Device for storing and / or converting energy and method for manufacturing such a device

HK40134671APending Publication Date: 2026-07-10GRAPHENANO ENERGY SL +1

Patent Information

Authority / Receiving Office
HK · HK
Patent Type
Applications
Current Assignee / Owner
GRAPHENANO ENERGY SL
Filing Date
2026-04-15
Publication Date
2026-07-10

AI Technical Summary

Technical Problem

In existing energy storage devices, the use of metal current collectors as conductive supports for electrodes leads to increased weight, reduced energy density, and high cost. Furthermore, thin metal current collectors are fragile and easily damaged during manufacturing.

Method used

Electrodes are formed on both sides of the membrane using ink containing graphene fibers. The membrane itself acts as a current collector, replacing the traditional metal current collector, and the graphene fibers provide conductivity.

Benefits of technology

It increases energy density, reduces overall equipment mass and cost, minimizes oxidation of metal current collectors, and enhances equipment stability and environmental friendliness.

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Abstract

The device for storing and / or converting energy (1) comprises one or more spacers (2) defining two sides; and electrodes (3) in contact with one or both sides of the spacer (2), each electrode (3) comprising an ink including at least one conductive additive. The method comprises the following steps: preparing an ink, the ink comprising at least one conductive additive; and forming electrodes (3) with the ink, the electrodes (3) being in contact with one or both sides of one or more spacers (2). It allows the separator itself to act as a collector at the same time, providing a solution to the problem of oxidation of metal collectors, among others.
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Description

(19) *EP004632776A1* (11) EP 4 632 776 A1 (12) EUROPEAN PATENT APPLICATION published in accordance with Art. 153(4) EPC (43) Date of publication: 15.10.2025 Bulletin 2025 / 42 (21) Application number: 22850574.9 (22) Date of filing: 05.12.2022 (51) International Patent Classification (IPC): H01G 11 / 52 (2013.01) H01G 11 / 02 (2013.01) H01G 11 / 06 (2013.01) H01G 11 / 38 (2013.01) H01G 11 / 50 (2013.01) H01G 11 / 86 (2013.01) H01M 4 / 04 (2006.01) H01M 4 / 139 (2010.01) H01M 4 / 62 (2006.01) H01M 10 / 0525 (2010.01) H01M 10 / 058 (2010.01) H01M 50 / 46 (2021.01) H01G 11 / 36 (2013.01) H01G 11 / 84 (2013.01) H01M 50 / 417 (2021.01) H01M 50 / 429 (2021.01) C09D 11 / 52 (2014.01) (52) Cooperative Patent Classification (CPC): H01M 4 / 625; C09D 11 / 52; H01G 11 / 02; H01G 11 / 06; H01G 11 / 38; H01G 11 / 50; H01G 11 / 52; H01G 11 / 86; H01M 4 / 0409; H01M 4 / 139; H01M 10 / 0525; H01M 10 / 058; H01M 50 / 46; H01G 11 / 36; H01G 11 / 84; (Cont.) (86) International application number: PCT / ES2022 / 070779 (87) International publication number: WO 2024 / 121442 (13.06.2024 Gazette 2024 / 24) (84) Designated Contracting States: AL AT BE BG CH CY CZ DE DK EE ES FI FR GB GR HR HU IE IS IT LI LT LU LV MC ME MK MT NL NO PL PT RO RS SE SI SK SM TR Designated Extension States: BA Designated Validation States: KH MA MD TN (71) Applicants: • Graphenano Energy, S.L. 30510 Yecla (Murcia) (ES) • Universitat De València, Estudi General 46010 València (ES) (72) Inventors: • ROMERO PASCUAL, Jorge 46010 VALENCIA (ES) • ABELLÁN SÁEZ, Gonzalo 46010 VALENCIA (ES) • CORONADO MIRALLES, Eugenio 46010 VALENCIA (ES) • SERNA GUIJARRO, Raúl 46010 VALENCIA (ES) • SIMÓN GARCIA, María 30510 YECLA (Murcia) (ES) • MOLERO CAMPOS, Rafael 30510 YECLA (Murcia) (ES) • MARTINEZ ROVIRA, Martín 30510 YECLA (Murcia) (ES) (74) Representative: Herrero & Asociados, S.L. Edificio Aqua - Agustín de Foxá, 4‑10 28036 Madrid (ES) (54) DEVICE FOR STORING AND / OR CONVERTING ENERGY AND METHOD FOR MANUFACTURING SUCH A DEVICE (57) The device for storing and / or converting energy (1) comprises one or more spacers (2) defining two sides; and electrodes (3) in contact with one or both sides of the spacer (2), each electrode (3) comprising an ink including at least one conductive additive. The method comprises the following steps: preparing an ink, the ink comprising at least one conductive addi- tive; and forming electrodes (3) with the ink, the electro- des (3) being in contact with one or both sides of one or more spacers (2). It allows the separator itself to act as a collector at the same time, providing a solution to the problem of oxida- tion of metal collectors, among others. EP 4 63 2 77 6 A 1 Processed by Luminess, 75001 PARIS (FR) (Cont. next page) (52) Cooperative Patent Classification (CPC): (Cont.) H01M 50 / 417; H01M 50 / 4295; Y02E 60 / 10 2 EP 4 632 776 A1 3 1 EP 4 632 776 A1 2 Description Object of the invention

