WO2019165734A1 - 一种炸用油变质程度的快速联合检测装置及其检测方法 - Google Patents

一种炸用油变质程度的快速联合检测装置及其检测方法 Download PDF

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WO2019165734A1
WO2019165734A1 PCT/CN2018/093128 CN2018093128W WO2019165734A1 WO 2019165734 A1 WO2019165734 A1 WO 2019165734A1 CN 2018093128 W CN2018093128 W CN 2018093128W WO 2019165734 A1 WO2019165734 A1 WO 2019165734A1
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oil
value
rapid
fried
color
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PCT/CN2018/093128
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English (en)
French (fr)
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张慜
苏雅
尹建宏
刘春泉
张卫明
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江南大学
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Priority to US16/620,820 priority Critical patent/US20200271590A1/en
Publication of WO2019165734A1 publication Critical patent/WO2019165734A1/zh

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    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N21/00Investigating or analysing materials by the use of optical means, i.e. using sub-millimetre waves, infrared, visible or ultraviolet light
    • G01N21/75Systems in which material is subjected to a chemical reaction, the progress or the result of the reaction being investigated
    • G01N21/77Systems in which material is subjected to a chemical reaction, the progress or the result of the reaction being investigated by observing the effect on a chemical indicator
    • G01N21/78Systems in which material is subjected to a chemical reaction, the progress or the result of the reaction being investigated by observing the effect on a chemical indicator producing a change of colour
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N21/00Investigating or analysing materials by the use of optical means, i.e. using sub-millimetre waves, infrared, visible or ultraviolet light
    • G01N21/75Systems in which material is subjected to a chemical reaction, the progress or the result of the reaction being investigated
    • G01N21/77Systems in which material is subjected to a chemical reaction, the progress or the result of the reaction being investigated by observing the effect on a chemical indicator
    • G01N21/78Systems in which material is subjected to a chemical reaction, the progress or the result of the reaction being investigated by observing the effect on a chemical indicator producing a change of colour
    • G01N21/80Indicating pH value
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N27/00Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
    • G01N27/02Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating impedance
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N33/00Investigating or analysing materials by specific methods not covered by groups G01N1/00 - G01N31/00
    • G01N33/02Food
    • G01N33/03Edible oils or edible fats
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N21/00Investigating or analysing materials by the use of optical means, i.e. using sub-millimetre waves, infrared, visible or ultraviolet light
    • G01N21/75Systems in which material is subjected to a chemical reaction, the progress or the result of the reaction being investigated
    • G01N21/77Systems in which material is subjected to a chemical reaction, the progress or the result of the reaction being investigated by observing the effect on a chemical indicator
    • G01N2021/7756Sensor type
    • G01N2021/7759Dipstick; Test strip
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N27/00Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
    • G01N27/02Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating impedance
    • G01N27/22Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating impedance by investigating capacitance
    • G01N27/221Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating impedance by investigating capacitance by investigating the dielectric properties

Definitions

  • the invention relates to a rapid joint detecting device for the degree of deterioration of fried oil and a detecting method thereof, and belongs to the technical field of rapid detection of food quality and safety.
  • the detection methods used by domestic testing institutions or manufacturers mainly include test paper method, titration method, mass spectrometry method, gas chromatography method, nuclear magnetic resonance method, conductivity method, electronic nose and electronic tongue method.
  • Tang Xinhua (Public No.: CN 104949947 A) invented a rapid detection method for the quality of edible oil.
  • the method establishes a correlation equation between the fluorescence value of the edible oil excited by the 365 nm light source and the nutrient composition in the edible oil to determine the fluorescence value. When it is 100, it is judged that the quality of the edible oil is acceptable.
  • Tu Bin (2016) studied the multi-source spectral data fusion technology using laser Raman and laser near-infrared spectroscopy, combined with chemometrics method to establish a method for detecting edible oil varieties, peanut oil adulterated content, authenticity and fatty acid content.
  • the difference of the present invention is that the dielectric property of the fried oil is combined with the color difference of the color test paper, and the correlation equation is established with the acid value and the peroxide value of the fried oil, thereby overcoming the intuitive judgment band. The error is obtained, and the quality index value of the fried oil is obtained accurately and quickly.
