Dry Ice Blasting
Overview:
Dry ice blasting is a relatively new cleaning process using solid CO2 pellets (known as dry ice pellets). The pellets sublimate (convert directly from a solid blast pellet to a vapor) leaving no residue.
The process is superior to sand blasting, glass bead blasting and other types of cleaning methods for numerous reasons.
Today, the dry ice method of cleaning is quickly becoming favored for environmental as well production reasons. Because of tremendous environmental regulations, industry has needed to minimize waste. Also there is a growing consciousness that many are placing now on the global environmental impact of their production practices. However, these benefits are accentuated due to the tremendous performance gains through dry ice blasting – little or no production downtime, quality of clean and minimized damaged to equipment.
What is dry ice?
Dry ice pellets are made by taken liquid carbon dioxide (CO2) from a pressurized storage tank and expanding it at ambient pressure to produce snow. The snow is then compressed through a die to make hard pellets.
The process:
With the dry ice blasting process, dry ice (CO2) particles are propelled to supersonic speed impacting and cleaning a surface. The particles are accelerated by compressed air, just as with other blasting methods. Overall, there are three steps involved in dry ice blasting.
Step #1 - Energy transferee:
Dry ice pellets are propelled out of the blasting gun at supersonic speed and impact the surface. The energy transfer knocks off the contaminant without abrasion. The force of the impact is the primary means of cleaning.
Step #2 – Micro-thermal shock:
The cold temperature of the dry ice pellets hitting the contaminant creates a micro-thermal shock (caused by the dry ice temperature of -79C) between the surface contaminant and the substrate. Cracking and delamination of the contaminant occurs furthering the elimination process.
Step #3:
The final phase has the dry ice pellet explode on impact, and as the pellet warms up it converts to a harmless CO2 gas, which expands rapidly underneath the contaminant surface. This forces off the contaminant from behind. The contaminant is the relocated, typically falling to the ground. Since the dry ice evaporates, only the contaminant is left for disposal.
Operating details:
To operate dry ice blasting equipment a few details need to be considered. First, through using dry ice is extremely safe, basic safety matters need to be followed including wearing hand, eye and ear protection. First, the process is noisy and ear protection should be used. Second, the temperature of dry ice is –109 degrees Fahrenheit. Gloves should always be warn when working with it. Thirdly, in dusty areas, a mask is recommended for eye and nose protection. Otherwise, wearing standard eye and ear protection would be acceptable just as with sand blasting or pressure washing. Fourthly, the gun should never be pointed at another individual or serious injury could occur.
Also, blasting in an enclosed area is safe with proper ventilation. Because CO2 is 40% heaver than air, placement of exhaust fans at or near ground level is necessary when blasting in an enclosed area. In an open shop environment, existing ventilation is sufficient to prevent undue CO2 buildup.
Further, though a large number of applications using dry ice blasting equipment only require between 80 to 100 psi and 120 to 150 CFM to operate.
Dry ice blasting compared to traditional methods:
The following two charts give a helpful perspective of how dry ice blasting compares with the traditional cleaning methods – sand, blasting, solvents, and others:
Blast cleaning comparison chart
| Cleaning Technique |
Waste for Disposal |
Abrasive |
Toxic |
Electrically Conductive |
Performance Comparison |
|
Dry Ice
|
No
|
No
|
No
|
No
|
Excellant
|
|
Sand
|
Yes
|
Yes
|
No*
|
No
|
OK
|
| Glass Beads |
Yes |
Yes |
No* |
No |
OK |
| Walnut Shells |
Yes |
Yes |
No* |
Yes |
Limited |
| Steam |
No |
No |
No |
Yes |
Poor |
| Solvents |
Yes |
No |
Yes |
Yes |
Limited |
*Each of these blast cleaning materials becomes contaminated upon contact if used to clean hazardous objects. When that happens, these materials are then classified as toxic waste requiring safe disposal.
Cleaning method comparison
| Issue |
Traditional |
Dry Ice Blasting |
| Equipment |
Cleaned in dedicated cleaning area |
Equipment can be cleaned in place; dry process |
| Downtime |
Disassembly/reassembly; Drying time required |
equipment restart immediately after cleaning |
| Hazardous Waste |
Intensive hand scrubbing; Lengthy cleanings |
dramatically reduced – often completed in a quarter Of time or better |
| Quality/Clean |
Poor to average |
Excellent |
| Potential Equipment Damage |
Grit abrasions; Grit contamination; Movement ofequipment to and from cleaning area |
No equipment damage; Preventive maintenance very realistic as labor hours are significantly less |
| Safety |
Health threats from solvents; Water-based cleaning pose Hazards around electrical equipment; Threats to environment |
Standard safety precautions: Dry process – safe around electrical equipment |
| Cost |
Cleaner becomes additional hazardous waste; expensive
Solvents: Additional labor |
Minimal – cost of dry ice |
Benefits of dry ice blasting technology;
Dry ice blasting benefits can be broken down into six general areas. Following each benefit is discussed:
Benefit #1 – Decreased downtime through cleaning in-place
Typical cleaning procedures require that equipment be disassembled and moved to an assigned area for proper cleaning. That is not the case with dry ice blasting. Equipment can be cleaned in-place and hot in most situations. Because of that, many time-consuming, labor intensive steps, which were required with other methods such as sand blasting, can be eliminated including:
- Cool down
- Disassembly
- Transport of equipment to and from a dedicated cleaning area
- Reassembly
- Reheating time
- Dry ice blasting can shorten the downtime for cleaning from days down to hours.
Benefit #2 – Faster and more thorough cleaning
With dry ice blasting, a superior cleaning can be achieved while reducing hours when compared to scrubbing with abrasive pads or wire brushes. A tremendous labor savings is accomplished. In addition, the dry ice blasting method cleans in crevices that can’t be reached by hand. As a result, equipment runs more efficiently and potential leaks are revealed possibly preventing major system failures.
Benefit #3 – Elimination of equipment damage
Cleaning methods such as sandblasting leave an aggressive and abrasive effect on the surface. They can actually remove part of the surface, changing the surface structure considerably. Dry ice is non-abrasive to surfaces and dose not change a surface’s structure. It lifts the contaminates away. Secondly, because equipment can now be cleaned in place, potential damage from moving equipment to and from a dedicated cleaning area is eliminated.
Benefit #4 – Reduction or elimination of solvents
No solvents are used when using CO2 pellets. This can be a critical need for certain companies in order to comply with environmental regulations or to improve worker safety. There are no issues pertaining to toxicity.
Benefit #5 – Reductions in waste disposal
With other cleaning methods, whether it be with solvents, sand blasting or some other means, the cleaning agent becomes a secondary contaminant and must be disposed of as toxic waste along with the primary contaminant. However, with dry ice blasting because the CO2 pellet vaporizes upon contact, the only waste created is the contaminant itself. This alone can result in significant waste reduction.
Benefit #6 – Increased safety
CO2 blasting pellets are non-toxic, non-hazardous creating advantages to the environment, employees, and production facilities:
- No secondary waste
- Safe for the environment
- Safe for employees
- Safe for end products
- Safe for equipmen
|
