Fluid energy mill – principle, construction, working, uses, merits, demerits MCQs With Answer

Fluid energy mill – principle, construction, working, uses, merits, demerits MCQs With Answer

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Fluid energy mill is a high-efficiency pneumatic micronizer widely used in pharmaceutical particle size reduction. This introduction summarizes the fluid energy mill – principle, construction, working, uses, merits, demerits – in clear, exam-focused language for B.Pharm students. Understand jet collision and fluidization principles, key parts such as nozzle, grinding chamber and classifier, critical operating variables (air pressure, feed rate, residence time), material suitability, and common pharmaceutical applications like dry grinding of APIs and excipients. Coverage also includes comparison with other mills, maintenance essentials, contamination control and scale-up considerations to support both practical lab work and theoretical exams. Now let’s test your knowledge with 50 MCQs on this topic.

Q1. What is the primary principle by which a fluid energy mill reduces particle size?

  • Mechanical impact from rotating hammers
  • Compression against a fixed surface
  • Particle–particle collisions driven by high velocity fluid jets
  • Abrasive action of grinding media

Correct Answer: Particle–particle collisions driven by high velocity fluid jets

Q2. Which of the following is NOT a main component of a fluid energy mill?

  • Nozzle or jet assembly
  • Grinding media like steel balls
  • Grinding chamber
  • Classifier or collector

Correct Answer: Grinding media like steel balls

Q3. Which fluid is most commonly used as the milling medium in pharmaceutical fluid energy mills?

  • High viscosity oil
  • Compressed air
  • Liquid nitrogen (always)
  • Hydraulic fluid

Correct Answer: Compressed air

Q4. The product particle size in a fluid energy mill is mainly controlled by which factor?

  • Nozzle diameter, gas pressure and classifier speed
  • Color of feed material
  • Type of grinding media
  • Temperature of the laboratory only

Correct Answer: Nozzle diameter, gas pressure and classifier speed

Q5. Why are fluid energy mills preferred for contamination-sensitive APIs?

  • They use inert ceramic grinding media
  • They have no moving mechanical parts that contact the product
  • They dissolve the API during milling
  • They coat particles with polymer during milling

Correct Answer: They have no moving mechanical parts that contact the product

Q6. Which material property makes a substance ideal for milling in a fluid energy mill?

  • High plasticity and ductility
  • High hardness and brittleness
  • Extremely elastic behavior
  • Very sticky and hygroscopic nature

Correct Answer: High hardness and brittleness

Q7. What is the role of the classifier in a fluid energy mill?

  • To add moisture to the product
  • To separate fine particles from coarse and control product size
  • To mechanically crush oversized particles
  • To heat the product before packaging

Correct Answer: To separate fine particles from coarse and control product size

Q8. Which operational parameter increases the degree of micronization in a fluid energy mill?

  • Decreasing gas pressure
  • Increasing feed particle size without changing other parameters
  • Increasing jet gas velocity (pressure)
  • Reducing nozzle number

Correct Answer: Increasing jet gas velocity (pressure)

Q9. A common advantage of fluid energy mills over ball mills is:

  • Lower energy consumption always
  • Absence of grinding media minimizing contamination
  • Ability to process highly plastic materials better
  • They are cheaper for large scale only

Correct Answer: Absence of grinding media minimizing contamination

Q10. Which statement about temperature control in a fluid energy mill is true?

  • Temperature never rises during milling
  • Temperature can rise due to compression and collisions; cooling mediums or chilled air may be required
  • Temperature is irrelevant for all APIs
  • Temperature is controlled by adding solvents

Correct Answer: Temperature can rise due to compression and collisions; cooling mediums or chilled air may be required

Q11. What is a primary demerit of using fluid energy mills?

  • They always cause chemical degradation
  • Relatively high energy consumption for very fine particles
  • They cannot produce submicron particles
  • They require large volumes of solvents

Correct Answer: Relatively high energy consumption for very fine particles

Q12. Which product characteristic is typically improved after milling with a fluid energy mill?

