ES2756973B2 - ELECTRICAL CORRECTOR APPLICABLE TO REFRIGERATION AND HEATING APPLIANCES - Google Patents

Description

DESCRIPTION

Electrical corrector applicable to refrigeration and heating appliances

TECHNIQUE SECTOR

The present invention refers to refrigeration appliances such as cold rooms or air conditioners, which work by changing the state of a refrigerant liquid, and which can also function as "heat pumps" by reversing the direction of the air outlet in contact with the compressed fluid that expands and cools as it expands.

The object of the invention is to ensure that no perceptible adhesion of the water contained in the humid air that passes through the compressor and vaporizer coils is generated to the contact surfaces, including the food in the cabin that it cools, and consequently not drying out the air. environment of this cabin or precipitating water that has to be evacuated, all with notable energy savings in the process and a certain reduction in the sound emitted by the machines that perform the function, obtaining unbeatable food preservation through a "cold dry”, an improvement for the vital functions of the people who occupy the passenger compartment that is cooled, such as obtaining oxygen from the air, even an improvement for the environment by not removing water from the atmosphere, thus not the title of the humid air of this one increases and in this way the atmospheric precipitation is favored.

BACKGROUND OF THE INVENTION

It is a fact that the electrons in an alternating current established in a circuit travel more or less in groups, which is deduced from the fact that the distance to be traveled by the electrons of the wire of this circuit is different for them, so it must have accumulation; which is overweighted by the circumstance that in ordinary urban circuits the distance to be traveled between points of discontinuity is very small so that at the speed that the electrons travel for a current of approximately 230 V there is normally a notable phase shift for these electrons between these points at a frequency of 50 Hz. ...But it also happens that inductions occur in the circuit out of phase with respect to the established current, which are large, such as self-inductions of the windings of household appliances, produce the generation of non-negligible groups of electrons that travel through the circuit separated from the group that forms the main current, which we will call "secondary currents" and the electrons that make it up "secondary electrons" . These "secondary electrons", when traveling in relevant groups, exert a certain pressure on the positive ion that surrounds the conductor, due to the electrostatic repulsion inside these groups, and easily transfer the discontinuities that appear in it towards new conductors. , and furthermore, when they are moved by an emf of a certain magnitude, they do not stay relevantly at the inflection points of the conductor they travel through. On the other hand, if the inductions are of little relevance, such as that produced by the humidity of the environment in the conductor, the groups with which they travel are tiny, and they do not easily cross the discontinuities that are produced in the positive ion that surrounds the conductor. towards new conductors, since the transverse pressure to the direction of the current is small, and they are de facto entering and leaving the inflection points of the conductor through which they travel, so when they are not settled in these we can say that they form a kind of "pangea" in the driver whose relationship with the sense and speed of the "main stream" is very distant. We will call these last electrons, which when settled at the inflection points polarize the conductor, and their generation is not only due to inductions of little relevance, but also to other reasons such as the change of state of a substance, before the abrupt change of linear momentum suffered by its molecules that makes the electrons inertially escape from them, or thermionic emission.

Well then: the presence of secondary electrons subtracts average power from the established current compared to what would result if the main and secondary currents had the same phase, since it is a current out of phase with respect to the main current that has a component contrary to movement established by the latter, or, if you prefer in more technical terms, between the emf that moves the main current and the intensity finally specified in the circuit, and since the electrons for the secondary currents come from the same circuit, it has generated a phase shift that decreases the “power factor” (cos. o). Therefore "correcting" the current, that is, Taking secondary electrons to form part of the main current would increase the average power of the established current, which in the end is equivalent to an increase in the emf applied to the circuit, which is what the multimeter shows us when measuring a current that has been subject to correction. For their part, the polarization electrons, when they are effectively settled in the polarization places (generally the inflection points of the circuit, since they are small "points" in it, which is where the electrons are electrostatically concentrated in a conductive material). ), in general, they oppose the passage of current, since the electrons of the current “collide” with them and leave part of their linear momentum in the positive ion through them. The latter becomes resistance in direct current and in alternating current they "smooth" it, since the path traveled by the electrons affected by this shock becomes, in each half cycle, less than that of the main current, although they do not form groups, which translates, in addition to a little less power due to what has already been explained for the secondary electrons, especially in anomalies in the operation of the devices, prepared to function with a correct sinusoidal cycle, as is the case of those that they replicate electromagnetic waves for audio broadcasting (the case, for example, of anomalies in the television image). For all these reasons, having a polarization level in the circuit as low as possible is the most appropriate.

