Coating or coating (or by its English designation: coating) is an object that is re-coated with a substrate "Substrate (chemistry)"). In many cases they are carried out to improve some properties or qualities of the substrate surface, such as appearance, adhesion, wetting characteristics, corrosion resistance, wear resistance, and scratch resistance among many others. At other times, particularly in printing and manufacturing processes for semiconductor devices (in which the substrate is a disk of semiconductor material "Wafer (electronics)"), the coating is an essential part of the functionality of the finished product.
In other words, the action of covering a surface, such as a wall, with the purpose of protecting it or, as in this case, decorating it, is known as covering. In short, it is a layer or covering that is placed on a wall for decorative, protective or other purposes. Wall coverings can be placed on both interior walls and exterior spaces, such as building facades, terraces or gardens.
Coatings are applied through processes in the form of liquids, gases or solids. Coatings can be measured and tested to verify their characteristics and film thickness using cards for visual observation of color, opacity or contrast (drawdown cards).
Features
Coatings can serve to allow the treated surface to fulfill a number of functions. For example:.
List of techniques for coating application
Contenido
Esta lista contiene un resumen de las técnicas de recubrimiento utilizadas en el ámbito de la ciencia de materiales. Las técnicas se pueden clasificar de la siguiente forma:.
Laser deposition
Scientist Sebastián González postulated: The procedure consists of laser fusion of a metallic powder on a metallic substrate, forming a face in which both are mixed.
Concrete coating
Introduction
Coating or coating (or by its English designation: coating) is an object that is re-coated with a substrate "Substrate (chemistry)"). In many cases they are carried out to improve some properties or qualities of the substrate surface, such as appearance, adhesion, wetting characteristics, corrosion resistance, wear resistance, and scratch resistance among many others. At other times, particularly in printing and manufacturing processes for semiconductor devices (in which the substrate is a disk of semiconductor material "Wafer (electronics)"), the coating is an essential part of the functionality of the finished product.
In other words, the action of covering a surface, such as a wall, with the purpose of protecting it or, as in this case, decorating it, is known as covering. In short, it is a layer or covering that is placed on a wall for decorative, protective or other purposes. Wall coverings can be placed on both interior walls and exterior spaces, such as building facades, terraces or gardens.
Coatings are applied through processes in the form of liquids, gases or solids. Coatings can be measured and tested to verify their characteristics and film thickness using cards for visual observation of color, opacity or contrast (drawdown cards).
Features
Coatings can serve to allow the treated surface to fulfill a number of functions. For example:.
List of techniques for coating application
Contenido
Esta lista contiene un resumen de las técnicas de recubrimiento utilizadas en el ámbito de la ciencia de materiales. Las técnicas se pueden clasificar de la siguiente forma:.
The addition of material can be carried out at the same time as the application of the laser
or as a prior deposition.
If the material is predeposited before melting, when applying the laser, the material
The most superficial melt will slide over the unmelted until it reaches the substrate that
melts acting as a heat sink allowing rapid hardening
of the coating.
If coating is provided along with the laser beam, a portion of the beam energy
melts the particles in suspension and another the substrate, so the speed of
cooling is of the order of 104 K/s and the diffusion of the contribution in the substrate is
even less than if it is pre-deposited. This creates temperature gradients between the
front of molten material and the center that cause the movement of the fluid and therefore
both the homogenization of the coating.
We can distinguish two main types of laser depending on the geometry of the part
and the thickness of the coating:.
0.1 s is enough for the coating to reach homogeneity and solidify,
forming a fine-grained microstructure with characteristics much superior to
those formed in other coating processes.
The beam parameters that determine the coating process are:
It must be adapted to the absorptivity of the filler material so that the process
be reasonably efficient.
The minimum energy needed to melt the coating onto the surface
base is about 100W/mm² which represents a minimum beam power
of 2 kW. A lack of power causes incomplete fusion of the material and
weak coating, excess power results in excessive melting
of the base substrate and the dissolution of the filler material in it. a beam
Continuously improves the material coverage rate.
To avoid possible damage from splashes, mirrors are used instead of lenses.
because they allow greater beam separation by increasing the length
focal. Oscillating mirrors are used to achieve a distribution beam
of uniform intensity since it influences the thickness of the coating.
