The vacuum oven is an essential tool used in laboratories and industrial settings for drying, curing, and heat treatment processes under reduced pressure conditions. This topic holds great importance due to its wide range of applications in various fields such as materials science, pharmaceuticals, and electronics. The vacuum oven allows for the gentle and controlled removal of moisture or volatile substances from sensitive samples without subjecting them to high temperatures or oxidative conditions.

By discussing the vacuum oven, we gain insights into its principles, functionalities, and advancements, which contribute to improved product quality, stability, and manufacturing efficiency. Exploring the topic of the vacuum oven is crucial for researchers, engineers, and manufacturers seeking reliable and precise methods for low-temperature drying and processing of sensitive materials.

A vacuum oven, or vacuum drying oven, is primarily used to expedite the drying process by employing vacuum and heat. As the pressure decreases, the boiling point of the solvent also decreases, allowing the vacuum oven to remove moisture and volatile substances at lower temperatures. Furthermore, since air is removed from the vacuum oven, heat transfer inside becomes more efficient. By reducing the levels of oxygen (O2) and moisture, the drying efficiency is enhanced while the risks of oxidation and explosion are mitigated. Some vacuum ovens can even be equipped with inert gases like nitrogen (N2) or helium (He) to prevent oxidation, corrosion, or scaling.

The advantages of a vacuum oven can be summarized as follows:

Reduction of solvent boiling point, enabling lower heating temperatures. This makes it suitable for processing heat-sensitive and volatile substances.

Minimization of oxidation, making it suitable for handling flammable and explosive substances.

Increased drying efficiency through improved heat transfer and the removal of oxygen and moisture.

The most common vacuum oven applications include:

Moisture Removal: One of the primary functions of vacuum ovens is to remove moisture from equipment or pharmaceutical products, particularly when dealing with fragile or temperature-sensitive items like microchips and pharmaceuticals. Porous objects, in particular, tend to retain moisture within their pores, leading to potential product damage and failure. Vacuum ovens can effectively and gently eliminate moisture, thus preventing such product failures.

Off-Gassing / Outgassing: Sealants and lubricants used in certain metal components can often release moisture or chemical vapors. These residues have the potential to cause product or electronic component failure. Vacuum ovens play a crucial role in removing moisture and chemical residues through a process known as off-gassing or outgassing, as referred to in ASTM E595 standards for outgassing in a vacuum environment.

Prevent Oxidation: By controlling the temperature and vacuum level, vacuum ovens can effectively prevent oxidation, corrosion, or scaling. This feature is particularly important in the pharmaceutical industry, where oxidation can compromise product quality.

Bake-Out & Degassing: Bake-out involves increasing the temperature inside the vacuum oven to force volatile chemicals out of the objects being treated. Since the oxidization reaction is effectively controlled within the vacuum oven, these chemicals can be removed more safely and efficiently. Bake-out is also utilized for degassing, as heated liquids release gases in the form of bubbles, which can then be captured and removed by the vacuum system.

Due to the aforementioned reasons, vacuum ovens find wide application in various industries, including electronics, semiconductor, aerospace, and pharmaceuticals. Additionally, the ability to dry objects at lower temperatures makes vacuum ovens valuable in the food industry, where high temperatures may lead to nutrient loss or food deterioration. For further information on drying methods, please refer to CNS 5033 “Methods for the Examination of Moisture in Food.”

Vacuum ovens are suitable for treating the following objects due to their ability to dry at lower temperatures:

Heat-sensitive substances: This includes fruits and vegetables, enzymes, microorganisms, antibiotics, and other sensitive materials that may degrade or lose their efficacy at higher temperatures.

Objects that are difficult to dry: Vacuum ovens are effective in drying powdery or granular substances that may clump together or form lumps when subjected to traditional drying methods.

Flammable or explosive substances: While caution must be exercised when dealing with flammable or explosive substances, vacuum ovens can be used for their drying. However, it is crucial to choose a vacuum oven that is certified as explosion-proof, such as those compliant with ATEX, IECEx, or Hazloc standards, to ensure safety during the drying process.

A high-temperature oven operates by heating objects under normal pressure. Fans are commonly utilized to circulate hot air throughout the chamber, facilitating the drying process.

In contrast, a microwave dryer differs from a vacuum oven primarily in its heating principle. It employs microwave radiation to generate heat energy within a vacuum environment. While the scope of applications may overlap with vacuum drying, the appropriate drying method should be chosen based on the specific characteristics of the sample.

Drying device

Vacuum oven

Hi-temp oven

Microwave dryer

Heat generation

Heat convection/Heat radiation

Heat convection

Microwave radiation

Heating principle

Vacuum lowers liquid boiling point and accelerate evaporation

Heat with fan circulation

Vacuum lowers liquid boiling point and accelerate evaporation

Heating temperature

Low

High

Low

Heating efficiency

High

Lower

Very high

Appropriate  for substances

Heat sensitive substances

Easily-oxidized substances

Difficult-to-dry substances

Flammable/explosive substances

Light-weighted substances

General substances

Heat sensitive substances

Easily oxidized samples

Decomposable samples

Light weight sample

Applications

Chemistry, biology, medicine, precision materials, food, aerospace

Food, agriculture, environment

Food (mainly), chemistry, biology, medicine

Vacuum ovens are generally equipped with a vacuum pump to achieve the required vacuum in its chamber, as well as several other devices depending on the applications.

Oven volume

Suggested pump model

Air flow

(L/min)

Max. vacuum

(mbar)

General objects

< 15 L

DC Chem 610 Pro

37

7

Rocker 410

23

25

< 30 L

Rocker 911

65

25

< 60 L

Rocker 901

120

85

Tanker 150

142

1.3 x 10-1

Tanker 230

85

6.6 x 10-2

Chemicals (solvents, acids)

< 15 L

DC Chem 610 Pro

37

7

Chemker 410 / 411

20

10

Chemker 610 / 611

34

7

Rocker 910C

37

15

< 30 L

Chemker 600

65

65

Rocker 900C

60

99

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