BE629670A - - Google Patents

Description

       

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 EMI1.1
 b for cellutoi l ('ctro1vtl ('! 1lu,
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 The lending ir'Yerttia (1 mi, rh;, t.orte lux, 11 the IC t t'Odf "'for o.1.l \ 11ee 6leo troly tiqs.



  In the cells tStectrolyl1f1I \., "Intir the tH" ctN1Y'8 of brines or dam the ÍJn.ra b1J'fi do C:) l1fL \ rt cl "ln UnI such as the batteries at cOlllbutlUb1 .., the cat ' : m! ee! .on more oonrl. \ rt "8 are faltee of iron or steel. These '; lect1' \ J..s, CJ.II! 'I9 de 1 "1If fl1lhtf'! R'- tiett and A corrosion in: '1111 8U actde Inn' 10I \ C: t the conc'tion of cells for example, her ° r,% -: \. ". vcLl c =, t, rur ,, direct contact with the & nolyte as a result of 1Lttayne r8: '[said to iron halogens in, .. Ut. '1 aqueous. These rit eOl1vlt'noAnt therefore not for bipolar cells.



  In addition, it is said that La ont.e (its; otN, .t, int miter the anode and the oathode of a cell J \ "'cLr, .1yt,! (; LItIr Jans Il. ,, 011. (letu,; m

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 and form at n 1,., IIU donated electrode e6 due to a number dt1.4Iel \ t 'iltmt one ert 1! oi4rt.illintoil item las them 41 $ utrodest bond las 088 \ 1l1l .. dleukrutyttquds Industrielles 11 est
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 very important, from the point of quick operation of the sows,
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 reduce to j.lnlulUl, l the drop in potential during eleotrolrrei and this condition dictates the use of electrodea rroeeadunt the lowest #urtenslon dll: '\ 1 the yatlxa utility.

   By tuu: ple, vil is ccrurar.t don alkali cells where a 4481w of, nent of hyJrun! 'N <eu, 1'q'IU;' I1 'occurs to use a niokel anode and a ontimde de t'or, build uiiti- # datio o..rll1IHU celltiloo, It is tit4i, ort4kit pouf of uutrvi rainoris "1, CIlr. rluh the * spawning of too", t.lonIl81.:. rt, d. té dutre MU; rtir, trmra III ehlll. tU tlol1T \ Utl. Un1l1, dative certvinl 0) t <, the cell reads be UselUIl'l / lcnt! LLI, pllfI4. do not give up
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 potential drop only 0.1 volts.
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  R4ce., T., Ert on 4.-Iii has point electrodes avoiding the probities of corrosion of 1ctrel of steel; it must not be r, plnC8 rJrll1rclt com-t cell * in graphite and Heliteit tunt L the ennolyte and a catholyte, oe which prrnet to use dp.! .seHblùu bipolar cells in group d4 cellulogt brouets These cells are described in Australian Patent No. 230,799. Clins these, cultlcells, a bipolar titanium electrode forms the partition separating two cells, a side of the atunt electrode the cbtllode of a cell and the other.
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 the anode side of the other cell.

   Therefore, these cells
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 are extremely: erncn t¯Ç9!,. pltCtt> 1 and do not require an expensive and energy-dissipating electrical connection between the anodes and the cathodes; the dlstwice between the electrodes is weak, the drop
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 of potential in the electrolyte and in the electrodes is low
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 high, and it is possible to achieve densities of
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 considerable 1 these cells therefore have an overall operating voltage
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 ball. low and one., laughs at cilizicity per unit area and unit price. However, the titAJ'e heads have a relatively high hydrogen 8Uftttfld \ '\.



  ; 1

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 ..; r ',; '. It is also known that finely divided coatings of platinum and palladium deposited * on the iron backing of 104lectro avoid the drawbacks of electrodes dictating by removing the hydrogen surge, but these deposits are very expensive and expensive. do not always have a long enough service life to stretch
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 economical.



   It has now been discovered that by depositing certain alloys on electrodes made of metal, in particular steel, and special-
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 By using titanium electrodes, electrodes are obtained which have considerable service life and which have reduced hydrogen surge when used as cathodes in electrolytes.



     The invention provides an electrode comprising a support formed of a metal suitable for the construction of solid electrodes, at least a part of the surface of this support being covered with a conductive coating of an alloy of iron and an iron. metal selected from the group of molybdenum and tungsten.



   It also provides an electrode comprising a support formed of a metal suitable for the construction of solid electrodes, at least part of the surface of this support being reflected.
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 covered with a conductive coating of an alloy of uolybdt-ne -and a secondary metal selected from the group consisting of nickel and cobalt.
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  The invention also provides an electrode comprising a support formed of a metal suitable for electrical construction. massive trodes and of which at least part of the surface is
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 .covered with a conductive coating of a ternary a111sEe of a primary metal selected from the group formed by moylbdenum and
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 tungsten with two metals encindn! ree selected from the group formed by cobalt, nickel and iron.



  It further provides an electrolytic cell which includes a cathode formed of a metal suitable for construction.

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 .-. of massive electrodes, part or all of the * .Hitt * 9 * A * this cathode being covered with either an çohoiofctu coating? ;? # <##### - <* #. # <# <&, # <- - "* # Jr of an alloy of a primary metal chosen from the group fora * by
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 molybdenum and tungsten and iron, or a coating consisting of a coma molybdenum alloy, @ primary metal with a #:.

    '. \. ; -: secondary metal chosen from the group formed by nickel and cobalt, with a conductive coating of a ternary alloy
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 of a primary metal chosen from the group formed by molybdenum and tungsten and of two secondary metals chosen from the group formed by cobalt, nickel and iron,
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 A preferred metal for the alloy bearing electrode is iron, preferably under the mild steel forint. Another preferred metal is titanium which here denotes pure titanium or an alloy containing more than 50% by weight of titanium.



   The electrodes of the invention can take the form of a line, of tubes, of rods, of flat or curved sheets of sheet.
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 perforated, expanded metal, non-woven fabric or porous metal powder compacted or sintered. '.



   Although the electrodes of the invention can be used generally as cathodes, they are particularly useful in the form of hydrogen cathodes, that is, working in contact with hydrogen.



  When the electrodes of the present invention are used as cathodes in fuel cells, higher operating voltage, faster reaction rate, better capacity and better efficiency are realized.
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  The invention also aims to produce electricity using an enmtmatible battery, the cathode of which is an electrode according to the present invention.



   The invention is particularly applicable to the electrolytic production of hydrogen from aqueous electrolytes.

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 The invention therefore thus provides a process1 4 '<< l <ctr <tly (from an aqueous electrolyte which releases hyirogzno to a cathode in accordance with the invention, the cathodes of the binder. Í.rUclll1. rftr,.,. \ t lntdrs¯ sweating for the <! lwctrolyee of solutions of alkaline chlorides * in order to obtain lT ;; 1droCt.ne, der iylrJ;>, 1.s 1 oa 1 lnw st of chlorine, or alkali chlorites. When one .r;, 1'1tt. do 1'h) 'dr:] (n.,;,' iodluu hydroxide and etitore from saturates l $ aid4 of the cathodes of lnYt1r: t ('n, In t181on da 1ftrvlce at oon.

   Ld4f.b1ejC '! pèdttite, and one gets a rn-dunant 4ri; ir4,4ttqite and a r4.tatanc. k la corro81LJn a..H 1ort <lI.



  According to a for w (irf jr 5th of realization he Invention a 'e11t1I1 tClectrolytl'1 "' for ldct.rols 1 oolutiont - quau8 .. de cliloride de t'di'in ')" t cnr: ct' rt ^ s6A e; ue; Ilifi the heard is an electrode eonf-T'-c l'lltv, .., t, .t, m.



  According to another forr.e ..r.; R'r '; e of the Invention, a * 41 * bipolar ctrude is constituted by I :,' g: 3e in Utano, arr 1I01n. a partle of the 8111 'race .11.1 (1 (' 1 ': 0 -from the eloctrid side as covered by a rftv.lel, the "1t C'HH1'; <: I. (! 'lr of a, "{.tal nr, h]. from the | r up of the platinum and to the anointing a part of the INr (, 10f. 'ClJt.lH> lU" I ".. 4hnt reopened with an ovllr1'Jct coating. wur of an all tate of a 114tal chosen in the Croupe ft) rae by the e 1r> lyùd ne and the tunstne et de fer, or d # tàn coating Cond "cle'11 'of an eUt !!. of , fI.r> 1yb- dtrne and of a secondary indtel chosen from the yrotjij * for: 4 pure cobalt and nickel, aolt of a rvtc, rt e inducer of a ternary el1hr.o of a primary metal chosen from the (1'IIIIp. ('Jr ... 44or molybdena and tin4! ltene with dwrx -..-' # t 'u bzz-otomis in the group formed by the cobnlt, In r; cHal was le t'trr.



  By Rudtal noble du ir01J) O d'i 1'd.tnlt ", one pritfrid ruthenium, rhodium, allaAin;, one {one, Iridium or platinum or an alloy of two to several of these , "tal1x. the invention further provides an electrolytic cell which can be assembled into "aulticel4lilep" of the type described in 1 <brw-

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   and Australian No. 230,799 and comprising a bipolar electrode made of a titanium steel, at Mina part of the anodal surface of this electrode being covered with a conductive coating.
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 A noble metal containing a platinum group and having at least part of the cathodic surface 4ta-it covers the roof with a conductive rRVteaent of an alloy of a 4tai chosen from.

   the troop rùr..d by molybdenum and tungatene with iron, or a conductive coating of a rcolybdenum alloy with a metal chosen from group r ') r: .. by cibelt and nickel , roof of a cladding of a ternary wake of a primary ai <5tal selected from the group formed by ie r.dn 'and tinestene and two secondary metals selected from the group forad by cobalt, nickel and iron, the bipolar electrode which forms the partition between the cathodic and wnjdic co-parts of adjacent cells. With cells !! of this last type we can, if we are delirious, replace the layer w <') dlque cn ,, 1.t.al noble in connectai. The side of the titanium opposite * to that coated with the alloy of molybdenum or tungsten has a 411) of graphite.
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  The preferred combination of compositions for molybdenum or tunin alloys will end at lau1 &. in Table 1. 81 the most advantageous composition to.ibe rtann the gaa ... t, shown on the right in Table I, the reduction of the hydro-
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 annoyance is lIuu1: .u.



  The above percentages are all expressed by weight. It has been established that the layers deposited by 4lactrolysa contain varying amounts which can reach several percent of non-metallic constituents such as oxides.
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 At these ht b1e! "Coticentrations, the oxides: atalliquca lend @ n # to t. Bect the 8'1lrtffillL () n in limiting them to measurement errors 1 therefore, all 13 results are expressed in percent of the known fenif t "ant9 u, (italllrtues.

   Analysis of very thin alloys is difficult, and the values are given with an approximation which is believed to be + 2%.

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 1, IAPLEA1LI It
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 Preferred Oammw Qan:.: The most AVûnUçeiise Alloy Constituent pri- Constituent Cnnti.t.ant pr'- Conatttu * AB trunk A,, <drive li Ïn 1 rt A, <in an me- weight , 6 by weight weight ce'natre. bzz, .- .¯r ......,., -... ¯ ..... w ...... war rrf ^ .e. '' L'f ..,.



  Mo Fe 5 to 704 Mo (100-A), c Y * AS to 65 .40 tl () l) -A, i1 W Fe 5 to gus W Fe 15 to A 6r) W w b'e M Co 5 70 Mo Co 4 5 A 70 f No m Co No Ni. 5 to 65% Mo Ni b5 to 53 <Ho w Ni r "Range uttered 0 if MLli 1Z plu? Will" .t <- .¯ ......-... ¯ .... ¯.s- ¯ ¯¯¯ ¯ ¯.¯¯¯.¯ ......... ¯¯¯¯¯ ..¯¯ .. # 4 * H?. *.



  Alloy Primary Constituent Constituent Constituent thr- Ciiatttti- ABC mayor A,; in in secondary 8, tinire C, in a: t ready- weight 4 in polish P) Ids eaire A, <.



  ABC No Ni Po 5 60.lj Mo (100-A-C) <Ni (100-A-B), 4 y * 50 60% ma No Mi Co at 60.! Mo ^ Ni Co i0 è 60 Mo !! 0 Co F 5 60 me Co Fe 5a to 6o Me W Co Ni 5 & 6o, w Co Mi 50 \ 60 .: w W Co Fe 5 to 60 'W Co Fe 50 k 6o! w
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 The alloys for the cathode of the snuff, the invention can.
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 be applied in the surface of the in.Hal "lq'ie aop ort by various onnua prooédés.

   They can be detonated by electrolysis, by sintering and with any pressure or not: '\ lftne rt8 n- <rate rr: powder deposited under vacuum, plllvt; r1f1etion des .r, -' t., M ua by lo ;;. t (1;, tt of Il; 1.1 e powder or a tu.18ngf9 of metals in r; o'ldr @ l on te) le, r, '\. Allt ( } 118, or by application of a paint of, "; tlill1! T <It1on ia the alloy on a metallic sheet and ctaaion t, I'r" 111 "., R..eJd <diiiis which the metals of the coating : Alloy üent are ri :, l1 (utS, 111: J ror.e flneise divided * in an organic resin 8YlltúIJe and da S,) 1vnllt.



