Monday, August 20, 2012

Thread Galling of Stainless steel fasteners Prevention from another author

Written by:J oe Greenslade

A few times each year we receive calls from fastener suppliers who are in conflict with their customer over the quality of stainless steel bolts and nuts. The customer's complaint is that during installation the bolts are twisting off and/or the bolt's threads are seizing to the nut's thread. The frustration of the supplier is that all required inspections of the fasteners indicate they are acceptable, but the fact remains that they are not working. 

This problem is called "thread galling." According to the Industrial Fastener Institute's 6th Edition Standards Book (page B-28), 

Thread galling seems to be the most prevalent with fasteners made of stainless steel, aluminum, titanium, and other alloys which self-generate an oxide surface film for corrosion protection. During fastener tightening, as pressure builds between the contacting and sliding thread surfaces, protective oxides are broken, possibly wiped off, and interface metal high points shear or lock together. This cumulative clogging-shearing-locking action causes increasing adhesion. In the extreme, galling leads to seizing - the actual freezing together of the threads. If tightening is continued, the fastener can be twisted off or its threads ripped out. 

Carpenter Technologies, the fastener industry's largest supplier of stainless steel raw material, refers to this type of galling in their technical guide as "cold welding." Anyone who has seen a bolt and nut with this problem understands the graphic nature of this description. 

The IFI and Carpenter Technologies give three suggestions for dealing with the problem of thread galling in the use of stainless steel fasteners: 

1. Slowing down the installation RPM speed will frequently reduce, or sometimes solve completely, the problem. As the installation RPM increases, the heat generated during tightening increases. As the heat increases, so does the tendency for the occurrence of thread galling. 
2. Lubricating the internal and/or external threads frequently eliminates thread galling. The suggested lubricants should contain substantial amounts of molybdenum disulfide (moly), graphite, mica, or talc. Some proprietary, extreme pressure waxes may also be effective. You must be aware of the end use of the fasteners before settling on a lubricant. Stainless steel is frequently used in food related applications, which may make some lubricants unacceptable. Lubricants can be applied at the point of assembly or pre-applied as a batch process similar to plating. Several chemical companies offer anti-galling lubricants. One such source, EM Corporation, suggests their Permaslik¨ RAC product for use at the point of assembly. They suggest Everlube¨ 620C for batch, pre-applying to stainless steel fasteners. 
3. Using different stainless alloy grades for the bolt and the nut reduces galling. The key here is the mating of materials having different hardnesses. If one of the components is 316 and the other is 304 they're less likely to gall than if they're both of the same alloy grade. This is because different alloys work-harden at different rates.
Another factor affecting thread galling in stainless steel fastener applications is thread roughness. The rougher the thread flanks, the greater the likelihood galling will occur. In an application where the bolt is galling with the internal thread, the bolt is usually presumed to be at fault, because it is the breaking component. Generally, it is the internal thread that is causing the problem instead of the bolt. This is because most bolt threads are smoother than most nut threads. Bolt threads are generally rolled, therefore, their thread flanks are relatively smooth. Internal threads are always cut, producing rougher thread flanks than those of the bolts they are mating with. The reason galling problems are inconsistent is probably due largely to the inconsistencies in the tapping operation. Rougher than normal internal threads may be the result of the use of dull taps or the tapping may have been done at an inappropriately high RPM. 

Fortunately, stainless steel bolt and nut galling problems do not occur everyday, but when they do it usually creates a customer crisis. Knowledge of why this occurs and how to remedy it can save the supplier much grief and many headaches. 

Below are the questions that should be asked and the suggestions that should be made immediately when you are confronted with a customer's complaint about thread galling: 

Questions: 
Suggestions: 

1. Are you using the same driver RPM you have used in the past to install these stainless fasteners? 
If they say they are driving them faster than in the past or if they say this is a new application, suggest they immediately try slowing the driver RPM and see if the problem goes away. In general, a stainless bolt of a given size should be driven slower than a steel bolt of the same size. 

2. Are the bolts and/or internal threads lubricated? 
If they say, "no", suggest they try lubricating the bolts and/or internal threads with one of the lubricants listed above. If this eliminates the galling, you might want to batch lubricate the remainder of the order to eliminate the extra work of applying lubricant at the point of assembly. 

