RU2782156C1 - Model for predicting the adhesion strength of cigarette tipping paper on the lip, method for building the model, and method for predicting by means thereof - Google Patents

Abstract

FIELD: testing.

SUBSTANCE: invention relates to a method for building a model for predicting the adhesion force of cigarette tipping paper on the lip. Method for building a model for predicting the adhesion force of cigarette tipping paper on the lip includes stage (1): using a testing tool to measure the adhesion force, stage (2): determining the dynamic friction coefficient of the cigarette tipping paper, stage (3): determining the thickness of the cigarette tipping paper, stage (4): determining the density of the cigarette tipping paper, and stage (5): conducting regression analysis using the dynamic friction coefficient (M), density (D), and thickness (H) of the cigarette tipping paper as variables and using the adhesion force of the tipping paper on the lip as a reaction variable (Y) in order to create a model for predicting the adhesion force of the cigarette tipping paper on the lip.

EFFECT: raised accuracy of controlling the quality and improving the products.

12 cl, 5 dwg

Description

FIELD OF TECHNOLOGY TO WHICH THE INVENTION RELATES

The present invention relates generally to the technical field of analysis and detection, and more particularly to a model for predicting the force of sticking of cigarette tipping paper to a lip, a method for constructing the same, and a method for predicting with it.

BACKGROUND OF THE INVENTION

The cigarette filter consists mainly of cellulose acetate, ficella and rim paper. Rim paper, also known as balsamic paper, is used to wrap the outside of the filter tip and glue the filter tip to the end of the cigarette rod. Edge paper is a kind of decorative paper obtained by printing, coating and processing base paper. Edge paper usually has a corky or matte white appearance and has a decorative function. The tipping paper is in direct contact with the smoker's lips and typically only paint or ink is printed on the tipping paper. In dry weather, when a person smokes a cigarette, the tip paper may be wetted with a small amount of saliva, and then during smoking, the tip paper dries slowly so that the saliva protein remaining on the lips will create the sticking effect of the tip paper, causing the tip paper to stick to the tip of the filter. to the skin of the lips. As a consequence, bleeding of the lip due to the rupture is possible. After smoking, the tip of the filter cannot be spit out freely, which greatly affects the sensations of the smoker.

At present, the research of cigarette filter rim paper at home and abroad is mainly focused on its pyrolysis performance, low flammability, harmful element content, cigarette paper modification and carbon monoxide emission capability after modification, toxicity, safety evaluation, etc. However, studies on lip adhesion strength or degree of lip adhesion are not conducted. Considering the aspect of sticking to the lip, the composition and method of making the tipping paper are improved, but there is no well-defined detection method. For example, in the invention patent "Scented health-care tipping paper capable of avoiding sticking to lips and preventing lips and tongue from drying and preparation method thereof" by Feng Li, the manufacturing method and composition of tipping paper are disclosed, but only strength is found when the effect is found. when stretching in the longitudinal direction and the air permeability of the base paper, and the detection of the force of adhesion to the lip is not mentioned. The invention patent "Anti-pollution filter tip of anti-sticking lip" discloses that a protective film is applied to the outside of the rim paper, but this does not prove the actual advantageous results. Invention patent of "Multi-functional Imitation Cork Paper", Zhejiang Techmay New Materials Co., Ltd., aims to prevent sticking to the lip, add fragrance and lower flammability, etc. The outer layer of cork imitation paper is composed of fruit waterproof layer and protective film layer, but the result of the lip sticking prevention test is not mentioned. Due to the lack of appropriate industry standards, cigarette manufacturers evaluate and judge the sticking effect by personally tasting cigarettes, which is associated with great subjectivity and inaccuracy. In order to accurately determine the tack/strength to the lip under different treatments and different types of tipping paper, it is imperative to develop and implement appropriate methods of objective analysis and testing.

SUMMARY OF THE INVENTION

The purpose of the present invention is to overcome the shortcomings of the prior art and to provide a model for predicting the lip stick strength of cigarette liner paper, a method for constructing it, and a method for predicting with it. Using this method, the dynamic friction coefficient and the density value are measured and determined from conventional physical indicators of cigarette liner paper to accurately predict the sticking force of cigarette liner paper to the lip, and the method is simple, practical, and easy to popularize and apply. When checking the accuracy of the proposed model, it was found that the predicted and measured values lie mainly near the 1:1 line, the R ² index is 0.99, and the normalized root mean square error (nRMSE) is 2.64%. The present invention can accurately predict the stickiness of cigarette liner paper to the lip, reliably avoid the influence of subjective factors and characteristics of differences introduced by the traditional organoleptic evaluation method in self-smoking, and has advantages in material selection, quality control and product improvement in the tobacco industry.

To achieve the above object, the technical solution adopted in the present invention is as follows:

A model for predicting the adhesion strength of cigarette liner paper to the lip, said model being the following:

if the thickness of the cigarette tipping paper is in the range (0.069-0.112 mm), Y _{lip adhesion force} = 0.205 +1.038 × M _{coefficient of friction} ;

if the thickness of the cigarette tipping paper is not in the range (0.069-0.112 mm), Y _{lip adhesion force} = -0.335 +1.181 × M _{friction coefficient} ×D _density ;

where Y is _{the sticking force to the lip} is the predicted sticking force of the cigarette liner paper to the lip; M _{coefficient of friction} is the coefficient of dynamic friction of the cigarette tipping paper; and D _density is the density of the cigarette tipping paper, that is, the mass in grams per unit area.