  The pre'4 "d. \\ thread eyelash 1 ',, 1', ll ':' is the 4tectl'otyu.



  ¯ De nozàbruittas coctpowl, tL m .1 "!) U! Is r3lectr .-. Lytt (ms; u1

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 can be used to deposit these alloys on metals have been described in the literature. For tungsten alloys. tungsten tioxide or soluble tungstate is used with
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 a s'1 Su radtal codupoaé. Hydroxyorganic acids oc their moles of sodiam and potassium are added in a conventional manner.
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 to complex the metals of the far group; all1 chloride, uonlu4a or ammonium asltate can be added and some baths also include inert salts 0 ') 1.1.re sodium or pola'! 3tQ chloride, a.

   The electrolytic baths for the application of the bindings of ol, bd; are not sel1bV.bles with the tungsten baths by the same composition, the trioxide of: volyodane or a soluble fiolybdate rez placing the compounds analogies of tungsten. The concentration of hydrogen ions in the bath can be adjusted to the desired value by ammonia or sodiam hydroxide solutions. Many
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 baths currently use citric or tartaric acid or their sodium and / or potassium salts. Electrolytic deposition rrocda are described, for example in the following articles *? A. Brenner, P. Burkhead and E. Soeg4ailler, Journal Reaearch of the Mail. Bur. Standards, 12, 351 (1947), and T.F. vrantmovLoti-Zabliidovskayae A.I. Zayats and Y.T.

   Barchuk,
Ukrain, Khim. Zhur. 25, 713 (1959).



   All these baths and other known baths give coatings. satisfactory for some time, but it has been found that particularly durable coatings can be obtained from certain compositions.



   The invention also provides an electro-deposition process. lytic on a metal suitable for the construction of electrodes
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 mass of a, úolybdime-nlckel alloy from a bath comprising 32 to 45 g NaMo04.2H20, 10 to 13 g of NiC12.6H20, 27 to 40 g of NR4P207 and from 70 to 100 g of NaHCO3 per liter of aqueous solution under a current (direct) dcnaitn of? has 25 amps per drn2 and a temperature of 40 to 70 C.



  It p rocure and% in addition to a deposition process él.ctrt) l: t1 \.

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 on a 4itai suitable for the C "J! l1tt.r'Ht. 1 m d'lactrMla4 4aootvos of a Mlybd alloy: .ra.n1a ', (e! .c" tlatt from a lmtn otnttfiant 32 4 45 1 of Ma 2 Moo 2112fit 5.2 h 6.2 of iiCl? .41lZ, 5.4 fc 6.5 1 CoC12.6HaO, 36 A it g of ila4. TOfl <<), 70 100 4 of N HCî 3 and 1.2 1.9 8 of I1ZH.! 1Z8J ner liter of 'Jl'Jt11n At1Ill "mua il' * 4 <! tt <of current included * e-tr- 2.5 and 15 will know by 4j2 and a teip4r & ttir * of $ 5 i 7C.



  Lit.rentian proctire 6.:e ,, t on n titic (14 de () t'4t t 41 * 0- trolyttqite on im #Tr .... 1 a: fmxmr.t vwr la c ',' utrJct, 1. ') N of t5uotpod i
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 aaelves of a rolybditio-n ttlliage-n 1 e, -, tl -fer from an oanteriait bath j2 5 of MaHoO, .2HJ, 4 4 5 1 (the yet: lj.6tl4, 584 to 6 # 6 1 of H1C12861120 ,) 6 to 54 1 of NnE'o7. lOtl2n, 70 to lio 410 Ha11C03 and 1.2 1.8 d of H2H4.H2n0, 6 to the .1ft 51 ", l1. of amrartt coriprison between 5 and 15 li. '": 1pÀre .. "r Il and 4, nit tftip4r & tqire from 50 to 70 ° C.



  8ut7a.it another proc (* d 5 o'.e'Jre of the deposit. FÍhctroLytlft'1e on corresponding totals for c # 'itrictln <J'.H..ctrod ... meut ... on Ftoouvrw du tit4 .ie nu un ïlî ". # of ti t.we du <tot": SOS * -. weight of titanium or a .1l11 \. IIOlyl..t ',!, .-. rftr-or) rl / l1t 1 pnrtlr of a bath l)) ntfl'1lr.t 32 to 45 1 of Ne2.H.OL ..? HzO, 4 damn Ae ErCl.brlz0, 5 # 3 to 6 # 5 g of COCI 2 * 6il 20 @ 36 to i4 I NaP? O'.li7N ?, 70 100 dw llaHC03 and 1,2 to lis a de "2H4KzS0411t .., f 'm4 der.lflU d .0 urttnt de S 15 oapèrei by d..2 and 11 111 \ 1'1 t, o.lp. {Ro1t.l1re eu .-. Pria * between 50 bt 70 "C.
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  The rirface 1e the table of .'t.il., Are l4tra s .11! '11'8 pretreatments for (> JCJ l1t, .r 1- * #' # t t1 lt cl 10'1l of ilt- liage and au, l'trace affeettve ie% t hre '1,' '' ' 'lIA, jar -m treated * - superficial merit or sort r "brt1111tJ1t tale, 1., titanium by h, 1tnftll' of titanium ert powder paitr get wee r.,: t'1 <! co,) 5t! t #t nr eantant a large effective area. Un cwrc., tn 11 '- ", \) ru de) r'1c.!. IJs tftt pretreatment and ti'A'I :: e :: tat1,')., dd 1 .. 5It! '' 'C hffectve 11 ... tH .. "are known. Most of these pritr.il t., i itn a"' r. '. \ t' 111 damn) mtt.9fia <mt and a good adh'fr meo du r ... 6 '' 'I''lt 1'i'allti'1! ft mir le

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 titanium support, but the dur4bilitiy of the coating under prolonged chemical and chemical attack conditions varies 1.ria.nt.

   Many revlnents .. in practice last for more than a few weeks2. It has been found that particularly durable deposits of the a111: es of the invention can be drilled from titanium, thus difficult to cover in a durable and satisfactory manner, when the titanium is p "" c1.rdt '. by tluon- acid
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 boric.
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  In a 4hctro11t.lque dap-1t process on titanium to obtain, and electrodes of the [Thirty invention, titanium is pre-treated with a fluurobortic acid solution not containing a 2 wt / v molie. fluroborlqul acid.



  Couparea with platinized titanium cntuodes the cathodes
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 of titanium of the present invention have the advantage of being very
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 less on4reunou; Against the classic iron or steel cataodee they have the advantage of an I1nrhnll1.on of hyl1ro,;, ne weaker and a, net lllIr. risiatnnck corrosion and, by
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 therefore, they are suitable for the construction of electrodes
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 bipolar poles pOlr mul ttcell'Jh 1cttvlytlquet, which constitutes a progress con9td '<r <' bla suc the current practice of using cathodes of iron and? finally separated graphite anodes, oo'a-
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 trimmed with a composite bipolar electrode in which a
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 iron grid or tale uses co.r ..:

  The cathode is Ippl1'lllt eOll welded in C)) nhct eiectrtquo on the back of a titanium tale or platinized titanium anode, they have the advantage of a much more sl-apl * construction, no larger coj ' pAoit.4, simplified maintenance and the elimination of corrosion at bi.aital-tail gaskets. Yet another advantage of the invention is that the 4lec-
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 trodes can be prepared from existing electrodes
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 made of mild steel by coating electrlJlytif11Ht, nent The steel electrodes have a decap6.ge. The costs of transforming existing cells into cells offering the small
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 cathodic overvoltage according to the present invention are therefore not very significant.

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     Lowering the overvoltage on the cathodes of the
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 proeente Invention can be shown in dem solutions of pure alkaline etilorireii and iodurea or in ordinary electrolyte of diaphragm cells and chlorate cells and. iodate.

   When
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 only bipolar electrodes reviving the funo l) r'l'éré of Illn- vention August asqn.bl4mii for fonor ctea '3ultlc''Huloa!' * ctrol / - tics and if chloride is .lctro? ys3 for pr niulre in the water of the cell dta; hrayae of sodium hydroxide and of chlorine or, in the case of the cells o..Jor te, of sodium chlorate, one obtains tilectrlqitcs returns comparable to those of classical diaphragm and chlorate cells. The reride- monta, however, party cit 1 i4renie, .i t don der.iitt'13 of high current, are greater than those of '! lactro'ytlqnes icultlcsllules in which the titanium is uMUs'5 co :: P cathode * and ant t also equal to or greater than those obtained in dos aultic llul 3 t} 'L''f- trolytiqiiem k electrodes p] .atlnrf * 9 or!) iron platinges and cathodes.



  The reduced hydroyan overvoltage of the ct, adaa of the pre- invention, under practical operating conditions is shown in Table II from the comparison with the cathode potential.
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 as possible means of "aged" electrodes, that is, highly ruined steel leotrodes, uncoated metal electrodes and platinized titanium electrodes;

   We know, and these experiences confirm it, that the :! Rusted steel electrodes have the lowest cathodic potential that can be practically achieved with steel electrodes.
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  The ion tones shown in Table II c.prsnrert the ilotentiole of Liquid Junction and the small amount of otunic potential of the column of Electrolyte between the side and the tip of the tugi capillary; in and the gotautlel of polarization of oon- centration at the surface of the cathode and, by c, nsfqtient, do not represent the overvoltages prapri'uflnt called, ... they i-esurex between different experiments '' oq .-, tit cn :. by-blrs 4vtre them. ,

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 TABLE II
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 Tefaraturs 6O0C
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 Composition of Exem- Compost ..

   Lower Potential- Density Solu- the surface of ple tion in de aatho-! Slow de tion the catJ10Je in n weight by the aqueous sur- current doox steel voltage ratio Apre9 / electro coated electro- compare here lyte of normal with hydro, ¯7bne cier in soft volts. -, - .I: 9'.111.: L ¯¯¯ # ¯¯¯ Mild steel 1 1.05 - rusted not 1.20 - 10 coated 1.28 - 30 (cora- arI base! 1! ! on) ...------- r¯¯¯¯¯- alloyed tH1r8 2 55 W 0.96 0.09 1 iron 45 <Fe 1.02 omitted 0 10 1.05 0,: 3 30 alloy 3 33.

   W 0.97 0.08 1 tun.'BtJine-iron 62 Ne 1.05 0.15 10 ¯ 1.09 0.19 30 mo- 4 alloy 44A Mo 0.90 0.15 1 lybdenum-cobalt 564 Co 0.96 0.24 10 0.99 0.29 30 Mo- alloy 5 6 '/, (Mo 0.91 0.14 1 lybdenum-cobalt 33! Co 0.98 0.22 10 1.01 0.27 30 Alloy ao- 6,451 Mo 0.93 0.12 1 lybd ': no-cobalt 55, Co 1.00 0.20 10 ¯¯¯¯ ¯¯¯¯ ¯¯¯¯ 1.03 0.25 30 Alloy mo- 7564 Mo 0.90 0.15 1100 g / 1 lb, 'me-n1Cl <: el 44 <Ni 0.95 0.25 10 NaOH 0.97 0.31 30 zao g / 1 Mm ;: ; 1 (;

  el 8 49 Mto 0.88 0.17 1 NaC1 ¯ ¯ 5H NI 0.92 0.28 10 ¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯ 0.94 0.34 30 Molyb- 9 alloy 50.1 Mo 0.90 0.15 1 dene-nickel 50% Ni 0.95 0.25 10 ¯¯¯¯¯¯¯¯¯¯¯¯¯¯ 0.97 0.31 30 '# Molyb alloy 10 55â Mo 0.93 0.12 1 i di'ne-for 45. <Fe 0.99 0.21 10 #### 1.02 0.26 30 Molyb-alloy 11 62 * Ho 0.91 0 14 1 Il dene-iron 384 Fe 1.02 0.18 10 - ¯ 1.0? 0.21 30 Motyb- alloy 12 55'6 Mo 0.92 0.13 1 -1 dene-for -cobalt 0.99 0.21 10 - 1.02 0.26 30 Uolyb- alloy 13 559 Mo 0.90 0, 15 1 dAne- niekel-fer 0 95 0 25 10 0.98 0.30 30

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 EMI13.1
 .- <, ".:":

   IHJL. (I "- '8U1pJr, ture W.C
 EMI13.2
 Composition of & xe.: - CoJ & pe) 81- Lower Potential- Denfltté * 8olu- the surface of the pie tton in de oit-io-: .. "t de tion the cathode in ne palet. By the sur- Gourant. 1 . ", .. mild steel cn7; .rt face Aapiree / ilactro coated with echctro- cO: lpar6 dm2 lyte of: mra: t a- 4 Nydra- c10r '## gine en hux volta r JI! lll4 Alloy taolyb- 14 5St Ho 0 (! 0.17 1 4n..n1o "l1. - ---- 0 'Q, 2 10 100, 11;: aabaH, 0,' 1 '0, i5' 1) WltrH '!' 1I1N. R1 i i .. - 1'if ^ c nl fm Y aset., Rt, r ....: t .aa .s 1 ... Q2f '"J.



