|
Salt and vinegar for rust removal
I have used the salt and vinegar method for cleaning small hand tools for
several years. It works slowly, but works well for high carbon steel -- especially plane irons and chisels. You will need to use something slightly abrasive to help clean the surface -- I have found that 3M ScotchBrite pads work well. On badly rusted plane irons, 2 to 3 cycles (soak for 30 minutes and scrub with pad) will clean it pretty well. The mixture is simple, standard 5% acidity white vinegar and table salt -- just dissolve as much salt in the vinegar as it will take, and it takes quite a bit and dissolves slowly as it nears the saturation point. The mixture can be reused several times even though it turns red from the rust. Another important point, the steel will rust very quickly when removed from the solution. Keep some clear rinse water and a can of WD40 spray handy to clean and protect the tool. -- Ken Vaughn Visit My Workshop: http://home.earthlink.net/~kvaughn65/ "Paul O." wrote in message ... Did a google for rust removal and saw a few references for removal of lightly rusted hand tools using table salt and vinegar. Any of you use this method? If this works would like to try it before scrounging up the parts for electrolytic rust removal. How much vinegar and salt do you mix with water? Thanks. -- Paul O. |
Salt and vinegar for rust removal
In article ,
Paul O. wrote: Did a google for rust removal and saw a few references for removal of lightly rusted hand tools using table salt and vinegar. Any of you use this method? If this works would like to try it before scrounging up the parts for electrolytic rust removal. How much vinegar and salt do you mix with water? Thanks. salt and any mild acid -- vinegar, lemon juice, etc. -- is extremely effective at cleaning up oxidized copper. takes off the oxidization, without touching the 'clean' metallic copper. I'm not sure of the entire chemical reaction, but one of the byproducts is copper chloride, *bright* blue. I'm guessing the situation with iron is similar, i.e. iron oxide + salt == iron chloride + ?? I've used salt + lemon juice on copper cookware, for many years. lemon juice straight out of the bottle, enough to wet the surface, and just sprinkle some salt on. doesn't take a lot. The reaction is fairly quick -- seconds, to a few tens of seconds. a single grain of salt seems to work over an area about half the diameter of a penny. for heavy oxidation, a paper towel thoroughly wetted with lemon juice, laid on the item, and then sprinkle some salt on. The _nice_ thing about cleaning copper this way is that it is a 'self-limiting' reaction. When the oxide is gone, things _stop_. I've never played with the technique on iron,, but I'm guessing that iron reacts considerably more slowly. |
Salt and vinegar for rust removal
This may sound odd, but I have used plain ole brake fluid to remove rust. Wear
goggles when using it because it is death to eyes. Not really, but it is bad stuff. No harm done to try it on some totally unimportant rusted steel or iron. "Nothing ventured Nothing gained" Hoyt W. Ken Vaughn wrote: I have used the salt and vinegar method for cleaning small hand tools for several years. It works slowly, but works well for high carbon steel -- especially plane irons and chisels. You will need to use something slightly abrasive to help clean the surface -- I have found that 3M ScotchBrite pads work well. On badly rusted plane irons, 2 to 3 cycles (soak for 30 minutes and scrub with pad) will clean it pretty well. The mixture is simple, standard 5% acidity white vinegar and table salt -- just dissolve as much salt in the vinegar as it will take, and it takes quite a bit and dissolves slowly as it nears the saturation point. The mixture can be reused several times even though it turns red from the rust. Another important point, the steel will rust very quickly when removed from the solution. Keep some clear rinse water and a can of WD40 spray handy to clean and protect the tool. -- Ken Vaughn Visit My Workshop: http://home.earthlink.net/~kvaughn65/ "Paul O." wrote in message ... Did a google for rust removal and saw a few references for removal of lightly rusted hand tools using table salt and vinegar. Any of you use this method? If this works would like to try it before scrounging up the parts for electrolytic rust removal. How much vinegar and salt do you mix with water? Thanks. -- Paul O. |
Salt and vinegar for rust removal
On Sat, 08 May 2004 13:32:19 -0500, Hoyt Weathers
wrote: This may sound odd, but I have used plain ole brake fluid to remove rust. Wear goggles when using it because it is death to eyes. Not really, but it is bad stuff. It certainly is death to paint, so keep it off the paint. Barry |
Salt and vinegar for rust removal
On Sat, 8 May 2004 06:02:31 -0700, "Paul O."
wrote: Did a google for rust removal and saw a few references for removal of lightly rusted hand tools using table salt and vinegar. Any of you use this method? If this works would like to try it before scrounging up the parts for electrolytic rust removal. How much vinegar and salt do you mix with water? Thanks. I've used sandpaper, then fine steel wool. Works just fine, and gets rid of heavy to light rust. Works on wood too, I hear. On one very badly rusted item I started with a fairly decrepit rough hone and scraped away with that. This was followed by sandpaper and steel wool. It changed an old piece of rust I'd bought at a yard sale for $5 Can into a cabinet maker's plane [hollow grooves in the base, about 18" long.] I repainted also, and gave it as a gift to a person with infinitely more talent than I have. He's still using it. Bill. |
Salt and vinegar for rust removal
|
Salt and vinegar for rust removal
|
Salt and vinegar for rust removal
Hi Paul As others have said, it works fine. What no one has discussed yet is the fact that it darkens the iron a lot. Like to a dark brown color. I don't really like that color for the surface of my jointer but I don't dislike enough to have the tables ground. Good luck, Jim "Paul O." wrote in message ... Did a google for rust removal and saw a few references for removal of lightly rusted hand tools using table salt and vinegar. |
Salt and vinegar for rust removal
"Jim Martin" wrote in message ... What no one has discussed yet is the fact that it darkens the iron a lot. I would think that it might work something like bluing a gun. RM~ |
Salt and vinegar for rust removal(New question)
I know nothing of chemistry so my questions are(1) When disposing of this stuff, anything in particular to worry about? (2) When storing, is a metal coffee can ok, should the container be vented? Don't want to use this mixture in anything that it will eventually eat thru. Thanks all for your help and advice. -- Paul O. |
Salt and vinegar for rust removal(New question)
|
Salt and vinegar for rust removal(New question)
"Paul O." wrote in message ... I know nothing of chemistry so my questions are(1) When disposing of this stuff, anything in particular to worry about? (2) When storing, is a metal coffee can ok, should the container be vented? Don't want to use this mixture in anything that it will eventually eat thru. Thanks all for your help and advice. -- Paul O. I store mine in the 1 gallon plastic containers that the vinegar came in. I don't think you would want to store it in a metal container. I haven't disposed of mine yet, but I would think you could neutralize the weak acid (vinegar) with baking soda. Coffee cans rust pretty quickly with just plain water -- I use one with water for cooling lathe tools when I grind them -- it looks pretty rusty. -- Ken Vaughn Visit My Workshop: http://home.earthlink.net/~kvaughn65/ |
Salt and vinegar for rust removal(New question)
|
Salt and vinegar for rust removal
On Sat, 08 May 2004 16:58:36 -0400, Bill Rogers
wrote: a cabinet maker's plane [hollow grooves in the base, about 18" long.] What's a "cabinet maker's plane" and why does it have a grooved base ? -- Smert' spamionam |
Salt and vinegar for rust removal
On Sat, 8 May 2004 06:02:31 -0700, "Paul O."
