TW201014657A - Portable ultrasonic mist generator - Google Patents

Abstract

In a portable ultrasonic mist generator, the temperature of an ultrasonic oscillator (3) is detected by a temperature sensor (18), and the oscillation signal of an oscillation circuit (7) is controlled by a controller (20) according to the signal detected by the temperature sensor (18), whereby the injection amount of mist (13) can be kept constant even if the temperature of the ultrasonic oscillator (3) is changed.

Description

201014657 VI. Description of the Invention: [Technical Field of the Invention] The present invention relates to a portable ultrasonic mist generating device. [Prior Art] Before the application of the present application, the applicant has developed and proposed a new form of portable ultrasonic mist generating device. Japanese Unexamined Patent Publication No. 2005~1 1 1328

(Patent Document 1) and JP-A-2006-142119 (Patent Literature). In the devices of the respective publications, the ultrasonic oscillator is provided at the bottom of the reservoir = and the oscillation circuit is connected to the amplifier. The amplifier is connected to the ultrasonic oscillator, and the oscillation signal is used to transmit the oscillation signal, and then the ultrasonic wave is vibrated by the oscillation signal to emit the ultrasonic wave. Therefore, the ultrasonic wave is used to vibrate the liquid in the storage tank, and then the self is vibrated. The liquid surface ejects the liquid column, and the liquid column generates a mist, and 'the nozzle is connected to the storage tank, and the mist is ejected from the nozzle. Therefore, for example, the device can be used for beauty treatment, and the mist is sprayed on the face. The skin is absorbed upwards. At this time, it is required to keep the amount of mist sprayed constant, and the amount of mist sprayed is related to the amplitude of the ultrasonic oscillator, that is, related to the vibration signal of the oscillation circuit. The greater the energy, the larger the amplitude of the ultrasonic vibrator and the larger the amount of fog, and the smaller the energy of the post-vibration signal, the smaller the amplitude of the ultrasonic (4) and the smaller the fog (4). Therefore, if the energy of the oscillation signal is kept at a certain timing, the amount of mist sprayed should also be kept constant. However, the problem lies in the temperature of the ultrasonic oscillator. For example, 3 201014657 If the ultrasonic oscillator is vibrated At the same time, the tTF, ^ -t - ^ V ^ ultra-chopper oscillator also heats up, and the temperature rises. In addition, the more the ultra-sonic oscillator is, the easier it is to vibrate. Right ultrasonic vibration ^ . . . . ^ ^ ^ I steals / the degree of the rise, the amplitude of the ultrasonic vibration is also large, and the amount of fogging is also increased by the guide l ^ ^ ^. Conversely, If the temperature of the ultrasonic oscillator is reduced, the amplitude of the ultrasonic oscillator is also reduced, so that the output of the mist is reduced. Therefore, even if the energy of the oscillation signal is kept constant, you are short of The taxi still has the problem of not being able to keep the amount of mist sprayed at a certain level. 'Because the portable ultrasonic mist generates a change in the temperature, and the fog can still be used. Therefore, the purpose of the present invention is to set the temperature of the ultrasonic oscillator. The amount of spray is kept constant. Patent Literature [Patent Document 2] Japanese Patent Laid-Open Publication No. Hei. No. Hei. No. Hei. No. Hei. No. Hei. On the bottom surface of the sump, and connecting the oscillating circuit to the amplifier, connecting the pulsator to the ultrasonic oscillator, transmitting the oscillating signal by the oscillating circuit, and then vibrating the ultrasonic oscillator by the oscillating signal, and emitting the super Therefore, the liquid in the reservoir can be vibrated by ultrasonic waves, the liquid column is discharged from the liquid surface nozzle, and then the liquid column generates a mist. Further, the nozzle is connected to the reservoir, and the mist is ejected from the nozzle. According to the present invention, the temperature of the ultrasonic oscillating device is detected by a temperature sensor. The temperature of the ultrasonic oscillator is indirectly detected. 