乳化剂用量对搅打稀奶油搅打性能和品质的影响机理研究

研究了乳化剂用量对搅打稀奶油的乳浊液粒度分布、脂肪球部分聚结、液相蛋白浓度、感官品质和泡沫稳定性的影响。研究结果表明:乳浊液冷却及解冻后脂肪球粒径随乳化剂用量增加而减小,随着乳化剂用量增加,脂肪部分聚结速度和液相蛋白质浓度增加速度加快,搅打起泡率和感官品质以乳化剂用量为0.60%时最好,搅打稀奶油稳定时间随乳化剂用量增加呈先增加后下降趋势,当乳化剂用量为0.60%时,稳定时间达到最大2.4h。综合考虑,当乳化剂HLB值为7,乳化剂用量为0.60%时,搅打稀奶油搅打性能和品质最佳。     

瓜尔豆胶对搅打稀奶油的搅打性能的影响

研究了不同浓度的瓜尔豆胶对搅打稀奶油乳状液的表观黏度、脂肪球粒度、脂肪球界面蛋白浓度、脂肪球部分聚结率、泡沫硬度和搅打起泡率的影响。结果表明，瓜尔豆胶对搅打稀奶油乳状液的表观黏度影响非常显著；瓜尔豆胶浓度过高或过低，都会使得解冻后的乳状液粒径变大；瓜尔豆胶的质量分数越高，脂肪球部分聚结速度越快，泡沫硬度也越大；搅打起泡率随着瓜尔豆胶质量分数增大而降低。     

二次均质工艺中一次均质压力对黄油基搅打稀奶油品质的影响

以无盐黄油和脱脂乳为原料制备黄油基搅打稀奶油,采用二次均质工艺,研究了一次均质压力（二次均质压力不变）对黄油基搅打稀奶油的粒径、脂肪部分聚结率、流变学特性、搅打性能的影响,分析了各评价指标之间的相关性。结果表明,黄油基搅打稀奶油的一次均质压力在10.0~15.0 MPa时,随着均质压力的增大,脂肪球粒径D4,3由1.85 μm逐渐减小到1.57 μm,且在15.0 MPa时脂肪球粒径D4,3达到最小为1.57 μm;黄油基搅打稀奶油的脂肪部分聚结率随着一次均质压力的增大逐渐增大,由13.74%增大到17.53%;搅打时间随着均质压力的增大逐渐由314 s减小到265 s且一次均质压力在15.0 MPa时搅打时间最少为265 s;泡沫稳定性由78.09%逐渐增加到87.26%,且泡沫稳定性在15.0 MPa时泡沫稳定性达到最大87.26%。因此将黄油基搅打稀奶油的一次均质压力控制在10.0~15.0 MPa范围内较适宜。     

蛋白质用量对黄油基淡奶油搅打前乳液性质及搅打性能的影响

以黄油为油相制备淡奶油,研究蛋白质用量(1.0%～3.0%)对黄油基淡奶油搅打前乳液性质及搅打性能的影响。研究表明:蛋白质用量为1.0%～2.5%时,随蛋白质用量的增加,搅打前乳液的界面蛋白浓度明显增加,脂肪部分聚结率降低,脂肪球粒径减小,粒度分布曲线变窄,表观黏度升高,乳液的稳定性提高;蛋白质用量由2.5%增加至3.0%时,脂肪部分聚结率增加,脂肪球粒径增大,乳液的稳定性降低。乳液在200 s的搅打过程中,随搅打时间的延长,脂肪部分聚结率不断增加,平均粒径呈现先减小后增大的趋势,搅打起泡率则先升高后降低。蛋白质用量为1.0%～1.5%时,在搅打过程中脂肪部分聚结率、平均粒径、搅打起泡率均快速增加,易出现搅打过度现象,且泡沫稳定性差。蛋白质用量为2.0%～2.5%时,脂肪部分聚结率、平均粒径、搅打起泡率则缓慢增加,而泡沫稳定性较好。蛋白质用量增加至3.0%时,尽管泡沫稳定性较好,但搅打200 s后的脂肪部分聚结率仅有26.45%。因此,将黄油基淡奶油的蛋白质用量控制在2.0%～2.5%范围内较适宜。     

复配蛋白质添加量对黄油基搅打稀奶油稳定性及搅打性能的影响

该文以m(酪蛋白)∶m(乳清蛋白)=2∶1复配蛋白质,以无盐黄油和离心乳脂肪为原料制备黄油基搅打稀奶油。以搅打时间、搅打起泡率、脂肪部分聚结率、粒径分布、表观黏度和泡沫稳定性为评价指标,研究复配蛋白质的添加量对黄油基搅打稀奶油乳液稳定性及搅打性能的影响。结果表明,当复配蛋白质的添加量为0.9%～1.2%(质量分数)时,脂肪球粒径分布为0.81～7.16μm,乳液脂肪附聚率为6%～10%,乳液的搅打时间为277～296 s,搅打起泡率达到200%～203%,泡沫稳定性为95.86%～97.03%。故将黄油基搅打稀奶油中复合蛋白质添加量控制在0.9%～1.2%,搅打稀奶油的乳液稳定性及搅打性能较好,为以黄油为原料生产高品质搅打稀奶油奠定理论基础。     

