최근 유통·물류 산업의 발달로 산업용 창고 바닥의 중요성a이 점점 높아지고 있다. 본 연구에서는 기존의 바닥재료로 사용되어 온 일반 시멘트계 모르타르가 가지고 있는 유동성의 한계 및 긴 양생 시간 등의 단점을 보완할 수 있는 속경성 폴리머 모르타르 바닥소재를 개발하 였다. 속경성 확보를 위해 초속경 시멘트를 결합재로 사용하였고, VAE 폴리머 분말수지를 5%~20% 혼입 범위로 설정한 4종류의 배합과 혼입 하지 않은 Proto배합에 대한 기초물성을 유동성실험, 압축강도실험, 휨강도실험, 부착강도실험 및 마모실험을 통해 평가하였다. 유동성 실험 결과를 통해 고성능 감수제량를 조절함으로써 플로우 250 mm 이상의 고유동 특성을 확보할 수 있었다. VAE 폴리머 혼입은 압축강도 감소에 영향을 미치는 것으로 나타났지만 휨강도는 Proto배합에 비해 우수하게 증진시킬 수 있어 압축강도/휨강도비를 증가시키는 것으로 평가되었 다. 또한 최소 2.6배 이상의 부착강도 향상과 4배 이상의 마모저항성을 확보할 수 있었다. 역학적 실험을 통해 VAE 폴리머 최적 혼입률을 10% 로 결정하였고, 현장적용 및 모니터링을 수행한 결과 VAE 폴리머를 혼입하지 않은 바닥재에 비해 오염도, 충격에 의한 저항, 부착성능 등이 우 수한 것으로 나타났다.

This paper investigates the effect of amount of Paraffin-encapsulated phase change material (PCM) on the thermal energy storage of cement mortar for developing energy saving concrete. The PCM with melting point of 44℃ was used in this study. The added amounts of PCM in the cement mortar were 0, 10, 20 and 30% of cement weight. The results indicated that the heat storage properties of cement mortar was improved with increasing contents of PCM.

In this study, hydration heat, autogenous shrinkage and compressive strength of the specimens has been verified with moisture supply on the hardened cement paste depending upon the difference in moisture condition of the fine aggregates. The result showed that, autogenous shrinkage was significantly reduced and also the compressive strength was improved due to the continuous moisture supply regarding on fine aggregates.

This paper investigates the effect of amount of Paraffin-encapsulated phase change material (PCM) on the thermal energy storage of cement mortar for developing energy saving concrete. The PCM with melting point of 44℃ was used in this study. The added amounts of PCM in the cement mortar were 0, 10, 20 and 30% of cement weight. The results indicated that the heat storage properties of cement mortar was improved with increasing contents of PCM.

This study investigated the compressive strength characteristics of concrete and mortar containing waste pottery fine powder. To identify the effects of waste pottery fine powder on the compressive strength of concrete and mortar, cement was replaced with waste pottery fine powder at 5, 10 and 15% rates and the variations in compressive strength were evaluated. For high strength concrete, compared with a control mix, 5% replacement resulted in the reduction of 3.4% in compressive strength at 7 days; however, at 28 days, the strength actually increased by 2.5%. For normal strength concrete, compared with a control mix, 5% replacement resulted in the reduction of 20.4% in compressive strength at 7 days, and 14% reduction at 28 days. As for the mortar, at 5% replacement, compared with a control mortar mix, compressive strength of mortar decreased by 3% at 7 days, while an increase of 5.9% was observed at 28 days. Therefore, the optimum replacement rate of cement with waste pottery fine powder appears to be 5%.

In this study, to evaluate the performance of fire resistance of the mortar with magnesium hydroxide(MH) and aluminium hydroxide(AH) which has a RCC (Radiant Control Capability) as repair material to the steel structure, temperature evaluation of mortar was conducted by increasing 500°C in the furnace. The performance of RCC can decrease a temperature to external and internal mortar. As a result, it is confirmed that temperatures of mortar with magnesium hydroxide(MH) and aluminium hydroxide(AH) were more decreased than general mortar due to the RCC effect of MH and AH. Therefore, it can be possible to apply to a repair material at the steel structure.