wrote: Did a google for rust removal and saw a few references for removal of lightly rusted hand tools using table salt and vinegar. Bad idea. It doesn't work especially well. It's _really_ risky on some copper-based alloys, especially bronzes. You do _not_ want to start chloride-based corrosion on bronzes, as it can be impossible to stop this afterwards. Acid processes around ferrous materials are likely to give colour changes (mainly darkening). You may find this useful, if you _want_ to blacken things. If you're cleaning ferrous metals, go for cathodic electrolysis. It's easy to do, hard to get wrong, non-damaging and works really well. For ferrous, a citric acid technique is commonplace (mainly for museum-grade work on _really_ damaged items, particularly iron rather than steel. IMHE, electrolysis is much simpler and works as well. For brass or other cuprous alloys, a vinegar soak alone can be useful. Don't leave it too long, or you'll find the brass de-zincs and turns pinc. -- Smert' spamionam |
Salt and vinegar for rust removal
On Sat, 8 May 2004 14:57:18 -0700, Larry Blanchard
scribbled: In article , says... I've used sandpaper, then fine steel wool. Works just fine, and gets rid of heavy to light rust. And completely destroys any collectible value the tool may have had. Good! ;-) Luigi Replace "nonet" with "yukonomics" for real email address www.yukonomics.ca/wooddorking/antifaq.html www.yukonomics.ca/wooddorking/humour.html |
Salt and vinegar for rust removal
Aww gee,
Do you suppose it could be a #6 bailey? I'd guess Stanley thought it should have grooves in the base (sole?). "Andy Dingley" wrote in message ... On Sat, 08 May 2004 16:58:36 -0400, Bill Rogers wrote: a cabinet maker's plane [hollow grooves in the base, about 18" long.] What's a "cabinet maker's plane" and why does it have a grooved base ? -- Smert' spamionam |
Salt and vinegar for rust removal
On Sat, 8 May 2004 06:02:31 -0700, "Paul O."
posted: Did a google for rust removal and saw a few references for removal of lightly rusted hand tools using table salt and vinegar. Any of you use this method? If this works would like to try it before scrounging up the parts for electrolytic rust removal. How much vinegar and salt do you mix with water? Thanks. I'm wondering why the salt. It surely does nothing but perhaps cause problems later on. I would prefer a stiff brush and kerosene or WD40. Although vinegar will not rapidly dissolve iron, it will very slowly. It will also, a little more quickly, dissolve rust, but I would prefer to remove this mechanically with something that impedes further rusting. Just my 3 cents... |
Salt and vinegar for rust removal
In article , Sandy
says... I'm wondering why the salt. It surely does nothing but perhaps cause problems later on. See your friendly local chemistry professor :-). -- Where ARE those Iraqi WMDs? |
Salt and vinegar for rust removal
On Wed, 12 May 2004 13:43:42 -0700, Larry Blanchard
posted: In article , Sandy says... I'm wondering why the salt. It surely does nothing but perhaps cause problems later on. See your friendly local chemistry professor :-). Do you not know what it does? I've got a fairly reasonable handle on chemistry, and I can't see what the salt is there for. The acetic acid will dissolve rust, and slowly dissolve iron. No need for the salt unless you know of a good reason. Please expound. |
Salt and vinegar for rust removal
"Sandy" wrote in message
... On Wed, 12 May 2004 13:43:42 -0700, Larry Blanchard posted: In article , Sandy says... I'm wondering why the salt. It surely does nothing but perhaps cause problems later on. See your friendly local chemistry professor :-). Do you not know what it does? I've got a fairly reasonable handle on chemistry, and I can't see what the salt is there for. The acetic acid will dissolve rust, and slowly dissolve iron. No need for the salt unless you know of a good reason. Please expound. A quick search turned up this. This guy says it pretty well. The bottom line is that the dissolution of the rust is prompted by the presence of acetate and chloride ions. Iron would rather form a molecule with acetate or chloride ions, which are soluble in water than remain as iron oxide, which is insoluble. It is easy to introduce chloride in the form of salt, and greatly increase the rate of reaction. The acid component of the solution apparently does not take part in the dissolution of the rust (but does dissolve the pure iron). It prevents the iron ions from reforming into iron hydroxides, which are insoluble as is the original iron oxide (rust). dwhite From: (Don Wilkins) Newsgroups: rec.crafts.metalworking Subject: Rust Date: Sat, 03 Apr 1999 01:35:37 GMT On 2 Apr 1999 13:49:14 GMT, (James W. Swonger) wrote: In article , Grant Erwin wrote: Muriatic acid works fine on rusty steel. It attacks the rust a lot faster than the steel. As a chemist my first choice is hydrochloric acid as a solvent for rust. Muriatic acid is readily available from the local hardware stores. Yes it will also dissolve iron so you don't want to dump the parts in and come back next week to see if the rust is dissolved. ... Vinegar alone is just a slower and milder form of the above. Commercial pickling (submersion in a hot bath of a combination of strong acids) is a more extreme version of the above. I guess I want to mildly disagree with this. Vinegar is about 5% acetic acid and also contains various organic stuff to provide some taste but which are not particularly essential to the derusting. Acetic acid is a weak acid and is going to behave differently than hydrochloric acid. The acetate ion forms soluble complexes with iron in solution which aids in the dissolution. Since acetic acid is a weak acid there will be a lot of the acetate ion tied up as undissociated acetic acid. Hydrochloric acid is a strong acid and will be essentially completely dissociated. The chloride ion forms a stable complex with trivalent iron. It is the stability of this complex which aids in dissolving the iron oxide (rust). The addition of sodium chloride to the vinegar provides the extra complexing power of the chloride to this mixture. I'm not sure what happens chemically with salt and vinegar. I've only used it to clean coppers, brasses and bronzes where if it works it is like magic. The chloride and/or the acetate ions form stable complexes with iron ions which aids in the dissolution of rust. The trivalent iron forms much more stable complexes which would lead one to believe that the solutions would be more effective with e.g. Fe2O3 than with lower oxides. Those tenacious black oxides are more dense and usually contain divalent iron oxide. The combination gives you a mild hydrochloric acid with other junk floating in it. H+ Na+ Cl- CH3COO- (acetate) Well sort of but there will also be a fair amount of undissociated acetic acid. The acetate might give you some buffering effect, perhaps. I've seen acetic acid as an additive in a couple of electroplating recipes. Yes but the buffering is not important in this case. The active principle is the HCl. For the copper based materials, it converts the insoluble oxides to soluble chlorides. I expect the same activity is responsible for iron cleaning. In principle it is the same but it is the complexing power of the anions (chloride and acetate) which drive the reaction. It needs to be acidic enough to prevent the precipitation of the very insoluble iron hydroxides. Other than that the hydrogen ion does not participate in the dissolution of the rust. The hydrogen ion concentration does contribute to the speed at which the metallic iron disappears. There have been extensive discussions of an electrolytic method in the past which I have stayed clear of. In that case it appears that the rust removal is accomplished by creating hydrogen gas underneath the rust coating and 'blasting" it off. This would explain why some of those black dense oxide coatings are not removed. The electrolytic method should not remove much metallic iron but on the other hand what ever is on the surface as rust and gets "blasted" off is not likely to be redeposited as metallic iron back on the piece from the same location from which it originated. In other words