FI127295B - PROCEDURES FOR THE MANUFACTURE OF SYSTEMS INCLUDING LAYER THIN FILM BATTERIES AND SYSTEMS CONTAINING A THINN MOVIE BATTERY WITH LAYERS CONNECTED TO AN ELECTRONIC DEVICE - Google Patents

Abstract

The layered thin-film battery of the invention is connectable to an external circuit and comprises a cover and an assembly of two or more cells. Each cell has an anode electrode, a cathode electrode with a cathode collector and a cathode collector extension, a separator keeping the electrodes apart, electrolyte and a first substrate. The battery is mainly characterized in that the cells are interconnected through electrical contacts on a second substrate extending over all the cells of the assembly. The electrical contacts are provided by areas of electrically conductive material that is in contact with the electrodes and that is provided by the substrate. The invention is also concerned with a system of the invention comprises such a battery connected to an electronic functional device. Still further, the invention is concerned with methods for manufacturing one or more of such batteries and systems. FIG. 2

Description

METHODS FOR MANUFACTURING A SYSTEM OF LAYERED THIN-FILM BATTERIES AND A SYSTEM COMPRISING A LAYERED THIN-FILM BATTERY CONNECTED TO AN ELECTRONIC DEVICE.

TECHNICAL FIELD

The invention is concerned with a method of manufacturing a serially connected system consisting of units on the same first substrate. Such a unit is a layered thin-film battery cell or an electronic device, whereby the system comprises an assembly of at least two layered thin-film battery cells or at least one layered thin-film battery cell and an electronic device.

BACKGROUND

An electric battery is a device consisting of one or more electrochemical cells that convert stored chemical energy into electrical energy. Each cell contains a negative electrode, which is called an anode, and a positive electrode, which is called a cathode. The battery has a positive cathode and a negative terminal connected to the anode. The basic components of a battery are electrodes with terminals to connect to an external circuit, a separator to keep electrodes apart and prevent them from shorting, an electrolyte which carries the charged ions resulting from the chemical reactions taking place at the electrodes and a cover to contain active chemicals and hold electrodes in place. Electrolytes allow ions to move between electrodes and terminals, which allows current to flow out of the battery to perform work.

All batteries utilize similar procedures to create electricity; however, variations in materials and construction have produced different types of batteries.

One battery type consists of a layered structure, i.e. those called thin film batteries or just thin batteries. The thin film batteries which are termed as "layered-structured" batteries can be deposited directly onto chips or packages or vice versa.

In thin batteries, the cathode typically consists of manganese dioxide and the anode of zinc and the electrolyte of e.g. ammonium chloride and / or zinc chloride dissolved in water but are not restricted to those.

The electrodes in the thin film batteries, especially the cathode, are usually connected to a collector material that receives electrons from the external circuit typically so that the anode collector tabs are associated with the cathode and the whole product is covered in an Envelope cover material. These Collector tabs are generally designed to extend outwardly from the battery cell.

The Collector material is formed to have terminals outside the layers to be connected to an external circuit. The Collector material can be conductive carbon ink, carbon film or other material that is chemically inert but conductive enough for the purpose.

It is possible to vary the total voltage and current in the batteries by connecting them in different ways in the circuit, the two simplest ways of these being called series and parallel connection. Components connected in series are connected along a single path, that is, the same current flows through all of the components. Components connected in parallel are connected so the same voltage is applied to each component.

In this connection it is important to connect the batteries with their terminals in the correct order. Batteries in series need to be connected with positive end of one battery to negative end of next battery. If they are incorrectly connected, the batteries will cancel out each other's energy and quickly flatten each other. Batteries correctly placed in series, positive to negative, will add their output voltages, producing a higher voltage.

Batteries in parallel need to have a connection between the positive ends of both batteries and another connection between the negative ends of both batteries. When connecting in parallel, the capacity (amp hours) of the battery is doubled while maintaining the voltage of the individual batteries.

Several methods have been used for connecting terminals of adjacent cells in a series connection. The terminals may be soldered together and especially cells of the flat type, such as thin film batteries, may be connected together only by physical contact between the surfaces of opposite electrodes of adjacent cells. Nowadays, non-solder conductive solutions are Frequently used especially in a serial connection of cells and a battery pack for e.g. electronic devices can have an anisotropic conductive film that is formed between the battery cells and a connecting bar.

Electrically conductive adhesives, also called electrically conductive tapes, play an increasingly prominent role in the design and production of electronic packages and assemblies. Continuing Improvements in Adhesive Technology Have Adhesives to Replace Solder in Some Specialized Electronic Assembly Applications

Two types of electrically conductive adhesives provide specific benefits where an electrical interconnect is desired. Isotropic conductive materials conduct electricity in all directions equally, and can be used to replace solder on thermally sensitive components. Isotropic materials are used on devices that require a ground path. Anisotropic conductive materials allow electrical current to flow only along a single axis (typically the Z-axis), and provide electrical connectivity and strain relief. All electrically conductive Adhesives provide a chemical bond between two surfaces and they conduct electricity.

Typical electrically conductive adhesive Formulations are made up of an insulating polymer resin that is filled with conductive particles. The resin provides a mechanical bond between two substrates, while the conductive filler particles provide the desired electrical interconnection.

Prior methods exist to use pieces of electrically conductive adhesive tape such as Anisotropic Conductive Film (AFC) to replace soldering and mechanical fasteners between serially connected cells of a battery to reduce assembly time and enable thin device designs. The material is also available in a paste formulated as anisotropic conductive paste (ACP) and both are grouped together as anisotropic conductive paste (ACAs).

The conductive adhesive coating of the tape may be intimately engaging the surfaces of the cell electrodes, to secure contact between the tape segments that are adhesively and electrically connected to the opposite electrodes of adjacent cells.

An example of such a prior art solution for a dry battery with conductive tape intercellular connections is known from US Patent 2,658,098.

Another solution of a battery pack having a coupling between a battery cell and a connecting bar is known from U.S. Patent 8,609,275, which is a welding region formed at a connecting area of a battery cell and a connecting bar. the film formed at the outer periphery of the welding region and connecting the battery cell and the connecting bar to each other. A further prior art solution is disclosed in WO publication 2006/012575. This battery packaging construction eliminates the need for soldering by providing current Collector tabs coated by electrically conductive adhesive tape such as anisotropic z-axis conductive tape or isotropic conductive tape. A piece of electrically conductive isotropic adhesive tape is placed on each current Collector tab or a strip of z-axis anisotropic electrically conductive adhesive tape is placed over and bridging both Collector tabs within one cell.

The object of this invention is an improved solution for the connection of adjacent cells in batteries.

