JP2007252657A - Hair property measuring device - Google Patents

Abstract

An object of the present invention is to make it possible to measure and display hair properties corresponding to the touch feeling.
A sensor device 12 is moved in the X1 direction by a step motor 30. The sensor device 12 is configured to include a sensor module 20, a rectangular base 13, an acrylic plate member 14, a rectangular sponge rubber member 15, a support member 16, and a rectangular upper plate 17. The sample hair is sandwiched between the sponge rubber member 15 and the contact 21. The sensor device 12 moves so as to comb the hair while pinching the sample hair, and scans the sample hair.
[Selection] Figure 1

Description

  The present invention relates to a hair property measuring device, and more particularly to a hair property measuring device that measures the properties of human hair and displays them as numerical values.

  Human hair is often damaged by physical factors such as brushing, chemical factors such as bleaching agents, and external environmental factors such as ultraviolet rays, and awareness of hair care is increasing. Damaged hair can be recovered by washing the damaged hair with a shampoo containing a conditioner component and then applying a conditioner treatment.

  At sites where shampoos and the like are developed and shampoos are sold, it is desired to develop an apparatus for objectively evaluating the properties of hair, which is the degree of damage to hair and the degree of recovery from damage.

Conventionally, attempts have been made to measure the properties of human hair and display them as numerical values. For example, by measuring the physical characteristics of hair, such as surface friction coefficient, cross-sectional shape, bending stiffness, etc., human hair has been trying to display the properties as numerical values.
JP 2004-305352 A

  However, these measurements do not show a significant difference between the value of damaged hair and the value of conditioner-treated hair, and are not suitable for displaying human hair properties as numerical values. It was.

  In addition to the fact that there is a big difference between the value of damaged hair and the value of conditioner-treated hair, this value indicates that humans put a hand comb into their hair. In this case, it is desirable to correspond to the touch feeling (smooth, moist, dry, supple, smooth, etc.) that the fingers of the hand feel.

  When the beauty staff touches the hair with a hand comb or the like, the untreated damaged sample hair B (N) shown in FIG. 7 (E) and the conditioner-treated damaged sample hair shown in FIG. 7 (F). There is a difference with B (SC), and similarly, there is also a difference between the untreated health sample hair G (N) shown in FIG. 7 (B) and the conditioner-treated health sample hair G (SC) shown in FIG. 7 (C). was there. That is, it has been found that when the conditioner treatment is performed, the feeling of touch is improved both in the case of damaged hair and in the case of healthy hair.

  Then, an object of this invention is to provide the hair property measuring device which solved the said subject.

  In order to solve the above-mentioned problems, the present invention has a sensor device and a moving means for moving the sensor device, and the hair property measurement is configured to scan the sample hair by moving the sensor device by the moving device. The sensor device has a configuration in which a sensor module having a contact and a sponge rubber member are provided facing each other, and the sample hair is sandwiched between the contact and the sponge rubber member. The sensor device moves to scan the sample hair.

  While the sample hair is sandwiched between the contact and the sponge rubber member, the sensor device moves and scans the sample hair, so that the sample hair is scanned under a moderate and moderate tension. This is done for a certain sample hair, and the hair property measurement can be performed with high accuracy.

  Next, an embodiment of the present invention will be described.

[Configuration of Hair Property Measurement System 10]
FIG. 1 shows a hair property measuring system 10 according to Embodiment 1 of the present invention. The hair property measurement system 10 includes a hair property measurement device 11, a control device 100, and a display device 110. The hair property measurement device 11 is operated by the control device 100 to measure hair properties, and the measurement result is a control device. The result is appropriately processed by 100, and the result is displayed on the display device 110 as a graph or the like corresponding to the feeling when the beauty staff puts a hand comb on the hair.

X1-X2 is the longitudinal direction of the hair property measuring device 11, Y1-Y2 is the width direction, and Z1-Z2 is the height direction.
[Configuration of Hair Property Measuring Device 11]
The hair property measuring device 11 is configured such that the sensor device 12 is moved in the X1 direction along the stage rail 40 by the step motor 30. At this time, the sensor device 12 sandwiches the sample hair. It is the structure which moves so that hair may be combed.

