JP2006153681A - Measuring method of dynamic characteristics of hair sample - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method capable of accurately and objectively measuring the state of hair, especially the dynamical characteristics of hair, such as flexibility or the like of hair, after the use of cosmetics. <P>SOLUTION: The measuring method of the dynamical characteristics of hair is characterized in that push bending load due to linear motion is applied to a hair sample, which is fixed at two ends thereof and to which constant tension is applied in the direction crossing the fixed hair sample at right angles and the bending load to the hair sample is detected as the concentrated load. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a method for measuring the mechanical properties of hair, and more specifically, the measurement of the mechanical properties of hair that enables measurement of the bending load of a hair sample with high detection power and evaluation of cosmetics and the like. On how to do.

  Flexibility and suppleness are properties that many people strongly demand for hair, and the provision of cosmetics that can impart such properties to hair is one of the major challenges in the cosmetics field. And in order to provide the cosmetics as described above, it is necessary to accurately measure and analyze the hair itself and the flexibility or suppleness of the hair after being treated with a predetermined hair cosmetic. This means is always requested by cosmetic engineers.

  By the way, at present, the evaluation of the flexibility and suppleness of hair is usually based on sensory evaluation by an evaluator, but since it is a method based on the evaluator's unique technology, the evaluation criteria differ depending on the evaluator. It was inferior in objectivity. For this reason, various attempts have been made to standardize the evaluation using instruments and the like.

  Examples of methods for measuring the flexibility and suppleness of hair using such instruments include a method in which both ends of the hair are fixed to give a bending action, and a method in which the hair bends due to its own weight.

  However, the conventional method of fixing both ends and giving a bending action is that the hair is a flexible body, so the hair measurement part is easily bent (displacement between the displacement direction and the bending direction is likely to occur), and partially deteriorated. There was a problem that it was easily affected by error factors such as bending from a location. Furthermore, there is a problem that the length of the hair measurement part is limited, the detection power decreases when the hair measurement part is shortened, and the number of hairs is excessively required to increase the detection power.

  On the other hand, the method using the deflection due to the weight of the hair has problems such as extremely low detection power, easy direction of the hair, and a small load for evaluation of the setting power. In order to solve these problems, it is necessary to devise a technique for increasing the detection power. However, there is a problem in the accuracy of the movable part of the measuring apparatus, and the problem cannot be easily improved.

  As described above, even in the conventional method using an instrument or the like, since there are various variable factors in the actual measurement, it is difficult to say that it gives information that accurately indicates the state of the hair, and it is difficult to achieve the standard method. there were. Further, in these conventional methods, the measurement accuracy may be lowered due to changes in the angle, speed, and number of bending directions, and it cannot be said that it reflects the bending motion that humans are performing in sensory evaluation.

  Accordingly, an object of the present invention is to provide a method capable of accurately and objectively measuring hair mechanical properties such as hair condition, in particular, hair flexibility after using cosmetics. To do.

  In such a situation, the present inventors conducted extensive research to achieve the above object, and as a result, applied a slight push-bending displacement to the fixed hair, and detected the concentration by measuring the concentrated load at the hair part where the bending load was applied. The inventors have found that objective hair evaluation can be performed with high strength and is hardly influenced by measurement conditions, and the present invention has been completed.

  That is, the present invention applies a pushing / bending load by linear motion to a hair sample with two ends fixed and given a constant tension in a direction orthogonal to the fixed hair sample, and detects the reaction force as a concentrated load. This invention provides a method for measuring the mechanical properties of hair.

  The present invention also measures a fixing mechanism that fixes two ends of a hair sample while applying a constant tension, a movable mechanism that applies a displacement in the bending direction to the hair sample to which the two ends are fixed, and a reaction force against a pushing bending load. An apparatus for measuring the mechanical properties of hair including a detection mechanism for recording and a computer for recording and analyzing signals is provided.