In the following, the invention is described by means of some advantageous embodiments by referring to the figures. The invention is not restricted to the details of these embodiments, which are presented as examples only.

SUMMARY OF THE INVENTION

The method of the invention is intended for manufacturing a serially connected system consisting of units on the same first substrate. Such a unit is a layered thin-film battery cell or an electronic device. The system comprises an assembly of at least two layers of thin-film battery cells or at least one layer of thin-film battery cells and an electronic device. The method comprises providing a first substrate as a platform for the cathode electrodes and the separator to be placed between the anode and the cathode electrodes. Anode electrode part with one or more anodes is prepared. The cathode electrode part with one or more cathodes on the first substrate is also prepared. The anode and cathode parts of the interconnected cells are made separately by printing the layers of the thin-film battery on each other before combining the cathode and anode electrodes to form cells. The units are interconnected by applying a second substrate to extend over all the units of the assembly. The second substrate provides electrical contacts of adjacent cells with electrically conductive material that is in contact with the battery cell (s) and / or the electronic device.

The preferred embodiments of the invention are presented in the sub claims.

In one such preferred embodiment of the invention, the battery and the functional device are positioned on the same first substrate.

The content of the sub claims are incorporated by reference.

The invention is first hand intended for serially connected cells but can be used for cells connected in parallel, too.

Several embodiments are full-filling with the Inventive idea and covered by the main claims. The common Inventive concept is that the cells of the battery are connected via a continuous second substrate that can be ribbon-like or a material sheet. The breadth of the second substrate is that it covers the electrical contact areas between the cells.

It has to be noted that the electrical contacts provided by the areas of electrically conductive material can be provided by the second substrate in different ways.

The second substrate can itself consist of an electrically conductive material, in which case it is preferably a ribbon or sheet of anisotropic tape in accordance with the second embodiment of the invention.

In another alternative, the second substrate is a support for anisotropic tape applied over its entire length. In that case, there are transversal areas of conductive material between the tape and the substrate in accordance with the first embodiment of the invention.

In a further alternative, there are transversal slices of isotropic tape on the second substrate in accordance with the third embodiment of the invention.

In a still further alternative, there are pieces of isotropic tape along the second substrate in accordance with the fourth embodiment of the invention.

The different embodiments will be described in detail in the detailed description part.

The use of a continuous ribbon or sheet has several advantages enabling e.g serial production of cell assemblies, batteries and systems comprising a battery and an electronic device.

The basic components of the battery of the invention are the electrodes that are directly or indirectly via other means connected to an external circuit. In most embodiments, these means consist of terminals, the battery having a positive terminal connected to the cathode and a negative terminal connected to the anode. In some embodiments, the connection to the external circuit is direct and the connection between the conduits between the battery and the external circuit is integral and done in one piece.

As was explained in the background section, each cell of a battery generally contains an anode and a cathode. In the Inventive methods of manufacturing the batteries of the invention, the anode and cathode assemblies of the interconnected cells are made separately to a given stage. Therefore, in this text, the anode and cathode parts of each cell are called "anode units" and "cathode units", respectively, throughout the process of their manufacturing.

In the following, the invention is described by means of several different embodiments mentioned above by means of figures. The invention is not restricted to the details of these embodiments.

FIGURES

Figures 1 a - 1 b illustrate batteries of prior art with serially interconnected cells

Figures 2a - 2b illustrate a first embodiment of a battery manufactured in the invention with serially interconnected cells

Figures 3a-3b illustrate a second embodiment of a battery manufactured in the invention with serially interconnected cells

Figures 4a - 4b illustrate a third embodiment of a battery manufactured in the invention with serially interconnected cells

Figures 5a through 5i illustrate a first embodiment of the invention for manufacturing a battery

Figures 6a through 6e illustrate a second embodiment of the invention for manufacturing a battery

Figures 7a - 7f illustrate a third embodiment of the invention for manufacturing a battery

Figures 8a - 8g illustrates a fourth embodiment of the invention for manufacturing a battery

Figures 9a to 9j illustrate a method of inventing a system comprising a battery manufactured with a first embodiment of the invention connected to an electronic device

Figures 10a through 10j illustrate a method of manufacturing a system comprising a battery manufactured with a second embodiment of an invention connected to an electronic device

Figures 11a-11d illustrate a further embodiment of the invention

DETAILED DESCRIPTION

Figure 1 illustrates a cross-section of a thin battery 1 p of a prior art in which the battery is presented in a plan. The battery 1a comprises an assembly of five cells 2, each built up as a layered structure. Each cell 2 has two electrodes, viz. a negative anode 3, a positive cathode 4 with a cathode Collector 4 'and a cathode Collector extension 5 of e.g. carbon C, Silver Ag, Copper Cu or other suitable conductive material. The cathode Collector 4 'is integrally layered on the cathode 4 and facing the cathode 4. A separator 6, such as a paper separator, keeps the electrodes 3, 4 apart and an electrolyte (not shown) carries the charged ions resulting from the chemical reactions taking place at electrodes 3, 4. Of illustrative reasons, all reference numbers are not noted on each cell being similar.

There is a substrate 7 that extends over the whole assembly and on which cells 2 are positioned. The substrate typically consists of Poly-Ethylene-Terephtalate (PET). In addition, the assembly is surrounded by an outer cover which is not shown as a battery for illustrative purposes presented in a cross-section.

The cells 2 are interconnected through pieces of isotropic conductive tape 8 to provide electrical contact areas between the electrodes 3, 4. One piece of conductive tape 8 contacts the cathode Collector extension 5 of one cell 2 over the end area of the piece of tape 8 and contacts the anode of an adjacent cell 2 over an end area in the other end of a piece of tape 8. The electrical contact areas 9 and 10 of the tape are shown in Figure 1 as Shadowed Areas, reference number 9 showing the contact area between two cells (ie the contact area between the cathode collector extension and one end of the tape 8) and reference number 10 showing the electrical contact area between the anode 3 and the other end of the piece of tape 8. The battery 1 a can be connected to an external circuit through terminals 23 and 24, the positive terminal 23 connecting to the anode 3 and the negative terminal 24 connecting to the cathode 4. Some pieces 8 of the isotropic tape are shown separately b elow the assembly to illustrate that pieces 8 of tape in the battery of prior art consists of separate pieces.

Figure 1b illustrates a cross-section of another thin battery 1 of prior art also showing the inside of the battery in a plane and comprising an assembly of five cells 2, each built up as a layered structure. The reference numbers represent the same things as in figure 1a, the battery being designed a little differently. This battery 1 b of a prior art has an anode extension 14 to which piece of tape 8 is connected.