  • the capacitive sensor is placed in the grease to be tested, in which a mathematical model is embedded in the signal converter for signal conversion, and the button operation can be displayed after 15 seconds.
  • the sample four parameter values are selected, and the alarm is selected according to the set value.
  • the difference of the present invention is that the color characterization reaction of the rapid test paper is more intuitive to detect the quality characteristics of the fried oil, and the correlation equation with the dielectric properties of the fried oil is improved to improve the accuracy of the quality of the fried oil.
  • the object of the present invention is to overcome the above-mentioned deficiencies, and to provide a rapid color-dielectric combined detection device for detecting the degree of deterioration of fried oil and a detection method thereof.
  • a rapid joint detection device for the degree of deterioration of a frying oil comprises a rapid test paper for explosive oil quality, a dropper, a color difference meter, a dielectric analyzer and a sample to be tested; It is connected with a dielectric analyzer; the pipette is used for sucking the sample to be tested and dropping on the explosive oil quality rapid test paper for testing; and the explosive oil quality rapid test paper is connected with the color difference meter.
  • the explosive oil quality rapid test strip comprises a carrier and a color developing layer covering the carrier.
  • the preparation method of the explosive oil quality rapid test paper is as follows:
  • the rapid combined detection method for the degree of deterioration of the fried oil is carried out by color-dielectric combined detection, and the steps are as follows:
  • the correlation between the acid value of the oleic acid and the peroxide value and the color difference ⁇ E(x) is obtained, and the correlation equation is obtained.
  • the acid value of the fried oil is the y-axis and the color difference ⁇ E is the x-axis.
  • the correlation between the peroxide value and the peroxide value and the dielectric characteristic value ⁇ (x) of the fried oil is used to obtain the correlation equation.
  • the acid value of the fried oil is the y-axis and the dielectric characteristic value ⁇ .
  • the method has shown that the accuracy of detecting the acid value of the sample is 98.7%, which indicates that the rapid detection method has high accuracy and good repeatability, and can perform on-site rapid screening of the fried oil sample.
  • the role of inspection Although the accuracy of the rapid detection method is less than 100%, the rapid detection analyzer used in the experiment uses the color difference sensor and the analysis of the dielectric constant of the explosive oil, which overcomes the cumbersome procedure of the national standard method laboratory detection and reduces the experimental cost. It overcomes the visual error of visual inspection by the naked eye, and realizes qualitative and quantitative detection of the tested substances, meeting the requirements of simple, rapid, intelligent and on-site detection.
  • the invention has the beneficial effects that the method of the invention develops a rapid test strip indicating the degree of deterioration of the frying oil by detecting the change of the acid value and the peroxide value during the deterioration of the frying oil. And the color difference value read by the color difference meter is combined with the dielectric constant data of the fried oil. Through the established correlation equation, the actual data of the oil value and the peroxide value of the fried oil are obtained, and then the degree of deterioration of the fried oil is obtained. Perform a quick joint test.
  • Figure 2-b is a schematic diagram showing the results of analysis of the value of the peroxide value and the color difference ⁇ E(x).
  • Figure 3-a is a schematic diagram showing the results of oleic acid valence and dielectric eigenvalue ⁇ (x).
  • Figure 3-b is a schematic diagram showing the results of analysis of the value of the peroxide value and the value of the dielectric characteristic ⁇ (x).
  • Example 1 Establishment of correlation between the quality index of the explosive oil and the color difference ⁇ E(x) of the rapid test paper and the dielectric characteristic value ⁇ (x) of the fried oil:
  • Fig. 2-a The analysis results of the oleic acid value and color difference ⁇ E(x) of the fried oil are shown in Fig. 2-a, and the results of the analysis of the value of the peroxide value and the color difference ⁇ E(x) are shown in Fig. 2-b;
  • the correlation between the acid value of the fried oil, the quality index value of the peroxide value and the dielectric characteristic value ⁇ (x) of the fried oil is established.
  • the analysis results of the oleic acid value and the dielectric characteristic value ⁇ (x) of the fried oil are shown in the figure.
  • the combination of the color difference of the color test paper and the dielectric properties of the fried oil is combined to make the detection of the acid value and the peroxide value of the fried oil more intuitive and accurate.
