DE3210420A1 - Electrochemical double-layer capacitor - Google Patents

Abstract

The invention relates to an electrochemical double-layer capacitor containing an electrolyte between the electrodes, and its object is to design such a capacitor so that it has both a small volume and a low weight, accompanied at the same time by high capacitance, and is also inexpensive. For this purpose the invention provides for the electrodes to be composed of metal sheet provided with a porous titanium nitride and/or titanium carbide layer. The novel double-layer capacitor is suitable, in particular, for applications in which a high capacitance is required.

Description

Electrochemical double layer capacitor

The invention relates to an electrochemical double layer capacitor with an electrolyte arranged between the electrodes.

Electrochemical double layer capacitors are made for example DE-OS 28 42 352 and DE-OS 30 11 701 known. For these double layer capacitors are electrodes with a high capacity related to the projected surface needed.

In addition, the electrode material must be in a wide potential range be corrosion resistant and have good electronic conductivity and mechanical Have stability; for application-technical reasons, the potential range mentioned should must not be less than 0.5 V.

The electrodes must also be thin to allow for the capacitors a high volume and weight-related capacity can be achieved. Required It is also ensured that the electrodes are liquid-tight, so that no electrolyte can get from one electrolyte chamber into the other.

In the case of electrochemical double-layer capacitors, the capacitance is of the electrodes is achieved by a high surface roughness or porosity. These Capacitance can only be used at high frequencies if the electrolytic Diaphragm resistance f in the porous electrode layer (with the thickness d) is small and at the maximum frequency f the following applies: # # # # c # d² <0.1; c is the volume-related capacity in the porous layer.

The known double-layer capacitors generally have electrodes made of activated carbon or vitreous carbon. Electrodes off activated However, carbon is only suitable for back-up capacitors because none of them are mechanical stable layers can be produced; in addition, the loss factor tgæ = 1 already reached at the frequency f = 1 Hz. Capacitors with electrodes from activated vitreous carbon result in comparison to the loss factor tg # = 1 at mains frequency, but here the problem arises that the Randelek-croden must be made metallic contact, which requires a complex manufacturing process.

The object of the invention is to provide an electrochemical double layer capacitor so designed that it has both a small volume and a low weight at the same time has high capacity as well as being inexpensive and simple Way is producible.

This is achieved according to the invention in that the electrodes metal sheet provided with a porous titanium nitride and / or titanium carbide layer exist.

# Titanium nitride * or n-titanium carbide are essentially about the compounds TiN and TiC; Deviations from the stoichiometric ratio but can be given. In addition to TiN and TiC, mixtures of these compounds can also be used and carbonitrides of the form TiCxN1x can be used, for example TiC0.5N0.5 Of the The double-layer capacitor according to the invention has electrodes in the form of thin metal sheets on which there are thin porous TiN or TiC layers. Compared to Vitreous carbon electrodes such electrodes have the advantage that they do not need to be activated. The electrodes can become a multi-cell capacitor are stacked, with the edge electrodes having a TiN or TiC layer on only one side wear, while the remaining electrodes on both sides with such a layer are provided. The electrodes are separated from one another by narrow electrolyte spaces separated, and the number n of these chambers determines the permissible voltage for the Capacitor (U - n. UO, where UO is the cell voltage).

When the double layer capacitor according to the invention can -related to the single electrode area capacities of up to 100 mF cm2 can be realized. For example, a single-cell capacitor has an area of 10 cm2 Capacitance of 0.43 F at a frequency of 50 Hz and results in a loss factor day = 0.67.

As a carrier for the porous TiN or TiC layers according to the invention Double layer capacitor used sheet metal. These metal sheets that are tight i.e., are non-porous, can for example consist of copper; preferably be Sheets made of titanium or stainless, i.e. stainless steel (so-called VA steel) used.

A TiN electrode can be produced, for example, by reactive Vapor deposition or sputtering of titanium take place in an N2 atmosphere. Advantageous is made from a supply of titanium with an electron beam gun titanium evaporated in an argon / nitrogen atmosphere and then titanium nitride on a titanium sheet deposited as a thin layer. A TiC electrode can also be used in a corresponding manner getting produced; in this case, the nitrogen is then, for example, replaced by methane CH4 replaced. When using CH4 / N2 mixtures, carbonitrides can be used accordingly be generated.

For a better connection of the porous TIN or TiC layer to the metal sheet it is advantageous if the N2 or CH4 partial pressure is applied during the coating of the sheet is slowly increased. In this case, a dense, i.e. non-porous, is formed first TiN or TiC layer and only then the corresponding porous layer.

There is then, for example, a transition from titanium (sheet metal) to a dense TiN layer to a porous surface layer made of titanium nitride.

The double layer capacitor according to the invention preferably contains a neutral aqueous or an aprotic electrolyte. Suitable neutral electrolytes are for example aqueous solutions of ammonium chloride and potassium chloride. as aprotic, i.e. non-aqueous electrolyte is used in particular by propylene carbonate, which contains an alkali metal salt such as lithium perchlorate (LiCl04).

A thin, porous, insulating layer can advantageously be provided between the electrodes Be arranged layer. This layer, which acts as a separating layer (between the electrodes) and serves as an electrolyte carrier, is preferably made of asbestos; in addition, for example Zirconia can also be used.

The invention is to be explained in more detail on the basis of examples.

