JP2006312032A - Apparatus utilizing ultrasonic waves - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To detect whether or not ultrasonic waves are emitted easily and visually. <P>SOLUTION: An ultrasonic oscillation means 15 enables an ultrasonic oscillator 4a to intermittently produce ultrasonic oscillation. A liquid 12a or 12b changes its shape depending on the start or stop of the intermittent ultrasonic oscillation so that the ultrasonic oscillation is visually checked from its behavior. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

The present invention relates to an ultrasonic device that can easily detect whether, for example, an ultrasonic toothbrush or various ultrasonic emission devices emit ultrasonic waves.
Furthermore, it is related with the ultrasonic utilization apparatus which can improve a toothbrushing effect conventionally by implementing with an ultrasonic toothbrush.

Conventionally, as an ultrasonic device of this type, a piezoelectric element (piezoelectric transducer) is embedded as an ultrasonic vibrator at the tip of a toothbrush body (handle), and a plurality of brushes (collection of hairs) are implanted. The brush part (brush head) is detachably tightly fitted, and the piezoelectric element is energized to expand and contract its volume, thereby oscillating ultrasonic waves in a direction perpendicular to the axis direction of the handle, and a toothbrush There is one that propagates in the direction of flocking of the brush through the bottom surface of the brush portion that is in close contact with the outer surface of the main body (see, for example, Patent Document 1).
In addition, a hollow chamber communicating with a void extending the lead wire is provided in the projecting portion at the tip of the toothbrush body (handle) so as to open to the tip surface, and the lead wire passes from the tip surface of the projecting portion to the void through the hollow chamber. After the insertion, by filling the hollow chamber with a filler made of a curable fluid substance, and then inserting a piezoelectric element (piezoelectric vibrator) into the hollow chamber and then replenishing the filler with the filler. In some cases, the piezoelectric element is buried in a filler so that the ultrasonic energy of the piezoelectric element can be efficiently transmitted to the brush of the head body fitted in the protruding portion (see, for example, Patent Document 2).

Japanese Patent No. 3313715 (page 3-4, Fig. 1-3) Japanese Patent Laying-Open No. 2003-61985 (page 3-4, FIG. 1-3)

However, in such a conventional ultrasonic device, since ultrasonic waves are continuously emitted from the piezoelectric element during operation, are ultrasonic waves easily emitted even by general consumers? There is a problem that it cannot be easily detected or confirmed.
Especially in an ultrasonic toothbrush with an ultrasonic output of 1 W / cm ² or less, for example, an ultrasonic toothbrush, the ultrasonic wave has a higher frequency than the audible range and cannot be heard by the human ear. Since there is no easy way for end users to check whether or not they are coming out, there are many cases where the question is raised whether the user is really coming out even if ultrasound is emitted, and retailers that sell toothbrushes There is a problem that it is impossible to have a device capable of detecting ultrasonic waves.

The invention according to claim 1 of the present invention aims to easily detect visually whether or not ultrasonic waves are radiated.
The second aspect of the invention is intended to simplify the control circuit in addition to the object of the first aspect of the invention.
In addition to the object of the invention described in claim 1 or 2, the invention described in claim 3 is intended to more clearly visually check whether or not ultrasonic waves are radiated.
In addition to the object of the first, second or third aspect of the invention, the fourth aspect of the invention is intended to perform a detection test of whether or not ultrasonic waves are radiated regardless of the vibration function. is there.
In addition to the object of the first, second, third, or fourth aspect, the invention described in claim 5 is intended to improve the ability to remove plaque.