  • the dielectric constant of the sample in the step (1) was measured by a network analyzer, and the specific values were 2.178 ⁇ 0.004 and 2.916 ⁇ 0.005, respectively.
  • step (3) Perform color difference analysis on the test strips of the color developed in step (1), combined with the dielectric constant data of the fried oil, and the correlation between the color difference value and the dielectric constant value and the acid value and peroxide value of the fried oil.
  • the equation obtains the actual data of the oleic acid value and the peroxide value of the fried oil, and then rapidly tests the degree of deterioration of the fried oil.
  • the test results showed that the color development test paper of fresh palm oil was dark blue, and the color test paper of the fried palm oil was blue-green, and the fresh palm oil obtained by the color difference value and the dielectric constant correlation equation was used.
  • the color difference values of the fried palm oil were 17.65 ⁇ 0.04 and 18.19 ⁇ 0.03, respectively, and the acid values were 0.25 ⁇ 0.01 mg KOH/g and 1.06 ⁇ 0.01 mg KOH/g, respectively, and the peroxide values were 2.12 ⁇ 0.02. And 2.36 ⁇ 0.01 meq / kg.
  • the research results show that the rapid detection method of the deterioration degree of the oil can accurately, quickly and conveniently detect the deterioration degree of palm oil in the frying process.
  • the dielectric constant of the sample in the step (1) was measured by a network analyzer, and the specific values were 2.446 ⁇ 0.003 and 3.746 ⁇ 0.007, respectively.
  • step (3) Perform color difference analysis on the test strips of the color developed in step (1), combined with the dielectric constant data of the fried oil, and the correlation between the color difference value and the dielectric constant value and the acid value and peroxide value of the fried oil.
  • the equation obtains the actual data of the oleic acid value and the peroxide value of the fried oil, and then rapidly tests the degree of deterioration of the fried oil.
