TWM510461U - Ultrasonic focused energy inspection unit of ultrasonic skin lift machine - Google Patents

Description

Ultrasonic focusing energy inspection unit for ultrasonic skinning machine

This creation is related to materials that absorb energy and produce physical changes; in particular, the inspection unit for ultrasonic focusing energy of an ultrasonic skinning machine.

In recent years, medical beauty technology in various countries has been constantly evolving and the speed of evolution has continued to grow. Among them, focusing on ultrasonic technology is one of the technologies currently used in High-intensity focused ultrasound (HIFU). This breakthrough technology is not The wound will be produced and the recovery period will take only one to two days without multiple treatments. In detail, the technology focuses on the sagging of the face and neck, focusing the ultrasonic energy on the 3 to 4.5 mm SMAS fascia below the dermis, and the ultrasonic energy forms a size in the SMAS fascia. The thermal coagulation point of a rice grain, whose temperature is about 65 ° C, is the optimal denaturation temperature of collagen, so it can really promote collagen regeneration; in addition, focusing on ultrasound technology and other earlier technologies The difference is that the ultrasonic wave of this technology can reach the deep depth below the skin, and the focus position is accurate, so as to enhance the effect of subcutaneous tissue by internal lifting.

The implementation of focused ultrasound technology requires an ultrasonic skinning machine to achieve the ultrasonic wave is emitted by the ceramic probe; wherein the energy, temperature and depth of the ultrasonic wave are subjected to the set voltage, time and other parameters and the ceramic probe Quality impact. As the number of ultrasonic waves emitted by the ultrasonic skinning machine increases, the internal parts will deteriorate due to the aging of the ultrasonic energy. The effect is not good.

In the past, when the ultrasonic energy was abnormal and the ultrasonic scanning machine was further tested, it was necessary to use an expensive thermal detection system and analysis software to detect and correct the voltage and time set by the machine. It is known whether the abnormality of the ultrasonic energy comes from the wear and tear of other parts inside the ultrasonic skinning machine. Therefore, the conventional detection method is not only costly, but also cannot be comprehensively tested for the ultrasonic skinning machine.

In view of this, the purpose of the present invention is to provide a supersonic focusing energy inspection unit for an ultrasonic skinning machine, which not only has a simple structure, but also has a low manufacturing cost, a simple and time-saving operation method, and can be used for comprehensively detecting ultrasonic waves. The condition of the leather machine.

In order to achieve the above object, the inspection unit for supersonic focusing energy of the ultrasonic pickup machine provided by the present invention comprises a base layer and a layer of bio-material, wherein the base layer has a melting point between 60 ° C and 70 ° C; a biomaterial layer is attached to the surface of the substrate, and the melting point of the biomaterial layer is also between 60 ° C and 70 ° C; thereby, when the probe of the ultrasonic skinning machine is close to the biomaterial layer, the super The focusing energy of the sound wave reaches between 60 ° C and 70 ° C, and a thermal condensation point is formed at the interface between the base layer and the bio-material layer.

The effect of the creation is that the ultrasonic sound focusing unit of the ultrasonic skinning machine has a simple structure, and the physical energy of the plastic shell and the bio-material layer is used to exhibit the ultrasonic energy, which can be easily seen by the naked eye. Whether there is a difference between the ultrasonic focusing condition of the ultrasonic skinning machine to be tested and the focusing condition of the standard ultrasonic wave to determine whether the ultrasonic ultrasonic machine to be tested is abnormal.

1‧‧‧Ultrasonic skinning machine

2‧‧‧Ceramic probe

100‧‧‧Test unit

10‧‧‧ grassroots

12‧‧‧ plastic shell

14‧‧‧ plastic shell

141‧‧‧ ruler line

20‧‧‧ Biomimetic material layer

200‧‧‧Test unit

30‧‧‧ grassroots

32‧‧‧ plastic case

40‧‧‧ Biomimetic material layer

D1‧‧‧ thickness

D2‧‧‧ spacing

U1‧‧‧ Ultrasonic

A1‧‧‧Hot condensate base

A2‧‧‧First thermal condensation point

A3‧‧‧second thermal condensation point

A4‧‧‧ third thermal condensation point

A5‧‧‧ fourth thermal condensation point

S1‧‧‧Standard Group

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a perspective view of an inspection unit for ultrasonic focusing energy of an ultrasonic pickup machine of a preferred embodiment.

