DE2658392C2 - Electric battery cell - Google Patents

Description

The invention relates to electric battery cells with a liquid anode, a liquid cathode, a solid electrolyte and an electrode device and is an improvement or modification the invention described in related British patent specification 15 08 805.

The electric cell described in the aforementioned British patent application has a solid electrolyte on, which on one side partially has a chamber for a liquid anode and on its other Side partially delimits a chamber for a liquid cathode, which is soaked in a conductive felt, as well electrode means extending along the chamber for the liquid chamber, said liquid chamber Chamber for the liquid cathode has an area which is free of conductive felt, and this Area has a relatively high electrical resistance and is essentially free of cathodic reactions is during operation of the cell.

An electrical cell according to the present invention has a solid electrolyte which is partially bounded on one side by a chamber which contains a liquid anode, and on the other side one Limited chamber that contains a liquid cathode, the liquid anode over the solid electrolyte is distributed across, and electrical insulating means is provided covering part of the other side of the solid electrolyte from the liquid cathode at a distance, such that this spaced part in the is essentially free of electrochemical reactions during the use of the cell and therefore the Edge or edges of this part of the surface of the solid electrolyte at which ionic reactions occur in the chamber for the liquid anode take place over the respective edge or edges of the surface of the solid electrolyte also extends or extends, sn which or which electrochemical reactions in the chamber for the liquid cathode, in order to intensify the current in the solid electrolyte at this edge or these edges during

ίο to prevent the cell from recharging.

According to a further aspect of the invention there is provided an electric cell comprising a solid electrolyte of tubular shape which on one side partially defines a chamber containing a liquid anode and on the other side partially defines a chamber which contains a liquid cathode and rod-shaped electrode means extending into and the length of the liquid cathode chamber, means for spacing a portion of that other side of the solid electrolyte from the liquid cathode to provide an area defining that portion is substantially free of electrochemical reactions during use of the cell and has an electronic conductor which is arranged in the chamber of the liquid cathode to form a portion of the chamber of the liquid cathode in which said electrochemical reactions take place.

According to a further aspect of the invention, an electrical cell has a solid electrolyte on one side closed tubular shape, on one side partially a chamber for a liquid anode limited and on the other hand partially a chamber for a liquid cathode also delimits a Electrode device with carbon, which extends into the chamber of the liquid cathode and over the length the same extends, furthermore an insulating spacer within the chamber of the liquid cathode, which provides an area of this chamber which is essentially free from electrochemical reactions during use of the cell and further a conductive felt that is in the chamber of the liquid cathode is arranged to form part of the chamber of the liquid cathode in which this chemical Reactions take place.

If necessary, the spacer device or the insulating spacer is shaped in this way and in the chamber the liquid cathode arranged so that this area

thus limits materials that could be seriously affected by the electrochemical reactions, z. B. the proximity of the glass sealant, and expediently the spacer extends over that part of the solid electrolyte bounded on the other hand by the glass sealant to prevent an intensification of the current in the solid electrolyte while the cell is being recharged.

The invention will now be described in more detail with reference to the drawing showing it as an example, the only figures of which are a section through an electrical cell of tubular shape for use with liquid sodium and liquid sulfur and with the longitudinal axis lying horizontally.

As can be seen from the drawing, the electric cell is shown in center section and is in cross section round, it has a solid electrolyte 2 made of beta-aluminum oxide with a tubular shape closed on one side on, which is made within a flanged housing 3

Stainless steel is arranged to have a chamber 4 in between for liquid sodium to form. A chamber 5 for liquid sulfur, which is inserted into an electronic conductor in rorm a graphite felt 6 is soaked is provided within the tubular solid electrolyte 2, a correspondingly distributed cavity is provided within the graphite felt 6 in order to allow expansion to allow, caused by the formation of sodium polysulphides when the electrical cell is discharged will. The solid electrolyte 2 is at its open End through glass sealant 7 with a HaI-teflange 8 connected from alpha alumina. A flanged wick-like tube 9 made of stainless steel is concentric arranged around the solid electrolyte 2, around a KapiUarraum 10 for liquid sodium to form and to force the liquid sodium to flow over the surface of the solid electrolyte 2. Inlet holes 11 extend over the bottom of the wick-like tube 9 and allow a flow of liquid sodium from the liquid sodium chamber 4 into the capillary space 10.

Electrode means in the form of a graphite rod forms a current coil 12 and extends extending over the length of the chamber 5 for liquid sulfur. A spacer device in the form of a flanged insulating spacer 13 made of alpha-alumina has a pin portion 14, which with solid Seat within the solid electrolyte 2 sits. The spacer 13 forms an area of relatively high electrical resistance that binds or limits the solid electrolyte 2, this area from open end of solid electrolyte 2 to at least 1 cm beyond the extreme end of the glass sealant 7 extends out, with the other side of the solid electrolyte 2 is masked or covered to this portion of the solid electrolyte 2, which by the Glass sealant 7 is limited or connected to protect. A flange 15 of the spacer 13 rests on Retaining flange 8 and also forms an elongated path to prevent the flow of electrons. A stainless steel end cap 18 closes the chamber 5 for liquid sulfur, making it a round one Has recess 16 in which the flange 15 sits, and a threaded pin 19 which is in a threaded hole 20 sits in the current collector 12. A spigot on the outside of the end cap 18 forms a positive Terminal 21, and a stainless steel pin 17, which is welded to the housing 3, forms a negative connection 17th

The cell is made using Grafoil packs 24, which between the flanged housing 3, the flanged wick tube 9, the retaining flange 8 and the end cap 18 are clamped together by an outer ferrule 22 made of low-alloy steel, the Edge-welded to an end ring 23 made of low-alloy steel A collar ring 25 made of alpha aluminum oxide, which sits between the end cap 18 and the current collector 12, electrically isolates the parts from one another.

