Cleanroom Ultrapure Fogger, Nitrogen Fog Generator, AP32
The AP32, cleanroom ultrapure fogger provides the highest volume of fog to visualize airflow for long periods up to 90 minutes providing airflow visualization of 20-30 feet distance. No cleanup is required after fogging! - Request a Quote
UltraPure fogger - The AP32 nitrogen fog generator is used in clean rooms, ISO suites, sterile rooms to provide visualization of airflow, flow patterns, dead spaces and turbulence. Nitrogen fog generators support Pharmaceutical guidelines, USP 797 In-Situ Airflow Analysis; and ISO guidelines, ISO 14644-3 Annex B7 guidelines.
The ultrapure fogger uses liquid nitrogen (LNG) and DI Water (DEMI Water) or Water for Injection (WFI) to generate an amazing 46 cfm of ultrapure fog for 90 minutes with 20-30 feet of visible airflow distance. Water for Injection is often used in ISO suites, sterile rooms and clean rooms. Liquid nitrogen is filled into an LNG dewar, while DI Water is filled into a Stainless Steel chamber. Both liquids are then brought to a boil, creating nitrogen vapor and water vapor. The boiling process creates an ultra pure nitrogen and water vapor. The two vapors then mix together to form a nominal 3 micron vapor droplet at an extremely high fog density. The ultrapure fog exits at very low pressure, making it buoyant in the airflow. It is highly visible and does not create a disturbance as it enters the airflow. Ultraure foggers provide the greatest visible distance of 20-30 feet or more to visualize airflow turbulence and patterns. The high fog density is superb to visualize airflow, and when using video, the dense fog is easily tracked in the airflow in a sterile room, clean room and ISO suite. The nitrogen fog generator does not generate any contaminants in the airflow and evaporates back to the same elements we breathe, that being oxygen, nitrogen and hydrogen. Although DI water is quite clean, the stainless steel chamber is grounded which helps to add additional purity to the 16 Meg Ohm DI water during the boiling process. The very high density of ultrapure fog provides superb visualization of airflow, patterns and turbulence. It also has the advantage of providing increased visual distance of the moving airflow. Ultrapure cleanroom foggers create the most pure form of fog that can be used in clean rooms, ISO suites and sterile rooms.
A nitrogen fog generator creates a particle free, non-contaminating fog, leaving no contamination or residue behind, thus no cleanup after fog use is required. The nitrogen based, ultrapure fog enters the airflow at very low pressure and does not create airflow turbulence. It is CE Mark and compliant to ISO and USP guidelines, and can be used in Class 1 - 100,000 clean rooms for airflow, turbulence visualization, flow balancing and contaminant transport studies.
AP32 Nitrogen Fog Generator Features - Request a Quote
- Continuous airflow visualization
- Containment transport airflow studies
- Visualization of unwanted gas emission locations
- Tracking routes of unwanted air flow infiltration into cleanrooms
- Providing 46 cfm of ultrapure fog for 90 minutes for mapping studies
- No contamination created, no contamination left behind
- No cleanup after fog visualization
- Neutrally buoyant fog does not create turbulence as fog enters airflow
- Neutrally buoyant fog and does not create turbulence as fog enters airflow
- Compact, transportable, rolling carry Case with stream output and fog rake output
- For use in sterile rooms, ISO suites and clean rooms
- High density fog visualization of airflow and turbulence
- Exhaust and ventilation studies around wafer handling systems
- Air balance studies in Pharmaceutical suites and clean rooms
Nitrogen Fog Generator, AP32 Technical Advantages - Request a Quote
- Very dense fog to improve airflow visualization using an ultra pure fog
- No contamination is created, no cleanup is required, no contamination to the process
- Superb airflow visible distance of 25 feet and more
- No turbulence created as fog enters the airflow
- Roller castors for easy movement over floor
- Large, 80mm, 3.15", fog outlet
- User Friendly display and touch pads
- Stainless steel contacts the LNG and DI Water for best purity of fog
- very low fog pressure to produce a buoyant fog for airflow visualization
- No metal contamination to fog using Stainless Steel water heater and LNG Dewar
- Rapid DI Water fill and LN2, LNG, fillup
* Fog distance measured at 40% humidity and air velocity of 90fpm. Visual fog distance decreases as humidity decreases or as airflow velocity increases.
AP32 Nitrogen Fog Generator Specifications- Request a Quote
(Subject to change without notice)
Use 16M ohm DI water or WFI Pharmaceutical Water
Do not permit DI Water to go stagnant in the chamber
** Use gloves when handling CO2 ice
The three types of foggers manufactured for use in the semiconductor and pharmaceutical industry are described below.
Ultrapure LN2 Fogger: This type of smoke generator or clean room fogger provides the highest volume, density and purity of fog. Purity is created by bringing the water to a high temperature, creating a vapor, while simultaneously using gravity to remove the residual mass from the vapor. This process removes any bacterial agents and residual particulate matter from the vapor. The pure vapor is then passed over an LN2 bath, which naturally boils at room temperature. The water molecules bond with nitrogen molecules, creating a nominal 3um fog droplet. The volume of water and nitrogen molecules that combine is extremely high in quantity, creating a dense, high volume, ultrapure fog output with exit temperatures of about 78 degrees F with an exit pressure of less than 0.5 lbs, so as not to disturb the surrounding airflow. The fog is ultrapure leaving minimal, if any, trace particles behind. It evaporates to its gaseous hydrogen, oxygen and nitrogen components, which are natural to the Cleanroom environment. The high density of the fog increases the duration and travel distance of the fog. This fogger can be used in a Class 1 - 10,000 cleanroom environments of pharmaceutical and semiconductor facilities; such as sterile rooms, hospital rooms, medical rooms and cleanrooms.