2 is a schematic view showing the use of the ultrasonic focusing energy detecting unit of the above-described preferred embodiment of the ultrasonic skinning machine, and revealing that the ultrasonic probe of the ultrasonic probe from the ultrasonic skinning machine is emitted and focused on the plastic shell and the bio-material layer. The interface between the two.

Fig. 3 is a flow chart showing the inspection method of the inspection unit for ultrasonic focusing energy of the ultrasonic percutaneous stretching machine of the above preferred embodiment.

Fig. 4 is a plan view showing the inspection unit of the ultrasonic focusing energy of the ultrasonic percutaneous stretching machine of the above preferred embodiment, revealing the difference in focusing between the standard ultrasonic wave and the ultrasonic wave to be tested.

Fig. 5 is a flow chart showing the inspection method of the inspection unit for ultrasonic focusing energy of the ultrasonic skinning machine of another embodiment of the present invention.

Fig. 6 is a plan view showing the inspection unit for ultrasonic focusing energy of the ultrasonic percutaneous stretching machine of another embodiment of the present invention, showing that the surface of the plastic casing is marked with a ruled line.

Fig. 7 is a perspective view showing the ultrasonic focusing energy detecting unit of the ultrasonic skinning machine of the present embodiment, revealing that the two plastic shells are pivotally connected to each other.

Fig. 8 is a cross-sectional view showing the inspection unit for supersonic focusing energy of the ultrasonic percutaneous stretching machine of the above-described still another embodiment.

In order to explain the present invention more clearly, the preferred embodiment will be described in detail with reference to the accompanying drawings. As shown in FIG. 1 to FIG. 2, the ultrasonic focusing of the ultrasonic skinning machine of the preferred embodiment is described. The energy inspection unit 100 is configured to receive the ultrasonic energy generated by an ultrasonic skinning machine 1 and record the energy. The amount of accumulation is used to further detect whether the components of the ultrasonic skinning machine are abnormal.

As shown in FIG. 1 to FIG. 2, the inspection unit 100 is a structure including a first layer and a second layer, and more specifically, the first layer is a bio-material. The layer 20, which constitutes the second layer, is a base layer 10 forming a plastic shell 12.

The plastic case 12 is a housing having an open end face and a certain depth, which has a light transmissive property and a melting point of between 60 ° C and 70 ° C. The bio-material layer 20 is formed by injecting a liquid glue into the plastic shell 12 and solidifying, which also has a light-transmitting property and a melting point of between 60 ° C and 70 ° C. The biomaterial layer 20 is used to simulate biological soft tissue, so the thickness D1 can be adjusted according to the ultrasonic depth emitted by different types of ultrasonic skinning machines, such as ultrasonic depth for the face and neck. Between 1.5mm and 4.5mm under the skin, the thickness of the bio-material layer used to detect the ultrasonic scanning machine is between 1.5mm and 4.5mm; for example, for the trunk or limbs The ultrasonic ultrasonic depth of the fat is 40 mm under the skin, so the thickness of the bio-material layer for detecting the ultrasonic peeling machine is 40 mm; in this embodiment, the thickness D1 of the bio-material layer 20 is 1.5 mm. .

Referring to FIG. 2, the inspection unit 100 is used for testing the ultrasonic pickup machine 1 as a new machine, or when the number of ultrasonic emission is very small, the focus of the ultrasonic wave emitted from the ceramic probe 2 is obtained. The energy is normal. That is, the temperature of the ultrasonic wave is maintained at the optimum denaturation temperature of collagen in the human body - 65 ° C, which can effectively stimulate collagen regeneration in this temperature environment. However, if the ultrasonic energy is abnormal, it will make the collagen regeneration effect in the human body lower. Here, a method for detecting whether or not the focusing energy of the ultrasonic skinning machine 1 is normal by the inspection unit 100 will be described later.