In addition, a method for constructing the above model for predicting the adhesion force of cigarette tipping paper to the lip is provided, including:

step (1): using a tester to measure the sticking force, where the sticking force is the force between the printed surfaces of different tipping paper and the artificial mouth skin glued with artificial saliva, and calculating the sticking force per unit area as the measured sticking force of the cigarette tipping paper to the lip wherein the tester is a peel strength tester, a tensile tester, or a dynamic friction coefficient tester;

step (2): determining the coefficient of dynamic friction of the cigarette tipping paper;

step (3): determining the thickness of the cigarette tipping paper;

step (4): determining the density of the cigarette tipping paper; and

Step (5): Performing regression analysis using dynamic friction coefficient (M), density (D), and thickness (H) of cigarette tipping paper as variables, and using sticking force of tipping paper to the lip as reaction variable (Y) to obtain a predictive model adhesion force of cigarette liner paper to the lip.

Further, preferably in step (1), the cigarette tip paper has a width range of 1-1000 mm and a length range of 1-1000 mm; the artificial mouth skin is cut into rectangles of the same size as the cigarette liner paper, one side of the cut artificial mouth skin is adhered to one side of the cigarette liner paper by the action of artificial saliva, the adhesion area is determined, and after being left to dry to constant weight, the tester is used to measure the maximum peeling force of the liner paper and artificial lips at the time of separation, and the maximum peeling force is used as the sticking force of the liner paper to the lip.

In addition, the drying time is preferably 1-1800 seconds.

Furthermore, preferably, after being left to dry to a constant weight, the other side of the rim paper and the other side of the artificial mouth skin, not glued together, are respectively clamped in two vices of the tester, the distance between the two vices and their relative speed of movement being set as follows: to measure the maximum peel force at the moment the rim paper separates from the artificial lip; the two vise of the tester can completely clamp the cigarette rim paper and artificial mouth skin; the tester has a load range of 0-200 N and a resolution greater than or equal to 0.01 N; and the distance between the two vise of the tester is 5-500mm, and the travel speed is 1-500mm/min.

In addition, preferably, in step (1), the artificial saliva contains sodium chloride, potassium chloride, calcium chloride, dibasic sodium phosphate, magnesium chloride, urea, glucose, mucin, amylase, acid phosphatase and lysozyme; the pH value of artificial saliva is 5.5–7.5; and the volume range of artificial saliva used is 1-1000 µl.

Further preferably, in step (1), the artificial saliva contains 1.40 mmol/l sodium chloride, 0.5 mmol/l potassium chloride, 0.1 mmol/l calcium chloride, 0.15 mmol/l monosodium phosphate, 0.025 mmol/l magnesium chloride, 0.09 mmol/l urea, 0.2 mmol/l glucose, 2.7 mmol/l bovine submandibular salivary gland mucin, 2.5 U/ml amylase, 0.004 U/ml acidic phosphatase and 0.7 U/ml lysozyme.

Further preferably, the material of the artificial mouth skin is a soft medical silicone rubber skin, an active composite skin with an epidermal cell layer, a polyvinyl chloride artificial skin, a polyurethane dry artificial skin, or a polyolefin artificial skin.

In addition, the coefficient of dynamic friction of the cigarette tipping paper in step (2) is preferably determined in accordance with GB10006-88 “Plastics. Film and sheets. Determination of friction coefficients» ;

the thickness of the cigarette tipping paper in step (3) is preferably determined in accordance with GB/T 451.3-2002 “Paper and board. Determination of thickness " ; and

the density of the cigarette tipping paper in step (4) is preferably determined in accordance with GB/T 451.2-2002 “Paper and board. Determination of Density" .

Also provided is a method for predicting cigarette lip sticking force of cigarette liner paper, which uses the above cigarette lip sticking force prediction model or the cigarette lip sticking force prediction model built by the above cigarette lip sticking force prediction model, including in particular:

measuring the thickness, dynamic friction coefficient, and mass in grams per unit area of the cigarette tipping paper, and then inputting the thickness, dynamic friction coefficient, and mass in grams per unit area into the lip sticking force prediction model of the cigarette tipping paper to calculate to obtain the sticking force of the cigarette tip paper to the lip.

Compared with the prior art, the present invention has the following advantages:

1. The invention provides a prediction model for the lip sticking force of cigarette liner paper, a method for constructing it, and a method for predicting with it, which can objectively and accurately quantify the lip sticking force of cigarette liner paper, effectively avoid traditional fuzzy concepts such as the feeling of sticking to the lip. and unpleasant spitting sensation obtained by sensory evaluation, and avoid the disadvantages of strong subjective factors, large differences in evaluation results, harm to human health, etc.

2. The method of the present invention performs stepwise regression analysis of the lip stick force and the values of the dynamic friction coefficient and density of the cigarette tipping paper to obtain a predictive model of the sticking force of the cigarette tipping paper to the lip. In this method, in order to better predict the sticking strength of cigarette tipping paper to the lip, conventional physical indicators, i.e., dynamic friction coefficient and density value of cigarette tipping paper, are determined, and this method is simple, practical, and easy to popularize and apply.