Heating pattern:
The most appropriate energy source for large thickness coatings
uniform is one with a wide and regular distribution of heat. They are
appreciable transitory effects at the beginning and end of the process, which
Preheating of the material is necessary.
The coating speed is generally higher than for treatments
superficial thermal effects since the material is provided in the form of powder. The
transverse speed in inverse proportion to the thickness of the coating.
The condition that the filler material and the base piece must meet to
Being able to apply this technique is that they are weldable. Due to the rapid solidification
of the coating, a strong metallic bond is formed between it and the base, although
with minimal mixing (< 5%) of the filler material in the base substrate.
The most common base materials are carbon, alloy, and tool steels.
and stainless. Alloys of aluminum, magnesium,
iron and nickel-based superalloys.
The most common filler materials are alloys of cobalt, chromium, carbon,
steel, silicon and nickel. Elements with an atomic radius are also added
large as tungsten and molybdenum to give hardness to the reticular structure.
Coatings are also made in which the base material and the filler material
belong to different categories, although in these cases the process conditions
They are very critical to achieving a strong enough bond.
It is used in case the base substrate or filler material is susceptible
of oxidation. The most used gas is argon although it is also
You can use nitrogen. One of the most critical problems in the process
are the oversights when designing the geometry of the material contribution and
protection gas conduction and dust transport systems
of contribution.
It is critical if you need to cover large surfaces since it optimizes the
process speed.
There are two main reasons for this: To avoid cracking of the coating
and increase the dissolution of the coating in the substrate by
composition motifs. Preheating is carried out in ovens and
allows many more ferrous alloys to be used as substrates than otherwise.
be realized. A controlled cooling of the piece is also carried out in case
risk of cracking. Post heat treatment:
It is necessary when depositing very extensive and thick coatings.
considerable, in which residual tensions will remain.
The coatings can be shot peened after deposition to induce
residual compression stresses and improve fatigue resistance. After
This treatment the piece practically meets the dimensional specifications
and required roughness.
Signals from the laser-coating interaction zone are recorded,
where data can be obtained on the links between the coating
and the piece, porosity, hardness of the coating, thickness and defects in the
substrate.
Advantages of laser coating:.
Disadvantages of laser coating:.
Method of manufacturing thin films of various materials. It consists of the application of short high-energy pulses on a filler material, generally ceramic, enclosed in a high vacuum chamber. The ceramic material is detached and deposited on a substrate, covering it as a thin film. The number of pulses can be adjusted to achieve different thicknesses of
material. In an ideal case, the laser pulses should have a short wavelength, that is, in the ultraviolet spectrum. Therefore, an excimer laser is used for these applications. Pulses of several nanoseconds are sufficient for non-thermal detachment of the filler material without changes in its composition. It is of great interest especially in the manufacture of high temperature superconductors and magnetic materials.
Others
They can basically be classified into two types: wood veneers and plastic coatings. When wooden veneers are used, we speak of veneered boards and when plastic coatings are used, we speak of coated boards.
They can basically be classified into three types: concrete coatings, wood veneers and plastic coatings. When wooden veneers are used, we speak of veneered boards and when plastic coatings are used, we speak of coated boards.
Coatings are mainly used to finish particle and fiber boards. Both sides of the board should be covered with the same coating or with coatings with similar behavior to prevent imbalances in the board that could cause it to warp.
Laser deposition
Scientist Sebastián González postulated: The procedure consists of laser fusion of a metallic powder on a metallic substrate, forming a face in which both are mixed.
The addition of material can be carried out at the same time as the application of the laser
or as a prior deposition.
If the material is predeposited before melting, when applying the laser, the material
The most superficial melt will slide over the unmelted until it reaches the substrate that
melts acting as a heat sink allowing rapid hardening
of the coating.
If coating is provided along with the laser beam, a portion of the beam energy
melts the particles in suspension and another the substrate, so the speed of
cooling is of the order of 104 K/s and the diffusion of the contribution in the substrate is
even less than if it is pre-deposited. This creates temperature gradients between the
front of molten material and the center that cause the movement of the fluid and therefore
both the homogenization of the coating.