This study presents the results of experiments to investigate the effect of polymer type and curing temperature on the mechanical properties of polymer mortar. The flexural strength, compressive strength of RHP mortar at the curing temperature of 20℃, 0℃, and –20℃ at the curing age of 24hr were 93%, 93%, and 91%, respectively, relative to those at the curing age of 168hr. On the other hand, The flexural strength, compressive strength of HDP mortar at the curing temperature of 20℃, 0℃, and –20℃ at the curing age of 72hr were 91%, 81%, and 80%, respectively, relative to those at the curing age of 168hr.

The mechanical properties of high temperature mortar reinforced by polypropylene fibers were investigated in this paper. Ordinary portland cement was used as basic binder and the effect of the replacement of fly ash, slag, silica fume and graphite for Ordinary portland cement was investigated.

An experiment was conducted to recycle sulfur which is industrial by-product, by producing concrete mix materials. production of specimens were implemented on the replacement of modified sulfur emulsion with cement. this paper presents data on the experimental results of durability test of the each specimens.

An experiment was conducted to recycle sulfur which is industrial by-product, by producing concrete mix materials. production of specimens were implemented on the replacement of modified sulfur emulsion with cement. this paper presents data on the experimental results of strength test of the each specimens.

As the industrialization is rapidly growing and the quantities of heavy weight waste glass have been quickly increased but the most of them are not recycled. The heavy weight waste glass have been treated by illegal dumping or being buried in landfills. And, it is caused some problem such as the environmental pollution. So, it is needed to investigate the possibility of recycling of heavy weight waste glass as concrete material ingredient. In this paper, the mechanical properties of mortar substituted the crushed waste glass as fine aggregate are evaluated. From the results, when waste glass substitution ratio increase, fluidity and specific gravity increase. However, the compressive strength and flexural strength decrease. So, the mechanical properties of mortar are significantly affected by waste glass substitution ratio.

This study was intended to estimate the effect of adding stone dust into cement mortar on the rheological properties. it was found that higher the content of stone dust decrease the yield stress but there was no noticeable correlation between stone dust dosage and the plastic viscosity.

Two main parameters were examined such as CSA content and polymer-binder ratio to find effects on the strength, water absorption, chloride ion penetration depth, carbonation depth, length change and chemical resistance of polymer-modified mortar with CSA and EVA polymer powder (EVAPP). As results, compressive, flexural, tensile, adhesive strengths, and length change of the polymer-modified mortar with CSA and EVAPP increases with increasing CSA content and polymer-binder ratio, although the water absorption, chloride ion penetration depth, and carbonation depth decrease with increasing polymer-binder ratio and CSA content, and also the chemical resistance decreases. Such strength and durability development is attributed to the high tensile strength of EVA polymer and the improved bond between cement hydrates and aggregates because of the addition of EVAPP and CSA.

This study was experimented by reviewing the possibility of applying non-sintered loess as a building material. Andthis study was to evaluate and compare flexural and compressive strengths characteristics of cementless mortar with non-sintered loess according to percentage of non-sintered loess and the type of curing without adding any cement. SEM,chloride ion penetration resistance and chemical resistance were also evaluated and compared to study characteristics ofcementless mortar with non-sintered loess. In order to evaluate the characteristics of cementless mortar with non-sinteredLoess. Test pieces were fabricated at 3, 7 and 28 days depending on the percentage of non-sintered loess and the typeof curing. And also normal portland cement mortar were fabricated to compare with cementless mortar with non-sinteredloess. The result of this study, Properties of cementless mortar with non-sintered loess strength are generally lower thannormal portland cement mortar. However cementless mortar with non-sintered loess which is mixed 20% show equallyas normal portland cement mortar. Also, cementless mortar with non-sintered loess show excellent results than normalportland cement mortar in the durability characteristics. The purpose of this study was to expand the utilizable scope ofnon-sintered loess and to use the basic data as a applying building material in the future.

