JPH10263038A - Ultrasonic esthetic apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To disperse the strength of vibration to the skin by preventing concentration in the distribution of ultrasonic waves even while an ultrasonic vibrating probe is at standstill during the irradiation of the ultrasonic waves. SOLUTION: In an ultrasonic esthetic apparatus 1 having an ultrasonic vibrating probe 2 in which an ultrasonic vibrating element 3 vibrated ultrasonically by an output signal from an ultrasonic oscillating circuit is placed on the opposite side to the skin-abutting surface 5 of a probe metal part which makes contact with the skin, the skin-abutting surface 5 of the probe metal part 4 which transmits the vibration generated from the ultrasonic vibrating element 3 is shaped to have undulations 6 capable of dispersing the concentration of vibration strength to the skin.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ultrasonic esthetic device for applying ultrasonic waves to human skin to promote blood circulation.

[0002]

2. Description of the Related Art Conventionally, there has been proposed, for example, Utility Model Registration No. 3015 as a method of performing treatment by applying ultrasonic waves to human skin.
No. 061 discloses an ultrasonic therapy device in which a vibrator having a flat skin contact surface is provided at the tip of an ultrasonic vibration probe, and a vibration driving mechanism is provided inside. In a state where the object is applied to the skin contact surface or the skin of the vibrator, the vibrator is applied to the skin to irradiate ultrasonic waves.

[0003]

By the way, it is known that the distribution of ultrasonic waves emitted from the skin contact surface of the vibrator is such that the intensity of the vibration is more concentrated toward the center of the skin contact surface. When the ultrasonic vibration probe is stopped in a state where the skin contact surface is applied to the skin and the ultrasonic irradiation is performed in the conventional ultrasonic treatment device, the ultrasonic irradiation is locally performed without feeling the vibration, and the ultrasonic irradiation unit is used. There is a problem that the skin temperature rises abnormally and leads to burns. In particular, in the case of obtaining a skin beauty effect, the practitioner is unspecified, and therefore, it is essential to prevent the concentration of vibration intensity on the skin and to use the skin more safely.

[0004] The present invention has been made in view of the above-mentioned conventional example, and it is intended to prevent the concentration of the ultrasonic distribution and to disperse the vibration intensity on the skin even when the ultrasonic vibration probe is stopped during the irradiation of the ultrasonic wave. It is an object of the present invention to provide an ultrasonic esthetic device which can ensure sufficient safety even when an unspecified practitioner uses it to obtain a skin beauty effect.

[0005]

In order to solve the above-mentioned problems, the present invention provides a probe metal part which comes into contact with the skin on the side opposite to the skin contact surface 5 by an output signal from an ultrasonic oscillation circuit. An ultrasonic esthetic device provided with an ultrasonic vibration probe 2 provided with an ultrasonic vibration element 3 for oscillating an ultrasonic vibration, wherein a skin contact of a probe metal part 4 for transmitting vibration generated from the ultrasonic vibration element 3 is performed. It is characterized in that the surface 5 has a shape capable of dispersing the concentration of the vibration intensity on the skin. With this configuration, even when the ultrasonic vibration probe 2 is stopped at the time of ultrasonic irradiation, the probe metal portion 4 The shape of the skin contact surface 5 can prevent the concentration of the ultrasonic wave distribution and disperse the vibration intensity on the skin.

Here, in order to efficiently disperse the vibration intensity concentration on the skin, it is preferable that a plurality of undulations 6 are formed on the skin contact surface 5 of the probe metal part 4. Further, the protrusion apex 6a of the plurality of undulations 6 becomes the maximum thickness portion D of the probe metal portion 4, and the thickness D is set to an integral multiple of a half wavelength of the propagation vibration [(λ / 2) × n] (n is an integer). Is preferred.
Further, it is preferable to form the plurality of undulations 6 concentrically. The skin contact surface 5 of the probe metal portion 4 is formed in a convex or concave, convex or concave apex 6a, probe metal part in other than the maximum thickness portion D or the minimum thickness portion D ₁ of the 6b 4
Is preferably set to an integral multiple of a half wavelength of the propagation vibration. Further, the skin contact surface 5 of the probe metal part 4 is formed into a shape having a plurality of concentric undulations 6 in a convex or concave shape, and the maximum thickness portion D or the minimum thickness portion D of the convex or concave concentric vertices 6b, 6c. _{In cases} other than ₁ , the thickness d of the probe metal part 4 is preferably set to an integral multiple of a half wavelength of the propagation vibration.