  • the test results showed that the color of the color test paper of fresh soybean oil was color blue and the color of the color test paper of the indigo and fried soybean oil was yellow-green, and the fresh soybean oil and the fried fish obtained by the color difference meter and the detection and analysis program were fried.
  • the color difference values of soybean oil were 17.85 ⁇ 0.02 and 18.99 ⁇ 0.04, respectively, and the acid values were 0.54 ⁇ 0.01 mg KOH/g and 2.25 ⁇ 0.02 mg KOH/g, respectively.
  • the peroxide values were 2.36 ⁇ 0.02 and 2.57 ⁇ 0.01, respectively. Meq/kg.
  • the research results show that the rapid detection method of the degree of deterioration of the fried oil can accurately, quickly and conveniently detect the deterioration degree of soybean oil in the frying process.

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Abstract

一种炸用油变质程度的快速联合检测装置及其检测方法,属于食品质量与安全快速检测技术领域。该装置包括炸用油质量快速检测试纸(1)、滴管(2)、色差计(3)、介电分析仪(4)和待测样品(5);待测样品(5)与介电分析仪(4)连接;滴管(2)用于吸取待测样品(5)并滴在炸用油质量快速检测试纸上(1)进行检测;炸用油质量快速检测试纸(1)与色差计(3)连接。通过炸用油质量快速检测试纸(1)的显色分析,结合炸用油的介电常数值,将试纸条显色的色差值转化为炸用油的酸价及过氧化值数据。

Description

一种炸用油变质程度的快速联合检测装置及其检测方法 技术领域
本发明涉及一种炸用油变质程度的快速联合检测装置及其检测方法,属于食品质量与安全快速检测技术领域。
背景技术
炸用油中含有人体不能合成却又不可缺少的重要营养成分,其在油炸食品的加工过程中可提高食品的感官性质,获得油炸产品独特的风味和口感,膳食中的脂肪还有助于脂溶性维生素的吸收及提供人体必需脂肪酸,是人类膳食营养的重要组成部分。随着经济全球化的加剧以及人们健康饮食意识的提高,食品安全已影响到国际食品的生产和贸易过程,成为国际社会关注的焦点问题之一。并且随着企业生产的机械化水平的提高,寻找新型、快速、准确以及智能的炸用油变质程度的检测方法,是现代企业机械化智能化生产以及食品安全保障长期关注并急待解决的问题。
传统的炸用油质量的鉴别和检测仪器不但价格昂贵,而且操作和维护也极其烦琐,更由于其非便携性,不适用于企业机械化生产过程中以及其他检测部门快速准确的检测要求。因此,研制相应的炸用油变质程度的快速检测方法,对加快和完善企业生产的机械化和智能化进程,制定炸用油品质的快速检测标准,以及食品企业生产和安全控制需要具有重要意义。
目前对炸用油的变质程度的评价方法已经有很多研究报道,但还没有确定一种全球公认的检测方法,不同使用场所也有不同的方法和标准。目前国内检测机构或生产商所用的检测方法主要有试纸法、滴定法、质谱仪法、气相色谱法、核磁共振法、电导率法、电子鼻和电子舌法等。
郑晓等(公开号: CN 103983606 A)公开了一种便携式近红外食用油品质快速检测仪,通过检测仪提供的主控系统智能控制恒温样品池中食用油的温度,有效减少了温度对待测食用油的光谱图的影响,并智能控制近红外光谱仪采集样品池中食用油的光谱图,最终通过主控系统中的分析软件对采集的图谱进行快速分析,实现对食用油品质快速现场检测。本发明的不同之处是克服了红外设备采样要求高,重复性低的缺点,采样方便,简单,重现性好。