3. When checking the accuracy of the model in accordance with the present invention, it was found that the predicted and measured values lie mainly near the 1:1 line, the R ² index is 0.99, and the normalized root mean square error (nRMSE) is 2.64%. This method can accurately quantify the sticking strength of cigarette liner paper to the lip, greatly reduces the cost of detection, is objective and efficient, and has certain advantages in material selection, quality control, and product improvement in the tobacco industry.

BRIEF DESCRIPTION OF GRAPHICS

FIG. 1 is the first schematic representation of the test instrument;

FIG. 2 is the second schematic representation of the test apparatus;

on these figures 1 - vice; 2 - holders; 3 - cigarette rim paper; 4 - artificial saliva for spreading; 5 - artificial skin of the mouth; 6 - intelligent panel containing force sensors and displacement sensors; 7 - device for collecting data on force and displacement;

FIG. 3 is a scatterplot plot of the correlation between thickness and lip adhesion strength of cigarette liner paper;

FIG. 4 is a scatterplot plot of the correlation between density and lip adhesion strength of cigarette liner paper;

FIG. 5 illustrates a graph comparing the predicted value and the measured value of the sticking strength of cigarette liner paper to the lip.

DETAILED DESCRIPTION OF EMBODIMENTS

Hereinafter, the present invention will be described in detail on examples of variants of its implementation.

Those skilled in the art will appreciate that the following embodiments are used solely to explain the present invention and should not be construed as limiting the scope of the present invention. If in these embodiments, some specific technology or conditions are not specified, these embodiments must be implemented in accordance with the technology or conditions described in the literature in the art or in accordance with the product specifications. Unless the manufacturer of the materials or equipment used is specified, those materials or equipment are all common items that can be purchased.

Unless specifically stated otherwise in the following embodiments described, "percent" means "percent by weight".

Embodiment 1

A model for predicting the adhesion strength of cigarette liner paper to the lip, said model being the following:

if the thickness of the cigarette tipping paper is in the range (0.069-0.112 mm), Y _{lip adhesion force} = 0.205 +1.038 × M _{coefficient of friction} ;

if the thickness of the cigarette tipping paper is not in the range (0.069-0.112 mm), Y _{lip adhesion force} = -0.335 +1.181 × M _{friction coefficient} ×D _density ;

where Y is _{the sticking force to the lip} is the predicted sticking force of the cigarette liner paper to the lip; M _{coefficient of friction} is the coefficient of dynamic friction of the cigarette tipping paper; and D _density is the density of the cigarette tipping paper, that is, the mass in grams per unit area.

Embodiment 2

A method for constructing a model for predicting the sticking force of cigarette rim paper to the lip, comprising:

step (1): using a tester to measure the adhesion force with which the printed surfaces of different tipping papers and the artificial mouth skin are bonded by artificial saliva, and calculating the adhesive force per unit area as the measured adhesive force of the cigarette tipping paper to the lip; wherein the tester is a peel strength tester;

step (2): determining the coefficient of dynamic friction of the cigarette tipping paper;

step (3): determining the thickness of the cigarette tipping paper;

step (4): determining the density of the cigarette tipping paper; and

Step (5): Performing regression analysis using dynamic friction coefficient (M), density (D), and thickness (H) of cigarette tipping paper as variables, and using sticking force of tipping paper to the lip as reaction variable (Y) to obtain a predictive model adhesion force of cigarette liner paper to the lip.

Embodiment 3

The method for constructing a model for predicting the sticking strength of cigarette tipping paper to the lip includes the following step.

step (1): using a tester to measure the adhesion force with which the printed surfaces of different tipping papers and the artificial mouth skin are bonded by artificial saliva, and calculating the adhesive force per unit area as the measured adhesive force of the cigarette tipping paper to the lip; wherein the tester is a tensile tester.

In particular, the artificial mouth skin is cut into rectangles of the same size as the cigarette rim paper. One side of the cut artificial mouth skin is adhered to one side of the cigarette rim paper by the action of the artificial saliva. Determine the adhesion area. After being allowed to dry to constant weight, a tester is used to measure the maximum peel force of the tipping paper and artificial lips at the time of separation, and the maximum peeling force is used as the sticking force of the tipping paper. The cigarette tipping paper has a width of 1 mm and a length of 1 mm. The drying time is 1 s. The artificial saliva contains sodium chloride, potassium chloride, calcium chloride, monosubstituted sodium phosphate, magnesium chloride, urea, glucose, mucin, amylase, acid phosphatase and lysozyme. The pH value of artificial saliva is 5.5. The volume of artificial saliva used is 1 µl. The spreading area is 0.5 × 1 = 0.5 mm ² . The material of artificial mouth skin is soft skin made of medical silicone rubber.

Step (2): Determining the coefficient of dynamic friction of the cigarette tipping paper.

Step (3): Determining the thickness of the cigarette tipping paper.

Step (4): determination of the density of the cigarette end paper.

Step (5): Performing a regression analysis using the coefficient of dynamic friction (M), density (D), and thickness (H) of the cigarette tipping paper as variables, and using the sticking strength of the tipping paper to the lip as the reaction variable (Y) to obtain a predictive model adhesion force of cigarette liner paper to the lip.

