SU828378A1 - Pulse generator - Google Patents

Description

The fiber core 1 has two side rods 8 and 9 with heaters 10 and I and thermomagnetic elements 12 and 13 with a low-temperature Curie point.

The pulse generator works as follows.

When a voltage is applied from an alternating voltage source 6 to an input winding 2 placed on the middle rod of an U-shaped ferromagnetic core 1 made, for example, of transformer iron, a non-temporary magnetic flux is excited, separating two identical fluxes Qi and F2 in the side rods x 8 and 9. Due to this, the thermomagnetic element 12 begins to be heated by the current of the winding 3 feeding the heater 10. At the same time, the thermomagnetic element 13 is also heated by the heater 11 fed by the winding 4. However, due to the greater mass t rmomagnntnogo member 12 its temperature reaches the Curie point under the operating shaft 9 in a lateral magnetic flux F2. When the thermomagnetic element 12 reaches the Curie temperature, it passes to the paramagnetic state, and the magnetic resistance of the side rod 8 increases dramatically, resulting in the entire magnetic flux of the middle rod closing on the side rod 9. Increasing the flow in the side rod 9 approximately doubles heating. thermomagnetic element 13 to the Curie point. The thermomagnetic element 12 at this time is even more fixed in the paramagnetic state, since the feedback winding 3 increases the current through the heater 10 as the flow in the side rod 9 increases. After the thermomagnetic element 13 reaches the temperature of the Curie point, the alternating magnetic flux in the side rod 9 falls almost to zero, and the windings 3, 4, 5 cease to produce alternating voltage. In order to eliminate the dead point effect during the transition of the thermomagnetic element 13 to the paramagnetic state, the threads of the heater 11 are unevenly arranged in its body.

After de-energizing the windings 3-5, both thermomagnetic elements 12 and 13 begin to cool. Since the mass of the thermomagnetic element 13 is greater than the mass of the thermomagnetic element 12, the thermomagnetic element 12 returns to the ferromagnetic state earlier than the thermomagnetic element 13, which is accompanied by the appearance of a magnetic flux in the side

the rod 8, almost equal to the magnetic notes in the middle rod. Further cooling of the thermomagnetic element 12 will occur until the temperature of the thermomagnetic element 13 reaches the Curie point and the thermomagnetic element 13 returns to the ferromagnetic state, after which all processes begin to proceed anew in the described sequence.

Due to the fluctuations of the magnetic flux in the side rod 8, the output winding 5 generates an alternating current pulsating in amplitude in the load 7. The frequency of the current pulses determines the frequency of the electrical oscillations produced by the generator. It depends on the masses of the thermomagnetic elements 12 and 13 and can be in oscillation ranges with a period from tens of seconds to tens of hundreds of minutes.

Claims (1)

1. USSR author's certificate No. 130071, cl. H OZK 3/45, 1959 (prototype).