DI Water Fogger: This type of fogger has less fog density (less capability to visualize airflow) than the UltraPure Fogger described above, but more density than the CO2 fogger described below. The DI water fog is generated by atomizing DI water into water droplets, which are nominally 3-10um in size. The water droplets may contain residual particulate matter remaining in the DI water, but this would be very trace amounts. If the facility manager operates a class 10 to Class 10000 Clean room, the use of a DI Water Fogger poses no problem. However, Cleanroom Engineers who manage facilities operating at Class 1 to Class 10 performance may desire to use an ultrapure fogger. Although some DI Water foggers are described as ultrapure, unless the DI water is vaporized to remove bacterial agents and residual particulate matter, the fog is not ultrapure. The 3-5lb output pressure of a DI water fogger also distorts the airflow patterns, thus adding to the turbulence. The temperature output is typically less than the surrounding room temperature, thus a fog generated from the atomized water droplets will sink momentarily in a typical 70 degree room temperature.
CO2 Fogger: This type of smoke generator or CO2 Fogger is designed for low volume, non-process critical applications such as bench airflow testing. The fog is created using CO2 ice as the fogging agent. The fog contains elements of the CO2 and the user must determine if the residual CO2 components are acceptable in a process environment operating Class 100 to Class 10,000. The 3-5lb output pressure of a CO2 fogger also distorts the airflow patterns, thus adding to the turbulence. The output starts at about 3cfm and slowly decreases to 0 CFM in about 10 - 12 minutes.
Smoke Sticks are used in some Pharmaceutical Clean Rooms around the world. Below is a discussion on the use of smoke sticks used to visualize airflow and turbulence?
A smoke stick is often used visualize airflow turbulence, but smoke sticks are filled with particulates and chemicals. Smoke is created using chemical reactions; thus the smoke is SPUTTERING (sputter) or popping out of the smoke stick in a non-consistent pattern with velocity, but little volume. It is a particle smoke, compared to a visible, pure water based fog, thus smoke sticks are a contaminating smoke. The smoke stick generates an inconsistent flow or pattern of smoke, but it is low cost, which is why some managers allow use of smoke sticks in their Pharmaceutical clean rooms.
Compare a smoke stick to a Clean Room Fogger or an UltraPure LN2 fogger, both which produce a constant volume of fog with a consistent fog output and pure fog. Di Water foggers produce a consistent flow of visible water vapor, which enters the airflow to visualize the airflow patterns and turbulence, then begins to evaporate, returning back to the hydrogen, oxygen and nitrogen components that we breathe. No particulate contamination, no chemical contamination. Water based foggers produce a constant volume of fog at a constant rate, which provides consistent visualization of airflow patterns and turbulence. The Smoke Stick has to be waved around to see what kind of airflow pattern there is, while a Di Water fogger is simply placed in position and produces a flow of fog that can be directed 360 degrees to easily describe the airflow patterns and turbulence. In addition, tubes are now available to create "fog curtains", or a wall of fog, which smoke sticks can not produce.
How many smoke sticks are used per smoke cycle? How much labor is needed to clean up after smoke stick use. Do you need to Clean all the walls where the smoke stick was used. How did the chemical particulates and particles affect the process area? These are critical questions for a pharmaceutical manager. Did the contaminating particles and chemicals get into the drug process?
How much labor is used to cleanup after smoke stick use and if the cleanup did not get every chemical particle, then some smoke chemical material is added to the Pharma process or trapped in a filter somewhere, until it escapes into the Pharma process. That is a quality control issue for that company using smoke sticks.
The low labor cost of using smoke sticks is the reason facility managers may use smoke sticks, but are the chemical and particulate effects to the pharma process being analyzed? Non-contaminating fog does not emit particulates, requires less labor and does not contribute any unwanted chemicals to the Pharma process. A Di Water Fogger provides these advantages in fog volume, fog consistency and fog purity, which easily outweighs the low cost of smoke sticks, the high cost of labor for cleanup and the detrimental affects to quality control!
Smoke Sticks - quality side of the drug product: The smoke chemicals are not of the same chemistry as the drug product, thus smoke chemicals and particulates could migrate into the drug process. There is no guarantee the cleaning process removed all the unwanted particulates and chemicals, from for example, a glove box or isolation box. The chemicals and particulates eventually migrate to the air filter system, which is not 100% effective. If this is the case, the quality and purity of the drug process is affected. Drug quality is the basis of product credibility, which is a valuable asset in customer relations.
Smoke Sticks - labor side of the drug product: The smoke is generated by a chemical reaction, which causes the smoke to sputter into the environment. The smoke is inconsistent in volume, thus the smoke stick is unpredictable for airflow visualization. The chemicals migrate to equipment and walls, which then must be cleaned, and requires an added labor cost. The use of Smoke sticks generates an inefficient smoke, not a consistent fog.
A Di Water Fogger produces a water (H2O) droplet that evaporates back into hydrogen and oxygen, the air we breathe. No clean up is required, at all. No additional time delays and clean up labor is not required. The fog is consistent in volume and constant in output to describe the airflow patterns and turbulence. These are equipment, quality and application concerns to consider when the need for airflow visualization is considered.