  • Bulk drug’s melting point
  • Particle size distribution and specific surface area
  • Chemical structure of API
  • Total solid content

Correct Answer: Particle size distribution and specific surface area

Q13. In a jet mill, what is the usual effect of increasing feed rate while keeping gas pressure constant?

  • Product becomes finer due to more collisions
  • Product tends to coarsen because residence time decreases and overloading occurs
  • It has no effect
  • It always improves product purity

Correct Answer: Product tends to coarsen because residence time decreases and overloading occurs

Q14. Which type of nozzle arrangement is commonly used in fluid energy mills for higher intensity?

  • Single static plate
  • Counter-jet or multiple opposing nozzles
  • Perforated rotating disk
  • Fixed abrasive strip

Correct Answer: Counter-jet or multiple opposing nozzles

Q15. Which of the following is a common application of fluid energy mills in pharmacy?

  • Wet granulation of tablets
  • Dry micronization of active pharmaceutical ingredients (APIs)
  • Sterile filtration of parenteral solutions
  • Coating tablet cores

Correct Answer: Dry micronization of active pharmaceutical ingredients (APIs)

Q16. How does particle hardness influence milling in a fluid energy mill?

  • Harder particles are harder to fracture, often requiring higher jet energy
  • Hardness has no effect
  • Softer particles always produce narrower PSD
  • Hard particles dissolve during milling

Correct Answer: Harder particles are harder to fracture, often requiring higher jet energy

Q17. Which of the following milling media is NOT used in a fluid energy mill?

  • Compressed air
  • Steam
  • Grinding beads
  • Inert gases like nitrogen

Correct Answer: Grinding beads

Q18. What is the effect of moisture in feed material for a fluid energy mill?

  • Moisture improves milling efficiency always
  • High moisture leads to agglomeration and poor milling performance
  • Moisture transforms the material chemically
  • Moisture has no effect on milling

Correct Answer: High moisture leads to agglomeration and poor milling performance

Q19. Which safety consideration is important when using a fluid energy mill with fine pharmaceutical powders?

  • Explosion risk due to dust and pressurized gas, requiring grounding and inerting when needed
  • No safety measures are necessary
  • Only radiation shielding is important
  • Only cryogenic hazards are present

Correct Answer: Explosion risk due to dust and pressurized gas, requiring grounding and inerting when needed

Q20. How does a fluid energy mill differ from a ball mill?

  • Fluid energy mill uses grinding media while ball mill does not
  • Fluid energy mill uses high-velocity jets and particle–particle collisions; ball mill uses tumbling grinding media
  • They are identical in principle
  • Ball mills are always used for gaseous products only

Correct Answer: Fluid energy mill uses high-velocity jets and particle–particle collisions; ball mill uses tumbling grinding media

Q21. Which parameter is adjusted to narrow the particle size distribution in a fluid energy mill?

  • Increase ambient humidity
  • Optimize classifier setting and jet energy
  • Eliminate the classifier entirely
  • Reduce inlet air filtration

Correct Answer: Optimize classifier setting and jet energy

Q22. Which of the following feed preparations may improve performance in fluid energy milling?

  • Agglomeration of feed into large lumps
  • Drying and pre-crushing to a controlled size range
  • Increasing oil content of feed
  • Mixing feed with sticky binders

Correct Answer: Drying and pre-crushing to a controlled size range

Q23. In scale-up of a fluid energy mill process, which factor is most critical?

  • Maintaining geometrically identical color schemes
  • Reproducing energy density and jet velocities to match particle dynamics
  • Using identical brand of compressed air
  • Mimicking operator schedules exactly

Correct Answer: Reproducing energy density and jet velocities to match particle dynamics

Q24. For heat-sensitive APIs, which modification can make fluid energy milling safer?

  • Use of chilled or cryogenic gases such as nitrogen or CO2
  • Increasing gas temperature intentionally
  • Adding water to the milling chamber
  • Using metallic grinding media

Correct Answer: Use of chilled or cryogenic gases such as nitrogen or CO2

Q25. What is a common downstream step after fluid energy milling for pharmaceutical powders?

