Unlock the secrets of using water-based titanium dioxide dispersants and start a journey of efficient production
Unlock the secrets of using water-based titanium dioxide dispersants and start a journey of efficient production
In many industrial fields such as coatings, papermaking, and plastics, titanium dioxide is a key raw material for improving product whiteness, hiding power, and gloss. However, when titanium dioxide is used in water-based systems, the dispersion problem often gives producers a headache. The emergence of water-based titanium dioxide dispersants has brought hope for solving this problem. But to give full play to its role, correct use is essential. Here is a detailed introduction to the use of water-based titanium dioxide dispersants.
Before use: Know yourself and the enemy, and make careful preparations
Understand the characteristics of titanium dioxide and the system
Different titanium dioxides differ in particle size, crystal form, surface properties, etc. For example, rutile titanium dioxide has good weather resistance, while anatase titanium dioxide has higher whiteness but slightly worse weather resistance. At the same time, the pH value, ionic strength, and solvent type of the water-based system will also affect the effect of the dispersant. For example, in a strong acid or alkaline system, some dispersants may hydrolyze or denature and lose their dispersing ability. Therefore, before using a dispersant, you must fully understand the characteristics of titanium dioxide and the composition of the aqueous system in order to choose a suitable dispersant.
Choose a suitable dispersant
There are many types of aqueous titanium dioxide dispersants on the market, including anionic, cationic, nonionic and amphoteric. Anionic dispersants are suitable for neutral or alkaline systems, and can form negative charges on the surface of titanium dioxide particles to produce electrostatic repulsion; cationic dispersants are suitable for acidic systems; nonionic dispersants are not affected by the pH value of the system and have good versatility; amphoteric dispersants combine the characteristics of anions and cations and have a wider range of applications. Choose the most suitable dispersant based on the specific conditions of titanium dioxide and the aqueous system.
Determine the appropriate dosage
The dosage of dispersant is not the more the better. Too little dosage cannot effectively disperse titanium dioxide; too much dosage may increase the viscosity of the system, increase the foam, and even affect the performance of the product. Generally speaking, the optimal dosage can be determined through small-scale experiments. Take a certain amount of titanium dioxide and aqueous medium, conduct dispersion experiments according to different dispersant dosage ratios, observe the dispersion state of titanium dioxide, the viscosity change of the system, and the performance of the final product, so as to find the most suitable dispersant dosage.
Prepare equipment and environment
Appropriate dispersion equipment can improve dispersion efficiency and quality. Common dispersion equipment includes high-speed mixers, sand mills, ball mills, etc. For titanium dioxide with coarse particles and easy dispersion, a high-speed mixer may be sufficient; for titanium dioxide with fine particles and easy agglomeration, a sand mill or ball mill is required for more fine dispersion. In addition, the temperature and humidity of the dispersion environment will also affect the dispersion effect. Generally speaking, dispersing operations at appropriate temperatures can improve the activity of the dispersant and the dispersibility of titanium dioxide. For example, in a low temperature environment, the viscosity of the dispersant may increase and the fluidity may deteriorate, thereby affecting its dispersion effect.
In use: standard operation, precise control
The order of addition is particular
The order of adding dispersants has an important influence on the dispersion effect. There are usually two ways of adding: one is to mix the dispersant and titanium dioxide evenly first, and then add it to the aqueous medium for dispersion; the other is to dissolve the dispersant in the aqueous medium first, and then add titanium dioxide for dispersion. For some titanium dioxide that is easy to absorb moisture or react chemically with the dispersant, the latter method is recommended to avoid agglomeration or deterioration of titanium dioxide before dispersion.
Control dispersion process parameters
Stirring speed and time: If the stirring speed is too slow, it cannot provide enough energy to disperse the titanium dioxide particles; if the stirring speed is too fast, it may generate too much heat, causing the dispersant to fail or titanium dioxide to deteriorate. Generally speaking, you can stir at a lower speed for a period of time to initially mix the titanium dioxide and the dispersant, and then gradually increase the stirring speed for full dispersion. The dispersion time should also be adjusted according to the properties of the titanium dioxide and the medium, and usually experiments are required to determine the optimal dispersion time.
Temperature control: Temperature has a significant effect on the dispersion effect. During the dispersion process, try to keep the temperature stable. If the temperature is too high, the dispersant may decompose or volatilize, reducing its dispersibility; if the temperature is too low, the viscosity of the system will increase and dispersion will be difficult. The temperature of the dispersion system can be controlled by a cooling device or a heating device.
Real-time monitoring and adjustment
During the dispersion process, the dispersion state of titanium dioxide and the performance of the system should be monitored in real time. The uniformity of the dispersion of titanium dioxide and whether there are agglomerates or precipitation can be observed visually; the size and distribution of titanium dioxide particles can also be measured using instruments such as a particle size analyzer. If the dispersion effect is not ideal, the amount of dispersant, stirring speed, temperature and other parameters should be adjusted in time until a satisfactory dispersion effect is achieved.
After use: Proper handling to ensure quality
Filtration and defoaming
After the dispersion is completed, there may be some undispersed titanium dioxide particles or foam in the system. In order to obtain high-quality products, filtration and defoaming treatment are required. Filters, filter cloths and other equipment can be used for filtration to remove larger titanium dioxide particles and impurities; defoaming can be done by vacuum defoaming, adding defoaming agents and other methods to eliminate foam in the system and improve the appearance quality and performance of the product.
Storage and stability maintenance
The dispersed titanium dioxide system also needs to pay attention to some issues during storage. Choose a suitable storage container to avoid chemical reactions between the container and titanium dioxide or dispersant. At the same time, the container should be sealed to prevent air, moisture, etc. from entering and affecting the stability of the product. The storage environment should be kept dry and cool, avoiding direct sunlight and high temperature environment. Generally speaking, the storage temperature should not be too high to avoid dispersant failure or titanium dioxide agglomeration.
Regular testing and optimization
During storage, the product should be tested regularly to check whether the dispersion state of titanium dioxide, the viscosity of the system, color and other properties have changed. If the product is found to be abnormal, such as precipitation of titanium dioxide, lightening of color, etc., timely measures should be taken to deal with it, such as re-dispersion or adjustment of the formula.
The use of water-based titanium dioxide dispersants is a systematic project. From preparation before use to operation during use, to maintenance after use, every link needs to be taken seriously. Only by mastering the correct method of use can the role of the dispersant be fully exerted, so that titanium dioxide can show the best performance in the water-based system, bringing higher efficiency and quality to industrial production. I hope the above usage suggestions can help you better control water-based titanium dioxide dispersants and create better quality products.