In applications where galling is a repetitive problem, it is advisable to supply the fasteners with pre-applied lubrication to eliminate future problems 

3. Are you using the same grade of stainless steel for the bolts and nuts? 
If the answer is, "yes", you can suggest changing one or the other to a different grade. 

Be sure the suggested grade meets their corrosion needs and changing the material does not cause a procurement problem. 

When thread galling occurs in stainless steel bolt and nut applications, don't panic. Try the suggestions listed above. One, or a combination of these, will probably resolve the problem immediately.

Tuesday, August 14, 2012

Galvanic Corrosion & BUMAX fasterners


One of the biggest questions I get today is about Galvanic corrosion and can BUMAX help.  The answer is yes, but it is not the end all product.  While the inherent properties of BUMAX reduces galvanic corrosion, it doesn’t fully prevent it.  BUMAX brand can be coated to provide maximum protection while retaining all the properties of 316L but with the increased strength.  BUMAX Fasteners for Galvanic Corrosion due exist.  If you would like more information email chris.portell@bufab.com  or look at www.BUMAX.us .  Below is additional information on what is Galvanic Corrosion.

 Galvanic corrosion, also called Bimetallic Corrosion, takes place when two dissimilar metals are electrically connected in an electrically conducting fluid.

The likelihood and severity of galvanic corrosion depends on several factors like:

  1. Corrosion potential of metals in the environment considered
  2. Relative area of the two metals
  3. Type of electrolyte

The corrosion potentials of the stainless steelsare noble than the corrosion potentials of aluminum, as can be seen in the galvanic series of metals in seawater below.

This mean that there will be no galvaniccorrosion on stainless steel when placed in contact with aluminum while aluminum will corrodes.

Permissible couples to avoid galvanic corrosion of aluminium when placed in contact with more noble materials are limited to a potential difference of 0.10 V on the galvanic series.

Anodic current density and hence corrosion rates can be reduced by increasing the anode-to-cathode surface area ratio; if a small area of stainless steel is placed in contact with a big area of aluminum the rate of aluminum galvanic corrosion is low due to the effect of the relative areas.

It is possible to avoid stainless steel aluminium galvanic corrosion isolating the two material by means of an electrical insulating material, like rubber.

In the presence of crevices stainless steels may exhibit less noble potentials due to oxygen depletion within the crevice.

Therefore, coupling a relatively large area with the small-area characteristic of a crevice may result in rapid attack of the material within the crevice leading to stainless steel corrosion.

Under some circumstances, coupling stainless steel to a more active metal can shift the stainless steel corrosion potential from a passive range to an active range. This shift results in an increase in the corrosion rate of the stainless steel due to stainless steel galvanic corrosion.

Stainless steel fasteners in contact with more active metals can become embrittled from the hydrogen
generated by the stainless steel aluminum galvanic corrosion couple.

The table below reports the Corrosion potentials in flowing sea water at ambient temperature.

The unshaded symbols show ranges exhibited by stainless steels in acidic water such as may exist in crevices or in stagnant or low velocity or poorly aerated water where Stainless Steel become active, while the shaded areas show the potentials of Stainless Steel when is in passive state.


This table is taken from: Atlas Steel Technical Note No. 7 "Galvanic Corrosion"

Tuesday, August 7, 2012

What is A2-70 Stainless Steel Fasteners and Material


What Is A2-70 Stainless Steel ?


DIN/ISO A2 Stainless Steel Is Corrosion Resistant Steel; It Is Also Known As ASTM-304.
A2 / ASTM-304 Is An 18/8 Stainless Steel : This Designates A Metallurgical Content Of 18% Chromium & 8% Nickel.
A Bolt Marked A2-70 Is A 304 Stainless Steel Bolt With A 700 N/mm2 Tensile Strength (See Below Table).
The -70 Representing The Tensile Strength Divided By 10.
-50 & -80 Grades Are Also Available But Are Not All That Common.
A2 / 304 Stainless Steel Is What Is Known As An Austenitic Stainless Steel : It Is (Mostly) Non-Magnetic.

Though Some Residual Magnetism Can Be Introduced When The Material Is Cold Worked.
A2 / 304 Stainless Steel Is One Of The Most Highly Corrosion-Resistant Materials Available To The Designer And Engineer.