Please cooperate with Figure 3 and Figure 4. First, the detection must be established. Reference standard used. In this step, the inspection unit 100 is first taken, and then the ceramic probe 2 of the ultrasonic percutaneous machine 1 which is still a new machine or has few ultrasonic emission times is aligned with the biomaterial layer 20, and then the ultrasonic skinning machine is used. The emitted ultrasonic wave U1 is focused on the interface between the bio-material material layer 20 and the plastic shell 12, and the focusing temperature thereof causes the bio-material material layer 20 and the plastic shell 12 to form a circular shape at the interface. The thermal condensation point a1 of the light can be easily visually observed from the outside, and the area size becomes a reference value. For the purpose of comparison, a plurality of thermal condensation points a1 may be formed in advance at the interface between the biomaterial layer 20 and the plastic shell 12, and the thermosetting base points a1 are defined to constitute a standard group S1.

Next, the ultrasonic wave emitted from the ultrasonic pickup machine (possibly the same model but the long-lasting ultrasonic skinning machine) to be tested is focused on an area other than the standard group S1, in this case, if The ultrasonic skinning machine to be tested has long been used for long-term use or due to aging of the parts, so that the ultrasonic energy is degraded, so that the interface between the bio-material material layer 20 and the plastic shell 12 forms an area smaller than the reference value (ie, thermal condensation). The area of the base point a1 is a small number of first thermal condensation points a2. At this time, after the detector observes the area of the first thermal condensation point a2 and compares the difference between the area and the reference value, it is found that the area of the first thermal condensation point a2 is significantly smaller than the reference value. The ultrasonic skinning machine is abnormal and needs further maintenance.

In the above embodiment, the thermal condensation point a1 generated by the ultrasonic wave emitted by the ultrasonic skinning machine 1 is a reference for detection, but the method of estimating the reference value by calculating the standard ultrasonic energy is not excluded. The thermal condensation points a1 are formed directly on the inspection unit. Through this pre-set method, the tester can use the inspection unit to reversely detect whether the ultrasonic pickup machine that has just been shipped but not used is abnormal. In special cases, when the ultrasonic ultrasonic machine that has just been manufactured is too large due to incorrect parameter setting or quality control, the boundary between the bio-material layer 20 and the plastic shell 12 will be made. The face forms a plurality of second thermal condensation points a3 having a larger area than the reference value. At this time, the detector can observe that the area of the second thermal condensation point a3 is significantly larger than the thermal condensation point a1, and then the ultrasonic peeling machine can be judged to be abnormal and needs to be returned to the original factory for maintenance.

In another case, when the ultrasonic ultrasonic machine emits irregular ultrasonic energy due to the damage of the parts, resulting in irregular focusing, the interface between the biomaterial layer 20 and the plastic shell 12 is formed. A plurality of third thermal condensation points a4 that are not circular. At this time, the detector can observe that the shape of the third thermal condensation point a4 is different from the thermal condensation point a1, and may be semi-circular or elliptical, and it can be judged that the ultrasonic skin-drawing machine is abnormal and needs to be further Overhaul.

In summary, the inspection unit 100 of the ultrasonic scanning machine of the present invention is not only simple in structure, but also can distinguish whether the size or shape of the thermal condensation point and the thermal condensation base point are different, and if there is a difference, the test unit can be judged to be tested. The ultrasonic skinning machine is abnormal.

5 and FIG. 6 , the only difference between the inspection unit of the ultrasonic focusing energy of the ultrasonic skinning machine and the inspection unit 100 is that the plastic case 14 of the inspection unit of the embodiment has a The ruler line 141 is an example of a metric mark for indicating the length unit. The inspection method of the inspection unit of this embodiment is as follows.