  GarlicUn * molyb- 15 Mo U,? 6 0,0 * Cl "d nr-ni0kel 75,1 NI! Tu tJ, tfa 10 ',! T! 6 Ij, 1.l N # ¯. ...; # # '- ##. -.-..-----' "## - #, Co.npor! - i'ote: zttel Abntaaa- Rotu- Compocition ExM- Coiponl- Potential Abntahii- Dw <it4 Polu- de la turfeoe pie tton, do cutiio-; Jflqt d. of tion of the cathode n. en de par lu sur- 0or 4f; nm ij, of titanium weight tension ratio rnnt / i 'lec4 coated 1'.: 1, .CtN- rHéron- A / d2 trolyte dtt normal c * 1 Ti A ryiro- p ' ne in V) 1 .., ¯ ¯ .....



  Sheet metal 18 170, 1.12 - 1 tanium 130 1.7 10 (not dreamed - 1, '36 30! T1e} --- "" 81 "" "------." - -. . --.. -----. --- ....-.......-... - ...- ..........- ..



  Mild steel 18 1.05 0.07 1 (rust 1.24 0.07 10 (uncoated) 1.28 0.08 30 Raolyfr- 18 75 'Nl alloy 0.97 0 15 1 dne..n1ckel 25, Mo 1.05 0,; '2 1.0 #; = * - ¯- 1.09 0 27 30 7 Alloy 19 J2; <W 0.96 0.16 l "1 tungatan-iron 48 Fe 1.02 û, i5 10 --- ¯.¯ = -¯ ... ¯-¯1., Q.¯¯¯¯3 '.? ¯ -, - ------ 1 Allir.ge 20 55- <W 0 89 0.23 1 i tungsten-iron <45. <Fe 1: U1 0.6 10 ¯¯¯¯¯¯¯¯¯ 1.07 o, z9 34 i Alloy 21¯¯ 5g W 0.99 u, 13 1 100 g / 1 t ', mg8tne..ter ..--: 42; (Fe 1.05 0.22 10 Na0lt ¯¯¯ ¯¯¯¯¯1'¯ ¯¯¯ 1.01 0 JO oo cIl' Molyb-alloy 22 50 (Mo 0.93 o 19 1 dne-iron 50 <Fe, y.3 0.9 10 1, CO O, 1 30 Molyb-alloy 23 59 o 0.96 0.16 1 dnne-iron 41j Fe 1.02 o, <<! 5 10 ¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯ 1.05 0.31 30

 <Desc / Clms Page number 14>

 
 EMI14.1
 ARRAY? I titiltp) ¯ ..u #i "
 EMI14.2
 Composition ZxM- CoMtaJL- Lower Potential- Peneite 0olu ;;

   of 11 surface pi * tlon, of cutiio- of of tlon 1 of In cathode n * in by the overcurrent aqueUM r of titanium weight ratio 1 voltage A / da'2 of elee. ràflrtn- trol1t. from norn.ale this T1 to hydrogen in "y ---------........................-- - --....-- ¯.Y5! .. ly- - ..... "" - "'! 48¯" "'" ,, ....,.



  AllURe luolYb- 24 56% Mo 0.90 0.22 1.1. due-'1Lokel '44.' Nl 0.95 0, J2 10 - 0.97. 0.39 30;, - <# - bzz N-tot # .. o <* <- tNf ttMtttHf t br f Af ^ t 11 '...., ...-. Rit- "' .f ,. .. '' '.: t 11 "" ..¯ ....... MM <to AlU <K <' 11 \ 11I'1 "100 </ 1 dtnenteNel 0 4tH Ho 0.91 0.21 1 AedN 51 (NI r7, Jf 0,) t 10 W0 </ 1 0, Vrt 7, 3A 30 IwGl A1UI. \ Elllol:, 'b- 26 Mi Ho 0.90 0.22 1,. dhno-oobnit 46, 'Co 0.90 0.29 10 1, G2 0.34 30 All1.8' molyb- 27 62 Mo 0.92 0.20 1 dna-eobttlt 3a Co 0.98 0.29 10 ¯ ¯ # ¯ 1.01 0.35 30 Al1 "1ege Illolyb- 28 50; <Mo 0.88 0.24 1 nickel-done- 0.91 0.36 10 cobalt ¯¯¯¯¯ 0.93 O, 1 , 3 30, A] olyb-29 55 linen; b Mo 0.91 0.21 1 - # .-. '". dtI.-nlcl \ el- 0.97 0.30 10 cobalt ¯¯¯¯¯¯¯ 1, OR 0.36 30 -: ¯'o AlUfge irtolyb- 30 S5 Mo 0.91 z 0.21 1 dbne- ntckel- 0.97 -, 0.30 10 for ¯ 1.00 '. 0.36 30,, Molyb-31 alloy 55JC Mo 0.92 0.20 1 # '. / #':

   V F dne-cobalt- 0.99 o '0.28 10; \. {- :: -,' ", iron 1.02>" 0.34 30 '<-,' 0 ", .." ...

 <Desc / Clms Page number 15>

 



   Electrolytic cells comprising electrodes;. According to the present invention will be described hereinafter with reference to the accompanying schematic drawings.



   In these drawings
 EMI15.1
 Fig.l is a view in vertical section ach4 -.! Litiqtie by. the center of a diaphragm cell perp <'rd! eulaire3er.t tux electrodes (P denoting the anolyte and H the cn l.tol yte).



  Fig. 2 is a vertical section r, with the center i an as $ * .-, binding of bipolar-type chlorate cells;
 EMI15.2
 . Fig. 3 is a vertical section of the saser: cell lining,, 1 chlorate following ia line a-a of Fig. 2 and
Fig. is a vertical section of an assembly of cells
 EMI15.3
 . '#. ¯ to diaphrngae.



  The experiments in leborntaire 1 to 15 are carried out by drawing a diaphragm cell with a vertical submerged cathode (arrrerr6sentée ach4nmtique) 3cnt in Fig.l. The cell is a glass container whose ratio between the. height, width (cross section of the cell) and length (plane of the @ electrodes and of the
 EMI15.4
 diaphragm) is about 2il. On the ile of the dtaeira, the walls 101 of the cell are made of glass; all liquid tight seals are made by silicone rubber rings.
 EMI15.5
 A graphite anode 102 and the interchangeable cal'.ode 104 are connected to opposing blades of a direct current source.

   The anode and cathode compartments are separated from each other
 EMI15.6
 by a periaélble porous disphragne in polyethylene 103. In order to avoid backscattering of the anodic products, a relatively large current of electrolyte is maintained in the compartments of the cell. The inlet and outlet ports for the electrolyte,
 EMI15.7
 , the polyte, hydrogen and chlorine not shown are arranged in the usual way for Y <"<eelL; tter. diaphruc"! * to ortho- .5 from vertical submerged.



   The cathodic potential is resured by means of a Lugpln 105 capillary which penetrates into the upper part of the cell.

 <Desc / Clms Page number 16>

 ot is extended to the vicinity of the middle of the cathode. The Luggin capillary is connected usually known by an elec-
 EMI16.1
 trolyt111, .e 3 ne electrode of the unrestrained calomel (not shown). The cell carrying fluid contains 100 g of NaOH and 200 g of tlaCl per liter.

   The interchangeable cathodes are prepared as shown in the examples and a series of tests are carried out for each current density chosen after careful balancing of the experimental conditions. The'! results shown in table II are the means of several determinations.
 EMI16.2
 



  On the!! h'iws. 2 and 3 the assFrb7ege of bipolar chlorate cells co morend two cells? A and B of Identical dimensions.



  The outer end of cell A is forced with a titanium sheet 4 on the inner surface of which has been coated with a platinum coating 5. The opposite wall of cell A is constituted by a titar.e sheet 6, the inner surface of which 7 has been
 EMI16.3
 eapsis to acid.

   The other side of the titanium sheet 6 is covered with a layer of platinum 8 applied so as to constitute the inner wall of cell D. The wall 0 [1 raised of cell B comprises a sheet of titanium 9 the inner surface of which has been covered to a thickness of about 0.002 cm with an alloy of about 45 wt% molybdenum and 55 wt% cobalt. Sheets 4, 6 and 9 form the liquid tight A and B cells,
 EMI16.4
 are t as !! e, nbHes pr.r rectangular polyethyHne 11 gaskets adapted near the edges.



   An electric conductor 12 is connected to the positive terminal
 EMI16.5
 from a source (not rp.pt'0SE'r, t: e) of direct current, and another electric conductor 13 is connected *) to the negative terminal of the same source. The sheet 4 thus constitutes the anode of the cell A, the cathode tar.t the pickled surface 7 of the sheet 6. The coating
 EMI16.6
 of trampling of t <island 6 is the qnodtque surface of cell.ulo B, the cathode surface Ótl: ut the layer of alloy 10. The electrotyte can enter from one cell A and B and exit through the pipes 14 , 15

 <Desc / Clms Page number 17>

 
 EMI17.1
 16 tlt 17 rtt44r! 'Til' t 1 "" ,,:., T .. 1! .- <; = '[1e U \ f4: i !: 1) 1 ..' 11 "from c: .llu1.e, co-vr''f'n" t, 1 (; <". ',":'; '- ;. r., t 2cra t'! 1!, Mtr., U. so ulal'7,; u.



  L..54 (: lJ! "! '-: t G. If ;;. ¯.' A- ,. 1; f r '!' .-. '." On the Fis, 4 fi.jr:' . ', 1 #! <##; \ ..:.! 1',>, i5 ', i: ... = 1 .-' 1,1. "'-1.



  Qtiet9 -1 d 1. 1} # (..-) #. -: 1 <'.:'. - - '## ?,. :: "",) 1 j1 t'Ii: 1..1, ".y.,. <Lr l (; 11;" CT'1 5 lrr Cft 11, t., .t. t. '. r ##>?' '"C' '' '1 .1 r t .:,' '' '' 1 ar.odlqn * de la c11'il C # '" t (. ## - '!.' ¯ '!' - '!' I '' '' '' '1141 yes flpt, a tale of ti tw 22 sar 13 9-ir l' t..r: 4''Ir. ..: 1 ..! R'l1 ,, \ 18 eat IIppU- ..- qui un roy4teu.ent 3rd., "L'U, 1 ci, \ fI.1,. Tr '!: Ce cnllulee C and is a WLd1 (1t .. 'S;, rl :,'. 'ltf., 1 Il:',) i7, rc, Çi l; 'ilt.1ïIdt (: I "Vtfrt the interest of the c4fll' il .; C # 01 'r. "<', t" ..t, zij 't'-n .1ltlle of envlrnn 45, tn pu Ma: \ 1, io yi; 1; <#'. 'J -'j4 ',.:. ,, ¯, t "! 1 11- c ,,') 1l d1 a 4pelanour of i1t. '\' ,; n 0. '').



  The other C (<<v J '"la V) 1 ?; i8 a.';, Roc m: r .j * '(r. C', 'IO!; 4 <1. Plfttno 30 q1! Co (.. '' '. iti.a li atirr-oo .y .. ,, !!.', 3a, 1 1. coU'ila D. The cakidi surface #: '..: J "1 co?] J 1 1 :: 't', ', "' '' / tf ',, \' it t 31 4'1'1 alliege d'e1vu'o /, .5, Mi <o ['! - io ilr "] .t .. ni s * 1 'Pli j: (i43 t1 ... cobnlt of envlr0n O, OO :! c .., -'-: 5i,. \ L .;' '' '; ,.,. 1!, #: #! #. .3. ". The U1. T-'ri - ir of the wall in t1ttil '.., 32 binds Ih c =:' t .; ', Ur . ct-.t ## .. ##. ir * l i.ctrl:; # -. # .13 connects t51e 32? tl r5 Iti: ", e: '. A;'.: 'VH tj 7 , ..., e; -o <5 (l, Il!! p = r, pt; rt-te) of current Cl) rt1., and a ri? t.'y.,!., .., ,.,. r # '# l'otrl-rie 34 rye-, binds the head 22 h la borre i il -:, 1:, 3,: .. r.! l''1rcot.



  The Cel3üln C q-t Li there! t> '?.;,! vs . #; 7 f 1: L (neither the ,, t, l.,.



  22, 28 and 32 and 1 ': <1 ti't' h: '-; \ .05.) You. t;>. '..: ,, cl3 nar and.,. gaskets rRCtstt; lF.ir9s t! ¯o "'r': 'r? #>," .7., # 1 .1'-' "for .. * set that \ 1 ,, :-) ir '::; il <V> <ô ri- ':, k3 o \' ll,) rt Il'1 '\ I, t, (! au: edges of the sheets !!. Un tl <lt 39 # .-> uv ..:. t "> # #: #. * #. "'1"'. ''! Ro #.! # * .; lyt cell C, and in t \ utr .-- ',': r; ,, r /.0 - #. # ..- ## ##. ## '.e .l 1, e 4 e 1 cpllnla C both pass pflr the f: ;; rw 3u, 1' .'t, # $ #,,! L ;: '@ ris, f' 2 '.) Volttin of the sheet. You c.tt, 'di. > l!, #, ## ,, -., .. ## <, u .r.i. ',. CHI :! . '' h tale 28, a pipe 41 por I ec; '. a (the; "1'.? # >>> r.;> #; '. n't-escape from the upper part * de le clhiY f ", '. # -, t.:/ u i2 pAr 1 <-n> il caustic liquor 0'! Jtre,: vÍ.c :, ':() ..] # <p" cf . '": rt'rleure d ta

 <Desc / Clms Page number 18>

 
 EMI18.1
 cell trt1vftrul \ l Polyethylene Joint 36.

