CA2669551C - Rechargeable electrochemical battery cell - Google Patents
Rechargeable electrochemical battery cell Download PDFInfo
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- CA2669551C CA2669551C CA2669551A CA2669551A CA2669551C CA 2669551 C CA2669551 C CA 2669551C CA 2669551 A CA2669551 A CA 2669551A CA 2669551 A CA2669551 A CA 2669551A CA 2669551 C CA2669551 C CA 2669551C
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- H—ELECTRICITY
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- H01M4/00—Electrodes
- H01M4/02—Electrodes composed of, or comprising, active material
- H01M4/36—Selection of substances as active materials, active masses, active liquids
- H01M4/48—Selection of substances as active materials, active masses, active liquids of inorganic oxides or hydroxides
- H01M4/485—Selection of substances as active materials, active masses, active liquids of inorganic oxides or hydroxides of mixed oxides or hydroxides for inserting or intercalating light metals, e.g. LiTi2O4 or LiTi2OxFy
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- H01M4/13—Electrodes for accumulators with non-aqueous electrolyte, e.g. for lithium-accumulators; Processes of manufacture thereof
- H01M4/131—Electrodes based on mixed oxides or hydroxides, or on mixtures of oxides or hydroxides, e.g. LiCoOx
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- H01M4/64—Carriers or collectors
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- H01M10/056—Accumulators with non-aqueous electrolyte characterised by the materials used as electrolytes, e.g. mixed inorganic/organic electrolytes
- H01M10/0564—Accumulators with non-aqueous electrolyte characterised by the materials used as electrolytes, e.g. mixed inorganic/organic electrolytes the electrolyte being constituted of organic materials only
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- H01M10/056—Accumulators with non-aqueous electrolyte characterised by the materials used as electrolytes, e.g. mixed inorganic/organic electrolytes
- H01M10/0564—Accumulators with non-aqueous electrolyte characterised by the materials used as electrolytes, e.g. mixed inorganic/organic electrolytes the electrolyte being constituted of organic materials only
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- H01M4/13—Electrodes for accumulators with non-aqueous electrolyte, e.g. for lithium-accumulators; Processes of manufacture thereof
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- H01M4/36—Selection of substances as active materials, active masses, active liquids
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- H01M4/36—Selection of substances as active materials, active masses, active liquids
- H01M4/38—Selection of substances as active materials, active masses, active liquids of elements or alloys
- H01M4/40—Alloys based on alkali metals
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- H01M4/36—Selection of substances as active materials, active masses, active liquids
- H01M4/48—Selection of substances as active materials, active masses, active liquids of inorganic oxides or hydroxides
- H01M4/50—Selection of substances as active materials, active masses, active liquids of inorganic oxides or hydroxides of manganese
- H01M4/505—Selection of substances as active materials, active masses, active liquids of inorganic oxides or hydroxides of manganese of mixed oxides or hydroxides containing manganese for inserting or intercalating light metals, e.g. LiMn2O4 or LiMn2OxFy
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- H01M4/36—Selection of substances as active materials, active masses, active liquids
- H01M4/48—Selection of substances as active materials, active masses, active liquids of inorganic oxides or hydroxides
- H01M4/52—Selection of substances as active materials, active masses, active liquids of inorganic oxides or hydroxides of nickel, cobalt or iron
- H01M4/525—Selection of substances as active materials, active masses, active liquids of inorganic oxides or hydroxides of nickel, cobalt or iron of mixed oxides or hydroxides containing iron, cobalt or nickel for inserting or intercalating light metals, e.g. LiNiO2, LiCoO2 or LiCoOxFy
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- H01M4/36—Selection of substances as active materials, active masses, active liquids
- H01M4/58—Selection of substances as active materials, active masses, active liquids of inorganic compounds other than oxides or hydroxides, e.g. sulfides, selenides, tellurides, halogenides or LiCoFy; of polyanionic structures, e.g. phosphates, silicates or borates
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- H01M50/40—Separators; Membranes; Diaphragms; Spacing elements inside cells
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- H01M6/00—Primary cells; Manufacture thereof
- H01M6/14—Cells with non-aqueous electrolyte
- H01M6/16—Cells with non-aqueous electrolyte with organic electrolyte
- H01M6/162—Cells with non-aqueous electrolyte with organic electrolyte characterised by the electrolyte
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- H01M4/62—Selection of inactive substances as ingredients for active masses, e.g. binders, fillers
- H01M4/621—Binders
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- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/10—Energy storage using batteries
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Abstract
Description
In particular, the invention relates to a battery cell in which the active metal (whose oxidation state is changed during the charging and discharging of the cell due to the electrode reaction at the negative electrode) is an alkali metal, alkaline earth metal, zinc, aluminium or a metal of the second subgroup of the periodic system, lithium being particularly preferred. Hereafter, without limiting the generality, reference will be made to lithium as active metal of the negative electrode.