汤新华(公开号: CN 104949947 A)发明了一种食用油质量快速检测方法,该方法通过食用油在365nm光源激发下的荧光值与食用油中的营养成分建立相关性方程,判断当荧光值为100时,判定为所述食用油品质合格。涂斌(2016)研究了利用激光拉曼和激光近红外光谱的多源光谱数据融合技术,结合化学计量学方法,对食用油品种、花生油掺伪含量及真伪、脂肪酸成分含量检测方法,建立了基于拉曼和近红外多源光谱数据融合技术的食用油品种快速鉴别、食用油掺伪以及脂肪酸含量定量预测模型。本发明的不同之处是避免了大型昂贵的仪器,以及繁琐的前处理方式,操作简单,并且降低了检测装置成本。
李靖等(2013)研究了一种利用PEN3型电子鼻系统分析高温煎炸过程中大豆色拉油的品质变化规律,得到利用电子鼻系统快速分析辨别煎炸油新鲜程度及品质是可行的。张航等(2013)研究了一种利用电子舌传感器快速检测油茶籽油中掺杂棕榈油的方法,将所得样品数据用主成分、判别因子以及相似性法进行分析。结果表明,当选择ZZ与GA传感器时,主成分分析图识别指数达到87,能够明显鉴别出油茶籽油小比例的掺杂,表明电子舌在油脂检测方面有着较为广阔的应用前景。本发明的不同之处是不仅利用快速显色试纸对炸用油质量进行快速直观检测,并且通过显色试纸色差值与炸用油介电特性相结合的方式,更加直观准确的表征出炸用油酸价及过氧化值的数值参数,更加准确的鉴别炸用油的质量。
王乐(2008)在餐饮业废油脂掺伪可食用油的鉴别检测研究中研究了利用薄层层析显色试纸,并利用不同含量餐饮废油掺伪的可食用油制作出不同食用油质量的显色试纸比色卡,用于食用油的鉴别。本发明的不同之处在于,利用炸用油介电特性与显色试纸的色差值相结合,与炸用油的酸价以及过氧化值建立相关性方程,克服了仅用直观的判断带来的误差,并且准确、迅速的得到炸用油的质量指标值。
赵元黎等(2012)设计了一种采用传感器方法检测煎炸油极性组分的检测仪。该仪器利用叉指电极式电容传感器检测煎炸油介电常数的变化情况,通过一个电容/频率转换电路将电容的变化量转换为便于测量的频率形式,测得输出频率的变化情况反映煎炸油介电常数的变化情况。马荣朝等(公开号: CN 202305460 U)发明了一种基于介电特性的食用油品质快速检测仪,将电容传感器放入待测油脂中,其中信号转换器中嵌入数学模型以进行信号转换,按键操作15s后就能显示出样品四项指标参数值,并根据设定值进行选择报警。本发明的不同之处是利用快速检测试纸的显色反应更加直观的检测出炸用油的质量特征,同时与炸用油介电特性的相关性方程提高对炸用油质量检测的准确性。
虽然现在对炸用油品质的检测已经有多种检测方法,但是这些方法存在的主要问题有:样品预处理如分离、提取等耗时;仪器装置价格昂贵、操作复杂、费时费力;有机试剂对环境和人员健康的不利影响;耗时较长,操作繁琐,结果重现性较差;性能佳的仪器普遍大型,无法实现功能与携带方便相结合,很难做到检测仪器的高性价比;不能适用于现代社会对食品安全检测快速、准确、智能的要求。在食品的加工生产过程中,为了确保食用油的质量卫生,开发快速有效、方便简单、低成本、以及无损准确的检测方法具有重要的意义。本发明通过检测炸用油的变质过程中的酸价、过氧化值的变化,研制出指示炸用油变质程度的快速检测试纸,并通过试纸显色色差值的检测结果与炸用油介电常数数值相结合,将试纸条显色的色差值转化为炸用油的酸价以及过氧化值数据,进而对炸用油变质程度进行快速检测。具有简单快速、准确方便,低成本高灵敏度、无损智能的特点,适用于企业生产、检测部门对炸用油变质程度的快速检测,具有广阔的开发前景。
技术问题
本发明的目的在于克服上述不足之处,提供一种炸用油变质程度的快速显色-介电联合检测装置及其检测方法。
技术解决方案
按照本发明提供的技术方案,一种炸用油变质程度的快速联合检测装置,包括炸用油质量快速检测试纸、滴管、色差计、介电分析仪和待测样品;所述待测样品与介电分析仪连接;所述滴管用于吸取待测样品并滴在炸用油质量快速检测试纸上进行检测;炸用油质量快速检测试纸与色差计连接。
所述炸用油质量快速检测试纸包括载体和覆盖在载体上的显色层。
所述炸用油质量快速检测试纸的制备方法,步骤如下:
(1)载体制备:采用透明磨砂塑料片作为所述载体;
(2)显色层制备:称取5g G型薄层层析硅胶,在其中加入20mL质量浓度为0.3%的羧甲基纤维素钠溶液,于研钵中研匀;将研匀的溶液均匀涂抹在步骤(1)所述载体上,室温条件下放置3-5h晾干,最后将其浸入溴甲酚绿指示剂中进行染色,即得到炸用油质量快速检测试纸。
所述炸用油变质程度的快速联合检测方法,釆用显色-介电联合检测,步骤为:
