PL34741B1 - - Google Patents

Description

The quality of transformer and generator sheets is usually defined by the so-called loss ratio, which gives the amount of losses in watts per kg of sheets at a magnetic saturation of 10,000 Gauss and achieved by a sinusoidal alternating magnetic flux of .50 rounds. knot. Various devices, which are generally quite complex, are used to measure this quantity, and they usually include a wattmeter or other device for measuring the active power of an alternating current. These devices require a relatively large number of sheets to be tested (weighing up to 10 kg). Such measurements are relatively expensive and involve a significant loss of time. In many cases, e.g. when checking the uniformity of the produced sheets, when approximating the quality of the sheet or sorting sheets with different magnetic properties, one could be satisfied with lower accuracy, than that which can be achieved with expensive measuring devices. Especially when it comes to testing large batches of sheets, one should use relatively cheap measuring devices that do not cause changes in the quality of sheets during the measurement. In addition, it is required that the measurement be short-lived, that it allows the control of whole sheets and that it approximates the loss of the sheet without any additional calculations. A measurement method of this kind is an object of the invention. The method of measurement according to the invention consists in the experimentally established finding that in the case of the conventionally used transformer and generator sheets there is a certain dependence between their magnetic permeability and their losses at low saturations. If the tested magnetic sheet of a given thickness is pressed against the appropriately shaped poles of the electromagnet, a closed magnetic circuit is formed, the magnetic resistance of which on the section running inside the electromagnet core is negligibly small in relation to the magnetic resistance on the section running inside the sheet. While the electromagnet is supplied with alternating current of such intensity that the maximum magnetic saturation of the sheet does not exceed a certain value, then the current flowing through the electromagnet coil depends in principle only on the magnetic resistance of the sheet under test, i.e. for a given sheet thickness and specific dimensions of the electromagnet yoke - from the permeability of sheet metal in the range of low saturations. From the deflection of a milliammeter placed in the current circuit of the electromagnet coil, it is possible to determine the magnetic permeability of the clot, with a known relationship between the permeability. and iron loss can also be approximated by sheet loss. The milliammeter can be directly measured by the loss of the tested sheets in watts per kilogram. If the electromagnet yoke does not adhere exactly to the sheet of the tested sheet, then the magnetic flux dissipates and the current in the electromagnet coil has a much greater value than in the case of non-dissipative magnetic flux. In order to avoid overloading the milliammeter and exposing it to damage, it is necessary to provide the coil of the electromagnet with a suitable set of contacts, mechanically connected to the yoke and the device holder in such a way that the yoke is not pressed against the sheet under test, the electrical circuit of the electromagnet coil and the milliammeter is opened or supplemented with an additional electrical resistance. If the yoke of the electromagnet is pressed against the sheet with a force, ensuring that the poles adhere tightly enough to the tested object, then the contact group switches on the circuit of the ammeter and the coil or switches off the additional resistance, enabling the correct indication of the device. sheet metal, while an additional resistance is connected to the circuit of the magnetizing coil and the milliammeter, or - in the case of the coil disconnection - the contact resistance, then the deflection of the milliammeter depends solely on the magnitude of the alternating voltage of the current source supplying this circuit. The above circumstance can be used to provide each voltage corresponding to the current for which the instrument is marked. The milliammeter scale has a color sign (e.g. a red line) corresponding to the nominal current. In the event of a deviation of the test current from the nominal value, its intensity can be adjusted using the voltage regulator, rip. of a regulating transformer or voltage divider, the milliammeter scale, indicated in loss units, is valid for a given supply voltage only for a given sheet thickness. In order to be able to measure the loss of sheets of different thicknesses, it is necessary to provide the device with a switch connected to the taps of the transformer or voltage divider, so that the appropriate supply voltage is set for any Macha thickness. The voltage switch can then be associated with the switch for additional resistances, which is selected in such a way that in each switch position in the unmeasured state and the appropriate supply voltage, the milliammeter needle coincides with the colored mark on the scale. The tuning of the device to different sheet thicknesses can also be achieved by varying the number of turns of the magnetizing coil. PL

Claims (8)

Claims 1. The method of testing the loss of ferromagnetic materials, especially transformer and generator sheets, characterized by the fact that the ferromagnetic material tested enters the magnetic circuit so that the magnetic resistance of the sheets under study has a dominant influence on the nature of the magnetic circuit. whose magnetic flux is excited by means of alternating current, the magnitude of the excitation current as a function of the magnetic resistance of the tested object at a permanently set supply voltage and low saturation of the tested sheet is a measure of the loss of the tested sheet, which during the test does not remain in no case damaged or worn. 2. Device for loss test according to the method according to claim 1, having an electromagnet connecting the lines of magnetic forces through the sheet under test and connected in series with the millimeter, characterized in that the yoke of the electromagnet is provided with a set of contacts which, when the yoke is pressed against the sheet under test, switches on the electric circuit of the milliammeter and the magnet coil Moreover, when the clamp is released, they turn off the circuit or turn on an additional protective resistance in order to protect the milliammeter against overload. 3. Device according to claim 2. A method according to claim 2, characterized in that the electromagnet yoke has contacts, which connect a specific constant resistance to the milliammeter circuit in place of the magnetizing coil, in order to enable an exact setting of the excitation current, corresponding to a given type of sheet, to a nominal value. 4. Device according to claim 2 and 3, characterized in that it has a voltage regulator, by means of which the excitation current is regulated to a nominal value simultaneously with the setting of the value of the protective or stepping resistance, according to the thickness of the sheets included in the tested batch. 5. Device according to claim A method according to any of the claims 2-4, characterized in that the milliamperemeter scale has a different color, corresponding to the nominal measuring current. 6. Device according to claim 2-5, characterized in that, in order to keep the magnetic saturation within the given limits, it is provided with a voltage and resistance switch for adjusting the ampere turns of the excitation coil according to the different thicknesses of the tested sheets. 7. Device according to claim 2 - 5, except that, in order to keep the magnetic saturation within the given limits, there is a ring and a magnetizing coil turns number selector to adjust the excitation amps according to the different thicknesses of the tested sheets. 8. Device according to claim A method according to claim 2 - 7, characterized in that the milliammeter scale is measured in loss units W / kg at 10,000 or 15,000 Gauss of saturation. / Tesla national podnik Deputy: Mgr Andrzej Au Patent attorney PL