In addition, it must be said that the almost exclusive source for the determination of secondary currents are the polarization electrons not settled in the respective polarization places (the "pangea"), since the electrostatic interaction of the groups that form the current pushes them towards the positive ion, where forces of attraction are established with it, so that it is as if it were a compact group "clinging", although in a mobile way, to the positive ion, which does not happen with the electrons of the " pangea”, so when an induction occurs in the circuit of a certain relevance, the electrons to form the corresponding groups, which travel as secondary currents, are detracted from it. For this reason, correcting the current, new unsettled polarization electrons are withdrawn by the inductions, which means that due to a lack of ionic tension those that are settled leave the settlements, which become secondary electrons, and these, corrected , electrons of the main current. All this without taking into account that, to correct secondary electrons, pointed conductors are used which, if they are not released properly, become a source of "efficiency in polarization", that is, in the settlement of electrons from the "pangea" in the places of polarization, by electrostatic repulsion, so if the excess electrons from the correction that could not have been subject to it are not conveniently withdrawn, the latter occurs even with an increase in polarization.

It must be said that there is a way to correct the current and transform secondary electrons into components of the main current: it is about rods made of a less conductive material than the one that carries the current, adhered with strong pressure as an appendage to the transverse of the conductor, and its operation is as follows: When the current passes through the place where the rod is, the transversal pressure of the groups that make it up and the strong union of the rods to the conductor causes at least part of these groups to cross the discontinuity. This occurs predominantly with those groups whose force that pushes them in the direction of the current is less, that is, whose emf to establish them is less, that is, with secondary currents. As the material of the rod, which is conductive (and therefore the electrons pass through) but less than that used to carry the current, has a lower conductivity than the copper used generically to carry the current, for the same unit of surface and the same unit of time for the conductor of the current and the rod, this indicates that fewer electrons fit on the surface of the rod than on that of the conductor of the current, so that before the cycle is completed in the current They are already "pushing" to get out of the rod, and the cycle of filling and emptying the rod is therefore different from that of the current (main). In this place we have to say that aluminum, which has a conductivity approximately half that of copper, appears to be ideal, since it holds, per unit area and time, approximately half as many electrons (for conduction) as in copper, so if the ratio between secondary electrons and the main current does not exceed that of the ratio of conductivities, weighted by the fact that they tend to leave the rod at times of the current cycle less prone to enter it, the charged electrons in the rod as an accumulator leave at least partially the conductor with the main current, so secondary electrons have been transformed into main current electrons. At this moment we have to say that a relationship close to 50% between secondary electrons and the main current is not far from the average: as an appendix we can say that in specific experiences with a multipurpose electrical corrector that can be improved in terms of dimensions and quality of construction, the performance is close to (may even have exceeded) 15%, but experiences carried out with the favorable sense of the passage of current in the entire conductor of the succession of rods that make up the polyvalent and in the cable that joins the last of these to the accumulator, both in the conductor itself and in the insulation that surrounds it, and with the use of the accumulator (in addition to other efficiency improvement criteria), which has significantly improved the performance observed in experiments with the polyvalent, leads us to conclude that the initial ratio of secondary electrons / main current electrons is not far from that 50%. ...In the case that the material of the rod is the same as that of the current, v. gr. copper, there is no correction, since the filling / emptying cadence is the same in the rod as in the conductor, and the electrons that enter the phase of the cycle in which the group that forms the main current is not found, return to leave the conductor of the current in that same phase of the cycle, without thereby becoming part of the main current.

Regarding the composition and shape of the rods, we have said that they are a cylindrical composition of thin sheets of aluminum foil or also fine aluminum wires, in both cases with the intention of increasing the surface of the material and thus the capacity of electrons. of circulation, since it is known that these are concentrated on the surface of the conductor, and in the case of using aluminum foil, the dust that could be brought on one of its faces must be removed as much as possible, always putting this face on the outside of the rod, since this, the dust, is a source of small induction and therefore of polarization. The reason they are cylindrical is that the return of the electrons produces less accumulation in the vicinity of the contact with the current cable than if they were wide, and the roundness of the shape produces uniformity in the process and, therefore, absence of in this sense of internal polarizations. They are finished with a tip free of insulation (they have insulation throughout their entire length, to increase the capacity and above all to protect them from the polarizations created by the irregular arrangement of the surrounding electrons), so that the charges that accumulate are released. due to incomplete correction and, in this sense, avoiding, as far as possible, polarizations inside the rod that, like these (polarizations) are transmitted, since every polarized point is also a source of efficiency in polarization in a symmetrical and opposite point of the circuit by electrostatic repulsion, . communicated to the rest of the circuit. However, they can be joined by means of a cable without a free end to another rod that does have one, and show a composition yes / no free end on the rods, if required, see. gr., the air currents for the referred free points in the enclosure in which they are. ..But it is possible, and in fact it happens, that the free ends are not enough for the release of excess electrons and polarization occurs with continued activity of the rods. In this case, and de facto always for the efficiency in the operation of the correctors, we have to insert an "accumulator" attached to the end of the last rod by means of a cable.