Further, according to the present invention, an ultrasonic vibrating element 3 which ultrasonically vibrates in response to an output signal from an ultrasonic oscillating circuit is arranged on the side of the probe metal portion 4 which comes into contact with the skin, opposite to the skin contact surface 5. An ultrasonic esthetic device provided with an ultrasonic vibration probe 2 formed as described above, wherein a probe metal part 4 for transmitting vibration generated from the ultrasonic vibration element 3 has a rotating shaft 7 perpendicular to a skin contact surface 5. And the ultrasonic vibration element 3 is disposed eccentrically from the rotation shaft 7 on the opposite side of the probe metal part 4 from the skin contact surface 5. Then, when the probe metal part 4 rotates, the ultrasonic vibration element 3 starts to draw a rotational trajectory eccentric from the rotation shaft 7,
Therefore, even when a strong vibration intensity distribution is concentrated at the center of the skin contact surface 5 when the ultrasonic vibration probe 2 is stopped at the time of ultrasonic irradiation, the vibration intensity is reduced by the eccentric rotation of the ultrasonic vibration element 3. Strong portions are not concentrated at one point, and the vibration intensity concentration can be dispersed.

Here, the rotating shaft 7 of the probe metal part 4 is arranged at the center position of the circular skin contact surface 5 in a direction perpendicular to the skin contact surface 5 and is eccentric from the rotating shaft 7. It is preferable to dispose the ultrasonic vibration element 3. In this case, the circular skin contact surface 5 that contacts the skin is rotated around the rotation shaft 7 in a well-balanced manner, and at the same time, the skin is eccentrically moved by the ultrasonic vibration element 3. Vibration intensity can be dispersed.

Further, according to the present invention, an ultrasonic vibrating element 3 that ultrasonically vibrates according to an output signal from an ultrasonic oscillating circuit is provided on the opposite side of the skin contact surface 5 of the probe metal portion 4 that comes into contact with the skin. An ultrasonic esthetic device provided with an ultrasonic vibration probe 2 comprising a probe metal part 4 for transmitting vibration generated from an ultrasonic vibration element 3, the probe metal part 4 being surrounded by a substantially cylindrical cover 10. The skin contact surface 5 of the probe metal part 4 can be moved in a direction in which the skin contact surface 5 projects from the cover 10 and in a direction in which the skin contact surface 5 is accommodated in the cover 10. When the ultrasonic vibration probe 2 is stopped at the time of ultrasonic irradiation, the skin contact surface 5 of the probe metal part 4 is stored in the cover 10 so that the surface 5 can be separated from the skin.
By separating the skin contact surface 5 from the skin, the concentration of vibration intensity can be prevented.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below. As shown in FIG. 1A, the ultrasonic aesthetic device 1 has a cable 11 wired inside a cylindrical ultrasonic vibration probe 2 that can be gripped by hand, and an ultrasonic At the other end opposite to the one end of the ultrasonic vibration probe 2, a substantially disk-shaped probe metal part 4 centered on an axis N inclined with respect to the axis of the ultrasonic vibration probe 2 is provided. A skin contact surface 5 that contacts the skin is formed on the surface of the probe metal part 4, and an ultrasonic wave that is ultrasonically vibrated by an output signal from an ultrasonic oscillation circuit is provided on a side opposite to the skin contact surface 5. A vibration element 3 is provided.