The electrolyte used in the invention is preferably based on SO2. The term "S02-based electrolyte", is understood to refer to electrolytes which contain SO2 not only in low concentration as an additive, but in which the mobility of the ions of the conductive salt that is contained in the electrolyte and that is responsible for the charge transport is at least partly due to the SO2. In the case of an alkali metal cell, it is preferable to use a tetrahaloaluminate of the alkali metal, for example LiAIC14, as conductive salt. A rechargeable alkali metal cell having an S02-based electrolyte is referred to as a rechargeable alkali metal-S02 cell.
The invention also relates to cells with other electrolytes which contain other conductive salts (e.g. halogenides, oxalates, borates, phosphates, arsenates, gallates) and other solvents that provide for the mobility of the ions. The solvents can be inorganic (for example sulfurylchloride, thionylchloride), organic (for example ethers, ketones, carbonates, esters), and ionic liquids. It is also feasible to use mixtures of the conductive salts and solvents mentioned.
It can happen that the cell housing ruptures or at least becomes leaky such that harmful gaseous or solid substances are released, or a fire may occur.
Especially critical are battery cells in which a strong increase of the temperature in the interior of the cell causes an increase of exothermic reactions which in turn leads to a further increase in temperature. This self-potentiating effect is referred to as "thermal runaway".
Battery manufacturers attempt to prevent any "thermal runaway" by controlling the charging and/or discharging circuit by electronic, mechanical or chemical means, such that the flow of electric current is interrupted below a critical temperature level. To this end, for example, pressure-sensitive mechanical or temperature-sensitive electronic switches are integrated.
In order to prevent the risks associated with the accumulation of lithium in unbound (metallic) form, commercially available alkali metal battery cells, in particular Li ion cells, use graphite intercalation electrodes as negative electrodes. In Li ion cells, the lithium resulting from the electrode reaction at the negative electrode (by taking up an electron) during the charging of the cell is incorporated into the layered lattice of the graphite. For this reason, Li ion cells usually do not contain accumulations of metallic lithium during normal operation.
However, safety problems still result in many cases despite these and other measures. It has happened, for example, that portable computers burst into flames as a consequence of a "thermal runaway" of the lithium ion cells installed therein. According to Battery Power Products &
Technology, January/February 2005, vol. 9, issue 1, 1.6 million lithium batteries have been recalled by their manufacturers since 2000 due to potential safety problems, and the responsible US authority (Product Safety Commission) has received more than 80 reports indicating that
Despite these safety problems, alkali metal cells are very important for practical applications, especially since they are characterized by high cell voltage and high energy density (electrical capacity per unit volume) and high specific energy (electrical capacity per unit weight).
On this basis, the invention addresses the problem to further improve battery cells, in particular alkali metal cells, with regard to their performance data (energy density, power density) while simultaneously allowing a very high safety standard.
This technical problem is solved by a rechargeable battery cell of the type described above, in which the cell contains a porous structure in which the active mass of the positive electrode is contained and which is arranged in the vicinity of an electronically conductive substrate of the negative electrode such that at least a part of the active metal resulting from the electrode reaction at the negative electrode penetrates into the pores of the porous structure comprising the active mass of the positive electrode and is stored therein, whereby the storage of the active metal in the pores of the porous structure comprising the active mass of the positive electrode is provided, at least in part, by deposition in metallic form.
Thus in a particular embodiment of the invention there is provided a rechargeable electrochemical battery cell having a negative electrode, an electrolyte containing a conductive salt and sulfur dioxide, a positive electrode and a reservoir for storing active metal resulting from an electrode reaction at the negative electrode during charging of the cell, wherein:
3a the cell contains a porous structure comprising a structure-forming solid material with pores distributed therein, the structure-forming solid material comprising an active mass of the positive electrode, the active mass changing its electric charge state during a redox reaction at the positive electrode;
the storing of the active metal resulting from an electrode reaction at the negative electrode taking place at least in part by deposition in metallic form;
the porous structure comprising the active mass of the positive electrode being arranged in the vicinity of an electronically conductive substrate of the negative electrode such that during charging of the cell at least part of the active metal resulting from the electrode reaction at the negative electrode penetrates in metallic form into the pores of the porous structure comprising the active mass of the positive electrode and is deposited in the pores;
and wherein in an operational state of the battery cell the internal surface of the of the porous structure comprising the active mass of the positive electrode is covered by an intraporous separator layer.