  As shown in FIG. 2, the sensor device 12 includes a sensor module 20, a rectangular base 13, an acrylic plate member 14, a rectangular sponge rubber member 15, a support member 16, and a rectangular upper plate 17. The sensor module 20 can be removed and the upper surface can be opened.

  In the sensor module 20, an acrylic contact 21 protrudes from the lower surface of the flat rectangular case 22 in the Z2 direction, and a PVDF (polyvinylidene fluoride, which is a polymer piezoelectric material) is formed inside the case 22. (Polyvinylidene fluoride) film 23, and the PVDF film 23 is configured to generate a voltage under pressure by vibration of the contact 21. The PVDF film 23 is a piezoelectric polymer that has the same output characteristics as a pacini corpuscle, which is a human sensory receptor, and has flexibility. In addition, it has been confirmed that the PVDF film 23 generates an induced electromotive force (Vi) proportional to the received pressure by receiving the pressure. The pachinko body is one of the finger tactile receptors of the hand, detects the acceleration of skin displacement, is highly sensitive to tactile pressures around 200 Hz, and is first excited when touched. Is the main part that causes the hand to feel when a hand comb is inserted into the hair. The PVDF film 23 is attached to a rectangular plate-shaped silicon rubber member 24 on the lower surface, covered with an acetate film 25 for protection, and provided inside the case 22 together with the silicon rubber member 24. The sensor module 20 is attached to the lower surface of the upper plate 17. The contact 21 has a length that contacts all the sample hairs in the Y direction. The upper plate 17 has a hole 17a in each corner portion.

  An acrylic plate member 14 is fixed to the upper surface of the base 13, and a sponge rubber member 15 is attached to the upper surface of the acrylic plate member 14. The sponge rubber member 15 functions as a table on which the sample hair is placed and faces the contact 21. The sponge rubber member 15 is made of foamed and flexible rubber, and is, for example, PON-01 with Wong Sangyo Co., Ltd. having a 25% compression load of 0.0001 to 0.0005 MPa. The sponge rubber member 15 supports the sample hair in a slightly submerged state so that the entire sample hair uniformly strikes the contactor 21, and when the sensor device 12 moves by the frictional force, Apply moderate tension to all sample hairs.

  There are four support members 16, which are fixedly erected on each corner portion of the base 13, and have a step portion 16 a and a bolt portion 16 b at the upper end. The bolt part 16b protrudes above the step part 16a. The height of the column member 16 from the base 13 to the stepped portion 16a is H. The step portion 16 a constitutes a structure portion that determines the height position from the upper surface of the sponge rubber member 15 of the sensor module 20. That is, the step portion 16a of the column member 16 determines the height of the upper plate 17 with respect to the base 13, and has a role of uniquely setting the height of the sensor module 20 with respect to the upper surface of the sponge rubber member 15 to a predetermined height. . Here, the predetermined height is a height at which the contact 21 just contacts the sponge rubber member 15.

  The upper plate 17 is fixed by a nut 26 that is supported by the stepped portion 16a and screwed into the bolted portion 16b by fitting the holes 17a of the respective corner portions to the bolted portions 16b. In this state, the contact 21 is in contact with the sponge rubber member 15.

  By loosening the nut 26, the sensor module 20 can be slightly moved upward together with the upper plate 17. By loosening the nut 26 and pulling up the upper plate 17 in the Z1 direction, the contact 21 can be lifted from the sponge rubber member 15 and a gap can be formed between the contact 21 and the sponge rubber member 15. When the nut 26 is removed, the sensor module 20 is removed upward together with the upper plate 17, and the upper surface of the sensor device 12 is opened, and the upper surface of the sponge rubber member 15 is exposed.

  Referring to FIG. 1 again, the stage rail 40 is installed with its axis line aligned with the X1-X2 direction. A screw shaft 41 passes through the stage rail 40. A slider 42 is slidably provided on the stage rail 40. The slider 42 has a nut portion fitted to the screw shaft 41. A stepping motor 30 with an encoder 31 is attached to the end of the stage rail 40. The screw shaft 41 is rotated by the stepping motor 30, and the slider 42 slides on the stage rail 40 in the X1-X2 direction by rotating the screw shaft 41.