(1)通过介电分析仪测定待测样品的介电特征,对待测样品的质量进行分析预测,通过前期试验建立的炸用油酸价以及过氧化值与炸用油的介电特征值之间建立的相关性方程,缩小炸用油显色试纸鉴定的精度;
(2)用滴管取1-2mL待测样品,均匀涂抹在炸用油质量快速检测试纸上,等待10s显色;观察炸用油质量快速检测试纸的颜色变化,并通过色差计读取色差值;
(3)通过得到的炸用油酸价以及过氧化值、色差值△E(x)的实际数据,进而对炸用油变质程度进行快速检测。
将炸用油酸价,过氧化值与色差值△E(x)进行相关性分析,得出相关性方程;其中以炸用油酸价为y轴,色差值△E为x轴得出的线性方程为y=0.346x-6.247,相关系数R 2为0.988;以过氧化值为y轴,色差值△E为x轴得出的线性方程为y=0.090x+0.486,相关系数R 2为0.985;
炸用油酸价,过氧化值与炸用油的介电特征值ε(x)之间建立相关性,得出相关性方程;其中以炸用油酸价为y轴,介电特征值ε为x轴得出的线性方程为y=1.186x-2.356,相关系数R 2为0.979;以过氧化值为y轴,介电特征值ε为x轴得出的线性方程为y=0.303x+1.510,相关系数R 2为0.975。
本方法经过多次的实验表明,检测样品炸用油酸价的准确率为 98.7%,说明快速检测法的准确率较高,重复性较好,能够起到对炸用油样品进行现场快速筛检的作用。快速检测法虽然准确率达不到100%,但是由于实验中所用快速检测分析仪采用色差传感器以及炸用油介电常数的分析,既克服了国标法实验室检测的繁琐程序,降低了实验成本; 又克服了单纯凭肉眼进行目测的直观误差,实现被检物质的定性定量检测,满足检测的简便、快速、智能和现场化的要求。
有益效果
本发明的有益效果:本发明方法通过检测炸用油的变质过程中的酸价及过氧化值的变化,研制出指示炸用油变质程度的快速检测试纸。并且通过色差计读取的色差值与炸用油的介电常数数据相结合,通过建立的相关性方程,得到炸用油酸价以及过氧化值的实际数据,进而对炸用油变质程度进行快速联合检测。
具有简单快速、准确方便,低成本高灵敏度的特点,适用于企业生产、检测部门对炸用油变质程度的快速检测,具有广阔的开发前景,整个过程操作简单快捷,大大提高了检测分析人员的工作效率,有利于食品企业提高生产的机械化程度;该方法性能稳定、准确率高、成本较低,适于现场的炸用油变质程度的快速检测。
附图说明
图1是本发明测试装置部件示意图。
图2-a是炸用油酸价与色差值△E(x)分析结果示意图。
图2-b是过氧化值质量指标值与色差值△E(x)分析结果示意图。
图3-a是炸用油酸价与介电特征值ε(x)分析结果示意图。
图3-b是过氧化值质量指标值与介电特征值ε(x)分析结果示意图。
附图标记说明:1、炸用油质量快速检测试纸;1-1、载体;1-2、显色层;2、滴管;3、色差计;4、介电分析仪;5、待测样品。
本发明的实施方式
实施例1 炸用油质量指标与快速检测试纸色差值△E(x)以及炸用油的介电特征值ε(x)之间相关性的建立:
将5L大豆油倒入电炸炉,控温在(200±2)℃进行无料空炸,在煎炸80h时间内每隔8h取样300mL,取10个标准样品,分别测量炸用油样品的酸价、过氧化值、介电特性, 以及采用快速检测试纸对标准样品进行显色分析色差值△E(x),将得到的炸用油酸价,过氧化值质量指标值与快速检测试纸的色差值△E(x)进行相关性分析;
其中炸用油酸价与色差值△E(x)分析结果如图2-a所示,过氧化值质量指标值与色差值△E(x)分析结果如图2-b所示;得出相关性方程分别为:y=0.346x-6.247,y=0.090x+0.486,相关系数R 2分别为0.988和0.985;
将炸用油酸价,过氧化值质量指标值与炸用油的介电特征值ε(x)之间建立相关性,炸用油酸价与介电特征值ε(x)分析结果如图3-a所示,过氧化值质量指标值与介电特征值ε(x)分析结果如图3-b所示;得出相关性方程分别为:y=1.186x-2.356,y=0.303x+1.510,相关系数R 2分别为0.979和0.975。
因此说明将显色试纸色差值与炸用油介电特性相结合,使炸用油酸价及过氧化值的检测更加直观和准确。
实施例2  新鲜棕榈油和煎炸过的棕榈油变质程度的快速检测
(1)用吸管将新鲜棕榈油和煎炸过的棕榈油各取1-2mL,分别均匀涂抹在自制炸用油质量快速检测试纸上,等待10 s进行显色,每个样品重复3次;
(2)对步骤(1)中样品采用网络分析仪进行介电常数的测定,具体数值分别为2.178±0.004和2.916±0.005。
