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How long does it take for liquid silicone to cure?

Author: Justin

Sep. 09, 2024

47 0 0

Tags: Chemicals

Curing (chemistry) - Wikipedia

Chemical process by which polymeric materials are hardened

Goto OSi Silicone to know more.

Curing is a chemical process employed in polymer chemistry and process engineering that produces the toughening or hardening of a polymer material by cross-linking of polymer chains.[1] Even if it is strongly associated with the production of thermosetting polymers, the term "curing" can be used for all the processes where a solid product is obtained from a liquid solution, such as with PVC plastisols.[2]

Curing process

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Figure 1: Structure of a cured epoxy glue. The triamine hardener is shown in red, the resin in black. The resin's epoxide groups have reacted with the hardener. The material is highly crosslinked and contains many OH groups, which confer adhesive properties.

During the curing process, single monomers and oligomers, mixed with or without a curing agent, react to form a tridimensional polymeric network.[3]

In the very first part of the reaction branches of molecules with various architectures are formed, and their molecular weight increases in time with the extent of the reaction until the network size is equal to the size of the system. The system has lost its solubility and its viscosity tends to infinite. The remaining molecules start to coexist with the macroscopic network until they react with the network creating other crosslinks. The crosslink density increases until the system reaches the end of the chemical reaction.[3]

Curing can be induced by heat, radiation, electron beams, or chemical additives. To quote from IUPAC: curing "might or might not require mixing with a chemical curing agent".[1] Thus, two broad classes are curing induced by chemical additives (also called curing agents, hardeners) and curing in the absence of additives. An intermediate case involves a mixture of resin and additives that requires external stimulus (light, heat, radiation) to induce curing.

The curing methodology depends on the resin and the application. Particular attention is paid to the shrinkage induced by the curing. Usually small values of shrinkage (2&#;3%) are desirable.[2]

Curing induced by additives

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Figure 2: General representation of the chemical structure of vulcanized natural rubber showing the crosslinking of two polymer chains (

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) with sulfur (n = 0, 1, 2, 3 &#;). Figure 3: Simplified chemical reactions associated with curing of a drying oil. In the first step, the diene undergoes autoxidation to give a hydroperoxide. In the second step, the hydroperoxide combines with another unsaturated side chain to generate a crosslink.

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Epoxy resins are typically cured by the use of additives, often called hardeners. Polyamines are often used. The amine groups ring-open the epoxide rings.

In rubber, the curing is also induced by the addition of a crosslinker. The resulting process is called sulfur vulcanization. Sulfur breaks down to form polysulfide cross-links (bridges) between sections of the polymer chains. The degree of crosslinking determines the rigidity and durability, as well as other properties of the material.[5]

Paints and varnishes commonly contain oil drying agents, usually metallic soaps that catalyze cross-linking of the unsaturated drying oils that largely comprise them. When paint is described as "drying" it is in fact hardening by crosslinking. Oxygen atoms serve as the crosslinks, analogous to the role played by sulfur in the vulcanization of rubber.[citation needed]

Curing without additives

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In the case of concrete, curing entails the formation of silicate crosslinks. The process is not induced by additives.

In many cases, the resin is provided as a solution or mixture with a thermally-activated catalyst, which induces crosslinking but only upon heating. For example, some acrylate-based resins are formulated with dibenzoyl peroxide. Upon heating the mixture, the peroxide converts to a free radical, which adds to an acrylate, initiating crosslinking.

Some organic resins are cured with heat. As heat is applied, the viscosity of the resin drops before the onset of crosslinking, whereupon it increases as the constituent oligomers interconnect. This process continues until a tridimensional network of oligomer chains is created &#; this stage is termed gelation. In terms of processability of the resin this marks an important stage: before gelation the system is relatively mobile, after it the mobility is very limited, the micro-structure of the resin and the composite material is fixed and severe diffusion limitations to further cure are created. Thus, in order to achieve vitrification in the resin, it is usually necessary to increase the process temperature after gelation.

