JPH0458903A - Brush - Google Patents

Abstract

PURPOSE:To simply and quickly measure the moisture percantage while brushing by providing at least a pair of electrodes of a projection shape for detecting moisture in many bristles, and providing a position variable means for making at least one of the bristle and the electrode movable so that the tip of the electrode moves relatively to a position for approaching the tip of the bristle and a position for retreating to the root side of the bristle. CONSTITUTION:A moisture sensor 4 having electrodes 8, 9 is provided so as to be freely movable vertically against a bristle base 5, and connected electrically to a printed board 13 by a fact that a socket 12 provided on the printed board 13 comes into contact with the side face of the rear end of the electrodes 8, 9. As for the bristle 2, the bristle base 3 and the printed board 13, the moisture sensor 4 becomes movable vertically against the bristle base 3 by operating a sensor position changeover switch 6. A position variable means is provided with the sensor position changeover switch 6, and a sensor push-up plate 14 for pushing up the moisture sensor 4 by interlocking with the sensor position changeover switch 6.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a brush that can measure the moisture content of hair as an electrical change in capacitance between a pair of electrodes.

[Conventional technology]

-II As a means of measuring the moisture content of hair, there are cases in which the moisture content is measured directly and cases in which it is measured indirectly.

When measuring directly, the weight W when measuring the hair and the weight W when completely dry. Please measure WW. )/W.

x100 (absolute dry method), and measuring the moisture content W' of hair by titration of Karl Fuscher reagent and calculating it by W'/(W-W')xlOO (
Karl Fuscher method).

However, although this direct measurement method can serve as a standard for measuring moisture content, it requires cutting and separating the hair. Moreover, there were disadvantages in that it took time to measure and the measuring device was bulky.

On the other hand, the indirect measurement method utilizes the physical properties of water, and involves irradiating the hair with light that is easily absorbed by water in the infrared light region and determining the moisture content from the absorption rate (infrared spectroscopy). ,
A method of determining moisture content by measuring the capacitance (permittivity) or electrical resistance (dielectric loss) of hair, taking advantage of the fact that water has a higher dielectric constant and lower dielectric loss than other substances.
There is a high frequency method). However, since the former uses infrared light, it requires maintenance to prevent dirt on the sensor surface and measures to eliminate the influence of ambient light, and the device is also larger, so the latter is more common.

As a hair moisture content measuring device using this latter method, for example, Utility Model Application No. 57-112947 and Utility Model Application No. 63-
There is No. 95508. That is, these methods measure the moisture content by providing an electrode on a probe that can be opened and closed and holding hair between the probes.

[Problem to be solved by the invention]

However, since it is possible to only measure the moisture content of the clamped part, in order to measure the moisture content of a wide range of hair, it is necessary to open and close the probe each time to clamp the hair, which is very time-consuming and requires a lot of effort, The disadvantage is that the operation is difficult to measure the moisture content of.

In particular, when measuring the moisture content of hair while it is drying with a hair dryer to find out how dry it is, if you measure the same area, the dryness will be delayed compared to other areas, so you will not be able to measure the overall dryness. To find out, stop drying with a hair dryer,
It was very inconvenient as it was necessary to measure the moisture content each time.

Therefore, an object of the present invention is to provide a brush that can easily and quickly measure the moisture content while brushing, and that can reliably detect the moisture content of short hair without interfering with the brushing action of long hair. be.

[Means to solve the problem]

The brush of the present invention includes at least one pair of protruding electrodes for detecting moisture in a large number of bristles of a bristle base,
Position variable means for movable at least one of the bristle and the electrode so that the tip of the electrode moves relatively between a position close to the tip of the bristle and a position retreated toward the base of the bristle. It was established.

[Effect]

According to the configuration of this invention, brushing can be performed by combing the hair with the bristle. In this case, since the hair enters between the electrodes, the moisture content of the hair can be detected by a high frequency method or the like, so it becomes possible to easily and quickly measure the moisture content while brushing. In the case of short hair, the hair can be inserted between the electrodes by moving the tip of the electrode close to the tip of the bristle using the variable position means, so that the moisture content can be detected with a difference.