  The slider 42 and the sensor device 12 are connected by an arm member 45. The arm member 45 is screwed to the upper surface of the upper plate 17 of the sensor device 12.

  As the slider 42 slides on the stage rail 40, the sensor device 12 is moved in the X1 direction.

Reference numeral 70 denotes a sample hair fixing unit, which fixes one end of the sample hair in a state where about 100 sample hairs are arranged in the Y1-Y2 direction. The sample hair fixing part 70 is arranged on the X2 side from the sensor device 12 in the initial position.
[Configuration of Control Device 100]
Referring to FIG. 1, the control device 100 includes a microcomputer 101.

In relation to the control device 100, an AD card 106, a stepping motor drive circuit 107, and a display device drive circuit 108 are provided. The microcomputer 101 contains a program for driving the stepping motor 30, a program for distributed processing of sampled data, and the like.
[Configuration of Display Device 110]
The display device 110 is a liquid crystal panel and is connected to the display device driving circuit 108.
[Operation and operation of hair property measurement system 10]
Next, operations and operations of the hair property measurement system 10 will be described.
[Measurement preparation operation]
One end of a large number of sample hairs 150 is closely arranged in the Y direction and fixed to the sample hair fixing unit 70. The X1 end of the sample hair fixing part 70 is free.

  Further, as shown in FIG. 3A, the nut 26 of the sensor device 12 is loosened and removed, the upper plate 17 is removed, and the sample hair fixing portion 70 of the sample hair 150 is attached to the sample hair 150 as shown in FIG. A close portion is placed so as to cross the upper surface of the sponge rubber member 15 in the X direction, and the upper plate 17 is attached and covered as shown in FIG. 4C, and finally, as shown in FIG. As described above, the nut 26 is tightened to fix the upper plate 17. The sensor device 12 is located near the sample hair fixing unit 70.

As a result, as shown in FIG. 3D, the sample hair 150 crosses the sensor device 12, and the contact 21 is placed on the upper surface of the sponge rubber member 15 as shown in FIG. It comes into contact. FIG. 4 shows an enlarged cross section along line IV-IV in FIG. Part of the sample hair 150 is indented into the sponge rubber member 15 so that the upper surface is aligned with the same surface, and the contact 21 is in uniform contact with all the sample hairs 150.
[Scanning operation]
When the operator performs a start operation, the stepping motor 30 is driven, the screw shaft 41 is rotated, the slider 42 slides on the stage rail 40 in the X1 direction, and the sensor device 12 starts moving in the X1 direction. The sensor device 12 moves the sample hair 150 by applying appropriate tension to the sample hair 150 in the same manner as a person combs the hair while holding the sample hair between fingers of the hand. Scan in the direction of.

  The stepping motor 30 is first rotated for 1 second at the first rotational speed N1, temporarily stopped, stopped for 1.5 seconds, and then rotated for 3 seconds at the second rotational speed N2. The first rotation speed N1 is a rotation speed for moving the slider 42 and the sensor device 12 at the first speed V1. The second rotation speed N2 is five times the first rotation speed N1, and is a rotation speed that moves the slider 42 and the sensor device 12 at the second speed V2.

  The movement of the sensor device 12 at the first speed V1 for 1 second is referred to as “pre-scan”. The movement of the sensor device 12 at the second speed V2 for 3 seconds is referred to as “measurement scanning”.

  FIG. 5A shows a state during pre-scanning. If the sample hair 150 is slack, the measurement error tends to increase. The pre-scan is performed to eliminate the slack existing in the portion of the sample hair 150 between the sample hair fixing unit 70 and the sensor device 12. Of these, the portion between the sample hair fixing portion 70 and the sensor device 12 is in a stretched state.

  The sensor device 12 is temporarily stopped. Noise data is sampled while the sensor device 12 is stopped. As will be described later, this noise data is used to correct the original data. The sampling of the noise data is performed with a delay of 1.0 second after the sensor device 12 stops, that is, in a state where the vibration generated in the sensor device 12 disappears when the sensor device 12 that has moved stops. Subsequently, the sensor device 12 starts moving at the second speed V2.