In order to achieve the above-mentioned object, the invention according to claim 1 of the present invention is an ultrasonic vibrator capable of adhering a liquid to a watertight ultrasonic vibration surface and an ultrasonic wave that intermittently oscillates ultrasonic waves. When the ultrasonic radiation presence / absence detection test is performed, the ultrasonic wave is intermittently oscillated, and the ultrasonic wave is oscillated by the behavior of the liquid adhering to the ultrasonic vibration surface of the ultrasonic vibration body. It is characterized by being detected.
As a result, when ultrasonic waves are radiated from the ultrasonic vibrating body, it is conventionally known that the surface tension of liquid such as water adhering to the ultrasonic vibration surface of the ultrasonic radiation portion is reduced. This is a phenomenon.
Using this property, ultrasonic vibrations are applied intermittently, so that liquids such as water rise or flatten due to surface tension, so it is possible to detect whether ultrasonic waves are emitted at a glance. It becomes possible.
The invention according to claim 2 adds the configuration in which the intermittent transmission used for the detection is also used for the transmission for the original purpose of the ultrasonic device to the configuration of the invention according to claim 1. It is characterized by that.
The invention described in claim 3 is characterized in that a configuration in which the intermittent period of ultrasonic vibration intermittently oscillated from the ultrasonic vibrator is changed from 1 Hz to 100 Hz is added to the structure of the invention described in claim 1 or 2. To do.
According to a fourth aspect of the present invention, in the configuration of the first, second, or third aspect, in addition to the ultrasonic vibrator, a means for mechanically vibrating at least a part of the apparatus main body is provided. The present invention is characterized in that a configuration is provided in which switching means for changing to a mode for stopping the operation of the mechanical vibration means is provided.
The invention according to claim 5 adds the configuration in which the ultrasonic vibrator and the ultrasonic oscillation means are provided to an oral hygiene instrument including an ultrasonic toothbrush to the configuration of the invention according to claim 2, 3 or 4. It is characterized by that.

According to the first aspect of the present invention, since the ultrasonic wave is intermittently oscillated from the ultrasonic vibrating body by the ultrasonic wave oscillating means, the shape of the liquid changes with the oscillation of the ultrasonic wave. It is possible to confirm the ultrasonic vibration by visually observing the behavior.
Therefore, it is possible to easily detect visually whether or not ultrasonic waves are radiated.
As a result, compared with the conventional type in which ultrasonic waves are continuously emitted from the piezoelectric element during operation, an ultrasonic output such as an ultrasonic toothbrush is inaudible and invisible to the ear. Even if it is a device using ultrasonic waves with a small output of 1 W / cm ² or less, it is convenient because the end user can easily check the output state of the ultrasonic waves without a specialized sensor or measuring instrument. There is no need to install a special sensor or measuring device for detecting ultrasonic waves at the dealers, so that sales can be promoted economically.

  In addition to the effect of the invention of claim 1, the invention of claim 2 uses the intermittent transmission used for detection for the transmission for the original purpose, thereby simplifying the control circuit, etc. Can be planned.

In addition to the effect of the invention of claim 1 or 2, the invention of claim 3 makes it possible to interrupt the ultrasonic vibration by changing the intermittent period of the ultrasonic vibration intermittently oscillated from the ultrasonic vibrator to 1 Hz to 100 Hz. Along with this, a change in the shape of a liquid such as water adhering to the ultrasonic vibration surface of the ultrasonic radiation portion can be seen better.
Therefore, it can be visually confirmed more clearly whether or not ultrasonic waves are emitted.

In addition to the effect of the invention of claim 1, 2 or 3, the invention of claim 4 is provided with means for mechanically vibrating at least a part of the apparatus main body separately from the ultrasonic vibrator. By providing a switching means for changing to a mode in which the mechanical vibration means is deactivated, when performing the ultrasonic radiation presence / absence detection test, if the switching means is changed to the operation stop mode of the mechanical vibration means, the machine The movement of the liquid due to vibration is eliminated, and the behavior of the liquid using only ultrasonic waves can be visually confirmed.
Therefore, it is possible to perform a detection test as to whether ultrasonic waves are radiated regardless of the vibration function.
As a result, when the ultrasonic device is, for example, an ultrasonic toothbrush, the user can recognize that the toothbrush is oscillating by mechanically vibrating the toothbrush, or can perform a toothbrushing operation without being moved by hand. In addition, in the case of an ultrasonic massage device, there is a device to which a mechanical massage function is added, but even in these cases, it can be confirmed visually whether or not ultrasonic waves are radiated.

