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Fog machine

A fog machine, sometimes referred to as a smoke machine, is a specialized device that produces a dense, visible vapor resembling natural fog or smoke by vaporizing a liquid fluid, typically through heating, and dispersing it into the air to create atmospheric effects. These machines operate on the principle of aerosolization, where a pump forces a glycol- or water-based fluid into a heated block or boiler, causing rapid vaporization, which is then expelled through a nozzle to form suspended particles that scatter light and mimic fog. The modern fog machine emerged in the mid-1970s as a safer alternative to earlier theatrical methods, such as burning wet straw, rosined rope, or flammable mineral oils, which posed significant fire hazards and produced inconsistent results. inventor Günther Schaidt, of Safex Chemie in 1973, developed the first glycol-based fog machine, revolutionizing by enabling precise, non-toxic generation for stages and ; in 1985, Schaidt and U.S. manufacturer Rosco Laboratories received a Scientific and Technical Award from the Academy of Motion Picture Arts and Sciences for this innovation. Prior to this, rudimentary fog effects date back centuries, with records of smoky atmospheres in 17th-century theaters like using damp wood or herbs, evolving through 1920s mechanical boilers mixing water and glycerin. Fog machines come in several types tailored to specific applications, including standard glycol foggers for dense, billowing clouds; low-lying variants using or liquid CO₂ to produce ground-hugging fog by chilling the vapor; they are widely employed in the entertainment industry for concerts, theater productions, sets, and theme parks to accentuate , simulate environments, and heighten dramatic tension, while also finding uses in , simulations, and applications like suppression. Modern designs prioritize , adhering to guidelines that limit exposure to glycol aerosols to prevent respiratory irritation, with fluids formulated to minimize health risks in controlled settings.

History

Early theatrical effects

The use of fog-like effects in theater dates back to and performances as early as the BCE, where smoke from fires or was employed to enhance atmospheric scenes in outdoor amphitheaters. These simple natural methods mimicked or divine interventions, often integrated into tragedies and comedies to evoke supernatural or environmental moods. By the , Elizabethan and Jacobean theaters like in refined these effects for indoor and outdoor productions, using smoke from fireworks, oil lamps, and combustible materials to create illusions of magic, fire, or ethereal atmospheres. Various chemicals were burned beneath the stage to produce colored smokes—black, white, yellow, or red—enhancing scenes in plays such as or . These manual methods, often ignited by squibs or candles, added dramatic tension but posed fire risks, as evidenced by the 1613 Globe fire sparked by a theatrical cannon effect during . In the , Victorian advanced these techniques with chemical mixtures like and water, which reacted to form a fine, persistent suitable for elaborate melodramas and operas. salts, known as sal ammoniac, were also heated to generate hazy vapors. This method, producing a cool, white fog without open flames, allowed for safer immersion in spectral or foggy settings, as seen in the Opéra premiere of Giacomo Meyerbeer's Robert le Diable, where innovative scenic simulations including hazy apparitions of nuns in a ruined captivated audiences and set new standards for spectacle. As theater transitioned into the , developments in the included mechanical boilers that mixed and glycerin to produce effects. Manual adaptations of industrial tools emerged in the , such as the insect foggers from the Madewell Company, which used oil-based sprayers to vaporize into theater for low-budget productions. These portable devices, originally designed for , were repurposed by stage technicians to create quick, dense mists, bridging pre-mechanical methods to later innovations while highlighting the ongoing evolution from chemical simplicity to controlled dispersion.

Modern inventions and advancements

The development of mechanical fog machines traces its origins to the , when inventor Dr. K.H. Stahl pioneered pulse-jet thermal foggers for and disinfection applications. Based on technology derived from wartime innovations like the rocket, Stahl's early devices, produced under brands such as Swingfog, generated fine mists for agricultural and sanitary purposes. By the late , these foggers had been refined over initial prototypes, with Stahl establishing production that laid the groundwork for broader adaptations, including eventual use in entertainment settings for atmospheric effects. A significant breakthrough occurred in the 1970s with Günther Schaidt's invention of the modern heated fog machine, which utilized glycol-based fluids to produce safer, more controllable fog compared to earlier oil-based systems that posed fire risks and residue issues. Schaidt, through his company SAFEX Chemie in , patented this design, enabling precise vaporization via a heated block that atomized the fluid into dense, persistent clouds suitable for theatrical applications. This innovation marked a shift from rudimentary thermal foggers to reliable, professional-grade equipment, enhancing safety and ease of use in live performances. Commercialization accelerated in the and as companies like LeMaitre and Rosco introduced specialized models tailored for theater and film industries. LeMaitre, founded in 1977, expanded its lineup with the in the late 1970s and followed with robust professional units in the , emphasizing high-output smoke for stage productions. Rosco similarly launched the 1500 series in the , a portable fogger that became a staple for its reliability in scenic and setups. Concurrently, Antari entered the market in 1985 with its debut fogger line from , quickly gaining traction for affordable, durable machines used in concerts and events. From the 2000s onward, fog machine technology evolved toward and integration, with a notable shift to water-based and biodegradable fluids that reduced environmental impact while maintaining fog density. Ultrasonic models emerged prominently in the 2010s, employing high-frequency vibrations to nebulize water or low-glycol mixtures without heat, as seen in devices like the Aqua Flame for safer, residue-free effects. controls became standard by the mid-2000s, allowing precise synchronization with lighting systems in professional setups. In the 2020s, eco-friendly variants proliferated in response to regulations like the EU's REACH framework, which mandates registration and restriction of hazardous chemicals in fog fluids to minimize health and ecological risks.