These "accumulators" are preferably pear-shaped masses with a non-smooth surface, made of a non-conductive material and also with a high polarizability per surface / volume unit, as is the case of some rubbers and in any case of the clay. The arrival of the charges inside the accumulator must be approximately at its center of mass, for uniformity in their communication inside and in their release, and thus avoid internal polarizations due to differences in release, the latter reason whereby the accumulators have to remain upright on the surface where they are located and, unless a greater power of these is sought without paying attention to their incidents, placing them directly on the ground, isolated from that surface on which they rest by means of insulation. The operation of accumulators is as follows: The high polarizability per unit area / volume causes the charges to adhere to their molecules upon arrival, but there is also a polarization of these molecules along any straight line that is drawn inside the accumulator. Thermal agitation can cause these charges to come off and some of them start to join the molecule that radially with respect to its arrival is behind the one to which it joined when it arrived, and with this last one the same thing can happen, and so on, from so that the charges that reach the interior of the accumulators go from it to the surface of the accumulator, and in fact an accumulator in operation is heated by the Joule effect. Once on the surface of the accumulator, it polarizes the environment, since the material of the accumulator is a "non-conductor", and as such it does not oppose a field contrary to that of the outside, a fact for which the conductors are not ideal for the release, except in the case that the centrifugal force carried by the direction of the turns in the driver, which will be discussed later, helps in that sense. The polarization of the accumulator environment helps the output of the charges from it. The entry of the cable into the accumulator must be vertical, for the same reason of uniformity in the distribution and avoidance of internal polarizations in the accumulator. Likewise, metallic surfaces exposed to insulation should be avoided, both in the vicinity of the accumulators and inside them and in the vicinity of the free points, since their charges create a field contrary to the one that moves the charges in their release. causing a release difference in the device for that purpose and, consequently, polarization in it.

We have talked about the cables that connect the rods and these with the accumulator. Indeed: the entrance to the rods can be done by cable, even coming from the main current. But at this point we have to say that in order for the efficiency in the operation of the corrective and depolarizing devices to multiply, the cable must be entangled with a direction of the turns that is the only one that pushes the charges that circulate through it towards the surface of the conductor, by the Lorentz forces that are exerted between opposite parts of the conducting wire in the entanglement, as shown in the drawing below. This entanglement is the result of a positive or anti-clockwise rotation direction of the charges in the turns that they describe, seen from the place where their circulation is going. Both the entanglement in the opposite direction to that indicated and the lack of entanglement produce attraction between the charges, and therefore flight from the places of the conductor with more surface area collateral to the direction of movement of the charges. This repulsion of the charges that circulate in the turns favorable to the current passage indicated causes them to go towards the outside of the entanglement, where the collateral surface differential to the direction of circulation of the charges is greater. As the charges in a conductor circulate through its surface, in this case we find ourselves with a greater aptitude of the electrons that are in the conductor to the transmission of the current. This is essential in the case of transmission of polarization electrons, as it happens for the release of excess charges from the correction, since the potential difference that moves them is tiny, as the multimeter shows, of the order of a few millivolts at most. in a device that works correctly, and consequently of a capacity for the transmission of current between 1 to 10 (v. gr.) in the electrons of the conductor that carries them, they need a capacity of "8" or "9", which is only found in a notable way in cables with the direction of the turns favorable to the passage of current. All this has been amply verified in the experiences carried out. ...But not only the direction of the turns must occur in the conductor, especially if it partially serves polarization electrons at least: a higher performance is also obtained with this same direction of entanglement in the insulation that surrounds the cables ( They are lined with insulation to avoid leaks and incidents from the external environment that generate polarizations), given that the notion of analog conductor and without a precise limit, the charges also circulate in the insulation, at a speed much lower than that of the conductor but with the same cycle, since it is in direct contact with the conductor. This fact pushes the charges of the insulator towards its exterior, moving them away from the conductor, therefore, before the less ionic repulsion, the charges of the conductor go more to the surface of the latter, and also tends to cancel the interaction of the external environment when these charges of the insulator approach it. All this has also been empirically verified. This last reason is the basis for the greatest efficiency to be found (as has also been verified) in the use of a high density of insulation that surrounds both the rods and the cables. Regarding the optimal length of the cables, for its part, we must say that this must determine that the ratio of surfaces between the cable and the rods is not less than that determined by the ratio of aluminum / copper conductivities. To the eye of a good cubero, in a normal composition, the cables must be somewhat longer than the rods (never the same length or less), but here we find another circumstance: as the direction of the turns determines an aptitude for the evacuation of polarization electrons, in general, the more cable, the more electrons with aptitude for it, so the cable that goes to the accumulator and the input cable of the circuit to the first rod must be significantly longer, which has also been verified in independent accumulators whose sole purpose is depolarization without binding to the rods. The same does not happen with the cable between rods, since this can determine an excessive loss of ionic tension necessary for the jump of discontinuities. On the other hand, say that in the event that we need to join cables, it will be done by simple juxtaposition of these strongly adhered by the pressure of the insulation that surrounds them (also the latter with a direction of turns favorable to the passage of current, to always be used), not entangling them one over the other, since the latter creates inductions of low magnitude and therefore polarization electrons and effective polarization at the end of the cables at the end. Needless to say, the entry of the cables to the rods must be from the inside of the rods, and the exit from the outside of the rods, since this makes better use of the centrifugal force created by the direction of the turns mentioned in the distribution. uniform charge on the rod.