Thus, the electrical contact areas 9 and 10 shown in figure 1b as the shaded areas are designed so that reference number 9 shows the contact area between two cells (ie the contact area between the cathode collector extension and one end area of tape 8) and reference number 10 showing the electrical contact area between the anode extension 14 and the other end of the piece of tape 8.

Figures 2a - 2b illustrate a first embodiment of the invention for manufacturing a battery 1 b shows a cross-section with an assembly of five serially interconnected cells in a state of manufacture and a part of another battery 1 a.

As in figure 1, there is an assembly of five cells 2 of a layered structure with terminals 23, 24 through which the battery 1 can be connected to an external circuit. Each cell 2 has a negative anode 3, a positive cathode 4 with a cathode Collector 4 'and a cathode Collector extension 5 of e.g. carbon C, Silver Ag, Copper Cu or other suitable conductive material, a separator 6 (such as paper), an electrolyte (not shown) and a substrate 7 that extends over the entire assembly and on which cells 2 are positioned.

In Figures 2a - 2b there is also an additional substrate 11 in the form of a ribbon and it is preferably of the same material as the other substrate 7 such as Polyethylenterephtalate (PET).

Anisotropic conducting tape 12 is layered inside the substrate 11, the anisotropic conducting tape 12 is also extending over all cells 2 of the assembly.

2a to 2b, the electrical contacts are provided by areas of the isotropic conductive material 13 printed between the anisotropic tape 12 and the substrate 11, the conductive material is often called a conductive ink in. the branch. These areas 13 can e.g. without rectangular areas of conductive ink of e.g. carbon C, silver Ag, copper Cu, or other suitable conductive material printed transversally to the substrate 11 and the anisotropic tape 12 on that. The areas 13 are positioned and distributed over the substrate 11 and tape 12 to connect to the cathode Collector extension 5 of one cell and the anode 3 of an adjacent cell. One end 9 of the area 13 of the conductive material contacts the cathode Collector extension 5 of the one cell and the other end 10 of the area 13 of the conductive material contacts the anode of an adjacent cell. The electrical contact areas of the entire area of conductive material are shown in Figure 2a as a Shadowed area in one of the cells 2, reference number 9 showing the contact area between two cells and reference number 10 showing the contact area between the anode 3 and the conductive material 13. The other cells 2 have similar contact areas.

The additional ribbon-like substrate 11 together with the anisotropic tape 12 and the areas of the conductive material 13 together the forms the ribbon 19 fastened on the assembly and it extends over all the cells 2 of the assembly in a way that the interconnecting parts of the cells 2 and the electrical contacts and contact areas are covered by the substrate 11 in a manner shown in figure 2a.

The anisotropic tape 12 conducts electricity in the z-axis direction, thus making an electrical contact between the anode 3 and the isotropic conductive material 13 in the contact area 10, likewise between the cathode Collector extension 5 and the conductive material 13 in the contact area 9 thus creating a serial connection from one battery cell to another. Additionally, there is a similar structure connecting the anode of the last / utmost cell to the negative terminal 24.

For illustrative purposes, the substrate 11 is shown separately in Figure 2b to show how the transversal areas 13 are distributed over the anisotropic tape 12.

One advantage of the battery 1 a of figure 2a is that it is very suitable for being manufactured by serial production. The ribbon 19 with the longitudinal substrate 11 and the anisotropic tape 12 and the areas 13 of the conductive material can be applied over many batteries at the same time, which is shown in Figure 2a, extending over two batteries of serially connected cells. is indicated. For forming the final batteries, the ribbon will be cut between the batteries.

Figures 3a - 3b illustrate a second embodiment of the invention in a manufacturing stage in which the cathodes and the anodes are not yet combined to build up a battery.

Figure 3a presents an anode assembly with five anode units on a substrate 7 'that extends over the entire assembly. Each anode unit (package) comprises an anode 3, an anode collector 3 'with an anode collector extension 14 and a separator 6. The anode collector extension 14 is a suitable conductive material that can be the same or different than the anode and / or anode Collector.

The anisotropic tape 12 alone makes a ribbon 19 fastened on the assembly. It extends over all the anode units of the assembly in a way that the electrical contact areas 10 (of the anode Collector extensions 14) are covered by the ribbon 19 in the distance shown in Figure 3a.

Figure 3b shows a cathode assembly with five cathode units on a substrate 7 that extends over the entire assembly. Each cathode unit comprises a cathode integrally layered on a cathode collector 4 'and a cathode collector extension 5 of e.g. carbon C, Silver Ag, Copper Cu or other suitable conductive material.

The battery 1 b of the second embodiment of the invention is built up by combining the cathodes of figure 3b with the anodes on figure 3a by placing them against eachother. The battery can be connected to an external circuit via the terminals 23 and 24 shown in figure 3b.

The electrical contacts in the battery 1 b constituted by the figures 3a - 3b when combined in the contacts between the anode and the cathode Collector extensions 14, 5 (and between the last anode Collector extension 14 and the negative terminal 24). Thus, an anode Collector extension area 10 of one cell and a cathode Collector extension area 9 of an adjacent cell are directly interconnected and therefore areas of additional conductive material are needed as in the embodiment of Figure 2a. The electrical contact areas 10, 9 formed by the contacts between the anode and cathode Collector extensions 14, 5 are Shadowed in only one anode unit and only one cathode unit in figures 3a and 3b but there are corresponding contact areas in each unit (when the units are combined).

The anisotropic tape conducts electricity in a z-axis direction. The electrical connection is therefore established only through contact areas 9, 10 of substrate 7, 7 '. It acts as an insulator between anode and cathode of the same cell.

The anode units are separated from each other by holes 17 in the substrate to isolate the cells from eachother in the battery to be built.

Figures 4a - 4b illustrate a third embodiment of the invention with an assembly of serially interconnected cells in a state of manufacture. As in figure 1, there is an assembly of five cells 2 of a layered structure with terminals 23, 24 through which the battery 1c can be connected to an external circuit. Each cell 2 has a negative anode 3, a positive cathode with a cathode Collector 4, and a cathode Collector extension 5 of e.g. carbon C, silver Ag, copper Cu or other suitable conductive material, a separator 6 and electrolyte (not shown). A substrate 7 extends over the whole assembly of cells 2.

In the embodiment of the figures 4a to 4b, there is also an additional ribbon-like substrate 21 applied, the additional substrate 21 being positioned to extend over the cells 2 of the assembly in a way that the interconnecting parts of the cells 2 are covered. by the substrate 21 in a way shown in figure 4a.