On the other hand, in the case of long hair, by positioning the electrode on the root side of the bristle, the amount of space between long hair will not be a hindrance.

〔Example〕

A first embodiment of this invention will be described based on FIGS. 1 to 5. That is, in FIGS. 1 and 2,
A bristle base 3 is fixed to the brush body 1, bristles 2 are flocked to the bristle base 3, and a moisture sensor 4 is installed at approximately the center of the bristle base 3 so as to be vertically movable. The moisture sensor 4 has a protrusion-shaped earth side electrode 8 and a hot side electrode 9 implanted therein. 5 is a power switch provided on the grip la of the brush body 1, and 6 is a sensor position changeover switch of the position variable means.

FIG. 3 is an enlarged view of the moisture sensor 4, in which electrodes 8.9 are alternately erected on the sensor base 7δ made of an insulator.
, 9 is provided with a hair introduction section 10 made of an insulator. The plunging hair is parted by this hair introduction part 10 so that it is easily guided smoothly into the moisture content measurement space 11 between the electrodes 8 and 9. Further, inside the sensor base 7, the electrodes 8.9 and electrode terminals 8a and 9a are connected, respectively.

4 and 5 illustrate the operation of the sensor position changeover switch 6. FIG. The moisture sensor 4 having electrodes 8 and 9 is provided so as to be able to move up and down with respect to the bristle base 3, and when the socket 12 provided on the printed circuit board 13 comes into contact with the side surface of the rear end of the electrodes 8.9, It is electrically connected to the printed circuit board 13. Since the bristle 2, the bristle base 3, and the printed circuit board 13 are fixed to the brush body 1, the moisture sensor 4 can be moved up and down with respect to the bristle base 3 by operating the sensor position changeover switch 6. Here, the position variable means of this embodiment includes a sensor position changeover switch 6 and a sensor push-up plate 14 that pushes up the moisture sensor 4 in conjunction with the sensor position changeover switch 6.

When the sensor position selector switch 6 is set to long hair, the moisture sensor 4 is free, and the stress of the hair during brushing pushes the moisture sensor 4 toward the bristle base 3 as shown in Fig. 4. .

Next, when the sensor position changeover switch 6 is set to the short position, the sensor push-up plate 14 moves between the moisture sensor 4 and the pudding I/substrate 13 in conjunction with the sensor position changeover switch 6.
The moisture sensor 4 is pushed up and protrudes onto the bristle base 3, as shown in FIG. However, the moisture sensor 4 is provided with a stopper (not shown) to prevent it from protruding beyond the state shown in FIG. When the sensor position changeover switch 6 is set to long hair again, the sensor push-up plate 14 is removed from the moisture sensor 4 and can be moved back due to the stress of the hair.

Note that the printed circuit board 13 is provided with a moisture content detection circuit (not shown) that detects the capacitance between the electrodes 8 and 9, and a display means (not shown) that displays and notifies the detection of the moisture content. It is provided in the main body 1.

The operation will be explained. That is, when the power switch 5 is turned on and the hair is brushed with the brush, the hair that has been cut by the bristle 2 is guided between the electrodes 8 and 9 of the moisture sensor 4. In this case, the height of the electrodes 8 and 9 in the direction of the bristle 2 is set to about 0.5 to 100 mL so that even if the amount of hair guided by brushing changes, a constant amount of hair is introduced into the moisture content measurement space 11.
It is set to l ml. Further, even if a large amount of hair is introduced, the insulator of the hair introducing portion 10 allows the hair exceeding a certain amount to be separated from the electrodes 8, 9 and not be affected. The moisture content of the hair guided into the moisture content measurement space 11 is detected as the capacitance between the electrodes 8 and 9, and the user is notified each time by display or buzzer notification. Further, the moisture content measurement space 11 is arranged above the bristle base 3 by the sensor base 7 so that the hair is reliably introduced into the moisture content measurement space 11 of the moisture sensor 4. However, in the case of short hair, the tip of the bristle 2 may hit the scalp and not be sufficiently guided to the moisture sensor 4 even when brushed. As shown in FIG. 5, the moisture sensor 4 is brought close to the tip of the bristle 2 by the sensor push-up plate 14, thereby ensuring that the hair is guided to the moisture sensor 4 even when brushing short hair.