  FIG. 5B shows a state during measurement scanning. The sponge rubber member 15 supports a portion of the sample hair 150 that is close to the free end in sequence, and the contact 21 scans the upper surface of the sample hair 150 that is supported by the upper surface of the sponge rubber member 15.

  The contact 21 traces the surface of the sample hair 150 and is displaced in the Z1-Z2 direction according to the surface condition of the sample hair 150 and vibrates. The PVDF film 23 generates a voltage in response to the vibration of the contact 21, and fluctuations in this voltage are sent out as an output of the sensor device 12 to measure the hair properties.

  Data is sampled at a sampling frequency of 25 kHz along with the start of the measurement scan, and is taken into the microcomputer 101 via the AD card 106. The measurement time is 3 seconds.

  The sensor device 12 stops after moving for 3 seconds.

Here, (1) the height position of the sensor module 20 with respect to the sponge rubber member 15 does not change due to the presence of the support member 16, and the contact displacement of the contact 21 to the sample hair 150 is constant. (2) By adopting the sponge rubber member 15, the sample hair 150 is partially submerged and supported by the sponge rubber member 15, and unevenness of the upper surface of each sample hair is improved, and the contact 21 is applied to the sample hair 150. (3) The pre-scanning causes the sample hair 150 to be properly stretched by eliminating slack, which is one of the causes of measurement errors. What is done to the sample hair 150 in a stretched state, (4) Sampling is corrected by noise data Like manner, from the sensor unit 12 is output accurate data.
[Data analysis and display operations]
In this embodiment, a variance value VAR is used as an evaluation parameter.

  Therefore, the microcomputer 101 corrects the sampling data, and then obtains a dispersion value VAR in a section from 1500 ms to 2500 ms from the start of measurement (that is, start of data sampling) based on the following equation (1).

なお、測定走査から１５００ｍｓ〜２５００ｍｓの区間を選択した理由は、異なるサンプル毛髪を走査した場合のセンサ装置１２からの出力データ電圧波形を目視で比較した場合に、振幅に違いが目立った区間であるからである。

The reason why the section of 1500 ms to 2500 ms is selected from the measurement scan is the section where the difference in the amplitude is conspicuous when the output data voltage waveform from the sensor device 12 when scanning different sample hairs is visually compared. Because.

  The obtained dispersion value VAR is displayed as a bar graph on the display device 110 (see FIG. 8).

The above preparation operation and scanning operation, and data analysis and display operation are performed every time the sample hair is replaced.
[Flowchart of Operation of Microcomputer 101]
FIG. 6 shows a flowchart of the operation of the microcomputer 101 when sampling the data while moving the sensor device 12 in the X1 direction.

  First, the stepping motor 30 is driven at the first rotational speed N1 for 1 second (ST1, ST2). Next, the stepping motor 30 is stopped (ST3, ST4).

  When 1 second has elapsed since the stepping motor 30 was stopped, noise data is sampled for 0.5 seconds (ST4, ST5, ST6, ST7).

  Next, the stepping motor 30 is driven at the second rotation speed N2 for 3 seconds (ST8, ST10), and data sampling is started (ST8). Next, the stepping motor 30 is stopped (ST11), and data sampling is stopped (ST12).

  Next, an average value of noise data for 500 ms from the initial start of the stepping motor 30 is calculated (ST13), and the average value of the above noise data is obtained from sampling data for 3500 ms from the initial start of the stepping motor 30. Is subtracted (ST14). As a result, the sampling data is corrected.

  Next, the sampled data is read from the memory in the interval of 1500 ms to 2500 ms from the start of data sampling (ST15).

  Next, the read data is subjected to distributed processing (ST16).

Finally, the result of the distributed processing is displayed (ST17).
[Output data from sensor device 12 corresponding to sample hair and display on display device 110]
FIG. 7 shows output data from the sensor device 12 when the sample hair is scanned, and FIG. 8 shows a display on the display device 110.