Another very important criterion, practically a sine qua non condition, for the efficiency in the operation of the corrective and depolarizing devices is the symmetry in the depolarization: Every polarized point, by electrostatic repulsion, is a source of efficiency in the polarization in a symmetrical place and opposite to it, as has already been said, that is, it causes the polarization electrons to become fixed in it: Since with continuous operation it is impossible for any individually considered depolarizing device not to saturate and also end up polarizing, we must place in a symmetrical and opposite place other depolarizing device, so that when the electrons arrive at it they are also evacuated and do not polarize the first one, and thus there is an equivalence in which the surplus electrons are sent from one to the other until they are evacuated. This is achieved, as in the composition object of the invention, by placing rods and accumulators in pairs, or, as in the case of the polyvalent one, in a symmetrical place and opposite to that of the accumulator, one or more "mobile depolarizers", which do not they are more than a few entangled copper wires with turns favorable to the passage of current, with approximately a third of their length without entanglement, in the open air, as tips. In the event that the depolarization must be on certain surfaces, such as a television screen, this will be done, by depolarizing gadgets, "at the four corners", closing the interior of the surface to be depolarized by depolarizing gadgets or those parts from the surface where its effects are felt.

Other criteria for efficiency to take into account are always strong contact pressure, to favor the jump of discontinuities, and the avoidance of inflection points as far as possible, for which purpose the sheets of the rods in the event of that are used must be previously landscaped in the event that they were not long enough, to avoid points of location of polarizations.

EXPLANATION OF THE INVENTION

The contraption in question consists of the placement of two groups of rods chained by cable with their respective accumulator, in the manner described in the previous section, joined together by a plate like the plugs' grounding plate, which has a crested hole. to avoid the polarization of the link in alternating current, for which purpose the same grounding plug plate is valid, and this connected by a single cable, also with turns favorable to the passage of current, to the existing appendage in the compressor of the refrigeration for the release, if it had one and both the appendage and the compressor were metallic, and if this were not the case, to an appendage for the purpose in contact as immediately as possible with it and in any case (both in the compressor and in the appendix independent) through which current flows. Both the free tips and the accumulators must be well ventilated, for the correct release.