When catalysts are activated by ultraviolet radiation, the process is called UV cure.[6]

Monitoring methods

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Cure monitoring is, for example, an essential component for the control of the manufacturing process of composite materials. The material, initially liquid, at the end of the process will be solid: viscosity is the most important property that changes during the process.

Cure monitoring relies on monitoring various physical or chemical properties.

Rheological analysis

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Figure 4: Evolution in time of storage modulus G' and loss modulus G" during a curing reaction.

A simple way to monitor the change in viscosity, and thus, the extent of the reaction, in a curing process is to measure the variation of the elastic modulus.[7]

To measure the elastic modulus of a system during curing, a rheometer can be used.[7] With dynamic mechanical analysis, the storage modulus (G') and the loss modulus (G) can be measured. The variation of G' and G" in time can indicate the extent of the curing reaction.[7]

As shown in Figure 4, after an "induction time", G' and G" start to increase, with an abrupt change in slope. At a certain point they cross each other; afterwards, the rates of G' and G" decrease, and the moduli tend to a plateau. When they reach the plateau the reaction is concluded.[3]

When the system is liquid, the storage modulus is very low: the system behaves like a liquid. Then the reaction continues and the system starts to react more like a solid: the storage modulus increases.

The degree of curing, α {\displaystyle \alpha } , can be defined as follow:[8]

α = G &#; ( t ) &#; G m i n &#; G m a x &#; &#; G m i n &#; {\displaystyle \alpha ={\frac {G'(t)-G'_{min}}{G'_{max}-G'_{min}}}} [8]

The degree of curing starts from zero (at the beginning of the reaction) and grows until one (the end of the reaction). The slope of the curve changes with time and has his maximum about at half of the reaction.

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Thermal analysis

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If the reactions occurring during crosslinking are exothermic, the crosslinking rate can be related to the heat released during the process. Higher is the number of bonds created, higher is the heat released in the reaction. At the end of the reaction, no more heat will be released. To measure the heat flow differential scanning calorimetry can be used.[9]

Assuming that each bond formed during the crosslinking releases the same amount of energy, the degree of curing, α {\displaystyle \alpha } , can be defined as follows:[9]

α = Q Q T = &#; 0 s Q ˙ d t &#; 0 s f Q ˙ d t {\displaystyle \alpha ={\frac {Q}{Q_{T}}}={\frac {\int _{0}^{s}{\dot {Q}}\,dt}{\int _{0}^{s_{f}}{\dot {Q}}\,dt}}} [9]

where Q {\displaystyle Q} is the heat released up to a certain time s {\displaystyle s} , Q ˙ {\displaystyle {\dot {Q}}} is the instantaneous rate of heat and Q T {\displaystyle Q_{T}} is the total amount of heat released in s f {\displaystyle s_{f}} , when the reaction finishes.[9]

Also in this case the degree of curing goes from zero (no bonds created) to one (no more reactions occur) with a slope that changes in time and has its maximum about at half of the reaction.[9]

Dielectrometric analysis

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Conventional dielectrometry is carried out typically in a parallel plate configuration of the dielectric sensor (capacitance probe) and has the capability of monitoring the resin cure throughout the entire cycle, from the liquid to the rubber to the solid state. It is capable of monitoring phase separation in complex resin blends curing also within a fibrous perform. The same attributes belong to the more recent development of the dielectric technique, namely microdielectrometry.

Several versions of dielectric sensors are available commercially. The most suitable format for use in cure monitoring applications are the flat interdigital capacitive structures bearing a sensing grid on their surface. Depending on their design (specifically those on durable substrates) they have some reusability, while flexible substrate sensors can be used also in the bulk of the resin systems as embedded sensors.

Spectroscopic analysis

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The curing process can be monitored by measuring changes in various parameters:

Ultrasonic analysis

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Ultrasonic cure monitoring methods are based on the relationships between changes in the characteristics of propagating ultrasound and the real-time mechanical properties of a component, by measuring:

  • ultrasonic time of flight, both in through-transmission and pulse-echo modes;
  • natural frequency using impact excitation and laser-induced surface acoustic wave velocity measurement.