We can distinguish two main types of laser depending on the geometry of the part
and the thickness of the coating:.
0.1 s is enough for the coating to reach homogeneity and solidify,
forming a fine-grained microstructure with characteristics much superior to
those formed in other coating processes.
The beam parameters that determine the coating process are:
It must be adapted to the absorptivity of the filler material so that the process
be reasonably efficient.
The minimum energy needed to melt the coating onto the surface
base is about 100W/mm² which represents a minimum beam power
of 2 kW. A lack of power causes incomplete fusion of the material and
weak coating, excess power results in excessive melting
of the base substrate and the dissolution of the filler material in it. a beam
Continuously improves the material coverage rate.
To avoid possible damage from splashes, mirrors are used instead of lenses.
because they allow greater beam separation by increasing the length
focal. Oscillating mirrors are used to achieve a distribution beam
of uniform intensity since it influences the thickness of the coating.
Heating pattern:
The most appropriate energy source for large thickness coatings
uniform is one with a wide and regular distribution of heat. They are
appreciable transitory effects at the beginning and end of the process, which
Preheating of the material is necessary.
The coating speed is generally higher than for treatments
superficial thermal effects since the material is provided in the form of powder. The
transverse speed in inverse proportion to the thickness of the coating.
The condition that the filler material and the base piece must meet to
Being able to apply this technique is that they are weldable. Due to the rapid solidification
of the coating, a strong metallic bond is formed between it and the base, although
with minimal mixing (< 5%) of the filler material in the base substrate.
The most common base materials are carbon, alloy, and tool steels.
and stainless. Alloys of aluminum, magnesium,
iron and nickel-based superalloys.
The most common filler materials are alloys of cobalt, chromium, carbon,
steel, silicon and nickel. Elements with an atomic radius are also added
large as tungsten and molybdenum to give hardness to the reticular structure.
Coatings are also made in which the base material and the filler material
belong to different categories, although in these cases the process conditions
They are very critical to achieving a strong enough bond.
It is used in case the base substrate or filler material is susceptible
of oxidation. The most used gas is argon although it is also
You can use nitrogen. One of the most critical problems in the process
are the oversights when designing the geometry of the material contribution and
protection gas conduction and dust transport systems
of contribution.
It is critical if you need to cover large surfaces since it optimizes the
process speed.
There are two main reasons for this: To avoid cracking of the coating
and increase the dissolution of the coating in the substrate by
composition motifs. Preheating is carried out in ovens and
allows many more ferrous alloys to be used as substrates than otherwise.
be realized. A controlled cooling of the piece is also carried out in case
risk of cracking. Post heat treatment:
It is necessary when depositing very extensive and thick coatings.
considerable, in which residual tensions will remain.
The coatings can be shot peened after deposition to induce
residual compression stresses and improve fatigue resistance. After
This treatment the piece practically meets the dimensional specifications
and required roughness.
Signals from the laser-coating interaction zone are recorded,
where data can be obtained on the links between the coating
and the piece, porosity, hardness of the coating, thickness and defects in the
substrate.
Advantages of laser coating:.
Disadvantages of laser coating:.
Method of manufacturing thin films of various materials. It consists of the application of short high-energy pulses on a filler material, generally ceramic, enclosed in a high vacuum chamber. The ceramic material is detached and deposited on a substrate, covering it as a thin film. The number of pulses can be adjusted to achieve different thicknesses of
material. In an ideal case, the laser pulses should have a short wavelength, that is, in the ultraviolet spectrum. Therefore, an excimer laser is used for these applications. Pulses of several nanoseconds are sufficient for non-thermal detachment of the filler material without changes in its composition. It is of great interest especially in the manufacture of high temperature superconductors and magnetic materials.
Others
They can basically be classified into two types: wood veneers and plastic coatings. When wooden veneers are used, we speak of veneered boards and when plastic coatings are used, we speak of coated boards.
They can basically be classified into three types: concrete coatings, wood veneers and plastic coatings. When wooden veneers are used, we speak of veneered boards and when plastic coatings are used, we speak of coated boards.
Coatings are mainly used to finish particle and fiber boards. Both sides of the board should be covered with the same coating or with coatings with similar behavior to prevent imbalances in the board that could cause it to warp.