  The hair sample used in carrying out the method of the present invention may be one hair or several hairs. The hair sample is fixed while giving a constant tension at two points (two ends) at a constant interval, and is subjected to measurement of mechanical properties. The fixing distance of the hair is not particularly limited, but is about 1 to 10 cm, preferably about 2 to 6 cm, and the tension applied to the hair is preferably about 1 to 10 gf. When one hair is used as a hair sample, it is desirable to use a hair having a diameter of about 10 to 500 μm, preferably about 100 to 300 μm.

  Next, a pressing load by linear motion is applied to the hair sample fixed at two ends in a direction orthogonal to the hair sample. This linear motion can be obtained by using a linear actuator or the like, and this linear motion acts as a bending load on the hair, for example, via a probe attached to the linear actuator. It is preferable that the position where the bending load is applied to the hair sample is in the vicinity of the center of the two ends that fix the hair.

  In carrying out the method for measuring the mechanical properties of hair according to the present invention, it is necessary to determine in advance, for example, the amount of displacement due to linear motion to be applied to the test hair and the operation thereof using a linear actuator or the like. This predetermined amount of displacement or movement is the pushing / bending load in the direction perpendicular to the hair as described above, and the amount of displacement (pushing width) and movement (push-down speed and speed change thereof) are, for example, It can be set according to which of hair flexibility, flexibility and the like is evaluated. Furthermore, the elasticity or the like of hair can be measured by setting the displacement or movement (pressing speed) at several levels as the response characteristics of the hair and finally grasping the relationship between the amplitude and the pushing bending load. .

  The amount of displacement (stroke) for applying the push-bending load can be set in the range of about 0.1 to 1000 μm. When the amount of displacement is about 0.1 to 50 μm, the surface state of the hair can be evaluated. When the amount of displacement is about 20 to 100 μm, the internal state of the hair can be evaluated. Is possible.

  The hair sample to which the pushing / bending load is applied as described above responds to the pushing / bending load with a reaction force response according to the characteristics of the hair. Therefore, by detecting this reaction force as a concentrated load, it is possible to obtain mechanical characteristics peculiar to each hair sample. This concentrated load can be measured by a tactile sensor such as a strain gauge or a semiconductor sensor.

Next, the structure and structure of the apparatus used in the present invention will be further described with reference to the drawings.
FIG. 1 is a drawing showing the configuration of a measuring device for the mechanical properties of hair used in the present invention. In the figure, A is a movable part, B is a signal detection part, C is a signal processing part, 1 of the movable part A is a controller, 2 is an actuator, 3 is a probe, 4 is a sensor, and 5 of the signal processing part C is an amplifier. , 6 represents A / D conversion, and 7 represents a computer.

  Among these, the movable part A has a role of realizing a predetermined displacement by the actuator 2 and giving it to the hair sample through the probe 3. As the actuator used here, a motor that moves in an appropriate bending direction can be used, and preferable examples include a stepping motor and a servo motor. This actuator is controlled via the controller 1 and operates according to the conditions input to the controller 1. The probe 3 is used for applying a bending load to the hair. The two ends of the hair are fixed ends, and a vertical bending displacement is given to the hair by a probe.

  The signal detection unit B includes a sensor 4. The probe 3 has a role of applying a pushing / bending load to the hair portion fixed in a state where a certain tension is applied, and simultaneously detecting a reaction force against the pushing / bending load as a concentrated load. A reaction force when a vertical bending displacement is applied to the hair is detected by the sensor 4. As the sensor used here, a load detector in an appropriate orthogonal coordinate component direction can be used, and a preferred example thereof is a strain gauge.

  Further, the signal processing unit C has a role of analyzing and recording the load data detected by the signal detection unit B. That is, the information detected by the signal detector B is first subjected to signal amplification and noise processing by the amplifier 6, numerically converted by the A / D converter 7, and the converted signal is captured by the computer 8 for analysis, display, Make a record.

  FIG. 2 schematically shows a detection mechanism centered on the probe 3 in the apparatus of the present invention. In the apparatus of the present invention, as shown in this drawing, the hair sample 8 is fixed to the fixing mechanism 9 while applying tension between the two fixed ends. A linear motion is given to the hair sample 8 by the actuator 2 through the probe 3. Then, the reaction force of the hair sample 8 against the pushing / bending load generated by this linear motion is transmitted to the sensor 4 via the probe 3, thereby measuring the mechanical characteristics of the hair sample 8.

