HPMC for gypsum

Hydroxypropyl Methylcellulose (HPMC) is a key additive used in a variety of building materials, and its role in gypsum-based products is especially crucial. Gypsum, widely used in construction for plastering, drywall, and other applications, requires specific properties to ensure ease of use and durability. HPMC is introduced into gypsum formulations to enhance several characteristics, making it an indispensable component in modern construction.

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What is HPMC

HPMC is a chemically modified cellulose derivative with unique properties. It is highly soluble in water, forming a transparent gel or solution at low concentrations. HPMC is widely used in industries ranging from pharmaceuticals to construction due to its multifunctional nature. In the construction industry, its application in gypsum-based products like plaster, putty, and dry mortar is well-established.

Applications of HPMC in Gypsum-Based Products

Gypsum Plaster: In plastering applications, HPMC ensures smoother application, better adhesion, and enhanced water retention, which leads to improved durability.

Gypsum Putty: For finer finishing, HPMC improves the spreadability and ensures a smooth finish, reducing the need for extensive sanding.

Drywall Joint Compounds: HPMC enhances the consistency and spreadability of joint compounds, making it easier to fill gaps and seams between drywall sheets.

Gypsum-Based Mortars: In mortars, HPMC helps improve the strength and adhesion properties, especially in situations where the substrate might be challenging to bond to.

Hydroxypropyl methylcellulose (HPMC) plays a significant role in gypsum, offering several beneficial properties that enhance their performance. Let's explore the role of HPMC in gypsum in relation to good water retention, excellent thickening effect, better workability, anti-sagging, and longer open time:

1. Good Water Retention: HPMC in gypsum formulations demonstrates excellent water retention properties. It forms a gel-like structure when in contact with water, effectively trapping and holding water molecules. This property helps to maintain an adequate moisture level in the gypsum mixture, preventing premature drying and ensuring optimal hydration. Good water retention contributes to improved workability, extended open time, and reduced shrinkage in gypsum-based materials.

2. Excellent Thickening Effect: HPMC acts as a highly effective thickener in gypsum-based products. When added to the mixture, it disperses and swells, increasing the viscosity of the material. This thickening effect imparts a desirable consistency to the gypsum mixture, making it easier to handle and apply. It also helps to prevent excessive sagging or running of the material, ensuring that it adheres well to vertical surfaces and maintains its desired shape.

3. Better Workability: The presence of HPMC significantly improves the workability of gypsum-based materials. The thickening effect of HPMC contributes to a smoother and more easily spreadable consistency, facilitating application and reducing the effort required during installation. This enhanced workability allows for better control and manipulation of the material, resulting in improved finishing and surface quality.

4. Anti-Sagging: HPMC is effective in preventing sagging or slumping of gypsum-based materials. The thickened consistency achieved with HPMC ensures that the material maintains its shape and adheres well, even on vertical surfaces. This anti-sagging property is particularly important in applications such as plastering or jointing, where the material needs to stay in place and provide a smooth, level finish.

5. Longer Open Time: Open time refers to the period during which a gypsum-based material remains workable after mixing. HPMC extends the open time of gypsum products by slowing down the drying process. The gel-like structure formed by HPMC retains moisture within the material for a longer duration, allowing for more extended working time. This longer open time is beneficial, especially in larger projects or when complex detailing is required, as it provides ample time for proper installation and finishing.

6. Enhanced Adhesion: For gypsum to be effective, it must adhere properly to the substrate it is applied to. Poor adhesion can lead to peeling, cracking, or a weakened structure. HPMC enhances the bonding strength of gypsum, ensuring better adhesion to a variety of surfaces such as brick, concrete, or drywall. This leads to increased durability of the applied material, making the construction more resilient to wear and tear over time.

7. Crack Resistance: Cracking is a common problem in gypsum-based materials, particularly if they dry too quickly or unevenly. By retaining moisture and controlling the setting time, HPMC helps prevent cracking, ensuring a smoother, more resilient finish. This is particularly important in high-traffic areas where cracks can quickly degrade the quality of the surface.

In summary, HPMC plays a versatile and crucial role in gypsum-based materials by offering good water retention, excellent thickening effect, improved workability, anti-sagging properties, and longer open time. These characteristics contribute to easier handling, better application, enhanced performance, and superior finished results in various construction applications involving gypsum.

Samples of gypsum plasters with initially various water-to-gypsum ratios which contained HEMC admixtures in weight fractions from 0.25 to 1.5% were prepared. Setting, mechanical and DSC tests were made. The results are shown in the following figures. The effect of HEMC admixture on the kinetics of gypsum hydration/crystallization process was discussed.

Setting time

Setting of material is a transition period during which the physical state of material changes from liquid to solid. This transformation occurs as a result of the development of hydrated products which cause rigid connections between hydrating grains. It is usually characterized by two points in the hydration process, namely initial and final setting time. The development of connected hydration product which reflects the transition of material state was measured by the penetration resistance technique.