   The pipes 43 and 44 of cell D serving respectively for the introduction of the electrolyte and .1 the evacuation of the chlorine pasaeiit by the upper part * of the Joint of the I) 1y \ t, lït; ne 37 dn cdt of the diaphragm 21 close to the sheet: 3. From otter c;:, hr) of diapliragwe 21, joint 38 is tr., Vnrrd phr a pipe 45 R the euperian part of 14 cell to rttcllel11 LI 'lIydro! Tt.n. and by a pipe 46 z the lower part of the cell to withdraw the caustic liquor.



  A cep111aire of Lllutn 47 p4-i;) be through the Joint of poly- 4thyU, ne 3A to bed upf5rleur part of cell C and o # dterid up to the vicinity of the middle of the cathodic aurface 29. Another capillary dA t , ogin 48 paaae by the Polyethylene Gasket 38 k the copper part of the D cell and a '(<te "d Up to the middle of 1H at the cathodic surface 31. Each of these capillaries of LlII1r. is connected by The electrolytic point at an electrode to refer to the individual calo: al (not shown). These Luggin capillaries and their caloiael electrodes do not form part of the cell assembly in the form that it would bind to using canopy. industry but have been included to allow for: measurements.

   If desired, assemblies of
 EMI18.2
 cells comprising more than two components may be similarly constructive. Examples 19 to 31 inclusive relate to a cell of the type shown in Fig.4.



   The invention is illustrated without being limited by the following examples.
 EMI18.3
 f "x 1 ') \ .Pj.l' We have 20 mild steel plates 1/8 inch (3:! 1.TI) thick in your pre-treated which consists in degreasing them with trlchlorethylene, poach and treat them for 10 minutes at room temperature (20 + 2C) with 17 hydrochloric acid. fine weight / volume, the samples are then rinsed in distilled water and bases in an oven at 110 ° C.



   After pre-treatment, they are left to "age" by

 <Desc / Clms Page number 19>

 
 EMI19.1
 exposure to the open air in an uary i1> production of chlorine for 4 fienminsa. A thin layer of rust forms in the steel during this period. Each aged sample is then used as the cathode of a 4 <'ctroiyti "uo splice to obtain sodium hydroxide and the potential cathode bed is inelliira troll'! \ 1el, tt, t! S de c '":'; '\: 1t dinVirrin ## *". The potential of electrodes vltilll1 (! i is more' \ 't') <t than c "lut of electrodes of shiny steel not trcu t . vi lt'Id. t "l ',, tl1o.



  Each of the three results of Offti! 1 were, f) J.t't.1I II Cl,) nlll1tI8 the average of the twenty dtt'rinJ.una and. and; t. Ulla '; by bed tnlte as the limit of calculation of AhlllP! 8. had ci- * 1.1 ,, rt..r1t, l ':> l1 11; <\ 1 \ 1' Examples 2 15 Included.



  W1iPH..L We degrease a Jchan tllloll of soft sugarcane, we plons't in elilorhydi-iqtie acid, 1.7, tf pet binder 5 .limits at 2L) OC and it is rinsed with water It is covered with an electrolyte dt5t in a solution of cs, matt.iun 811. \ 'unlo t 50 S / 1 of NaWO.2H20, 7 g / 1 of Fera 4 (NH4) 2S0 4 . II'.O (II), 8.7 ') 1 of FENN 4 (SO 4) 2'12H20 (III), 66 g / 1 resolves citric and NII4uH up to pH 8.0 petulant 7 tuihut-e fi > '70 C nno lcs ;! t current of 10 s..vt: res / Aa2. Il sA rl ') rl,' in drv't. ,, tal: içno bnllwnt.



  The sample is then used C,) I, ', e cr, t, dP 1111/1: "a *' diaphragm cell to obtain hyr1rcI,;:, 16 ci .. sciiso and chlorine, Le cnthodic potentials of this': cllnnl111on dona the alkaline Slll.J, 1urOI are tter: ur <s. The results are shown in Table 11.



  W ..: Jjf-l ¯¯¯¯ We trout a mild steel plate containing the acid Con "se in Example 2 and we form .. a cH ;, 14t" 'ctNl., T1 (1 '1t the nirfe of the following 8OJut1o'l: 3.6 g / l .le lij Wl 2111) (), 85.6 g / 1 ri ,.



  Feso4.71i20, 66 g / l of ctt.rlcs acid, u Pt Nil 4 () Il to obtain pH 8.0. The current density is 1d l1 "p; 'r.' /, Jo ;: 1111. ,, tetii; e pcndutnt 5 Timed V 70 '* C. An ar unit-piler is used. The' sonH11on is then used. 00 "./ ,, 8 cl'lthof1e dn: q nrA c:! 1.tle lU;, t, ry ### * to obtain l ':, y, Bodiut stainless steel .. and cl Lnr :. I, a :; yot; st.il cntho <

 <Desc / Clms Page number 20>

 
 EMI20.1
 dlques are inll tQ1I.fs aux tbhl H1! II.



  WUw :: ". K We prepare ': n", [' 11t1t: fJ d'r.c1. <? R two CO ';,: 13 in the axis II The d'W, n;: t, r () lyttI111e ant otTct! : 1 <!! ",;} a solution in U cc - po9iti r. T: '.. ¯r: t: 32 dl dt'!: 1,)! Ol) /..'!- i-Ol, 1.1.9 -! / 1 .1 CoCl-, 6H., 0J
 EMI20.2
 
 EMI20.3
 40 9/1 -le '' '-'0 .. ,, 0 -' ": <;.! X, t 1,5 * J \ .id, 't ,,' ltl'1rnt 'Ut.' ' .11 '' '(c5 7 "a; ...- =., 60'C: j or <-? # M *.; Iir.))'. ':" Sounds a der.3t' .- i * t C "* ir> nt # 'j a .. ### r> -j / i \ .: 2. l, f * <'<< # *>' 1t> te! \ 'tt rl3 io # ". i'.i-i't'tH.nn. L * =' cl ta ri t L 1 L on TH then 'jt! li3'i cof: ... e cat- thoda suede .1' - '? p!') I; d) / r ''.!?; T3'irbt '- ") L' ' i "ly-lruxycl da sodium It..11! c-'Ior". Lei ro'.Ti t.1 l. ':: t'.hod! r'3 are dOI ".! '4, (1
 EMI20.4
 at the bare table II.



  We resume, the ex-pj.c 4, go La # .- #> 1 1: -jt * current is maintained 'A a ..' n. '.? E8 / !.' r: pfndart ' .t Prompts. L- * iônt n- nc '! r ') distinguished? <' r one aspect fis c e 1 '; do "r '('), r: l <1.;. L-3" r's ': I': a '.'! are given ri t: -tile <\ i; II.



  We f? .. un def-rt î1 se '.roly tic s'tr ones pluiue in side \ Hr soft pr''tralte coirm.e dm:!' F'Xt -! .. iL 2, <Ja> - '.s nr. ;,. a l p. d "Ta * v; .t, following po- sitlon t 155 3 /: dp Gr :: 04 .7H20, 295 r ,, / l 1,3 citrate dq lodiwo, 2 () 6/1 (the TlA2Mo04 .: ? H;.? () Ilh 4 OH jut "-! 'A'j fold 10.5,, ou has a density of jui-hiI, dM leu .3:' pt.r's / d.T2, ### ndar .t I0-tiirut03 250C used some rtl-ttne anort ... We get a dark rta deposit. L '' 'ct \ J1! tlllon enc then 1jt.1Us' crn:,; e cat'iod d: <-3 una Céll'.11e '\ dl ;; rtL7, .. e to obtain de) hy! Roxy of sodiina dil Chlorine .LftS, o'. "Nt.!." L '! c "thf: d!. '<pp sonr."', 11 <'; \ JtL1 a.i t! .b' '-) (:. II,' I1PLEJ7.



  We fi rm.; TrfitL by 1 'c-tc !, the a "Im't' jn r (Ci" r soft c'tna described, daiir, 1 1 and we cover it in a! 'H1: n I; t iii no '- posmon ii'. VHritfl: / 0 g / 1 of NaMoO,.? H, 0, il,!. / l 4.9 N1C12.6! 1: O, Il g / 1 of Na4 and 30/1 do Nnilcu "n 11'.titgilnt un *) 1111 oli f1 T ''" '! 1 hl! PO, h 1 <) * Q = or; an "a? -." it4 1 .4. 4l cnuiinl: j ,. 50

 <Desc / Clms Page number 21>

 
 EMI21.1
 upèr "/ d" 2 pandart 2 ralrtutR, * and 8 ": 'IlItte \ Jtl1 hA as Cttodo' iana $% fin ass lui * à 411,11 lirri '4 Jbtpr4t de 1'hyt1l') xydt dp ,, 1 \ ',,' I fit read 1) ', \> 11'>. I. ,, "! 'I, .., .. t! FIn 1 tfi flllf * ll $ il 01) 1! Rd due "t & IC1l! \ T" "18', 4l, tli. 11 \\ 1 \ \" "'11' 1 '1 1,'> \ "I'I Il, ttflUW il Un" oh, últlll-I / I, I '",' lt> r.1 -1 1, (Lr '' '', la 0144ilile!. ,: / 1.



  1t1lCILIYItrt n't1!) <1n, .4l te 1 # à il tr at 11 1 and 'M 1. 11 .Si / 1,1.1 -il 149 lit composition ulvwU i 4U 1 ± / 1 110 HyM, W 4. JliO, 11, "tI / 1 te IItClZ.llix0y 31 1./1 of Na4pzt) and dt! K / 1 .1 "! (Rcltct-r3., Trv \ lt.1a" e a tr¯ptl1te anode therefore here thtn 7) "C. 11-ir r1en! Tll 'of co, reis% t of 5 AiUp'r ... /. \ :(. 2 have Iu111rItHi'IV l'te (in' '0 I1t. ,,, t ", On t1l , tlprlt. i "\ déildt ftr 1 etitir. t'.II" 'It.11 Inrt .Il t f'rlafrtt.f uH) t) t'4 cf :, e 041 \ .11111 "diub lino cell h < i tau '4 r *. ',' i * turn "wt .." ir: 1: \ '11 \ '' r "J..l ... 1. taditna and du c; Jor i Llr s.tr.:t,l1. c , t .., .1. 1 \, 1. td "ul '.! 1f o'i
 EMI21.2
 table It.
 EMI21.3
 



  W: l) 1L 2 ...



  We take 1 ecx; rie: rce 8, law 1! CrlI1t. (1 of C ';' ll'io: lt fit Range at 50 ..npr "! 1 d ..: 2 and nnlnG.uu ,, l ., :: I 1, h iilmte. We obtained a deposit '., IIlttr4 gris fatie "1. V': C: .flld.t1hn Pht # r? I'U 'lt.It1: 1.'; 0o. .; rt cathode duna lino cell dl ;,, \ '1', '' "!; .o <ir <, i. hold cie the sodium bydroid and da c iore. It-B c ' viffrra are t r1nn "" eu Ubletit Il. La comrfl.rnlsc) f1 de !: oxo 8 ft 9 (or <ft (] 'l' '1rr') 0- t4 \ Uet. de ddr, fI !! '- 1f1'lt of hm: ru:;: r, t feels "a11,1c 0'11" Il ", Irr :: * 1 gas of d.l81 tee. Of outrant.



  J '.,' 1 ('P1.E..l9 ..:. - On pr't.rtl1.tt: n: 1 lfcîie and; kCtf1! "Ú') 'l C" I; 1 c duns 1 'f'; t ".!, 1., 2. The d6té. electr-il ytiniie <'? tt of t 4 ctit. t1T1! 1 un h; tlr! do In C).' P,) 4 ettion next 4U g / 1 called NHHnG4. '; iO, 9 ç / l of FeCl, .6itJ0, 27 z / 1 of Na "P207 and 75 e / 1 (the NnFif7.t. 1 soc. On 1t.IU /! "an ar.ode of 6rt) .hit, tt. L'l, t, ntU" 1H and t tr ..; t. <s'.n.4; t? 4: u1n'ltf '' 'a Ciiurant density of 3 & -, 1 rt ,, "/, \ .2, Il rt' hr. ,,. 1In d ': I' (light gray zietallic t . The sample and te! -S; w: ct I1t, 1 t !! l or. E cathode dalla a cell Po dial..rt; .. e for .t, tenf du-, I'i,:, 1a ',; <. Yde

 <Desc / Clms Page number 22>

 
 EMI22.1
 de lodlur.1 and -lu cl, o, 1 '', r-'2i 1 t-i eurlt 1,) nnSs at ut>! oat! II X.il1'Iu .s.