The term "active mass of the positive electrode" is understood to refer to a component of the cell which changes its electric charge state during the
In particular metal compounds (for example oxides, halogenides, phosphates, sulfides, chalcogenides, selenides) are suitable.
Compounds of a transition metal M, in particular of an element of atomic numbers 22 to 28, are particularly suitable. Also suitable are mixed oxides and other mixed compounds of metals. Lithium-cobalt oxide is particularly preferred. During discharging of a cell of this type, ions of the active metal are incorporated into the positive active mass. For reasons of charge neutrality, this leads to an electrode reaction of the positive active mass at the electrode during which an electron transition occurs from a current collector element of the electrode into the positive active mass. The reverse process occurs during charging: the active metal (for example lithium) is removed from the positive active mass in the form of an ion, causing an electron transition from the positive active mass into the current collector element of the positive electrode.
According to a basic principle of battery engineering, the active metal of the negative electrode and the active mass of the positive electrode are separated from each other such that no electronic conduction between the electrodes is possible inside the cell. Such internal electronic conduction would interfere with the function of the cell in multiple ways:
- Both the conversion of electrical energy to chemical energy during the charging of the cell and the reverse conversion of chemical energy to electrical energy upon discharging are based on electrode reactions (redox reactions) that take place at both electrodes between the active material and the electronically conductive current collector element (substrate) of the respective electrode. The electronic current resulting from the electrode reactions is meant to flow through the outer electrical circuit. An electronically conductive contact between the active metal of the negative electrode and the active mass of the positive electrode inside the cell forms a short circuit causing a direct transition of electrons between the electrodes within the cell. A short-circuit of this type leads to a loss of charge, i.e. to reduced efficiency during charging and a loss of stored electrical energy caused by self-discharge.
- Short-circuits cause strong electric currents which again cause strong generation of heat. This can lead to a "thermal runaway" and its
The required separation of the active masses is usually achieved by locating these masses in spatially separated layers. The layers are in most cases separated by a separator. The term "separator" is used in lci battery engineering to refer to a material that is suited to insulate the electrodes, in particular their active masses, with regard to electronic conduction, while, on the other hand, allowing the required ionic conduction. The separator divides the overall volume of the battery cell into two partial spaces, namely a positive electrode space and a negative electrode space, between which an exchange of charge by means of the ions of a conductive salt is possible, whereas an electronic exchange of charges is not possible. This is true regardless of the shape of the cell including, for example, spirally wound (so called "jelly roll"), in which the partial spaces are provided in the form of thin parallel layers that are wound about a common axis.
US patent application 2003/0099884 recommends interpenetrating electrodes for battery cells. According to this document, these are electrodes forming a network which extends in two or three directions of space, whereby each electrode penetrates into the other. This is meant to achieve a higher power density (at unchanged high energy density) compared to the common thin layer cells. In the embodiments described in the document, the interpenetrating electrodes consist of insertion materials, preferably intercalation materials, the active metal being bound in the lattice structure thereof. In order to achieve a complete separation of the electrodes despite their interpenetrating structure, with electrolyte present in the spaces between the electrodes, the document suggests a range of special measures, in particular by mutually matched electrostatic attraction and/or repulsion of the electrode materials and the electrolyte. This is meant to exclude with certainty any short-circuiting.
not bound, in particular not within an insertion material or intercalation material). W02003/061036 refers to this type of cells and proposes, in order to achieve the required safety with the lithium being present in metallic form, to provide a layer having a microporous structure, in immediate contact with the electronically conductive substrate of the negative electrode, the layer having a pore size such that the active mass deposited during the charging process grows into its pores in a controlled manner. This layer is termed "deposition layer". The design of the deposition layer is such that its pores are completely filled by the active metal growing into the porous structure, whereby the active metal contacts the electrolyte essentially only at the relatively small boundary areas at which further deposition takes place (within the pores). The publication describes additional measures regarding the layer structure of the deposition layer aiming to achieve the desired pore size and porosity as well as the required safety. This includes the use of a plurality of materials with different particle sizes to form the porous structure and also includes the use of an additional salt that is integrated into the deposition layer.
W02005/031908 describes a similar design having a deposition layer.
This publication contains the further information that there is no absolute need to have a separator between the deposition layer of the negative electrode and a layer formed by the active mass of the positive electrode.