Embodiment 4

The method for constructing a model for predicting the sticking strength of cigarette rim paper to the lip includes the following steps.

step (1): using a tester to measure the adhesion force with which the printed surfaces of different tipping papers and the artificial mouth skin are bonded by artificial saliva, and calculating the adhesive force per unit area as the measured adhesive force of the cigarette tipping paper to the lip; wherein the tester is a tensile tester.

In particular, the artificial mouth skin is cut into rectangles of the same size as the cigarette rim paper. One side of the cut artificial mouth skin is adhered to one side of the cigarette rim paper by the action of the artificial saliva. Determine the adhesion area. After being allowed to dry to constant weight, a tester is used to measure the maximum peel force of the tipping paper and artificial lips at the time of separation, and the maximum peeling force is used as the sticking force of the tipping paper. Cigarette rim paper has a width of 1000 mm and a length of 1000 mm. The time left to dry is 1800 s. Artificial saliva contains 1.40 mmol/l sodium chloride, 0.5 mmol/l potassium chloride, 0.1 mmol/l calcium chloride, 0.15 mmol/l monosubstituted sodium phosphate, 0.025 mmol/l magnesium chloride, 0.09 mmol/L urea, 0.2 mmol/L glucose, 2.7 mmol/L bovine submandibular salivary gland mucin, 2.5 U/mL amylase, 0.004 U/mL acid phosphatase and 0.7 U/mL lysozyme . The volume of artificial saliva used is 1000 µl. The spreading area is 500 × 1000 = 500000 mm ² . The artificial skin material of the mouth is an active composite skin with a layer of epidermal cells. The tester has a load range of 0-200 N and a resolution greater than or equal to 0.01 N. The distance between the two jaws of the tester is 500 mm and the travel speed is 500 mm/min.

Step (2): Determining the coefficient of dynamic friction of the cigarette tipping paper.

Step (3): Determining the thickness of the cigarette tipping paper.

Step (4): determination of the density of the cigarette end paper.

Step (5): Performing a regression analysis using the coefficient of dynamic friction (M), density (D), and thickness (H) of the cigarette tipping paper as variables, and using the sticking strength of the tipping paper to the lip as the reaction variable (Y) to obtain a predictive model adhesion force of cigarette liner paper to the lip.

Embodiment 5

The method for constructing a model for predicting the sticking strength of cigarette rim paper to the lip includes the following steps.

Step (1): using a tester to measure the adhesion force with which the printed surfaces of different tipping papers and the artificial mouth skin are bonded by artificial saliva, and calculating the adhesive force per unit area as the measured sticking force of the cigarette tipping paper to the lip; wherein the test apparatus is a peel strength test apparatus.

In particular, the artificial mouth skin is cut into rectangles of the same size as the cigarette rim paper. One side of the cut artificial mouth skin is adhered to one side of the cigarette rim paper by the action of the artificial saliva. Determine the adhesion area. After allowing to dry to constant weight, the other side of the rim paper and the other side of the artificial mouth skin, not glued together, are respectively clamped in two vise of the test apparatus. The distance between the two vices and their relative moving speed are set to measure the maximum peeling force at the time of separation of the tip paper from the artificial lip, and the maximum peeling force is used as the sticking force of the tip paper. Cigarette rim paper is 200mm wide and 100mm long; the drying time is 300 s. Artificial saliva contains 1.40 mmol/l sodium chloride, 0.5 mmol/l potassium chloride, 0.1 mmol/l calcium chloride, 0.15 mmol/l monosubstituted sodium phosphate, 0.025 mmol/l magnesium chloride, 0.09 mmol/L urea, 0.2 mmol/L glucose, 2.7 mmol/L bovine submandibular salivary gland mucin, 2.5 U/mL amylase, 0.004 U/mL acid phosphatase and 0.7 U/mL lysozyme . The volume of artificial saliva used is 100 µl. The spreading area is 90 × 200 = 18000 mm ² . The material of the artificial mouth skin is polyolefin artificial skin. The tester has a load range of 0-200 N and a resolution greater than or equal to 0.01 N. The distance between the two jaws of the tester is 5 mm and the travel speed is 1 mm/min.

Step (2): Determining the coefficient of dynamic friction of the cigarette tipping paper.

Step (3): Determining the thickness of the cigarette tipping paper.

Step (4): determination of the density of the cigarette end paper.

Step (5): Performing a regression analysis using the coefficient of dynamic friction (M), density (D), and thickness (H) of the cigarette tipping paper as variables, and using the sticking strength of the tipping paper to the lip as the reaction variable (Y) to obtain a predictive model adhesion force of cigarette liner paper to the lip.

The coefficient of dynamic friction of the cigarette tipping paper in step (2) is determined in accordance with GB10006-88 "Plastics. Film and sheets. Determination of friction coefficients" . The thickness of the cigarette tipping paper in step (3) is determined in accordance with GB/T 451.3-2002 “Paper and board. Determination of thickness" . The density of the cigarette tipping paper in step (4) is determined in accordance with GB/T 451.2-2002 “Paper and board. Determination of Density" .