  Gold 1 ,. r * t> d l '. # # <. #! ipl-j '1.1. eyt; MMHfi 1.1. # i r 9 1f'f: 'Q!': .1., '1 \ 1. rw t 111! IW '1 ,,,. "' 1 '.1) m,. #! ## .-. /, 1. ,, #, Ii:': \,.,. 1. 1 1) , q 4) 1, t 1 Itp "1:,; 1,, 11 \> 1 '\, - 1 bed t. Li l, '",' f tj = ai'It 1 $ 4 Îi.i: .1 ..t'il 'j, li'rf Isiilro1! R,' 1 .. <'t, i" 11! t- i1i t,., i ####. n 11 i .fn 1 i i!. r t J, S; V! i '1 el t! (t!; t J 1,! l '' I! .I '/: y 1 l'l', "I ,,! '! I',. '. i. ,, !!. ne; 1 "; '11 Í.! L1 'ja ir.lll, ldl ... \' 1 ... 1, '' Ii '9 * l 4! Chlorine. Ro: o p'-' '-' * 1 ' #l 'i .1tl1, .1! 1''e obtained net 11 \ <11'jll.1 an ttlul.1 \\ 1 II.



  Len denai.t'a,! A f.:';rnr t t.r- '., V; r th? r of Ii .n> '. 0t41;' and If ne prol "11 l'f! rl t,! 1 '} lJ' 1 ('11 \ 1 fill C 'rI' tH rr / r. ': 1 (t-! a \, .. r.' c: 1 ... b 0 .j t1 '11 r ton Il tl) na "y, lr <I 1JR, 1.". l 'l' f,. '1 /.



  (ht (IJ '; wj "11 la .r'1;'! '::' I 1 t'i 5i '' -fW'.â jt 3) '"! ", 1..1''1' <f,.! o II. We read 1'ift ## fa'Tr, len .t Ma; .t ;;.>! <# \ a tJ1I:;., H '",') f fod'l .U \ ':::.



  A0 9/1 of N.) 1iJ \)! ..; III, 1.a, 4.5! / 1 da FCl.6it; O, 5.9 It / l. 1 "Ct.L1., F. .U20, A'5k / 1 <* # 'lt (tPt) .i (: ti6, O, 75 dt' 1 fli! {; J 4! T 1,5 / 1 '1 * N2114.H2Ei04'. " ,! '#:' ?. t is e: '.'e..v: ri; 6i) "C atv c' .ne t! 1'I '1! t-; current, 1P 5 h, : 1: I '.' / (!., ''! 7 !! it ''. I! 15 - ::! 1'11t ,,, S en Iltl il.a: .-, '1: 1' I \ 110d., Of graphite, r. "Di't t,) 1 ') t 1;.' 1 \ 1: v., 4: ri" shiny ,,!. F.:, .- 1) tl '1 n ed't then "t. t 1 l "'; r:".-¯ i, 1,') -! - '# hr-- m ##>. <#,' fJ: ': 1' '1 t.1,': r :: ., ;.or? get do '1': \ '! rx,.' de lo 3üdt :: and dll c, 1orfll. Lec r3 '<lt.at.s are H "tH.!" N'1 1, Wii.fj..L1J ...



  We rfC! vVl't # i * <:,! t:., 8t lin '; Chflnf.l11, m of an aclor plate il j #: t.ratV! e: ur de!'. ic;, iP, C (). C ... 1! d..cr1, t in exovinle 2, du- :: "\ ,, an lu cl on Ù V <C.u ..,;. i: lnr; ': t: .W t.' 40 g / 1 due Yr: tnt'1F, ..>: f,; '1, 4.5 dl -1- "F-C1.). 6HO. 5.9 1 i- 1CL \. '; H "q 45 9/1 do; Vn4;) ?. 11); 1 :),'! 5 t ;, l1 'the NnHCO, and 1.5 r / l of N; H4o:; 04 'La t:, pf; rs1t; irt4 -i1 -, t7:' 1 P! "t 'vtitr:'. é! '.'; e "" 1 6JC,! .af..it- '! ; 't'f) :, perform the .jtlW3 under, \: f! râfff.é r: <i C: qf:!: 1t oa truidlq1) * -le 15 5 3 ". ,, 1 '<' 3ii" during 'lIt., 1', "r \ ') d' 1 h trmcr9. I1 sn r3r .. un \ 1,!, l \ r. f'lticlroly- tique,:,.) tl.l1.:t,:q "! 1: '' J d ,, 1r on 1, 'C-ttt'otjC \ 1:' ". ÛC '.' R, j.111X. Is''vClvttl: - i tin on 8! '. T then used this .¯! # E.iUiotfe' I1: ' \ '; ne C8f, 11C'% di |> hrai; .u Dom 'Wl: ii du i' ^ j '(iJ'OX; Jt; 9 de! 10d!. \ ::! and d't C115) ) ".

   Lt'i "

 <Desc / Clms Page number 23>

 
 EMI23.1
 r4imiltats nt Indian 'garlic' .au'pu. ij, WltP1JL.l / u.



  We treat an olian ti i ion, 1 ', ;; - r.) - <.. <rJ (- i ## <'. (J * Ql) I'j, i .. da.n3 la 2. un the -. # / <"## if L .'-'-. ctr '-' i / t.iT'f d (ms a solution of: 1) c'.oHjt;, - -.'.-. .. '' .. vs> / \,.



  Nl.I2Mo04.2H20, 5.7 cD / 1 MiCl-.0,), / i .. ,, CoC., 0,> 6 / l of Nn4P. <. 7.10H: JO, 75¯g / l d N -,: *), 1.5 '/ 1' 1e l4 '! If we have a density of d.- 5 a -.T-r /.' . (r- Jart 15 .nin Jt '.i, U tattpérauire du bain est do 6o, c I .. 1 "\ -' 'II-ll i" 1 ..)' m'I tl10de de gruphl-; you. the sample is e: 1f \ 'I1tP. utlll - c t.nude in a * ceUu.



  1 diaphrag-day {) Lta, Lr .- L'r.,) R.-xy <do aoJl-j-, t chlorine.



  The po #: nt: .1ela Cj * thgdii;., H.t - <..- i '. L '.): -...'.- <##. t., t); 9.) 't ri, m-m'jjj- On Irait *, r' îo ..L.). ' # -o r.P -! ',,, ur, 1JlIX C11: 4' ', describes J31} 3 3 l' xa ;. , t,, nl, i, ..., .. #.,., #., ltljn Je u co "'!) û1JltlJr1. -i! Ul": t: 1t' ": .5 j / L. î- ..0.7;), c1trite of o.1l.i, n, 48 iI / 'l, 1 ..:' 1'1: 'k: ",";., t1, r., - ,, #!, H. ,,. Ui], ;;; U <afc: erfectud hanged 20 L .......: ', .....,: 1' .. on .., IJ '; ! \ t., 16, 5 ar r.:)s/(Í.1.2 and: 35 C .n utili-.i ....- ... ,, ,,. i: ..,. r. (1o, Let obtained is gray -ut. I '-.- k.:. T. #.: -, # -. T, #>,.! {,> ... i ,. c ,, 0 C ', - method in an e. 1 -., ......... -: r, ..- :,' 1t '1.: l /, lP, <y,! e I sodll \: 1 and from c: do. R.r''1 r. H. # m /: 1. ............ <,., -, U.



  The oaM3 '1 :, totl 1'., - ## (# i mX.] # Tr,: j i.



  11 r1i., 11r; i.ne du t .-. A tnd.i: Up; - '-..-....., .. v.-L-.l.' tallow. , <#! -.-. L.?- 9.9, treatas; mt 1-¯1> ". Ç - -i-, .->.> # ..; .... ,,,, ... . ,, # 1JI: n rl6:, t JtiCt. L / tl i 1 <3 c ".. rf, # 't #.,. , ...... 1, il}, U3 c ,, ll- tf'1: î and the C) 'l'.,;: ¯ =, - :: '' -: 2 - ¯, " ': \ ""': '1 .., ... jP.J l0; 1 "111' osnnt, for = 1 1 aia-r. : # -, ..,. # <...,; i.



  -le la toll c.L..K .. .., <; '..., .. ,,, ..., #; # ..,., #,, ClVlll, flS 5) ILt en! L1l1ta Insui L-.! #. (,, -.; # #, -,>,: ,,,. # ,,., # ,, # and.. li-l! #; e5 in te. lis to ".r '. -. i . ..-....: .., V.) C, u, 3 .ilrt (ît.ro. De. Nor :: l (!, 8 "i. D ') 11.:.,' - . #. <-......, ...,, 1 ""

 <Desc / Clms Page number 24>

 independent working conditions are carried out for
 EMI24.1
 40 days three tbia a day. The average of all 114'lSlIt'IfH rear les thuatru3 # t 8 \\ I) I) rltJ \ lr. of 0.20 volts \ the mean of all measurements for the *) cells containing medium iron cathodes.
 EMI24.2
 s ..: '. r ". 1? - - - The three-cell, d1aphrng, industrial type, vertical cathode industrial type steel cloth cathodes are degra- ded, acid-treated, rinsed and coated. COI1 \ ... 8 described in Example 8.

   These conditions and the utility current are chosen CO, 11I1; e in 1 Jexe:, Jple has in sup ,, ocant to si-nnllfier that the '' 10 tI 8, 1b18 of the INrfi'lo-, ttXP09 '' dolf ln canvas eutlio4ltqtç nnt t11 "otrt'1u, n" nt, fnattc .. tem or1f; h (), lu are then l nt! t "l188 in three industrial cells and used in ... ê, 0 times as three test cells include mild steel norial electrodes. The levels of the operating voltages under industrial conditions are performed for 40 crazy days per day.
 EMI24.3
 of all Ijf! SUr8-11r ian tn1c11c5s is 0.27 volts greater than the average of all measurements on cells with
 EMI24.4
 electrodes coated with \! lol: rbdne-n1ckel ..



  EXAMPLE 18.



   A rectangular sample of a rolled titanium sheet (grade 130 defined in the I.C.I. WrouKht brochure
 EMI24.5
 Titanium, 4th edition (1953), page 5, Impertal Chemlcal Industries Ltd, 20 S.W.Q.) for 5 minutes at a temperature of 60 C in a solution of the following composition: 200 cm3 of concentrated HCl
 EMI24.6
 56% of No, 142 g of H) 80) per liter of IH1'lftU98 solution. After r1n9a [: é, distilled water, the.! Ctuwtlllon is placed in a bath containing 20 g per liter of cobalt in the form of etiltnteo and hydrochloric acid is added to obtain a pH of 0. , 5k 1.0. The purpose of this bath pr4trlte ') is to facilitate tilting deposition of the alloy.

   Using 1'sohmttllon of titanium c (j; n.je aittnde and plutinated titanium cQJe anode, we pass for 3

 <Desc / Clms Page number 25>

 
 EMI25.1
 mtntttee a current of itertnlytte of .'0 a- "p >> rf / d-i2 of airfuoi et- thodique. The sample of tita; c anint <'\'") tt "der;, t a bath alloy deposit of the co.i # 'i3Ï tl> ri trrv:, r.tht 1.) g, the! 1,118 the smoke of: rul fbcl, ts dE b'xIIki, 4' te 'island! mi , ii reads r4) ,,. tj # nickel sulfate, 20J do salt lof h sc: o :! "t eo il de color'ruz de eodiua per liter (the ttotiv ^ ..

   On it .h 'l' ny Jr - // #! 1'a: ". T nliun to adjust the lil (10.5 4 37 * Co t '-' rttrt -ii-.t T! - # 'by the deposit Un 4ohnntUl3n dt li! R .l. Titifm 4 'tttrsl t> î ql.is CH hK! n for 20 minutes <'. t <ir) "do-Yi 4 tt il, 7,, 1 ,,, t (le;, t Fl., p:, t , /, f.f1 using nie founds wt nic'K l. trrt # <'# #> #' ¯t; <li | Tie nrtss l'ifj-, tr4 4'tvlron, Ul) 2 eu d ', Spuls: aN sr CI) ir- it, ¯5: d il @ and 754 de ntakel eet btxrm.



  L $ 4cti & ntilton ti (at! F t''f'it "is then ntlllai c'j.e cathode, l1i1111 a> nu 1 1 1 o <r 1 1 <1 1 eh Ci l> rtt # *. L. o 1! m1 * 'r-, .r'r "'. d ln-lir celliiles blpctlalrHS r * ir - 'it'W, <s scr.; t.ix, i; s.2 and, 3' La cell is pr've e '!'! '. H "l" f "i; #) ir cm; i *. * rr / 1 *! î * c- trodes, and we grant the most rnid ntin- iii < il. "u5tt [') 940za4triqLles ldentlquev and anx d; in! :;, tee ite'ist <? #> .. part liuntji.



  In 4clluieetint !! 1 ...! 'F'ita on f'f'it. 'lin {"> \ fx e.,). t'".) - lâents aont gâ.,; triqne e.st and '/ iro-j / r. # the .. "cl '' quvaoita.



  On '4ntr) diqt dieift le5 c "ll il-9 ii t' 1'ctr. '. Yta c> nrt! Ti4. Of an aqum5e solution of 316 t; / 1i trt ln ch'. <Rtr '* 4e e: wilu where we added4l g / liter dē chrm: ute de s) Uui nnl.;.: rr. irt., '.ère cf-1. luit (A) e, intercepting the rrta4e (the titanium uL-'tin 'and. 1;': attude 9.1 tdle of titanium d4cell4o 't 1'rrcl.le r "" t <'! r ,,: vrt;.: e oit t., abtl. nu caurs des es lai and serves as tkIC) t .1. Wire c ').'! i '<' .. nt the #? ut ".od '9 of the se * -inde qI 1,11 e B til 114si <'!' '"c'.er': n" c.,; sr3t: rmflruc'o des Lutières u1; 11isW for caL ... t ,, a, Le- 9 ,, .- Jt -, r,; - netities for 1 * Ù ', jr.ltlures cat.odtT :. s-jlvr.