In addition to the effect of the invention of claim 2, 3 or 4, the invention of claim 5 is provided with an ultrasonic vibrator and an ultrasonic oscillation means in an oral hygiene instrument including an ultrasonic toothbrush, thereby providing ultrasonic waves. Intermittent waves are radiated to the tooth surface, and the plaque adhering to the tooth surface by this intermittent wave repeats compression and expansion alternately, so the adhesion to the tooth surface decreases and the plaque easily peels off. .
Therefore, the plaque removal ability can be improved.

The apparatus using ultrasonic waves of the present invention is, for example, an oral hygiene instrument including an ultrasonic toothbrush or an ultrasonic massage apparatus, and an ultrasonic radiation unit in the apparatus main body, for example, a piezoelectric element (such as PZT, quartz, barium titanate). An ultrasonic vibrating body composed of a piezoelectric vibrator is incorporated, and an intermittent wave (burst wave) is radiated from the ultrasonic vibrating body to give movement to the radiation target.
The frequency of the ultrasonic vibration radiated from the ultrasonic vibration body is about 1.0 to 3.0 MHz so that an action that is harmless to the human body can be obtained by using the vibration acceleration by this ultrasonic oscillation. It is preferable to do.
Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

  This Example 1 shows the case where the ultrasonic utilization apparatus 1 of this invention is an ultrasonic toothbrush as shown to FIG. 1 (A) (B)-FIG. 2, This ultrasonic toothbrush 1 The toothbrush body 2 and the brush part 3 are formed of a handle corresponding to the apparatus body. The brush part 3 is provided with a fitting hole 3b so as to be arranged on the back surface of the brush 3a. The fitting hole 3b Is attached to the ultrasonic radiation part 4 provided at the tip of the neck part 2a of the toothbrush body 2 so as to be detachable.

As shown in FIG. 2, the ultrasonic radiating section 4 watertightly covers the outer periphery of the ultrasonic vibrating body 4 a made of a piezoelectric element with a casing 2 a forming the outer periphery of the toothbrush body 2, and the fitting hole 3 b of the brush section 3. Attached to the back surface of the brush 3a so that it cannot be easily escaped.
In addition, as a material of the casing 2a, plastic or metal can be used.

1-3, reference numeral 5 denotes a power ON / OFF switch button, 6 denotes an operation switch attached to the control circuit board 7, 8 denotes a power rechargeable battery, and 9 denotes the toothbrush body 2 described above. A motor with an eccentric weight for mechanical vibration generation provided as means for mechanically vibrating a part of the motor, 10 is an indicator lamp made of LED, 11a is a lead wire for an ultrasonic vibrator, and 11b is a lead wire for a power source. .
This ultrasonic vibrator lead 11a is connected to an output terminal (not shown in FIG. 2) of an ultrasonic oscillator circuit 15 (shown in FIG. 7), which will be described later, mounted on the ultrasonic vibrator 4a and the control circuit board 7. ).
The power supply lead wire 11b is wired through a through hole provided in the neck portion 2a of the toothbrush body 2 to connect a power input terminal (not shown) of the control circuit board 7 and the power supply rechargeable battery 8 together. Yes.
A lead wire that connects the motor 9 with an eccentric weight for generating mechanical vibration and a motor drive circuit 16 (shown in FIG. 7) described later is omitted.

Next, referring to FIG. 3 and FIG. 4, the action of the ultrasonic wave radiated from the ultrasonic vibrating body 4a of the ultrasonic radiation unit 4 will be described.
3A and 3B, when a liquid such as water is attached to the surface of the casing 2a that is the ultrasonic vibration surface of the ultrasonic radiation portion 4, that is, the ultrasonic vibration surface, the ultrasonic vibration member 4a is energized. When the ultrasonic vibration surface is not ultrasonically vibrated, as shown in FIG. 3A, the surface of the casing 2a is generally made of a hydrophobic material that hardly wets a liquid such as water. Therefore, it is well known that the liquid aggregates due to surface tension to form a hemisphere (this state is represented by reference numeral 12a).

When the ultrasonic vibrating body 4a is energized to ultrasonically vibrate the ultrasonic vibration surface, as shown in FIG. 3B, the surface tension of the liquid, such as water, is reduced. Then, it was crushed by gravity and the wetted area was widened (this state is represented by reference numeral 12b), and it was visually observed that the state of the liquid containing water was apparently changed in shape.
In addition, the code | symbol 13 shown to FIG. 3 (B) has shown that the ultrasonic wave is radiated | emitted.
4A and 4B are enlarged views of the state of change in the aggregation state of the liquid containing water.