  FIG. 7A shows healthy sample hair G, FIG. 7B shows an untreated healthy sample hair G (N), and FIG. 7C shows that the healthy sample hair G is washed with a commercially available shampoo. It is the conditioner-treated health sample hair G (SC) that has been treated.

  FIG. 7 (D) shows sample hair B that has been artificially damaged by hybrid treatment and ultrasonic treatment, FIG. 7 (E) shows untreated damaged sample hair B (N), and FIG. 7 (F) shows damage. Sample hair B is a conditioner-treated damaged sample hair B (SC) that has been washed with a commercial shampoo and conditioner-treated.

  FIG. 7G shows a waveform of voltage output data from the sensor device 12 when the sensor device 12 scans the untreated healthy sample hair G (N) as described above. It can be seen that a peak appears in the vicinity of 520 ms from the start of sampling of the noise data, and the waveform of the data is stable in the interval of 1500 ms to 2500 ms.

  7 (H) and (I) show portions where features appear in the data shown in FIG. 7 (G). FIG. 7H shows a waveform of data in a section from 500 ms to 550 ms from the time when data sampling is started, among the data shown in FIG. FIG. 7I illustrates a waveform of data in a section from 1500 ms to 2500 ms from the start of data sampling in the data illustrated in FIG. The scale of the vertical axis in FIG. 7I is about 10 times the scale of the vertical axis in FIG.

  7 (L) and 7 (M) show waveforms of voltage output data when the sensor device 12 scans the treated healthy sample hair G (SC), and FIG. 7 (L) shows data in the section of 500 ms to 550 ms. FIG. 7M shows a waveform of data in a section of 1500 ms to 2500 ms.

  7 (J) and (K) are waveforms of voltage output data when the sensor device 12 scans the untreated damaged sample hair B (N), and FIG. 7 (J) is data in a section of 500 ms to 550 ms. FIG. 7K shows the waveform of the data in the interval of 1500 ms to 2500 ms.

  7 (N) and (O) are waveforms of voltage output data when the sensor device 12 scans the treated damaged sample hair B (SC), and FIG. 7 (N) is data in a section of 500 ms to 550 ms. FIG. 7 (O) shows the waveform of data in the interval of 1500 ms to 2500 ms.

  Comparing the above data, in the case of untreated damaged sample hair B (N), the peak in the vicinity of 520 ms is larger than that of other hairs, and the amplitude of the waveform of the data in the section of 1500 ms to 2500 ms is You can see that it ’s big. This is because the vertical vibration (displacement) of the contact 21 is intense when the contact 21 scans the untreated damaged sample hair B (N).

  Further, when attention is paid to the amplitude of the waveform of the data in the section of 1500 ms to 2500 ms, when the conditioner process is performed, the case where the original is the damaged sample hair B (FIG. 7 (K) and FIG. 7 (O) are compared). Even when the original is the healthy sample hair G (when comparing FIG. 7 (I) and FIG. 7 (M)), it can be seen that the amplitude is small and there is a difference. . The present invention has been made paying attention to this.

When the data shown in FIG. 7 (K) is distributed and the dispersion value VAR is obtained, it becomes 3.6 × 10 ⁻⁶ , and the hair properties are displayed in the column 200B (N) in FIG. When the dispersion value VAR is obtained by performing dispersion processing on the data shown in FIG. 7 (O), it becomes 1.2 × 10 ⁻⁶ and the hair properties are displayed in the column 200B (SC).

  The column 200B (N) and the column 200B (SC) are displayed on the liquid crystal panel of the display device 110 of FIG. 1, and a person who sees the column 200B (N) visually observes the damaged hair with the conditioner treatment by the arrow 201. As shown, it can be recognized that the hand feeling has been improved.

When the dispersion value VAR is obtained by performing dispersion processing on the data shown in FIG. 7I, it becomes 2.1 × 10 ⁻⁶ , and the hair properties are displayed in the column 300G (N) in FIG. When the dispersion value VAR is obtained by performing dispersion processing on the data shown in FIG. 7M, it becomes 1.4 × 10 ⁻⁶ and the hair properties are displayed in the column 300G (SC).