大豆蛋白与酪蛋白比例对搅打稀奶油稳定性影响的研究

研究了大豆蛋白与酪蛋白不同配比对搅打稀奶油乳浊液的表观粘度及搅打过程中的液相蛋白浓度、脂肪部分聚结、搅打起泡率的变化和泡沫稳定性的影响,并在此基础上探讨了其作用机理。结果表明:大豆蛋白比例的增大能增加界面膜的粘弹性,抑制脂肪球的部分聚结,提高泡沫结构的稳定性,当大豆蛋白与酪蛋白比例为4∶1时,搅打稀奶油可以获得最佳的稳定性。     

均质压力对UHT搅打稀奶油品质的影响

以新鲜稀奶油为主要原料,考察了不同的均质压力对UHT搅打稀奶油的脂肪球粒径、流变学特性、搅打特性的影响,分析了各评价指标之间的相关性。结果表明,UHT搅打稀奶油最适均质压力范围为3～5 MPa;随着均质压力的增大(1～9 MPa),脂肪球粒径减小,但打发成型所需时间增加;在α=0.01水平上,粒径与搅打时间、起泡率显著相关;在α=0.05水平上搅打时间与起泡率显著相关。     

黄油-代可可脂基奶油生产工艺优化及其晶型形成分析

在分析油脂用量对黄油-代可可脂基奶油品质影响的基础上,通过正交试验研究油脂用量、黄油-代可可脂质量比和均质压力对奶油搅打性能、质构特性、脂肪球部分聚结率、结晶特性等的影响。结果表明,在油脂用量30%、黄油-代可可脂质量比2∶3、均质压力60?MPa的条件下,能保证脂肪部分聚结的发生,并保持搅打稀奶油较好的感官特性、起泡性和结晶特性。60?MPa的均质压力保证了体系的稳定性,使大量游离脂肪球产生从而促进脂肪部分聚结。晶型形成分析结果表明,在优化条件下,原料乳浊液X-射线衍射峰峰形由较宽、较尖锐变为峰形适中均匀,适宜搅打稀奶油的β’晶型晶体明显增多,搅打稀奶油乳浊液在低温条件下发生脂肪结晶,表现为脂肪晶体尺寸增大。     

搅打稀奶油品质及其影响因素的研究进展

搅打稀奶油是一类可搅打起泡的水包油乳液。作为重要的食品工业原料,搅打稀奶油可作为呈味物质赋予食品良好的感官特性,应用前景广阔。本文首先介绍搅打稀奶油贮藏期内常见的失稳作用,包括乳析、聚集、聚结、部分聚结及奥氏熟化,并阐述界面特性及脂肪球间的交互作如何影响搅打稀奶油的稳定性;其次介绍搅打稀奶油的搅打过程,阐述结晶特性、界面特性和液相蛋白特性如何影响搅打特性。本文可为搅打稀奶油产品的工业化生产提供一定的理论指导。     

油脂种类对植脂鲜奶油搅打性能的影响

通过研究不同种类的油脂在植脂鲜奶油搅打过程中脂肪球的部分附聚、搅打时间、搅打起泡率和泡沫稳定性之间的关系。结果表明：不同种类的油脂对搅打性能的影响与其熔点有着密切的关系，其实质是油脂在常温下的固体脂肪指数决定了脂肪球能否发生部分聚结与聚结的程度，熔点为35～43℃的部分氢化植物油的聚结率接近60％，可以达到最佳的部分聚结率，能够形成稳定的泡沫结构；熔点为47～53℃的部分氢化植物油的聚结率超过70％，容易产生过度的部分聚结，形成结构粗糙的泡沫；天然奶油的部分聚结率低于10％；大豆油或者极度氢化油不能发生脂肪球的部分聚结，不能形成稳定的泡沫结构。     

Effect of sorbitan monostearate on the physical characteristics and whipping properties of whipped cream

In this work, the effects of sorbitan monostearate (Span 60) level on the particle size distribution, microstructure and apparent viscosity of the emulsion were investigated. Average particle size (d_4,3), surface protein concentration, partial coalescence of fat and overrun of whipped cream during whipping were also determined. As Span 60 level increased (0–0.8%) in emulsion, the apparent viscosity was increased gradually, and the particle size range was narrowed, which was also detected by microstructure. A positive effect of whipping time was observed on the average particle size, partial coalescence of fat, surface protein concentration and overrun during whipping, respectively. An increase of Span 60 level resulted in a reduction of d_4,3 values and partial coalescence of fat during 0–1 min whipping, then increasing after whipping for 2–5 min (0.6% Span 60 as the critical level). A negative behaviour was observed between surface protein concentration and Span 60. Moreover, Span 60 could improve the overrun and organoleptic properties of whipped cream efficiently.     