If the change in the shape of the liquid containing water due to the presence or absence of such ultrasonic radiation is expressed as a change with respect to time, it can be expressed as shown in FIG.
That is, in FIG. 5A, the liquid is hemispherically raised 12a until no ultrasonic wave is radiated (time t1), but after the ultrasonic wave emission starts, the liquid is more widely crushed. When the shape changes continuously to the state 12b and the ultrasonic radiation is stopped (time t2), the state 12a is reached again.

  Therefore, in the present invention, when the ultrasonic vibration from the ultrasonic vibrating body 4a is intermittently performed to form an intermittent wave (burst wave), as shown in FIG. Until (time t1), the liquid state was 12a, but it changed to 12b during the oscillation period (Δt), and when radiation ended, the radiation stop period (Δt until the next radiation started) ': In this embodiment, the state continues until Δt' = Δt), and thereafter, while continuing the intermittent emission of ultrasonic waves, the vibration is repeated until time t2 is stopped.

Selection of the value of the intermittent period (Δt in the present embodiment) of the ultrasonic vibration will be described.
That is, it is difficult to confirm the ultrasonic vibration unless the liquid state 12a and the state 12b of FIG.
Then, as a result of experimenting by changing the intermittent period (repetitive frequency of the intermittent wave) of the ultrasonic vibration intermittently oscillated from the ultrasonic vibrator 4a, the results shown in Table 1 were obtained.

  From the results of Table 1, the preferable range of the intermittent period of the intermittent wave (burst wave) can be easily detected by visual observation if it is a value between approximately 1 Hz and 100 Hz.

Further, the above-described change in the shape of the radiation object due to the presence / absence of ultrasonic radiation is not limited to liquids such as water, and the same effect can be obtained, for example, in plaque (plaque) adhering to the tooth surface. I found out through experiments.
In this experiment, as shown in FIG. 6, a glass plate 12d to which pseudo plaque 12c having substantially the same adhesive force as dental plaque is attached is immersed in water, and the ultrasonic vibrating body 4a is arranged close to the glass plate 12d. At the same time, an ultrasonic oscillator (ultrasonic oscillation circuit) 15 'communicating with the ultrasonic vibrator 4a via the lead wire 11a causes ultrasonic vibration having a frequency of 1.6 MHz to be pseudo plaque from the ultrasonic vibrator 4a. Radiated intermittently toward 12c.

As a result of this experiment, when the ultrasonic vibration is radiated, the pseudo plaque 12c, which is the radiation target, is pressed toward the glass plate 12d to be compressed and deformed, and when the ultrasonic vibration is not radiated, It was visually observed that the pseudo plaque 12c was expanded and restored, and that the intermittent deformation of the pseudo plaque 12c alternately and repeatedly fluctuated by these intermittent oscillations.
In addition, when a continuous wave is radiated from the ultrasonic vibrating body 4a toward the pseudo plaque 12c under the same conditions, it is visually observed that the pseudo plaque 12c remains pressed toward the glass plate 12d and does not change greatly in shape. Observed.

In the ultrasonic toothbrush 1 described above, a preferred example of the control circuit 14 equipped with a program for outputting an intermittent wave of ultrasonic vibration as shown in FIG. 5B and creating a suitable ultrasonic radiation detection environment is shown in FIG. explain.
In addition, the same code | symbol is attached | subjected to the already demonstrated member in FIG. 7, and the overlapping description is abbreviate | omitted.

  The control circuit 14 includes an ultrasonic oscillation circuit 15 which is an ultrasonic oscillation means for intermittently operating the ultrasonic vibration body 4a, a motor drive circuit 16, and an LED display circuit 17 for lighting / flashing the LED display unit 10. And a control IC 18 composed of a microcomputer for driving these circuits.