what is turned to rust ain't gonna get put back where it once was. Search for Google's copy of this article ---------------------------------------------------------------------------- ---- From: (Don Wilkins) Newsgroups: rec.crafts.metalworking Subject: Rust Date: Sun, 04 Apr 1999 18:25:07 GMT On Sat, 3 Apr 1999 12:04:33 -0600, "Don Foreman" wrote: . It needs to be acidic enough to prevent the precipitation of the very insoluble iron hydroxides. Other than that the hydrogen ion does not participate in the dissolution of the rust. The hydrogen ion concentration does contribute to the speed at which the metallic iron disappears. Does this mean that using stronger acetic acid probably would not speed rust removal but may increase rate of attack on steel? I probably should say I don't know the answer to this question. My opinion not backed by any research is that the 5% concentration of acetic acid in vinegar probably isn't the optimum concentration. I ran through some equations below to show why increasing the acetic acid concentration doesn't increase the hydrogen ion concentration at the same rate as occurs with hydrochloric acid. At 5% acetic acid I doubt if the hydrogen ion concentration is high enough to dissolve iron. Rust is already oxidized iron so when it is dissolved there is no requirement for a change in oxidation state. When you dissolve the metal (any metal) into an aqueous solution the metal is oxidized. If the metal is oxidized then something must be reduced. If there is nothing there to be reduced then the metal won't be oxidized. In the mixtures under discussion (hydrochloric acid solutions or vinegar-salt) there are three things present in the solution to serve as oxidizing agents. These are the hydrogen ions from the acid, the oxygen dissolved in the solution, and ferric iron. So if you increase the hydrogen ion concentration then there will be an increase in the dissolution of the metal (in this case iron). This will be very apparent when a strong acid is used such as hydrochloric acid because all of the acid is ionized. Acetic acid however is a weak acid so an increase in the concentration of this acid does not increase the hydrogen ion concentration proportionally. If you look at the equation for the ionization of acetic acid HAc ---- (H+) + (Ac-) one finds that there is an equilibrium constant for that dissociation (H+) (Ac-)/ (HAc) = ~10^-5 since (H+) = (Ac-) (H+) = square root of (HAc)*10^-5 With that it is obvious that increasing the acetic acid concentration is not going to cause a rapid increase in the dissolution of iron metal. Who ever came up with the addition of chloride ion did so to provide something to form a complex with the dissolved iron among other things. If you look at that equation above for the dissociation it is obvious that if they had added acetate ion (e.g. sodium acetate) it would have reduced the hydrogen ion concentration probably causing precipitation of iron compounds. Clever idea for kitchen chemicals. On the other hand there are other reactions which will come into play once the process is started. As most of you know ferric chloride can be quite corrosive and is a pretty good etching agent. The ferric chloride produced from the dissolved rust is going to look at that freshly produced iron metal surface as a nice place to do some etching (dissolve iron metal). Of course there will be some divalent iron present as well. This will come either from the rust or by the reaction of the ferric chloride with the metallic iron. Oxygen (from air) dissolved in the solution will oxidize the ferrous ions up to ferric. This ferric can then react again with metallic iron. If you don't want to dissolve iron metal then you should remove air from the procedure. A little bit of ferric chloride in a sodium chloride solution with a continuous supply of oxygen can dissolve one hell of a lot of iron. I hope this hasn't confused the issue more than it helped. I suspect that one could make a better rust removal solution using glacial acetic acid, water, and sodium chloride. I believe the formula was developed because of the ready availability of vinegar and salt. I would vary the chloride concentration as well as the acetic acid concentration. If you don't want to dissolve iron metal keep oxygen out of the process. If you are inclined to do this be careful with glacial acetic acid. It doesn't burn or cause immediate discomfort on the skin but if not removed promptly will cause large thick patches of skin to come off leaving tender exposed meat. This is a type of chemical burn that you are not likely to get more than once. As I read and reread this post I am not entirely satisfied but there is some very complex chemistry taking place and it is not easy to describe it in a short note. |
Salt and vinegar for rust removal
On Thu, 13 May 2004 02:26:20 GMT, "Dan White"
posted: "Sandy" wrote in message .. . On Wed, 12 May 2004 13:43:42 -0700, Larry Blanchard posted: In article , Sandy says... I'm wondering why the salt. It surely does nothing but perhaps cause problems later on. See your friendly local chemistry professor :-). Do you not know what it does? I've got a fairly reasonable handle on chemistry, and I can't see what the salt is there for. The acetic acid will dissolve rust, and slowly dissolve iron. No need for the salt unless you know of a good reason. Please expound. A quick search turned up this. This guy says it pretty well. The bottom line is that the dissolution of the rust is prompted by the presence of acetate and chloride ions. But I can't understand why. Iron acetate is as soluble as iron chloride, although it will be a moot point as the solution will just be a mixture of hydrogen ions, iron ions, acetate ions, sodium ions, chloride ions, and undissociated acetic acid. The undissociated acetic acid supplies the pool of hydrogen ions at a concentration that depends on the "strength" (not concentration) of that acid. Iron would rather form a molecule with acetate or chloride ions, which are soluble in water than remain as iron oxide, which is insoluble. Only because the neutralisation (rust dissolution) results in water which is effectively removed from the reaction. This is what drives the reaction in the direction of the dissolution of the iron oxide. It is easy to introduce chloride in the form of salt, and greatly increase the rate of reaction. I don't see how. The acid component of the solution apparently does not take part in the dissolution of the rust (but does dissolve the pure iron). Of course it does! The H+ of the acid is involved in dissolving the rust. Try doing it without :) It prevents the iron ions from reforming into iron hydroxides, which are insoluble as is the original iron oxide (rust). Not only does it prevent this (through the formation of water) it is the only thing which dissolves the rust in the first place. dwhite From: (Don Wilkins) Newsgroups: rec.crafts.metalworking Subject: Rust Date: Sat, 03 Apr 1999 01:35:37 GMT On 2 Apr 1999 13:49:14 GMT, (James W. Swonger) wrote: In article , Grant Erwin wrote: Muriatic acid works fine on rusty steel. It attacks the rust a lot faster than the steel. As a chemist my first choice is hydrochloric acid as a solvent for rust. Of course, but you have to be quick to keep any of the iron. My first choice is certainly not a strong acid like this. Far too dangerous. Muriatic acid is readily available from the local hardware stores. Yes it will also dissolve iron so you don't want to dump the parts in and come back next week to see if the rust is dissolved. Too dangerous for me. .. Vinegar alone is just a slower and milder form of the above. Commercial pickling (submersion in a hot bath of a combination of strong acids) is a more extreme version of the above. I guess I want to mildly disagree with this. Vinegar is about 5% acetic acid and also contains various organic stuff to provide some taste but which are not particularly essential to the derusting. Acetic acid is a weak acid and is going to behave differently than hydrochloric acid. Only in speed. They both do much the same thing eventually. The acetate ion forms soluble complexes with iron in solution which aids in the