Embodiment 6

A method for predicting cigarette lip sticking force of cigarette liner paper, which uses the above cigarette lip sticking force prediction model or a cigarette lip sticking force prediction model built by the above cigarette liner paper lip sticking force prediction model, including: measuring the thickness, dynamic friction coefficient, and mass in grams per unit area of the cigarette tipping paper, and then inputting the thickness, dynamic friction coefficient, and mass in grams per unit area into the lip sticking force prediction model of the cigarette tipping paper to calculate to obtain the sticking force of the cigarette tip paper to the lip.

Application example 1

Step (1): Twenty-five pieces of various cigarette papers manufactured by China Tobacco Yunnan Industrial Co., Ltd are prepared and accurately cut to a width of 15 mm and a length of 50 mm. The artificial saliva was prepared according to Table 1. As the artificial mouth skin, medical silicone rubber soft skin was prepared with a thickness of 1 mm, and the artificial mouth skin was cut into 15 mm wide and 50 mm long. 10 µl of artificial saliva is accurately transferred using a microinjection syringe and evenly smeared with it on the artificial skin of the mouth. Spreading area \u003d 10 × 15 \u003d 150 mm ² . The surface printed with cigarette liner paper and the artificial mouth skin are glued with artificial saliva and left to dry for 2 minutes. A tensile tester M250-2.5 CT manufactured by KARL, Germany was chosen as the test equipment. As shown in FIG. 1, the other end of the glued rim paper and the other end of the artificial mouth skin are respectively clamped between two vise holders of the tensile tester, the vise holders being set at a distance of 50 mm and the travel speed being set to 50 mm/min. Two vices are installed on an intelligent panel (existing equipment) containing a force value sensor and a displacement sensor, and a force value/displacement data acquisition system (usually a computer) is connected to an intelligent panel containing a force value sensor and a displacement sensor, which can collect data on changing the force value and moving in real time. The maximum force measured at the moment when the rim paper separates from the artificial lips is the sticking force. The adhesion force to the lip is calculated by the formula: F=adhesion force (N)/adhesion area (mm ² ).

Table 1. Composition of artificial saliva

Composition Concentration (mg/ml) Composition Concentration (mg/ml) NaCl 1.4 Glucose 0.2 KCl 0.5 Mucin 2.7 _CaCl2 0.1 Amylase 2.5* _{NaH2PO4 _} 0.15 Acid phosphatase 0.004* MgCl ₂ 0.025 Lysozyme 0.7* Urea 0.09 Adjust pH to 7.0 before adding protein

Note: * in units/ml

Step (2): Dynamic friction coefficients of twenty-five samples were determined in accordance with GB10006-88 Plastics. Film and sheets. Determination of friction coefficients" .

Step (3): thickness values of twenty-five samples are determined in accordance with GB/T 451.3-2002 “Paper and board. Determination of thickness" .

Step (4): The density values of twenty-five samples are determined in accordance with GB/T 451.2-2002 “Paper and board. Determination of Density" .

Step (5): test results are shown in Table 2.

Table 2. Sample test results

Sample Adhesion force (N/mm ² ) Dynamic friction coefficient Thickness (mm) Density (g/m ² ) Relative standard deviation (%) one 1.96×10 ^-3 0.409 0.043 39.28 1–6.9 2 0.68×10 ^-3 0.254 0.047 42.3 1.2–7.2 3 1.20×10 ^-3 0.374 0.042 36.9 1.3–7.7 four 1.29×10 ^-3 0.404 0.042 38.7 0.5–9.2 5 2.90×10 ^-3 0.432 0.044 39.3 0.2–9.8 6 1.45×10 ^-3 0.293 0.045 38.5 0.6–8.2 7 3.95×10 ^-3 0.541 0.043 36.34 1.2–9.2 eight 0.91×10 ^-3 0.287 0.046 41.54 1.5–10 9 4.40×10 ^-3 0.6 0.043 37.54 1.4–9.3 ten 0.87×10 ^-3 0.3 0.042 42.1 0.9–8.2 eleven 5.93×10 ^-3 0.75 0.04 37.1 1.6–8.4 12 1.10×10 ^-3 0.373 0.046 42.4 1.4–9.6 13 4.04×10 ^-3 0.608 0.04 36.4 0.2–7.2 fourteen 1.20×10 ^-3 0.367 0.042 39.62 1.5–8.5 fifteen 1.21×10 ^-3 0.306 0.04 37.94 1.0–9.8 16 1.32×10 ^-3 0.463 0.04 39.06 1.7–9.2 17 1.31×10 ^-3 0.285 0.044 41.28 1.0–7.7 eighteen 2.90×10 ^-3 0.266 0.044 39.32 1.6–8.2 19 2.97×10 ^-3 0.323 0.04 38.54 2.2–9.7 twenty 3.47×10 ^-3 0.381 0.093 92 3.2–10.0 21 6.91×10 ^-3 0.884 0.11 83.3 2.4–9.4 22 0.78×10 ^-3 0.264 0.042 36.4 1.2–9.3 23 8.17×10 ^-3 0.943 0.1 89.45 1.7–7.9 24 4.25×10 ^-3 0.339 0.084 89.5 2.1–9.4 25 3.40×10 ^-3 0.292 0.069 53.7 1.4–8.8

As can be seen from Table 3, all four indicators, i.e. friction coefficient, thickness, density and sticking force to the lip, have a relatively high degree of correlation with each other, and the correlation between the coefficient of friction and the sticking force to the lip is relatively high (0.897 **). Moreover, as can be seen from FIG. 3 and 4, due to the more powerful aggregation of the samples along the thickness and density gradient, the correlation between thickness and lip adhesion force and between density and lip adhesion force can mainly be broken down into two levels of thickness ranges (0.04–0.047 , 0.069–0.112) and two levels of density ranges (36.34–42.4, 53.7–92), with correlations in the thickness range (0.04–0.047) and density ranges (36.34–42.4, 83.7–92) are negligible, while there is a definite correlation in the thickness range (0.069–0.112). Therefore, the correlations between thickness and lip adhesion strength and between density and lip adhesion strength in the thickness range (0.069–0.112) can be further investigated.