The probe metal part 4 is an ultrasonic vibration element 3
The vibration generated from the skin is transmitted, and the skin contact surface 5 on the surface thereof has a shape capable of dispersing the concentration of the vibration intensity on the skin. In the embodiment shown in FIG. 1, a plurality of undulations 6 are provided on the skin contact surface 5 of the probe metal part 4. Each of the undulations 6 has a smooth dome shape, and functions to prevent the concentration of the ultrasonic wave distribution from the ultrasonic vibration element 3 and to disperse it.
Further, the protrusion vertex 6a of each undulation 6 is the maximum thickness of the probe metal part 4, and one of the plurality of protrusion vertices 6a is located at the center of the skin contact surface 5. doing.

When the ultrasonic aesthetic device 1 of the present invention is used, for example, as a cosmetic device, electricity is supplied to the ultrasonic vibrating element 3 through the cable 11 drawn into the ultrasonic vibrating probe 2. The vibration generated from the ultrasonic vibration element 3 is transmitted through the probe metal part 4 and transmitted to the skin contact surface 5 on the surface of the probe metal part 4. And
When the skin contact surface 5 of the probe metal part 4 or the skin is applied with a vibration medium such as gel on the skin and the skin contact surface 5 is moved, the ultrasonic vibration is converted into heat energy in the body. By increasing the deep temperature, blood circulation is promoted, and a cosmetic effect on the skin can be obtained.

At this time, the skin contact surface 5 of the probe metal part 4
Has a swell 6 so that the concentration of vibration intensity on the skin can be dispersed.
The distribution of the irradiated ultrasonic waves can prevent the vibration intensity from being strongly concentrated at the center of the skin contact surface 5. In other words, when the skin contact surface 5 of the probe metal part 4 is formed in a flat shape, the distribution of the ultrasonic waves emitted from the skin contact surface 5 of the vibrator becomes
When the ultrasonic vibration probe 2 is stationary at the time of ultrasonic irradiation, the ultrasonic irradiation is locally performed.
On the other hand, in the present embodiment, since the skin distribution surface 5 of the probe metal part 4 has the undulation 6 and the ultrasonic distribution is dispersed, when the ultrasonic vibration probe 2 is stopped at the time of ultrasonic irradiation. However, it is possible to prevent ultrasonic waves from being locally irradiated, and to suppress a rise in skin temperature. Therefore, by preventing the vibration intensity from concentrating on the skin even if the operator is unspecified, safer use can be ensured and the skin temperature can be maintained even if the predetermined skin portion is continuously irradiated with ultrasonic waves. Because it can prevent abnormal rise, it is very effective for beauty. In addition, since the dispersion effect can be obtained by a simple structure in which the waviness 6 is provided on the skin contact surface 5, there is an advantage that the manufacture of the probe metal part 4 is simplified, and an increase in equipment cost can be suppressed.

FIG. 2 shows another embodiment. In this embodiment, a plurality of undulations 6 are provided on a skin contact surface 5 of a probe metal part 4 that propagates generated vibration of an ultrasonic vibration element 3 installed inside an ultrasonic vibration probe 2, and a plurality of projections of the plurality of undulations 6. The vertex 6a is defined as the maximum thickness portion D of the probe metal portion 4, and the thickness D is an integral multiple of a half wavelength of the propagation vibration [(λ
/ 2) × n] (n is an integer). Other configurations are the same as those of the embodiment of FIG. Here, the reason why the maximum thickness portion D of the probe metal portion 4 is set to an integral multiple of a half wavelength of the propagation vibration is that when an ultrasonic wave (longitudinal wave) is transmitted to the probe metal portion 4, the probe metal portion 4 and the ultrasonic vibration element 3 has the maximum amplitude of the longitudinal wave, so that the skin contact surface 5 of the probe metal part 4 also has the maximum amplitude, the thickness d of the probe metal part 4 is set to the half wavelength of the propagation vibration. The reason is that it should be an integral multiple of. The reason why the skin contact surface 5 is formed into a shape having the undulation 6 is to prevent the concentration of the ultrasonic wave distribution and obtain the effect of dispersing the vibration intensity on the skin, as in the above-described embodiment. By making the thickness of the probe metal part 4 an integral multiple of a half wavelength of the propagation vibration at the maximum thickness part D, the maximum strength due to the irradiation of the ultrasonic wave over the entire skin contact surface 5 is simultaneously achieved while dispersing the vibration intensity. This is so that an effect can be obtained. This is the same in each of the embodiments shown in FIGS.