dissolution. All acids will form complexes of greater or lesser solubility. Since acetic acid is a weak acid there will be a lot of the acetate ion tied up as undissociated acetic acid. Only until the dissociated H+ is used up. There will be a constant supply of H+ ions, just a much lesser concentration than with a strong acid. Hydrochloric acid is a strong acid and will be essentially completely dissociated. The chloride ion forms a stable complex with trivalent iron. It is the stability of this complex which aids in dissolving the iron oxide (rust). But there is no hydrochloric acid in the salt/vinegar solution. The iron acetate is as soluble and stable as the iron chloride. The addition of sodium chloride to the vinegar provides the extra complexing power of the chloride to this mixture. What is "complexing power"? I must've missed that lecture :) I'm not sure what happens chemically with salt and vinegar. I've only used it to clean coppers, brasses and bronzes where if it works it is like magic. The chloride and/or the acetate ions form stable complexes with iron ions which aids in the dissolution of rust. But the acetate ion is sufficient, I would have thought. The chloride is surely superfluous. It's the H+ which does the neutralising. The trivalent iron forms much more stable complexes which would lead one to believe that the solutions would be more effective with e.g. Fe2O3 than with lower oxides. Those tenacious black oxides are more dense and usually contain divalent iron oxide. And it will be the concentration of H+ that does the trick, and sodium chloride in the vinrgar will make no difference to this AFAICS. The combination gives you a mild hydrochloric acid with other junk floating in it. H+ Na+ Cl- CH3COO- (acetate) Well sort of but there will also be a fair amount of undissociated acetic acid. Which is of no consequence, as whenever the H+ is taken out of solution by becoming water, more acetic acid dissociates supplying more H+. The acetate might give you some buffering effect, perhaps. I've seen acetic acid as an additive in a couple of electroplating recipes. Yes but the buffering is not important in this case. The active principle is the HCl. For the copper based materials, it converts the insoluble oxides to soluble chlorides. I expect the same activity is responsible for iron cleaning. In principle it is the same but it is the complexing power of the anions (chloride and acetate) which drive the reaction. Not at all. It is simply the formation of water from the neutralising by the acetic acid of the iron oxide base. It needs to be acidic enough to prevent the precipitation of the very insoluble iron hydroxides. And vinegar is just that. Salt will make no difference to the acidity. It is neutral, remember. It will supply NO hydrogen ions (H+) Other than that the hydrogen ion does not participate in the dissolution of the rust. Of course it does. It is the other half of the reaction. The water forming bit which drives it to the right, in fact. Most reactions go a certain direction because of the loss, or inability to participate further, of one or more of the reactants. Carbon dioxide may bubble off and get lost, or a precipitate of an insoluble reactant may form. In this case, effectively-undissociated water is formed. The hydrogen ion concentration does contribute to the speed at which the metallic iron disappears. But also the rate at which neutralisation of the iron oxide (base) occurs. There have been extensive discussions of an electrolytic method in the past which I have stayed clear of. In that case it appears that the rust removal is accomplished by creating hydrogen gas underneath the rust coating and 'blasting" it off. This would explain why some of those black dense oxide coatings are not removed. No, it is surely just applying an electric potential to drive a reaction in the direction you want. The electrolytic method should not remove much metallic iron but on the other hand what ever is on the surface as rust and gets "blasted" off is not likely to be redeposited as metallic iron back on the piece from the same location from which it originated. I think the advantage of electrolytic methods are that not one further molecule of metallic iron will be dissolved. Unlike your drastic hydrochloric acid method :) In other words what is turned to rust ain't gonna get put back where it once was. Nope. Maybe a few molecules on the surface of the metal, but I would guess this is insignificant. The aim really is to halt the corrosion where it is at, and not advance it further by the rust removal process. Search for Google's copy of this article ---------------------------------------------------------------------------- ---- From: (Don Wilkins) Newsgroups: rec.crafts.metalworking Subject: Rust Date: Sun, 04 Apr 1999 18:25:07 GMT On Sat, 3 Apr 1999 12:04:33 -0600, "Don Foreman" wrote: . It needs to be acidic enough to prevent the precipitation of the very insoluble iron hydroxides. Other than that the hydrogen ion does not participate in the dissolution of the rust. The hydrogen ion concentration does contribute to the speed at which the metallic iron disappears. Does this mean that using stronger acetic acid probably would not speed rust removal but may increase rate of attack on steel? I probably should say I don't know the answer to this question. My opinion not backed by any research is that the 5% concentration of acetic acid in vinegar probably isn't the optimum concentration. I ran through some equations below to show why increasing the acetic acid concentration doesn't increase the hydrogen ion concentration at the same rate as occurs with hydrochloric acid. At 5% acetic acid I doubt if the hydrogen ion concentration is high enough to dissolve iron. Slowly (very) Rust is already oxidized iron so when it is dissolved there is no requirement for a change in oxidation state. When you dissolve the metal (any metal) into an aqueous solution the metal is oxidized. If the metal is oxidized then something must be reduced. If there is nothing there to be reduced then the metal won't be oxidized. Hydrogen ions? In the mixtures under discussion (hydrochloric acid solutions or vinegar-salt) there are three things present in the solution to serve as oxidizing agents. These are the hydrogen ions from the acid, the oxygen dissolved in the solution, and ferric iron. Which are not supplied by the salt. So if you increase the hydrogen ion concentration then there will be an increase in the dissolution of the metal (in this case iron). This will be very apparent when a strong acid is used such as hydrochloric acid because all of the acid is ionized. Yep. Acetic acid however is a weak acid so an increase in the concentration of this acid does not increase the hydrogen ion concentration proportionally. If you look at the equation for the ionization of acetic acid Yep HAc ---- (H+) + (Ac-) one finds that there is an equilibrium constant for that dissociation As with everything..... (H+) (Ac-)/ (HAc) = ~10^-5 since (H+) = (Ac-) (H+) = square root of (HAc)*10^-5 With that it is obvious that increasing the acetic acid concentration is not going to cause a rapid increase in the dissolution of iron metal. Yep. Godawful slow. Who ever came up with the addition of chloride ion did so to provide something to form a complex with the dissolved iron among other things. If you look at that equation above for the dissociation it is obvious that if they had added acetate ion (e.g. sodium acetate) it would have reduced the hydrogen ion concentration probably causing precipitation of iron compounds. Clever idea for kitchen chemicals. Of course. On the other hand there are other reactions which will come into play once the process is started. As most of you know ferric chloride can be quite corrosive and is a pretty good etching agent. The ferric chloride produced from the dissolved rust is going to look at that freshly produced iron metal surface as a nice place to do some etching (dissolve iron metal). Well simply a salt of a strong acid and a weak base. Of course there will be some divalent iron present as well. This will come either from the rust or by the reaction of the ferric chloride