[0001] The present invention relates to a device for storing and / or converting energy and to a method for manufacturing such a device for storing and / or convert- ing energy. Background to the invention

[0002] Currently, energy storage devices comprise metallic collectors as the conductive support for their electrodes, since the electrodes do not have enough conductivity to function properly.

[0003] One of the biggest problems in energy storage devices are these collectors, since, being the metal part, it is the part that increases its weight the most, thus reducing its energy density.

[0004] At the same time, collectors are one of the most expensive parts of a battery, especially nowadays, with the problem of sourcing materials and their geolocation.

[0005] The solutions that have been considered so far have been to reduce the thickness of the collector as much as possible in order to reduce weight and price, but metal collectors are still present.

[0006] In addition, this partial solution of reducing the thickness and weight of the collectors can generate problems in the manufacturing processes, as when the collectors are so thin they are very fragile and can break on the production line during printing and assembly, with the economic cost of stopping production and bringing the machinery back up to speed after removing the broken part. Description of the invention

[0007] With the device for storing and / or converting energy and the method of the invention, the aforemen- tioned disadvantages are solved, presenting other ad- vantages that will be described below.

[0008] Therefore, an objective of the present invention is to provide a device for storing and / or converting energy and a method for depositing the electrode on the separa- tor, causing the separator itself to act as a collector, and providing a solution to the problem of oxidation of metal collectors, among others.

[0009] These objectives are achieved by hybridizing the inks with graphene fibers, which provide the neces- sary conductivity to the electrode without the use of a metal collector.

[0010] The device for storing and / or converting energy and method according to the present invention are de- scribed in the respective independent claims, and the dependent claims include additional features that are optional.

[0011] It should be noted that in the present description and claims, the term separator refers to any type of material which physically separates one material from another, such as, for example, the cathode and anode in a battery.

[0012] It should be noted that in the present description and claims, the term device for storing and / or converting energy refers to any type of device for storing and con- verting energy, such as, for example, lithium, sodium, potassium batteries, whether ion or solid-state, metal-air, organic, etc., fuel cells, electrolysers, etc.

[0013] According to a first aspect, the device for storing and / or converting energy comprises: - one or more separators defining two sides; and - electrodes in contact with one or both sides of the separator, each electrode comprising an ink includ- ing at least one conductive additive.

[0014] Preferably, the conductive additive comprises graphene fibers.

[0015] In addition, the ink advantageously also com- prises a binder, active materials and solvents.

[0016] Preferably, the separator is made of cellulose, plastic, or glass fiber.

[0017] According to a second aspect, the method for manufacturing a device for storing and / or converting energy comprises the following steps: - preparing an ink, the ink comprising at least one conductive additive; and - forming electrodes with said ink, the electrodes being in contact with one or two sides of one or more spacers.

[0018] According to a preferred embodiment, the elec- trodes are formed by applying the ink directly to the two sides of the separator. In this case, preferably, the ink is first applied to a first side of the separator, it is dried, and once the ink has dried, the ink is applied to a second side of the separator, and it is dried.

[0019] According to an alternative embodiment, the electrodes are formed on a support and, once formed, they are placed in contact with the two sides of the separator.

[0020] If desired, the method may also comprise a final stage of cutting the assembly of the separator and the two electrodes.