Principles of Operation

Fog generation mechanisms

Artificial fog is produced by creating an consisting of suspended microscopic droplets or particles, typically ranging from 1 to 5 micrometers in , which scatter visible to produce a hazy effect similar to natural . This process relies on , where vapor or is induced to form droplets either by on existing nuclei or direct , ensuring the particles remain airborne long enough to mimic atmospheric . Several common mechanisms are employed to generate these aerosols. In , a is heated to produce a gas or vapor, which then cools rapidly upon expulsion into ambient air, leading to into fine droplets. involves the direct transition of a solid, such as (solid ), to gas at low temperatures, releasing cold gas that chills surrounding air and promotes of atmospheric moisture. Cryogenic cooling uses , which evaporates and absorbs heat from the air or a vapor stream, causing rapid temperature drops that induce and droplet formation. Ultrasonic nebulization employs high-frequency vibrations (typically 1-3 MHz) from a piezoelectric to create in a , shattering it into a fine mist without heating. The key physics underlying these mechanisms centers on adiabatic cooling, where the expansion or mixing of gases or vapors with cooler air reduces temperature without heat exchange, leading to supersaturation and subsequent condensation via nucleation on aerosol nuclei. This process ensures droplet formation in the optimal size range for light scattering and persistence. For visibility, the diameter d of a spherical droplet can be related to its volume V by the illustrative equation d = \left( \frac{6V}{\pi} \right)^{1/3}, which highlights how particle volume determines the size critical for effective fog opacity. Output characteristics of fog generation are influenced by several factors, including pump pressure to ensure proper dispersion of the through nozzles. efficiency in vaporization-based systems affects the completeness of fluid conversion to vapor, with higher yielding denser output. rates control the volume and persistence of the fog by facilitating mixing and preventing premature settling.

Fluids and their properties

Fog machine fluids primarily consist of glycols and other humectants that, when vaporized or atomized, produce the desired atmospheric effects. The most common base fluid is (), a clear, colorless, slightly syrupy liquid with 99% or higher purity, often USP-grade for safety and performance in fog applications. is hygroscopic, meaning it attracts and retains moisture from the air, which contributes to the persistence of the fog. Its is 188.2°C, is 1.036 g/cm³ at 25°C, and dynamic is approximately 42 cP at 20°C. Another key fluid is (TEG), valued for its lower volatility compared to PG, resulting in longer-lasting fog with reduced evaporation. TEG is a colorless, odorless liquid that is also hygroscopic and miscible in , with a of 285°C, of 1.125 g/cm³ at 20°C, and of 47.8 cP at 20°C. Vegetable-based (glycerol) serves as a viscous alternative or supplement, offering a sweet-tasting, non-toxic profile that enhances fog density due to its high moisture retention. has a of 290°C, of 1.261 g/cm³, and significantly higher of about 1490 cP at 20°C, making it thicker and more residue-prone than glycols. For unheated ultrasonic systems, plain is used as the primary fluid, as it atomizes effectively without additional chemicals. Key properties of these fluids influence their suitability for fog production, including for flow through machine components, for (typically >93°C, with PG at 99°C and TEG at 165°C in pure form, higher in mixtures), and for formation. Eco-friendly variants, such as those based on PG or glycerin, meet EU 301 standards for ready biodegradability, achieving over 60% degradation in 28 days under aerobic conditions, minimizing environmental impact. Fluids often incorporate additives to optimize performance, such as mixtures of 50-90% for dilution, which reduces and cost while controlling density. Colorants are rarely used, limited to specialized due to potential machine clogging, and scents are minimally applied—typically less than 1% by volume—to avoid health risks and residue buildup, as seen in commercial scent additives compatible with water-based systems. Selection of fog fluids depends on with the , such as high-temperature for heated systems (e.g., or TEG with boiling points above 180°C) versus low-residue options for ultrasonic use. Other criteria include desired output —thicker with higher glycerin content—and residue minimization to prevent , achieved through high-purity formulations and dilution ratios. Fluids must also align with standards, ensuring flash points exceed operational temperatures for non-flammable operation.

Types of Fog Machines

Heated fog machines

Heated fog machines represent the predominant type employed in theatrical, concert, and event settings due to their reliability and versatility in generating dense atmospheric effects. The core design incorporates a , typically holding 0.5 to 7 liters depending on the model, an electric heater block rated at 800-1600 watts to vaporize the fluid, a —often peristaltic or piston-driven—to transfer the , a for controlled expulsion, and a or interface for precise operation. These components are housed in a compact, portable , with output capacities ranging from 2000 to 50,000 cubic feet per minute (CFM) to suit small venues or large arenas. For instance, the Rosco Vapour series utilizes a die-cast aluminum for efficient , ensuring minimal residue accumulation when paired with high-quality fluids. Operation begins with the heater reaching operational temperature, after which the draws glycol- or water-based from the reservoir and injects it into the heated block, where it flash-vaporizes at approximately 200-250°C. The resulting vapor expands rapidly and is forced through the nozzle by an internal , cooling instantly in ambient air to form microscopic droplets that create visible, lingering lasting 5-30 minutes per burst before dissipation. This allows for intermittent or continuous output, controlled via or remote, with consumption varying from 3-320 per minute based on intensity. Professional models like the Antari M-8, designed for touring applications, feature a 1700W heater, approximately 9.5-minute warm-up, and up to 50,000 CFM output from a 10-liter tank, enabling extended use in demanding environments. Variants of heated fog machines include vertical configurations that project fog upward for volumetric fills in aerial lighting setups and horizontal designs equipped with auxiliary fans to direct low-level, ground-hugging dispersion across stages. Vertical models, such as certain Chauvet Hurricane series units, facilitate mounting in tight spaces for rising plumes, while horizontal ones prioritize even coverage in floor-based effects. These machines offer advantages like high-volume production for immersive atmospheres, portability under 20 kg for most units, and economical fluid costs of $20-50 per , making them accessible for and use alike. However, drawbacks encompass a required warm-up period of 2-10 minutes, potential residue buildup in the heater and pump necessitating periodic , and sensitivity to fluid quality to avoid or overheating. Compared to unheated types, heated fog machines excel in producing denser, longer-lasting airborne suitable for elevated effects.

Unheated fog machines

Unheated fog machines produce atmospheric effects through cooling processes or mechanical vibration rather than thermal , resulting in dense, low-lying that hugs the ground for enhanced visual impact in performances and events. These systems rely on the of solid or cryogens or ultrasonic of to generate , offering alternatives to heated methods by avoiding the need for prolonged warm-up times and specialized fog fluids. Dry ice machines operate by placing solid (dry ice) into a heated water bath, where the dry ice sublimates directly from solid to gas at -78.5°C under , cooling the surrounding air and to form thick, low-lying that remains below 1 meter in height for 5-10 minutes per batch. This process creates a rolling, ground-hugging effect ideal for stage illusions, with machines like the Chauvet DJ accommodating up to 10 pounds of dry ice for continuous output over 6 minutes, covering areas up to several thousand square feet. Cryogenic fog machines utilize at -196°C or to chill and condense or pre-generated , producing extended plumes of that roll along the when output through insulated hoses. These systems, such as the CryoFX NitroCannon, generate massive low-lying effects for large venues by rapidly cooling ambient , but require careful handling due to the risk of asphyxiation from nitrogen displacing oxygen in enclosed spaces. Ultrasonic fog machines employ piezoelectric transducers that vibrate at frequencies around 1.7 MHz to break it into a fine without or additives, resulting in silent, cool output suitable for indoor applications. Basic models produce fine from a reservoir, offering adjustable density for subtle ground effects. Unheated fog machines provide advantages such as instant startup without preheating and no oily residue on surfaces, making them preferable for quick setups in theaters and events. However, they often require frequent refills of or cryogens, increasing operational complexity and costs compared to self-contained heated systems.