Influence of whipping temperature on the whipping properties and rheological characteristics of whipped cream

The effects of whipping temperature (5 to 15°C) on the whipping (whipping time and overrun) and rheological properties of whipped cream were studied. Fat globule aggregation (aggregation ratio of fat globules and serum viscosity) and air bubble factors (overrun, diameter, and surface area) were measured to investigate the mechanism of whipping. Whipping time, overrun, and bubble diameters decreased with increasing temperature, with the exception of bubble size at 15°C. The aggregation ratio of fat globules tended to increase with increasing temperature. Changes in hardness and bubble size during storage were relatively small at higher temperatures (12.5 and 15°C). Changes in overrun during storage were relatively small in the middle temperature range (7.5 to 12.5°C). From the results, the temperature range of 7.5 to 12.5°C is recommended for making whipped creams with a good texture, and a specific temperature should be decided when taking into account the preferred overrun. The correlation between the whipped cream strain hardness and serum viscosity was high (R² = 0.906) and persisted throughout the temperature range tested (5 to 15°C). A similar result was obtained at a different whipping speed (140 rpm). The multiple regression analysis in the range of 5 to 12.5°C indicated a high correlation (R² = 0.946) in which a dependent variable was the storage modulus of whipped cream and independent variables were bubble surface area and serum viscosity. Therefore, fat aggregation and air bubble properties are important factors in the development of cream hardness. The results of this study suggest that whipping temperature influences fat globule aggregation and the properties of air bubbles in whipped cream, which alters its rheological properties.     

Effect of xanthan gum on the physical properties and textural characteristics of whipped cream

Xanthan gum was used as thickening agent to prepare whipped cream in this work. A dose-dependent effect was observed on the average particle size (d_3,2) of whipped cream. At each xanthan gum level (0.025–0.125%) used, whipping time also showed a positive effect on the average particle size. With the increase of xanthan gum level or whipping time, the partial coalescence of fat in the whipped cream increased gradually. However, xanthan gum level showed no significant effect on the overrun of whipped cream. The textural characteristics of whipped cream were also investigated and the results indicated that a positive correlation was found between xanthan gum level and firmness, cohesiveness or viscosity of whipped cream. A different tendency was detected for consistency. The consistency of whipped cream increased with the increase of xanthan gum level to 0.100%, thereafter decreased.     

Physicochemical properties and application of micronized cornstarch in low fat cream

With normal cornstarch (CS) as material, micronized starch was prepared first by acid hydrolyzed pretreatment and then ball-milling (HMS). A control sample (MS) was prepared by ball-milling without pretreatment. Particle size and shape of micronized starch were investigated, and its application in low fat cream was studied. The Maltase cross of HMS granules almost disappeared and the particle size clearly decreased. It was evident that acid-lintnerised starch granules were more susceptible to break down upon milling. However, the granules would aggregate with an increase in milling time. Compared with full-fat cream, the apparent viscosity of low-fat cream increased, while fat globules partial coalescence rate, overrun and textural properties decreased with the increasing of the fat replacement rate. The average particle size of whipped cream increased with the increase of whipping time. Results indicate that a 15% fat replacement rate would produce cream with good foaming and storage stability.     

Effect of hydroxypropyl methylcellulose on the textural and whipping properties of whipped cream

In this work, hydroxypropyl methylcellulose (HPMC) was added into whipped cream for improving its textural and whipping properties. By determination of the particle size distribution, a single peak for the emulsion after homogenization and two distinguishable peaks for the emulsion after whipping for 5 min were observed. With the increase of HPMC level, the average particle size (d_3,2) decreased for the emulsion after homogenization and increased for the emulsion after whipping for 5 min. Both whipping time and HPMC level showed positive effects on the partial coalescence of fat globules. The partial coalescence of whipped cream with 0.125% HPMC after whipping for 5 min reached 56.25%, significantly (P < 0.05) higher than that (4.77%) without whipping treatment. Surface protein concentration was measured to evaluate the change of protein content at the droplet interface. The results indicated that the increase of HPMC level could decrease the surface protein concentration slightly. The overrun of whipped cream slightly increased when the HPMC level increased in the range of 0.025–0.125%. Firmness, cohesiveness, consistency and viscosity of whipped cream were analysed in this work. HPMC showed a positive dose-dependent effect on all these textural properties.     

搅打稀奶油的搅打机理研究

通过研究稀奶油在搅打过程中的起泡率、泡沫硬度和浆液分离系数随搅打时间的变化规律,及搅打过程微观结构的变化,可将其分成3个阶段,即迅速充气阶段、脂肪球稳定附聚阶段和脂肪球急剧附聚阶段,在此基础上建立了搅打过程的模型,并分析了其搅打机理。