PREPARATION TIPS

Conventional electrostatic powder application leads to large quantities of negative charges being transferred to the object. If this large surplus of electrons cannot be efficiently earthed, the coated surface rapidly develops a powerful negative charge thus repelling the negatively charged powder from the spray gun. Consequently, without sufficient earthing it becomes impossible to build up a thick layer of powder with good flow and finish, rapidly and efficiently.

Powder application by friction charging results in powder leaving the spray gun positively charged; that is it will have a deficiency of electrons. To build up the powder layer on an object, it is therefore necessary to partially neutralize the powder by drawing electrons from earth. Should this not occur quickly enough, the coated surface would develop a strong positive charge that subsequently repels positively charged powder on leaving the gun. The resultant effect being the same as for high voltage equipment; an insufficient powder coating thickness.

Inadequate earthing can easily be recognized by little or no powder accumulation around the hanging point of the object being coated.

To ensure plant safely, it is absolutely essential to fully and effectively earth spray equipment, spray booths, and related equipment. This ultimately maximizes the avoidance of high voltage discharge and the possibility of resultant electrical sparks.

With friction charging equipment, good earthing of the spray gun is decisive for successful application. As the powder becomes positively charged, the electrons that are stripped away must be earthed. Without effectively earthing the spray gun, negative charges will accumulate and powder will then be allowed to pass through the gun without being charged.

Relative humidity within the working environment is of great significance for spraying efficiency. Ideal relative humidity being 45-55%. A quicker build-up of the powder layer and more even coating thickness are two of the advantages achieved by controlled humidity. Relative humidity can be measured with simple and inexpensive equipment.

Only clean, dry compressed air should be supplied to powder coating equipment. The quality of the compressed air can change the electrostatic charging and transporting properties of the powder. Impure compressed air may also cause visual defects in the coating.

Pressurized air must be free from oil, water and as dry as possible. Chillers are often used in addition to mechanical water/oil separators for removing moisture from compressed air. Air leaving the cooler/dryer at a temperature of 3°C or lower is an indication that it is dry and well suited for powder coating.

All powder coating processes necessitate the powder, suspended in its air flow, being as close as possible to the object. The force of electrostatic attraction between powder particles and the object decreases by the square of the distance between them (D2), and only when that distance is just a few centimeters will the powder be drawn towards the object. Careful positioning of the spray gun also assures that small and large particles are deposited on the object in the same proportions found in the virgin powder.

In order to increase spraying efficiency it remains advantageous to suspend objects as close together as possible along the conveyor line. This reduces the amount of powder that is recycled thus preventing an excess of finer particles returning to the powder reservoir. To achieve the same coating thickness on all objects, however, spacing must be adapted according to the size of the objects, as the following diagrams illustrate:

a. When the distance is too small, objects are not evenly coated:

b. By increasing the distance, the coating thickness is even on all objects:

c. A small object will produce a higher concentration of fields and subsequently receive a thicker coating than a larger object adjacent to it. It is advantageous to hang objects of equal size next to each other along the conveyor. Hanging objects correctly on the conveyor is of greater importance to successful conventional electrostatic spraying than it is to friction charged powder spraying.

A major advantage of powder coatings over liquid paint systems is the ability to reuse powder that does not adhere to an object (overspray). Air and powder are separated by either a cyclone or a filter system, as illustrated.

Powder that is recycled will be recollected in the powder hopper. Particles which are more easily charged adhere themselves to the object whilst the proportion being recycled are of another particle distribution size than that of virgin powder. The relationship between small and large powder particle size has significant meaning regarding spraying properties and consequently the end result.

 

Recycled powder will always have properties that differ from virgin powder. In order to maintain a constant composition it is always an advantage to keep the volume of reused powder to a minimum and continuously return any recycled powder to the powder hopper.

 

 

 

“Solvent degreasing” is very often employed as the sole pre-treatment prior to powder coating. To illustrate what can happen when such a system is exposed to a corrosive environment, salt spray chamber tests are suitable. In comparison, a system recommended for pre-treatment of higher corrosion classes can be used.

A series of factors will consequently affect the choice of pre-treatment method, some of which will be specific to the individual user.

The following factors should be identified:

1. Metal type and quality
2. Surface condition, i.e. degree of contamination and what contami nants to be removed
3. The finished products and areas of application and its protective quality requirements
4. Economic and environmental considerations (most often a question of various alternatives to similar or equivalent pre-treatment systems)

Whether you consider using cleaning/degreasing as the only pre-treatment or as an integral part of a more comprehensive treatment, the method employed should be based on the types of contamination to be removed, as well as the type of substrate (base) in question.