Applications

Entertainment and events

Fog machines play a pivotal role in entertainment by creating atmospheric effects that enhance mood, visibility, and immersion in live performances and visual media. In theater and film, they produce low-lying mists or dense clouds to simulate environments like foggy streets or ethereal realms, allowing light beams to become visible and adding depth to scenes. For instance, in Broadway's , which has run since 1988, 10 fog and smoke machines are used per performance to generate haunting vapors during key sequences, such as the descent into the underground lair. Similarly, the production employs six City Theatrical SS6000 foggers to create ground-hugging fog that has been in use for over two decades. In , fog diffuses light to establish and tension, as seen in Steven Spielberg's films like (1982), where it softens moonlight and accentuates otherworldly elements. This technique is particularly prevalent in horror genres, where fog obscures visibility to build suspense and reveal action gradually. In concerts and nightclubs, fog machines amplify lighting and laser displays by scattering beams, fostering a dynamic "rock band ethos" that immerses audiences in high-energy atmospheres. At festivals like Coachella, performers such as J Balvin in 2024 utilized extensive fog packages to blanket the stage, enabling vivid 2000W laser spectacles that pierced the desert air for synchronized visual effects. During Coachella 2019, custom props integrated low fog, standard fog, and smoke bursts from machines producing thousands of cubic feet per minute (CFM) to simulate cosmic elements, enhancing sets for artists like Childish Gambino. High-output models, such as those exceeding 10,000 CFM, are common for large venues to rapidly fill spaces and make pyrotechnics more striking when combined with timed fog bursts. For holidays and private events, fog machines create thematic illusions, from spooky Halloween scenes to romantic moments. During Halloween, they generate ghostly atmospheres in houses and parties, with machines like those from Froggy's Fog outputting up to 20,000 CFM to envelop rooms in dense, lingering mist for dramatic reveals. In weddings, low-lying fog adds a fairy-tale quality to first dances, producing a dreamy cloud effect under soft lights that makes couples appear to float, as popularized in events with LED-integrated units for color-synced immersion. These applications often use water-based fluids for quick dissipation and minimal residue, ensuring versatility for indoor celebrations. Technical integration elevates fog machines in entertainment through DMX protocols, allowing precise control of output and timing via lighting consoles for synchronized effects. Professional units, like those from Rosco, feature DMX interfaces to trigger bursts in rhythm with music or cues, integrating seamlessly with for explosive reveals in concerts. In the 2020s, advancements include built-in RGB LEDs that sync with DMX signals, creating multicolored fog plumes that enhance immersive experiences in clubs and festivals without additional fixtures.

Industrial and scientific uses

Fog machines play a vital role in firefighting training by generating artificial smoke to replicate hazardous low-visibility conditions, allowing firefighters to practice search and rescue, ventilation, and navigation techniques safely. These systems are used in training that complies with safety standards for facilities, including NFPA 1403 for live fire evolutions and guidance for artificial smoke use. Specialized oil-based fluids are used to produce dense, heat-resistant fog that persists in high-temperature environments up to 400°F, enabling drills in burn buildings or training towers. For instance, high-capacity units like the SG-M1800 deliver up to 50,000 cubic feet per minute (CFM) of fog, facilitating large-scale visibility exercises across academy facilities. As of 2025, fog machines are seeing expanded use in public health campaigns for mosquito control in urban environments, with electric thermal foggers facilitating efficient dispersal of insecticides for vector-borne disease prevention such as dengue and malaria. In and disinfection, particularly in , thermal foggers disperse insecticides, fungicides, and sanitizers as ultra-fine droplets over large crop areas, improving coverage and efficacy compared to traditional spraying. PulsFOG systems, developed since 1949, exemplify this application, with models like the K30 treating up to 150,000 square feet in 45 minutes by vaporizing chemicals for deep penetration into canopies. These devices have been integral to agricultural pest management since the mid-20th century, reducing labor and chemical usage while targeting hard-to-reach pests like mites and . EPA-registered formulations ensure environmental safety, with no-rinse concentrations suitable for food-contact surfaces in post-harvest disinfection. Scientific visualization employs fog machines to trace airflow patterns in controlled experiments, serving as non-invasive tracers for studies. In wind tunnels, fog acts as seed particles to reveal boundary layers, vortices, and aerodynamic properties around models like airfoils or vehicles, aiding research in and . Systems such as the FlowLiner produce continuous, high-density fog threads compatible with techniques like () for quantitative analysis. Post-COVID-19, fog generators have simulated dispersion in medical labs to model respiratory spread, confirming that artificial fog does not prolong particle suspension and thus informs strategies in healthcare settings. Additional industrial applications include training for and tactical maneuvers, where dense simulates battlefield obscuration to train troops in and concealment. In HVAC testing, fog machines detect duct leaks and evaluate distribution by introducing traceable into systems, with models certified under 110 for and critical environment validation. These uses highlight fog machines' versatility in professional settings, often employing glycol-based or aqueous fluids approved for non-contaminating air quality assessments. In residential applications, portable low-lying foggers are increasingly popular for home events and holiday displays as of 2025, reflecting innovations in consumer-grade, easy-to-use models.