For illustrative purposes, the substrate 21 is shown separately in Figure 4b to show the extent to which rectangular pieces or slices of isotropic conducting tape 18 are fastened transversally inside the substrate 21 to face the electrodes. The substrate 21 covers those parts of the cells that have electrical contacts.

Rectangular areas of isotropic adhesive material 18 have been printed, laid or placed transversally to the length of the substrate 9 distributed in order to connect the cathode Collector extension 5 of one cell and the anode 3 of an adjacent cell.

The additional substrate 21 together with the isotropic adhesive material 18 forms a ribbon 19 fastened on the assembly and it extends over all the cells of the assembly in the way that the Interconnecting parts of the anode units and the cathode units are covered in the way shown in figure 4a. The ribbon substrate 21 needs to contain a non-conductive adhesive that seals the gap between adjacent cells under the ribbon.

The electrical contacts in the battery formed by the figures 4a - 4b consist of the contacts between the anode 3 and the cathode Collector extension. Thus, an anode contact area 10 of one cell (or an anode extension) and a cathode Collector extension contact area 9 of an adjacent cell are directly interconnected via the isotropic adhesive material 18. The isotropic adhesive material 18 conducts electricity through the thickness (the Z-axis) and the plane of adhesive (X, Y planes), ie providing isotropic XYZ-axis electrical connectivity. The electrical contact areas 10, 9 formed in the end areas of the isotropic tape 18 between the anode and the cathode Collector extension are shaded in only one anode unit and only one cathode unit in figures 3a and 3b but there are corresponding contact areas in each unit as well as in the negative terminal.

One advantage of the battery of figure 4a is that it is very suitable for serial production. The ribbon 19 with the longitudinal substrate 21 and the isotropic tape 18 can be placed over many batteries at the same time which is indicated in figure 4a, with the extension over two batteries being indicated. For making the final batteries the ribbon will be cut between the batteries.

Figures 5a to 5h illustrate an example of a first embodiment of a manufacturing for a battery.

Anode units 3 printed on separator paper 6 presented in figure 5a are prepared by applying anode material by printing or coating in a certain pattern of anode units on a thin film of paste paper 6 that may or may not be wetted with electrolyte . The active anode material can be e.g. zinc and the anode material in the whole can contain additional substances such as conductive carbon, binders and solvents.

The printing can be done by rotary printing on a paper coming from an unwinding roll and can if desired be performed as a continuous process. Another way is to print the anodes by screen printing through a patterned screen so that the anode material is printed through the areas having the desired anode form.

If desired, the anode units can be printed in groups of e.g. five units when the intention is to prepare batteries containing an assembly of five serially connected cells so that the distance between the fifth anode unit is longer than the mutual distance between the other anode units. Such a distance is not necessary but could be greatly enhanced in a later stage.

The anode assembly is then dried and the anode units are cut Apart as shown in figure 5b. The cathode assembly of cathode units presented in figure 5c is prepared by first applying cathode Collector material 4 'by screen printing or coating as a thin film of paste on a Poly-Ethylene-Terephtalate (PET) substrate 7. The printing can be performed by screen printing on a substrate from an unwinding roll and can be performed as a continuous process.

If desired, the cathode units can be printed in groups of e.g. five units when the intention is to prepare batteries containing an assembly of five serially connected cells so that the distance between the fifth cathode unit is longer than the mutual distance between the other cathode units. Such a distance is not necessary but could be greatly enhanced in a later stage.

The cathode units to be formed are also foreseen with the cathode collector extensions 5 which can be printed on the substrate 7 at the same time as the cathode collector 4 'if being of the same material as the cathode collector. Otherwise they are printed separately. Likewise, terminals 23, 24 are formed to the substrate by printing as well and can also be printed at the same time on the substrate if they are of the same material as the cathode Collector 4 '. The cathode units to be formed are then dried.

Thereafter cathode material, e.g. manganese dioxide Mn02, is screen printed on the cathode Collector as a patterned wet paste as shown in Figure 5d.

The anode and cathode assemblies are then combined as indicted by figure 5e by placing them against each other when the cathode material is still wet so that the separator paper layer is between the anode and cathode. The ribbon 19 is illustrated in Figure 5f is then pre-fabricated by providing another PET substrate 11. Areas of suitable isotropic conductive material 13 (such as ink) are then printed transversally to the length of another PET substrate 11. Anisotropic conductive adhesive 12 is then printed / placed over the length of the substrate 11. The PET substrate 11 provides a platform for the conductive material 13 and the support for the conductive adhesive 12. The anisotropic conductive adhesive 12 provides the electrical connection from the cathode Collector extension 5 to the conductive material layer 13 and from layer 13 to the anode 3.

The ribbon 19 is then placed on top of the anodes and cathodes presented in figure 5g and it can extend over all the cells not over those intended to form a single battery. In this way, serially connected batteries can be serially produced without the need to build up a serial connection individually for each cell and not even individually for a given battery.

Ionic separation between adjacent cells is realized by the isolating properties of isotropic conductive adhesive material 12 in the x-y direction. Outside the area of ribbon 19 and tape 12 the separation is realized by sealing material 20.

The electrical contacts are provided by the areas of conductive material 13 co-working with the anisotropic tape 12. These areas 13 can e.g. without rectangular areas of conductive ink, e.g. carbon C, silver Ag, copper Cu or other suitable conductive material printed transversally to the substrate 11 between the substrate 11 and the anisotropic tape 12 on that. The areas 13 are positioned and distributed over the substrate 11 on positions at the cathode Collector extension 5 of one cell and the anode 3 of an adjacent cell. One end 9 of the area 13 of the conductive material contacts the cathode Collector extension 5 of the one cell and the other end 10 of the area 13 of the conductive material contacts the anode of an adjacent cell. The other cells 2 have similar contact areas. A PET sticker to form a cover 20 for the battery is then placed on the assembly of figure 5f as indicated in figure 5h.

Figure 5i illustrates two final batteries 1, one of which can be seen only partially, the batteries each having five cells separated from each other by cutting the substrate 7 and the ribbon 19 between the cells of adjacent batteries.

There are different possibilities to add the electrolyte to the battery. The cathode material can e.g. contain enough electrolyte and / or, in addition, the separator paper can be wetted with the electrolyte after having applied the anode material on it. Even additional separator papers wetted or not wetted with the electrolyte can be added to the battery. As an example, the electrolyte can be zinc chloride ZnCh.

Figures 6a - 6e illustrate an example of a second embodiment of the invention for manufacturing a battery.