The operation is as follows: The change of state produces a large amount of free electrons, as can be seen in the freezer of a refrigerator, where if we are not careful the fingers that we place on top get stuck by electrostatic attraction, or in the active clouds where the change of state is taking place,...hence the good heavens. These electrons are ultimately polarization electrons, which both in the compressor and in the immediate vicinity, such as in the vaporizers of the room to be cooled (or heated) cause the ionization of the humid air that comes into contact with them, and among other things , in this way, the cumulative adhesion of the water molecules that this humid air contains to the surfaces in contact with it. At this point we have to say that although the liquefaction of water in refrigeration appliances is due to thermodynamic reasons (reaching the dew point temperature at the partial pressure of the water found in humid air with its relative humidity in question), this only causes the adhesion of a few molecular layers imperceptible to the naked eye unless these molecules are ionized: The dipole moment of water, one of the largest if not the most existing ones, materializes in a structure in which the positive charges of the dipole (two) form an angle of 106° with each other, so that the cumulative adhesion of these dipoles to the contact surface as in a house of cards, as if of a crystalline structure is treated, with the corresponding thermal agitation, is unfeasible. However, if one of the negative dipoles is neutralized with an electron, the dipole structure takes axial symmetry, and its orientation for cumulative adhesion to a contact surface is much more probable, reaching with this accumulation the point of precipitation, for which reason the Refrigeration appliances generate noticeable liquefaction of water, which must be evacuated or returned to the atmosphere in sprayed outdoor appliances. But they also generate the adhesion of the water molecules in the room to be cooled to the contact surfaces, with which, on the one hand, the air in the room dries out and, on the other hand, this water accumulates on the contact surfaces of the itself, including food in a cold room. The presence of excessively ionized air in the room to be cooled or heated is also very harmful for human beings, especially the elderly: thus, v. gr., by dissolving the air mixture to extract oxygen in our lungs, a certain percentage of oxygen radicals can be formed, which if the air is ionized, apart from these radicals, an ion present in the air adheres to them and they are already they do not join other oxygen radicals to form an oxygen molecule, so they are chemically inoperative. This increases with a polarized environment, as is the case with the elderly, since it directs the radicals formed towards the walls of the passenger compartment and prevents them from being oriented with respect to each other. the others to form the oxygen molecule, until an ion from the air ends up joining that radical. It is the feeling that we have that "we lack air" in environments charged by thermal manipulation of it. Even more: the ionized air jet, if it has a permanent direction and is sufficiently apparent, ends up polarizing our body, responsible for many ills in it and for the reduction of the necessary chemical reactions due to the aforementioned orientation towards the walls of the passenger compartment.

This contraption, when in contact with the current of the refrigeration appliance, and with sufficient proximity to the generation of polarization electrons in it, corrects the secondary electrons of the latter, thereby gaining power, or in the case of If a certain amount is needed to reach the established dimension, it reduces consumption, as indicated in the previous section. ...And since the formation of secondary electrons is almost exclusively from polarization electrons, by evacuating the first ones we consume the second ones, so the result is that a remarkable energy saving is produced while eliminating liquefaction of perceptible water, food is kept in a perfect state of conservation with that "dry cold" generated, while the harmful effects for human beings of thermal handling devices are practically eliminated through the change of state (also in this last case if the polarization electrons are not due to the change of state). .All this with the way of functioning that can be deduced from the previous epigraph.

Finally, since the presence of secondary electrons and, to a lesser extent, polarization electrons generates vibration in machines and household appliances, by reducing them with this device, the noise produced by the refrigeration/heating appliance (such as “heat pump”) to which it is applied.

DESCRIPTION OF THE DRAWINGS

To complement the description that is being made and in order to help a better understanding of the characteristics of the invention, in accordance with a preferred example of practical embodiment thereof, a single drawing is attached as an integral part of said description where, with character illustrative not limiting, it has been represented the following:

The figure shown in the drawing corresponds to a schematic representation of the practical application of the invention, forming an electrical corrector applicable to refrigeration and heating appliances.

PREFERRED EMBODIMENT OF THE INVENTION

As can be seen in the referred figure, the electrical corrector applicable to refrigeration and heating appliances is applied to a refrigeration or heating appliance by means of a "heat pump" (1), through a cable with turns favorable to the passage of current ( 2), that a small plate with a crested hole inserted like the grounding ones (3) bifurcates into two branches that go to the correcting rods (4), linked together by cables with turns favorable to the passage of current (2). At the end of each of the last corrective rods (4), a cable with turns favorable to the passage of current (2) joins them to two accumulators (5).

Claims (1)

1a.- Electrical corrector applicable to refrigeration and heating appliances, in which a heat pump (1) participates, characterized by the fact that it consists of two groups of corrector rods (4) arranged symmetrically and linked together by means of individual branches or cables. with turns favorable to the passage of current (2), which are connected at one of their ends to respective accumulators (5) while at their opposite end they are connected to a common ground (3), rods that are all joined together yes from a plate with a ridged hole for eliminating the polarization of the alternating current link, ground connection that is connected to the heat pump (1).