Frequently Asked Questions

  1. What is CO2 blasting?
  2. How does it remove contaminants?
  3. How does this differ from how sandblasting works?
  4. What happens to the dry ice once it strikes the surface?
  5. What happens to the contaminant?
  6. Does the process damage the substrate?
  7. Can CO2 be used to clean hot online?
  8. Does the CO2 cool the substrate?
  9. Will the temperature drop damage the hot mold?
  10. Will the process create condensation?
  11. How is dry ice made?
  12. How are dry ice pellets made?
  13. Are there advantages to the Triventek pelletizer?
  14. How is block dry ice converted to blastable granules?
  15. Does block dry ice have advantages over pellets?
  16. Are there differences in the cleaning effectiveness of dry ice pellets vs. the granules produced by the SDI-5?
  17. How do Triventek pellet blasters compare to the competition's?
  18. Are some dry ice pellets better than others?
  19. Why is pellet uniformity important?
  20. What is the difference between a one-hose system and a two-hose system?
  21. How did the dry ice blasting technology originate?
  22. How much air will I need to clean effectively?
  23. What blasting pressures are possible?
  24. How much dry ice should I expect to use?
  25. Can I vary the dry ice consumption rate?
  26. How do I store my dry ice?
  27. Are the portable blasting units easy to move around?
  28. Will I need an air dryer?
  29. What other equipment will I need?
  30. How much regular maintenance is required?
  31. What are the best cleaning applications for CO2?
  32. How is dry ice blasting used in foundries?
  33. What are some successful rubber molding applications?
  34. How is CO2 used in the food industry?
  35. What are some examples of applications where CO2 does not work well?
  36. Can CO2 be used to remove paint?
  37. Will CO2 remove greases, oils, or weld slag?
  38. Can CO2 be used to remove rust?
  39. Will CO2 clean glass?
  40. Can CO2 be used to clean wood? For mold remediation, for example?
  41. Does CO2 replace sandblasting / bead blasting / water blasting, etc.?
  42. What are the primary safety issues relating to the use of dry ice blasting systems?
  43. Is the system noisy?
  44. Do the contaminants or dry ice particles ricochet?
  45. Does the process generate static electricity?
  46. What should I do if my blast hose is cracked?
  47. Is it okay to blast in an enclosed area?

1. What is CO2 blasting?

It is a process in which dry ice particles are propelled at high velocities to impact and clean a surface. The particles are accelerated by compressed air, just as with other blasting systems. Today, most applications are able to use standard shop air, in the 30 - 100 psi range.

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2. How does it remove contaminants?

It depends on what you're cleaning. If you're removing a brittle contaminant such as paint, the process creates a compression tension wave between the coating and the substrate. This wave has enough energy to overcome the bonding strength and literally pop the coating off from the inside out. If you're removing a malleable or viscous coating such as oil, grease, or wax, the cleaning action is a flushing process similar to high pressure water. When the particles hit, they compress and mushroom out, creating a high velocity snow flow that actually flushes the surface.

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3. How does this differ from how sandblasting works?

Sandblasting is similar to using an ice pick whereas dry ice blasting is similar to using a spatula. Sand cuts or chisels away the contaminant. Dry ice lifts it away.

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4. What happens to the dry ice once it strikes the surface?

It sublimates and returns to the atmosphere as carbon dioxide (CO2) gas. CO2 is a naturally occurring element that constitutes less than 1% of our atmosphere.

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5. What happens to the contaminant?

People sometimes think it disappears too, but it does not. All cleaning involves the relocation of dirt. When you mop a floor, the dirt moves from the floor to the mop to the water in the bucket. With dry ice, the dirt moves from an undesirable area to an area where you can better deal with it. If it is a dry substance, it generally falls to the floor where it is swept away or vacuumed during normal maintenance. If it is a wet substance like grease, you take a methodical approach similar to hosing down a driveway. You start at one end and guide the grease to the other end where it is vacuumed or squeegeed up.

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6. Does the process damage the substrate?