[0021] The device for storing and / or converting energy according to the present invention is very versatile, and provides several advantages, such as: - Higher energy density: by avoiding the use of me- tallic collectors, the total mass is considerably re- duced and, consequently, the energy density per kilogram is improved. - Decrease of the final price: one of the most expen- sive parts in devices for storing and / or converting energy are the metallic collectors. As these collec- 5 10 15 20 25 30 35 40 45 50 55 4 3 EP 4 632 776 A1 4 tors are no longer needed (at least partially), and as they are replaced by one or more separators that can be made of different materials such as: cellulose (paper), polymers (e.g., polypropylene), fibers (e.g., ceramic, glass, carbon...), the components of the devices are simplified, reducing the cost. - Collector oxidation / reduction problems are mini- mized. Both when the electrolyte solvent is organic and, to a greater extent, when using water-based electrolytes - which are much more environmentally friendly and economical - degradation of the collec- tors can drastically affect the stability of the devices.

[0022] All these advantages make the device for stor- ing and / or converting energy and method according to the present invention better and cheaper than current devices for storing and / or converting energy. Brief description of the drawings

[0023] For a better understanding of what has been explained above, drawings are included in which, sche- matically and only as a non-limiting example, a practical case of embodiment is shown. Figure 1 is a diagrammatical sectional view of an energy storage device according to the present in- vention; Figure 2 shows a charge-discharge cycle in a LFP versus Li metal half-cell using conventional current collectors (Aluminum) and as electrolyte: LiPF6 1 M EC / EMC=50 / 50 (v / v). Figure 3 shows a charge-discharge cycle in a semi- cell of LFP versus Li metal using the new method described above on the polypropylene separator and using as electrolyte: LiPF6 1 M EC / EMC=50 / 50 (v / v). Figure 4 shows a charge-discharge cycle in a gra- phite versus Li metal half-cell using conventional current collectors (Copper) and as electrolyte: LiPF6 1 M EC / EMC=50 / 50 (v / v). Figure 5 shows a charge-discharge cycle in a gra- phite versus Li metal half-cell using the new method described above on the polypropylene separator and using as electrolyte: LiPF6 1 M EC / EMC=50 / 50 (v / v). Figure 6A shows 10-hour charge and discharge cycles of a lithium-ion button cell using aluminum and copper collectors for the cathode and anode, respectively, with a cellulose separator. Device: stainless steel button cell; cathode: commercial LFP on aluminum collector with conductive carbo- naceous materials; anode: commercial synthetic graphite on copper collector with conductive carbo- naceous materials; electrolyte: LiPF6 1 M EC / EMC=50 / 50 (v / v). Figure 6B shows charging and discharging cycles for 10 hours in a lithium-ion button cell using the new method described above on the cellulose separator and using as electrolyte: LiPF6 1 M EC / EMC=50 / 50 (v / v). Description of a preferred embodiment

[0024] The device for storing and / or converting energy according to the present invention, identified generally by reference number 1, comprises a spacer 2 on which an ink with graphene fibers is applied on its two sides, forming two electrodes 3, as shown schematically in figure 1.

[0025] In this way, it is the separator 2 itself that also acts as a collector, providing a solution to the problem of oxidation of metal collectors, among others. Thus, inks with graphene fibers provide the necessary conductivity to electrode 3 without the use of a metal collector.

[0026] The separator 2 on which the ink is applied can be any material used in devices for storing and / or con- verting energy, such as cellulose in capacitors, plastic or glass fiber separators in lithium batteries, metal mesh, etc.

[0027] It should be noted that the device shown sche- matically in figure 1 is only a non-limiting example, as the device according to the present invention can be double spacer, have two spacers printed only on one side, spacers on a support, etc.

[0028] The method of manufacture according to the present invention starts with the preparation of the ink which is applied on the separator 2.

[0029] This ink is prepared using a binder, solvents, conductive additives and active materials. All existing binders can be used to prepare the ink, the most common being polyvinylidene fluoride (PVDF) and styrene-buta- diene rubber (SBR).

[0030] The percentage of such binders may change, for example, from 0.1 % to 40 % by total mass of the ink. Solvents that can be used for printing are also any, for example, N-methyl‑2-pyrrolidone (NMP), water or alco- hols.