The column 300G (N) and the column 300G (SC) are displayed on the liquid crystal panel of the display device 110 in FIG. 1, and a person who sees them performs a conditioner process even when the hair is healthy. Thus, as indicated by an arrow 301, it can be recognized that the touch feeling has been improved.
[Example using the power spectral density (PSD) area (FET AREA) as an evaluation parameter]
Next, the case where the area (FET AREA) of the power spectral density (PSD) is selected as the evaluation parameter will be described.

  FIG. 9 (A) is the same data as the data shown in FIG. 7 (I) for the untreated healthy sample hair G (N), and when this is fast Fourier transformed, it becomes as shown in FIG. 9 (B). The vertical axis in FIG. 9B is PSD.

In FIG. 9B, the area (FET AREA) of the region S of 250 to 500 Hz that is the acceptance frequency of the pachini body is 7.1 × 10 ⁻⁴ , and the hair properties are column 300G in FIG. 9C. (N) is displayed.

The area (FET AREA) of the region of 250 to 500 Hz in the data shown in FIG. 7M is 5.5 × 10 ⁻⁴ , and the hair properties are displayed in the column 500G (SC) in FIG. 9C.

  The column 500G (N) and the column 500G (SC) are displayed on the liquid crystal panel of the display device 110 in FIG. 1, and a person who sees the column 500G (N) visually recognizes the healthy hair with the conditioner treatment by the arrow 501. As shown, it can be recognized that the hand feeling has been improved.

The area (FET AREA) of the region of 250 to 500 Hz in the data shown in FIG. 7 (K) is 9.0 × 10 ⁻⁴ , and the hair properties are displayed in the column 400B (N) in FIG. 9 (C).

The area (FET AREA) of the 250 to 500 Hz region of the data shown in FIG. 7 (O) is 7.5 × 10 ⁻⁴ , and the hair properties are displayed in the column 400B (SC) in FIG. 9 (C).

A column 400B (N) and a column 400B (SC) are displayed on the liquid crystal panel of the display device 110 in FIG. 1, and a person who sees the column 400B (N) visually observes the damaged hair with a conditioner treatment by an arrow 401. As shown, it can be recognized that the hand feeling has been improved.
[Example using the minimum value of peak induced electromotive force as an evaluation parameter]
Next, the case where the induced electromotive force induced in the PVDF film 23 in the sensor device 12 of FIG. 2 is selected as the evaluation parameter will be described.

  As shown in FIGS. 7 (H), (J), (L), and (N), this focuses on a peak that appears around 520 ms from the start of data sampling. This peak occurs due to an impact when the sensor device 12 that has been stopped starts moving at the second speed V2.

  In order to obtain a peak voltage with high sensitivity, an induced electromotive force Vi is used instead of the measurement voltage vo.

  FIG. 10A shows a measuring instrument connection model. R is A / D. 10B shows the pressure acting on the PVDF film 23, FIG. 10B shows the induced electromotive force Vi induced in the PVDF film 23, and FIG. 10C shows the measured voltage Vo.

  Based on the measured voltage Vo, the induced electromotive force Vi is calculated by the following equation (2).

ここで、ｎは計測データ点数、Ｔｓはサンプリング周期である。

Here, n is the number of measurement data points, and Ts is the sampling period.

  In the measuring instrument connection model shown in FIG. 10A, the RC value takes a very small value compared to the Vo value, so that the measured voltage Vo is obtained as a pressure differential type output. Therefore, the sensor device 12 becomes a highly sensitive pressure sensor by converting the measurement voltage Vo into the induced electromotive force Vi according to the above equation (2).

  FIG. 11 shows the induced electromotive force Vi obtained by converting the signal of the measured voltage Vo shown in FIGS. 7H, 7J, 7L, and 7N according to the above formula.

  The minimum value Vi min of the induced electromotive force Vi of the untreated healthy sample hair G (N) is displayed in a column 700G (N) in FIG. The minimum value Vi min of the induced electromotive force Vi of the treated healthy sample hair G (SC) is displayed in a column 700G (SC) in FIG.