  The power supply system includes a rechargeable battery 8, a charging coil 19 that supplies electric power from an external power source (not shown) by electromagnetic induction, and charging that charges the rechargeable battery 8 by converting alternating current supplied from the charging coil 19 into direct current. The circuit 20, the power supply circuit 21 that operates to stabilize the voltage supplied from the rechargeable battery 8 and prevent backflow from the rechargeable battery to the charging circuit 20 side, and the ON / OF of the operation switch 6 are detected. The switch input circuit 22 outputs a signal to the control IC 18.

  When the electromagnetic induction electromotive force is generated in the charging coil 19, the charging circuit 20 converts alternating current into direct current, charges the charging ground 8 through the power supply circuit 21, and outputs a charging circuit ON signal to the control IC 18 for reception. The control IC 18 outputs a signal for turning off all the circuits to the ultrasonic oscillation circuit 15, the motor drive circuit 16, and the LED display circuit 17.

  The power supply circuit 21 is configured to prevent a backflow of current from the rechargeable battery 8 to the charging circuit 22 during charging, and to connect the rechargeable battery 8 to the power supply circuit of the control circuit 14 at times other than charging.

  The switch input circuit 22 is programmed to detect ON / OFF of the operation switch 6 and to provide a switch input signal to the control IC 18 while the switch is turned ON.

  The control IC 18 gives an off signal to the ultrasonic oscillation circuit 15, the motor drive circuit 16 and the LED display circuit 17 when the operation switch 6 is in the OFF state and when the charging circuit ON signal is given as described above ( This state is hereinafter referred to as “standby mode”), and when a switch input signal is applied from the switch input circuit 22, an ON signal is applied to the circuits 15, 16, and 17 (hereinafter this state is referred to as “operation mode”). When 6 is kept pressed for a predetermined time (for example, 3 seconds) or longer, the control circuit 14 is programmed to enter the confirmation mode (test mode).

The operation mode described above is a signal (in this embodiment, a 1.6 MHz intermittent wave oscillation in which the frequency of ultrasonic vibration is modulated by 10 Hz) that causes the ultrasonic oscillation circuit 15 to perform intermittent oscillation of ultrasonic waves (in this embodiment, 10 Hz). This is a mode for outputting a rectangular wave signal), a signal for operating the motor 9 with an eccentric weight in the motor driving circuit 16, and a signal for lighting the LED display unit 10 in the LED display circuit 17.
Note that the signal generated by the ultrasonic oscillation circuit 15 intermittently oscillating is output to the ultrasonic radiator 4a as shown in FIG.

In the confirmation mode, the signal output to the ultrasonic oscillation circuit 15 is the same as described above, but the signal for causing the motor drive circuit 16 to stop the operation of the motor and the LED display circuit 17 to light or blink the LED display unit 6a. And a signal to be output.
Although the same ultrasonic waveform was used for both the operation mode and the confirmation mode in this embodiment, the ultrasonic oscillation in the operation mode can be changed as necessary, such as a continuous wave. .
Furthermore, it is possible to perform various control operations such as stopping the oscillation when a predetermined time (for example, 3 minutes) has passed.

Next, an example of a program selected by the operation of the operation switch 6 as means for switching between the standby mode, the operation mode and the confirmation mode described above will be described with reference to the flowchart shown in FIG.
When power is supplied to the power supply circuit of the control IC 18, as shown in FIG. 8, the control IC 18 starts a standby mode and monitors whether or not the operation switch 6 is turned on in step 1.

  When the switch input signal is input, the operation mode is entered, the ultrasonic wave is emitted from the ultrasonic radiator 4a, the motor 9 with the eccentric weight is actuated, the entire ultrasonic toothbrush 1 is vibrated, and the LED display unit 10 is moved. Light.

Subsequently, the confirmation mode selection in step 3 is entered.
In step 3, it is detected whether or not the confirmation mode switch has been turned on, that is, whether or not the operation switch 6 has been pressed for a predetermined time (for example, 3 seconds), and if the switch 6 has not been pressed for more than 3 seconds. Shifts to step 4, and if the switch is pressed for 3 seconds or more, the confirmation mode of step 7 is selected.