How Do A2-70's Material Properties Compare To OEM Mild Steel Bolts ?


 
Tensile Strength Denotes The Load At Which The Material Breaks.
0.2% Yield Strength Denotes The Load That Will PERMANENTLY Deform / Stretch The Material By 0.2% Of Its Original Size.
This Is Sometimes Referred To As The Elastic Limit.
As Can Be Seen : A2-70 Stainless Exceeds Ordinary Low Grade Steels For Strength.  Though It Is Weaker Than 8:8 Heat Treated Steels, Which Are Quite Commonplace.

It Does Mean That You Have To Think A Little About Mechanical Loadings Before You Replace An 8:8 Steel Bolt With An A2-70 Stainless Steel Bolt.! If You Are Replacing A 4:6 Or A 5:8 Bolt Then There Are No Concerns.




How Much Of An Issue Is Galvanic Corrosion ?
Galvanic Corrosion Takes Place When Two Dissimilar Metals Are Electrically Coupled In The Presence Of An Electrolyt : The Electrolyt Assisting In The Transfer Of The Charged Atoms / Molecules Necessary For The Corrosion To Take Place.
The More Reactive Of The Two Metals (The Anode) Will Corrode In Preferance To The Less Reactive Metal (The Cathode).

Steel Structures In The Maritime Environment Are Often Protected By Zinc Anodes. The (More Reactive) Zinc Corrodes And Dissolves In The Presence Of The Salt Water (The Electrolyt), Thereby Offering Some Anti-Corrosion Protection To The Steel (Cathode). The Servicable Life Of The Steel Is Thus Extended.
The Rate At Which Galvanic Corrosion Can Proceed Is Governed By Two Key Factors.
  • Availability Of Electrolytic Liquid (Such As Salt Water) To Facilitate Ion Transfer
  • The Relative Exposed Area Of The Two Dissimilar Metals That Are Exposed And Electrically Coupled In The Electrolyt
Stainless Steel Is Less Reactive Than Ordinary Mild Steel Or Cast Irons ; Therefore The Iron/Steel Will Corrode Galvanically (If The Above Conditions Are Met) Protecting The Stainless Steel.

In Terms Of A Cast Iron Or Aluminum Engine Block With Stainless Exhaust Studs The Exposed Area Of The Engine Block Is Massive Compared To The Small Exposed Area Of The Studs. This Minimizes The Galvanic Effects Should An Electrolyt Be Introduced ; This Is Unlikely On A Hot Engine Unless You Wash It With A Water Based Cleansing Agent.

Fuel/Oil Misting & Residues Around Engines Will Offer Protection As It Forms A Dielectric Insulation Barrier To Electron Flow. This Barrier Stops Electrically Charged Ions Flowing And Thereby Stops The Formation Of A Galvanic Corrosion Cell.

Thread Locking Compounds And Lubricants Also Provide A Dielectric Barrier, As Does Plating In Inert Metals (Gold, Chrome Etc) And Painting.

The Stainless Steel Exhaust Aftermarket Thrives Without Any Reported Galvanic Corrosion Issues Despite The Relative Exposed Areas Being Closer Than With A Few Threaded Studs. The Hot And Dry External Environment Of The Exhaust Helps To Drive Water Based Electrolytic Liquids Away.

The DeLorean Motor Company Also Opted To Make A Whole Car Bodyshell Out Of Stainless Steel : Coupling It To An Iron Engine.

Friday, August 3, 2012

So one of the most overlooked asspect of fasteners, Nuts and Washers.  I always have to try to remember what size relates to the size of the bolt.  See below

US NUT SIZE TABLE

SizeDiam.*Height
Hex NutMachine Screw NutHex NutJam NutNylock NutMachine Screw Nut
0-5/32---3/64
1-5/32---3/64
2-3/16--9/641/16
3-3/16--9/641/16
4-1/4--9/643/32
6-5/16--11/647/64
8-11/32--15/641/8
10-3/8--15/641/8
12-7/16--5/165/32
1/47/167/167/325/325/163/16
5/161/29/1617/643/1611/327/32
3/89/165/821/647/3229/641/4
7/1611/16-3/81/429/64-
1/23/4-7/165/1619/32-
9/167/8-31/645/1641/64-
5/815/16-35/643/83/4-
3/41-1/8-41/6427/647/8-
7/81-5/16-3/431/6463/64-
11-1/2-55/6435/641-3/64-
* This is the diameter across the flats. It is also the size of wrench to use.