  • Direct use without any handling
  • Classification, sieving, and collection to ensure desired PSD and remove fines or oversize
  • Immediate sterilization by heat
  • Mixing with large amounts of solvent

Correct Answer: Classification, sieving, and collection to ensure desired PSD and remove fines or oversize

Q26. Which measurement best assesses the efficiency of micronization in a fluid energy mill?

  • pH of the powder
  • Particle size distribution metrics like D50 and D90
  • Color index
  • Viscosity of the powder

Correct Answer: Particle size distribution metrics like D50 and D90

Q27. Why can fluid energy mills be preferable for sterile pharmaceutical powders?

  • They always sterilize the product during milling
  • Absence of internal moving parts reduces hard-to-clean crevices and cross-contamination
  • They produce large coarse particles ideal for sterile products
  • They use disposable grinding beads

Correct Answer: Absence of internal moving parts reduces hard-to-clean crevices and cross-contamination

Q28. What happens if nozzle diameter is reduced while keeping pressure constant?

  • Jet velocity decreases and milling reduces
  • Jet velocity increases leading to higher energy density and potentially finer particles
  • No change in milling
  • The classifier will become redundant

Correct Answer: Jet velocity increases leading to higher energy density and potentially finer particles

Q29. Which of the following is a merit of fluid energy milling?

  • High contamination from wear
  • Capability to achieve very narrow submicron distributions with proper settings
  • Low reproducibility
  • Requires large quantities of solvents

Correct Answer: Capability to achieve very narrow submicron distributions with proper settings

Q30. In a fluid energy mill, what is the typical effect of increasing the classifier speed?

  • Allows coarser particles to pass, making product coarser
  • Rejects more coarse particles, producing finer product
  • Has no influence on product size
  • Always increases product contamination

Correct Answer: Rejects more coarse particles, producing finer product

Q31. The most suitable feed particle size range for efficient fluid energy milling is generally:

  • Extremely coarse (>5 mm) without pre-crushing
  • Pre-crushed to a small, controlled range (e.g., <500 µm) depending on material
  • Liquid suspension only
  • Highly agglomerated cake form

Correct Answer: Pre-crushed to a small, controlled range (e.g., <500 µm) depending on material

Q32. Which property of powder can worsen during over-micronization (excessively fine particles)?

  • Increased flowability
  • Increased tendency to agglomerate and reduced flowability
  • Improved tableting without additives
  • No change in handling properties

Correct Answer: Increased tendency to agglomerate and reduced flowability

Q33. Which maintenance practice is important for consistent operation of a fluid energy mill?

  • Ignoring nozzle wear
  • Regular inspection and replacement of nozzles and seals, and cleaning of classifier and cyclone
  • Never cleaning the cyclone separator
  • Using abrasive grinding media to clean internal parts

Correct Answer: Regular inspection and replacement of nozzles and seals, and cleaning of classifier and cyclone

Q34. Why might inert gas (e.g., nitrogen) be used instead of air in fluid energy milling?

  • To increase oxygen content
  • To prevent oxidation or explosive atmospheres with combustible powders
  • To add moisture during milling
  • To dissolve the API

Correct Answer: To prevent oxidation or explosive atmospheres with combustible powders

Q35. Which is a typical sign of overloading a fluid energy mill?

  • Consistent production of finer particles
  • Drop in throughput without size reduction and increased coarser fraction
  • Immediate reduction in gas use
  • Perfectly stable classifier behavior

Correct Answer: Drop in throughput without size reduction and increased coarser fraction

Q36. How does particle shape often change after fluid energy milling?

  • Particles always become perfectly spherical
  • Particles tend to become more irregular and angular due to fracturing
  • Particles fuse into large rods
  • Shape remains identical to feed always

Correct Answer: Particles tend to become more irregular and angular due to fracturing

Q37. Which parameter would you monitor to detect nozzle wear affecting milling performance?

  • Ambient lab color
  • Pressure drop across nozzle and change in particle size distribution
  • Time of day
  • Humidity of operator’s hands

Correct Answer: Pressure drop across nozzle and change in particle size distribution

Q38. For hygroscopic materials, what precaution is recommended before fluid energy milling?