Health and Safety Considerations

Health risks by fog type

Heated fog machines, which typically use or vaporized at high temperatures, pose acute respiratory risks including , dry throat, and eye irritation due to the aerosolized particles irritating mucous membranes. A 2005 study of industry workers found that short-term exposure to glycol-based fogs was associated with increased acute upper airway symptoms, such as and throat discomfort. Chronic exposure to these fogs has been linked to exacerbated symptoms, persistent wheezing, and reduced lung function, particularly among those with cumulative high-level contact over years. The same study reported significantly higher rates of chronic work-related wheezing and chest tightness in employees with prolonged glycol fog exposure compared to unexposed controls. Dry ice fog machines, which produce fog by sublimating solid carbon dioxide (CO2) at -78.5°C into water vapor, primarily risk asphyxiation in enclosed spaces where CO2 gas displaces oxygen, leading to symptoms like dizziness, rapid breathing, and unconsciousness at concentrations above 5%. The Occupational Safety and Health Administration (OSHA) sets a permissible exposure limit for CO2 at 5,000 parts per million (ppm) as an 8-hour time-weighted average to prevent such hazards. Direct skin contact with dry ice can also cause frostbite burns within seconds due to its extreme cold. Cryogenic fog machines using (N2) at -196°C generate fog through rapid evaporation but carry similar asphyxiation risks from N2 displacing breathable air, potentially causing without warning odors. Unlike chemical-based fogs, they leave no residue, but direct contact risks cryogenic burns, tissue freezing, and cold stress leading to in prolonged exposure scenarios. Water-based fog machines, often employing ultrasonic nebulization, present minimal chemical risks but can increase indoor , potentially aggravating mild respiratory discomfort in sensitive individuals. If not regularly cleaned, these devices may promote bacterial growth in standing water, aerosolizing pathogens like that could cause flu-like symptoms or infections upon inhalation. Individuals with pre-existing conditions, such as , and performers facing prolonged exposure are particularly vulnerable to these effects; for instance, glycol fog has been associated with vocal cord and dryness, potentially worsening voice strain during extended use.

Safety measures and regulations

Operational guidelines for fog machines emphasize proper to dilute airborne particles and maintain levels below recommended limits. For indoor use, adequate is essential to achieve (ACH) sufficient to keep concentrations under 10 mg/m³ as an eight-hour time-weighted average (TWA), in line with the American Industrial Hygiene Association (AIHA) Workplace Environmental Level (WEEL). Fluid compatibility requires adhering to manufacturer specifications to prevent overheating, which can exceed safe temperatures and pose risks; using incompatible fluids may lead to or hazardous emissions. Cleaning protocols involve residue removal after approximately 30 hours of operation or weekly for frequent use, typically by flushing the with a compatible cleaner such as or diluted to dissolve glycol buildup and prevent clogs. Personal protective equipment (PPE) is recommended for operators handling fog fluids and during active use. N95 masks effectively filter at least 95% of airborne particles from glycol-based fogs, protecting against respiratory irritation in enclosed spaces. gloves should be worn when refilling reservoirs with glycol or oil-based fluids to avoid skin contact, and cryogenic gloves are necessary for unheated fog machines using or liquid CO2 to prevent . Monitoring tools, such as CO2 detectors, are critical for cryogenic systems to alert for accumulation that could displace oxygen. Regulations governing fog machines focus on equipment design, fluid composition, and exposure limits to ensure safe theatrical and event use. The ANSI E1.5-2009 (R2024) standard specifies safe compositions for aqueous fog solutions using di- and trihydric alcohols like propylene glycol and glycerin, limiting components to protect performers and audiences from short- and long-term exposures. ANSI E1.29-2009 (R2024) establishes product safety testing for fog generators, evaluating risks of fire, electrical shock, and aerosol hazards in design and operation. ANSI E1.23-2023 provides guidance on implementing fog effects, requiring a safety summary document outlining hazards, mitigation, and maintenance. In the United States, OSHA's 29 CFR 1910.1000 addresses general air contaminants, with AIHA WEEL values applied for propylene glycol at 10 mg/m³ TWA since it lacks a specific permissible exposure limit (PEL). In the European Union, fog fluids must comply with the Classification, Labelling and Packaging (CLP) Regulation (EC) No 1272/2008 for hazard communication, while glycerin used in fluids should meet purity standards under the Cosmetics Regulation (EC) No 1223/2009, typically requiring at least 99.5% purity to minimize impurities like diethylene glycol. Environmental safety measures address fluid disposal and emissions to reduce ecological impact. In regions like , fog fluids must not contain Proposition 65-listed chemicals known to cause cancer or reproductive harm; common glycol-based fluids are generally compliant as propylene glycol and glycerin are not listed. Some jurisdictions encourage or require biodegradable fluids for outdoor use, with spill containment protocols recommended for CO2-based systems to manage liquid CO2 leaks and prevent asphyxiation hazards in confined areas.

Related Technologies

Haze machines

Haze machines generate a subtle, fine that hangs persistently in the air, distinguishing them from denser effects by creating an even, translucent layer ideal for light diffusion rather than ground-level clouds. These devices vaporize specialized fluids into ultra-small particles, typically 0.2 to 1 micron in diameter, to achieve long-lasting atmospheric enhancement without obstructing visibility. In design, haze machines resemble heated foggers but utilize finer nozzles and slower pumps to produce a continuous output of approximately 500-5,000 cubic feet per minute (CFM), depending on the model, ensuring steady . Operation involves low-heat of glycol- or water-based fluids, where the mixture is atomized through heaters or high-pressure air systems, forming a lingering that scatters light beams effectively without settling quickly. This process allows for precise control via or manual adjustments, enabling variable density to suit different environments. Haze machines are predominantly employed in entertainment venues like concerts and nightclubs to improve beam visibility for lighting rigs, lasers, and moving heads, creating immersive three-dimensional effects. A representative example is the Look Solutions Unique 2.1, a water-based hazer designed for 24/7 continuous operation with a 2-liter and rapid 60-second warm-up, supporting extended use in professional settings. Key advantages of haze machines include uniform coverage over large areas and minimal residue, particularly with water-based models that reduce equipment buildup. However, they require slower buildup times to achieve desired density and may consume more fluid over prolonged periods due to their emphasis on sustained output, typically 4-10 ml per minute.