Wednesday, August 1, 2012

What size wrench to use with your Bolts

This ia always a fun question.  You know the bolt size, but forgot what size socket or wrench you need.  Here is your answer.

Bolt Diameter
(mm)
Head/Wrench Size
(mm)
ANSI/ISODINJISDIN/ISO
Heavy Hex
4777-
5888-
6101010-
7-11--
8131312-
10161714-
1218191722/21*
14212219-
1624242227
18-27--
203030-34/32*
ANSI - American National Standards Institute
ISO - International Organization for Standardisation
DIN - Deutsches Institut fur Normung
JIS - Japanese Industrial Standard
* Indicates ISO standard.

Monday, July 30, 2012

Stainless Steel Fasteners for Timber Construction

Choice of fastener material

Austenitic stainless steels are considered to have Group 4 (excellent resistance)in the ranking of the resistance of common metals to corrosion by acetic acid emitted by wood.
Where CCA preservative treatments have been applied, the timber should be aged for at least seven days before fasteners are inserted. Standard for external timber framed walls recommends austenitic stainless steel as a suitable material for:
  • staples, screws, and nails for fixing sheathing and breather membranes
  • nails, screws for fixing CCA treated wood
  • wall ties and fixings.
Austenitic stainless steel is also a recommended material for external structures of woods such as cedar and permanent structures (painted or oiled).

Timber in immersed structures

Austenitic stainless steel fasteners are suitable for use in immersed timber structures. The choice of stainless steel grade will depend on water conditions such as:
  • chloride level
  • water flow rates
  • temperature
  • oxygen levels
  • crevice conditions in the fastener system geometry.
Stainless steel grade 304 (1.4301) may be suitable for fresh water, but in higher chloride levels 316 (1.4401) is preferable. BUMAX 316L HiMo (1.4436) is considered to be the strongest of 316L classifications and able to withstand corrosion longer.  http://www.BUMAX.se/en  The conditions in tidal river estuaries and seawater where higher chlorides, low flow rates and low oxygen levels can predominate may require higher molybdenum grade stainless steels such as a 6% molybdenum grade (1.4547). Care must also be taken to avoid bimetallic (galvanic) corrosion if combinations of dissimilar metals are to be used.

Timber in swimming pool buildings

Particularly aggressive internal environments can also exist in swimming pool buildings, especially for roof fixings where applied loading can also give rise to stress corrosion cracking (SCC) failure hazards. For these applications SCC resistant grades such as:
1.4436 BUMAX www.BUMAX.se/en/
1.4547
1.4529
1.4565
should be considered.

Wednesday, July 25, 2012

Selecting the best material for your fastner application

Materials

Stainless Steel
Stainless steel is an alloy of low carbon steel and chromium for enhanced corrosion characteristics. Stainless steel is highly corrosion resistant for the price and because the anti-corrosive properties are inherent to the metal, it will not lose this resistance if scratched during installation or use.
It is a common misconception that stainless steel is stronger than regular steel. In fact, due to the low carbon content, stainless steel cannot be hardened. Therefore when compared with regular steel it is slightly stronger than an un-hardened (grade 2) steel fastener but significantly weaker than hardened steel fasteners.
Stainless steel is also much less magnetic than regular steel fasteners though some grades will be slightly magnetic.
18-8 Stainless
18-8 refers to any stainless steel containing approximately 18% chromium and 8% nickel. This is the most common stainless designation for hardware. For information on 18-8 stainless steel material properties see our Material Grade Identification and Properties Chart.
Steel
Steel is the most common fastener material. Steel fasteners are available plain as well as with various surface treatments such as zinc plating, galvanization, and chrome plating.
Steel fasteners are commonly available in 4 grades. Many other grades exist but are used far less often. The most common grades are Grade 2, Grade 5, Grade 8, and Alloy Steel. Grade 2, 5, and 8 are usually plated with a silver or yellow zinc coating or galvanized to resist corrosion.
Determining Bolt Grade
Bolts of different grades are marked on the head to show what grade bolt they are.
Grade 2
Grade 2 is a standard hardware grade steel. This is the most common grade of steel fastener and is the least expensive. Grade 2 bolts have no head marking (sometimes a manufacturer mark is present).
Grade 5
Grade 5 bolts are hardened to increase strength and are the most common bolts found in automotive applications. Grade 5 bolts have 3 evenly spaced radial lines on the head.
Grade 8 
Grade 8 bolts have been hardened more than grade 5 bolts. Thus they are stronger and are used in demanding applications such as automotive suspensions. Grade 8 bolts have 6 evenly spaced radial lines on the head.
Bumax88
Special 316L stainless steel bolt equivlent to a hardered carbon steel bold SAE J429  Grade 5 bolt while retaining or exceeding all characteristics of 316L stainless steel
Bumax109
Special 316L stainless steel bolt equivlent to a hardered carbon steel bold SAE J429  Grade 8 bolt while retaining or exceeding all characteristics of 316L stainless steel
Alloy Steel
Alloy steel bolts are made from a high strength steel alloy and are further heat treated. Alloy steel bolts are typically not plated resulting in a dull black finish. Alloy steel bolts are extremely strong but very brittle.