If during operation the electric cell is discharged via an external circuit (not shown), wifu uä5 liüs & igc thallium, vvciuuca mil ucni rcSiäiOii electrolyte 2 is in contact, ionized when electrons are released and forms the corresponding positive sodium ions. The electrons leave the cell via the negative terminal 17 to the external circuit, while the sodium ions are conducted via the solid electrolyte 2 to the liquid sulfur. The electrons from the external circuit are finally conducted through the current collector 12 and the graphite felt 6 to the liquid sulfur, whereby sodium polysulfides are formed with the sodium ions. That portion of the solid electrolyte, which is kept at a distance from the graphite felt 6 and current collector 12 by the spacer 13, is essentially free of electrochemical reactions and thereby protects the glass seal 7, which is provided between the solid electrolyte 2 and the holding flange 8, from being destroyed Effect of these reactions.

While the cell is being recharged, a current is provided to draw electrons through the negative terminal 17 to supply the liquid sodium, the other wire of the charging current to the positive terminal 21 is connected The flange 15 of the spacer 13 reduces the likelihood of a Short-circuit path between the end cap 18 and the solid electrolyte 2. The polysulfides that are associated with the Graphite felt 6 and the solid electrolyte 2 are in contact, dissolve, and the released sodium ions flow over the solid electrolyte 2 to sodium atoms with the electrons of the other side of the solid electrolyte 2 to form. Because of the isolated area provided by the spacer 13 find essentially no electrochemical reactions on the adjacent surface of the solid electrolyte 2 instead, and relatively few sodium ions flow through it, creating problems due to a current intensification in the solid electrolyte 2 can be avoided.

A current intensification can occur during recharging if the edge of that part of the surface of the solid electrolyte 2 in the chamber 5 for liquid sulfur, where electrochemical reactions with the polysulfides take place, is in the vicinity of the corresponding edge of the surface of the solid electrolyte 2 in the chamber 4 for liquid sodium or beyond, at which ionic reactions that form sodium atoms from the combination of sodium ions and electrons take place. An exemplary embodiment is shown in the figure, in which a portion of the solid electrolyte 2 with sulfur on one side is masked or shielded on the sodium side by the glass seal 7, which is used to connect the solid electrolyte 2 to the retaining flange 8. If the spacer 13 were not provided, then an intensification of the current would occur during the recharging, because the sodium ions which flow in the solid electrolyte 2 converge and therefore when they flow in the direction of a section of the solid electrolyte 2 which is not shielded by the glass seal, increase and could lead to a breakdown of the solid electrolyte 2. Such a situation could be introduced anywhere else in the solid electrolyte, e.g. B. in places where the liquid anode surface of the solid electrolyte is masked or shielded in some way or the solid electrolyte by a butt joint with a non-ionic: »v; ucii iciiciiucu ι cn vci uunucil lsi.

Although the invention has been described with reference to the use of a spacer device, to provide an area that is essentially free of electrochemical reactions at one end of the The chamber of the liquid cathode could of course also have a spacer device in terms of shape and arrangement

be provided so that similar areas are formed in other locations, for example around the river to smooth out sodium ions through the solid electrolyte at other local areas, which one Current intensification while the cell is being recharged.

Although the electrode device has been described as being made of graphite, it can also be made of any other carbonaceous material and can be made from a composite Construction, for example reinforced with a metal such as stainless steel, to provide structural strength and reduced electrical resistance, the carbonaceous Material a corrosion-resistant outer conductive layer for such a composite Forms electrode device. Alternatively, the electrode device can also be provided by a metal are protected in a corresponding manner against the corrosive effects of the electrochemical reactions as described, for example, in related British patent specification 15 82 845. The electrode device can also be of a hollow shape, as for example in the German patent application P 26 27 196.5.

The invention can also be incorporated into electrical cells designed to operate in a different orientation are designed as that shown in the drawing, for example in a vertical arrangement.

It goes without saying that other embodiments of spacer devices can also be used, to keep part of the solid electrolyte at a distance from the liquid cathode.

The insulating spacer 13 can also be made of another insulating material, provided that that this withstands the environment within the chamber of the liquid cathode, or it can be of composite construction (e.g. metal / ceramic) provided that the ceramic material is considered to be electrically insulating layer is arranged on the outer surface of the spacer.

1 sheet of drawings

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Claims (4)

Patent claims: 1. Electric cell with a solid electrolyte in the shape of a tube, which is on the outside at least partially a chamber for a liquid anode and in the space inside the solid electrolyte tube at least partially delimits a chamber for a liquid cathode, characterized by an electrically insulating spacer (13) in the chamber (5) for liquid cathode, which part the inner tube wall of the solid electrolyte (2) separates from the liquid cathode and is close by a portion of the solid electrolyte (2) is arranged on which otherwise during recharging the cell a current intensification takes place, wherein the electrically insulating spacer (13) the Electricity intensification prevented 2. Electrical cell according to claim 1, characterized in that the solid electrolyte (2) through a ceramic component (8) is held and attached to this by glass sealing means (7), and that the spacer device (13) extends beyond the glass sealing means (7). 3. Electrical cell according to claim 1 or 2, characterized in that the shape of the spacer device (13) forms an extended path around the periphery of the spacer device (13) around prevent electrons from flowing around. 4. Electrical cell according to one of claims 1 to 3, characterized in that the spacer device (13) is of composite construction (e.g. metal / ceramic).