Next, in the case of long hair, the moisture content can be measured at the position shown in Figure 5, but because of the moisture sensor 4, the effective length of the bristle 2 is short (and there is a disadvantage that a sufficient gap cannot be secured). Sufficient clearance is secured by switching the position changeover switch 6 for long hair and retracting the electrodes 8 and 9 as shown in Figure 4.As described above, the sensor position changeover switch 6 is used for short hair and long hair. By moving the moisture sensor 4 up and down depending on the hair, the hair is reliably introduced into the moisture sensor 4 in both cases, without sacrificing the amount of clearance in the case of long hair.

According to this embodiment, the moisture content of hair can be easily and quickly measured while performing normal brushing without requiring any operation for measuring the moisture content. In addition, since the moisture sensor 4 is movable relative to the bristle 2, it is possible to reliably introduce the hair into the moisture sensor 4 and measure the moisture content accurately regardless of whether the hair is short or long. A sufficient amount of hair space can be secured.

Note that a spring may be provided between the moisture sensor 4 and the printed circuit board 13 to bias the moisture sensor 4 in the direction of protruding outward.

A second embodiment of the invention is shown in FIG. That is, this brush is configured so that the moisture sensor 4 can move vertically with respect to the bristle base 3. That is, Bristle 2. The bristle base 3 and the printed circuit board 13 are fixed to the brush body 1, and only the moisture sensor 4 can move forward and backward. The position variable means is one in which the moisture sensor 4 is pushed up against the printed circuit board 13 by a spring 15. Therefore, when no force is applied to the moisture sensor 4, it protrudes from the bristle base 3 to the maximum extent, and this state is suitable for short hair. Also, in the case of long hair, when brushing the head, the hair is guided to the moisture sensor 4 in the same state as shown in the figure, but when it passes the head, the bristle 2 penetrates the hair without being obstructed by the head. The spring 15 is pushed by the tension during brushing, and the moisture sensor 4 falls into the bristle base 3, which relatively increases the effective length of the bristle 2 for brushing, so that a sufficient amount of hair can be secured.

A third embodiment of the invention is shown in FIG. That is, this brush has a bristle base 3. A moisture sensor 4 and a printed circuit board 13 are fixed to the brush body 1, a bristle 2 is provided on a bristle base 3 so as to be movable forward and backward, and a spring]5
is biased in a direction away from the printed circuit board 1. Therefore, when brushing the head of short hair or long hair, the bristle 2 hits the scalp and the pressure is repelled by the spring 15 due to the force, and the bristle 2 is pushed against the bristle base 3 and the moisture sensor 4
The closer the hair is to the head, the easier it is for hair to be introduced. However, when long hair is brushed past the head, there is nothing to push the bristle 2, and the bristle automatically protrudes to the maximum relative to the bristle base 3, providing a sufficient amount of hair clearance.

A fourth embodiment of the invention is shown in FIGS. 8 and 9.

That is, this brush has bristle 2 and bristle base 3.
The edge 3a of the bristle base 3 is attached to the groove 1a of the brush body 1 so that it can move forward and backward, and the cover spring 1
5, it is pushed in the direction away from the print 13. The moisture sensor 4 is fixed to a printed circuit board 13, and the printed circuit board 13 is fixed to the brush body 1.

In this embodiment, when brushing the hair on the head of short hair or long hair, the tip of the bristle 2 hits the scalp and is pushed into the brush body 1, so the moisture sensor 4 relatively comes out toward the head. , hair is easily introduced into the moisture content measurement space 11. Also, when brushing past the head of long hair, bristle 2
The tip becomes free and there is no pressing force, so it protrudes from the brush main body 1 by the spring 15, and the moisture sensor 4 is relatively pushed into the bristle base 13, ensuring a sufficient amount of hair clearance in the bristle 2. Ru.

