AT34131B - Collector electrodes with degassing device. - Google Patents

Collector electrodes with degassing device.

Info

Publication number
AT34131B
AT34131B AT34131DA AT34131B AT 34131 B AT34131 B AT 34131B AT 34131D A AT34131D A AT 34131DA AT 34131 B AT34131 B AT 34131B
Authority
AT
Austria
Prior art keywords
collector electrodes
degassing device
electrolyte
current
gas bubbles
Prior art date
Application number
Other languages
German (de)
Original Assignee
Phoenix Elektrotechnische Ges
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Phoenix Elektrotechnische Ges filed Critical Phoenix Elektrotechnische Ges
Application granted granted Critical
Publication of AT34131B publication Critical patent/AT34131B/en

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Description

  

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 EMI1.1 
 
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 verbunden sind. Die Richtung des Stromlaufes im Elektrolyt ist durch wagrechte Pfeilstriche angedeutet worden und sollen die punktierten, nach oben gekrümmten Pfeilstriche die aus den Gruben oder Hohlräumen d kommenden Gasströme veranschaulichen. 



   Hieraus geht hervor, dass nach Ansicht der Erfinderin die beabsichtigte neue Wirksamkeit und eine wesentliche Steigerung der Kapazität eintritt, denn der z. B. in die positive Elektrode   (Fig. l)   eintretende   Strom fliesst infolge   der vielen und ziemlich tief in die wirksame Masse eindringenden Gratspitzen der Metallplatte durch den gesamten Körper der wirksamen Masse nach dem isolierenden Träger des letzteren und durch die infolge der Krümmungen oder Wellungen vermehrten vielfachen Öffnungen des Masseträgers auch durch diesen hindurch und durch den Elektrolyt zur anderen negativen Elektrode, woselbst er wieder durch die vielfachen Öffnungen und der mit dem Elektrolyt in Berührung kommenden Stellen der wirksamen Masse in diese eindringt,

   um schliesslich mittels der auch dort eingreifenden Gratkanten oder Spitzen der Metallplatte fortgeleitet zu werden. 
 EMI2.1 
 und   keine leitende Metallfäche   haben. 



   Es ist selbstverständlich, dass auch an jener Stromausflussstelle, d. h. an den vielfachen   kleinen Öffnungen des isolierenden Masseträgers Gasblasen entstehen müssen. Da aber die Mehrzahl   der aus der wirksamen Masse kommenden Gase den viel bequemeren Weg durch   die ziemlich   
 EMI2.2 
 so ist hiedurch die Menge der Gase oder Gasblasen an der Elektrodenseite. die zum Austritt des   elektrischen Stromes zum Elektrolyt benutzt wird, erheblich verringert und ist infolgedessen   auch der Widerstand im Elektrolyt erheblich vermindert bew. ist ein innerer Widerstand in der   wirksamen   Masse selbst sonst nicht vorhanden und die Kapazität wesentlich   erhöht worden.   



  Die Gasblasen finden also an jenen Elektrodenseiten einen vermehrten und   leichten Ausweg.   wo eine Stromleitung im Elektrolyt nicht stattfindet, dagegen ist an den anderen Elektrodenseiten.   durch   welche der Strom im   Elektrolyt fliesst, die   Entstehung der Gasblasen erheblich vermindert 
 EMI2.3 




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 are connected. The direction of the current flow in the electrolyte has been indicated by horizontal arrow lines and the dotted, upwardly curved arrow lines are intended to illustrate the gas flows coming out of the pits or cavities d.



   From this it can be seen that, in the opinion of the inventor, the intended new effectiveness and a substantial increase in capacity occurs, because the z. B. in the positive electrode (Fig. 1) entering current flows as a result of the many and rather deeply penetrating ridge tips of the metal plate through the entire body of the effective mass to the insulating support of the latter and through the increased due to the curvatures or corrugations multiple openings of the mass carrier also through this and through the electrolyte to the other negative electrode, where it penetrates again through the multiple openings and the areas of the effective mass that come into contact with the electrolyte,

   in order to finally be carried away by means of the ridge edges or tips of the metal plate that also engage there.
 EMI2.1
 and have no conductive metal surface.



   It goes without saying that also at that current outlet point, i. H. Gas bubbles must arise at the multiple small openings in the insulating mass carrier. But since the majority of the gases coming from the effective mass take the much more convenient route through the fairly
 EMI2.2
 so is the amount of gases or gas bubbles on the electrode side. which is used for the discharge of the electric current to the electrolyte is considerably reduced and, as a result, the resistance in the electrolyte is also considerably reduced, otherwise an internal resistance in the effective mass itself is not present and the capacitance has been significantly increased.



  The gas bubbles therefore find an increased and easier way out on those electrode sides. where there is no current conduction in the electrolyte, it is on the other electrode sides. through which the current in the electrolyte flows, the formation of gas bubbles is considerably reduced
 EMI2.3
AT34131D 1905-06-19 1905-06-19 Collector electrodes with degassing device. AT34131B (en)

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
AT34131T 1905-06-19

Publications (1)

Publication Number Publication Date
AT34131B true AT34131B (en) 1908-08-25

Family

ID=3550149

Family Applications (1)

Application Number Title Priority Date Filing Date
AT34131D AT34131B (en) 1905-06-19 1905-06-19 Collector electrodes with degassing device.

Country Status (1)

Country Link
AT (1) AT34131B (en)

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