with the metallic iron. H+ + Fe --- Oxygen (from air) dissolved in the solution will oxidize the ferrous ions up to ferric. This ferric can then react again with metallic iron. If you don't want to dissolve iron metal then you should remove air from the procedure. A little bit of ferric chloride in a sodium chloride solution with a continuous supply of oxygen can dissolve one hell of a lot of iron. H+ + Fe + O2 --- Rust :) I hope this hasn't confused the issue more than it helped. I suspect that one could make a better rust removal solution using glacial acetic acid, water, and sodium chloride. I believe the formula was developed because of the ready availability of vinegar and salt. I would vary the chloride concentration as well as the acetic acid concentration. If you don't want to dissolve iron metal keep oxygen out of the process. Fine, but what does the chloride contribute? If you are inclined to do this be careful with glacial acetic acid. It doesn't burn or cause immediate discomfort on the skin but if not removed promptly will cause large thick patches of skin to come off leaving tender exposed meat. This is a type of chemical burn that you are not likely to get more than once. Of course, but as vinegar is so harmless and cheaply available... As I read and reread this post I am not entirely satisfied but there is some very complex chemistry taking place and it is not easy to describe it in a short note. I just want to know the rationale for the addition of neutral chloride ions. They don't increase the dissociation of the acetic acid, I would have thought. Iron chlorides are no more soluble than iron acetates. |
Salt and vinegar for rust removal
"Sandy" wrote in message
... In article , Sandy says... I'm wondering why the salt. It surely does nothing but perhaps cause problems later on. See your friendly local chemistry professor :-). Do you not know what it does? I've got a fairly reasonable handle on chemistry, and I can't see what the salt is there for. The acetic acid will dissolve rust, and slowly dissolve iron. No need for the salt unless you know of a good reason. Please expound. Sandy - I provided that rather long post that you responded to yesterday. I deleted it because of its size, and most of it is unrelated to your question. Also, you should realize (if you didn't) that I was passing on an article written by someone and didn't add any of my own thoughts, since I have forgotten so much chemistry I didn't want to dust off the brain cells. However, after reading your correct responses to his article, I had some thoughts that might possibly help, although I don't have a proven answer to your question. :( Let me say that I agree that the driving force in the reaction to dissolve the iron oxide is the hydronium ion, and formation of water on the right side of the equilibrium. I think the answer to why you have to add salt to the mix is that the salt increases the ionic strength of the solution. This improves the conductivity of the solution, and might have the effect of improving the rate of reaction by allowing an easier transfer of charges among the reacting ions. I know this is a bit vague, but I don't know if anybody has a really good answer on this. On the other hand, I recall that the equilibrium constant is really based on the activity of the ions in solution, and not their concentration. At higher ionic strengths (due to salt addition), I believe the activity, and therefore, the equilibrium constant, is lower than it would be without the salt. It seems to me this would tend to lower the dissociation of the acetic acid, and bind up even more H+ than without the salt. I think if this is correct, that it isn't the prevailing factor as I believe the salt does increase the reaction rate. I think the case of cleaning your copper pots is similar to the rust issue. In that case, if you pour vinegar on the copper pot with the oxides on it, you won't see much if anything happen. When you sprinkle salt on the surface wetted with vinegar, you quickly see the oxides disappear from the spots where the salt is dissolving. It is very clear that salt does speed the rate of reaction in the case of copper oxides, and I have to think it does the same with iron oxides. If you don't believe salt does anything, it is simple enough to test for yourself on two equal rusty spots. As to "why" it works, I have to think it is because of improved migration of electrons through solution due to the higher ionic strength of the solution. You might find, for example, that it takes two weeks to do the job with acetic acid alone, and one day with the salt added. Whatever problems you say the salt may cause later on may be outweighted by the time factor. Of course it is also possible (probable?) that the acid alone will not only take longer, but might in fact not remove as much oxide in the end. I had one other thought, improbable as it may be: I'd say the Fe3+ ion is relatively large compared to the Cl- ion. On the other hand, the acetate ion is of course a molecule and not a single ion. Maybe there is also a bit of steric hindrance going on as well. With no Cl- present, all the Fe3+ has to bond with the acetate molecule (3 of them). If there is some difficulty fitting 3 of these molecules on one Fe ion, the reaction could be inhibited. If free Cl- is present, it could more quickly and easily neutralize the Fe ion and move the molecule away from the reacting area. regards, dwhite |
Salt and vinegar for rust removal
"Dan White" wrote in message . net... On the other hand, the acetate ion is of course a molecule and not a single ion. Minor correction: it is a single ion, just not a single atom. dwhite |
Salt and vinegar for rust removal
On Thu, 13 May 2004 07:31:37 GMT, "Dan White"
posted: "Sandy" wrote in message .. . In article , Sandy says... I'm wondering why the salt. It surely does nothing but perhaps cause problems later on. See your friendly local chemistry professor :-). Do you not know what it does? I've got a fairly reasonable handle on chemistry, and I can't see what the salt is there for. The acetic acid will dissolve rust, and slowly dissolve iron. No need for the salt unless you know of a good reason. Please expound. Sandy - I provided that rather long post that you responded to yesterday. I deleted it because of its size, and most of it is unrelated to your question. Also, you should realize (if you didn't) that I was passing on an article written by someone and didn't add any of my own thoughts, since I have forgotten so much chemistry I didn't want to dust off the brain cells. However, after reading your correct responses to his article, I had some thoughts that might possibly help, although I don't have a proven answer to your question. :( Let me say that I agree that the driving force in the reaction to dissolve the iron oxide is the hydronium ion, and formation of water on the right side of the equilibrium. I think the answer to why you have to add salt to the mix is that the salt increases the ionic strength of the solution. This improves the conductivity of the solution, and might have the effect of improving the rate of reaction by allowing an easier transfer of charges among the reacting ions. I know this is a bit vague, but I don't know if anybody has a really good answer on this. On the other hand, I recall that the equilibrium constant is really based on the activity of the ions in solution, and not their concentration. At higher ionic strengths (due to salt addition), I believe the activity, and therefore, the equilibrium constant, is lower than it would be without the salt. It seems to me this would tend to lower the dissociation of the acetic acid, and bind up even more H+ than without the salt. I think if this is correct, that it isn't the prevailing factor as I believe the salt does increase the reaction rate. I think the case of cleaning your copper pots is similar to the rust issue. In that case, if you pour vinegar on the copper pot with the oxides on it, you won't see much if anything happen. When you sprinkle salt on the surface wetted with vinegar, you quickly see the oxides disappear from the spots where the salt is dissolving. It is very clear that salt