   Ict j (a) titanium sheet pickled for 3 'bears 1, *; ,, iti de l' - '0i <ic: clorhy- drlqije 4nCentrN q'taUte anal. ,, tl Lit n''ff d "caitr. tle is hydrare, (b) platinized titanium prepared by d4, ilt .i'.ectr tlnne mr un t, "j 1 of titanium in a bath G 'hyir xy 1., t: n., te ùlcailn? rr: 1 n of 80 g

 <Desc / Clms Page number 26>

 
 EMI26.1
 do platinum par. 11, 3'slvnr.t 1.: r, H ':; 11i C ..) I \ III18.



  (c) steel roof ions t,;) Fi ',' prolonged exposurea '1 PJ1t.IIO ... phàre polish <1 \) t>! i '.m 1!'! '.: C:' n11 itf la \ ::. 1i.C}) û d 'wj 10 l.iilt rd'it.t <l', 1lHl 'i .. "' n 'Ut.,; \' 1 C "I '' 's1t t'lItlll!' 1" tt, r. c :: 'Me cathode, CJ .: 1fJ> #>. If m., 1i,; ( d) 1 tl t 1; 1, {t, lll'l \ 1 '.' <in tl> t, r "<'.") 7 "rt -1 rett) *, 1.9 dan all Ipit'n gas'; ii':" i '| # !! * # <###' .. ,; e nle: 011 (; o.:. hî ti's (. '1 i.ß Cl ..!: "91l". LI)' ruz- 8111tats are 111'11 1 "':'! to b!) I '\' 1 III.



  The tel "Î4 clu :. r''o / II: e a9 .ao \ ybi1n -ni3'K l daL 0u: Jaltllt ut II t IO co.tie c., Ts, t'lo il '.': A . ^, ttl ;, tft soft end c ll ".i-î8,) 1410 t.rl) ... lyHTt" "! , di t / '0:' pr3 ti 5 ', 1:' la Fl,: .. 4 1 vle, .t.rlytt said COI ')', l't. "'1Cllt. Crtt: s.ol1 as '' t.it.tt da CI! case a anintl '- :, s 3T-i * "3" cunt.'; u.zt Q ');, \ ilr lit. * df c'Q'1nr'1 He ... 3> .Jin..i ah 1tJn 4;: \ t 'litrfl d'hy.rp.,!' 1 <1 ...!) N :. "On: Ta ^ l:;? 1 <*., Ot'1tt ..., l '11; 1 !! 'ie1' .- tl '!:, Ll "nt9 i.9 ot 3i pu1'; ti; T. ';'. T ti 'i'! .'l- ci.rtî "S de 1" l''1'P'.v: 'r; t', ü) 8 ptntlT1t. <, c ',:!: r'¯'a '', m'3.:.: ..

   The: .; ît -; -. tial3 ',,,, "! OP' ;! ';:} [, c: \ t. a: .3-Ua aa, eparf aux V% 1>"; r9) t7t =;' ;: r; 3 t'Ht1 ':' nn alttl.t.:4lft 'me t..l1. "do tt-3! ie' pur au l lan to- la Ge 1 1'J et. s 6rjC, and the values? r 'the': t'.ac; for the CIit.I (}, 11! 1 '']; ': 1'! .1. '., ot ï! .a. ;; e' \ c (, el tl'Sidul, ... t. '1' '' 1,> surten-! alon la '.' Hrlonr dw 150 atiliv) Ws for 'U1 "! current dar.sltë I t fi! : tpr </ d2 and 1a 2!) .nLllv;, lts (day a def1: '4ttJ of csuract dot 10 8: lipèrl) / dl.? ra cel t e 1a la t3lle I t1 tg- e; -> \ 11 '.



  T3.! R; 'Aa ¯L.
 EMI26.2
 



  Electrodes Te, a 1;, of cell under T., 3f'r1t t ', rp. titi "! <the: i? lt S of running OC" "'----- <1" --- ¯.-. -...- .. - .... ¯.¯., ¯¯, ¯.¯ .. '¯ .., ... ¯ ..... .¯. , ...- .. ¯.



  Anode .i't .1; W ^ .JI: n. <I.6 '' '/' ¯
 EMI26.3
 
<tb> Pt / Ti <SEP> Ti <SEP> 4.03 <SEP> 5.60 <SEP> 40
<tb>
<tb> Pt / Ti <SEP> Fe <SEP> 1.63 <SEP> 5.24 <SEP> 4U
<tb>
<tb> Pt / Tl <SEP> Pt / Ti <SEP> 3.61 <SEP> 5.26 <SEP> 40
<tb>
<tb> Pt / Ti <SEP> Mo / N1 <SEP> 3.65 <SEP> 5.19 <SEP> 40
<tb> on <SEP> Ti
<tb>
 
 EMI26.4
 Cowae 1, 110ntr 'Table III, If cellulaa using a * C9t'10de an titanium rcmvNrt i1'aU., R, ta:' '101Jbd''le-l' \ tcl <81 have 'IN' voltage 1n! ' ; r> iJI1 "d'fr" r1J'1 0.4 volt cella of a cal1'1'e with

 <Desc / Clms Page number 27>

 
 EMI27.1
 a 0 a tiode do titan .. pus 1 <\ "1 ,," t ,,) \ 1 '""': J ',' t. 11 ntua r.11b1 ... lia 0 $ t: lQfB do tltitria r.'I / t .. '1iJ 1 (:,' J11 ',, 1 .'j-'Js:' t.

   St: O4jrf11'H 'lr; ilZ.'. iUtJnt a \ ts, l: if'li rt '! 1 l' l t i f Î. "'It e ;; t,.: Il c'.t'.fd classic for you 1; U1' ,, il l,;, '111' '.: 5 n' t, t" L: I:! ,! 1, .. 1 ',; J lit.f it / a rl- cmactent: n! in point., XJ :; l.PJ, .. 12. ciili t 11] .on de tir; 4 :: t t'a; l ;, 'C! 7m, e 1 c r L t il -t! 10 example 18 and t 1) 1 st 0 daf \ 1 un 1il n Hle: r.rJi.! Tl '!: = 1 -1 ta ni) 2 1 t 1 C n following 50s / l of Na , .WQ.2HgO, 7 7 / i of FerQ. (NH.) M.6HgO, 8.7 aIl of 'eNH4.Sl) /.) 2'1.? N; OJ 66 / l dlC1j "cll; rlqit flt NH40U. pil N, 0, hri bell't11 sot hlf1: 1 rl L fit.: t..v: ": 11I" f) m pure Il.) oIL .. tion of a.oniaqu pour.) 1 , Ii: tr law r1 (.1. ', Tr' :, la atodoc f1 ',. Oler are 11tl1i8e8 in 1'.nCt "M1: H' 1'LI t. T) fr" ct '!, A 1Ioe deri3it4 current of cAt'I., da of 10 ëi.'17'r..î / .1 I; If.'n'Ia lt 7 Liriiter. 70 * C.



  We get a dtli3et,: lctJ. "¯) / t'l" ;! ;. 'r! ..'; '1 :: tÜt! .1P brUhnt.



  The sample '). One tri3ttg eqt. ,,,, 1.L. 'It'l 1ft,',.:,. 4: 'cat'tade r1WJ: 5 a callula <' Íl ('ctrolyt! .F1'It:' J '!!' jbt ", d, '\ 1' l '.,> ii, n :: t!., ic ec tit chlorine. la f7til: ij70 i, t% t)' l rl '\ <1';: \ "'':" L 1 ,.; 1, -t, .t '.' d '* 1 <1 coltlI) df' '' gave 1I to thb19h \ l Il.



  : i.T: 'p .; .. t We rprnd 1 r t:, ob '1.!, t:'.? ;.,. ,. ''. ea c "I \ tJltt () '13,; aBl IiV9C inc .jer11.t ,; ilik o; or..a' .. 1 c; .. '. ir: dd sr7 ü 7àrts / ; .tn and uno duration of tj (tiu, 1t} -1. n ',:; l'. ',' 1. 1.1 it Il '\' ';: i.iltlll9!: Shiny metal. L " ; C! Ht: 1tttt, ")!" \ Tr: tt '. e..r, ".3 '!! te lt t! 7 L, t; C'.M' .. e cat, -ioC4e dAn9 a !! C91, i'lle-," l-> ot.r -1:, 'tlll "', CI ':;' of In f!) Caustic Udo and of La. '..' r '.'-. n' '.' .-. " Uf! L 11., c:, thr, ie are don., It: a to bbl:; '1 IC.



  EX Fl1.PJ.JLli On rHCO! LVl'9 1i, ^, ulr.:.t, ws.J1, 1 .. t. t.n ..,! , I,:. '! 1' {'c,)'. q .1!: crlt in I $ exerpl.e 18, d'ui! n: 1 t ;; N '.,)!),; ... r.c' - '\ "' 11: 1 \,: bu1n of the COIJ1jJositi, m Itlvtr; lt; 7: Tof- / l: <;) /.¯. "0, ', 1 g / l..18 I' ':; 04.7tlxpr 66 g / 1 1'llCld ,. cLtrt'1 "1j nt H.JH." --11 3, n 'It! l1.! 1l1nt una anode of t.) nFnt4ne. La ta'Il ', -: rl1lro d'. h. '<tr. ., t, t, .s 6 <jC and the c1o [1 "tt ,, <11.

 <Desc / Clms Page number 28>

 
 EMI28.1
 current 17.5 amps / 112 for 6 minutes. The Sohanttllon then treated utility as a cathode in an electrolytic cell i
 EMI28.2
 
 EMI28.3
 to obtain Il: J1111 '' caistti, ie and chlorine. The potentials! df cathode appear in Table II. m: I. 1.! .J..1 ...: ...



  A sample of the titanium is taken as described in Example 18 and it is obtained from an electrilytlqtto deposit in a bath of the following composition: 40 g / 1 of Nalto0.2Hp0, 9 g / 1 d of FeC13 .6H20, 27 g / l NS4P207 and 75 g / l NaHCO30 A soft acler cathode is used with a bath temperature of 50 ° C.



  The titanium elongation is treated at 30 ulwttee a cathode density of 381f1PQNS / d, r :. It formed a shiny metallic electrolytic deposit. The chRn tU 1.on is then used C01l.e cathode in an electrolytic cell to obtain
 EMI28.4
 soda water :; tick and chlorine. The results are shown in Table II.
 EMI28.5
 



  ! P LI? 3.



  Example 22 is repeated but the d4p8t is carried out at a density of 50 nr., Nrea / dn2 at 58 ° C., maintained for i minutes.



  We get a laughing gray deposit. The chlmtll1.on is then used CO,:. The catiod in a cell <t dt8phrl. The caustic soda / cyro.



  The results are given in Table II.Biea that the samples 22 and 23 slow anect different and pr (.-. Ar6a with very different current densities, their compositions and their shrinkage.
 EMI28.6
 overvoltage ticks hardly differ retort as shown in the table
 EMI28.7
 II. In addition, samples pre-selected at current densities
 EMI28.8
 intermediate'! give cathodic discharge potentials se =: ..
 EMI28.9
 blableg. t:; <. 'dPIIF. 4., - A sample of rod titanium is stripped in the exe, ilp18
 EMI28.10
 18 and treated in a bath of the following composition
 EMI28.11
 40 g / l of NazMo0.2if20, 11.4 g / l of NiCl.6H20, 33 g / l of Na, P207 and 80 g / l of NaECO, using a 70 ° C graphite anode under a denul ty of current of 50 arnpèrea / cLa2 for 2
 EMI28.12
 minutes.

   The treated sample is then used entrusted cathode

 <Desc / Clms Page number 29>

 
 EMI29.1
 in an Eight jleCtNiytlq'It r1P nhtt.tr (1 (4 le% JIJ11dQ CO'ltll1qllt and ei chlorine. The iototitteli dit Cúl: f) (ltJ # t, 1 eo "t" t dot l'loQtr'f1yu tunt indicated at tebleitti Il. zwul "l.



  We see the e: w; ft.p1e I "',,; lt 1ft -j (!' L1lt (le, out da 2,5 a'pbre / d., 1 et periçlaiit 0 nt 'tt. Le- - r ':': 1 tllt: J t-idi, liils au tltbleal1 II. maPJt On p.1 <trait <lin 4chflnt11 tlm, '0: Li t "'11! C,) l, If .1: 1 : 11 't'f "(,: p18 18 and on ik) t: i.et, \ 1' ôlflot.rnlyu t1ltn 3tt 1, n1: de la c..p9! T.! N town 32 S / 1 of NnrtoO.2li j0, 11.9 g / 1 lit- CIJC12.611O, 40 C / 1 of H'4P07 'or C / 1 (the Njic; 0 and: 1.5 e / 1 of N li4cil La
 EMI29.2
 0-it current deneity of 2.5 *. ">;> ## re / iiw i, t. Li d; tr, Ss i''1: - lolysis is 30 mlrsutos. A il 'J 1 cri r ..,., lr: * .- i \% .tl \ t'l .: and 1. t up4r 4tiire of the bath is ie 7vioc. An C1'1r r: = s flei .t, la (1 () u \ "OItr de la lol'lttrm, lnttl;, t" 'i191 \ 1. ") ;.' 'en ..' ', <11' '': '' '' ': i' '. '! 3 u>! n>! 4> .r.