Rather, the boundary between the positive electrode and the negative electrode is to be designed such that the active metal deposited at the negative electrode during the charging of the cell contacts the active mass of the positive electrode in such a manner that locally limited short-circuit reactions can occur at the surfaces thereof.
The inventors have found that, surprisingly, an electrode design is not only possible but even particularly advantageous, in which the active
With this design there is contact, and thus the risk of short-circuiting, between the two active masses at the very large internal surface (preferably more than 20 cm2/cm3) of the porous structure of the positive electrode.
The porous structure consists of a structure-forming (solid) material and pores distributed therein (preferably homogeneously). Basically, any structure can be used which has a suitable porosity for taking up the lithium which is deposited during the charging of the cell. A porous structure made from particles is preferred, the structure-forming particles being preferably bonded to each other such that they form a fixed particle composite structure However, in principle, the porous structure comprising the active mass of the positive electrode can also consist of particles that are not bonded to each other. In this case suitable measures (e.g. stamping into the cell, pressing) have be used to achieve that the particles are in sufficiently tight and permanent contact to each other to provide for the required electronic conductivity.
According to a preferred embodiment of the invention, the electronic conductivity of the porous structure comprising the active mass of the positive electrode is improved by integrating into its structure-forming material an electronically conductive material as conductivity-improving material. Suitable for this purpose are, for example, carbon particles or metal particles (e.g. tinsel, chips). Carbon is particularly preferred.
According to further preferred embodiments, the porous structure containing the positive active mass can be formed by incorporating the structure-forming particles into a metal foam (for example, nickel foam).
Another possibility is to fix them to a sheet of metal or to expanded metal (rib mesh) by pressing or by means of a binding agent.
Surprisingly, simultaneously an improved safety is achieved. The invention results in a macroscopically essentially homogeneous distribution of the components to the invention. This provides in reality the conditions which are presumed for common safety calculations based on the Berthelot-Roth' product (BRP). This means that a degree of safety calculated theoretically according to the BRP is achieved in reality.
Calculating the BRP, the presumption is made that the reaction components are distributed homogeneously such that optimal reactivity is ensured. If the components are not distributed homogeneously, but rather spatially separated (such as e.g. in the electrode layers of a customary battery) the actual explosibility is higher than expected according to the calculated BRP. A substance is called explosible if it has a BRP of 1200 x 106kJ/Im3 or higher.
4000x106 kJ/m3. Thus it would be explosible even if the components were mixed homogenously. In contrast the rechargeable lithium/lithium-cobalt oxide system with inorganic electrolyte solution L1AIC14xS02 has a calculated BRP value of approx. 200x106 kJ/m3 if mixed homogenously.
The substantially lower value for a cell having a lithiumcobaltoxide electrode according to the invention results from the reduction of the concentration of the components Li and SO2 caused by an inert non-reactive substance, namely LiCo02. A condition of this effect is, however, that the distribution in the reduced-concentration system is homogenous.
This is achieved because a cell according to the invention can be presumed to have a macroscopically homogeneous mixture such that the calculated BRP value is an essentially accurate measure of the actual explosion safety.
The invention leads to an "inherently safe" cell, i.e. a battery cell whose safety is not based on additional external safety measures, but rather on its physico-chemical properties and internal design features. Another important aspect in this context is that only a very small amount of electrolyte is required. Preferably, the volume of the electrolyte in the cell corresponds to no more than twice the free pore volume of the porous structure. More preferably it even corresponds at most to the free pore volume of the porous structure of the positive electrode. To further improve the function of the cell and, in particular, its safety, an additional salt, in addition to the conductive salt of the electrolyte, can be present in the cell. In particular a halogenide, preferably a fluoride, can be used.
The cation of the additional salt can be identical to the cation of the conductive salt or it may be different. Li + or any other alkali metal cation is preferred as cation of the additional salt. The additional salt is preferably contained in the electrolyte.
The invention is particularly advantageous in combination with a battery cell according to international patent application WO 00/79631 Al, which can be operated with a very small amount of electrolyte. This document describes a cell, having a negative electrode which contains in its charged state an active metal, in particular an alkali metal, having an electrolyte based on sulfur dioxide and comprising a positive electrode which contains the active metal and from which during charging ions are 5 released into the electrolyte. The electrolyte is sulfur-dioxide-based.
At the negative electrode, a self-discharge reaction takes place, in the course of which the sulfur dioxide of the electrolyte reacts with the active metal of the negative electrode to form a compound of low solubility.
According to the invention described in the international patent
If a binding agent is present in the porous structure for generating a particle composite structure, its volume fraction should not be too high.