  In the method of the present invention described above, for example, when a linear motion is applied to the hair sample 8 at a constant speed in a perpendicular direction, the following data is obtained.

(1) Bending load Flexibility, flexibility (2) Load change when bending displacement is maintained Hair elasticity, brittleness

  In addition, according to the method of the present invention, by changing the movement speed and the movement direction of the actuator 2, the degree of hair damage (branched hair, cut hair), stiffness, elasticity, specimens other than hair (threads, fibers) Etc.), it is possible to estimate and determine the strength of the coating film when a hairdressing material or material is applied.

  EXAMPLES Hereinafter, although an Example is given and this invention is demonstrated further in detail, this invention is not restrict | limited at all.

Example 1
Measurement of changes in hair bending load:
Hair A and B were sampled from Asians in advance (length 10 cm). When these two types of hair were evaluated by sensory evaluation, hair A was determined to be hard, and hair B was determined to be soft.

  Next, one hair of approximately the same thickness is taken from each of the A and B hairs, and this is used as a hair sample. With the measurement device of the configuration shown in FIG. 1 and the mechanism shown in FIG. A displacement in a perpendicular direction was applied in an amount of 1 to 200 μm, and the bending load was measured.

  First, the measurement environment is set to a temperature of 25 ± 2 ° C. and a humidity of 55 ± 2% RH, and each hair sample is fixed and held at the initial position (between fixed ends (distance between 9a and 9b) 5 cm, tension: 5 gf) . Next, the initial position of the probe and the motion conditions (speed: 0.1 mm / sec) are set by the controller. The probe was pushed and bent by linear motion on the hair immediately after being set to the initial position, and the pushing and bending load at this time was detected.

( Measurement result )
The push-bending load (reaction force) at the time of measurement for the hair samples A and B is shown in FIG. From this figure, the hair sample A has a high pushing bending load (reaction force) with respect to each displacement, and can be evaluated as “hard”. On the other hand, B has a low push-bending load with respect to displacement, and can be evaluated as “soft”.

  The result of FIG. 3 clearly has a correlation with the result of sensory evaluation. Therefore, it has been clarified that the flexibility of the hair can be expressed numerically by the method of the present invention.

Example 2
Measurement of changes in hair bending load due to treatment treatment:
Hair sampled from Asians (10 cm in length) was treated with a treatment agent. Glycerin was used as a treatment agent, and the hair bundle was immersed in a 20% aqueous solution of glycerin for 1 hour and then dried in a constant temperature and humidity chamber (25 ° C., 55% RH) for a predetermined time to obtain treatment-treated hair. On the other hand, for comparison, the same hair was immersed in purified water for 1 hour and then dried in a constant temperature and humidity chamber (25 ° C., 55%) for a predetermined time (untreated hair).

  With the same measuring apparatus as in Example 1, the flexibility of the hair was measured. That is, one treatment-treated hair and one untreated hair having approximately the same thickness were selected and used as hair samples. Next, the measurement environment of this hair sample was set at a temperature of 25 ± 2 ° C. and a humidity of 55 ± 2% RH, and the hair bundle was fixed at the initial position as in Example 1. Furthermore, the initial position of the probe and the motion conditions (speed: 0.1 mm / sec, two levels of displacement 10 μm and 20 μm) are set by the controller, and in a direction perpendicular to the hair immediately after the initial position is set. The probe was moved linearly, and the bending load (reaction force) was detected. Three hairs were used for each level, and the median value was the representative value.

( Measurement result )
FIG. 4 shows the measurement results of the bending load when the displacement is 10 μm and the bending load when the displacement is 20 μm for the treatment-treated hair and the untreated hair. As is apparent from the results, the treatment-treated hair has a lower bending load at any displacement than the untreated hair, indicating that it has a treatment effect (flexibility effect).