Smoke machines

Smoke machines are specialized devices engineered to generate thick, opaque particulate clouds that mimic the and of actual , distinguishing them from lighter fog effects. These machines primarily utilize oil-based fluids, such as , or glycol-based variants, which are vaporized through high- systems to produce persistent, heavy . Designs incorporate robust heat exchangers and burners capable of withstanding temperatures up to 400°F (204°C), ensuring the fluid remains stable in demanding environments like hot simulations. Larger fluid reservoirs, often exceeding standard fog machine capacities, enable sustained high-volume output for immersive scenarios. In operation, smoke machines employ through high-heat systems to produce fine , typically ranging from 0.2 to 0.3 microns in mass median diameter, allowing for rapid dispersal and prolonged in the air. These systems are optimized for short, intense bursts rather than continuous emission, delivering dense clouds that can fill large spaces quickly. A representative example is the LeMaitre LSG (Low Smoke Generator), which integrates a compatible fog machine, such as the G Force 3, with liquid CO₂ in a patented conditioning process: upon activation, CO₂ is released first to cool and densify the vaporized fluid, creating a heavy, ground-hugging effect without additional heating elements. This method produces through rapid expansion and cooling, ideal for controlled, high-opacity simulations. These machines find primary application in fire training programs, where they replicate zero-visibility conditions to enhance skills in , search, and techniques. In simulations, they create realistic battlefield obscuration for tactical exercises, improving soldier readiness in low-light, smoke-filled environments. Additionally, smoke machines serve as safer alternatives to traditional in , providing controllable dense effects for action sequences. Oil-based variants, like foggers used in industrial settings, facilitate smoke tests for evaluating HVAC performance and in large-scale systems. The primary advantage of smoke machines lies in their ability to deliver highly realistic opacity and persistence, closely approximating real smoke for effective training and without the dangers of live . However, oil-based models can lead to residue buildup on surfaces and , necessitating thorough cleaning to prevent slippery conditions or damage. Overheating poses hazards, as mineral oil fluids are flammable and may ignite if temperatures exceed design limits, requiring strict adherence to operational guidelines and .