Silicon Bronze
Silicon bronze, often referred to simply as bronze, is an alloy made mostly of copper and tin with a small amount of silicon. Bronze is used primarily in marine environments. It is preferred over stainless in wooden boat construction and re-fastening due to its superior corrosion resistance, and over brass due to its higher strength. Bronze is similar to copper in color and is also sometimes seen in fine woodworking where it is used for its appearance. The main drawback of bronze is its high cost.
Brass
Brass is an alloy of primarily copper and zinc. Brass is highly corrosion resistant and electrically conductive. However, its use as a fastener is somewhat limited due to its relative softness. It is used primarily for its appearance.
Aluminum
Aluminum is a light, soft, corrosion resistant metal. Like stainless steel, aluminum's corrosion resistance is inherent to the material. Therefore scratches and nicks will not effect the corrosion resistance.
Fasteners are made from a variety of aluminum alloys with elements such as manganese, silicon, iron, magnesium, zinc, copper, and silicon being added to increase strength and melting point.
Rivets are often made from aluminum alloys in the 5000 series which uses magnesium as the primary alloying element.

Coatings

Zinc Plating
Many steel fasteners are electro-plated with zinc for better corrosion resistance. Fasteners that have been zinc plated have a shiny silver or golden appearance referred to as clear or yellow zinc respectively. They are fairly corrosion resistant but will rust if the coating is destroyed or if exposed to a marine environment.
Hot Dip Galvanizing
Galvanizing is another coating involving the application of a layer of zinc. Hot dipped galvanizing puts the thickest possible coating on the metal resulting in superior corrosion resistance. Due to the thickness of the coating hot dipped galvanized bolts are not compatible with other nuts. Galvanized nuts are tapped slightly larger than other nuts to accommodate this coating. 
Hot dipped galvanized fasteners are frequently seen in coastal environments.
Chrome
Chrome is used in plating fasteners for its appearance. It provides similar corrosion resistance to zinc plating. The main drawback of chrome is the extremely high cost. If more corrosion resistance is required stainless steel may be chrome plated, preventing any corrosion should the chrome be penetrated.

Monday, July 23, 2012

Coating of carbon steel ISO: 4042 Standard Platings/ Surface Coatings


STANDARD PLATINGS: SURFACE COATINGS
ISO : 4042 (EN ISO 4042) Electroplated coatings
DIN : 267 Part 9


Electroplated coatings/Rivestimenti elettrolitici/Revêtement électrolytiques/
Revestimientos electrolìticos/Elektrolytische Überzüge

Code system/Sistema di codifica/Systême de codification/sistema de codificaciòn/Kodifizierungssystem

1. Scope and field of application
These technical conditions are in particular related to threaded fasteners (mainly bolts and nuts), but are also applicable
to the whole range of mechanical fasteners.

2. Electroplated coatings
An electrolytically applied coating shall be defined as a protective metallic layer being deposited onto the surface of metal articles by immersing these parts in an aqueous solution through which an electrical current is passed.

Note: The use of the nomenclature “galvanizing” for this treatment is not correct.
This information on electroplated coatings corresponds with DIN 267 Part 9 and ISO 4042.