Table 3. Overview of correlation coefficients among the four indicators

Friction coefficient Thickness Density Sticking force on the lip Friction coefficient Pearson correlation one 0.618** 0.520** 0.897** Significance (two-tailed) 0.001 0.007 0.000 N 26 26 26 26 Thickness Pearson correlation 0.618** one 0.966** 0.749** Significance (two-tailed) 0.001 0 0 N 26 26 26 26 Density Pearson correlation 0.520** 0.966** one 0.683** Significance (two-tailed) 0.007 0.000 0.000 N 26 26 26 26 Sticking force on the lip Pearson correlation 0.897** 0.749** 0.683** one Significance (two-tailed) 0.000 0.000 0.000 N 26 26 26 26 ** Significant correlation at the 0.01 level (two-tailed).

Note: There is nothing in space in statistical software.

(1) Using the stepwise regression equation for friction coefficient, thickness, density, and lip adhesion force, it is found that there is a strong correlation between thickness and density, as well as a multicollinear relationship between thickness and friction coefficient. Therefore, the thickness element in the established stepwise regression equation is omitted, and the coefficient of friction and density are left as representative elements for establishing the model of the binary regression equation, i.e., equation (1) for the sticking force to the lip:

............ (1)

............ (1)

where:

Y is the sticking force of the rim paper to the lip, the unit of measurement is newtons per square millimeter (N / mm ² );

M is the coefficient of dynamic friction, dimensionless; and

D is the density of the tipping paper, the unit of measurement is grams per square meter (g / m ² ).

(2) Using the stepwise regression equation for friction coefficient, thickness, density, and lip adhesion force, it is found that there is a strong correlation between thickness and density, as well as a multicollinear relationship between thickness, density, and coefficient of friction. Therefore, the thickness element and the density element in the established stepwise regression equation are excluded, and the coefficient of friction is left as a representative element for establishing a model of the binary regression equation, i.e., equation (2), for the sticking force to the lip, which shows that for a thicker For tipping paper, the correlation between the coefficient of dynamic friction and the sticking force to the lip is considered to be strong:

·............. (2)

· ............. (2)

where:

Y is the sticking force of the rim paper to the lip, the unit of measurement is newtons per square millimeter (N / mm ² ); and

M is the coefficient of dynamic friction, dimensionless.

Step (6): use and test the model of sticking strength of tip paper to the lip.

Ten kinds of tipping paper with different printing processing and different grades are selected, the dynamic friction coefficient of the tipping paper is determined, and then the sticking force of the tipping paper to the lip is predicted from Equation (1). The density of ordinary tipping paper is usually no higher than 0.069 mm, so model (2) will not be used and will not be tested. In addition, the same specimens were tested to simulate the lip adhesion force according to the peel strength tester, and Table 4 shows the comparative results.

Table 4. Comparison of predicted and measured values of the sticking strength of cigarette tipping paper to the lip

Sample Dynamic friction coefficient Density (g/m ² ) Predictable adhesion force (N/mm ² ) Actual adhesion force (N/mm ² ) nRMSE (%) one 0.404 38.5 3.36 × 10 ^-1 3.20 × 10 ^-1 2.38 2 0.293 38.5 2.04 × 10 ^-1 1.98 × 10 ^-1 1.38 3 0.541 36.34 4.86 × 10 ^-1 4.59 × 10 ^-1 2.81 four 0.432 39.3 3.72 × 10 ^-1 3.54 ×10 ^-1 2.44 5 0.287 41.54 2.12 × 10 ^-1 2.32 × 10 ^-1 4.59 6 0.6 37.54 5.61 × 10 ^-1 5.45 × 10 ^-1 1.47 7 0.341 42.1 2.78 × 10 ^-1 2.98 × 10 ^-1 3.43 eight 0.55 37.1 5.00 × 10 ^-1 4.89 × 10 ^-1 1.12 9 0.373 42.44 3.18 × 10 ^-1 3.23 × 10 ^-1 0.83 ten 0.484 83.35 6.53 × 10 ^-1 6.48 × 10 ^-1 0.41

Ten of the above representative test sets were selected to test the accuracy of the model. FIG. 5 is a comparison of predicted and measured values. As can be seen in this figure, the data points lie near the 1:1 line, R ² is 0.99, and the normalized root mean square error (nRMSE) is 2.64%. The predicted value of the sticking force to the lip of each sample is basically comparable with the measured value, which shows that the present invention can be used to predict the sticking force of the cigarette tipping paper to the lip.

