply.

If the maximum current flows through the primary winding 5, if the yoke 3 were suddenly removed, the current through 13 the primary winding 5 would increase such that damage to the device can occur. In order to prevent this, a current transformer 11 is connected in series with the primary winding 5.

When the current through the primary winding 5 of the transformer 2 increases above a predetermined value, the secondary winding of the current transformer 11 outputs a signal to the current controller 20, which in turn supplies a signal to the logic circuit 13 and thereby causes the direct current in the winding 9 to be reduced to zero very quickly.

In this way it is prevented that the device would be damaged by an excessive current through the primary winding 5.

The device described above is preferably carried out with "solid state" parts and does not contain any mechanically moving parts, so that mechanical wear is excluded.

In known devices, use is made of energy losses in the magnetic core or chain of a spool or a transformer fed by alternating current. These energy losses generate heat that is used for heating the body to be heated. A yield of 10-20% is hereby obtained. 35

7900127 can be found in the method and the device according to the invention

Claims (11)

A method for heating a body of electrically conductive and magnetizable material, wherein this body is placed in an alternating electromagnetic field ** generated by an alternating current until this body has reached the desired temperature as a result of the electric current induced therein, with 10, characterized in that, in order to prevent residual magnetism from occurring in the heated body, the alternating current is gradually reduced to zero when the desired temperature is reached. 2. A method according to claim 1, for heating an annular body, wherein said body is applied as a secondary winding around the yoke of a transformer and then an alternating current is passed through the primary winding of the transformer until the body has the desired temperature characterized in that after the desired temperature has been reached, the alternating current in the primary winding of the transformer is gradually reduced to zero. Method according to claim 1 or 2, characterized in that the reduction of the alternating current is caused by increasing the value of an adjustable inductance 25 through which this alternating current flows. Method according to claim 3j, characterized in that the size of the controllable self-induction consisting of a coil with a core of magnetizable material, around which core also a winding connected to a direct current source is increased, is increased by the reduce the winding flowing direct current, which is initially so strong that the magnetizable core is magnetically saturated, such that the magnetic saturation is canceled. Method according to one or more of the preceding claims, characterized in that the heating takes place 7900127 et c by transferring AC energy via a transformer, whereby an efficiency of 85-95% is achieved. 6. Device for carrying out the method according to claim 1, consisting of a coil connected to an alternating current source for generating an alternating electromagnetic field, characterized in that this coil is connected in series by means with which the alternating current passing through this coil can be gradually reduced to zero. Device according to claim 5 for carrying out the method according to claim 2, consisting of a transformer 10 with a yoke of magnetizable material, which yoke can be opened and is provided with a primary winding, characterized in that in series with this primary winding means are switched, with which the alternating current through the primary winding can be gradually reduced to zero. 15 8. Device as claimed in claim 5 or 6, characterized in that the means for reducing the alternating current consist of an adjustable self-inductance. 9. Device as claimed in claim 7, characterized in that the adjustable self-induction consists of a coil with a core of magnetizable material, around which core also a winding is connected which is connected to a controllable direct current source. 10. Device according to one or more of claims 5-8, characterized in that a temperature sensor is arranged at the location for the body to be heated, which sensor is connected to a switch for activating the means to reduce the alternating current. Device according to one or more of claims 6-10, characterized in that it is provided with "solid 50 state" parts and does not contain any mechanically moving parts. 7800127