In step 4, it is monitored whether or not the operation switch 6 is pressed. When the operation switch 6 is turned on, the operation mode is stopped and the standby mode is entered.
If the operation switch 6 is not pressed in step 4, it is detected in step 5 whether or not charging is being performed, that is, whether or not the charging circuit ON in FIG. 7 has been detected. Stop operation mode and enter standby mode.
If charging is not in progress, step 6 is entered to see if 3 minutes have passed.

When 3 minutes have not elapsed, the process returns to step 3 and steps 3, 4, 5, and 6 are repeated until 3 minutes have elapsed. When 3 minutes have elapsed, the operation mode is stopped and the standby mode is entered.
When returning to step 3 and pressing the operation switch 6 for 3 seconds or more to enter the confirmation mode, the motor 9 stops from the operating state, and the ultrasonic vibration is output as an intermittent wave.
Then, the ultrasonic confirmation mode described above is entered.
Steps 9, 10, 11, and 12 are executed in the same manner as steps 4, 5, 6, and 8, respectively, and therefore redundant description is omitted.

  Therefore, in the ultrasonic toothbrush 1 having the above-described structure, when performing a test for detecting whether or not ultrasonic waves are radiated from the ultrasonic vibrator 4a, first, as shown in FIG. The brush unit 3 is removed from the sound wave radiating unit 4 to expose the surface of the casing 2a which is the ultrasonic vibration surface, and the operation switch 6 is pressed for 3 seconds or more by pressing the power ON / OFF switch button 5 to confirm the mode. Switch to.

In this state, as shown in FIG. 3, tap water, well water, etc., which are inexpensive and most readily available as test liquids, adhere to the surface of the casing 2 a which is the ultrasonic vibration surface of the ultrasonic radiation unit 4. As shown in FIG. 5 (B), the shape of the liquid of the water droplet changes with the oscillating / stopping of the intermittent ultrasonic oscillation emitted from the ultrasonic vibrator 4a.
The ultrasonic vibration surface of the ultrasonic radiation portion 4 is not limited to the surface of the casing 2a, but also the surface of the brush portion 3 attached to the ultrasonic radiation portion 4, and the brush 3a of the brush portion 3 is the same. Even if the inspection liquid adheres to a flat surface that does not exist, the shape of the liquid changes with the oscillation of the ultrasonic intermittent oscillation emitted from the ultrasonic vibrator 4a.
By visually observing the behavior of these liquids, anyone can easily confirm whether or not ultrasonic waves are radiated.

  Further, when the ultrasonic oscillation from the ultrasonic vibrating body 4a in the operation mode is an intermittent wave, the ultrasonic wave harmless to the human body of 1.0 MHz or higher from the ultrasonic vibrating body 4a of the ultrasonic radiation unit 4 is intermittent. A wave is radiated to the tooth surface via the brush 3a of the brush part 3.

  As a result, when an intermittent wave of ultrasonic waves is radiated to the tooth surface, the plaque is compressed and deformed, and when the emission of ultrasonic waves is stopped, the compressed plaque is expanded by the reaction force, The shape change of compression deformation and expansion deformation is repeated alternately by intermittent oscillation, and by stopping this intermittent oscillation, the one that repeated expansion and contraction stops suddenly, so the adhesion of plaque to the tooth surface Decreases and becomes easy to peel.

As a result of the experiment, it was observed that the plaque is more easily peeled off than an ultrasonic toothbrush that emits a continuous wave from the ultrasonic vibrator 4a.
In the experiment shown in FIG. 6, the intermittent period of the ultrasonic vibration intermittently oscillated from the ultrasonic vibrator 4a is several seconds (about 2 to about 2) with respect to the pseudo plaque 12c having substantially the same adhesive force as the plaque. Even when radiating for 3 seconds), the adhesive force was reduced due to the shape change of the pseudo plaque 12c.

  Further, if the average output level of the ultrasonic toothbrush 1 is the same, the temperature rise in the mouth due to the radiation (irradiation) of the ultrasonic waves is suppressed. Therefore, even if the instantaneous output level is raised, the temperature rise in the mouth is kept at a predetermined temperature (1). The degree of plaque removal ability can be further improved.