An anode assembly of anode units presented in figure 6a is prepared by first applying an anode Collector material 3 'by screen printing or coating as a thin film of paste on a Poly-Ethylene-Terephtalate (PET) substrate 7' in a pattern in order to form separate anodes followed by drying. The printing can be performed on a substrate from an unwinding roll and can be performed as a continuous process.

Next, the anode material 3 is printed or coated on the anode collector areas 3 'as a thin film of paste. The active anode material can be e.g. zinc and the anode material in the whole can contain additional substances such as conductive carbon, binders and solvents. The anode units to be formed are also foreseen with the anode collector extensions 14 which can be printed on the substrate 7 'at the same time as the anode collector 3' if being of the same material as the anode collector 3 'otherwise it is printed separately.

5a to 5i, the anode units can, if desired, be printed in groups of e.g. five units when the intention is to prepare batteries containing an assembly of five serially connected cells. A separator paper 6 without electrolyte is placed on top of the anode assembly of figure 6a and the anode assembly is then dried. A ribbon of suitable anisotropic conductive material (tape) 12is then placed on top of the anode and cathode contacts over the entire assembly and can be extended on consequent assemblies when serial production is performed. In this way, serially connected batteries can be serially produced without the need to build up a serial connection individually for each cell and not even individually for a given battery. In this example of figure 5, the serial connection is built over several batteries at the same time. The cathode assembly of cathode units shown in Figure 6b is prepared by first applying a cathode collector material 4 'by screen printing or coating as a thin film of paste on a Poly-Ethylene-Terephtalate (PET) substrate 7 followed by drying. The printing can be performed on a substrate from an unwinding roll and can be performed as a continuous process.

5a to 5i, the cathode units can be printed in groups of e.g. five units when the intention is to prepare batteries containing an assembly of five serially connected cells.

The cathode units to be formed are also foreseen with the cathode collector extensions 5 which can be printed on the substrate 7 at the same time as the cathode collector 4 'if being of the same material as the cathode collector. Otherwise they are printed separately. Likewise, terminals 23, 24 are formed to the substrate 7 by printing as well and can also be printed at the same time on the substrate 7 if they are of the same material as the cathode Collector.

Thereafter cathode material 4, e.g. manganese dioxide MnO2, is screen printed on the cathode Collector 4 '.

The anode and cathode assemblies are then combined as indicted by figure 6c by placing them against each other so that the anode and cathode collector extensions 14, 5 meet when the cathode material is still wet so that the anode and cathode materials have a separator paper between them.

The electrical contacts in the battery to be prepared as described in the connection with these figures 6a through 6e thus consistently connect the contacts between the anode and the cathode Collector extensions 14, 5 as illustrated by the Shadowed contact areas 9, 10. Thus, the anode collector extension area 10 of one cell and a cathode Collector extension area 9 of an adjacent cell is directly interconnected and therefore no additional areas of conductive material are needed as in the embodiment of Figure 2a. The electrical contact areas 10, 9 formed by the contacts between the anode and cathode Collector extensions 14, 5 are Shadowed in only one anode unit in figure 6a and only in one cathode unit in figure 6b and in only one cell 2 in figure 6c but there are corresponding contact areas in each unit.

The anisotropic tape 12 conducts electricity in a z-axis direction, thus making an electrical contact between anode extension 14 and a cathode collector extension 5 in contact areas 9, 10, thus creating an electrical connection from one battery cell to another. Additionally, there is a similar structure connecting the anode extension of the last / utmost cell to the negative terminal 24. The PET sticker to form a cover 20 for the battery is then placed on the assembly of figure 6c as indicated in figure 6d. The cover is not necessary transparent but is drawn so for illustrative purposes. The cells are now inside the cover and the reference numbers being the same as in figure 6c are not marked in figures 6d and 6e.

The assemblies are then separated from each other by cutting to form the final battery 1 containing five cells 2 as illustrated by figure 6e.

As in the first embodiment, there are different possibilities to add the electrolyte to the battery and the way of introducing the electrolyte is not relevant to the invention.

Figures 7a - 7h illustrate a third embodiment of the invention for manufacturing a battery.

Anode units 3 presented in figure 7a are prepared by applying an anode material by printing or coating in a particular pattern of anode units by a thin film of paste on a separator paper 6. The anode material can be printed by screen printing in which case it can be printed continuously. The active anode material can be e.g. zinc and the anode material in the whole can contain additional substances such as conductive carbon, binders and solvents.

If desired, the anode units can as in figure 7a be printed in groups of e.g. five units when the intention is to prepare batteries containing an assembly of five serially connected cells so that the distance between the fifth anode unit is longer than the mutual distance between the other anode units.

The anode assembly is then dried and the anode units are cut Apart. The cathode assembly of cathode units 4 shown in figure 7b is prepared by first applying the cathode Collector material 4 'by screen printing or coating as a thin film of paste on a Poly-Ethylene-Terephtalate (PET) substrate 7. The printing can be performed on the substrate from an unwinding roll and can be performed as a continuous process.

If desired, the cathode units can be printed in groups of e.g. five units when the intention is to prepare batteries containing an assembly of five serially connected cells so that the distance between the fifth cathode unit is longer than the mutual distance between the other cathode units.

The cathode units to be formed are also provided with the cathode collector extensions 5 which can be printed on the substrate 7 at the same time as the cathode collector 4 'if being the same material as the cathode collector 4'. Otherwise they are printed separately. Likewise, terminals 23, 24 are formed to the substrate 7 by printing as well and can also be printed at the same time on the substrate if they are of the same material as the cathode Collector. The cathode units to be formed are then dried.

Thereafter cathode material, e.g. manganese dioxide Mn02, is screen printed on the cathode Collector 4 'as a patterned wet paste.

The anode and cathode assemblies are then combined as indicted by figure 7c by placing them against each other when the cathode material is still wet so that the anode and cathode materials are on the opposite / different sides of the separator paper layer. A ribbon 19 as illustrated in Figure 7d - 7e is then pre-fabricated by adding areas of isotropic conductive adhesive (such as tape) transversely to the length of another PET sticker substrate 21. The PET sticker substrate 21 provides support for the conductive adhesive material 18 and ionic separation between adjacent cells.

The ribbon 19 is then cut in suitable dimensions as illustrated by figure 7e, and each piece of ribbon is placed on top of the anodes and cathodes presented in figure 7f. The ribbon 19 can extend over all the cells and not only over those intended to form a single battery but also over several cells to form several batteries. In this way, serially connected batteries can be serially produced without the need to build up a serial connection individually for each cell and not even individually for a given battery.

The isotropic conductive adhesive 18 provides electrical connection from the cathode Collector extension 5 to the anode 3 of an adjacent cell.