See also

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References

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How Long Does Silicone Sealant Takes To Cure?

Silicone sealant is a popular adhesive used in various applications, from household repairs to industrial projects. Understanding its curing time is crucial to ensure optimal bonding and effectiveness. Contrary to the misconception that AI drives every explanation, let&#;s delve into the science behind silicone sealant curing.

The Basics of Silicone Sealant Curing

Silicone sealants consist of silicone polymers, additives, and curing agents. The curing process involves the transformation of the liquid of the dental sealants near you into a solid, rubber-like material. This transformation occurs through a chemical reaction initiated by the moisture in the air, commonly known as curing by atmospheric humidity.

Factors Affecting Curing Time

  1. Type of Silicone Sealant: Different types of silicone sealants exist, such as acetone cure (acid cure) and neutral cure. Acetoxy cure sealants usually cure faster, within 24 hours, emitting an acetic acid odour during the process. Neutral cure sealants take longer, typically 48 hours, and emit no strong odours.
  2. Thickness of Application: The thickness of the applied sealant layer significantly impacts curing time. Thicker layers take longer to heal, hindering the moisture penetration needed for curing.
  3. Environmental Conditions: Temperature and humidity play crucial roles in silicone sealant curing. Optimal curing occurs at temperatures between 40°F and 100°F (5°C to 38°C) with humidity levels above 40%. Extreme temperatures or arid conditions can prolong the curing process.
  4. Ventilation: Proper ventilation aids in moisture distribution, facilitating the curing process. In poorly ventilated areas, curing might take longer due to the lack of moisture exchange.

Curing Stages

Skin Formation: Within 10&#;20 minutes after application by a dentist in West Roxbury, a thin skin or film forms on the surface of the sealant. However, the sealant underneath remains uncured.

Initial Cure: The sealant gradually starts to cure and becomes touch-dry within 24 hours for most standard silicone sealants.

Complete Cure: While the initial cure might occur within a day, achieving a comprehensive treatment and maximum strength can take up to 48 hours or more, depending on the factors above.

Tips for Optimal Curing

  1. Prepare Surfaces: Ensure surfaces are clean, dry, and contaminant-free before applying silicone sealant. Use appropriate cleaning agents to enhance adhesion.
  2. Proper Thickness: Apply the sealant in an even layer of the recommended thickness. Avoid excessive application, as it might prolong curing.
  3. Ideal Environmental Conditions: If possible, apply the adhesive at moderate temperatures and humidity levels for optimal curing.
  4. Patience: Allow sufficient time for the sealant to cure completely before exposing it to stress or moisture.

Testing for Cure

To check if the silicone sealant has cured completely, gently press the surface with a finger. It has likely been fixed if it feels firm and no indentation remains. Avoid subjecting it to heavy use or stress until the entire curing period has elapsed, as recommended by a dentist near you.

Summary Notes

The curing time for silicone sealant varies based on multiple factors, including the sealant type, application thickness, environmental conditions, and ventilation. While a general guideline of 24-48 hours exists for most sealants to achieve a complete cure, understanding these influencing factors is essential for effectively utilizing silicone sealants in diverse applications.

Remember, a patient approach and adherence to manufacturer recommendations regarding curing times and application techniques are vital for ensuring the durability and effectiveness of silicone sealants in your projects.

In a world often reliant on AI, grasping fundamental knowledge without technological assistance can foster a deeper understanding of various subjects, such as the intricate process of silicone sealant curing.

Nine One Dental Group Offers Tailor-Made Dental Sealants And Helps You Recover Quickly

At Nine One Dental Group, personalized care is our cornerstone. Our tailored dental sealants are meticulously crafted to suit individual needs, ensuring optimal protection against decay and damage.

With a keen focus on your specific oral health requirements, our team delivers precision and expertise in applying these sealants, promoting swift recovery and enhanced oral hygiene. We prioritize your comfort and recovery speed, utilizing advanced techniques and materials to safeguard your dental well-being.

Experience the difference of custom-designed dental sealants in West Roxbury at Nine One Dental Group, where your smile&#;s health is our top priority.

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