Preferably it is less than 50%, more preferably less than 30%, of the entire solids volume of the porous structure. The binding agent proportion should be so small that it is concentrated only at the contact sites between the structure-forming particles. For this reason, binding agent fractions (ratio of binding agent volume to total volume of the structure-forming particles) of less than 20% or even less than 10% are particularly preferred.
The positive active mass is contained in the porous structure of the positive electrode layer preferably in a concentration of at least 50 wt.%.
More preferably, by far the major share of the structure-forming particles of the porous structure, i.e. a fraction of at least 80%, consist of the material of the positive active mass. Polytetrafluoroethylene is a suitable binding agent, to name an example.
The mean diameter of the pores of the porous positive electrode layer can vary substantially. If the active metal is deposited in the form of so-called whiskers or dendrites, the mean pore diameter should be on the order of size of the whiskers or dendrites. Usually, this corresponds to approx. 1 to 2 pm in an S02-based electrolyte. Smaller values can lead to an increase in the over-voltage required for charging, but are in principle possible. Likewise, larger mean pore diameters may be acceptable depending on the particular case. Preferably, the mean pore diameter of the porous positive electrode layer should be no more than 500 pm, preferably no more than 100 pm, and particularly preferably no more than 10 pm.
Surprisingly it has been found, that when a cell according to the invention is in operation, short circuiting within the pores of the positive electrode layer, which would interfere with its long term function, is prevented by a layer covering the internal surface thereof. This layer is referred to as "intraporous separator layer".
Preferably at least a part of the intraporous separator layer is generated within the cell (in situ). This takes place in particular during the charging and/or discharging, in particular during the charging of the cell. The in-situ-formation of the separator layer can take place at the production site of the manufacturer and/or during practical use of the cell at the location of the user. Ideally it takes place without introducing additional layer-forming substances which have to be removed after the layer formation.
The initial formation of the intraporous separator layer can take place during first charging cycles of the battery cell. However, the intraporous separator layer can also be generated or regenerated during the later operation. This applies, in particular, if the layer gets damaged. Any missing parts of the intraporous separator layer are newly generated and/or supplemented during subsequent charging cycles. This "repair mechanism" is maintained over the entire serviceable life of the cell and ensures permanently safe and functional cells.
A reaction mechanism, by means of which a covering layer suitable as intraporous separator layer is formed on the internal surface of the porous positive electrode layer, can take place in different cell systems.
General rules for the selection of suitable cell systems cannot be given.
However, with the knowledge of the present invention it is possible with little effort to test potentially suitable cell systems for checking whether the desired formation of an intraporous separator layer (in particular during the charging of the cell) takes place therein.
In this context, cell systems containing an electrolyte which reacts with the other components of the cell, in particular during the charging of the cell, to form a covering layer having the properties of an intraporous separator layer (as described above) are preferred.
An electrolyte containing SO2 is particularly suitable. This does not mean that the electrolyte is necessarily "S02-based" as per the definition given above. Rather, the SO2 can be used at a lower concentration in a mixture with another electrolyte (examples have been named above). In
If ¨ according to a preferred embodiment of the invention ¨ an intraporous separator layer is formed in situ during operation of the cell and if further ¨ as is also preferred ¨ the formation of the intraporous separator layer includes, as one of the reactants, SO2 contained in the electrolyte, it is necessary to distinguish the S02-concentration before the first operation of the cell, e.g. before the first charging, from the SO2-concentration during later operation of the cell, after formation of the intraporous separator layer. With these facts in mind the following approximante information regarding a preferred S02-concentration can be provided:
a) Before the first charging of the cell:
- For an electrolyte in which SO2 is the only solvent: At least 0.5 mol SO2 per mol conductive salt.
- For mixed electrolytes containing SO2 as an additional component: At least 0.1 mol, preferably at least 0.5 mol and particularly preferred at least 1.0 mol SO2 per mol conductive salt.
b) During routine operation of the cell after formation of the interporous separator layer: At least 0.1 mol SO2 per mol conductive salt.
In principle the cell remains operable even if the SO2 is almost completely consumed during formation of the separator layer such that no liquid electrolyte is present after such interporous separator layer formation. The inventors have found that the electrolyte must not necessarily be present in the liquid state because in the context of the invention an electric conductivity which is sufficient for many purposes, i.e. a sufficiently low cell resistance, can be achieved even with an almost completely solidified electrolyte. In such a case the SO2 content of the cell can be very low, e.g. 0.1 mol SO2 per mol conductive salt.
- It must allow application in the form of a sufficiently thin layer to the internal surface (preferably to the external surface also) of the porous positive electrode layer.
