ES2351138B1 - ELECTROMECHANICAL GENERATOR CELL AND PROCEDURE FOR OBTAINING THE SAME - Google Patents

Abstract

Electromechanical generating cell and method of obtaining it. # The invention consists of a sheet of flexible material (1) in whose central area a sector (2) with a dome-shaped deformation is defined, over which at least one of its faces is established a magnet (3), being established concentrically to said assembly, and on at least one of the faces of the flexible sheet, a plurality of turns (4), of an electric conductive material, in coil functions , forming one or more electrical circuits, defining a perimeter deformation (5) from the location area of the magnet or magnets, in function of a recovery element. Thus, when pressing the sector (2), it will deform, causing an axial displacement between turns and magnets that will induce a current in the turns that can be used for the specific application that has been planned.

Description

the set of turns of an electrically conductive material

Electromechanical generator cell and procedure to obtain it. Object of the invention

The present invention refers to an electromechanical, printed generator cell, that is, to an electromechanical automatism that, by mechanical action, generates electrical energy in the form of electromotive force or induced current at its output. This energy can be used in certain applications where you want to avoid the use of power batteries.

The device of the invention has been designed to be produced industrially by means of printed electronics technology. Background of the invention

There are many applications of consumer electronics and small electronic circuits that use battery power. The use of batteries has some drawbacks such as the physical space it occupies, sometimes more than its own circuits, and the need for maintenance, recharging or replacing them, as well as the environmental impact they produce. Therefore, in cases where it is possible it is useful to have alternative energy sources that avoid the use of batteries.

The applicant is unaware of the existence of electromechanical generating cells with a similar structure and configuration similar to the present invention. Description of the invention

The proposed device constitutes a method to generate small amounts of electrical energy to use in applications where possible, thus avoiding the use of batteries.

To do this, it bases its development on two scientific-technical concepts:

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Principle of electromagnetic induction

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Printed electronics

In relation to the first concept, it is known that the variation in the flux of the magnetic field within a conductor loop induces an electromotive force and, therefore, an electric current if the loop circuit is closed. The intensity of the energy produced by a winding of turns in whose interior the flux of the magnetic field varies depends on the derivative of the flux as a function of time, that is, on the speed of variation of the magnetic flux through the winding. Many are the devices that generate energy based on this principle as we motors.

On the other hand, the technology of printed electronics makes it possible to industrially produce electronic circuits using procedures and machinery commonly used in the printing of documents (roll-to-roll printing processes). This form of massive circuit production lowers costs, in addition to giving them a flexible and adaptable character to different surfaces and materials.

Well, according to the invention, the recommended cell is constituted from a flexible substrate or sheet having a slight deformation in its central part, for example in the form of a dome, on which at least one magnet, although two, one on each side will preferably participate, thin magnets separated by the trico itself acting as a winding that surround it, and which are also supported on the same substrate. Between the dome and the spiral assembly there is another deformation in the substrate as a recovery element that allows some relative displacement between both parts; the one that supports the magnets and the one that supports the turns. The ends of the set of turns are taken outside for consumption, by means of electrical conductive extensions.

After this structuring, two states are defined in the device, the state of repose and the forced state.

Starting from the state of rest, when pressing in the center of the dome it begins to deform so that, from a point of deformation, a break in the tension equilibrium of the same occurs, causing a sharp acceleration until its total deformation in the sense opposite to its resting position, thus reaching the forced state position. This "one-way" path causes the magnets to move in the normal direction to the plane of the surface of the set of turns, with the consequent variation of the flux of the magnetic field inside the assembly and the generation of the induced current in it. When the initial force on the dome ceases and due to the tension due to its deformation, it undergoes a second displacement, that is, a "back" path from the forced position to the rest position, so that also from At a certain point, the displacement is accelerated sharply again by crossing the magnets again the horizontal plane of the surface of the turns, which again will cause a variation of the flow of magnetic field with the generation of the induced current.

Optionally, the device could be developed in reverse, that is, that the magnets had an annular configuration, arranged in the periphery, and that the turns be placed on the elastically deformable zone, so that the deformation of said central sector, will also bring about a relative displacement between magnets and turns, also generating an induced current on the turns.

Similarly, a material with magnetic properties could be included in the substrate composition itself, so that it enhances the magnetic field of the existing magnets in the cell.