(3)对步骤(1)中显色的试纸条进行色差分析,结合炸用油介电常数数据,通过色差值以及介电常数值与炸用油酸价、过氧化值的相关性方程,得到炸用油酸价以及过氧化值的实际数据,进而对炸用油变质程度进行快速检测。
检测结果表明,新鲜棕榈油的显色试纸显色为深蓝色、煎炸过的棕榈油的显色试纸显色为蓝绿色,经过色差值和介电常数相关性方程得到的新鲜棕榈油和煎炸过的棕榈油的显色色差值分别为17.65±0.04和18.19±0.03,酸价分别为0.25±0.01 mg KOH/g和1.06±0.01 mg KOH/g,过氧化值分别为2.12±0.02和2.36±0.01 meq/kg。
研究结果表明,该炸用油变质程度的快速检测方法能够准确、快速、方便的检测棕榈油在煎炸过程中的变质程度。
实施例3:新鲜大豆油和煎炸过的大豆油变质程度的快速检测
(1)用吸管将新鲜大豆油和煎炸过的大豆油各取1-2mL,分别均匀涂抹在自制炸用油质量快速检测试纸上,等待10 s进行显色,每个样品重复3次;
(2)对步骤(1)中样品采用网络分析仪进行介电常数的测定,具体数值分别为2.446±0.003和3.746±0.007。
(3)对步骤(1)中显色的试纸条进行色差分析,结合炸用油介电常数数据,通过色差值以及介电常数值与炸用油酸价、过氧化值的相关性方程,得到炸用油酸价以及过氧化值的实际数据,进而对炸用油变质程度进行快速检测。
检测结果表明,新鲜大豆油的显色试纸显色为靛蓝色和煎炸过的大豆油的显色试纸显色为黄绿色,经过色差计和检测分析程序得到的新鲜大豆油和煎炸过的大豆油的显色色差值分别为17.85±0.02和18.99±0.04,酸价分别为0.54±0.01 mg KOH/g和2.25±0.02 mg KOH/g,过氧化值分别为2.36±0.02和2.57±0.01 meq/kg。
研究结果表明,该炸用油变质程度的快速检测方法能够准确、快速、方便的检测大豆油在煎炸过程中的变质程度。

Claims (5)

  1. 一种炸用油变质程度的快速联合检测装置,其特征在于:包括炸用油质量快速检测试纸(1)、滴管(2)、色差计(3)、介电分析仪(4)和待测样品(5);所述待测样品(5)与介电分析仪(4)连接;所述滴管(2)用于吸取待测样品(5)并滴在炸用油质量快速检测试纸(1)上进行检测;炸用油质量快速检测试纸(1)与色差计(3)连接。
  2. 根据权利要求1所述炸用油变质程度的快速联合检测装置,其特征在于:所述炸用油质量快速检测试纸(1)包括载体(1-1)和覆盖在载体(1-1)上的显色层(1-2)。
  3. 权利要求2所述炸用油质量快速检测试纸的制备方法,其特征在于步骤如下:
    (1)载体制备:采用透明磨砂塑料片作为所述载体(1-1);
    (2)显色层制备:称取5g G型薄层层析硅胶,在其中加入20mL质量浓度为0.3%的羧甲基纤维素钠溶液,于研钵中研匀;将研匀的溶液均匀涂抹在步骤(1)所述载体(1-1)上,室温条件下放置3-5h晾干,最后将其浸入溴甲酚绿指示剂中进行染色,即得到炸用油质量快速检测试纸。
  4. 权利要求1所述检测装置用于炸用油变质程度的快速联合检测方法,其特征在于釆用显色-介电联合检测,步骤为:
    (1)通过介电分析仪(4)测定待测样品(5)的介电特征值ε,对待测样品(5)的质量进行分析预测,通过前期试验建立的炸用油酸价以及过氧化值与炸用油的介电特征值之间建立的相关性方程,缩小炸用油显色试纸鉴定的精度;
    (2)用滴管(2)取1-2mL待测样品(5),均匀涂抹在炸用油质量快速检测试纸(1)上,等待10s显色;观察炸用油质量快速检测试纸(1)的颜色变化,并通过色差计(3)读取色差值;
    (3)通过得到的炸用油酸价以及过氧化值、色差值△E(x)的实际数据,进而对炸用油变质程度进行快速检测。
  5. 根据权利要求4所述炸用油变质程度的快速联合检测的方法,其特征在于:将炸用油酸价,过氧化值与色差值△E(x)进行相关性分析,得出相关性方程;其中以炸用油酸价为y轴,色差值△E为x轴得出的线性方程为y=0.346x-6.247,相关系数R 2为0.988;以过氧化值为y轴,色差值△E为x轴得出的线性方程为y=0.090x+0.486,相关系数R 2为0.985;
    炸用油酸价,过氧化值与炸用油的介电特征值ε(x)之间建立相关性,得出相关性方程;其中以炸用油酸价为y轴,介电特征值ε为x轴得出的线性方程为y=1.186x-2.356,相关系数R 2为0.979;以过氧化值为y轴,介电特征值ε为x轴得出的线性方程为y=0.303x+1.510,相关系数R 2为0.975。
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