201014657 And the control device is connected to the oscillating circuit and the temperature sensor, and the oscillating amount of the oscillating circuit is controlled by the control device according to the detection signal of the watt sensor, and the amount of the mist is kept constant. In a preferred embodiment, the heat sink configuration is disposed adjacent to the ultrasonic vibrator and the temperature sensor is mounted to the heat sink. Therefore, the sensible sensor detects the temperature of the heat sink and indirectly detects the temperature of the ultrasonic wave. / In other embodiments, in the vicinity of the ultrasonic oscillator, the temperature sensing device is disposed in the storage tank, and then the temperature sensor is used to detect the temperature of the liquid, and the ultrasonic oscillation is indirectly detected. Temperature of the device. Brewing [Embodiment] Hereinafter, an embodiment of the present invention will be described. Fig. 1 shows a portable ultrasonic mist generating device of the present invention. This device has a casing 1, a liquid storage tank 2, and an ultrasonic vibrator 3. The size of the cabinet 1 is one-handed. The storage tank is housed in the upper portion of the casing 1, and the ultrasonic vibration device 3 is disposed on the bottom surface of the storage tank 2. In this embodiment, the reservoir 2 is provided with a permeable membrane 4, and the reservoir 2 is divided into an upper portion and a lower portion, and an ultrasonic oscillator s is disposed on the lower surface of the lower portion. Further, a liquid 5' is placed in the lower portion of the reservoir 2, closed by the permeable membrane 4, and the liquid 6 is introduced into the upper portion of the reservoir 2. The liquid 5, 6 is composed of water. The permeable membrane 4 is made up of a thin sheet of film. 9, the oscillating circuit 7 is connected to the power circuit 8 and the amplifier 9, and the sorcerer 9 is connected to the ultrasonic stimulator 3, and the oscillating signal is transmitted by the oscillating circuit 7 and then oscillated by the oscillating signal. The acoustic oscillator 3 vibrates and emits ultrasonic 1G. The amplifier 9 is used to amplify the oscillation signal and is composed of a power transistor. Therefore, the liquid 5, 6 of the reservoir 2 can be vibrated by the ultrasonic wave so that the liquid column 12 is ejected from the liquid surface u, and then the mist 13 is generated by the liquid column 12. Further, the nozzle 14 is provided at the upper end of the casing ,, and the fan 15 is provided at the lower portion of the casing i, and the nozzle 14 is connected to the flow path i6 and the sump 2. Further, a flow path 17 is formed between the fan 15 and the storage tank 2, and the air can be fed by the fan 15, and the air is introduced into the storage tank through the flow path 17, so that the mist 13 can be sent out by the air. The mist 13 is ejected from the nozzle 14 through the flow path 16. Therefore, for example, the device can be used for cosmetic surgery to spray mist 13 on the face to absorb the skin. Also, in this apparatus, the temperature of the ultrasonic oscillator 3 can be detected by the temperature sensor 18. The temperature of the ultrasonic oscillator 3 is indirectly detected. In this embodiment, the heat sink 19 is disposed near the ultrasonic oscillator 3 and the temperature sensor 18 is mounted on the heat sink 19. The heat sink Η is used to discharge the heat of the ultrasonic vibration stomach 3 . Further, in the bottom surface of the storage tank 2, the central portion thereof protrudes downward, and the ultrasonic oscillation $3 is provided at the lower end of the protruding portion, and a through hole is formed in the central portion of the heat dissipation plate 19, and the through hole is fitted to The protruding portion of the storage tank 2. Further, the heat radiating plate 19 is pressed upward toward the bottom surface of the sump 2 around the protruding portion, and is attached to the bottom surface of the sump, and the temperature sensor 18 is attached to the heat radiating plate 19. Therefore, the temperature of the heat sink 19 can be detected by the temperature sensor 18, and the temperature of the ultrasonic oscillator 3 can be indirectly detected. 201014657