does speed the rate of reaction in the case of copper oxides, and I have to think it does the same with iron oxides. If you don't believe salt does anything, it is simple enough to test for yourself on two equal rusty spots. As to "why" it works, I have to think it is because of improved migration of electrons through solution due to the higher ionic strength of the solution. You might find, for example, that it takes two weeks to do the job with acetic acid alone, and one day with the salt added. Whatever problems you say the salt may cause later on may be outweighted by the time factor. Of course it is also possible (probable?) that the acid alone will not only take longer, but might in fact not remove as much oxide in the end. I had one other thought, improbable as it may be: I'd say the Fe3+ ion is relatively large compared to the Cl- ion. On the other hand, the acetate ion is of course a molecule and not a single ion. Maybe there is also a bit of steric hindrance going on as well. With no Cl- present, all the Fe3+ has to bond with the acetate molecule (3 of them). If there is some difficulty fitting 3 of these molecules on one Fe ion, the reaction could be inhibited. If free Cl- is present, it could more quickly and easily neutralize the Fe ion and move the molecule away from the reacting area. regards, dwhite Interesting thoughts, Dan. This discussion has certainly disturbed some old cobwebs in my attic :) Gotta be over 40 years since that happened, although my daughter is doing some elementary chem at night school and my helping her is also raising the dust. I don't disbelieve that it helps matters, but I just can't quite understand why, although you have given me some food for thought. I have never tested it, although as it happens, I had a rusty steel band on a hose fiting that I wanted to remove and so stuck it in a glass of white vinegar overnight. It cleaned the rust off enough to show me that there was so much metal left that it needed the grinder to get it off. I can't really buy the conductivity argument, as what needs to happen is the migration of H+ to the rust and the migration away from it of iron ions. I also can't buy the spatial problem of the size of acetate ions, coz the stuff is all in solution, and not forming crystals. BTW, the problems later with soaking a piece of rusty steel in salt solution is that the salt gets trapped in the fine pits of the rusted surface and later attracts moisture and THEN the conductivity of this solution exposed to oxygen continues the corrosion at a pace. Anyways, thanks for the stimulating discussion :) |
Salt and vinegar for rust removal
On Thu, 13 May 2004 08:21:20 GMT, "Dan White"
posted: "Dan White" wrote in message .net... On the other hand, the acetate ion is of course a molecule and not a single ion. Minor correction: it is a single ion, just not a single atom. dwhite Yep, it's big, but this surely only matters when it has to associate with a cation. Crystalisation. |
Salt and vinegar for rust removal
"Sandy" wrote in message ... On Thu, 13 May 2004 07:31:37 GMT, "Dan White" posted: "Sandy" wrote in message .. . In article , Sandy says... I'm wondering why the salt. It surely does nothing but perhaps cause problems later on. See your friendly local chemistry professor :-). Do you not know what it does? I've got a fairly reasonable handle on chemistry, and I can't see what the salt is there for. The acetic acid will dissolve rust, and slowly dissolve iron. No need for the salt unless you know of a good reason. Please expound. Sandy - I provided that rather long post that you responded to yesterday. I deleted it because of its size, and most of it is unrelated to your question. Also, you should realize (if you didn't) that I was passing on an article written by someone and didn't add any of my own thoughts, since I have forgotten so much chemistry I didn't want to dust off the brain cells. However, after reading your correct responses to his article, I had some thoughts that might possibly help, although I don't have a proven answer to your question. :( Let me say that I agree that the driving force in the reaction to dissolve the iron oxide is the hydronium ion, and formation of water on the right side of the equilibrium. I think the answer to why you have to add salt to the mix is that the salt increases the ionic strength of the solution. This improves the conductivity of the solution, and might have the effect of improving the rate of reaction by allowing an easier transfer of charges among the reacting ions. I know this is a bit vague, but I don't know if anybody has a really good answer on this. On the other hand, I recall that the equilibrium constant is really based on the activity of the ions in solution, and not their concentration. At higher ionic strengths (due to salt addition), I believe the activity, and therefore, the equilibrium constant, is lower than it would be without the salt. It seems to me this would tend to lower the dissociation of the acetic acid, and bind up even more H+ than without the salt. I think if this is correct, that it isn't the prevailing factor as I believe the salt does increase the reaction rate. I think the case of cleaning your copper pots is similar to the rust issue. In that case, if you pour vinegar on the copper pot with the oxides on it, you won't see much if anything happen. When you sprinkle salt on the surface wetted with vinegar, you quickly see the oxides disappear from the spots where the salt is dissolving. It is very clear that salt does speed the rate of reaction in the case of copper oxides, and I have to think it does the same with iron oxides. If you don't believe salt does anything, it is simple enough to test for yourself on two equal rusty spots. As to "why" it works, I have to think it is because of improved migration of electrons through solution due to the higher ionic strength of the solution. You might find, for example, that it takes two weeks to do the job with acetic acid alone, and one day with the salt added. Whatever problems you say the salt may cause later on may be outweighted by the time factor. Of course it is also possible (probable?) that the acid alone will not only take longer, but might in fact not remove as much oxide in the end. I had one other thought, improbable as it may be: I'd say the Fe3+ ion is relatively large compared to the Cl- ion. On the other hand, the acetate ion is of course a molecule and not a single ion. Maybe there is also a bit of steric hindrance going on as well. With no Cl- present, all the Fe3+ has to bond with the acetate molecule (3 of them). If there is some difficulty fitting 3 of these molecules on one Fe ion, the reaction could be inhibited. If free Cl- is present, it could more quickly and easily neutralize the Fe ion and move the molecule away from the reacting area. regards, dwhite Interesting thoughts, Dan. This discussion has certainly disturbed some old cobwebs in my attic :) Gotta be over 40 years since that happened, although my daughter is doing some elementary chem at night school and my helping her is also raising the dust. I don't disbelieve that it helps matters, but I just can't quite understand why, although you have given me some food for thought. I have never tested it, although as it happens, I had a rusty steel band on a hose fiting that I wanted to remove and so stuck it in a glass of white vinegar overnight. It cleaned the rust off enough to show me that there was so much metal left that it needed the grinder to get it off. I can't really buy the conductivity argument, as what needs to happen is the migration of H+ to the rust and the migration away from it of iron ions. I also can't buy the spatial problem of the size of acetate ions, coz the stuff is all in solution, and not forming crystals. BTW, the problems later with soaking a piece of rusty steel in salt solution is that the salt gets trapped in the fine pits of the rusted surface and later attracts moisture and THEN the conductivity of this solution exposed to oxygen continues the corrosion at a pace. Anyways, thanks for the stimulating discussion :) Ditto! All I can say is that the presence of ions in solution, ionic strength, does definitely affect how species in solution react. Maybe there is some physical chemistry website or ng you can visit and ask this question. I'd be interested to know, too! dwhite |