FIG. 3 shows still another embodiment. In this embodiment, a plurality of undulations 6 are formed concentrically. By forming the plurality of undulations 6 concentrically, in addition to the effect that the dispersion effect of the ultrasonic wave distribution is further improved, the projection apex 6a of the undulation 6 is separated from the center of the skin contact surface 5 by a certain distance. It appears concentrically, so that the same vibration intensity can be obtained regardless of the direction in which the skin contact surface 5 is oriented, and there is an advantage that ultrasonic waves can be evenly irradiated. Other configurations are the same as those of the embodiment of FIG.

FIG. 4 shows still another embodiment, in which the skin contact surface 5 of the probe metal part 4 is formed in a smooth convex shape, and the probe metal part other than the maximum thickness part D of the convex vertex 6b. By setting the thickness d of 4 to be an integral multiple of a half wavelength of the propagation vibration, the vibration intensity concentration on the skin may be dispersed. Other configurations are the same as those of the embodiment of FIG. Here, FIG. 5 shows the relationship between the shape of the skin contact surface 5 of the probe metal part 4 of FIG. 4 and the vibration intensity distribution, and FIG. 6 shows the conventional skin contact of the probe metal part 4 having a flat surface. The relationship between the shape of the surface 5 and the vibration intensity distribution is shown. First, in FIG. 6, when the thickness d of the probe metal part 4 having the flat skin contact surface 5 is matched with the maximum amplitude of the propagating vibration wave, a strong vibration intensity distribution is provided at the center of the skin contact surface 5, As the distribution of the ultrasonic wave emitted from the contact surface 5 becomes closer to the center of the skin contact surface 5, the vibration intensity is more concentrated, and as a result, the ultrasonic wave (longitudinal wave W) is generated at the center of the skin contact surface 5. When the ultrasonic vibration probe 2 is stopped at the time of ultrasonic irradiation, there is a problem that the ultrasonic wave is locally irradiated.

On the other hand, in the structure of FIG. 4 which is one embodiment of the present invention, the skin contact surface 5 of the probe metal portion 4 is formed.
Is formed in a convex shape, and the thickness of the maximum thickness portion D of the convex vertex 6b is set to be larger than an integral multiple of a half wavelength of the propagation vibration. Therefore, as shown in FIG. The portion D is different from the maximum amplitude of the propagating vibration wave, and especially the skin contact surface 5
At the center of the skin, the maximum amplitude of the ultrasonic wave (longitudinal wave W) can be weakened, and as a result, the center of the skin contact surface 5 is prevented from having an extremely strong vibration intensity distribution as compared with the surroundings. can do. On the other hand, if the maximum amplitude at the central portion of the skin contact surface 5 is reduced, the vibration intensity decreases with the same input to the ultrasonic vibration element 3 as a whole. By providing a thickness d portion that is an integral multiple of a half wavelength of the propagation vibration, the vibration intensity is increased at the thickness d portion that is an integral multiple of a half wavelength of the propagation vibration. A structure capable of preventing a decrease in vibration intensity as a whole of the skin contact surface 5 while concentrating and dispersing the vibration intensity at the central portion of the surface 5, and thus increasing the ultrasonic wave input intensity. While
An abnormal rise in skin temperature can be prevented and the beauty effect can be enhanced. The skin contact surface 5 may be formed not in a convex shape but in a smooth concave shape, and the thickness of the probe metal portion 4 may be set to an integral multiple of a half wavelength of the propagation vibration except for the minimum thickness portion of the concave vertex. Also, in this case, the same effect as shown in FIG. 4 can be obtained.