   We obtain titi c1Jpôl l.ctf't) lyl.t'1q ,. ,, 't, ... 1 \ tTI \ "r tt: rila.ir1t., 140 treated tillon is WUI11ttf s) titt. ^. cs .., ctiide drfrw of celtileo éloctrailtiq'tes served' f t'ahriy r 19 µH cn. Stf y; and çl, -, chlorine. The vnlefms; jour had .. \ 11 t ::: r; n, s, m, rul5m t fvt tii) 1.meé, i U. cr, PLa '7.



  We take the eJCA ': \ ple 26, used one of # r 1 t> î of <current of 25 fathers / du2 for 3; rl ;; rW? S -me fjf' .. 1: 1 a deposit matt gray. The results s) r't r1 () ",; iI'1 ttbief" II. Avtc 1 "5 alloys of efOj :: rtA 6, .t.27 r; t! P. ,, t, Li overpoclon i'ny.irn'no is only slightly affected by the detst Lb jl cl) ru t of 41'lct: '() lytllt9, this fact is raontr4 even 4'hutrap' ')', the I'Lp'1 ('' '' ''. 1, ^ .1 .. ,.: - tt .: li current 1nterQ; UlilrH! '.
 EMI29.3
 



  Wl1PJJ; .. "> h, We apply lectmlyt: aP, en: t '.r ù; \ t.'A * - # plaire de meulybdone, nickel et cobalt h11r dia tlt ..:, a, c. ,, .la, 9 a bath of the following composition 3? g / 1 df Nr:, r) .2Hyl, 5.7 / 1 of N1C12.6H20, 5.9 g / 1 of CoCl. 6H, O, 45 dl of , 'dH.PU7.li) ii ,, Q, 75 Il of NaHCO- and 1.5 g / 1 <) e N; 1L> .H.'; O / .o Un nt; Ii :; uno 1 \ ,, 0.14

 <Desc / Clms Page number 30>

 
 EMI30.1
 in platinized titanium I; 1V '} C lino te,: 60 * C itorts bath p'rnbtrn one * den' '!. t4 current t Jo! 9: r "r" '' / d: n3 laying 15 minuta * to obtain on t! ";) 3t" "..11 ti1" 13 .'r; 9 c'.iU, r "\ (p1 (l: 1t1.11on tratté is then * utltt'3 'C \ 1! 1 "t} out tjdc Ltm a cnllule Ól" ctrolytlqll8 to get i * lit? #> idi * the i1': "t; l ' l'll! qt ûu chlorine, LA. fl \ 5ulhta for this al I1'lr: t 1 \ "tl1'llg au t.rh1 im Il.



  J11'jiP1.- We retrs'; d 1'8 '<:;' 1 2B using \ 11 "\ 0 current density c, d..h) d1q" e (1 "1,1;.: Xesl 1 ':, L, 4,3t) ect of the pla (' 111 is similar. \ Ao1ul du la, '41 lqttt l: 'nxe ytir. 9, 118 ad7irrn.ce Qutllir des borda is' noinn hur: : 'I1. Lot r''r't.tntt! Are given to t !! [I "U Ut li. \' LPJL'1 11.



  On '.'Cn, !!' ltl # '# eiv.m Ullon e8 tl +: 1 \ \ 41 :) .. 1.' described in e; AIIJ1e lA,., 1, in d tr 'll r ni' 9:! SQ i'ltv) !. âr1! Vü;:;, ç 40 g / l of Na2Mo0.2iI2d, A, * 5/1. ilJ rr \ 'Cll, 6f1O, 5? g, l of; ilCll.6tt20, 45 i / 1 of ra4Ptl ,. tOi9,), 15? / l -J "= ïv1! C :) \ lt \, 3 ï / l da N2 !!., H2 :: 04 'The te. iptT.r turn of the bowl". -Ht -1m, î) '1C ît La tl #Ht' of cvjrant of 15 anp.] Rcs / d ", 2 is # .uintaue (1f., Ji..L., T 6, aL '' ': ntE.> and we used an anode of! '; - I', 1lt6. IL '1p. for .. a starter ... îtal I Iquo shiny.



  The sample tr.tt ": '" t') is cathode in an electrolytic cell to obtain s. 1 \ of caustic and cilorium.



  The potentials of c.rt'a.7de d11: 19 at the rati-itire ca, ij4ttqiie sint, given in Table II.



  L) E-iEL L-1 1 We prôtralto a c, .ntll1: m of titanium coi, ne in example 18. We f1jll, llr! I & 1ct.rolyt1q: e have wn al: la'e t! Rldlr ..plybctns iron / cobalt tar le t1l (j! '10 <\ <'- cn') 4 1 1'c.'le de l [following flolutlon: 40 Il de tl2: 11) 4,1! / J, 4.5 g / l I FACI. 110, 5.9 K / L of Cocu2 * 61120, 45 f / 1 of a4P; <) 7.10! 120, 75 µl / l of N <1! 1CO) and 1.5 g / l of N2H4 'H /; 04 'On Il tt UH' i-) rl, 3 dt titanium olatl'T '' Etvec une <te.'ipnitsiro (11: 1 ['<lin J 60 C, The 1 ni to of the current <3t ri ,; 5 years / d, .r2 pei.dfi / iL 15 r.1.nllt ..:. The: 1 d îoôt obtained have. T'rL9 clear.



  The iclmntillnn trvttv 5rt "'1: lItte 1 1 # .11;' - 'C,) ,,: e; t .7iR in a

 <Desc / Clms Page number 31>

 
 EMI31.1
 electrolytl cell <111 / t for nt) tr -1 the no nie car'.t! "the at of chlorine. The potentials of crl t ,, ciN [1.) 1] 1 'e.> t,; 1'1:, f'o:' 7: r i .r: rva ait
 EMI31.2
 table II.
 EMI31.3
 



  1! IVE t LC "rT- '.! ±' 1.- Electrode co .11 taking a rt ti 7rt f.rv '# j' 11.;! Tal convartant for the construction il''1'Cthr.i! ' , aSiVt? '. t, of which from .lUtnû a part of In surface .1ort a l'tVV H .tr! 1. C \' ,, 1i1, tt! llr of a 4.11- iron bond wt of a .notai chnL'tL L d m. Le, 'N'I! lIl du .r.olyhi: rra
 EMI31.4
 and tungsten.
 EMI31.5
 



  2.- Electrode co, pretllt! 1t un S'I;) '. Ort f,) r..2j d'ICt 6t1J1 suitable for the construction ct'taf> (tr!) 11 "! J r: naivrn, dI / lIt at least part of the surface,; orte a rvt.e .erit Cjlldll (! t ..,. 'lr of an alloy of molybdenum and a 1 / d,: t, Jl 9? G :. 'nj.lir0 .. ^. l1;,. 1: da:; s! 1 t.',: lm t! '
 EMI31.6
 nickel and cobalt.
 EMI31.7
 



  3.- Electrode comprising a support for., D '! N,:, ttl suitable for the construction of (lectl "' Jd9 .m5sivcr., Of which at t) init a part of the door surface, n revotemenl conductor of a ternary ally of a # ai'tul prt, nr! I, re c! nttlt <1dl \ le rr! .e of T., n; tst! r and tunKtne and of two mul rates c '.uiata in In' tr11p. du co-
 EMI31.8
 balt, nickel and iron.
 EMI31.9
 l, - Cell leetrolyttttne c -:> ..: prp, 11! 1t 'Illn c. , .rl drilling of an a <} tal suitable for the constriction j '(; tpct, r, j1,. \!' !! 1tvfl. of which a part or 1- # etiaeit) the of In surface oorte a rnvnk ^ .ent conductor of an iron alloy and a; '' LHL nr1. : .hlre chnlfJ1 in the groupa du, Q1y11 (. 'nP and du t, in ,,, lt ne.



  5.- Cell 'Jp.ctrolytl1'le CJ,; 7I'e'lIt! Lt a c tiiod * fjr..e of a metal suitable for the con ** trie t Ion i: lPctr7dea.: 11qslllflt, including one part or set .ble of 1 ;! aurfcic carries 111 \ rfvAtéi ,,?. conductor of an alloy of ... olybd '' ', e comv n-tal pr' 'h'1tt't' and a
 EMI31.10
 secondary metal c: ", ': 11, 1 (t1:.: 1., ¯t .: nickel and cu1 t.



  6.-Ce] Iule '1f'ct.r,' 1; .t! R, 'If> <):') rf.l '' 't': 1 ':',. ,!:, ie f'r'e of a lùt <tIIl ornve t IIOtlT the construction \ 1 ': J :( "tl'vlh: J t, nI1V8,

 <Desc / Clms Page number 32>

 
 EMI32.1
 part of which or the ins..t11e to the surface carries a conductive ravW'cent of a ni 1 i î * p t.ec1'L re of a: 1, 'ttil nr! cartire chosen in the group dl1 ... y "tJ (1.r'F and du t'.f.: 'te thread: of two Gsttill7! chosen in 1'. 'grr' :: a of cc'r ..:. t, du l'ic1 <el est du fr.



  7.-: ': l -': Ct.l '-. L following 1.6 r' - '' / N: ct1..c "t &) r 1, carne # / # ris * 4 en c * que '- .:,: t, 1. '1 "' I <r :. ');' 1. <was mild steel.



  3.- Fifcti-Mf1 * -s I.; E, t> 1 "r (": f ".1lCHt.!, I, 1 '.l, CiI'F.CtEC19''P, in this rr.: e., t ,! v! '; !!' ;; i, ort t, Ear 1 '' .c! -rd ux.



  9.- E1.fc: t '! "JC: :: - i! V",. T lfl l'f''ie: .d1Ctl.t1nn 3, Cfii' <1Cl: Ej '! 8l1 in that the tn-'tn) d1; 'I:; 1 or'l ;. "t L 'c1 jt- soft.



  10.- F: s'C I ''. T2 according to the- r-'VP. (J LCF: tiOf1 7, characterized in that the #.; ## t.- l di:, 5 '' '' : 'JrL f'r't the titar.' ".



  11.-: CtLi'.j, l! , ': 11j.'. Ti. "T la r" lei (? LCLtitl (; 3, crt'ctt'rLsc'e in c (1lJP "1e m té1! D) 1 Z or *. O. # T le titanium.



  12.-: # "! *!" r, # '-.' -s:; "iY; tr; t '.. r> -vç- <1 J.C" t-ion 9, crF'.t.'r.: r.'e only the metal of 51J. , \ ')!' is t 1 rlt.u: e.



  13.- \; '> 1' ')' -, ': 4: <1 ## t'O''u'v> My d "C ^, rFrar'.? 1pctrLqll '# from a stack: \ C'j..u ':: d, Ll1 C <rnC!: - r:. :: in that the A CFi tr; ") Ej of the stack is a * LE1', '. Fu;: f ! 8'i ': ir', t Î <3 r '/ e -'- dlcation 1.



  1l, .- .T '! 7r¯' 'd, .. ", rI) (1" cti (J ri ri c C 11 rH:, t {' 1 11 ct, r He a:, p 'rt 1 r of a girl 1 Cû.t, 1t'IJh1n.J ruTHctfiti? .4 e. co que la c'I! ": '. HiF11B the stack is a PJt:> tl'o1o) followed the r'rer. (icFtto !! 2.



  15, - Procrd1 'of production in this aura! t electric> # from a battery 'S cw'Sto .., tth; lA, cllt'f1et, lrt; and- what your cathode of ptle 6! "a * ^ 1 ^ c tr ': r en Ivan t In ruVE't.llC: tiEm 3.



  16.- h ,, c '::, ¯i'tlet, r': 1 E of an aqueous ûlectrolyte, carllctl. rlp in cc (111 "1 de l'.viri ;! 1: (> esi, rl? al1; lraatrolytirlfP.:.ar,t a CCth (: r1 1.t'Ii1r t! la rt'vdtc ... tt.jfi. 1.



  17.-) r, ctê11 r:! ': 1 ": ctl'01:' A of a watery J'etrol¯rtP, carae- tfr1rl er. This f1'J of hyirn ./ 'is ( ii'r3ugri lect, rolyt.iqIJE'.1ent 2: a cathode "! sn t" m! '1 <1 r'; '! (H d: c: .t, 1.' :: ":? ..



  13.- Pmr¯ = d .'- d'4lect.rol. / 3 of an aqueous electrolyte, carnc- tcrLf 'et-, ce qli) d "l h':! O.;,. Rlc ost Eic,% r;: r, lctrlytiql: e.isr.t at a cntI10 (1p. "julvar. t In 7'v (" d; cat.lon 3.