References

  1. [1]
    How A Fog Machine Works - Rosco Spectrum Blog
    Oct 24, 2022 · The 20th century witnessed the birth of the modern fog machine. In the 1920s and 1930s, the first chemical-based fog machines were introduced.
  2. [2]
    In Favor of Fog and Fans - PLSN
    Nov 3, 2022 · When glycol fog was first developed by the late Günther Schaidt in Germany in the mid-1970s, it was a major improvement to the technology at the ...Missing: invention | Show results with:invention
  3. [3]
    Protocol Summer 2025: A history of fog and haze
    Sep 2, 2025 · Smoky, dramatic effects have been used for hundreds of years, there's even mention of it being used as early as the 1600s in Shakespeare's Globe theater in ...
  4. [4]
    Effects of theatrical smokes and fogs on respiratory health ... - PubMed
    Background: Theatrical fogs (glycol or mineral oil aerosols) are widely used in the entertainment industry to create special effects and make lighting visible.
  5. [5]
    Special Effects | Shakespeare's Globe
    Theatre companies used smoke mostly as a magic effect, although it was sometimes used to suggest a fire. They could make black, white, yellow and red smoke ...
  6. [6]
    Shakespeare's Globe Theatre: The Fire of 1613 Facts | HistoryExtra
    Jun 29, 2020 · On 29 June 1613, the original Globe theatre in London, where most of William Shakespeare's plays debuted, was destroyed by fire during a performance of All is ...
  7. [7]
    The drunken history of theatrical fog effects - YouTube
    Apr 7, 2020 · ... fog that disappear almost instantly. The melted smoke machine video is here:- https://www.youtube.com/watch?v=8ZGGgb3iFpg If you enjoy these ...Missing: modern | Show results with:modern
  8. [8]
    The Diorama, Apparitions, and Dream Image in Robert le diable
    Abstract. The far-reaching transformation of grand opera into a modern medium of spectacle was inaugurated by Giacomo Meyerbeer's Robert le diable.
  9. [9]
    Fogger- Madewell / Mole - Pacificwest Special Effects
    In stockThis unit heats up when plugged into a 110V power source. Runs with a thumb pump so it can operate for a few minutes after being disconnected from the power ...Missing: theater 1940s
  10. [10]
    News | pulsFOG
    In 1968, after two decades of producing and perfecting thermal foggers, Dr. Stahl and his son Werner Stahl, who was just 27 at the time, founded pulsFOG....Missing: invention | Show results with:invention
  11. [11]
    Chung Hsi Chemical | Products | K-10-SP thermal fogger
    Dr. Stahl, the founder of the German company pulsFOG, developed the earliest pulse engine thermal fogger based on the pulse engine of the V1 rocket, a war ...Missing: 1948 | Show results with:1948<|separator|>
  12. [12]
    History - Fog Machines - Thomann
    In the 1970s, Günther Schaidt developed the fog machine as we know it today. This invention greatly improved the safety, ease, and precision of smoke and steam ...
  13. [13]
    Le Maitre at 40 - PLSN
    Apr 14, 2017 · “He came up with a brilliant new concept, and it hit the market as the Cloud Nine, the first commercially developed smoke machine specifically ...
  14. [14]
    Smoke Machine Reviews - Rosco 1500
    Although no longer in production (replaced by the 1600), introduced in the 1980s, the Rosco 1500 was a very popular unit for stage and film. It was a highly ...Missing: 1990s | Show results with:1990s
  15. [15]
    Robe America Named Exclusive US Distributor for Antari Fog ...
    Fog machine manufacturer Antari has appointed Robe America as its sole US distributor. ... Founded in 1985, the Taiwan-based Antari is internationally known as a ...
  16. [16]
    https://www.robelighting.fr/actus/robe-america-named-exclusive-us-distributor-for-antari-fog-machines
  17. [17]
    USF2000 - Involight
    The USF2000 is a water-based ultrasonic fog machine with 1800W power, DMX control, 4 min heat-up, 8L water tank, and 1.2L fog fluid tank.Missing: advancements 2000s
  18. [18]
    Europe Fogging Machine Market Size & Outlook, 2025-2033
    Europe's stringent regulatory environment encourages the adoption of eco-friendly and bio-based solutions, pushing manufacturers to innovate. Moreover, ...Missing: 2020s | Show results with:2020s
  19. [19]
    REACH Regulation - Environment - European Commission
    REACH is the main EU law to protect human health and the environment from the risks that can be posed by chemicals.Access to European Union law · 1907/2006 - EN · ChemicalsMissing: fog machines
  20. [20]
    Smoke Machines Particle Size
    A smoke particle of unit density, 0.2 micron in diameter, will fall at 8mm/hour, compared to a 2 micron particle, which falls at 468mm/hour. In essence this ...
  21. [21]
    Fogmaster Frequently Asked Questions
    In general, the output of Fogmaster foggers falls in a range from a near-invisible ULV dry fog (7-10 micron diameter), to an intermediate fog (15-20 microns), ...Missing: aerosol | Show results with:aerosol
  22. [22]
    [PDF] A Molecular Explanation of How the Fog Is Produced when Dry Ice ...
    This film of. CO2 vapor insulates the solid dry ice from the surrounding liquid, causing slow dry ice sublimation and cooling of the bulk liquid (Figure 4, ...
  23. [23]
    Process and apparatus for creating fog for special effects
    Cryogenic fluid is sprayed into the nozzle in the humid air path. The cryogenic fluid mixes with the humid air to create fog, which injects itself from the ...Missing: sublimation ultrasonic principles
  24. [24]
    Nebulizers | Journal of Aerosol Medicine and Pulmonary Drug ...
    Apr 29, 2024 · Large volume nebulizers, typically jet or ultrasonic nebulizers, hold up to 200 mL and may be used for either bland aerosol therapy or ...Missing: fogger | Show results with:fogger
  25. [25]
    Adiabatic and radiative cooling are both important causes of aerosol ...
    Sep 24, 2025 · Adiabatic and radiative cooling are both important causes of aerosol activation in simulated fog events in Europe.
  26. [26]
    A new conceptual model for adiabatic fog - ResearchGate
    The new fog paradigm is formulated as a conceptual model that relates the liquid water path of adiabatic fog with its thickness and surface liquid water content ...Missing: nucleation | Show results with:nucleation
  27. [27]
    3. Operating principle - Fog Machines - Thomann
    When you start the fog generation using your remote control, the pump goes into operation, and it keeps operating as long as the "start" button remains ...
  28. [28]
    Propylene Glycol | C3H8O2 | CID 1030 - PubChem
    Propylene glycol is clear, colorless, slightly syrupy liquid at room temperature. It may exist in air in the vapor form, although propylene glycol must be ...Dipropylene Glycol · Water · Chlorhexidine gluconate
  29. [29]
    Triethylene Glycol | C6H14O4 | CID 8172 - PubChem
    Triethylene glycol is a poly(ethylene glycol) that is octane-1,8-diol in which the carbon atoms at positions 3 and 6 have been replaced by oxygen atoms.
  30. [30]
    Glycerol | C3H8O3 | CID 753 - PubChem - NIH
    It has a minimum specific gravity (25 °C/25 °C) of 1.249, corresponding to no less than 95% glycerol. Kosher glycerin meets all USP requirements and is produced ...Missing: fog | Show results with:fog
  31. [31]
    Biodegradation of poly(propylene glycol)s under the conditions of ...
    The OECD 301E Test is a screening test with activated sludge as an inoculum and tested surfactant as a sole source of organic carbon (OECD, 1981). The ...
  32. [32]
    [PDF] GLYCEROL CAS N°: 56-81-5
    (performed according to OECD 301) 92% biodegradation was reported after 30 days. ... information on the biodegradability of glycerol with pre-adapted.
  33. [33]
    https://www.froggysfog.com/1-oz-charred-corpse-water-based-scent-additive-for-fog-haze-snow-bubble-juice-scents-2-gallons.html
  34. [34]
    The Complete Guide to Fog Machine Fluid Types - avsyncstudio