As a modified example of FIG. 3, as shown in FIG. 7, a plurality of concentric undulations 6 are provided on the skin contact surface 5 of the probe metal portion 4 in a convex or concave shape, and the convex or concave concentric undulations 6 are provided. apex 6b, the thickness d of the probe metal portion 4 may be an integral multiple of the half wavelength of propagating vibrations in other than the maximum thickness portion D or the minimum thickness portion D ₁ of the 6c. In this case, by making the plurality of undulations 6 concentric, in addition to the effect that the dispersion effect of the ultrasonic distribution is further improved, the projection apex 6 a of the undulations 6 is fixed at a certain distance from the center of the skin contact surface 5. When the skin contact surface 5 is oriented in any direction, the same vibration intensity can be obtained, so that the ultrasonic wave can be evenly radiated. Further, the maximum thickness portion D or the minimum thickness D can be obtained. since the thickness d of the probe metal portion 4 in non-thickness section D ₁ is an integral multiple of the half wavelength of propagating vibrations, while the vibration intensity of the convex vertex 6b is weakened, intensified vibration intensity at peripheral portions thereof As a result, it is possible to obtain the effect that the reduction of the vibration intensity as a whole of the skin contact surface 5 can be suppressed while achieving the concentrated dispersion of the vibration intensity.

In each of the above-described embodiments, the shape of the skin contact surface 5 of the probe metal portion 4 is formed into a shape having a waviness 6, or a convex or concave shape so as to perform concentrated dispersion of the ultrasonic distribution. However, instead of this, the skin contact surface 5 of the probe metal part 4 may be made flat, and the probe metal part 4 may be rotated or protruded and retired to perform the concentrated dispersion of the ultrasonic distribution. The embodiment is shown in the following FIGS.

FIG. 8 shows the probe metal part 4 in the direction of the arrow B in FIG. 8 with the skin contact surface 5 of the probe metal part 4 made flat and the rotation axis 7 perpendicular to the skin contact surface 5 as the center. Are rotatable, and the ultrasonic vibration element 3 is disposed on the side opposite to the skin contact surface 5 eccentrically from the rotation shaft 7. A motor M for rotating and driving the probe metal part 4 is disposed in the ultrasonic vibration probe 2, and a drive shaft 8 of the motor M is a rotating body 13 that supports an outer peripheral end of the probe metal part 4.
Mounted on The ultrasonic vibration element 3 has a skin contact surface 5
Therefore, when the probe metal part 4 is rotated by the motor M, the ultrasonic vibration element 3 moves the rotary trajectory eccentric from the rotary shaft 7 as shown in FIG. I will draw. Thereby, even when a strong vibration intensity distribution is concentrated at the center of the skin contact surface 5 when the ultrasonic vibration probe 2 is stopped at the time of ultrasonic irradiation, the eccentric rotation of the ultrasonic vibration element 3 It is possible to disperse the ultrasonic distribution without a portion having a strong vibration intensity being concentrated at one point. Moreover, since the skin contact surface 5 has a circular shape and the rotation shaft 7 is disposed at the center thereof, the circular skin contact surface 5 that contacts the skin is rotated around the rotation shaft 7 with good balance. At the same time, the eccentricity of the ultrasonic vibrating element 3 prevents an abnormal rise in skin temperature, thereby improving the beauty effect.

FIG. 9 shows a configuration in which the rotating shaft 7 of the probe metal part 4 is eccentric from the center of the skin contact surface 5 and the center of the ultrasonic vibration element 3 is eccentric from the rotating shaft 7. In this case, the probe metal part 4 and the ultrasonic vibrating element 3
9 are eccentrically rotated from the rotation shaft 7 to rotate, so that both the probe metal part 4 and the ultrasonic vibrating element 3
4B, the orbits eccentric from the center of the skin contact surface 5 are drawn in the arrow direction C. Therefore, when the ultrasonic vibration probe 2 is stopped at the time of ultrasonic irradiation, the skin contact surface 5
Even when the strong vibration intensity distribution is concentrated in the center of the, the portions with high vibration intensity are not concentrated at one point, and as a result, the distribution of the vibration intensity to the skin can be more effectively performed. Become like Other configurations are the same as those in FIG.