Thus, an anode contact area 10 of one cell and a cathode Collector extension contact area 9 of an adjacent cell are interconnected via areas of conductive material 18. The electrical contact areas 10, 9 formed by contacts between the anode 3 and conductive adhesive material 18, likewise between cathode Collector extension 5 and conductive adhesive material 18 are indicated in only one anode unit and only one cathode unit but there are corresponding contact areas in each unit (when units are combined). The PET sticker 20 to form a cover for the battery is then placed on the assembly of figure 7f as indicated in figure 7g.

Figure 7h illustrates the final battery 1, the batteries, each containing five cells 2 separated from each other by cutting.

As in the first and second embodiments, there are different possibilities to add the electrolyte to the battery and the way of introducing the electrolyte is not relevant for the invention. Also one or more separators can be other than paper in all the embodiments.

Figures 8a through 8h illustrate a fourth embodiment of the invention for manufacturing a battery.

Anode units 3 presented in figure 8a are prepared by applying an anode material 3 by printing or coating in a particular pattern of anode units as a thin film of paste on a separator paper 6. The active anode material can be e.g. zinc and the anode material in the whole can contain additional substances such as conductive carbon, binders and solvents. The printing can be performed on the substrate from an unwinding roll and can be performed as a continuous process or then the printing is performed by screen printing.

The anode units to be formed are also provided with anode extensions 14 which can be printed on the separator 6 at the same time as the anode material if being of the same material otherwise it is printed separately.

If desired, the anode units can be printed in groups of e.g. five units when the intention is to prepare batteries containing an assembly of five serially connected cells so that the distance between the fifth anode unit is longer than the mutual distance between the other anode units.

The anode assembly is then dried and the anode units are cut Apart. The cathode assembly of cathode units presented in figure 8b is prepared by first applying the cathode Collector material 4 'by screen printing or coating as a thin film of paste on a Poly-Ethylene-Terephtalate (PET) substrate 7. The printing can be performed on the substrate from an unwinding roll and it can be performed as a continuous process.

If desired, the cathode units can be printed in groups of e.g. five units when the intention is to prepare batteries containing an assembly of five serially connected cells so that the distance between the fifth cathode unit is longer than the mutual distance between the other cathode units.

The cathode units to be formed 4 are also provided with the cathode collector extensions 5 which can be printed on the substrate 7 at the same time as the cathode collector 4 'if being of the same material as the cathode collector 4'. Otherwise they are printed separately. Likewise, terminals 23, 24 are formed to the substrate by printing as well and can also be printed at the same time on the substrate if they are of the same material as the cathode Collector. The cathode unit is then dried.

Thereafter cathode material, e.g. manganese dioxide Mn02, is screen printed on the cathode Collector 4 'as a patterned wet paste.

The anode and cathode assemblies are then combined as indicated by figure 8c by placing them against each other when the cathode material is still wet so that the anode and cathode materials have a separator paper layer between them. A ribbon 19 as illustrated in figure 8d is then pre-fabricated by placing isotropic conductive adhesive 18 (such as ink) over the length of another PET sticker substrate 21, the adhesive part being Narrower than the ribbon. Holes 22 through ribbon and conductive adhesive wider than conductive adhesive region but Narrower than ribbon are processed. The substrate 21 provides a platform for the conductive adhesive material 18. The isotropic conductive material 18 provides the electrical connection from the cathode Collector extension 5 of one cell to the anode extension 14 of an adjacent cell. The holes 22 in the ribbon 19 and in the isotropic tape 18 provide electrical insulation between the electrodes of the same cell and between adjacent batteries.

The electrical contacts when the anode and cathode assemblies are combined consist of the contacts between the anode extension 14 and the cathode Collector extensions 5. Thus, an anode extension of one cell and a cathode Collector extension of an adjacent cell are interconnected via a piece of conductive adhesive material 18. The electrical contact areas 10, 9 formed by the contacts between the extensions 14, 5 and the conductive tape 18 are indicated in only one anode unit and only one cathode unit but there are corresponding contact areas in each unit.

The ribbon 19 is then placed on top of the anode and cathode extensions 14.5 presented in figure 8e with the adhesive side facing the electrodes. The ribbon 19 can extend over all the cells not only over those intended to form a single battery. In this way, serially connected batteries can be serially produced without the need to build up a serial connection individually for each cell and not even individually for a given battery. The PET sticker 20 to form a cover for the battery is then placed on the assembly of figure 8e as indicated in figure 8f. Ionic separation between adjacent cells is realized by isolating properties of PET sticker substrate 21 of ribbon 19. Outside area of ribbon 19 and within holes 22 separation is realized by sealing material 20.

Figure 8g illustrates the final battery 1, the batteries, each containing five cells 2 separated from each other by cutting.

As in the first and second embodiments, there are different possibilities to add the electrolyte to the battery and the way of introducing the electrolyte is not relevant for the invention. Also one or more separators can be other than paper in all the embodiments.

Figures 9a through 9j illustrate a method of manufacturing a system comprising a battery manufactured with a first embodiment first connected to an electronic device.

Anode units 3 printed on separator paper 6 presented in figure 9a are prepared by applying anode material by printing or coating in a particular pattern of anode units as a thin film of paste on the separator paper 6 that will be wetted with electrolyte in a lateral stage. The active anode material can be e.g. zinc and the anode material in the whole can contain additional substances such as conductive carbon, binders and solvents.

The printing can be done by rotary printing on a paper coming from an unwinding roll and can if desired be performed as a continuous process. Another way is to print the anodes by screen printing through a patterned screen so that the anode material is printed through the areas having the desired anode form.

If desired, the anode units can be printed like in figure 9a in groups of e.g. five units when the intention is to prepare batteries containing an assembly of five serially connected cells so that the distance between the fifth anode unit is longer than the mutual distance between the other anode units. Such a distance is not necessary but could be greatly enhanced in a later stage.

The anode assembly is then dried and the anode units are cut Apart as shown in figure 9b. The cathode assembly of cathode units presented in figure 9c is prepared by

First: applying wiring of the intended electronic circuit material by screen printing or coating as a thin film of paste on a Polyethylene-Terephtalate (PET) substrate 7, including drying. The printing can be performed on a substrate from an unwinding roll and can be performed as a continuous process.

Second: cathode Collector extensions 5 are printed on the substrate 7 at the same time as electronics wiring if being of the same material as that wiring. Otherwise they are printed separately.

Third: cathode Collector material is applied by screen printing and dried.

If desired, the cathode units can be printed in groups of e.g. five units when the intention is to prepare batteries containing an assembly of five serially connected cells so that the distance between the fifth cathode unit is longer than the mutual distance between the other cathode units. Such a distance is not necessary but could be greatly enhanced in a later stage.