The development of functional finishes for the improvement of indoor air quality is one of important issues in the fieldof building materials. Indoor air quality can be affected by gases, particulates, microbial contaminants or any mass thatcan induce adverse health conditions. The purpose of this study is to develop eco-friendly internal material of acrylicemulsion mortars using light-weight aggregate carrier which contains pyroligneous liquid. Four types of light-weightaggregates (perlite, vermiculite, charcoal and zeolite) those are functionally used in interior finishing materials are selectedand the properties such as flowability, adhesion, water absorption coefficient, crack and impact resistance are evaluatedin accordance with KS F 4715. As a result, the properties of acrylic emulsion mortars using light-weight carrier in thisstudy are satisfied with KS requirements. Among the four types of mortars with light-weight carrier, properties of acrylicemulsion mortars using zeolite carrier is more excellent than those of other light-weight carriers.

This study is regarding the property evaluation of mortar for ‘ONDOL’ floor (Korean floor heating system) finishing with reduced drying and shrinking properties to use it in the form of ready-mixed concrete mortar. The mortar utilized furnace slag based inorganic binding agent NSB, which has the characteristic of CaO included in HCFA generated from the fluidized-bed-firing power plant. Based on the test results, it is judged that mortar for ‘ONDOL’ floor finishing based on NSB including HCFA can be used in the form of ready-mixed concrete. According to site test construction, the flow property was relatively poor because fine gravel at ready-mixed concrete factory was used. However, since finishing property, crack resistance and water content are good, it is believed that it can be used at construction site in the form of ready-mixed concrete mortar. More study on adhesion property with floor plate would be required in the future.

In this study, manufactured of cement mortar using high early strength cement(10 ~ 50 wt%) and blast furnace slag powder(50 ~ 90 wt%), according to compressive strength and flexural strength of hardened cement mortar. XRD and SEM were evaluated utilizing the initial cement hydration properties.

While carrying out a series of study for improving the durability of High Volume Admixture Concrete using the ERCO, we found that the resistance of freezing and thawing declined due to the decrease of air amount in concrete when using the ERCO. In order to solve the problem, we carried out an experiment using the DEM. As a result of that, it did not affect the basic characteristic of concrete, and the problem of decreasing air amount caused by using the ERCO is also considered to be solved by securing the target air amount.

Experiments were divided into two parts; one part is to understand the basic properties of high flowable VA/VeoVa-modified cement mortar with different polymer cement ratio (P/C) and the weight ratio of fine aggregate to cement (C:F) and the other part is to investigate the effect of surface water spread on the concrete substrate on adhesion in tension. To understand the basic performance, the specimens were prepared with proportionally mixing VA/VeoVa redispersible powder, ordinary portland cement, silica sand, superplasticizer and viscosity enhancing agent. Here, P/C were 10, 20, 30, 50 and 75% and C:F were 1:1 and 1:3. As the change of P/C and C:F unit weight, flow test, crack resistance and adhesion in tension were measured. Three specimens with good adhesion properties were selected among specimens with different P/C and C:F. The effect of surface water evenly sprayed on concrete substrate on adhesive strength is investigated. The results show that surface water on concrete substrate increases the adhesion in tension of high flowable VA/VeoVa-modified cement mortar and additionally improves the flowability compared to the non-sprayed case.

This study investigates the fundamental properties of the water-binder (W/B) ratio and fine aggregate-binder (F/B) ratio in the alkali-activated slag cement (AASC) mortar. The W/B ratios are 0.35, 0.40, 0.45, and 0.50, respectively. And then the F/B ratios varied between 1.00 and 3.00 at a constant increment of 0.25. The alkali activator was an 2M and 4M NaOH. The measured mechanical properties were compared, flow, compressive strength, absorption, ultra sonic velocity, and dry shrinkage. The flow, compressive strength, absorption, ultra sonic velocity and dry shrinkage decreased with increases W/B ratio. The compressive strength decreases with increase F/B ratio at same W/B ratio. Also, at certain value of F/B ratio significant increase in strength is observed. And S2 (river sand 2) had lower physical properties than S1 (river sand 1) due to the fineness modulus. The results of experiments indicated that the mechanical properties of AASC depended on the W/B ratio and F/B ratio. The optimum range for W/B ratios and F/B ratios of AASC is suggested that the F/B ratios by 1.75~2.50 at each W/B ratios. Moreover, the W/(B+F) ratios between 0.13 and 0.14 had a beneficial effect on the design of AASC mortar.