Generally no, but it depends on the substrate. There is an energy threshold at which disbonding will occur and a threshold at which damage will occur. When the disbonding threshold is lower than the damage threshold, you can clean. If the reverse is true, damage can occur. Most of our applications deal with production equipment (cast iron, tool steel, tool grade aluminum), so there is no damage. We do have success with softer substrates such as plastics, wiring, pure copper, and fabrics, but these must be examined on a case-by-case basis.

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7. Can CO2 be used to clean hot online?

The process cleans best hot. Most contaminants have weaker adhesive strength when hot. In many applications, you may be able to clean three to five times faster hot than cold. In addition, because dry ice sublimates on impact, entrapment of the blasting media is not an issue. Grit entrapment is an important reason those who clean with sand, walnut shells, or other grit media cannot clean online.

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8. Does the CO2 cool the substrate?

Yes, but generally not as much as you might think. The amount of cooling is dependent upon three main factors: mass of the targeted surface, dwell time, and ice usage rate. Typically, a tire mold may start at 350°F and drop to 325°F during cleaning. With a very thin mold, the drop can be much greater. Generally, however, cooling is not a concern and only rarely does it affect cleaning performance.

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9. Will the temperature drop damage the hot mold?

It depends on the mass of the mold. Large, heavy molds will not be harmed in any way because the drop in temperature is insignificant when compared to the mass of the mold. With thin molds where tolerances are critical, some testing may be required to determine if the drop in temperature would alter the structure of the mold.

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10. Will the process create condensation?

Once again, it depends on the mass of the object you're blasting, your dry ice usage rate, and your dwell time. There will be condensation if you cool the substrate below the dewpoint (the dewpoint varies depending on local climate). Of course, if you're cleaning a hot mold it is rare to have condensation because you seldom cool the mold below the dewpoint. Condensation is not a factor 80% of the time. When it is, it can be dealt with quite easily. Use of a hot air knife can be highly effective.

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11. How is dry ice made?

It is made from liquid carbon dioxide. Dry ice exists as a liquid only under high pressure. When it drops to ambient pressure (the normal pressure that surrounds us), approximately half turns to gas and half turns to solid. The solid, usually in the form of fluffy snow, is then compressed to form dry ice blocks, pellets, or nuggets.

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12. How are dry ice pellets made?

Pellets are made by taking liquid CO2 from a pressurized storage tank and dropping it to ambient pressure to produce snow. The snow is then pushed through a die to make pellets. The Triventek system is a mechanical extruder process in which the pellet extrudes through 3 easily interchangeable die plates.

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13. Are there advantages to the Triventek pelletizer?

There certainly are. First, our system produces pellets that are uniform in size and in density. Uniformity is important because pellet size and density directly impact cleaning performance. With Triventek pellets you will achieve a very consistent, high level of performance. Second, unlike other systems, no metering of the pellets is required. You use the pellets as you make them. If you want more pellets, you make more. If you want less, you make less. If you don't want any, the pelletizer stops making them. The Triventek pelletizer is designed with the individual user in mind, most companies produce large pelletizers for dry ice manufacturers. Triventek has targeted the companies who only need pellets for their own use.

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14. How is block dry ice converted to blastable granules?

When you pull the trigger on the SDI-5, an actuator engages the ice, pushing it into the cutting face (the granulator) which produces particles that look much like raw sugar crystals, about 10 mils in size. Because the granulator only operates when the trigger is engaged. The SDI-5 is a patented system, the only blasting unit on the market capable of starting with block dry ice to create a blastable medium.

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15. Does block dry ice have advantages over pellets?

Yes. It is easier to transport. Block dry ice has a longer shelf life. Pellets have a higher surface-to-mass ratio which makes them more hydroscopic, meaning they attract water. When stored, this causes them to sublimate (turn into a gas) faster than block. Block machines are larger and more complex and consequently are much more expensive to purchase and operate.

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16. Are there differences in the cleaning effectiveness of dry ice pellets vs. the granules produced by the SDI-5?