First, an ultrasonic skinning machine is taken, and the probe of the ultrasonic skinning machine is set to be movable in an equal interval in a predetermined stroke, and the distance of each equal spacing is defined as a set value. In particular, the set value is set by the internal program of the ultrasonic skinning machine, and the magnitude of the set value depends on the active portion of the ultrasonic energy, the magnitude of the energy, and the depth of action. That is, when the corresponding spacing is too small, the thermal condensation point is too dense, so that the energy of the ultrasonic focusing is too large, which may cause the skin to be burned. Conversely, when the corresponding spacing is too large, the ultrasonic energy cannot achieve the best destruction. The effect is not good enough. Therefore, the probe of the ultrasonic skinning machine moves between the preset strokes The distance is set in advance and appropriately depending on the application method of the ultrasonic wave.

Then, according to the foregoing inspection method of the inspection unit 100, the ultrasonic energy of the ultrasonic skinning machine is focused and formed into a plurality of fourth thermal condensation points a5; wherein any two adjacent fourth thermal condensation points have a Spacing D2. At this time, the detector can obtain the length of the spacing D2 through the ruler line 141, and further determine whether the length of the spacing D2 is different from the set value; if different, the ultrasonic drawing machine can be known. The part is abnormal and needs further maintenance.

Referring to FIG. 7 and FIG. 8 , the ultrasonic focusing energy inspection unit 200 of the ultrasonic skinning machine further includes a structure in which one of the first layer and the second layer is attached to the first structure. The layer is a bio-material layer 40, and the second layer is composed of a base layer 30 comprising two plastic shells 32 of the same structure. In this embodiment, the two plastic shells 32 are pivotally connected to each other and can be pivoted correspondingly, that is, they can be mutually engaged or opened, and the foreign matter dust impurities can be prevented from contaminating the bio-material layer 40 when the pair is combined, and The damage caused by the collision of the bio-material layer 40 is avoided; when opening, the ceramic probe 2 of the ultrasonic skinning machine 1 is faced with the bio-material layer 40 as the first layer, and the inspection Compared to unit 100, the area providing the ultrasonic skinning machine 1 is doubled.

The above is only a preferred embodiment of the present invention, and equivalent changes to the scope of the present application and the scope of the patent application are intended to be included in the scope of the present patent.

1‧‧‧Ultrasonic skinning machine

2‧‧‧Ceramic probe

10‧‧‧ grassroots

20‧‧‧ Biomimetic material layer

U1‧‧‧ Ultrasonic

A1‧‧‧Hot condensate base

Claims (5)

A supersonic focusing energy inspection unit for an ultrasonic skinning machine for testing the focusing energy of an ultrasonic wave, comprising: a base layer having a melting point between 60 ° C and 70 ° C; a bio-material layer Attached to the surface of the substrate, and the melting point of the bio-material layer is also between 60 ° C and 70 ° C; thereby, the focusing energy of the ultrasonic wave is obtained when the probe of the ultrasonic skinning machine approaches the bio-material layer A temperature between 60 ° C and 70 ° C is reached, and a thermal condensation point is formed at the interface between the base layer and the biomaterial layer. The ultrasonic sound focusing energy inspection unit of the ultrasonic skinning machine of claim 1, wherein the base layer comprises a plastic shell having a melting point of between 60 ° C and 70 ° C; the bio-material layer is liquid The compound is injected into the plastic shell to solidify the former. The inspection unit for ultrasonic focusing energy of the ultrasonic skinning machine according to claim 1, wherein the biomaterial material layer is a transparent colloid. The ultrasonic focusing power detecting unit of the ultrasonic skinning machine of claim 2, wherein the plastic casing has a metric mark for indicating the length unit. The ultrasonic cell focusing energy detecting unit of the ultrasonic skinning machine of claim 1, wherein the base layer comprises two plastic shells, and the two plastic shells are pivotally connected to each other and can be pivoted correspondingly.