A fifth embodiment of the invention is shown in FIG. That is,
This brush is attached to a dryer, and when combined with the dryer, it can perform efficient drying, and it also has a built-in control circuit (not shown) that automatically controls the output of the dryer according to the detected moisture content. This can prevent damage to your hair due to overdrying. In this dryer, bristles 2 are implanted on a bristle base 3, a moisture sensor 4 is installed approximately in the center of the bristle base 3, and an attachment 19 having a discharge port 18 is attached to the dryer 20.
It is installed on. This attachment 19 has the same structure as the brush of the previous embodiment. 21 is a power switch, 22 is an attachment/detachment button for the attachment brush 19, 2
3 is a moisture sensor operation selector switch, 24 is a suction port, 25
is the power line lead-in section. The moisture sensor 4 is movable relative to the bristle 2 in the same manner as in the embodiment described above, and hair is reliably introduced into the moisture sensor 4 regardless of whether the hair is short or long.

Regarding operation, when the moisture sensor changeover switch 23 is off, hot air or cold air can be obtained by turning on the power switch 21 in the same way as a normal hair dryer.

Here, when the moisture sensor changeover switch 23 is turned on, the moisture sensor 4 detects the moisture content of the hair introduced by brushing, and when the moisture content is high, the control circuit causes the maximum output of warm air to be discharged from the discharge port 18. As the hair gradually dries, the hot air temperature is lowered according to the moisture content of the hair until the optimum moisture content (1
0 to 13%), either cold air is applied or the dryer is automatically stopped, which prevents overdrying of the hair and does not damage the hair. Furthermore, by notifying the moisture content of the hair during drying using the display/notification means or the buzzer, the hair can be dried starting from areas with high moisture content, thereby achieving effective drying. By coating the surfaces of the electrodes 8 and 9 of the moisture sensor 4 with an insulator, electric shock can be prevented without insulating the moisture sensor circuit from the commercial power source, and corrosion of the surfaces of the electrodes 8 and 9 can be prevented.

〔Effect of the invention〕

According to the brush of the present invention, the moisture content of the hair can be detected by a high frequency method or the like by allowing the hair to enter between the electrodes, so that the moisture content can be easily and quickly measured while brushing.

Furthermore, in the case of short hair, by bringing the tip of the electrode close to the tip of the bristle using the variable position means, the hair can be inserted between the electrodes, so that the moisture content can be detected. On the other hand, in the case of long hair, by positioning the electrode on the root side of the bristle, there is an effect that the gap between the long hair does not become a hindrance.

[Brief explanation of drawings]

Fig. 1 is a plan view of an embodiment of the present invention, Fig. 2 is a front view thereof, Fig. 3 is a partially enlarged sectional front view thereof, and Fig. 4 is a partial sectional view when measuring the moisture content of long hair. , FIG. 5 is a partial cross-sectional view when measuring the moisture content of short hair, FIG. 6 is a partial cross-sectional view of the second embodiment, FIG. 7 is a partial cross-sectional view of the third embodiment, and FIG. 8 is a partial cross-sectional view of the second embodiment. 9 is a partial sectional view of the fourth embodiment, FIG. 9 is a partial sectional view showing the joint between the brush body and the bristle base, and FIG. 1O is a plan view of the fifth embodiment. DESCRIPTION OF SYMBOLS 1... Brush main body, 2... Bristle, 3... Bristle base, 6... Sensor position changeover switch of position variable means, 8, 9... Electrode diagram diagram diagram diagram diagram diagram 1. (nnear'

Claims (1)

[Claims] A brush body, a bristle base provided on the brush body and having a large number of bristles implanted therein, and at least one pair of protruding electrodes for moisture detection provided in the large number of bristles of the bristle base. and a variable position that allows at least one of the bristle and the electrode to move such that the tip of the electrode moves relatively between a position close to the tip of the bristle and a position retreated toward the base of the bristle. Brush with means.