Solvents remove only “greasy” contaminants such as oil, fats, lubricants etc. The most common being tri and perchloroehtylene. Subsequent rinsing is not necessary after degreasing with solvent.

Degreasing with acidic, neutral or alkaline chemicals can also be employed. Such agents may also remove corrosion, mill scale and other oxides.

Mechanical methods are used both to remove stubborn contaminants such as welding flash, mill scale etc., and to provide better adhesion for the subsequent surface coating.

If blast cleaning is used (the abrasive agent to be chosen be determined by the base in question and the desired roughness), it is important to remember that grwasy contaminants should be removed in advance.

Treatment with iron phosphate (often called thin layer phosphating) provides very good adhesion properties and has no adverse effects in the mechanical properties of the powder coating. Iron phosphate provides good corrosion protection for exposure in the low and middle corrosion classes, though it cannot compete with zinc phosphate in this respect. Iron phosphate can be used in either spray or dip facilities. The number of steps in the process may vary from 2-7, depending on the basemetal and the requirement for protection. In relation to zinc phosphate treatment, the iron phosphate process is generally cheaper and simpler to accomplish The phosphate layer normally weighs between 0.3-1.0g/m2.

The zinc phosphate process deposits a thicker layer than iron phosphating, and is securely anchored to the base material. Zinc phosphate also has very favourable adhesion properties, though in some cases it may reduce the mechanical integrity (flexibility of the system. Zinc phosphate provides excellent corrosion protection and is recommended for pre-treatment of steel and galvanized steel for exposure in high corrosion classes. Zinc phosphate can be used in either spray or dip facilities. The number of steps in the process varies between 4-8.

Zinc phosphating is normally more expensive than iron phosphating, due to both higher plant costs and more expensive operation.

A series of different systems are available within the chromate group of treatments. The system selected depends on the type of metal or alloy, the type of object (method of manufacture: casr, extruded etc.) and of course, quality requirements.

Chromate treatment may be sub-divided into:

1. Thin layer chromate treatment
2. Green chromate treatment
3. Yellow chromate trearment

The latter is the most common method for pre-treatment prior to powder coating. The number of steps in the process may vary, depending on how extensively the goods have to be prepared for chromating, for example by pickling, neutralization etc. and consequent rinsing steps.

a. Aluminum pressings, sheetings and extrusions for exterior application

b. The aluminum or aluminum alloy materials must be suitable for the coating processes specified in this document It must be free from corrosion and must not have any anodic or organic coating. The radii of the angles must be as large as possible

a. Equipment necessary for testing the pre-treatment chemicals, rinsing water and final results

1. Tests of pre-treatment chemicals to be performed according to suppliers’ instructions

2. Conductivity measurement gauge for evaluation of final rinse

3. Temperature recorder

4. Coating weight equipment, DIN 50939 or equal

b. Equipment necessary for testing the powder coating

1. Film thickness gauge suitable for use on aluminum (e.g. ISO 2360, DIN 50984)
2. Cross hatch equipment, DIN-EN ISO 2409 – 2mm
3. Bending test equipment, DIN-EN ISO 1519
4. Indentation test equipment, DIN-EN ISO 2815
5. Impact test equipment, ASTM D 2794 (5/8” ball) or ECCA T5 (1985)
6. Erichsen Cupping test equipment, DIN-EN ISO 1520
7. Gloss measurement equipment, DIN 67530, ISO 2813 (using a 60 head)
8. Equipment for boiling water test
9. Temperature recorder
10. Equipment for test of curing (MEK-test)

a. Handling

1. Handling of details should be done carefully and contamination (dust, oil, at, finger marks, etc.)

2. Care should be taken to secure proper treatment of the total area

b. Pre-treatment

1. As a minimum, the following pre-treatment should be performed:

• – Degreasing / etching – alkaline
• – Rinsing
• – Acid Wash
• – Rinsing
• – Chromating
• – Rinsing, demineralized water. (The last running water from the object should be tested at 20°C. The readings should measure below 30 micro Siemens/cm)
• – Drying, max, object temperatures: 100°C