In about 75% of the applications, users do not choose dry ice media based on its cleaning effectiveness because there is little or no difference. In the remaining cases, pellets work better in some of the applications, granules in others. Generally speaking, pellets are more effective with thick hard to remove contaminants as the greater mass behind each individual particle more readily travels all the way through the contaminant to disbond it. Because the granules are smaller than the pellets, they produce a significantly greater number of surface impacts and are therefore better at removing paint. In addition, they are better for cleaning intricate patterns or tiny openings such as microvents in coreboxes. Triventek has designed a very simple accessory that allows the pellets to be quickly and easily fractured thereby simulating the cleaning effect of shaved ice.

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17. How do Triventek pellet blasters compare to the competition's?

Triventek engineers are responsible for introducing to the marketplace a truly economical, yet versatile pellet blaster. the Triblast-2 offers aggressive cleaning capabilities, but work equally well at low pressures where the majority of applications exist and they do so while using less ice. They are the easy to use, reliable, and the lowest maintenance units on the market.

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18. Are some dry ice pellets better than others?

Dry ice pellets vary in uniformity of size and hardness. Triventek can deliver consistent, uniform pellets. This is due to having the pellet machine in house ready to use when you need them. Often the logistics of getting pellets can be a daunting task and when you finally receive them they lack the consistency of fresh pellets.

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19. Why is pellet uniformity important?

It is critical in ensuring repeatability of performance. There are many applications where pellets of a certain size and density deliver optimal performance. Once you determine the size and density that best suits a given application, the Triventek pelletizer system will consistently deliver pellets to those precise specifications.

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20. What is the difference between a one-hose system and a two-hose system?

In a two-hose system, the dry ice travels in one hose and the high pressure air in another. The two are not mixed until just before the pellets exit the end of the nozzle. The primary advantage of a two-hose system is simplicity. In a one-hose system the pellets and air are mixed together in one hose at an air lock and travel the complete length of the hose. Although generally a one-hose system uses more ice, in the Triblast-2 Triventek one-hose system, ice consumption can be adjusted to permit very low ice consumption. In areas where there is a substantial thickness of contaminant the single hose system can permit added blasting aggression and faster cleaning. With the Tirblast-2 system customers receive the advantages of simple design, ease of maintenance and adjustability, all in one unit.

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21. How did the dry ice blasting technology originate?

Dry ice blast cleaning originated at Lockheed in the 70's when a coatings engineer, Calvin Fong, was researching ways to strip paint off aircraft. The technology did not become commercially available until Alpheus bought the license and patents from Lockheed and introduced it to the marketplace in 1987.

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22. How much air will I need to clean effectively?

It is typical to operate at about 90 psi with 130 cfm, however your needs will depend on your application. Triventek designs nozzles that clean effectively while using as little air as possible. Triventek makes it easy and inexpensive to move from one nozzle to another.

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23. What blasting pressures are possible?

Most of our standard gun configurations are rated up to 125 psi which is well above the 90-100 psi used in the vast majority of applications.

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24. How much dry ice should I expect to use?

This is an important question to ask because the amount of dry ice you need to clean effectively can vary dramatically within the industry. With Triventek equipment, most customers use 1½-2 pounds per minute while the trigger is engaged. Of course, when you are cleaning, you won't be pulling the trigger constantly. At a rate of 2 pounds per minute with 50% trigger time, you would use 60 pounds of dry ice in an hour.

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25. Can I vary the dry ice consumption rate?

Yes, you can easily vary the rate at the control panel on the Triblast-2 blasters.

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26. How do I store my dry ice?

Since dry ice is -109°F, putting it in a freezer doesn't really help. The best way to extend your shelf life is to store the ice in an insulated bin. Depending on the quality of the bin and how much ice you are storing, your loss due to sublimation should range from 2% to 10% per day. For your convenience, the Dry Ice Tote is available through Wickens Industrial. It holds up to 570 pounds of pellets. It features a hinged lid and includes casters to make it easy to move around the shop floor. The tote was specially designed to withstand the extreme temperatures, payload, and rugged use associated with the dry ice industry.

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27. Are the portable blasting units easy to move around?

One person can easily roll all the Triventek portable blaster around the shop floor without any special equipment. The Triblast-2 is small enough to carry up stairs for complete blasting freedom.

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28. Will I need an air dryer?