  A column 700G (N) and a column 700G (SC) are displayed on the liquid crystal panel of the display device 110 of FIG. 1, and a person who sees the column 700G (N) visually observes the condition by treating the healthy hair with an arrow 701. As shown, it can be recognized that the hand feeling has been improved.

  The minimum value Vi min of the induced electromotive force Vi of the untreated damaged sample hair B (N) is displayed in the column 600B (N) in FIG. The minimum value Vi min of the induced electromotive force Vi of the treated damaged sample hair B (SC) is displayed in a column 600B (SC) in FIG.

  A column 600B (N) and a column 600G (SC) are displayed on the liquid crystal panel of the display device 110 of FIG. 1, and a person who sees the column 600B (N) visually observes the condition by treating the healthy hair with an arrow 601. As shown, it can be recognized that the hand feeling has been improved.

It is a figure which shows the hair property measuring system which becomes Example 1 of this invention. It is a figure which shows the sensor apparatus in FIG. It is a figure which shows a measurement preparation operation | movement. FIG. 4 is an enlarged view showing a cross section taken along line IV-IV in FIG. It is a figure which shows roughly the pre-scan and measurement scan of a sensor apparatus. It is a flowchart of operation | movement of the microcomputer in FIG. It is a figure which shows the output data from the sensor apparatus corresponding to sample hair. It is a figure which shows the display of the hair property to a display apparatus. It is a figure explaining evaluation of the hair property performed using the area of power spectrum density as an evaluation parameter. It is a figure which shows a measuring device connection model. It is a figure explaining evaluation of the hair property performed by using the minimum value of peak electromotive force as an evaluation parameter. It is a figure which shows the display of the hair property to a display apparatus.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Hair property measuring system 11 Hair property measuring device 12 Sensor device 13 Base 14 Acrylic board member 15 Sponge rubber member 16 Strut member 16a Step part 16b Bolt part 17 Upper plate 20 Sensor module 21 Contact 22 Case 23 PVDF film 24 Silicon rubber member 25 Acetate film 26 Nut 30 Step motor 31 Encoder 70 Sample hair fixing part 100 Controller 101 Microcomputer 105 LPF
106 AD Card 107 Stepping Motor Drive Circuit 108 Display Device Drive Circuit 110 Display Device 150 Sample Hair

Claims (6)

A hair property measuring apparatus having a sensor device and a moving means for moving the sensor device, wherein the sensor device is moved by the moving means to scan a sample hair;
The sensor device has a configuration in which a sensor module having a contact and a sponge rubber member are provided facing each other,
A hair property measuring apparatus, wherein the sensor hair moves and scans the sample hair while the sample hair is sandwiched between the contact and the sponge rubber member. In the hair property measuring device according to claim 1,
The sensor device includes:
The sponge rubber member is provided on the base;
A plurality of support members are erected on the base,
The support member has a structure that determines the height position of the sensor module;
The hair property measuring apparatus, wherein the sensor module has a structure in which a height position is determined by the structure portion of the support member. In the hair property measuring device according to claim 1,
The moving means first performs a moving process in order to eliminate the slack existing between the fixed end of the sample hair and the sensor device, stops the one end, and then takes out data on the properties of the sample hair. A hair property measuring apparatus characterized by being configured to perform a process of moving at an appropriate speed. In the hair property measuring device according to any one of claims 1 to 3,
Data processing means for processing the data output from the sensor device such that the variance value becomes an evaluation parameter;
A hair property measuring apparatus characterized by further comprising a display device for displaying a dispersion value obtained by the data processing means. In the hair property measuring device according to any one of claims 1 to 3,
Data processing means for processing the data output from the sensor device such that the area of the power spectral density is an evaluation parameter;
A hair property measuring apparatus, further comprising a display device for displaying an area of the power spectral density obtained by the data processing means. In the hair property measuring device according to any one of claims 1 to 3,
Data processing means for processing the data output from the sensor device so that the minimum value of the peak induced electromotive force becomes an evaluation parameter;
A hair property measuring apparatus further comprising a display device for displaying a minimum value of the peak induced electromotive force obtained by the data processing means.

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