- The material must be chemically stabile, i.e. inert with respect to the other components present in the cell, also in an electric field.
The intraporous separator layer can be generated and/or applied by a variety of suitable methods. These include:
- Coating the structure-forming particles prior to their use for formation of the porous positive electrode layer;
- Coating methods based on the passage of gas (for example physical vapor deposition, chemical vapor deposition, plasma or high-current discharge). Methods involving passing a liquid through the layer can also be suitable.
- Methods involving coating from the gas phase, in particular sputtering, wherein the atoms penetrate into the porous positive electrode layer such that they cover its internal surface.
The two options of forming an intraporous separator layer described above (in situ or coating during manufacture prior to the first charging of the cell) can also be combined. For example, a coating method can be carried out in which the porous positive electrode layer is partly (preferably to the larger extent) coated prior to the first charging, using one of the methods described above, whereas the complete intraporous separator layer is formed only during operation of the cell (mainly during initial charging cycles).
If not at least the external surface of the porous positive electrode layer is electronically-insulating by a suitable coating prior to assembly into the cell, it is useful to provide, at the boundary between the substrate of the negative electrode and the porous structure comprising the active mass 5 of the positive electrode, means preventing electronic conduction, but allowing passage of the active metal resulting from the electrode reaction at the negative electrode during the charging of the cell, such means preventing electronic short-circuits. In particular, the following means are suitable for this purpose 10 - coating of the substrate of the negative electrode with an electronically-insulating, but lithium ion-permeable layer;
- coating of the external surface of the porous positive electrode layer with an electronically-insulating, but lithium ion-permeable layer; and - incorporation of a very thin, porous and electronically-insulating layer
The invention is illustrated in more detail hereafter based on exemplary embodiments shown in the figures. The technical features shown therein can be used individually or in combination to create preferred embodiments of the invention. In the figures:
Fig. 1 shows a cross-sectional view of a battery according to the invention;
Fig. 2 shows a schematic view of the substrate of the negative electrode and the porous positive electrode layer, the pores of which are penetrated by active metal of the negative electrode;
Fig. 3 shows a schematic view similar to figure 2 with a porous positive electrode layer the pores of which contain a material suitable for storing the active metal of the negative electrode;
Fig. 4 shows measuring results obtained during the experimental testing of the invention by means of cyclic voltammetry;
The housing 1 of the battery 2 shown in figure 1 consists, for example, of stainless steel and contains a plurality of battery cells 3, each having a positive electrode 4 and a negative electrode 5. The electrodes 4, 5 are -as is common in battery engineering - connected to terminal contacts 8, 9 by means of electrode leads 6, 7. Electrodes 4,5 are shaped as layers -as is also common ¨ having a thickness which is small relative to their extension in the other two dimensions. Obviously, a bipolar design (serial circuiting), instead of the parallel circuiting of the cells shown, is also feasible.
One particularity of the electrode arrangement of cells according to the invention, shown separately in figure 2, is that the electronically conductive substrate 12 forming the current collector element of the negative electrode is located immediately adjacent to a porous structure 13 which contains the active mass of the positive electrode (porous positive electrode layer) such that lithium (active metal of the negative electrode) deposited during charging of the cell penetrates into the pores 14 of layer 13. The current collector element 12 of the negative electrode is much thinner than the porous positive electrode layer. In this and in other respects, the schematic views of the figures are not true to scale.
Preferably, the porous positive electrode layer is at least 10 times as thick as the electronically conductive layer that forms the current collector element 12.
According to the invention electrodes 4, 5 are not disposed in separate layers (macroscopically separated subspaces) of the cell, but rather the active mass of the positive electrode is simultaneously a structural component of a porous layer which is adapted and arranged such that the lithium is taken up and deposited at least partly in metallic form in its pores during the charging of the cell. The heretofore customary spatial separation of (i) the parts of the cell providing the required lithium uptake capacity and (ii) the parts of the cell containing the positive active mass, both parts shaped as separate layers, is not provided. The cell only
Figure 2 shows a strongly simplified schematic view of a microscopic enlargement of a section of the porous positive electrode layer 13 in the vicinity of the negative current collector element 12. In the embodiment shown structure-forming particles 16 of the layer 13 consist of the active mass 17 of the positive electrode 4 (e.g. L1C002). The structure-forming particles 16 are bonded to each other by means of a binding agent 19 whose quantity is such that it is concentrated only in places at which the structure-forming particles 16 contact each other, whereas numerous connection channels between the pores 14 of the porous positive electrode layer 13 remain in other places. The pores 14 of the layer 13 are filled with electrolyte prior to the first charging. Methods are known by means of which it can be ensured that the electrolyte penetrates even into fine pores of a porous layer during the filling process. A suitable method is described in WO 2005/031908, for example.