Cold Jet equipment is designed to operate with clean, dry air which most plants are able to provide, so an additional air dryer is generally required only when using the equipment with portable diesel compressors. The Wickens Industrial Chiller/Dryer was developed to meet this need. You should, however, always blow down your in plant air lines before hooking them up to your dry ice blasting unit. This will eliminate water and sediment that may be present and prevent these impurities from entering the equipment.

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29. What other equipment will I need?

If you plan to make your own pellets, you will need a source of liquid CO2 and the means to store it. Otherwise, you will need a source of dry ice. You will need a Dry Ice Tote or similar storage device to store your dry ice supply. You need an air source. Standard shop air is sufficient for most applications. For the electric Triblast-2, you also need a source of electricity.

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30. How much regular maintenance is required?

Very little. Triventek blast units are designed to provide years of trouble free use with a minimum of maintenance. You must periodically examine the airlock for wear and hoses for cracks and abrasions. That is it. The TriventekPE-45 is a more complex design, yet still requires minimal maintenance. Items such as roller bearings, carrier bearings, and the airlock require infrequent, periodic attention, and all hoses should be examined periodically for cracks and abrasions. A maintenance schedule is included in the operations manual for each unit. With routine maintenance, you can expect many years of reliable use.

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31. What are the best cleaning applications for CO2?

The range of cleaning applications for dry ice is phenomenal and is easily demonstrated in just a small sampling of our customer base: core boxes for Ford; delicate wiring in copy machines for Xerox; conveyors for Nabisco; tire molds for Michelin; dry ice blasting shines in cleaning production equipment online, because it eliminates the need for masking, cool down and disassembly. Users minimize downtime which maximizes production efficiency. We have achieved outstanding results cleaning production equipment for foundries, molded rubber producers, food processors, printers, and the semiconductor industry. Dry ice blasting is also widely used in the nuclear industry for decontamination. Anytime waste volume or health risks are a concern, the viability of CO2 should be examined. Because CO2 disappears on impact, it creates no additional waste. Competing processes such as grit blasting or solvents often present disposal problems or health hazards.

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32. How is dry ice blasting used in foundries?

Dry ice blasting equipment is used in foundries worldwide to clean core boxes and permanent molds. Not only does dry ice blasting increase production by decreasing downtime, but it also eliminates mold damage, preserving the critical tolerances and greatly extending the life of the expensive tooling. Dry ice foundry clients include major auto-makers like Chrysler, Ford, GM, Nissan, BMW, Mercedes, and Renault. Yet, you don't have to be an industrial giant to enjoy the cost benefits of CO2. A large number of small to medium-sized foundries in the U.S. and Canada who successfully use Cold Jet equipment to clean online.

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33. What are some successful rubber molding applications?

Virtually every major tire manufacturer uses dry ice blasting equipment to clean tire molds, including B.F. Goodrich, Bridgestone, Dunlop, Firestone, Goodyear, Kelly, Michelin, and Uniroyal. We also clean rubber molds for manufacturers of gaskets, o-rings, shoes, and many other products. A good rule of thumb in the rubber industry is, if you can see it, you can clean it with CO2.

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34. How is CO2 used in the food industry?

CO2 is perfectly suitable for use in this industry because it is food grade quality, the ingredient that provides the carbonation in soft drinks. It is used to clean ovens, conveyor belts, molds, dry mixers, laminators, and packaging equipment. Nabisco, Hunt-Wesson, Uncle-Ben's, Pillsbury, Frito-Lay, and General Mills, are among the food industry leaders who clean using dry ice blasting systems.

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35. What are some examples of applications where CO2 does not work well?

Dry ice Blasting Will not etch or profile most surfaces. If you need to clean large quantities of small parts, CO2 is not generally as efficient as other alternatives such as ultrasonics. Because dry ice blasting is primarily a line-of-sight cleaning process, if you can't see what you need to clean, you probably can't clean it with dry ice.

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36. Can CO2 be used to remove paint?

Yes, however, the removal rate is dependent on a great many factors including: the underlying surface profile of the substrate; the thickness of the coating; the adhesive bond strength of the coating; and the cohesive strength of the coating (generally a function of age). Paint removal rates can vary dramatically, from 300 square feet/hour down to 1 square foot/hour. Generally speaking, if you have concerns with contamination, toxic substances, waste disposal, or substrate damage, dry ice blasting should be considered as a cleaning option. Otherwise, grit blasting is probably a more efficient method for paint removal.

