Thursday 23 May 2019
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The realized project

1.

On February 12, 1980 on MOIP physics section at Moscow State University (MSU) Zajev N. E. made the message about cooling of some dielectrics the changing field with energy generation.

 Sychev V. V. (Sychev V. V. Complex thermodynamic systems. Science, M.,1980. This book is in our section "Literature") the ferroelectric material capable in the cycle "heating  cooling" to generate the electric power with efficiency (on Carnot's cycle) ~ 3%-5% are described.  In the offered varikonds cycle (ferroelectric condensers) work in the cycle "charging discharge" with efficiency of 126%, selecting heat of Wednesday. At capacity 33 мФ, frequency ~ 100 Hz, efficiency ~ 138% (settlement ~ 123%); specific power of generation ~ 2,1 kW/m3 of dielectric. In the long term varikonds on dielectric can provide to a polivinilendenftorida specific power to 45 kW/m3. The concentrator (generator) of energy on capacity - C-kessor - in fact the perpetual motion machine of the second sort because nonlinear dielectric with dε/dE>0  its energy grows with growth E (el.fields) only before saturation. It generates energy periodically, itself being cooled. S-kessor No. 12, 1998 of, page 53-55 is described in "Electrician".

 2.

      THE DEVICE FOR OBTAINING ELECTRIC ENERGY

It is worth paying attention to the patent RU No. 2390907. The device can find application in electrical equipment as an autonomous source of power supply. The device contains the case with a package of plates of both signs divided by a layer of a ferroelectric material and equipped with the charging plate separated from the others by a layer of a ferroelectric material and executed from a bipolar electret, for example, of a politetraftor ethylene, polyethyleneterephthalate, polycarbonate, titanate of calcium, glass, sitall, etc.; as a ferroelectric material the stabilized single-crystal ferroelectric material, for example, barium titanate, polyvinylidene fluoride, triglycine sulfate, a ferro salt, dihydrogen phosphate potassium, lithium niobate, fluorine beryllates ammonium, etc. is used; in a package of plates at least one elementary cell consisting of one electret and two metal plates, all layers most densely adjoin to each other and are placed in sequence: metal plate - a ferroelectric material - an electret - a ferroelectric material - a metal plate; in the presence in a package more than one elementary a cell each following cell adjoins to previous the charges of metal plates of the same name. The invention provides utilization of internal energy of the used substance.

Various dielectrics are known. The ferroelectric material dielectrics possessing spontaneous polarization which significantly increases and changes under the influence of external influences, in particular, under the influence of electrostatic and magnetic fields. A ferroelectric material on the properties is in many respects similar to ferromagnetics (see Zheludev I. Ferroelectric material based of a ferroelectricity, M., 1973). The electrets dielectrics’ capable to accumulate is also long to keep electric charge or polarization.

In a basis of the invention the task of receiving the electric power due to utilization of internal energy of the used substance is set.

The objective is solved in the device for obtaining electric energy which is turning on the case with a package of plates of both signs divided by a layer of a ferroelectric material and equipped with the charging plate separated from the others by a ferroelectric material layer that the charging plate is executed from a bipolar electret, for example from a politetraftor ethylene, polyethyleneterephthalate, polycarbonate, titanate of calcium, glass, sitall, etc., and as a ferroelectric material use the stabilized single-crystal ferroelectric material, for example barium titanate, polyvinylidene fluoride, triglycine sulfate, to a ferro salt, dihydrogen phosphate potassium, lithium niobate, fluorine beryllates ammonium, etc. Electric power of an elementary cell is in directly proportional dependence on its area and electric capacity.

The declared device including a bipolar electret and the stabilized single-crystal ferroelectric material allows to receive steadily the electric power of necessary power due to utilization of internal energy of the used substance, for example, at the power of one elementary cell of 0,160 MW the device continuously works at an extent not less than 8000 hours.

The following dielectrics were used.

Politetraftor ethylene, temperature of melting of °C (melt. tem. ) - 310, dielectric permeability () - 3,1;

Polyethyleneterephthalate, temperature of melting of °C (melt. tem.) - 170, dielectric permeability () - 2,6;

Sittal, temperature of melting of °C (melt. tem.) - 750, dielectric permeability () - 5,3.

Barium titanate, Curie's point of °C (CP) - 120, the maximum spontaneous polarization (Ps), ¼¬è½/sq.m – 300.

Polivinilidenftorid, Curie's point of °C (CP) - 170, the maximum spontaneous polarization (Ps), ¼¬è½/sq.m – 80.

Ferro salt, Curie's point of °C (CP) - 24, the maximum spontaneous polarization (Ps), ¼¬è½/sq.m - 2,5.

  3.

At present we began the production of a polymeric autonomous source of current of small power on the basis of the theoretical and practical materials and publications presented on our site in the section "Electret Battery".

Our experiments