There are various types of ultrasonic utilizing apparatuses 1 to which the present invention is applied.
Accordingly, various modifications can be made to the embodiment for carrying out the present invention, and the present invention cannot be interpreted in a limited manner by the above-described embodiment, and various modifications can be made without changing the essence of the present invention. It goes without saying that it can be implemented.
If it demonstrates concretely, in the previous Example, although the case where the ultrasonic utilization apparatus 1 was an ultrasonic toothbrush was shown, it is not limited to this, For example, it replaces with an ultrasonic toothbrush and has a shape like a mouthpiece. It may be an oral hygiene device or an ultrasonic massage device for oral cavity using ultrasonic vibration.
In the case of an oral hygiene device such as a mouthpiece, the same effect as the ultrasonic toothbrush described above can be expected.

The one Example of the ultrasonic utilization apparatus of this invention is shown, (A) is a top view of an ultrasonic toothbrush, (B) is the side view. The state which removed the brush part by the vertical side view which follows the (X)-(X) line | wire of FIG. 1 (A) is shown. It is a principle figure of the present invention, (A) shows a liquid shape in case there is no ultrasonic radiation, and (B) shows a liquid shape in case there is ultrasonic radiation. It is explanatory drawing which expanded the liquid corresponding to FIG. 3 (A) (B) partially. It is explanatory drawing which shows the shape change of the liquid with time passage, and its waveform figure, (A) shows the behavior of the liquid when giving ultrasonic vibration continuously, (B) shows the intermittent vibration of ultrasonic. The behavior of the liquid when given is shown. It is explanatory drawing of the experiment example performed in order to see the shape change of plaque. It is a circuit diagram of the control part of an ultrasonic toothbrush. It is a flowchart which shows an example of operation | movement of a control part.

Explanation of symbols

1 Ultrasonic device (ultrasonic toothbrush) 2 Device body (toothbrush body)
2a toothbrush body neck part 3 brush part 3a brush 3b fitting hole 4 ultrasonic radiation part 4a ultrasonic radiation body 5 switch button 6 switching means (operation switch)
7 Control circuit board 8 Rechargeable battery for power supply 9 Mechanical vibration means (motor with eccentric weight) 10 Indicator lamp 11a Lead wire for ultrasonic vibrator 11b Lead wire for power source 12a Liquid when not ultrasonically vibrated 12b Ultrasonic vibration Liquid at time 12c Pseudo plaque 12d Glass plate 13 Radiation state of ultrasonic wave 14 Control circuit 15 Ultrasonic oscillation means (ultrasonic oscillation circuit) 15 'Ultrasonic oscillator 16 Motor drive circuit 17 LED display circuit 18 Control IC 19 Charging coil 20 Charging circuit 21 Power supply circuit 22 Switch input circuit

Claims (5)

An apparatus using ultrasonic waves is provided with an ultrasonic vibrator (4a) capable of adhering liquid to a watertight ultrasonic vibration surface and ultrasonic oscillation means (15) for intermittently oscillating ultrasonic waves. When performing the ultrasonic radiation presence / absence detection test, the ultrasonic wave is intermittently oscillated, and the ultrasonic oscillation is detected by the behavior of the liquid adhering to the ultrasonic vibration surface of the ultrasonic vibration body (4a). An ultrasonic device characterized by that. The ultrasonic utilization apparatus according to claim 1, wherein the intermittent oscillation used for the detection is also used for oscillation for an original purpose of the ultrasonic utilization apparatus. The ultrasonic utilization apparatus according to claim 1 or 2, wherein an intermittent period of ultrasonic vibration intermittently oscillated from the ultrasonic vibration body (4a) is 1 Hz to 100 Hz. When means (9) for mechanically vibrating at least a part of the apparatus main body (2) is provided separately from the ultrasonic vibrator (4a), the mechanical vibration means (9) is deactivated. The ultrasonic utilization apparatus according to claim 1, 2 or 3, further comprising switching means (6) for changing the mode. The ultrasonic utilization apparatus of Claim 2, 3 or 4 which provided the said ultrasonic vibration body (4a) and the ultrasonic oscillation means (15) in the oral hygiene instrument containing an ultrasonic toothbrush.

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