2. Coating thickness of the chromate conversion layer between 0.4 – 1.0 g/m2

c. Powder application and curing

1. The pre-treated parts are to be transferred to the coating process immediately in a clean and dry state and before the integrity of the pre-treatment process has deteriorated
2.  Application shall be done in one operation to a minimum thickness of 60 microns for exposed areas. On details which are to be treated mechanically (e.g. sawing, milling, drilling) after coating, the coating film thickness must not exceed 120 microns (100 microns for Corro-Coat PE-SDF)
3. The Powder coating shall be cured as specified by Corro-Coat Powder Coatings for the product used. The metal temperature must be recorded on the area with greatest metal thickness and with the oven fully loaded.
4. At no single point in the curing zone must air temperature deviate from adjusted Nominal by more than ± 10°C

d. Handling after curing

1. Coated items should be cooled to less than 40°C before handling.
2. Precaution should be taken to avoid damages on the finished coating during stacking, packing, storing and transportation

a. Operation and raw materials

1. Prior to start of a running production and by start-up after stops, necessary test panels shall be pre-treated, coated and cured, to control equipment and materials. Tests as under 5.a. The temperature shall also be recorded.

2. The same procedure (4.a.1) shall be performed for each separate color

3. Testing of pre-treatment chemicals and rinsing stages shall be done according to written instructions from supplier

4. The final rinsing stage must be constantly monitored and adjusted regarding conductivity

5. Testing of the last running water from the object (3.b.1) shall be done at least once per shift, color or job (if less than one shift is required). The conductivity of the rinsing bath must be adjusted accordingly

6. Testing of the drying oven at least once per shift, color or job (if less than one shift is required according to 3.b.1)

7. Testing of the chromate conversion layer (3.b.2 at least once per shift, color or job if less than one shift is required) according to procedures given in DIN 50939 or equal

b. Production Control

1. When the oven is fully loaded, the temperature shall be recorded. Temperature to be measured in air and on greatest metal thickness. The temperature shall also be recorded prior to shutting production in fully loaded oven

2. At least once per shift, color or job (if less than one shift is required), necessary panels shall be coated for testing purposes. Panels to be coated and cured under current working conditions

c. Coated Materials

1. At least once per shift, color or job (if less than one shift is required),  tests shall be performed according to 5.b

2. On parts with variable thickness and shape, test shall be performed according to 5.b on a representative selection

a. Test on Panels (Panel thickness 0.8 mm. Film thickness 60 microns)

1. Measuring of gloss DIN 67530, ISO 2813 (using a 60°C head Specification: as specified for the product)
2. Adhesion, cross hatch/tape test, DIN-EN ISO 2409 – 2mm. Specification: Gt.0
3. Falling weight impact. Specification: as specified for the product
4. Erichsen Cupping Test. Specification: as specified for the product
5. Bend test. Specification: as specified for the product
6. Indentation test, DIN-EN ISO 2815. Specification: Min. 80
7. Color shall be controlled visually according to specification
8. Pre-treatment shall be controlled in distilled boiling water test for 2 hours. Specification: no blistering or loss of adhesion (according to 5.a.2)
9. Cure test by MEK resistance. 30 double rubs according to Corro-Coat Powder Coatings procedures

b. Finished Material

1. The surface coating shall be continuous, free from damage, even in color and gloss visually controlled

2. Decorative appearance shall be visually evaluated on a distance of 5 meter (15 feet) for material for exterior use, and 3 meter (9 feet) for interior use

3. Fill thickness. Specifications: as 3.c.2

4. Adhesion, cross hatch/tape. To be tested according to 5.a.2. Specification: Gt.0

5. Indentation test according to 5.a.6. Specification: as specified for the product

6. Cure test by MEK resistance. Specification as 5.a.9

1. Full powder products identification, processing data and test panels, to be kept for the duration of the warranty period

a.When a failure is detected, the coating process shall stop and necessary steps be taken

b.The powder coating must be handled and stored under dry conditions at a temperature not exceeding 25°C Storage stability to be controlled after 6 months from the date of receipt

c. Special care must be taken when loading and unloading the coated components and reasonable care exercised during handling and transport on site. Each coated component should be packed separately and separated from the other components by tissue paper, plastic sheeting, or foam padding to prevent damage during transport. Regular adhesive tapes must not be allowed to come into direct contact with the polyester coating. Should protective tape must be required, then only tape designed for the protection of coated aluminum shall be used. The responsibility of compliance is our clients’ as well as ensuring that no residue of any nature is left on the finished product