  Therefore, it has been clarified from the method of the present invention that “there is a treatment effect (flexible effect)” can be expressed numerically.

Example 3
Measurement of changes in hair bending load due to rinsing treatment:
Hair sampled from Asians (length 10 cm) was rinsed. A rinse agent having the following composition is used. After immersing the hair bundle in a 5% aqueous solution of this rinse agent for 1 hour, the hair bundle is dried in a constant temperature and humidity chamber (25 ° C., 55% RH) for a certain period of time, and rinsed. Hair was obtained. On the other hand, for comparison, the same hair was immersed in purified water for 1 hour and then dried in a constant temperature and humidity chamber (25 ° C., 55%) for a predetermined time (untreated hair).

<Rinse composition> (mass%)
Polyoxyethylene hydrogenated castor oil 1
Cetostearyl alcohol 2
Liquid paraffin 2
Stearyltrimethylammonium chloride 1
1,3-butylene glycol 5
Methyl paraoxybenzoate 0.1
Citric acid 0.1
100% purified water

  With the same measuring apparatus as in Example 1, the flexibility of the hair was measured. That is, rinse-treated hair and untreated hair of approximately the same thickness were selected and used as hair samples. Next, the measurement environment of this hair sample was set to a temperature of 25 ± 2 ° C. and a humidity of 55 ± 2% RH, and this hair sample was fixed at the initial position as in Example 1. In addition, the initial position of the probe and the movement conditions (speed: 0.1 mm / sec, two levels of displacement 100, 200 μm) are set by the controller, and in the direction perpendicular to the hair immediately after the initial position is set. The probe was moved linearly, and the bending load (reaction force) was detected.

( Measurement result )
FIG. 5 shows the measurement results of the bending load when the displacement is 100 μm and the bending load when the displacement is 200 μm for the rinsed hair and the untreated hair. As is clear from this result, it was revealed that the hair subjected to the rinsing treatment had a lower bending load at any displacement than the untreated hair, and the flexibility was increased by rinsing.

  Therefore, according to the method of the present invention, it is possible to objectively express the state in which the hair is “soft” with the rinse agent.

Drawing which shows the structure of the measuring device of the mechanical property of the hair used by this invention Drawing schematically showing the load detection mechanism of the device of the present invention with a probe at the center. Drawing showing the relationship between displacement and pushing bending load (reaction force) for hair samples Drawing showing the measurement results of the bending load when the displacement of the same hair is 10 μm and the bending load when the displacement is 20 μm, depending on the presence or absence of treatment treatment Drawing showing measurement results of bending load when displacement of the same hair is 100 μm and bending load when displacement is 200 μm, with and without rinsing treatment

Explanation of symbols

A ... Movable part B ... Signal detection part C ... Signal processing part 1 ... Controller 2 ... Actuator 3 ... Probe 4 ... Sensor 5 ... Amplifier 6 ... A / D conversion 7 ... Computer 8 ... … Hair sample 9…… Fixing mechanism

Claims (6)

  It is characterized by applying a pushing and bending load by linear motion to the hair sample fixed at two ends and given a constant tension in a direction orthogonal to the fixed hair sample, and detecting the bending load as a concentrated load. A method for measuring the mechanical properties of hair.   2. The method for measuring the mechanical properties of hair according to claim 1, wherein the position to which the bending load is applied is approximately the center of the fixed hair sample.   3. The method for measuring the mechanical properties of hair according to claim 1, wherein a pushing and bending load is repeatedly applied by a predetermined linear motion, and the attenuation of the bending load is detected.   4. The method for measuring the mechanical properties of hair according to claim 3, wherein the predetermined linear motion is accompanied by a change in speed.   The method for measuring mechanical properties of hair according to claim 3, wherein the predetermined linear motion is accompanied by a change in amplitude. Recording mechanism for fixing the two ends of a hair sample while applying a constant tension, a movable mechanism for shifting the hair sample with two ends fixed in the bending direction, a detection mechanism for measuring the bending load, and a signal A device for measuring the mechanical properties of hair, including a computer for analysis.

Images