[0031] Regarding conductive additives, conductive carbonaceous materials are used, either only one or a combination of several, e.g., carbon black, graphene fibers, carbon nanotubes, graphitic carbon, etc. The amount of conductive additives can change from 0.1 % to 40 % by total mass of the ink.

[0032] Once the binder has been dissolved in the solvent and the rest of the materials have been added, the ink is homogenized with a special system for this purpose, such as a ball mill, shear mill, vacuum agitator, or similar. 5 10 15 20 25 30 35 40 45 50 55 5 5 EP 4 632 776 A1 6

[0033] The ink is then applied to one side of the se- parator 2 to form an electrode 3.

[0034] This application can be done with any process, e.g. a doctor blade to apply the ink on the separator 2, but it can also be applied with systems such as lamination, ink jet, etc. Using a doctor blade, the ink can be applied on the cellulose separator 2 and the desired thickness can be achieved.

[0035] Once the ink has been applied to one side of the separator 2, it is dried, for example, at a temperature of between 20 and 150°C for the time necessary to remove all the solvent. After the first drying or curing, the ink is applied to the other side of separator 2 and dried in the same way.

[0036] It is worth mentioning that it can also be done by applying the ink on a smooth surface, from which the electrode can be removed as a wafer, and is fully func- tional, without the need for a metal collector.

[0037] It is also possible to apply the ink on fabrics as an aid support, but these must be soluble in a solvent, which can be removed during assembly using a corre- sponding solvent and leaving the electrode without col- lector and support.

[0038] In addition, if desired, the separator and elec- trode assembly can be cut to a desired shape, e.g. for button cells, by cutting out circles of the desired diameter.

[0039] For the demonstration of the device for storing and / or converting energy according to the present inven- tion the following comparative examples are provided in the following description.

[0040] For the manufacture of the lithium batteries, a classic LFP (lithium ferrophosphate) battery configura- tion was used, using LiPF6 1 M EC / EMC=50 / 50 (v / v) as electrolyte and polypropylene or cellulose separator. Commercial LFP was used as the active material for the cathode, together with the conductive additives and the binder. On the other hand, a commercial syn- thetic graphite was used as the anode, with its respective conductive additives and binder.

[0041] For the tests, the different electrodes were de- posited in the classic way, using a copper or aluminum collector as appropriate. Once the electrodes had been deposited, cut and dried, the different button cells were assembled in a glove box with an argon atmosphere in the following configurations. Firstly, a button cell was made with a semi-cell configuration in which a commer- cial LFP (lithium ferrophosphate) cathode was as- sembled against lithium metal, using as electrolyte LiPF6 1 M EC / EMC=50 / 50 (v / v) and a polypropylene separator (Figure 2). The same configuration is shown below, but without using metal collectors, using the technology that has been developed (Figure 3).

[0042] Secondly, a button cell with a semi-cell config- uration was made in which a commercial graphite vs. lithium metal anode was assembled, using LiPF6 1 M EC / EMC=50 / 50 (v / v) and a polypropylene separator as electrolyte (Figure 4). The same configuration is shown below, but without using metal collectors, using the tech- nology that has been developed (Figure 5).

[0043] Finally, figure 6A shows several charge and discharge cycles in a lithium-ion button cell assembled using aluminum and copper collectors for the cathode (LFP) and anode (graphite), respectively. LiPF6 1 M EC / EMC=50 / 50 (v / v) was used as electrolyte and cellu- lose was used as separator.

[0044] Figure 6B shows several charge and discharge cycles in a lithium-ion button cell assembled with the same materials for cathode and anode, the same elec- trolyte, but using the newly developed method on the cellulose separator. As can be seen in Figure 6B, the newly developed technology can be employed on both polymeric separators (e.g. polypropylene) and cellulose separators showing adequate behavior. Of course, these results can be improved by using other materials as separators.