FIG. 10 shows a case in which the probe metal part 4 for transmitting the vibration generated from the ultrasonic vibration element 3 is surrounded by a substantially cylindrical cover 10, and the skin contact surface 5 of the probe metal part 4 is covered by the cover 1.
It is movable in a direction protruding from zero or in a direction in which it is stored. In this embodiment, for example, a screw cylinder 14 is fixed to the outer periphery of the drive shaft 8 of the forward / reverse rotation type motor M, and the screw cylinder 15 has a screw hole 15 of an elevating plate 16 that supports the outer peripheral end of the probe metal part 4. The lifting plate 16 is screwed, and is movable in the axial direction of the drive shaft 8 of the motor M. On the other hand, a cylindrical cover 10 is provided so as to surround the outer periphery of the skin contact surface 5 of the probe metal part 4. 4 can be brought into contact with the skin by protruding the skin contact surface 5 from the cover 10. On the other hand, when the ultrasonic vibration probe 2 is stopped at the time of ultrasonic irradiation, the motor M By being drawn in, the skin contact surface 5 can be separated from the skin, and the concentration of vibration intensity on the skin can be dispersed. Therefore, even if the ultrasonic vibration probe 2 is stopped and the ultrasonic wave is continuously applied to a predetermined skin portion, an abnormal increase in skin temperature can be prevented, which is extremely effective for beauty. In addition, since the skin contact surface 5 is securely separated from the skin by the cover 20, safety is further enhanced.

The ultrasonic esthetic device 1 of the present invention can be used not only as a cosmetic device but also as an ultrasonic therapy device.

[0024]

As described above, according to the first aspect of the present invention, the output signal from the ultrasonic oscillation circuit is provided on the opposite side of the skin contact surface of the probe metal portion which comes into contact with the skin. An ultrasonic esthetic device provided with an ultrasonic vibration probe having an ultrasonic vibration element for ultrasonic vibration, wherein a skin contact surface of a probe metal part for transmitting vibration generated from the ultrasonic vibration element is covered with a skin. The ultrasonic vibration is converted into thermal energy in the body by irradiating the skin with the skin contact surface and irradiating ultrasonic waves, and the blood temperature increases due to the rise in deep temperature. Is promoted, and a cosmetic effect on the skin is obtained. At this time, even if the ultrasonic vibration probe is stopped at the time of ultrasonic irradiation, the concentration of the ultrasonic distribution can be prevented by the shape of the skin contact surface of the probe metal part, and the vibration intensity to the skin can be dispersed, and as a result, The safety can be sufficiently ensured even when an unspecified practitioner uses it to obtain a skin beauty effect.

According to a second aspect of the present invention, in addition to the effect of the first aspect, since a plurality of undulations are formed on the skin contact surface of the probe metal portion, the concentration of the ultrasonic wave distribution is prevented by the undulations. With this, the vibration intensity to the skin can be dispersed. According to the third aspect of the present invention, in addition to the effect of the second aspect, the apex of the plurality of undulations becomes the maximum thickness portion of the probe metal portion, and the thickness is set to an integral multiple of a half wavelength of the propagation vibration. When an ultrasonic wave (longitudinal wave) is transmitted to the probe metal part, the amplitude becomes maximum at the skin contact surface of the probe metal part, and the skin contact surface has a undulating shape. Thus, the effect of dispersing the vibration intensity to the vibration can be obtained.

According to the fourth aspect of the present invention, in addition to the effect of the second or third aspect, since a plurality of undulations are formed concentrically, the effect of dispersing the ultrasonic wave distribution is further improved, and the undulations are further improved. The projection apex of the skin appears concentrically at a certain distance from the center of the skin contact surface, so that the same vibration intensity can be obtained regardless of the direction of the skin contact surface, and ultrasonic waves are evenly irradiated You can do it.