From this con fi guration a substantial advantage derives, and that is that the energy is produced by a mechanical action, both in the outward movement and in the return movement, and just at the moment when a user action is requested by the system. Therefore, it is not necessary to store energy for long periods for the consumer system to function, without prejudice to the energy generated and not consumed during the operation of the system can be stored for later use.

In addition, this cell can be miniaturized and adapt to the appropriate size that the application requires, allowing its applications to be virtually unlimited.

Simply exemplary, the generating cell may preferably be manufactured in a size such that it conforms to the pulsation surface of a human finger.

3 ES2351 138A1 4

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, according to a preferred example of practical realization of the same, a set of drawings is attached as an integral part of said description. and not limiting, the following has been represented:

Figure 1.- Shows a perspective and diametrical section view of an electromechanical generating cell made in accordance with the object of the present invention.

Figure 2.- Shows a top perspective view of the invention device in a previous manufacturing phase in which said device has not been integrated into a rigid support.

Figure 3.- Shows a view in diametral section of the set of the previous figure, in a state of rest.

Figure 4.- Shows a view similar to that of Figure 3, but corresponding to its state in forced position. Preferred Embodiment of the Invention

In view of the fi gures outlined, it can be observed how the electromechanical generating cell that is recommended is obtained from a sheet of flexible material (1) in whose central area, in its manufacturing process a sector (2) with a deformation is defined, in the form of a dome, sector (2) on which a pair of permanent magnets (3) of small thickness, of an elastically deformable nature are established both on its upper face and on its lower face. Concentrically to said assembly, and on at least one of the faces of the sheet of flexible material (1), a plurality of turns (4), of an electrically conductive material, are provided in coil functions that surrounds the magnet assembly (3). ), being able to implant more groups of turns that determine interconnected electrical circuits.

Between the sector (2) and the zone of location of the turns (4) in the sheet piece of flexible material (1) another perimeter deformation (5) is defined, with a concavity opposite to that of the sector (2), in function of a recuperating element, which allows certain axial displacement between both parts containing the magnets and the turns.

The two free terminals or ends of the coil that determine the turns (4) will be connected to respective electrical conduits, not shown in the fi gures, to take advantage of the current generated in the use of the device.

Finally, it should be noted that, as can be seen in Figure 1, the device will be integrated into a rigid support (6), formally dimensionally suited to the specific needs of each case.

From this structuring, and as can be seen in Figures 3 and 4, a state of rest for the device, shown in Figure 3, will be defined, so that by exerting pressure on the sector (2), as shown Figure 4, said sector will be temporarily deformed, the assembly of magnets (3) moving inside the turns (4), and generating an induced current, which will be harnessed through the corresponding electrical conduits associated with them, returning said sector (2) to its original position once the force (7) exerted on it ceases, a maneuver that returns to generate an induced current in the turns (4), equally usable.

For its part, and if the industrial manufacturing of the device is re-located, it can be obtained using the printed electronics manufacturing technique.

More specifically, the substrate or sheet of fl exible material (1) is rolled up in coils and subsequently it will be printed on different parts of the device. Different functional inks are printed on this substrate forming the assemblies of turns and magnets, one or more printing processes being necessary for it, said processes being able to even be carried out in the form of several superimposed layers. After each of these processes, the printed substrate goes through a series of drying phases of the inks or sintering of the inks, which confers on them their definite functional characteristics. After this process the magnets can be subjected to a magnetization process if it is that do not incorporate it previously. Finally, the substrate is subjected to a molded by pressure, heat, or both, to form the definitive characteristic of the device in terms of its dome and shape retrieval elements.

During the previous printing processes, conduits have been established that connect both ends of the set of turns with the output terminals of the generating cell, where it is connected to the consumer system.

Once the previous processes have concluded, the substrate must be cut into pieces that contain one or more generating cells depending on the functionality to which they are intended, which will be housed in a rigid platform or support (6) so that the area of the substrate containing the turns

(4) is firmly supported on it, thus leaving the central area free, which when pressed will perform the energy-generating actions repeatedly cited.

5 ES2351 138A1 6

Claims (5)

one.

Electromechanical generating cell, characterized in that it is constituted from a sheet of flexible material (1) in whose central area, a sector (2) with a deformation, sector (2) is defined on which in at least one of its faces a permanent magnet (3) is established; said assembly being established concentrically, and on at least one of the faces of the sheet of flexible material (1), a plurality of turns (4), of an electric conductive material, in coil functions, forming one or more electrical circuits , defining a perimeter deformation from the location zone of the magnet or magnets, in function of the recovery element, which allows axial displacement between magnets, turns (4) whose ends are connected to respective electrical conduits or output terminals of the generating cell .