Figure 2 also shows how the active metal 24 of the negative electrode, for example lithium, grows into the pores 14 of the porous positive electrode layer 13 when it is deposited at the surface of the current collector element 12 during the charging of the cell. The required separation of the active masses 24, 17 of the two electrodes is provided by an intraporous separator layer 25 which covers the entire internal surface of the porous positive electrode layer 13, i.e. the surface of its structure-forming particles 16.
As mentioned above, the intraporous separator layer can be created during manufacture of the battery 2 having cells 3 by coating the surface of the structure-forming particles with a covering layer that possesses the required properties (insulation against electronic conduction, permeability for ions, no detrimental effects on the remaining components of the cell).
Suitable coating materials include in particular, ion-conductive glasses.
Many variants are possible with regard to the components contained
P. Hagenmuller, W. Van Gool (Editors): Solid Electrolytes, Academic Press, year of publication 1978, wherein reference can be made, in particular, to the publication by D. Ravaine et al. "Ionic Conductive Glasses" pp. 277 to 290.
An embodiment of the invention in which the intraporous layer is formed in situ is particularly preferred. This formation process takes place mainly during the first charging cycles. The intraporous separator layer can be formed either by the manufacturer of the battery or at the location of the user.
Preferably, the porous positive electrode layer 13 is arranged on the substrate 12 of the negative electrode 5 so tightly that no hollow spaces are present inbetween, which would allow accumulation of active metal 24 deposited in metallic form during the charging of the cell. Preferably, any such hollow spaces should not be substantially larger than the pores of the porous positive electrode layer 13.
With the cell design of the invention, penetration of the active metal into the positive electrode causes continuous changes of the shape and structure of the positive electrode layer during charging and discharging of the cell. However, in the context of the invention it has been found that this is not detrimental for the cell to such an extent that serious interference with its function results.
According to a further preferred embodiment, shown in figure 3, a material 23 suitable for storing the active metal of the negative electrode is located within the pores 14 of the porous positive electrode layer 13.
Such a material will ¨ without limiting the generality - hereafter be referred to as "lithium-storing material". Different solids capable of taking up lithium are suitable as lithium-storing material. This includes, in particular, graphite, intercalation compounds and metals forming alloys
The electronically conductive substrate 12 can be completely made of metal, preferably of nickel. A simple nickel sheet is suitable, but other metal structures, in particular in the form of a perforated plate or similar, are feasible. According to a further alternative embodiment, the electronically conductive substrate 12 of the negative electrode may consist, at least in part, of a material suitable for storing its active metal, i.e. in particular of a lithium-storing material. In an embodiment of this type, a part of the lithium resulting from the electrode reaction during the charging of the cell is initially stored in the electronically conductive substrate of the negative electrode. As before, active metal is deposited in metallic form in the pores of layer 13 at least during part of the charging process.
During the experimental testing of the invention, experimental electrodes with a geometric surface of 1 cm2, having a porous positive electrode layer, were prepared as follows:
- The components of the electrode layer, namely 94 % lithium-cobalt oxide, 4 % binding agent (PTFE), and 2 13/0 carbon black were mixed in the dry state.
- The mixture was taken up in isopropanol resulting in a paste whose solvent content was approx. 20 to 30 wt.%.
- The paste was homogenized by stirring and then pasted into a current collector element made from nickel foam.
- Subsequently, a drying step followed by a pressing step was carried out until a porosity of 35 'Yo was attained, and then a thermal treatment involving heating to 370 C for 1 hour.
5 These experimental electrodes were then used in a three-electrode cell to carry out voltametric experiments with the experimental electrode serving as working electrode, with a counter-electrode made of nickel sheet onto which lithium was deposited during the charging, and with a nickel electrode covered with lithium metal serving as reference 10 electrode. The arrangement of the electrodes in the cell differed from the common arrangement of experimental cells of this type in that the working and counter-electrode were arranged so closely adjacent to each other that there was just no electrical contact between them before the start of the charging cycle. Due to this arrangement the metallic lithium 15 deposited during the charging contacted the working electrode. In conventional chargeable battery cells, this corresponds to an internal short circuit and leads, for example in the case of Li ion battery systems, to safety-critical states.
The results shown in figure 4 demonstrate that the cycle efficiency is reduced during the first cycles. This can be attributed to the formation of an intraporous separator layer during these cycles. The charge capacity required for this process is not available during the discharging of the cell. After a few cycles (after 4 cycles in the case shown), a cycle efficiency of more than 97 % is attained and then remains constant.