According to a fifth aspect of the present invention, in addition to the effect of the first aspect, the skin contact surface of the probe metal portion is formed in a convex or concave shape, and a maximum thickness portion of the convex or concave vertex is formed. Since the thickness of the probe metal portion other than the minimum thickness portion is set to an integral multiple of a half wavelength of the propagation vibration, the concentration of the vibration intensity on the skin can be efficiently dispersed. According to a sixth aspect of the present invention, in addition to the effect of the first aspect, the skin contact surface of the probe metal portion has a plurality of concentric undulations in a convex or concave shape, and a convex or concave concentric circle. Since the thickness of the probe metal portion other than the maximum thickness portion or the minimum thickness portion at the apex is set to an integral multiple of a half wavelength of the propagation vibration, the concentric circular undulations further improve the dispersion effect of the ultrasonic distribution. In addition to the effect, the ridge of the undulation appears concentrically at a certain distance from the center of the skin contact surface,
The same vibration intensity can be obtained even if the skin contact surface is oriented in any direction, and the effect of being able to irradiate ultrasonic waves evenly is obtained.Moreover, the maximum or minimum thickness of the convex or concave concentric vertex is obtained. In other cases, the thickness of the probe metal part is an integral multiple of half the wavelength of the propagation vibration, so that the vibration intensity at the convex vertex is weakened, while the vibration intensity is increased in the surrounding area, resulting in vibration The effect that the reduction of the vibration intensity as a whole of the skin contact surface can be suppressed while the concentration and dispersion of the intensity is achieved.

According to a seventh aspect of the present invention, an ultrasonic vibrating element for ultrasonically vibrating according to an output signal from an ultrasonic oscillating circuit is provided on a side of the probe metal portion which comes into contact with the skin, opposite to the skin contact surface. An ultrasonic esthetic device provided with an ultrasonic vibration probe, wherein a probe metal part for transmitting vibration generated from the ultrasonic vibration element has a rotation axis perpendicular to a skin contact surface, Since the ultrasonic vibrating element is arranged eccentrically from the rotation axis on the side opposite to the skin contact surface of the metal part, the ultrasonic wave is applied by irradiating the skin contact surface with the skin and irradiating the ultrasonic wave. The vibration is converted into heat energy in the body, and blood circulation is promoted by increasing the deep part temperature, and a cosmetic effect on the skin is obtained. At this time, the ultrasonic vibration element draws a rotational trajectory deviated from the rotation axis due to the rotation of the probe metal part. Therefore, when the ultrasonic vibration probe is stopped at the time of ultrasonic irradiation, the center of the skin contact surface is Even if the strong vibration intensity distribution is concentrated, the eccentric rotation of the ultrasonic vibration element prevents the strong vibration intensity from concentrating on one point, so that the vibration intensity on the skin can be dispersed as a result. Become.

According to an eighth aspect of the present invention, in addition to the effect of the first aspect, the rotation axis of the probe metal part is provided at a center position of the circular skin contact surface in a direction perpendicular to the skin contact surface. Since the ultrasonic vibrating element is arranged eccentrically from the rotation axis while being arranged, the circular skin contact surface in contact with the skin is rotated with good balance about the rotation axis, and at the same time the eccentricity of the ultrasonic vibration element Thereby, the vibration intensity to the skin can be dispersed.

According to a ninth aspect of the present invention, an ultrasonic vibration element that ultrasonically vibrates in response to an output signal from an ultrasonic oscillation circuit is disposed on a side of the probe metal portion that comes into contact with the skin, opposite to a skin contact surface. An ultrasonic esthetic device provided with an ultrasonic vibration probe, comprising: a probe metal portion that transmits vibration generated from an ultrasonic vibration element, a periphery of which is surrounded by a substantially cylindrical cover, and a skin contact of the probe metal portion. Since the surface can be moved in the direction that protrudes from the cover and in the direction that it is stored in the cover, the ultrasonic vibration is converted into heat energy in the body by irradiating the skin with the skin contact surface and irradiating ultrasonic waves. By increasing the deep temperature, blood circulation is promoted and a cosmetic effect on the skin is obtained.
At this time, the skin contact surface of the probe metal part has a structure in which the skin contact surface of the probe metal part can be separated from the skin. By storing the skin contact surface in the cover, the skin contact surface can be separated from the skin, and local ultrasonic irradiation can be prevented to further enhance the cosmetic effect.

[Brief description of the drawings]

FIGS. 1A and 1B show an example of an embodiment of the present invention, in which FIG. 1A is a cross-sectional view of an ultrasonic esthetic device, and FIG.

FIG. 2 is a cross-sectional view showing another embodiment.