    Sep 26, 2025 · Glycol-Based Fog Fluids. Glycol-based fluids contain higher concentrations of glycols (propylene glycol or triethylene glycol) mixed with water.
  35. [35]
    [PDF] Material Safety Data Sheet Fog Fluids Smoke Factory
    Flash point: >140 degrees C. Ignition temperature: 355 degrees C. Spontaneous ... Viscosity: low viscosity. Spontaneous combustion: not spontaneously ...
  36. [36]
    https://www.rosco.com/products/brand/vapour
  37. [37]
    Foggy Notions - Part 1 - Theatre Effects
    The specifics of any fog machine's operation can vary among manufacturers, but the basics are the same. Fog fluid is introduced into a heat exchanger by a pump.Missing: advantages disadvantages
  38. [38]
    M-8 FOG MACHINE - Antari Lighting And Effects
    Introducing the M-8, the industry's first 1700W fog machine tailored for professionals. Its special design is perfect for large concert and touring ...
  39. [39]
    The Safety of Atmospheric Effects | AVIXA Xchange
    Aug 30, 2024 · They operate by pumping fluid through a heater and exhausting it into a fan that disperses the fog (ESTA, 2016). Gas-propelled machines work by ...
  40. [40]
    https://www.fullcompass.com/prod/267179-adj-vf400-400w-water-based-fog-machine-with-3-000-cfm-output-and-remote
  41. [41]
    https://www.musson.com/atmospheres-fog-fluid.html
  42. [42]
    Low-Lying Fog Machines - The Inside Scoop - CryoFX Co2 Info
    Ultrasonic atomization machines are even easier to use than dry ice or fog chiller machines. Also, they are less expensive and less complicated to use. With an ...Missing: unheated | Show results with:unheated
  43. [43]
    Dry Ice Sublimation - Science World
    Dry ice is solid. It sublimates or changes states from a solid to a gas at temperatures of -78 degrees Celsius under normal atmospheric pressure of 1 atm.Missing: machine physics
  44. [44]
    https://www.avmaxx.com/chauvet-dj-nimbus.html
  45. [45]
    Create dry ice fog
    Dry ice fog is created when you place dry ice into warm or hot water. This white fog is condensed water vapor, mixed with the invisible carbon dioxide release.
  46. [46]
    https://www.atlspecialfx.com/products/liquid-nitrogen-cryogenic-cannon-nitrocannon
  47. [47]
    https://www.co2meter.com/blogs/news/liquid-nitrogen-safety-requirements-osha
  48. [48]
    25MM 16MM 20mm Ultrasonic Mist Maker Piezoelectric Ultrasonic ...
    Rating 4.5 · Review by anonymousThe piezoelectric ceramic atomized generates a high-frequency resonance oscillation of 1.7MHZ or 2.4MHZ after being activated by the electric energy signal.Missing: CFM | Show results with:CFM
  49. [49]
    Froggy's Fog Poseidon Aqua 2 Ultrasonic Ground Fog Generator
    Type: Poseidon Aqua 2 Low-lying Fog Machine · Fog Output: 3000 cfm · Tank Capacity: Fog: 0.8 gal (3.02 liter), Water: 6 gal (22.71 liter) · Fluid Consumption: 25 ...
  50. [50]
    How To Choose The Right Low Fog Machine? - MOKA SFX
    Oct 10, 2024 · Dry ice machines create thick low-lying fog by changing dry ice into vapor. The mist produced by the machine stays close to the ground, creating ...
  51. [51]
    30 Little-Known Phantom Facts and Backstage Stories - Playbill
    There are 10 fog and smoke machines employed at each performance. The replica of the Paris Opera House chandelier features 6,000 beads It weighs one ton and ...
  52. [52]
    A Celebration of Phantom Broadway - City Theatrical
    Apr 26, 2023 · The Broadway company of Phantom uses six City Theatrical SS6000 Dry Ice Foggers which are finishing their second decade on the show.
  53. [53]
    Fog, Smoke, & Haze: The Swiss Army Knives of Cinematography ...
    May 3, 2014 · Here are a few examples of "Spielbergian" fog from, you guessed it, Spielberg movies: Here in E.T., Spielberg uses fog to not only diffuse the ...
  54. [54]
    Coachella 2024: J Balvin's 2000W Laser Spectacle Lights Up the ...
    Lightwave worked exhaustively to create a fog package that was capable of blanketing the desert with the required atmosphere to deliver a laser show that was ...
  55. [55]
    https://www.rythmefx.com/co2-jets-fog-machines/
  56. [56]
    Fog Machines And Co2 Jets - Rythm EFX
    CO2 jets produce dramatic bursts of fog, perfect for concerts, sports events, and high-energy moments like DJ drops or stage entrances. Are fog machines and ...
  57. [57]
    Froggy's Fog Titan 1200 Fog Machine, High Output Indoor Fogger ...
    High Output Fog Machine: Titan 1200 fog machines put out an amazing 20,000 CFM of fog; That's enough to fill an entire 2500 sq. ft. house in just 1 minute ...
  58. [58]
    https://www.amazon.com/Generator-Equipment-Professional-Entertainment-Halloween/dp/B0DXK4RRCP
  59. [59]
    1200W Fog Machine with RGB 6LEDs Lighting Smoke Haze ...
    ✓【Powerful 1200W Fog Machine】Our smoke machine has a power of up to 1200W and 6000CFM fog. Its surface is made of aluminum and is very durable.Missing: synced 2020s
  60. [60]
    http://www.ontario.ca/document/firefighter-guidance-notes/6-42-training-artificial-smoke
  61. [61]
    6-42 Training with artificial smoke | Firefighter guidance notes
    Jul 29, 2019 · Artificial smoke machines are frequently used for firefighter training. Common agents used to create special atmospheric effects are glycol-water mixtures and ...Missing: fog | Show results with:fog
  62. [62]
    Smoke & Hot Fire Training - Fog Machines
    The Vulcan & ViCount fog machines create a fog that is resistant to temperatures of up to almost 400°F, an effect which is simply impossible with a water-based ...
  63. [63]
    Smoke Generator M1800 - Rugged - High Capacity - 1800 Watt
    2–5 day delivery 30-day returnsThe M1800 is rugged, high capacity with 1800W heater, 50,000 CFM output, 2.5 gallon tank, and 50 min max operating time. It has a thermal control system.
  64. [64]
    K30-O Pulse Fogger - Best Vet Solutions
    Rating 5.0 (1) The PulsFOG advantage is speed. With models that can treat 150,000 square feet in as little as 45 minutes, the PulsFOG makes quick work of chemical ...
  65. [65]
    Common Applications for Thermal Fogging Machines
    May 13, 2024 · Thermal foggers allow for the precise and extensive application of disinfectants, pesticides, and other chemical treatments across wide areas.<|control11|><|separator|>
  66. [66]
    Environmental Hygiene Remediation via an Effective Fogging ...
    Sometimes you can successively fog with approved food contact, no-rinse concentrations of the EPA-registered product, such as a sanitizer, and achieve your ...Missing: fluids | Show results with:fluids
  67. [67]
    Wind Tunnel Studies - Concept Smoke Systems
    Artificial smoke is widely used in wind tunnels to visualise airflow patterns and enhance measurement techniques such as Particle Image Velocimetry (PIV) and ...Missing: fog | Show results with:fog
  68. [68]
    Professional Flow Visualization | FlowMarker®
    The FlowLiner® is based on the SAFEX Fog Probe System NS3. This fogger was specially developed for wind tunnels and produces a very powerful fog thread.
  69. [69]
    (PDF) Development of a Smoke Visualisation System for Wind ...
    The smoke visualisation system utilised a fog machine for smoke generation and required the design and manufacture of a smoke rake to produce smoke lines inside ...
  70. [70]
    (PDF) COVID-19 Implications of the Physical Interaction of Artificial ...
    Mar 20, 2021 · Conclusion Artificial fog use does not increase suspension time of respiratory aerosols, and therefore does not appear to increase the risk of ...
  71. [71]
    Why Is Russia Blowing Smoke (Literally)? The Military Uses of ...
    Aug 19, 2016 · It can do so to camouflage major military installations and military equipment as well as military personnel engaged in fording rivers. A ...
  72. [72]
    Military / Defence Training - Concept Smoke Systems