Selected results of the Vicat needle test are shown in Figs. 2 and 3. The beginning of the setting period was estimated as the first inflection point on h curve. The time of setting was measured as the time of the intersection of straight line on the curve. The time from the onset of the experiment to the beginning of the setting period is known as the induction period.

Setting of gypsum obtained with various water-to-gypsum ratios (w/g'='0.6'0.74). Weight fraction of HEMC is equal to 0.5%. ts example of setting time measurements, ti induction time of setting

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Setting process of gypsum samples with w/g'='0.66 for various HEMC contents (0.25'1.5%) and for sample without admixtures

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Figure 2 shows setting of the samples with water-to-gypsum ratio x from 0.6 to 0.74. In the case of higher water content (in initial gypsum mixture), the initiation of the setting process (initiation time ti) followed later than in the case of low water content. Gypsum setting time ts also increased with increasing amounts of water. Excess water caused prolongation of the nucleation process and also adsorption/accumulation of ions or other molecular units at the interface due to lowering of the oversaturation degree.

Figure 3 illustrates the setting process of gypsum for samples with w/g'='0.66 and various HEMC contents. In Fig. 3, for comparison, a sample without any admixtures with w/g'='0.66 is also presented. The addition of a small amount of HEMC admixture (lower than 1%) caused an insignificant prolongation of the setting and induction time. Results for the samples with 0.25, 0.5 and 0.75% are very similar. Compared to the samples with a smaller content of admixtures and those without any admixture, the addition of 1% prolongs the setting time. HEMC in the amount of 1.5% causes a significant (almost double) increase in the setting and induction time. The applied polymer prevents diffusion of water molecules and anions to the binder surface due to relatively rigid polymer molecule conformation in the water phase. No electrostatic interactions of polymer active groups with the binder surface of gypsum were predicted because it was found elsewhere that the gypsum zeta potential was close to zero [17].

Dependence of ti and ts on the w/g ratio was presented in our previous paper [2].

Mechanical tests

The results of mechanical tests are shown in Figs. 4 and 5. Figure 4 presents the dependence of bending stress σ on HEMC content for water-to-gypsum ratio equal to 0.6'0.74. The bending stress increases with increasing HEMC content for chosen w/g. The higher values of σ are received for a smaller water-to-gypsum ratio.

Bending stress σ versus HEMC content for various w/g ratios. Error is equal to 1 MPa

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Bending stress σ versus water-to-gypsum ratio, w/g

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Figure 5 presents bending stress σ versus water-to-gypsum ratio w/g. In both cases (samples without admixture and with 1% HEMC), the bending stress σ decreases with increasing water content. It results from a change in the sample morphological structure and increasing pore content. Greater HEMC content causes the growth of overlapping crystals which leads to significantly increasing bending stress of the sample.

Hydration/crystallization process

The hydration of calcium sulfate hemihydrate is an exothermic reaction

$${\text{CaSO}}_{4} \cdot 0.5{\text{ H}}_{2} {\text{O}} + 1.5{\text{ H}}_{2} {\text{O }} \to {\text{CaSO}}_{4} \cdot 2{\text{ H}}_{2} {\text{O }} + \, Q,$$

where Q, the amount of heat evolution, depends on a number of factors.

The reaction of gypsum with water [18,19,20] is divided into three main stages which involve a set of coupled chemical processes:

1. 1.

   A nucleation period starts immediately after the hemihydrate powder sample is mixed with water solvent and dissolved. The dissolution involves detachment of molecular units from a solid surface in contact with water as well as diffusion and transport of solution components into volume paste. The solution becomes supersaturated with respect to Ca2+ and SO 2'4 ions, which leads to the precipitation of solid grains of calcium dihydrate due to the nucleation process.

2. 2.

   An acceleration period in which a complex reaction between ions or solid complexes adsorbed on solid surfaces due to the crystallization/hydration process is observed.

3. 3.

   A deceleration period of very slow reactions of adsorption and accumulation of ions or other molecular units at an interface. The late stage of hydration is thus controlled by the diffusion process.

The wide range of properties can be observed as hydration proceeds, including heat of hydration, porosity and setting time as well as phase volume fraction.

The rate of all the reactions can be changed by the presence of a polymer admixture. For example, the induction period can be prolonged with:

1. a.

   Reduced diffusion of water and calcium ions at gypsum surface because the adsorbed polymer (if so) hinders the process,

2. b.

   Formation of a complex between calcium ions and the polymer in the pore solution,

3. c.

   Change in the growth kinetics and morphology of hydrated phases caused by the dispersive action of the polymer.