FIG. 3 (a) is a perspective view showing still another embodiment,
(B) is a sectional view.

FIG. 4 (a) is a perspective view showing still another embodiment,
(B) is a sectional view.

FIG. 5 is an explanatory diagram of the skin contact surface shape and the vibration intensity distribution of FIG.

FIG. 6 is an explanatory diagram of a comparative example of a skin contact surface shape and a vibration intensity distribution.

FIG. 7 (a) is a perspective view showing still another embodiment,
(B) is a sectional view.

FIG. 8A is a cross-sectional view showing still another embodiment,
(B) is a perspective view.

FIG. 9A is a cross-sectional view illustrating still another embodiment,
(B) is a perspective view.

FIG. 10 is a sectional view showing still another embodiment.

[Explanation of symbols]

1 ultrasonic esthetic unit 2 ultrasonic probe 3 ultrasonic transducer 4 probe metal portion 5 skin contact surface 6 waviness 6a protruding apex 6b, 6c vertex 7 rotary shaft 10 cover D maximum thickness portion D ₁ the minimum thickness portion d Thickness

Claims (9)

[Claims] 1. An ultrasonic vibration probe comprising: an ultrasonic vibration element that ultrasonically vibrates according to an output signal from an ultrasonic oscillation circuit, on an opposite side of a skin contact surface of a probe metal part that contacts the skin. An ultrasonic esthetic device comprising: an ultrasonic oscillating device, wherein a skin contact surface of a probe metal part for transmitting vibration generated from an ultrasonic vibration element has a shape capable of dispersing vibration intensity concentration on skin. Beauty equipment. 2. The ultrasonic esthetic device according to claim 1, wherein a plurality of undulations are provided on the skin contact surface of the probe metal part. 3. The ultrasonic esthetic apparatus according to claim 2, wherein the vertexes of the plurality of undulations become the maximum thickness portion of the probe metal portion, and the thickness is an integral multiple of a half wavelength of the propagation vibration. 4. The ultrasonic esthetic apparatus according to claim 2, wherein a plurality of undulations are formed concentrically. 5. A skin contact surface of a probe metal part is formed in a convex or concave shape, and a thickness of the probe metal part is set to a half wavelength of propagation vibration except a maximum thickness part or a minimum thickness part of a convex or concave vertex. 2. The ultrasonic esthetic device according to claim 1, wherein the ultrasonic esthetic device is an integral multiple. 6. A probe metal part having a plurality of concentric undulations in a convex or concave shape in a skin contact surface of a probe metal part, and a probe metal part other than a maximum thickness part or a minimum thickness part of a convex or concave concentric vertex. 2. The ultrasonic estheter according to claim 1, wherein the thickness of the escalator is an integral multiple of a half wavelength of the propagation vibration. 7. An ultrasonic vibration probe in which an ultrasonic vibration element that ultrasonically vibrates according to an output signal from an ultrasonic oscillation circuit is disposed on a side of a metal part of a probe that comes into contact with the skin opposite to a skin contact surface. The probe metal part for transmitting the vibration generated from the ultrasonic vibration element has a rotation axis perpendicular to the skin contact surface, and the skin contact surface of the probe metal part. An ultrasonic esthetic device comprising an ultrasonic vibration element disposed eccentrically from the rotation axis on a side opposite to the ultrasonic vibration element. 8. A rotation axis of a probe metal part is disposed at a center position of a circular skin contact surface in a direction perpendicular to the skin contact surface, and an ultrasonic vibration element is eccentrically arranged from the rotation axis. The ultrasonic esthetic device according to claim 7, wherein 9. An ultrasonic vibration probe in which an ultrasonic vibration element that ultrasonically vibrates according to an output signal from an ultrasonic oscillation circuit is disposed on a side of a metal part of a probe that comes into contact with the skin, opposite to a skin contact surface. An ultrasonic esthetic device having a probe metal part for transmitting vibration generated from an ultrasonic vibrating element is surrounded by a substantially cylindrical cover, and a skin contact surface of the probe metal part is projected from the cover. And an ultrasonic esthetic device which is movable in a direction to be stored in the cover.