  • Increase moisture content intentionally
  • Dry the material thoroughly and maintain low humidity during milling
  • Add a sticky binder
  • Use only warm air to increase stickiness

Correct Answer: Dry the material thoroughly and maintain low humidity during milling

Q39. Which analytical technique is commonly used to evaluate PSD after fluid energy milling?

  • UV-Vis spectrophotometry only
  • Laser diffraction or dynamic light scattering
  • pH titration
  • Thin layer chromatography

Correct Answer: Laser diffraction or dynamic light scattering

Q40. Which of the following is a correct statement about residence time in a fluid energy mill?

  • Longer residence time always reduces energy consumption
  • Residence time influences extent of comminution and can be affected by feed rate and circulation
  • Residence time is irrelevant in jet milling
  • Residence time only affects color, not size

Correct Answer: Residence time influences extent of comminution and can be affected by feed rate and circulation

Q41. Which type of pharmaceutical substances are generally NOT suitable for fluid energy milling?

  • Brittle and crystalline APIs
  • Highly thermolabile and sticky/fatty substances without cryogenic support
  • Hard inorganic excipients
  • Glass beads

Correct Answer: Highly thermolabile and sticky/fatty substances without cryogenic support

Q42. What is a typical downstream collector used in jet milling to capture fine product?

  • Magnetic separator only
  • Cyclone separator followed by bag filter or electrostatic precipitator
  • Rotary evaporator
  • Centrifugal pump

Correct Answer: Cyclone separator followed by bag filter or electrostatic precipitator

Q43. How can particle adhesion to equipment surfaces be minimized during fluid energy milling?

  • Operate at high humidity
  • Apply appropriate anti-static measures and use coatings or inert gas
  • Use sticky binders in feed
  • Increase ambient temperature drastically

Correct Answer: Apply appropriate anti-static measures and use coatings or inert gas

Q44. Which energy form is primarily responsible for particle breakage in a fluid energy mill?

  • Chemical energy from reagents
  • Kinetic energy of particles imparted by high-velocity gas jets
  • Thermal energy only
  • Electrical energy in the powder

Correct Answer: Kinetic energy of particles imparted by high-velocity gas jets

Q45. Which control strategy improves reproducibility of particle size in routine milling?

  • Varying feed arbitrarily during shift
  • Standardizing feed pre-conditioning, gas pressure set points and classifier settings
  • Changing nozzle geometry daily
  • Ignoring maintenance

Correct Answer: Standardizing feed pre-conditioning, gas pressure set points and classifier settings

Q46. What is one environmental consideration when operating fluid energy mills at industrial scale?

  • They emit large volumes of solvent vapors
  • Large compressed air consumption and potential particulate emissions requiring filters and energy management
  • They always operate without any emissions
  • They only consume renewable energy

Correct Answer: Large compressed air consumption and potential particulate emissions requiring filters and energy management

Q47. If a product shows increased amorphization after jet milling, what is a possible consequence?

  • Decreased dissolution rate always
  • Potential increase in apparent solubility and dissolution rate, but also possible stability issues
  • Complete chemical inertness
  • No change in stability

Correct Answer: Potential increase in apparent solubility and dissolution rate, but also possible stability issues

Q48. Which maintenance check helps identify air leaks that reduce milling efficiency?

  • Visual inspection of product color
  • Leak testing of piping, fittings and seals and monitoring compressor pressure
  • Measuring tablet hardness
  • Checking pH of compressed air

Correct Answer: Leak testing of piping, fittings and seals and monitoring compressor pressure

Q49. Which terminology describes the median particle size commonly reported after milling?

  • D0 (zero)
  • D50 (median particle diameter)
  • PDI only
  • RPM

Correct Answer: D50 (median particle diameter)

Q50. For regulatory documentation, which information about fluid energy milling should be included in a pharmaceutical process file?

  • Only the brand name of the mill
  • Process parameters (pressure, feed rate, classifier settings), PSD data, maintenance records and cleaning validation
  • Only the color of the product
  • Only the operator’s name

Correct Answer: Process parameters (pressure, feed rate, classifier settings), PSD data, maintenance records and cleaning validation

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