3. Code system
The electroplated coatings of mechanical fasteners are designated by a code consisting of a combination of two capital letters and a number.
This callout system is built up as follows:
– a capital letter for the coating metal (Table 1)
– a number for the minimum layer thickness (coating structure) (Table 2)
– a capital letter for the degree of gloss and after-treatment (Table 3)




Table 1. Coating metal
     
Table 2. Minimum layer thickness (coating structure)


Code



Layer thickness (coating structure) in µm



letter
Coating metal
Symbol
Code number
1 coating metal
2 coating metals


A
Zinc
Zn
1)


B
Cadmium
Cd
1
3


C
Copper
Cu
2
5
2+ 3


D
Brass
CuZn
3
8
3+ 5


E
Nickel
Ni
4
12
4+ 8


F
Nickel-chrome 1)
NiCr
5
15
5+10


G
Copper-nickel
CuNi
6
20
8+12


H
Copper-nickel-chrome1)
CuNiCr
2)
25
10+15


J
Tin
Sn
2)
32
12+18

K
Copper-tin
CuSn
2)
40
16+24 3)

L
Silver
Ag
1) Code number 0 applies to screw threads below

N
Copper-silver
CuAg

M 1.6, where no specific layer thickness can be specified.

P
Zinc-Nickel 3)
ZnNi

2) Does not apply to threaded components.

Q
Zinc-Cobalt 3)
ZnCo

3) Not in ISO 4042 

R
Zinc-iron 3)
ZnFe



1) Thickness of chrome layer 0,3 µm



3) Not in ISO 4042






Table 3. Degree of gloss and after-treatment



Codeletter
Degree of gloss
Chromating in accordance with DIN 50 941 Process group
Self-color of chromate layer passivation by chromate


A
mt (dull) (mat)
none 1)
none


B
mt (dull) (mat)
B
bluish to bluish iridescent 2)


C
mt (dull) (mat)
C
yellowish glistening to yellowish-brown,iridescent


D
mt (dull) (mat)
D
olive green to olive brown


E
bk (bright)
none 1)
none


F
bk (bright)
B
bluish to bluish iridescent 2)


G
bk (bright)
C
yellowish glistening to yellowish-brown,iridescent


H
bk (bright)
D
olive green to olive brown


J
gl (glossy)
none 1)
none


K
gl (glossy)
B
bluish to bluish iridescent 2)


L
gl (glossy)
C
yellowish glistening to yellowish-brown,iridescent


M
gl (glossy)
D
olive green to olive brown


N
hgl (high gloss)
none


P
bel (optional)
B, C or D 3) at manufacturer's discretion
as for process group B, C or D


R
mt (dull) (mat)
F
brownish black to black


S
bk (bright)
F
brownish black to black


T
gl (glossy)
F
brownish black to black


U
all finishes

no chromate treatment


1) In the case of Zn and Cd

3) Process groups B, C or D in accordance with DIN 50 941 only apply to



however, process group A

cadmium and zinc coatings. In the case of other electroplated coatings, "P"



2) Only applies to Zn coatings

in the code symbol signifies "degree of gloss optional".






Ordering code for electroplated coatings for commercial fasteners











Copper


Coating

Zinc-chromated

Nickel
nickel



Degree of gloss
Glossy
Glossy
Glossy
Glossy
Glossy
Glossy


Nominal size
Nominal size
Color
Color
Color
Color




metric
inch
none
bluish
yellowish
black

< 5 mm
< 3/16 "
A1J
A1K
A1L
A1T
E1J
G2J


5 < 10 mm
3/16" < 3/8 "
A2J
A2K
A2L
A2T
E2J
G2J

> 10 mm
> 3/8 "
A3J
A3K
A3L
A3T
E3J
G3J




Example of coding: A3L means zinc-plating (A in Table 1) with a minimum layer thickness of 8 µm
(3 in Table 2) and yellow-chromated with a glossy degree of gloss (L in Table 3).
Callout Example: Hexagon bolt DIN 931 - M12 x 50 - 8.8 - A3L.

Chromate (passivate) effected immediately after electroplating by short immersing in chromic acid
solutions. The chromating process increases the corrosion protection and prevents a starting and
a discolouring of the zinc layer. The protective effect of the chromate layer is different depending
upon group of procedures (see table).
 



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