2.

Electromechanical generating cell, characterized in that it is constituted from a sheet piece of flexible material (1) in whose central area, a sector (2) with a deformation, sector (2) is defined on which at least one of its faces a plurality of turns is established, of an electrical conductive material, in coil functions, forming one or more electrical circuits; said assembly being established concentrically, and at least one of its faces of the sheet piece of flexible material (1), a permanent magnet, defining a perimeter deformation from the location of the turns in function of recovery element, which allows the displacement axial between turns and magnets, turns whose ends are connected to respective electrical conduits or output terminals of the generating cell.

3.

Electromechanical generating cell according to previous claims, characterized in that it is integrated in a rigid support (6), formally dimensionally suited to the specific needs of each case.

Four.

Procedure for obtaining the electromechanical generating cell of the preceding claims, characterized in that the following production phases are defined therein:

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By one or several printing processes, on the substrate or sheet of flexible material

(1) the different parts of the device are printed from different functional inks forming the sets of turns and the magnets, said processes being able to be carried out in the form of several superimposed layers, as well as the establishment of conduits that connect both ends of the set of turns with the terminals output of the generating cell.

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Submission of the product obtained to a series of drying phases of the sintered ink of the same

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Magnetization of magnets.

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Molded by pressure, heat, or both, to form the shape of the sector (2), as a dome or similar, as well as the perimetral deformation (5) in function of shape retrieval element.

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Cutting of the sheet of flexible material (1) containing several different generating cells depending on the functionality to which they are intended and implantation of them in a rigid platform or support (6).

 ES2351 138A1    ES2351 138A1   SPANISH OFFICE OF THE PATENTS AND BRAND Application no .: 201030736 SPAIN Date of submission of the application: 05/18/2010 Priority Date: REPORT ON THE STATE OF THE TECHNIQUE 51 Int. Cl.: H01H13 / 702 (2006.01) H02K35 / 02 (2006.01) RELEVANT DOCUMENTS

Category

Documents cited Claims Affected

TO

JP 10074426 A (MATSUSHITA ELECTRIC IND CO LTD) 17.03.1998 EPODOC Database. Recovered from EPOQUE; PN JP 10074426 1-4

TO

JP 5276680 A 22.10.1993 EPODOC database. Recovered from EPOQUE; PN JP 5276680 1-4

TO

JP 2009199961 A (CASIO COMPUTER CO LTD) 03.09.2009 EPODOC Database. Recovered from EPOQUE; PN JP 2009199961 1-4

TO

US 3882337 A (FINSTERHOELZL RAFI ELEKT) 06.05.1975 Column 2, line 8-column 3, line 26. US 3036453 A (EXPL DE BREVETS D APP EELECTRON) 29.05.1962 1-4

TO

column 2, line 35-column 4, line 53. JP2005071875 A (MATSUSHITA ELECTRIC WORKS) 17.03.2005 EPODOC database. Recovered from EPOQUE; PN JP 1-4

TO

2005071875 US 2003008602 A1 (KYOUNO TSUNEO) 24.01.2002 Paragraphs [0008] - [0013]; paragraphs [0023] - [0035] 1-4

TO

1-4

Category of the documents cited X: of particular relevance Y: of particular relevance combined with other / s of the same category A: reflects the state of the art O: refers to unwritten disclosure P: published between the priority date and the date of priority submission of the application E: previous document, but published after the date of submission of the application

This report has been prepared • for all claims □ for claims no .: S

Date of realization of the report 24.11.2010

Examiner L. García Aparicio Page 1/5

SPANISH OFFICE OF THE PATENTS AND BRAND Application no .: 201030736 SPAIN Date of submission of the application: 05/18/2010 Priority Date: REPORT ON THE STATE OF THE TECHNIQUE 51 Int. Cl.: H01H13 / 702 (2006.01) H02K35 / 02 (2006.01) RELEVANT DOCUMENTS

Category

Documents cited Claims Affected

To

US2005145472 A1 (POLAR ENGINEERING INC) 07.07.2005 Paragraphs [0008], [0009] and [0015] US 2007102270 A (SONY CORP) 10.05.2007 Paragraphs [0064] - [0100]; Figure 1. 1-4 1-4