  19.- C, 11. \ 11Q, 1 "" CLf ") lytt (llje suitable ORf Electrolysis

 <Desc / Clms Page number 33>

 
 EMI33.1
 d ', ne /1)Ilt.,)n 11r'lf,' II'tI rh 't'!; lmt ', i'! 1 \ 1 ,: 1t,!. H \\ UI, QA1'1 l ; 3iit; e1 0H '' '-' # '":;, 1-," ..t. "'. qtle h O.dJIIHtn frt un" si ft 1 'clrr -' '.. f.' '1', ntierti 'lautr doft laughs.



  VOI \ 11 t Ch t.1ntl 'le 2 dit,, 2) ... elect.t "H'" b1il "tU" f \ c;! It, 't'J'a pl1r tltW ii. "T) tie t, It.U: 8, including nu J \ () LUI! Ine! ltrL1 of 1: ^ it: f., c.;: .. ", \ 'tf'I' \ 1! rte un r .. \. t ',.' 1:; "nt, condl.lctovr d''in: 1.t, (Il nou1.A d .. ', r) n, cry ,. ,,: , r.t'.lr.c rt Jnut su o111. a part (J5 Ir. atirfncr cr tte.dir; re 'jrtt,' mm r'vt.u: ar, t. condiiatfrr of a 4 \ 11 taC . of iron and a: 'tn1 swelled -ïî-i.

   It '.t.,;!. E of ai) 3.yh- dine and imi'îiit'11, 21.- l': lcr: tf'Of1. blp, lt, 'ttr' ,,: '. I! "/, 1., J reads' 1111 '.' .'JI'I tin tt. Tans dont year 1 "') \ Il a C. 'fi r t. t, 1 I "1 1", 'ri -> 0. t,) ci 1'1' ", 1. rt u- r *" v6te:; ïf'rtt ril, ll ('ICt.MI ^ d' a.). tltl n'II !!,. , the; 'r', l '\ I d'l, .l;, U'I "#. .j.mt au ionins an I) rrtie of !! UrC! cf' C '., l" 1! -, toi I, ort "ur. r.", "', 1'1' tOI t conductre. d # ii! i II 1r '/, 1.) l,: t.: 1', # p * d '-:;.', 't.1' ro ch.) !, 1 d lH 1 the cobalt group, damn t '111.

   (... '1 22.- f, lt \' t. R ') 1 \' "b! 1 '/ il ;, l re ,: i:> #: t .. î. - #' '; or '("# fî!. tt; 11' 0, including 111 Minus one nnrtle says In / 111 [" '1 "" .11 ",;! r> #', r (> 1: rv * - '; ? 1 1- #####. 'Conductor of a: l, tGl r1t1t11 ti'1 .'1 ": 1', '. (11'1 i 1 1. 1 * # #! (J tit, hll minus 111'11 'fll, r'tia il 1 .. 1, rr /, CI' c ..! I, '' r ';, "1'1.,' '11 r" "" 'I " .r., 't or- d'lct.e'lIr d'un ntl 1, p' "t.": "H ,! J '/' J" a, r '01 1 (pr l ': P ! l '(' ctl (ltt le grovipe du, I \ o] .... bd: ne and on ttlll:; t;! if! t, t, lit, ',:' II> ': 1 .: . 1 :( (') 11., [::. 1 ", funl! The rump says cutmlt., Du nlckpl and. Says' .Vf, z3.- Cp1! Ule el * -ct.rolyf. '' - . (#; mr, u! ticNllois lu type described in the patent 8118trnl! .er r, <'. 799, cj) r' - ". at't '<r' '', Bipolar Slcc- trode constltlllt3 by ' 1'1 'i \ "f' 11 .. tt tr,; 'c, d" It..111.'. Ni ': 9 part of 1 p 8'IrrfCC! LJJ \ l1di,' t1J "port 1 \ 1'0;

  "" ./f 1, "" 1 f. coJ! 'c1 \ r., t ": r of a noble metal do: group dt4 1 pt r:" ;, t,;, 11,;, .l "! 1 wq r'1 of the surface catiodlq' le portf 'un rw' PI tc tducl o; rd "Ir. 1I11f1 \ age of iron and a chosen nltésl dm f lo .'i1- 'i: .r du:. ##>' vhiii "ne and t1q tun '; rttt \ ne, this 3 lec Lipolt; re f¯ r.;, '., 1,; ..,', ': wheren 0;: 1.1' .. len compartments sca ti; od 1 (j 1 'e and tand 1 ec * J 1 # * l * rc # . i #, * "ii * c.



  2.- Cell e 41 met ro 1 yt 1 (1,) tt 1 rt 1 e 1 do i jc described in the nustrallen patent n '3:.' 7yg <?: it; rN'a; 't no \ q "c'rJde

 <Desc / Clms Page number 34>

 
 EMI34.1
 bliolnlr * el1 ',; ", 1 til'fJ' 1111 'i: n" .Yi * .1 .. tUti' 0, dutt Il'1 --j tril lifte pnrH "d" 1 '".r' '"t' <'"', 1.1 \ 'III ": 1, - .. t. 'ln r "' Jt'1" "I" t. !; 'lrl (ill..tih, w of an inl'i.tlÎ 1), tlfJ idi ..i: 1-, <#' 1 '\ .'t.' '! [' <! , 0: 1..t / H't t eu if7lrl a part dr la suri \ c <? Cttt, "dlr: 'It1;' ortt 'a rHvjt! Tln: ft conductor of an al1lf ,.' d # ## ..- # l: -b ', 1'.ufl nv.ic un .'.-' al c'.f: is1 in te: rl) 1 \ pO of cobalt and dru nic el l ": \ .Ic!, ', Ji1 blj> ol6lr for-nnt the partition' antre les Clil) Ilrtt. (, 'T tl'Jd \ 1'1t! And arlainl9 di' C'll'11t3q cont1. '!; lës , 25.- C''H'tlc .lfwt, 1'I) lytlq \ 1e for: Jultlc ..- llllles of the type described drzns;

   the L: "'ht - <u't'r'i'Han nll,;. i19 coupr! i": û' ': n4, Hect ..; Jode blpulftlr CI)';: t.lt, ita Il .'11 '"! 1Il (the t.lthl.) Whose. UI1" oit' "'l1UI purtlç <1 1'1" 1': f'I '.,:.' 'l'. ,,, 1L (\ '!;'! Itorto 11: 1 t '..' lhlrn, tfCtf crl! \ d "c!, tl1: rtJ \ l1 ru \ t81 noble <): 1; ' ;:, i ,!, lttira, <\. dont, su.:, "" 10: 3 uno1 # '. ##. rtl * d la siirfe4ce c; t.iod 1 1 y, t, (J; 1 .. 'un r {' vl..r: C1; tc "> ''. 1vic!. * i; r ij ', 7f .... il! 3: 1! ternary 1"' 1 / t1! nt ': .ft.Lr? chosen in Te r'l'IlO: du.;: otyb <1 "r <! t du tllT1t:' iti.rp and .e -, 1 '' '' '' chosen rate dftns le ::; r "" 'J! 1 cobalt, n (., f'1. ft, 1' \ t, ',. ^.!),'.., 6. ('i.Wt ;: JlH11t.l! 'T' fu- ,, 1'it t] ... l: l'Pleitrt 1 C !: ce, ##! '* "T.' ... ci t.! ' C It. ',; C1J,.: 11 and' fJ \ 1dtrr du (: NL v: 11! F conttl "I! 4.



  26.- '' L '.- c' '. R <.. t! ": I': e'irl :: tn rp'l {'f: r1i.e" ll,) t, 1, ca. : ':. ct.irtIH "8 in that the lf1! t'l1r fil): ol.L.:. Ir, is 5,? 0, ..'.



  27.- ': \ cct.f'!) 111 "K ': tv * rt la rfJ'm.dtcilt1ûn 1, cr! Ict,' r1: SÁe en ce ll1tt la t-et fili-r <. '< . torf, rt'tm rt from 5 to 60, Z.



  28.- H ct.jMd c swjvnnt! # * Rf "'/ e; dlclltlon 1, <: aractér1l'ée in this mie In tf'f (' 'r in:, olhfi-ne is Old 45 to 65. < - 29.- t "ctT'h] e: J'l1'lil!: T 7a r" ver, d! Ci.tlv! 1 1, cnrct '' 'rte er ce qll "In I.ef'" " 11 "-" :: J t .. 'lf1': t; .r, ee ^ t of 3, Ex7 "30.- 1 ec t, rilp. =. U tnc, T: tr <= 've'. d! c3t! or: 2, caact4rle in that the t'p.,!. tf1 .., f1r't. 5 5 \ 70, 'de :: 101: rbd! le and 95 30'6 de cobnl t .



  31.- E! Ect.ro; ie followed the aleaticn dream, "nr,"! Ctéri1! Óe in that '.f'. ^ T! ': ÇS.:,., F L.r.; ylir, i'. 5 7l) i dR 'llfyVt! If: '13 t 55 30 :( de cnbul t.



  32.- 'lECtr; Tta "t \' i1nt" l r "" 'lt'rdlcotl () n .2, nrIctrtIS6e in this (life on:'.) 7 '.' <; J;. ': <. at at 65, IP .n'llybd l't 95

 <Desc / Clms Page number 35>

 35% nickel.
 EMI35.1
 33. - Electrode according to r ('v8'td tCll t101l a, characterized in that the rev3tf (/ Ì1t contains 1.5 *> 58, <of molybdenum and 55 42% of nickel.
 EMI35.2
 



  34.- kleotroda according to claim 3, 1l \ rf.ct.r1t ', e in that the coating contains 5 to 6o of' 1.t.lIl selected from the group of molybdenum and t'irwjrt 1'1 ' .



  35.- Electrode according to the rNre iicß: cs: 3, 1ljr.ct.lrt! 'E in that the rtlvI, tflT1E11t conttfmt 50 il 6C)' j du .., 'tx: c:! At ^! dnn "the gl '" 1Ipt. du tl1nly, b (!; 'ne and du tnn: 9r..n.



  36.- Method of revoting rLect.r, l, -ti, caso, Plll '.f' l, t! suitable for the electru construction (the ..aq, tvan bzz?. 'tdb of an alloy IIlolybdÍJfle nlelel dursa oo "p!' 'bath: ant 3 sA 45 of NaMoU.2H20, 10 Il 13 g of Nico ,) 1611 "0, 2? At 1.0 g of r "4Po" and 70 to 100 g of NaItCt), phr 1 ltr <fe de! 'Iù1'1t':! 1;: -; w ,,. Ss ", 11! S a density of courart continuous at 2 5 a ;; rn / dn ', f! and at tinn te ip4- rature from 40 to 700C.



  37.- Proc4d4 of revtP.e: t,; lF.-ctl'lyttqtl of a suitable for the construction of J1f'ct1 "'J <1 :::;, 1'f.!"! '/ l'Ft1ti / lt of a lIIolybd alloy, Ile-nl (: kal-co (; ùlt t d.ir.a un bai' C <1! tt "i'it 3Z 45 g of Na2MoU4.?HO , 5.2 g NiClk.6H2O, 5.4 6.5 ltlff CoCl.



  6H20 # 36 to 54 g of Na4PZ0,, 10l10, 70 to 100 it of Naii (: 03 and 1.2 1 # 9 g of N2U4.H2S04 per liter of rir solution. '.: P: at 8.113 one den "< - current tee of 2.5 A 15 8 "1r'r" 's / (Li12 and 4 read te, yraturh from 55 è 5C.



  38.- Proceeds from coating * '., En,; l "' ct.r ,, ytlr'1f 'of a -notnl, suitable for construction, t'J' !!.! '" D..t ', "\! \' '' '! J' ^ -. 1'asae of an alloy: nolybdine-ntcvel-fE'r df1n ut) Hltn ccmtp'lt1J, t 32 45 g of K8004.; HO, 4 5 g of FrCl..0, 5.4 6.6 g of NiC12.6H2O, 36 to 54 g of Na4PZU.) UIIO, 70 h 100 g of NnlIC03 and 1.2 to 1.8 g of NH4.Hz04 under deo "de-isit'Is i omit from 5 to 15 amps / d.a2 and at a te. prrtW re from 50 to 70 * C.



  39.- Proceeds of coating.rent -'lectnl :. '# iq-ir da .dtuux suitable for the construction of electrodrs ... hp.Ivos, cstr; ct.'rt: S en

 <Desc / Clms Page number 36>

 
 EMI36.1
 what a coated titanium or unalloyed titanium containing at least 50.1! we weight of titanium, of an olybdenum-fer- cobhit alloy in a ri.111 e-yr. * ,. eriant 32 45 g of YzzMoOl.H20, 4 to 5 g of F <, ClrÍ \ H11, 5 6, 3 g CoCl, .U20, 36 ft 54 3 of Nft4P207.1020 70 100 g of NtiHCO and 1.2 to 1.8 g of N2H4.R2S04 under a df:; tt / rie c '.' 1: 'P. Jit. d 5 to 15 a.;. pr8 / di 2 t a df, - 5'J u 70''C.



  4 '.). <, 11'Jt: f: rl .; -the rtvate,; ent /.1f !ctrolytiqe of titanium to obtain coated electrodes, characterized in that the t! teat is pretreated with a solution of acid n ', oroborlqlle oon- menting. care 2; \ in p4ids / volu ;, p t'l1 / orf acid,) bor1i \ IHt.