Salt and vinegar for rust removal
"Sandy" wrote in message ... On Thu, 13 May 2004 08:21:20 GMT, "Dan White" posted: "Dan White" wrote in message .net... On the other hand, the acetate ion is of course a molecule and not a single ion. Minor correction: it is a single ion, just not a single atom. dwhite Yep, it's big, but this surely only matters when it has to associate with a cation. Crystalisation. But steric hindrance is not a phenomenon reserved only to the crystalization of compounds. There are several kinds of hindrance, and they don't all have to do with crystallization. I don't think it really matters anyway because the acetate ion probably isn't nearly large enough. It was just a thought. dwhite |
Salt and vinegar for rust removal
|
Salt and vinegar for rust removal
"Larry Blanchard" wrote in message ... But what I meant by "ask a chemist" is that a friend of mine who is a chemist said that the vinegar and salt combined to form a weak hydrochloric acid. I took his word for it. I think Sandy's point on this was that the H+ ions are already in solution from the acetic acid. The presence of Cl- ions doesn't change anything related to acid strength. For instance, it does not change the dissociation constant for acetic acid, thereby increasing the H+ concentration. It is the H+ concentration that determines how strong the acid is. My point was that the activity of the ions in solution is decreased by the addition of a lot of ions like Cl- and might actually lower the acidity. This does not seem to be the predominant outcome, however, because the salt does increase the speed of the reaction. dwhite |
Salt and vinegar for rust removal
On Thu, 13 May 2004 09:04:26 -0700, Larry Blanchard
posted: In article , says... Ditto! All I can say is that the presence of ions in solution, ionic strength, does definitely affect how species in solution react. Maybe there is some physical chemistry website or ng you can visit and ask this question. I'd be interested to know, too! Wow! I didn't mean to start such a learned discussion :-). My knowledge of chemistry is limited to making various explosive compounds, learned long ago in my juvenile days. And lately, I think I've forgotten most of that - CRS seting in :-). But what I meant by "ask a chemist" is that a friend of mine who is a chemist said that the vinegar and salt combined to form a weak hydrochloric acid. I took his word for it. Yep it makes what might be regarded as a "weak" hydrochloric acid. This doesn't mean "dilute" BTW. And guess what? Acetic acid is "weak" so there is effectively no difference on this count. If you could make acetic acid "strong" you would have the equivalent of hydrochloric acid. Strong and Weak wrt acids means that they dissociate forming the H+ and anions to a greater or lesser extent. |
Salt and vinegar for rust removal
On Thu, 13 May 2004 09:04:26 -0700, Larry Blanchard
wrote: ,;In article , says... ,; Ditto! All I can say is that the presence of ions in solution, ionic ,; strength, does definitely affect how species in solution react. Maybe there ,; is some physical chemistry website or ng you can visit and ask this ,; question. I'd be interested to know, too! ,; ,;Wow! I didn't mean to start such a learned discussion :-). My ,;knowledge of chemistry is limited to making various explosive ,;compounds, learned long ago in my juvenile days. And lately, I ,;think I've forgotten most of that - CRS seting in :-). ,; ,;But what I meant by "ask a chemist" is that a friend of mine who ,;is a chemist said that the vinegar and salt combined to form a ,;weak hydrochloric acid. I took his word for it. You shouldn't have as he was wrong. Vinegar is approximately 5% acetic acid plus some other goodies to provide some taste. The hydrogen ion concentration is not sufficient to react with metallic iron and therein lies one of the keys to the process. The other key is the fact that chloride ions form a stable complex with iron ions in solution. The iron chloride complex is strong enough so that iron oxide will dissolve and form that complex. Since there is no oxidant strong enough to react with iron metal the net result is that the iron oxide goes into solution as the chloride but the iron metal does not react. It is essential that the solution be kept oxygen free or the metal will dissolve. This is particularly noticeable if you allow the metal to be "derusted" to stick out of the solution into air e.g. you will find that there has been a dissolution of iron metal at the air liquid interface. The role of the acetic acid is to keep the solution acidic enough to prevent the precipitation of iron oxide but low enough so that iron metal does not react with hydrogen ions. It is the high concentration of chloride that removes the rust not a "weak hydrochloric acid". If one used a concentrated salt solution without the acetic acid then one would get a preciptate of hydrous iron oxide at the surface. This would slow the reaction to a crawl. A weak acid such as acetic acid allows one to put a lot of acid in the solution but maintain a relatively low hydrogen concentration. The solution if kept covered can be used repeatedly until the amount of dissolved iron reaches a point where the hydrous oxide begins to precipitate. If the used solutions are left open to the air then it will accumulate ferric chloride as a result of air oxidation. That ferric chloride is an oxidizing agent strong enough to react with iron metal which is the reason one gets an "etch line" at the liquid surface. |
Salt and vinegar for rust removal
"Unknown" wrote in message ... On Thu, 13 May 2004 09:04:26 -0700, Larry Blanchard wrote: ,;In article , says... ,; Ditto! All I can say is that the presence of ions in solution, ionic ,; strength, does definitely affect how species in solution react. Maybe there ,; is some physical chemistry website or ng you can visit and ask this ,; question. I'd be interested to know, too! ,; ,;Wow! I didn't mean to start such a learned discussion :-). My ,;knowledge of chemistry is limited to making various explosive ,;compounds, learned long ago in my juvenile days. And lately, I ,;think I've forgotten most of that - CRS seting in :-). ,; ,;But what I meant by "ask a chemist" is that a friend of mine who ,;is a chemist said that the vinegar and salt combined to form a ,;weak hydrochloric acid. I took his word for it. You shouldn't have as he was wrong. Vinegar is approximately 5% acetic acid plus some other goodies to provide some taste. The hydrogen ion concentration is not sufficient to react with metallic iron and therein lies one of the keys to the process. The other key is the fact that chloride ions form a stable complex with iron ions in solution. The iron chloride complex is strong enough so that iron oxide will dissolve and form that complex. Since there is no oxidant strong enough to react with iron metal the net result is that the iron oxide goes into solution as the chloride but the iron metal does not react. Can you explain exactly what this iron-chloride complex is? Are you saying that the iron oxide (rust) is preferentially breaking it's molecular bonds and is reforming as some kind of complex, or as iron chloride? I take it that it is not iron chloride because you say below that if oxygen is introduced, then ferric chloride will form. Second question: What is the reaction that transforms this "iron chloride complex" into ferric chloride? Your mechanisms sound interesting, but it's hard to know if this is the actual path without knowing the driving forces mathematically. dwhite It is essential that the solution be kept oxygen free or the metal will dissolve. This is particularly noticeable if you allow the metal to be "derusted" to stick out of the solution into air e.g. you will find that there has been a dissolution of iron metal at the air liquid interface. The role of the acetic acid is to keep the solution acidic enough to prevent the precipitation of iron oxide but low enough so that iron metal does not react with hydrogen ions. It is the high concentration of chloride that removes the rust not a "weak hydrochloric acid". If one used a concentrated salt solution without the acetic acid then one would get a preciptate of hydrous iron oxide at the surface. This would slow the reaction to a crawl. A weak acid such as acetic acid allows one to put a lot of acid in the solution but maintain a relatively low hydrogen concentration. The solution if kept covered can be used repeatedly until the amount of dissolved iron reaches a point where the hydrous oxide begins to precipitate. If the used solutions are left open to the air then it will accumulate ferric chloride as a result of air oxidation. That ferric chloride is an oxidizing agent strong enough to react with iron metal which is the reason one gets an "etch line" at the liquid surface. |