According to the results of the experimental tests, the glass does not need to be ion-conductive in its original state. It was found that an ion-conductive glass can be formed in situ from a previously non-ion-conductive glass, in particular borosilicate glass. This is attributed to a reaction sequence in which initially lithium hydroxide is formed from the lithium-cobalt oxide of the positive electrode reacting with water and then lithium oxide is formed from the lithium hydroxide by uptake of water. The resulting lithium oxide is incorporated into the glass and effects the required ion conductivity.
In order to check the surprising results of the experiments with the three-electrode-cells, the electrode material from experiment 1 was used to set up complete battery cells according to the invention of the system:
(Ni sheet)Li/LiAIC14x1.5 S02/L1Co02. Between the nickel sheet 12 and the porous positive electrode layer 13 a very thin coarsely-porous glass cloth of 60 pm thickness was provided, by means of which the current collector element 12 and the porous positive electrode layer 13 were insulated from each other prior to the start of the charging process. This cloth is no barrier for the lithium deposited at the surface of the current collector element 12. Therefore the lithium is in full contact to the active mass 17 of the positive electrode immediately after the start of the charging process.
Figure 5 shows results of these experiments. The ratio of the capacity that can be obtained from the cell (CE) and the nominal capacity (CN) in
continuous increase of the capacity up to 100% of the nominal capacity within the first 20 cycles and essentially constant resistance values are 5 evident from the plot.
According to the current knowledge of the inventors the intraporous separator layer of the tested battery system is generated by reactions which are triggered by short-term, very strong local currents flowing when lithium contacts the LiCo02. These in turn trigger reactions of the electrolyte components and/or of secondary products commonly formed during the reactions taking place in the cell. The electrolyte components are L1AIC14 and SO2. Secondary products are formed e.g. during charging and over-charging, for example in the form of lithium chloride (LiCI), aluminum chloride (AIC13), lithium dithionite (L12S204) and sulfurylchloride (SO2C12).
As has been mentioned before, the invention is not limited to the tested systems. Although the design according to the invention is not suitable for any and all battery systems it is, based on the explanations provided herein, possible without difficulty to test the suitability of different systems in combination with the design according to the invention and thereby to identify suitable system. In addition to the S02-based electrolyte, other electrolytes, including organic electrolytes, are capable of forming stabile covering layers that possess the required properties of electronic insulation, but ionic conductivity. Mixtures of organic electrolyte and SO2-based electrolyte may in this context be particularly advantageous.
Claims (47)
the cell contains a porous structure comprising a structure-forming solid material with pores distributed therein, the structure-forming solid material comprising an active mass of the positive electrode, the active mass changing its electric charge state during a redox reaction at the positive electrode;
the storing of the active metal resulting from an electrode reaction at the negative electrode taking place at least in part by deposition in metallic form;
the porous structure comprising the active mass of the positive electrode being arranged in the vicinity of an electronically conductive substrate of the negative electrode such that during charging of the cell at least part of the active metal resulting from the electrode reaction at the negative electrode penetrates in metallic form into the pores of the porous structure comprising the active mass of the positive electrode and is deposited in the pores;
and wherein in an operational state of the battery cell the internal surface of the of the porous structure comprising the active mass of the positive electrode is covered by an intraporous separator layer.
Applications Claiming Priority (3)
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| EP06023611.4 | 2006-11-14 | ||
| PCT/EP2007/009744 WO2008058685A1 (en) | 2006-11-14 | 2007-11-10 | Rechargeable electro chemical battery cell |
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| EP (2) | EP1923934A1 (en) |
| JP (1) | JP5356240B2 (en) |
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| KR101639238B1 (en) | 2016-07-13 |
| WO2008058685A1 (en) | 2008-05-22 |
| US20100062341A1 (en) | 2010-03-11 |
| EP2089924A1 (en) | 2009-08-19 |
| KR20090088405A (en) | 2009-08-19 |
| JP5356240B2 (en) | 2013-12-04 |
| CN101622738B (en) | 2013-09-18 |
| ES2574564T3 (en) | 2016-06-20 |
| IL198445A0 (en) | 2010-02-17 |
| EP2089924B1 (en) | 2016-04-13 |
| EP1923934A1 (en) | 2008-05-21 |
| RU2009117719A (en) | 2010-11-20 |
| AU2007321466A1 (en) | 2008-05-22 |
| MX2009003977A (en) | 2009-06-23 |
| ZA200904054B (en) | 2010-04-28 |
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