Application example 2

Step (1): Ten pieces of different cigarette papers from China Tobacco Yunnan Industrial Co., Ltd are prepared and accurately cut into 15 mm wide and 50 mm long. The artificial saliva was prepared according to Table 1. As the artificial mouth skin, medical silicone rubber soft skin was prepared with a thickness of 1 mm, and the artificial mouth skin was cut into 15 mm wide and 50 mm long. 10 µl of artificial saliva is accurately transferred using a microinjection syringe and evenly smeared with it on the artificial skin of the mouth. Spreading area \u003d 10 × 15 \u003d 150 mm ² . The surface printed with cigarette liner paper and the artificial mouth skin are glued with artificial saliva and left to dry for 2 minutes. A device for determining the coefficient of dynamic friction was chosen as the test equipment. As shown in FIG. 2, the other end of the glued rim paper and the other end of the artificial mouth skin, respectively, are clamped between two vise holders of the dynamic friction coefficient instrument. The distance between the vise holders is set to 50 mm and the travel speed is set to 50 mm/min. Two vices are installed on an intelligent panel (existing equipment) containing a force value sensor and a displacement sensor, and a force value/displacement data acquisition system (usually a computer) is connected to an intelligent panel containing a force value sensor and a displacement sensor, which can collect data on changing the force value and moving in real time. The artificial mouth skin is clamped to the determination platform in a vise, as shown in FIG. 2. The maximum force measured at the moment when the rim paper and artificial lips are separated is the sticking force. The adhesion force to the lip is calculated by the formula: F=adhesion force (N)/adhesion area (mm ² ).

Step (2): Dynamic friction coefficients of twenty-five samples were determined in accordance with GB10006-88 Plastics. Film and sheets. Determination of the coefficient of friction " .

Step (3): thickness values of twenty-five samples are determined in accordance with GB/T 451.3-2002GB/T 451.3-2002 “Paper and board. Determination of thickness" .

Step (4): The density values of twenty-five samples are determined in accordance with GB/T 451.2-2002 GB/T 451.2-2002 “Paper and board. Determination of Density" .

Step (5): The test results are shown in Table 5.

Table 5. Predicted value of sticking strength of cigarette rim paper to the lip

Sample Dynamic friction coefficient Density (g/m ² ) Predictable adhesion force (N/mm ² ) one 0.273 42.3 1.99 × 10 ^-1 2 0.393 39.5 3.27 × 10 ^-3 3 0.353 37.3 2.68 × 10 ^-1 four 0.373 38.7 2.99 × 10 ^-1 5 0.442 39.3 3.83 × 10 ^-1 6 0.294 38.3 2.03 × 10 ^-1 7 0.542 36.6 4.88 × 10 ^-1 eight 0.615 38.3 5.83 × 10 ^-1 9 0.311 42.1 2.43 × 10 ^-1 ten 0.577 37.1 5.32 × 10 ^-1

As can be seen, the present invention provides a method that can quickly and easily quantify the adhesion strength of cigarette liner paper to the lip, reliably avoid the influence of subjective factors and characterize the difference created by the traditional method of personal sensory evaluation of smoking, and greatly reduce the cost of detection and increase efficiency.

The basic principles, main features and advantages of the present invention have been shown and described above. Those skilled in the art will appreciate that the present invention is not limited to the above embodiments and that the description is merely to illustrate the principles of the present invention. Various changes and modifications are possible within the spirit and scope of the present invention, all of which are within the claimed scope of the present invention. The claimed scope of the present invention is defined by the appended claims and their equivalents.

Claims (23)