Category of the documents cited X: of particular relevance Y: of particular relevance combined with other / s of the same category A: reflects the state of the art O: refers to unwritten disclosure P: published between the priority date and the date of priority submission of the application E: previous document, but published after the date of submission of the application

This report has been prepared • for all claims □ for claims no:

Date of realization of the report 24.11.2010

Examiner L. García Aparicio Page 2/5

REPORT OF THE STATE OF THE TECHNIQUE Application number: 201030736 Minimum documentation searched (classification system followed by classification symbols) H01H, H02K Electronic databases consulted during the search (database name and, if possible, terms of search used) INVENES, EPODOC State of the Art Report Page 3/5  WRITTEN OPINION Application number: 201030736 Date of Written Opinion: Statement

Novelty (Art. 6.1 LP 11/1986)

Claims Claims 1-4 IF NOT

Inventive activity (Art. 8.1 LP11 / 1986)

Claims Claims 1-4 IF NOT

The application is considered to comply with the industrial application requirement. This requirement was evaluated during the formal and technical examination phase of the application (Article 31.2 Law 11/1986).  Opinion Base.- This opinion has been made on the basis of the patent application as published. State of the Art Report Page 4/5  WRITTEN OPINION Application number: 201030736 1. Documents considered.- The documents belonging to the state of the art taken into consideration for the realization of this opinion are listed below.

Document

Publication or Identification Number publication date

D01

JP 10074426 A (MATSUSHITA ELECTRIC IND CO LTD) 17.03.1998

D02

JP 5276680 A 22.10.1993

D03

JP 2009199961 A (CASIO COMPUTER CO LTD) 03.09.2009

D04

US 3882337 A (FINSTERHOELZL RAFI ELEKT) 06.05.1975

D05

US 3036453 A (EXPL OF BREVETS D APP EELECTRON) 05/29/1962

D06

JP2005071875 A (MATSUSHITA ELECTRIC WORKS) 03/17/2005

D07

US 2003008602 A1 (KYOUNO TSUNEO) 01/24/2002

D08

US2005145472 A1 (POLAR ENGINEERING INC) 07.07.2005

D09

US 2007102270 A (SONY CORP) 05.10.2007

2. Statement motivated according to articles 29.6 and 29.7 of the Regulations for the execution of Law 11/1986, of March 20, on Patents on novelty and inventive activity; quotes and explanations in support of this statement The object of the present invention is an electromechanical generating cell, which is formed by a flexible sheet which has the deformed central part on which at least one of its faces is provided with a permanent magnet, and concentrically on the flexible part a plurality of turns, so that displaced the flexible sheet element induces a current on the turns by varying the magnetic field to which the turns are subjected. The alternative embodiment is also part of the invention that a set of turns is arranged in the deformable central part, while a series of magnets are arranged in the perimetral part and concentrically. Based on both embodiments on the same principle, subjecting a set to exhale to a variable magnetic field when acting on the flexible membrane, thus avoiding having to carry power to the push-button, the latter being in charge of generating the necessary current to report that has been pressed. Documents D01 to D06, all of these disclose pushbuttons capable of generating current as a result of the action on the pushbuttons, but nevertheless in all of them except in D01, a spring is used as a recovery element of the original position of the pushbutton. In D01 the position is recovered by means of elastic means in which a permanent magnet is embedded, however no coil is located concentrically in relation to the magnets. Therefore, in view of what is claimed and disclosed in documents D01 to D06, it can be considered that the claimed matter is new as established in Art. 6.1 of LP 11/86 It can also be considered that the matter claimed has inventive activity as established in Art 8.1 of LP 11/86 since the technical problem that the object of the invention would solve in view of the solutions provided by the different embodiments, would be how to design a push button or equivalent means , capable of generating enough energy to report that it has been operated, with the minimum possible volume. Thanks to the use of the flexible membrane, and by embedding or disposing on it, both the permanent magnet and the coils, the actuator element and the recovery element are achieved on the one hand, and all this with the minimum possible volume. Documents D07 to D08, although based on the same principle as that of the invention, refer to pushbuttons that generate a vibration from a received external signal, using the diaphragm as a vibrating element and not as a current generating element . Therefore, it would also have inventive activity as established in Art. 8.1 LP 11/86. State of the Art Report Page 5/5