    Artificial smoke plays a crucial role in military and defence training exercises by creating a realistic battlefield environment.Missing: camouflage | Show results with:camouflage
  73. [73]
    Fog Machine - Models AL900 & Hazer Pro - Kanomax USA
    Ultra-fine, persistent fog ideal for laminar flow testing · Clean, non-toxic, low-residue output · Certified for use in critical environments per ASHRAE 110 ...
  74. [74]
    https://www.moglix.com/articles/an-overview-of-the-different-uses-of-fogging-machines
  75. [75]
    Effects of theatrical smokes and fogs on respiratory health in the ...
    Apr 12, 2005 · Acute cough and dry throat were associated with acute exposure to glycol-based fogs; increased acute upper airway symptoms were associated with ...
  76. [76]
    [PDF] Use Nitrogen Safely - Air Products
    However, a discharge of liquid nitrogen itself creates a vapor cloud that is an asphyxiation hazard as well as a visibility hazard.
  77. [77]
    Liquid Nitrogen Can Cause Severe Burns - Poison Control
    Mar 2, 2021 · Although liquid nitrogen is generally inert if untouched, it has the potential to cause severe injury and even death if handled improperly.
  78. [78]
    Portable ultrasonic humidifier exacerbates indoor bioaerosol risks ...
    Nov 27, 2021 · Ultrasonic humidifiers increase bacterial aerosols, especially pathogenic genera like Pseudomonas, and can cause "humidifier fever". Avoid long ...Missing: fog machine growth
  79. [79]
    [PDF] Theatrical Fog, Smoke, and Haze Effects
    Theatrical fog, smoke, and haze use chemicals like glycols, glycerin, and water. These can cause skin irritation, eye pain, and biological hazards from water.
  80. [80]
    [PDF] Calibration Factors And Time-and-Distance Guidelines For Use of ...
    (10 mg/m3 as an eight-hour TWA) should also be protective for actors in theatrical productions. To ensure that peak smoke, fog, and haze levels are below these ...
  81. [81]
    Published Documents - ESTA TSP
    ANSI E1.29 is a guide for product safety testing laboratories in evaluating fog-making equipment for design or construction defects that might create ...
  82. [82]
    8. Cleaning fog machines - Thomann
    Free delivery over $149Generally, fog machines should be cleaned after every 30 hours of operation or before longer periods of not being operated. Cleaning removes the fluid residue ...
  83. [83]
    Effectiveness of Respiratory Protective Equipment in Theatrical ...
    Aug 23, 2024 · These masks are designed to filter out at least 95% of airborne particles, making them effective against the larger particles typically produced ...Missing: operators | Show results with:operators
  84. [84]
    Simulated Smoke, Real Health Effects - Fire Engineering
    Dec 22, 2014 · Wear nitrile gloves when refilling fog machine reservoirs with oil-based or glycol-based fluids. Wash your hands at the end of each training ...Missing: operators | Show results with:operators
  85. [85]
    https://www.fireengineering.com/firefighting/simulated-smoke-real-health-effects/
  86. [86]
    [PDF] As of June, fog fluids require a new marking. The EU has ... - Monacor
    As of June, fog fluids require a new marking. The EU has introduced a new classification with regard to hazardous substances (see EC directive 1272/2008). The ...
  87. [87]
    Glycerin for Fog Machine: Premium Solutions & Suppliers - Accio
    Rating 5.0 (141) · Free 14-day returnsAug 23, 2025 · Technical Specifications and Standards: Prioritize high-purity glycerin, typically 99.5% or higher (USP or equivalent industrial grade).
  88. [88]
    The Proposition 65 List - OEHHA - CA.gov
    The list contains a wide range of naturally occurring and synthetic chemicals that are listed for cancer or reproductive harm, or both.How chemicals are added to... · Lead · N-Nitrosomethyl-n-dodecylamine
  89. [89]
    [PDF] Molecular Fog Fluid | Ultratec Special Effects
    Mar 31, 2022 · The product is not classified as environmentally hazardous. ... California Proposition 65. Not Listed. Inventory status. Country(s) or ...
  90. [90]
    Pea Soup Phantom Hazer
    With a haze particle size of just 0.2 micron (mass median diameter) this hazer is truly in a class of its own, beating all competitor's systems hands-down.
  91. [91]
    ATMe | mdgfog.com
    Haze colour. ATMe: Pure white. Particle size. ATMe: 0.5 - 0.7 micron. Total running time. ATMe: 23 hours at 2.76 bar (40 psi) with a full tank. Warm-up time.
  92. [92]
    Fog Machine vs Haze Machine: Key Differences Explained - Vorlane
    Sep 22, 2025 · A haze machine is designed to create a fine, translucent mist that spreads evenly across a venue, unlike the dense clouds produced by a fog ...
  93. [93]
    Fog and Haze 101: A Primer - Look Solutions USA
    Sep 3, 2019 · Some haze machines vaporize fluid by forcing it through a heater, while others use high air pressure to vaporize the fluid. Haze is primary used ...
  94. [94]
    Choosing the Best Stage Effects Equipment Complete Guide to ...
    A haze machine vaporizes a unique haze fluid—water or oil-based—to a minute fog which is highly dispersed in the air. The fog consists of ultra-fine particles ...
  95. [95]
    Amhaze ECO - CHAUVET Professional
    Amhaze Eco is a professional water-based haze machine that delivers high output while utilizing economic fluid consumption. ... output of 120 cfm with a single ...
  96. [96]
    Look Solutions Unique 2.1 Hazer 16a Plug | Trade Hire - IPS
    Suitable for continious operation, this machine produces high quality haze for live lighting applications. Look Solutions Unique 2.1 Hazer 16a Plug. £80.00.
  97. [97]
    Hurricane Haze 4D - CHAUVET DJ
    Output:4,300 cfm; Fluid Consumption: 10 ml/min; Compatible Fluids: HFG, HF5 (EU), HFDJ5 (EU). What's Included. Hurricane Haze 4D; Power cord; Controller ...
  98. [98]
    Chauvet DJ Hurricane Haze 1DX Water Based Haze Machine ...
    Output: 800 cfm. Fluid Consumption: 4 ml/min. Compatible Fluids: HFG.
  99. [99]
    ViCount Oil Based High Output Fog Machine
    It creates an oil based fog effect that is resistant to temperatures of up to almost 400°F making it the perfect fog generator for hot fire training. The fog is ...
  100. [100]
    Pea Soup - Rocket smoke machines
    Particle size 0.2 - 0.3 micron, mass median diameter - the smallest particle size of any smoke machine. ('Disco' systems' smoke particle size are usually 3 ...
  101. [101]
    "LSG" Low Smoke Generator - J&M Special Effects
    When used with a Le Maitre G Force 3 Fog Machine, the LSG's patented CO2 conditioning process produces a huge, continuous output of low-lying fog.
  102. [102]
    [PDF] LSG Operations Manual - Schell Scenic Studio
    11) When the G300 Fog machine is up to operating temperature, activate the 'Smoke' button on the remote control. The CO2 will be activated first. After the ...
  103. [103]
    Smoke Particle Size Explained | Visibility, Filtration & Testing ...
    A smoke particle of unit density, 0.2 micron in diameter, will fall at 8mm /hr, compared to a 2 micron particle, which falls at 468mm/hr. In essence this means ...
  104. [104]
    https://www.concept-smoke.co.uk/about-smoke/particle-size/
  105. [105]
    Information about Oil & Water Based Fog Machines
    This term means that the fog chemical is water miscible, in the main these fluids are based on glycols and glycerol. Water –based fog machines are typically ...
  106. [106]
    The Ultimate Fog Machine Guide: Everything You Need To Know
    What are the Advantages and Disadvantages of Each Type of Fog Machine? 1. Water-Based Fog Machines: Advantages : – Less expensive and easier to maintain ...
  107. [107]
    https://fogmachines.com/ultimate-fog-machine-guide/
  108. [108]
    Fire Risks in Fume Extraction Systems - Lincoln Electric
    Fire can be a serious risk in these systems because it can occur unexpectedly and can cause not only equipment damage but may result in a fire in your facility.