And the control device 20 is connected to the vibrating circuit 7, the power supply circuit 8, and/or the nucleus sensor 18, and controls the vibration of the vibrating circuit 7 by the control device 2G according to the detection signal of the temperature sensor 8. The signal is covered, and the amount of the mist 13 and the amount of the spray 13 are kept constant. For example, if the ultrasonic vibrator 3 is vibrated, the ultrasonic vibrator 3 will also heat up, and the temperature will rise, but it can be detected by the temperature sensor 18, and then detected according to the signal. The oscillation signal of the oscillation circuit 7 is controlled by the control device 20 to reduce its energy. Therefore, even if the temperature of the ultrasonic oscillating device 3 rises, the amplitude of the ultrasonic oscillator 3 does not increase, so that the amount of generation of the mist 13 and the discharge enthalpy do not increase. Conversely, if the temperature of the ultrasonic oscillator 3 drops, it is detected by the temperature sensor 18 and then the oscillation signal of the oscillation circuit 7 is controlled by the control device 20 according to the detection signal thereof to increase its This amount. Therefore, even if the temperature of the ultrasonic vibration detector 3 is lowered, the amplitude of the ultrasonic oscillating device 3 is not reduced, so that the amount of generated mist mist 13 and the discharge amount are not reduced. As a result, the discharge amount of the mist 13 can be maintained at determinate. The control device 20 is constituted by a computer. When the oscillation signal of the oscillation circuit 7 is controlled, the control is program control. Therefore, in the case of the device, when the mist is sprayed on the face and absorbed by the skin, even if the temperature of the ultrasonic vibrator 3 changes, the amount of the mist 13 can be ejected (4). Therefore, it is better. Moreover, if the temperature sensor 18 is attached to the ultrasonic oscillator 3, the temperature sensor 18 and the adhesive affect the vibration of the ultrasonic wave _3, but the situation of the device is as described above. The temperature sensor 18 is attached; mounted on the heat sink 19 to indirectly detect the temperature of the ultrasonic oscillator 3 7 201014657 Therefore, the temperature sensor 18 and the adhesive do not affect the ultrasonic vibrator 3 Vibration. Figure 2 shows other embodiments. In this embodiment, in the vicinity of the ultrasonic oscillator 3, the temperature sensor 18 is placed in the reservoir 2, and attached to the wall surface. Therefore, the temperature of the liquid 5 can be detected by the temperature sensor 18, and the temperature of the ultrasonic oscillator 3 can be indirectly detected. Further, the control device 20 is connected to the vibrating circuit 7 and the temperature sensor 18. Therefore, the oscillation signal of the oscillation circuit 7 can be controlled by the control device 2〇 according to the detection signal of the temperature sensor 18, so that the discharge amount of the mist 13 is maintained at one time. The temperature sensor 18 and the adhesive also do not affect the vibration of the ultrasonic oscillator 3. ° This device can be used not only for beauty but also for other purposes. j can also be used for medical purposes, that is, using a chemical as the liquid 5, and the milk 3 has metal ions and medicinal ingredients for absorption by the skin. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is an explanatory view showing an embodiment of the present invention. Fig. 2' is an explanatory view showing another embodiment. [Main component symbol description] 2 Liquid storage tank 3 Ultrasonic oscillator 5,6 Liquid 7 Oscillation circuit 201014657 10 Ultrasonic 11 Liquid level 12 Liquid column 13 Mist 14 Nozzle 18 Temperature sensor 19 Heat sink 20 Control device 9

Claims (1)

201014657 VII. Patent application scope: 1. A portable ultrasonic mist generating device is composed of the following components: a liquid storage storage tank; an ultrasonic oscillator disposed on the bottom surface of the storage tank; connected to the ultrasonic oscillator The oscillating circuit is connected to the amplifier to transmit an oscillating signal, and the ultrasonic oscillator vibrates the ultrasonic wave by the oscillating signal, and then vibrates the liquid of the sump by the ultrasonic wave from the liquid surface thereof Spraying a liquid column, and generating a mist by the liquid column; a nozzle connected to the storage tank to eject the mist; a temperature sensor for detecting the temperature of the ultrasonic oscillator; and a control device' The oscillating circuit and the temperature sensor control the oscillating signal according to the detection signal of the temperature sensor, so that the amount of the mist is kept constant. 2. The portable ultrasonic mist generating device of the first application of claim 1 wherein the heat sink is disposed adjacent to the ultrasonic oscillator, and the temperature sensor is mounted on the heat sink by the temperature The sensor detects the temperature of the heat sink and indirectly detects the temperature of the ultrasonic oscillator. 3. The portable ultrasonic mist generating device of the first aspect of the patent application, wherein 'in the vicinity of the ultrasonic oscillator, the temperature sensor is disposed in the storage tank' by the temperature sensor The temperature of the liquid is detected, and the temperature of the ultrasonic oscillator is indirectly detected.