One or more electronic components 27 are then printed or assembled on the same substrate 7. The connection between the terminals 23, 24 and the conductors 25, 26 can be integral in which case there are no separate terminals 23, 24. components 27 can suitably be eg a Microcontroller, Light-Emitting-Diode (LED) light source, or a temperature meter.

The cathode units to be formed are then dried.

Thereafter cathode material, e.g. manganese dioxide Mn02, is screen printed on the cathode Collector as a patterned wet paste as shown in Figure 9d.

The anode and cathode assemblies are then combined as indicted by figure 9e by placing them against each other when the cathode material is still wet so that the separator material 6 is between the anode and cathode materials. The anode and cathode materials are outmost, respectively. A ribbon 19 as illustrated in figure 9f is then pre-fabricated as in figure 5f by printing areas of suitable isotropic conductive material 13 (such as ink) transversally to the length of another PET substrate 11. Anisotropic tape 12 is then applied over the length of another PET substrate 11 on which tape there are areas of conductive material 13. The ribbon 19 is then placed on top of the anodes and cathode Collector extensions presented in Figure 9g and it can extend over all cells not only over those intended to form a single battery. In this way systems of serially connected batteries can be serially produced. The contacts between the cells are built up the same way as in FIG 2. The contact between the utmost cell and the electronic device is similar, being between the utmost cell and the terminal 24 that can be integral with the conductor 26.

Additionally, there is a similar structure connecting the anode of the last / utmost cell to the negative terminal 24. A PET sticker to form a cover of 20 for the battery is then placed on the assembly of figure 9g as indicated in figure 9h.

Figures 9i -9j illustrate two final systems, one of which can be seen only partially. The systems each containing five cells 2 and an electronic device 27 have been separated from each other by cutting into shape the substrate 7, the cover 20, and the ribbon 19.

Figures 10a through 10g illustrate a method of manufacturing a system comprising a battery manufactured with the second embodiment connected to an electronic device.

Figure 10 illustrates a first phase of a method of wiring for electronic devices or electronic components by printing conductors 25, 26 and other associated conductors on a substrate 7 '. Battery terminals 23, 24 do not exist as separate elements, but they have been depicted for comparison with other embodiments.

Anode Collector extensions 14 and anode Collectors 3 'are printed on the substrate 7' as well.

In figure 10b, an anode assembly of anode units is then prepared by applying anode material 3 by screen printing or coating as a thin film of paste on anode collectors 3 '. Next, a separator layer 6 is placed on the anode and drying of the assembly is then performed. The separator will be wetted with an electrolyte in a later stage. The active anode material can be e.g. zinc and the anode material in the whole can contain additional substances such as conductive carbon, binders and solvents.

In figure 10c, the electronic components 27 are printed or assembled on the same substrate 7 'to be connected to the wiring performed in figure 10 a.

In figure 10d, the cathode collector material 4 'and the cathode collector extensions 5 are screen printed on another polyterephthalate (PET) substrate 7, followed by drying.

An assembly of cathode collectors 4 'is then cut off from the substrate 7 in a manner that the individual cathode collectors 4' are separated from each other as indicated in figure 10e.

In figure 10f, conductive material is applied on the cathode extensions 5. For this step, there are three alternatives:

In the first alternative, which is described in figure 10f, the conductive material is applied in the form of a ribbon of anisotropic conductive tape to extend over the entire assembly. In this, alternative, the battery in the final system corresponds to the second implementing.

In the second alternative, pieces of isotropic tape are applied between the cells between the cathode Collector extension 5 of one cell and the anode extension of an adjacent cell. In this alternative, the battery in the final system corresponds to the prior art battery of figure 1. This method to prepare the prior art battery of figure 1 and the method described by figures 10a - 10j, in which the second alternative is used, are Inventive methods and a part of the invention.

In the third alternative, the conductive material pads of the anisotropic or isotropic conductive material are applied in the form of the paste, followed by the paste drying process.

The ribbon of anisotropic conductive adhesive tape 12 of suitable conductive material can be extended on consequent assemblies when serial production of systems is performed.

In figure 10g, cathode material 4 is printed over the separator layer 6 of the anode assembly with the electronic device 27.

In figure 10h, the cathode collector sheet of figure 10f is placed over the anode assembly sheet so that the electrical contact areas between the battery cells and the electronics are established via the conductive tape. The electrical contacts for the different alternatives are described in e.g. figures 1 -3. The PET sticker to form a cover 20 for the battery is then placed on the battery of figure 10h as indicated in figure 10i. The cells are now inside the cover and the reference numbers being the same as the foregoing figures are not marked.

As with all the embodiments described, there are different possibilities to add the electrolyte to the battery and the way of introducing the electrolyte is not relevant for the invention.

Figures 11a through 11 illustrate a further embodiment of the invention.

It presents another design in that there are two units in each system, one being a battery and the other being an electronic device instead of a second battery.

Figure 11a, presents two systems of invention in a state of manufacture. Each system consists of a battery with an anode and a cathode which is connected in series to an electronic device in a way of invention on the same substrate 7 with the other systems. Several systems can be manufactured on the same substrate but figures 11a - 1d show only two of illustrative reasons.

The connection between the battery and the electronic device can be realized as in figure 1 or in accordance with the other embodiments of the invention and consists of one integral connection to the conductors of the battery and one connection performed e.g. through a piece of isotropic conductive tape 8 to provide electrical contact areas between the electrode of the battery and the electronic device. One piece of conductive tape 8 contacts the anode of the battery over an end area of the piece of tape 8 and the contacts of the electronic device over the end area in the other end of the piece of tape 8. The electrical contact areas 9 and 10 of the tape are shown in figure 11b as Shadowed areas, reference number 10 showing the contact area of the anode (ie the contact area between the anode and one end area of the tape 8) and reference number 9 showing the electrical contact area between the electronic device and the other end of the piece of tape 8.

The ribbon 19 is on top of both the battery and the electronic device extending over these. The ribbon 19 has areas of suitable isotropic conductive adhesive material 8 applied transversally to the length of a PET sticker substrate 21.

In figure 11 b, A PET sticker to form a cover 20 for the battery has been placed on the assembly of figure 11a.

Figure 11c illustrates the final systems. The systems, each containing two units, one battery and one electronic device have been separated from each other by cutting into shape the substrate 7, the cover 20, and the ribbon 19.

Figure 12 shows a further development of the invention in a state of manufacture. In this embodiment, the desired number of systems comprising an electronic device and two batteries of the invention (connected to each other in figure 1 but could be realized in accordance with the other embodiments of the batteries of the invention) are serially produced.