Electrodes were used to determine the electrochemical properties in the form of titanium sheets with a thickness of 0.4 mm, which are 16 µm thick TiN layer were provided, built into an electrode holder and at room temperature investigated by potentiostatic load with regard to the corrosion behavior. The following were used as aqueous electrolytes: 6 M KOH, 2.5 M H 2 SO 4, 4 M or 5 M NH 4 Cl and 1 M KCl. It showed the following.

In 6 M KOH there is a double layer capacitance of 100 mF. cm 2 at, y = 1 Hz. Because of the corrosion and resistance in the porous layer is the (strongly) alkaline electrolyte for a capacitor with TiN electrodes unsuitable if this is to be used at mains frequency.

In 2.5 M H2S04 a TiN electrode has a capacity of 107 mF. cm measured, but with positive potentials corrosion occurs. Therefore can no capacitors with TiN electrodes can be built up with acids as electrolyte.

An aqueous solution of 5M NH4Cl has one with 6M KOH and 2.5M H2S04 comparable resistivity; this is important because of the electrolyte Must have a high conductivity when a low dissipation factor is achieved shall be. With 5 M NH4Cl, therefore, results in a similar way to acidic and alkaline Electrolyte, a capacitance of 98 mF cm 2, based on the frequency # = 1 Hz; at 700C the capacitance is even higher (120 mF # cm-2). In the potential tial interval -0.5 V # # / Hg2Cl2 # 0.5 V there is no corrosion.

Each with two TiN electrodes of the type mentioned above were single-cell capacitors constructed. The two electrodes were each spaced apart 5 mm apart, and the potential of the individual electrodes can be measured as a function of the voltage U across the capacitor.

With 1 M KCl as the electrolyte, the impedance measurement resulted in one amplitude of 0.5 V for v = 1 Hz a capacitance of 0.16 F with an electrode area of 7 cm²; this results in, based on the individual electrode, at room temperature a Capacity of 46 mF. cm The capacitor was then on for 70 h with a voltage loaded by 0.5 V at a frequency of 10 mHz; the capacity remained constant. Then the temperature was increased to 70 ° C .; here the capacity changed (C = 0.20 F) either.

Is used instead of 1 M KCl as electrolyte 5 M NH4Cl, the has a higher conductivity, a capacitance results at room temperature of 55 mF cm2 at t = 1 Hz.

To reduce the distance between the electrodes, and thus to reduce the electrolyte resistance, was placed between the two electrodes (Diameter: 40 mm) a 30 / µm thick asbestos layer - as a separating layer and as a Electrolyte carrier - arranged and soaked with 5 M NH4Cl; the edge was glued in the process. Such a capacitor has a capacitance of 0.24 F at 50 Hz and a loss factor tgS = 0.38. If the capacitor runs for 240 h with a DC voltage of 0.5 V is loaded, the capacity does not change and the residual current fluctuates between 4 and 6 / uA.

The self-discharge was then followed; it resulted in a time constant of 3300 s. Thereupon the voltage was increased to 1 V and after 5 h again the Followed self-discharge: The voltage changed with Y - 3.5. 105 s very slowly. The capacitance is then initially 0.17 F, but increases again to 0.213 F (r - 50 Hz, tgÆ = 0? 418) and remains constant for months.

Are electrodes in a corresponding single-cell capacitor if the TiN layer is 30 μm thick, the result is - after 120 h Operating time with a voltage of 0.5 V - at g = 50 Hz a capacity of 0.43 F and a loss factor of 0.67. The condenser is then operated at 70 ° C loaded with a voltage of 0.5 V, the capacity increases to 0.98 F.

If the voltage is then increased to 1 V, the internal capacity decreases from 76 h to half.

A single-cell capacitor with disc-shaped stainless steel electrodes Steel on which a dense and then a porous TiN layer is applied - with an effective area of 7 cm2 and an electrode spacing of 200 / µm - with 4 M NH4Cl as electrolyte at r = 50 Hz a capacity of 51 mF and could withstand a voltage of 0.5 V.

Used in a capacitor with electrodes of the type described above Kind (thickness of the TiN layer: 16 / um) and an asbestos layer of 30 / Ufll an aprotic If electrolyte is used, the operating voltage can be increased to 1 V. At 1 M LiCl04 in propylene carbonate is applied to the individual electrode (area: 12.5 cm2) related capacity of 42 mF cm 2 the loss factor tg - 1 at one frequency of 3 Hz.

In addition to the good electrochemical properties, the inventive Double layer capacitor still has the main advantages on the fact that it is thin, mechanically Has stable electrodes that do not need to be activated and that are relatively cheap are. In addition, there is the further advantage that the contact is unproblematic is.

5 claims

Claims (5)

Patent claims Electrochemical double layer capacitor with a Electrolyte arranged between the electrodes, d a d u r c h e k e n n z e i c h n e t that the electrodes are made with a porous titanium nitride and / or titanium carbide layer provided sheet metal. 2. Electrochemical double layer capacitor according to claim 1, d a D u r c h e k e n nz e 1 c h -n e t that the metal sheet is made of titanium or stainless Steel is made. 3. Electrochemical double layer capacitor according to claim 1 or 2, d a d u r c h e k e n n -z e i c h n e t, that is made between the layer porous titanium nitride and / or titanium carbide and the metal sheet dense titanium nitride and / or titanium carbide. 4. Electrochemical double layer capacitor according to one of the claims 1 to 3, d u r c h g e -k e n n n z e i c h n e t that it is a neutral aqueous or contains an aprotic electrolyte. 5. Electrochemical double layer capacitor according to one or more of claims 1 to 4, d a ci u r c h g e k e n n z e i c h n e t that between a thin, porous, insulating layer, especially made of asbestos, is arranged.