[0045] Although reference has been made to a specific embodiment of the invention, it is obvious to a person skilled in the art that the method and device described are susceptible to numerous variations and modifications, and that all the details mentioned can be replaced by technically equivalent ones, without departing from the scope of protection defined by the appended claims. Claims 1. Device for storing and / or converting energy (1), characterized in that it comprises: - one or more spacers (2) defining two sides; and - electrodes (3) in contact with one or both sides of the separator (2), each electrode (3) compris- ing an ink including at least one conductive additive. 2. Device for storing and / or converting energy (1) ac- cording to claim 1, wherein the conductive additive comprises one or more forms of carbon, such as graphene fibers. 3. Device for storing and / or converting energy (1) ac- cording to claim 1, wherein the ink also comprises a binder, active materials, and solvents. 4. Device for storing and / or converting energy (1) ac- cording to claim 1, wherein the separator (2) is made of cellulose, polymeric, glass fiber or ceramic or combination thereof. 5. Method for manufacturing a device for storing and / or converting energy (1), characterized in that it com- prises the following steps: - preparing an ink, the ink comprising at least one conductive additive; and - forming electrodes (3) with said ink, the elec- 5 10 15 20 25 30 35 40 45 50 55 6 7 EP 4 632 776 A1 8 trodes (3) being in contact with one or two sides of one or more spacers (2). 6. Method for manufacturing a device for storing and / or converting energy (1) according to claim 5, wherein the electrodes (3) are formed by applying the ink directly to one or both sides of the spacer (2). 7. Method for manufacturing a device for storing and / or converting energy (1) according to claim 5, wherein the electrodes (3) are formed on a support and, once formed, are placed in contact with the two sides of the spacer (2). 8. Method for manufacturing a device for storing and / or converting energy (1) according to any one of claims 5 to 7, further comprising a final step of cutting the separator assembly (2) and the two electrodes (3). 9. Method for manufacturing a device for storing and / or converting energy (1) according to claim 6, wherein ink is first applied to a first side of the separator (2), it is dried, and once the ink has dried, the ink is applied to a second side of the separator (2), and it is dried. 5 10 15 20 25 30 35 40 45 50 55 7 EP 4 632 776 A1 8 EP 4 632 776 A1 9 EP 4 632 776 A1 10 EP 4 632 776 A1 11 EP 4 632 776 A1 12 EP 4 632 776 A1 5 10 15 20 25 30 35 40 45 50 55 13 EP 4 632 776 A1 5 10 15 20 25 30 35 40 45 50 55 14 EP 4 632 776 A1 5 10 15 20 25 30 35 40 45 50 55 {ACIPPTGZ-26005-HKSPT / 02467007v1} 摘要 用于存储和 / 或转换能量的装置(1),包括:一个或更多个间隔件(2),其限定两侧; 和电极(3),其与所述间隔件(2)的一侧或两侧接触,每个电极(3)包括油墨,所 述油墨包括至少一种导电添加剂。该方法包括以下步骤:制备油墨,所述油墨包括至 少一种导电添加剂;以及用所述油墨形成电极(3),所述电极(3)与一个或更多个间 隔件(2)的一侧或两侧接触。该装置允许间隔件本身同时充当集流体,为金属集流体 的氧化等问题提供了解决方案。

Claims

1. Device for storing and / or converting energy (1), characterized in that it comprises: - one or more spacers (2) defining two sides; and - electrodes (3) in contact with one or both sides of the separator (2), each electrode (3) comprising an ink including at least one conductive additive.

2. Device for storing and / or converting energy (1) according to claim 1, wherein the conductive additive comprises one or more forms of carbon, such as graphene fibers.

3. Device for storing and / or converting energy (1) according to claim 1, wherein the ink also comprises a binder, active materials, and solvents.

4. Device for storing and / or converting energy (1) according to claim 1, wherein the separator (2) is made of cellulose, polymeric, glass fiber or ceramic or combination thereof.

5. Method for manufacturing a device for storing and / or converting energy (1), characterized in that it comprises the following steps: - preparing an ink, the ink comprising at least one conductive additive; and - forming electrodes (3) with said ink, the electrodes (3) being in contact with one or two sides of one or more spacers (2).

6. Method for manufacturing a device for storing and / or converting energy (1) according to claim 5, wherein the electrodes (3) are formed by applying the ink directly to one or both sides of the spacer (2).

7. Method for manufacturing a device for storing and / or converting energy (1) according to claim 5, wherein the electrodes (3) are formed on a support and, once formed, are placed in contact with the two sides of the spacer (2).

8. Method for manufacturing a device for storing and / or converting energy (1) according to any one of claims 5 to 7, further comprising a final step of cutting the separator assembly (2) and the two electrodes (3).

9. Method for manufacturing a device for storing and / or converting energy (1) according to claim 6, wherein ink is first applied to a first side of the separator (2), it is dried, and once the ink has dried, the ink is applied to a second side of the separator (2), and it is dried.