Experimental observations have suggested that the formation of a cementitious hydrated product is a rate-controlling process at early stages [19]. Furthermore, this led to the development of hydration kinetics models based on nucleation and growth phenomena such as presented by Avrami et al. [21, 22].

Avrami [21, 22] and also Johnson and Mehl [23], as well as Kolmogorov [24], proposed a simple but widely used equation which is derived using the assumption within the transforming volume in changing liquid on crystal. Avrami power law is as follows:

$$X\left( t \right) = 1{-}\exp \left( { - Kt^{\text{n}} } \right),$$

(1)

where X(t) is the volume fraction of crystalline phase that is transformed at time t, K is the combined rate constant that involves the rates of growth and nucleation, and n is a parameter dependent on the mechanism and dimensionality of growth.

Depending on crystal, growth n can reach a value between 1 and 3. If n'''1, the growth will have one-dimensional (needle) character. In the case of n'''2, two dimensions and n'''3 isotropic growth (sphere) are observed [25, 26].

The volume of the transformed phase will increase with the simple power law (Avrami equation) at early stages of the process before adjacent regions of the growing product impinge. Thus, the overall growth rate in the system decreases with time.

It is commonly assumed that hydration is the diffusion controlled by the rate at which the reactants can diffuse through the nanoporous layer of hydration product around the remaining unhydrated gypsum particles. The point in which the hydration process shifts away from nucleation and growth is not well established, but it is an important aspect of the hydration process.

The increasing use of mineral or polymer admixtures in cementitious materials leads to the question how the admixtures can affect hydration rate, especially at early stages.

The wide range of sample properties can be observed as hydration/crystallization proceeds, including heat of hydrated phase, volume fraction, chemical shrinkage, percolation of capillary porosity and setting time.

Hydration/crystallization of calcium hemihydrates, both pure and with admixtures, was conducted by DSC research. Figures 6 and 7 show curves of the process. Figure 6 presents curves obtained for samples with the water-to-gypsum ratio equal to 0.66. Gypsum hydration occurs in the main three-stage processes, i.e., nucleation (I), acceleration (II) and deceleration (III). The hydration/crystallization process occurs faster in the case of sample 6 (without admixtures). The increasing polymer content causes a delay of the hydration/crystallization process. Not only the induction period is extended, but also the rate of the following hydration reaction is slowed down. This is illustrated by lower values of maximum heat release and broader exothermal peaks in the calorimetric curves of the polymer-modified pastes.

Isothermal DSC curves: heat flow of gypsum hydration/crystallization versus time for various HEMC contents, w/g'='0.66

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Isothermal DSC curves: heat flow of gypsum hydration/crystallization for various w/g (for 0.5% HEMC content)

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Figure 7 shows samples with various water-to-gypsum ratios (0.60'0.74) and HEMC content equal to 0.5%. With an increasing w/g value, the hydration/crystallization process also delays. Both the presence of polymer in water solution and increasing w/g ratio leading to the delay of gypsum hydration/crystallization result from the same prevention of nucleation process of gypsum species.

Figure 8a presents curves transformed in Fig. 6 to the plots of the degree of hydration/crystallization X drawn versus time. Figure 8b shows Log['ln(1'''X)] versus log t (obtained according to Avrami equation).

a Curves from Fig. 6 transformed into Avrami plots'degree of hydration/crystallization X versus time t. b. Log['ln(1'''X)] versus log t

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The values of crystal growth rate constant K (dependent on the nucleation rate) are determined from Fig. 8a, b and presented in Fig. 9 (parameter n'''1.4). An increasing polymer admixture content causes a decrease in the K value. The results indicate that HEMC is an efficient agent disturbing the nucleation and crystallization of gypsum (lower K value).

Parameter K versus HEMC content

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SEM microphotographs

The morphology of calcium sulfate dihydrate crystals depends on the formation conditions and the presence of additives [9]. SEM microphotography is helpful for observation of gypsum crystals. Figures 10 and 11 present microphotographs of bending fracture area of the samples with water-to-gypsum ratio equal to 0.6 (with the admixture in Fig. 11'0.5% of HEMC). The crystal habit is affected by the presence of polymer as may be seen in the SEM photographs. Crystals in the absence of admixtures are thin and elongated which is a result of their rapid growth. They are longer than in the case when HEMC is added. The presence of the polymer in the reacting solution enhances the agglomeration of crystals. A decrease in the total pore volume and increase in crystal overlapping lead to a more impact structure and higher mechanical strength.

Microphotograph of bending fracture area of the sample with w/g'='0.6

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Microphotograph of bending fracture area of the sample with w/g'='0.6 containing 0.5% HEMC

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Admixtures in the form of water-soluble polymers change the interaction between Ca2+, SO 2'4 and OH' ions forming hydrated crystals of gypsum. Polymers are not built into gypsum crystals but can form a separate phase (for example thin films in the pores).

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