1. A method for constructing a model for predicting the sticking force of cigarette rim paper to the lip, characterized in that the model is Y _{lip adhesion force} = 0.205 + 1.038 × M _{friction coefficient} if the thickness of the cigarette liner paper is in the range of 0.069mm ~ 0.112mm; the model is Y _{lip adhesion force} = -0.335 + 1.181 × M _{friction coefficient} × D _density if the thickness of the cigarette liner paper is not in the range of 0.069mm ~ 0.112mm; wherein Y _{the lip sticking force} is the predicted sticking force of the cigarette liner paper to the lip; M _{coefficient of friction} is the coefficient of dynamic friction of the cigarette tipping paper; and D _density is the density of the cigarette tipping paper, that is, mass in grams per unit area; while the construction method includes: step (1): using a tester to measure the sticking force, where the sticking force is the force between the printed surfaces of different tipping paper and the artificial mouth skin glued with artificial saliva, and calculating the sticking force per unit area as the measured sticking force of the cigarette tipping paper to the lip wherein the tester is a peel strength tester, a tensile tester, or a dynamic friction coefficient tester; step (2): determining the coefficient of dynamic friction of the cigarette tipping paper; step (3): determining the thickness of the cigarette tipping paper; step (4): determination of the density of the cigarette tipping paper and step (5): performing a regression analysis using the coefficient of dynamic friction (M), density (D) and thickness (H) of the cigarette tipping paper as variables, and using the sticking force of the tipping paper to the lip as the reaction variable (Y) to obtain a prediction model adhesion forces of cigarette tipping paper to the lip; wherein in step (1), the cigarette tipping paper has a width range of 1-1000 mm and a length range of 1-1000 mm; the artificial mouth skin is cut into rectangles of the same size as the cigarette rim paper, one side of the cut artificial mouth skin is adhered to one side of the cigarette rim paper by the action of artificial saliva, the adhesion area is determined, and after being left alone until a constant weight is reached, the device is used to a test to measure the maximum peel force of the liner paper and artificial lips at the time of separation, and the maximum peel force is used as the sticking force of the cigarette liner paper to the lip. 2. A method for constructing a model for predicting the force of sticking of cigarette rim paper to the lip according to claim 1, characterized in that the rest time is 1-1800 s. 3. A method for constructing a model for predicting the force of adhesion of cigarette rim paper to the lip according to claim 1, characterized in that after being left alone until a constant mass is reached, the other side of the cigarette rim paper and the other side of the artificial skin of the mouth are not glued and, accordingly, clamped in two vise of the device for testing, and the distance between the two vices and their relative speed of movement is set so as to measure the maximum peel force at the time of separation of the cigarette tipping paper from the artificial lip; the two jaws of the tester completely clamp the cigarette rim paper and the artificial mouth skin; the tester has a load range of 0-200 N and a resolution greater than or equal to 0.01 N; and the distance between the two vise of the tester is 5-500mm, and the travel speed is 1-500mm/min. 4. A method for constructing a model for predicting the strength of adhesion of cigarette rim paper to the lip according to claim 1, characterized in that in step (1) the artificial saliva contains sodium chloride, potassium chloride, calcium chloride, monosubstituted sodium phosphate, magnesium chloride, urea, glucose, mucin, amylase, acid phosphatase and lysozyme, and the pH value of the artificial saliva is 5.5-7.5; and the volume range of artificial saliva used is 1-1000 µl. 5. A method for constructing a model for predicting the strength of adhesion of cigarette rim paper to the lip according to claim 4, characterized in that in step (1) the artificial saliva contains 1.40 mmol/l sodium chloride, 0.5 mmol/l potassium chloride, 0. 1 mmol/l calcium chloride, 0.15 mmol/l dibasic sodium phosphate, 0.025 mmol/l magnesium chloride, 0.09 mmol/l urea, 0.2 mmol/l glucose, 2.7 mmol/l bovine submandibular salivary mucin glands, 2.5 U/ml amylase, 0.004 U/ml acid phosphatase, and 0.7 U/ml lysozyme. 6. A method for constructing a model for predicting the adhesion force of cigarette liner paper to the lip according to claim 1, characterized in that the material of the artificial mouth skin is soft skin made of medical silicone rubber, skin made of an active composite with a layer of epidermal cells, polyvinyl chloride artificial skin, polyurethane dry artificial leather or polyolefin artificial leather. 7. A method for predicting the force of sticking cigarette rim paper to the lip, characterized in that the model for predicting the force of sticking cigarette rim paper to the lip is built by the method of building a model for predicting the force of sticking cigarette liner paper to the lip according to any one of paragraphs. 1-6, wherein said prediction method includes: measuring the thickness, dynamic friction coefficient, and mass in grams per unit area of the cigarette rim paper, and then inputting the thickness, dynamic friction coefficient, and mass in gram per unit area into the cigarette lip adhesive force prediction model to calculate to obtain the adhesion force of the cigarette rim paper paper to the lip. 8. The method for predicting the sticking force of a cigarette rim paper to a lip according to claim 7, characterized in that the rest time is from 1 s to 1800 s. 9. The method for predicting the sticking strength of cigarette liner paper to the lip according to claim 7, characterized in that after being left alone until a constant weight is reached, the second side of the cigarette liner paper and the second side of the artificial skin of the mouth are not glued and, accordingly, are clamped in two vise of the testing device , and the distance between the two vise and their relative speed of movement is set so as to measure the maximum peel force at the time of separation of the cigarette liner paper from the artificial lip; the two jaws of the tester completely clamp the cigarette rim paper and the artificial mouth skin; the tester has a load range of 0-200 N and a resolution greater than or equal to 0.01 N; and the distance between the two jaws of the tester is 5-500mm, and the relative movement speed is 1-500mm/min. 10. The method for predicting the strength of adhesion of cigarette rim paper to the lip according to claim 7, characterized in that in step (1) the artificial saliva contains sodium chloride, potassium chloride, calcium chloride, monosubstituted sodium phosphate, magnesium chloride, urea, glucose, mucin, amylase, acid phosphatase and lysozyme, and the pH value of the artificial saliva is 5.5-7.5; and the volume range of artificial saliva used is 1-1000 µl. 11. The method for predicting the adhesion force of cigarette liner paper to the lip according to claim 10, characterized in that in step (1) the artificial saliva contains 1.40 mmol/l sodium chloride, 0.5 mmol/l potassium chloride, 0.1 mmol / l calcium chloride, 0.15 mmol / l monosubstituted sodium phosphate, 0.025 mmol / l magnesium chloride, 0.09 mmol / l urea, 0.2 mmol / l glucose, 2.7 mmol / l mucin of bovine submandibular salivary gland, 2.5 U/ml amylase, 0.004 U/ml acid phosphatase and 0.7 U/ml lysozyme. 12. The method for predicting the adhesion force of cigarette liner paper to the lip according to claim 7, characterized in that the material of the artificial mouth skin is a soft skin made of medical silicone rubber, an active composite skin with a layer of epidermal cells, a polyvinyl chloride artificial skin, a polyurethane dry artificial skin or polyolefin artificial leather.

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