BE1018711A3 - MAGNETIC ENERGY SAVING DEVICE. - Google Patents

Abstract

The principle consists in using two magnetic modules 2 and 3 in parallel, fixed at a good distance from the cable 1 carrying the mains current. In principle, it is advisable to carry out a triangulation with the polar concordance points and the axial axis of the magnetic modules 2 and 3 with respect to the cable 1. This focusing point is moreover variable according to the flux of the intensity of the current flowing in the copper conductor located under the north flux of the magnetic modules 2 and 3. The more this flux is intense, the greater the focusing distance will be and vice versa, if the flux decreases this distance will be lower. An adjustable screw rack device will make it possible to precisely adjust the distance between magnetic modules as a function of the average power of the device. The yields achieved will be variable and depend essentially on the electrical power consumed, that is to say that the more energy the system consumes, the greater the energy gain obtained. For small power of 25… 40 kilowatts / day, the average gains will oscillate from 18… 20%. On the other hand, ...

Description

Magnetic energy saving device H is well known in magnetism that the poles of the same polarity repel each other and, on the contrary, those of opposite polarity attract each other.

Many applications have been described based on this principle, such as, for example, electric motors with permanent magnets or brushless motors, bistable relays or electromagnetic brakes such as Telma The idea that is the subject of the present application also in practice this principle of polarity and brings a new idea.

The principle consists in using two parallel magnetic modules fixed at a good distance with respect to the cable carrying the mains current. The polarities of these two modules will be in the same orientation with the north poles oriented towards the electric cable.

The peculiarity of the idea is to resonate these two magnetic modules, and to maintain the good distance between them with respect to the cable conveying the energy of the sector. Indeed with the proximity of the two magnetic modules, placed a few centimeters apart, we obtain a consequent crossing of the lines of force of the north and south polar masses.

In principle, it is advisable to triangulate with the polar points of agreement and the axial axis of the magnetic moduli with respect to the cable. This focusing point is also variable as a function of the flow of the intensity of the current flowing in the copper conductor located under the north flow of the magnetic modules. The more intense this flux, the greater the focus distance will be important and conversely, if the flow is less this distance will be lower. An adjustable screw rack device will allow to precisely adjust the distance between magnetic modules, between 30 and 120 mm, depending on the average power flowing in the device.

When maximum power flows in the copper conductor, the magnetic modules exhibit significant vibrations, the greater the greater the current flowing in the cable. These vibrations are of a frequency proportional to the frequency of the alternative network conveyed in the copper, in this case for France and Europe with a frequency of 50 Hertz or one of its harmonics and for the USA 60 Hertz or one of its harmonics The orientation of the magnetic modules is perpendicular to the axis of the cable and their north poles will be favorably oriented toward said cable.

This particular use of the magnets makes it possible to resonate said magnets constituting in part the magnetic modules and this particular arrangement will reduce in a significant way the energy consumption used in a device where this system has been installed.

The device is not productive instantly, but we will observe an average duration of ramp-up times which is of the order of sixty hours before reaching its full functionality from the point of view of performance, so the duration, before presenting an economy more and more important on consumption.

The yields achieved will vary and essentially depend on the power consumption, that is, the more energy the system consumes, the greater the energy gain. For small powers of 25 to 40 kilowatts / day, the average gains will oscillate from 18 to 20%. On the other hand, for powers above 100 kW / day, the average earnings can, in principle, quickly reach more than 25%.

Any removal and installation of the device with respect to the cable will require a reset of the performance of the magnetic device and thus a new duration of re-powering the order again of about sixty hours to reach its full functionality and allow to present to again the most important consumer economy.

Other features and characteristics of the invention will emerge from the description of an advantageous embodiment given below, by way of non-limiting example, and with reference to the appended figures.

Figure 1 shows the device in its entirety.

Figure 2 shows the operation of the system with the different currents.

In these figures the same references designate the same parts.

The entire device shown in FIG. 1 shows, surrounded by its sheath, the copper wire 1 which conveys the energy of the sector as well as the two magnetic modules 2 and 3 oriented towards the north pole to obtain maximum resonance. point of focus should vary depending on the intensity of the flow flowing in the copper wire 1, the distance 4 between the magnetic modules being adjustable through an adjustable rack 5 screw 6.

Figure 2 shows the operation of the system.

In this figure, the current I] is the current consumed by the load 7 .. The value of this current Ii is conditioned by the type of the load 7, its voltage U and its internal resistance R and as long as U and R remain constant the intensity will remain invariable according to Ohm's law which indicates that the intensity is equal to the voltage divided by the resistance (I = U / R).

The magnetic module 2 supplies a current of intensity h and the magnetic module 3 supplies a current of intensity I3.

The resulting energy (I2 +13) having no freedom through the load 7 can only pass in the direction of the consumption meter 8, ie in the count of Ii consumed by the load 7, therefore by consequently, to reduce the consumption of the system as well as validation made by said consumption meter 8.

The magnetic modules 2 and 3 are parallel to each other and are arranged perpendicular to the axis of the copper cable 1 which conveys electrical energy to the load 7.

The north poles of the modules 2 and 3 will be oriented towards the cable 1 and thanks to the rack system 5 adjustable screw 6 will optimize the yield by changing the distance 4 inter modules.

Although a preferred embodiment of the invention has been described and illustrated, it should be understood that other variants may also be applied while remaining within the scope of the inventive principle.

Claims (4)

1. Magnetic energy saving device characterized in that due to the presence of two magnetic modules 2 and 3, with north / north or south / south orientation, arranged parallel to the cable 1 conductor of the electrical flow and which, following significant vibrations caused in these modules, vibrations proportional to the frequency of the network and induced by the electrical flow flowing in the cable 1, resonate the magnets of said magnetic modules 2 and 3 which has the effect of significantly reducing the consumption of energy used. 2. Device according to claim 1 characterized in that this energy saving will be variable depending on the power consumed, plus the system will be large consumer plus energy gain will be important. 3. Apparatus according to preceding claims characterized in that to achieve a triangulation with the points of polar agreement between the axis of the magnetic modules 2 and 3 and the cable 1 is provided an adjustable screw rack system to change the distance focusing between modules as the higher the flow will be higher the distance will be high and vice versa. 4. Device according to preceding claims characterized in that for small powers for example 25 to 40KW / day the gain will be 18 to 20% and for powers for example greater than 100 KW / day this gain will be greater than 25%.