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37. Will CO2 remove greases, oils, or weld slag?

A methodical approach similar to hosing down a driveway is required if dry ice is to be effective on these and other wet contaminants. You must start at one end and work the grease to the other end where it can pass through a grate or be vacuumed or squeegeed for disposal. Some customers use a paper or plastic backdrop to catch the wet contaminant as it is removed from the substrate. dry ice doesn't dissolve the oil and doesn't make it disappear so you must have an acceptable way of handling it when it is relocated by the blasting process.

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38. Can CO2 be used to remove rust?

It tends to remove the loosely adhered oxidation and salts, but will not remove the deeply adhered oxidation. You will not get a white metal finish. To do that you have to remove the surface metal, something the dry ice blasting process cannot do. Of course in many applications, this is a major advantage because it preserves the surface integrity of the substrate.

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39. Will CO2 clean glass?

It can, but some prior testing is required to avoid shattering the glass. Wickens Industrial produces a CO2 WIL 100 Snow Horn that customers use to clean glass monitors before applying a non-glare coating. We have others who use it to clean optics for cameras, fiber optics and other high quality glass components. To clean glass with solid dry ice, it is important to remember that a certain impact energy is required to disbond the contaminant. If that energy level is high enough to also shatter the glass, you cannot clean using this process.

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40. Can CO2 be used to clean wood?

Yes indeed. One of the exciting areas of dry ice use today is in mold remediation and fire restoration. Dry ice blasting will slightly raise the grain on the wood, leaving a finish similar to that of very light sandblasting. If you need a smooth wood finish, dry ice blasting will have to be followed by sanding or some other smoothing method. Because dry ice disappears as it strikes the surface, the only waste that must be disposed of is the removed contaminant and some wood fiber particles.

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41. Does CO2 replace sandblasting / bead blasting / water blasting, etc.?

They are all tools in the toolbox. Consider that there are many types of hammers: ball peen; tack; claw; sledge; and so on. Could each do the job of the other? Perhaps, but the ideal toolbox would include each, because each has specific capabilities that it does better than any of the others. Triventek equipment should be in your toolbox if you are concerned with downtime, entrapment, waste volume, or equipment damage.

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42. What are the primary safety issues relating to the use of dry ice blasting systems?

One safety issue, as in any factory setting, is protecting workers from moving parts. Triventek equipment is designed so that there is no access to moving parts. Another issue is the temperature of the dry ice. At -109°F, we recommend you never handle it directly without gloves. Proper PPE for the contaminant involved is required and just as in sand blasting or steam cleaning, the gun should never be pointed at anyone or serious injury could occur. The issue that comes up most often is noise.

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43. Is the system noisy?

Yes. Noise is a function of air volume and air velocity. Within the nozzle, the stationary air is sheared by the high velocity air causing turbulence which creates noise. The level can range from 80 - 130 db. Hearing protection is required. Triventek Triblast-2 equipment can be so finely tuned in air volume that many times the noise is much less than in comparable systems.

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44. Do the contaminants or dry ice particles ricochet?

As long as it strikes the surface head on, dry ice does not ricochet because it sublimates (turns into a gas) on impact. As for the contaminant, you usually do not see or feel it as it disbonds and leaves the substrate, however, it is removed with some force which is why eye protection is recommended at all times.

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45. Does the process generate static electricity?

Yes. Any dry air process will generate static electricity and dry ice blasting is no exception. As long as both the blasting unit and the piece you are blasting is properly grounded, you are unlikely to have static discharge problems.

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46. What should I do if my blast hose is cracked?

Replace it. The hoses carry high pressure air and could lead to problems if cracked or abraded.

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47. Is it okay to blast in an enclosed area?

Yes, with proper ventilation. Because CO2 is 40% heavier than air, placement of exhaust vents at or near ground level is recommended when blasting in an enclosed area. In an open shop environment, existing ventilation is sufficient to prevent undue CO2 buildup.

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