Salt and vinegar for rust removal
On Fri, 14 May 2004 03:56:58 GMT, "Dan White"
wrote: ,; ,;"Unknown" wrote in message ... ,; On Thu, 13 May 2004 09:04:26 -0700, Larry Blanchard ,; wrote: ,; ,; ,;In article , ,; says... ,; ,; Ditto! All I can say is that the presence of ions in solution, ionic ,; ,; strength, does definitely affect how species in solution react. ,;Maybe there ,; ,; is some physical chemistry website or ng you can visit and ask this ,; ,; question. I'd be interested to know, too! ,; ,; ,; ,;Wow! I didn't mean to start such a learned discussion :-). My ,; ,;knowledge of chemistry is limited to making various explosive ,; ,;compounds, learned long ago in my juvenile days. And lately, I ,; ,;think I've forgotten most of that - CRS seting in :-). ,; ,; ,; ,;But what I meant by "ask a chemist" is that a friend of mine who ,; ,;is a chemist said that the vinegar and salt combined to form a ,; ,;weak hydrochloric acid. I took his word for it. ,; ,; You shouldn't have as he was wrong. ,; ,; Vinegar is approximately 5% acetic acid plus some other goodies to ,; provide some taste. The hydrogen ion concentration is not sufficient ,; to react with metallic iron and therein lies one of the keys to the ,; process. The other key is the fact that chloride ions form a stable ,; complex with iron ions in solution. The iron chloride complex is ,; strong enough so that iron oxide will dissolve and form that complex. ,; Since there is no oxidant strong enough to react with iron metal the ,; net result is that the iron oxide goes into solution as the chloride ,; but the iron metal does not react. ,; ,;Can you explain exactly what this iron-chloride complex is? Are you saying ,;that the iron oxide (rust) is preferentially breaking it's molecular bonds ,;and is reforming as some kind of complex, or as iron chloride? I take it ,;that it is not iron chloride because you say below that if oxygen is ,;introduced, then ferric chloride will form. Second question: What is the ,;reaction that transforms this "iron chloride complex" into ferric chloride? Both ferrous ions and ferric ions form stable chloride complexes. Stable enough so that the rust does dissolve in the strong chloride solution by breaking iron-oxygen bonds. When the rust dissolves in a chloride solution one will get a solution which contains both species. In the presence of metallic iron the ferric chloride (from dissolution of iron III in rust) will be reduced to ferrous chloride so when the reaction is done we have a ferrous chloride in solution. If one adds oxygen (from air) then the ferrous is oxidized to ferric and this ferric immediately reacts with the metallic iron. The result is that one dissolves more metallic iron than is necessary and probably more than one wants. In general you don't usually find three different oxidation states of an element present in solution at the same time. The highest oxidation state (ferric in this case) tends to react with the lowest (iron metal) to equilibrate with the one in the middle (ferrous). If you keep adding more air to form more ferric it should be obvious that the above reaction will continue until you run out of iron or oxygen. You can run out of oxygen by keeping the pot covered and the piece immersed. Usually the quantity of rust dissolved is small in comparisons to the mass of iron metal so one doesn't notice the fact that some iron metal is sacrificed in this procedure. If you allow air into the mix the effect of dissolved oxygen can be very apparent. You can demonstrate this by letting a piece of iron be partially immersed in the solution. You will get an etch line at the liquid surface. If it is some antique you are restoring this etch line will not be a pleasant sight and will be almost impossible to fix. ,; ,;Your mechanisms sound interesting, but it's hard to know if this is the ,;actual path without knowing the driving forces mathematically. It is nice that the correct chemistry is also interesting. If you need the math lookup some coordination chemistry text books at a technical library. The topic is probably not of that much interest for this group. Google "coordination chemistry" with the quotes will give you a good start. Probably more than you ever wanted to know. ,; ,;dwhite ,; ,; ,; ,; ,; It is essential that the solution be kept oxygen free or the metal ,; will dissolve. This is particularly noticeable if you allow the metal ,; to be "derusted" to stick out of the solution into air e.g. you will ,; find that there has been a dissolution of iron metal at the air liquid ,; interface. ,; ,; The role of the acetic acid is to keep the solution acidic enough to ,; prevent the precipitation of iron oxide but low enough so that iron ,; metal does not react with hydrogen ions. It is the high concentration ,; of chloride that removes the rust not a "weak hydrochloric acid". ,; ,; If one used a concentrated salt solution without the acetic acid then ,; one would get a preciptate of hydrous iron oxide at the surface. This ,; would slow the reaction to a crawl. ,; ,; A weak acid such as acetic acid allows one to put a lot of acid in the ,; solution but maintain a relatively low hydrogen concentration. ,; ,; The solution if kept covered can be used repeatedly until the amount ,; of dissolved iron reaches a point where the hydrous oxide begins to ,; precipitate. If the used solutions are left open to the air then it ,; will accumulate ferric chloride as a result of air oxidation. That ,; ferric chloride is an oxidizing agent strong enough to react with iron ,; metal which is the reason one gets an "etch line" at the liquid ,; surface. ,; ,; ,; |
Salt and vinegar for rust removal
"Unknown" wrote in message ... On Fri, 14 May 2004 03:56:58 GMT, "Dan White" wrote: ,; ,;Your mechanisms sound interesting, but it's hard to know if this is the ,;actual path without knowing the driving forces mathematically. It is nice that the correct chemistry is also interesting. If you need the math lookup some coordination chemistry text books at a technical library. The topic is probably not of that much interest for this group. Google "coordination chemistry" with the quotes will give you a good start. Probably more than you ever wanted to know. OK, thanks for the follow up. dwhite |
Salt and vinegar for rust removal
|
Salt and vinegar for rust removal
"Charles Erskine" wrote in message om... More than you probably wanted to know: http://yarchive.net/metal/rust_remove.html snip This is the post I pasted in this thread originally to try and answer the original question. thanks, dwhite |
Salt and vinegar for rust removal
|
Salt and vinegar for rust removal
On Fri, 14 May 2004 16:30:02 GMT, "Dan White"
wrote: ,; ,;"Charles Erskine" wrote in message e.com... ,; More than you probably wanted to know: ,; ,; http://yarchive.net/metal/rust_remove.html ,; ,; snip ,; ,;This is the post I pasted in this thread originally to try and answer the ,;original question. OK I missed your original post. I wrote the article you refer to. I am a chemist and do know what is happening in this procedure so let's start fresh. What is it that needs more clarification on this topic? You ask the questions and I will try to give a reasonable explanation. |
| All times are GMT +1. The time now is 04:24 AM. |
Powered by vBulletin® Copyright ©2000 - 2025, Jelsoft Enterprises Ltd.
Copyright ©2004 - 2014 DIYbanter