The following reference numbers have been used in the figure pages

Claims (18)

A method for manufacturing a series connected system consisting of units on the same diaphragm (7), the unit being a thin-film battery cell (2) or an electronic device (27), comprising at least two Comprising a separator (6) between the anode (3) and the cathode (4) electrodes, the assembly of 5 thin-film battery cells (2) or at least one thin-film battery cell and electronic device (27), the method comprising using a first film (7) as a cathode electrode support; making an anode (3) electrode part having one or more anodes, ίο making a cathode (4) electrode part having one or more cathodes on the first diaphragm (7), whereby the anode and cathode parts of the interconnected cells are made by pressing the thin film battery layers overlapping before the cathode (4) and anode (3) electrodes are connected, characterized in that the units (2, 27) are interconnected by placing one membrane (7 ', 11, 21) over all the units of the second membrane, (7 ', 11, 21) providing electrical contacts (9, 10) of adjacent cells having areas of electrically conductive material in contact with the ston cell (s) (2) and / or 20 electronic devices (27). Method according to Claim 1, characterized in that the electrically conductive binder / tape (12, 18) is applied to act as the electrically conductive substance on the second film (11, 21). Method according to Claim 1, characterized in that the anode current collector (3 ') and / or the anode current collector extension (14) is pressed against the anode (3). Method according to claim 1 or 2, characterized in that 30 pre-fabricating the tape (19) or sheet by positioning the anisotropic conductive binder / tape (12) along the length of the second film (11) and pressing regions of the conductive material (13) transverse to the second film (11), dimensioning and dividing 9, 10) and 20146140 prh 20 -04-2017 by positioning the ribbon (19) or plate on the cell assembly such that the printed areas and the cathode current collector of one cell (2) anode (3), anode current collector extension (14) or anode extension and adjacent cell (2) said areas of electrical contacts (9, 10) of the extension (5) meet. Method according to claim 4, characterized in that areas of the conductive material (13) transverse to the length of the conductive tape (12) are arranged to form electrical contact areas (9, 10) which are distributed to contact one anode of the cell (2). the anode collector extension (14) or the anode extension and the adjacent cell (2) cathode extension (5). Method according to claim 1 or 3, characterized in that an anisotropic binder / tape (12) is used as the second film (11) to act as an electrically conductive substance. Method according to Claim 1,3 or 5, characterized in that an anisotropic binder / tape (12) is used in the form of a strip (19) or a sheet and placed over the cells (2) thereby connecting the electrical contact areas (9, 10), and followed by placing a strip (19) or plate on top of the anode assembly comprising 20, and connecting the anode assembly to the cathode assembly so that the electrical contact areas (9, 10) between the cathodes (4) and the anodes (3) meet. A method according to claim 1 or 2, characterized in that the tape (19) or sheet is prefabricated by applying an isotropic binder / tape (18) Regions transverse to the second film (21), dimensioning and dividing these regions to face electrical contact areas (9, 10) of adjacent cells (2), and then positioning the strip (19) or plate on the cell assembly such that said regions and one cell (2) anode (3), anode extender (14) or anode extender and adjacent cell (2) cathode extender (5) 30 electrical contact areas (9, 10) meet. A method according to claim 1 or 2, characterized in that the tape (19) or sheet is prefabricated by placing regions of the isotropic conductive binder / tape (18) over the length of the second film (21), such that The electrical contact areas (9, 10) of the 35 cells (2) are isolated from one another, after which 20146140 prh 20 -04-2017 a strip (19) or plate over the cell assembly such that said areas and the electrical contact areas (9, 10) of adjacent cells (2) meet. Process according to claim 1 or 2, characterized in that 5 pre-fabricating the tape (19) or sheet by positioning areas of the isotropic conductive binder / tape (18) along the length of the second film (21) and making holes (22) in the film (21) and tape (18) so that the holes (22) the electrical contact areas (9, 10) of one cell (2) are isolated from each other, whereupon a strip (19) or plate is placed on the cell assembly (comprising the anode (3) and cathode (4) units) so that the adjacent cells (2) ) contact areas (9, 10) are interconnected via the remaining conductive binder. Method according to claim 10, characterized in that longitudinal regions of the isotropic conductive binder / tape (18) are applied to the film (21). 15 to form electrical contacts (9, 10) by contacting the anode extension of one cell (2) or the anode current collector (14) at one end of the region or the cathode current extension (5) of the adjacent cell (2) at the other end of the region. 20 Method according to one of Claims 1 to 11, characterized in that a final pristo is produced by placing the cover (20) over the cell assembly after the cathode (4) and anode (3) units are combined and after the second diaphragm (11, 21) is positioned over the cells (2). 25 A method according to any one of claims 1 to 11, characterized in that two or more batteries are serially produced, such that an amount of anode (3) units are produced to produce the batteries by pressing all of these anode (3) ) units for the common separator (6) and thereafter dried, a corresponding number of cathode (4) units are prepared by pressing the cathode current collector (4 ') on the common membrane (7) and then drying and then printing the cathode (4) material and cathode (4) extension material for the dried cathode (4) units, combining the cathode (4) and anode (3) units to form the cells (2), interconnecting the cells (2) by placing a second membrane (11,21) over each of their cells ( 2) over the number corresponding to the number of batteries to be manufactured, the second film (11, 21) providing electrical contacts (9, 10) with the conductive material; The pin is in contact with the electrodes, producing the final batteries by placing a cover (20) around all cathode (4) and anode (3) units, cutting the cells (2) apart into assemblies intended to be provided in individual batteries to produce final batteries. Method according to Claim 10, characterized in that the number of anodes (3) and cathodes (4) which are to be contained in each battery are determined and printed on the anode (3) material and the cathode (4) material according to a defined number. 15 groups. Method according to claim 10, characterized in that assembly is carried out by placing an optional electronic device on the first film (7) before the anode and cathode electrodes are combined. Method according to claim 13, characterized in that the conductors (25, 26) of the electronic device (27) of the first diaphragm (7) are pressed together with the cathode (4) or cathode current collector extension (5), whereby the device is integral with the battery. 25 Method according to claim 13, characterized in that in the embodiment in which the anode units (3) are manufactured on the first film (7), the electronic device (27) is placed on the first film (7) during assembly. The method of claim 13, further characterized in that In an embodiment wherein the cathode units (4) are fabricated on the first membrane (7), the electronic device (27) is positioned upon assembly on the first membrane (7). 20146140 prh 20 -04- 2017 1/16 20146140 prh 22 -12- 2014 CO ^^ COK- CO st CO PRIOR ART 2/16