KR101325941B1 - A Vibrating Cosmetic Using Magnetic Sensing - Google Patents

Abstract

The present invention incorporates a vibrating means and a magnetic body detecting means in the cosmetic puff structure, and a magnetic material is installed in the case means to stop the operation of the vibration means when the magnetic body is detected and to install the vibration means to operate more easily if the magnetic body is not detected Regarding cosmetics vibrated by magnetic sensing, characterized in that the use of vibration type cosmetics,
A puff structure; A vibrating actuator inserted into the puff structure to cause vibration; A mounting case having a magnetic body for mounting the puff structure and generating a switching signal of the vibrating actuator; The vibrating actuator includes: a power supply inserted into the puff structure and supplying power to the apparatus; A non-contact magnetic sensing sensor for sensing the presence or absence of a magnetic substance inserted into the seating case and outputting an on switch signal and an off switch signal according to whether the magnetic substance is detected; And a controller for outputting a control signal for turning on / off the vibration means according to the detection result of the sensor.

Description

A Vibrating Cosmetic Using Magnetic Sensing

The present invention relates to cosmetics vibrated by magnetic sensing, and in particular, a vibration means and a magnetic sensing means are built into the cosmetic puff structure, and a magnetic body is installed in the case means to stop the operation of the vibrating means when the magnetic body is detected. If it is not detected by vibrating means is installed to operate the cosmetics that are vibrated by the magnetic sensing, characterized in that to use the vibration type cosmetics more easily.

Generally, cosmetic powders such as foundations, skin covers or twin cakes are used to naturally cover the blemishes and blemishes of the skin exposed to the outside such as the face, or to have clean and bright skin or clear and smooth skin. Will be used).

The cosmetics must be applied evenly without sticking to the area to be applied to make up a close feeling, as well as to make up by touching to satisfy the emotional feeling, which is used for cosmetic puffs.

The cosmetic puff taking the above cosmetics has a puff shaped to apply the cosmetics while lightly tapping the face of the cosmetics while putting the finger on the finger insertion band formed on one side to the cosmetic site, and the puff is automatically applied. There's a vibrating puff that lets you knock on your makeup.

Among the puffs, the puffs that can be used with fingers can be used to make makeup by tapping the puffs on the skin with artificial force. I couldn't lift my make-up and I couldn't make up quickly because there was a limit to the speed of tapping by hand.

The above-mentioned cosmetics are put on the area to be make-up uniformly and spread uniformly, and the make-up puff is used for touching to satisfy emotional feeling.

These puffs have puff pads that allow the cosmetics to be spread while the fingers are placed on the finger insertion bands formed on one side and the cosmetic is knocked on the cosmetic area while the fingers are pinched. There is a vibrating puff (also known in the industry as "electric puff").

The vibration puff according to the prior art is configured in the exterior case, the interior of the exterior case and the vibration motor for generating a vibration force by receiving the power of the battery, the puff pad is coupled to receive the vibration force generated in the vibration motor It comprises a puff pad coupling.

Therefore, in the related art, when the battery power is applied to the vibration motor, the vibration motor is driven to generate vibration force, which is transmitted to the puff pad engaging portion through the exterior case, and the puff pad automatically applies the makeup part. By hitting, the cosmetics can be settled on the makeup area without using artificial force.

On the other hand, as an example of such a vibration puff, looking at the registered Patent No. 10-1058359, as shown in Figures 1 to 3, on one side of the cosmetic puff 10, the finger insertion band 11 is formed In this case, a separate vibration means 20 is built into the inside of the puff 10, wherein the vibration means 20 includes a support plate 21 made of a soft elastic material and a vibrator 22 coupled to the support plate 21. ) And the battery 23 and the switch 24 and the control plate 25, the vibration means 20 is configured to be inserted into the puff 10 is sealed in a separate waterproof pack 30, Looking at the effects of the prior art, by effectively transmitting the vibration of the vibrator to the puff is to be able to make makeup in a state of excellent adhesion as well as a more easy makeup when using the puff, to maintain the same shape as the existing puff According to existing The built-in waterproof pack prevents the vibrating means from being contaminated by the cosmetics perfused with puffs, which prolongs the service life, and enables the water to be washed with the puffs for more clean and hygienic use. It is.

However, the prior art has been inconvenient to press the operation button separately because it is configured to operate using the contact switch.

In other words, the mechanical switch structure that must be touched by the ball at the time of first use, there is an inconvenience in use, there is a high possibility of failure by frequent switching operation. In addition, although the timer circuit is mounted to be configured to operate only for a predetermined time, it is inconvenient to set a new operation start timing.

In addition, there is a disadvantage that the replacement cost is expensive because the switching means must replace the entire vibration means at the time of failure.

The present invention is to solve the above problems, by configuring a non-contact magnetic sensing switching means using a reed sensor or a Hall sensor in the configuration of the vibration puff to simplify the switching operation to use the vibration puff more conveniently The purpose is to make it possible.

In addition, the main body is provided with a magnetic signal that transmits an electrical signal to the reed sensor or hall sensor, and the vibration device and the battery are enclosed in a waterproof pack so as to be separately stored in the puff to protect the vibration means and to protect the magnetic means when the magnetic switch is damaged. The purpose is to strengthen the troubleshooting by replacing the bay.

As means for achieving the above object,

The present invention is a puff structure (100); A vibration actuator 200 inserted into the puff structure to generate vibration; A mounting case (300) for mounting the puff structure and having a magnetic material for generating a switching signal of the vibrating actuator; The vibration actuator 200 includes a power supply unit 210 inserted into the puff structure and supplying power to the device; A non-contact magnetic sensing sensor 220 for sensing the presence or absence of a magnetic substance inserted into the seating case and outputting an on switch signal and an off switch signal according to whether the magnetic substance is detected; The puff structure is electrically connected to the non-contact magnetic sensing sensor, and when the on-switch signal is input, the puff structure is inserted into the seating case. When the off-switch signal is input, the puff structure is separated from the seating case. A controller 230 for determining that it is determined and outputting a control signal corresponding thereto; It is characterized in that it comprises a vibration means 240 for generating vibration while the power is supplied to the control unit according to the control signal itself.

The non-contact magnetic sensing sensor 220 may include a superconducting quantum interference device (SQUID), a search coil magnetometer, a magnetoresistive sensor, a hall sensor, a magnet diode, a magnet transistor and a lead. It is one of the sensors selected.

In addition, the vibration actuator 200 is characterized in that it is housed in a sealing means for waterproofing.

In addition, the non-contact magnetic sensing sensor 220 and the control unit 230, and the Hall IC 232 consisting of a circuit operating voltage applying means 231, a Hall sensor 220b, and sensor stabilizing elements (R1, C1) and ; A voltage amplifier 233 for amplifying the voltage signal output from the hall IC 232; A power transistor 234 which is switched while the base end is activated by the output of the voltage amplifier 233 and supplies power to the vibration means 240 connected to the collector end so as to generate vibration; It is characterized by consisting of a bypass diode 235 connected in parallel with the vibration means in order to bypass the counter electromotive voltage when the vibration means is off.

In addition, the non-contact magnetic sensing sensor 220 and the control unit 230, and the Hall IC 232 consisting of a circuit operating voltage applying means 231, a Hall sensor 220b, and sensor stabilizing elements (R1, C1) and ; A power transistor 234 for switching while the base end is activated according to the output of the hall sensor and turning on the vibration means 240 connected to the collector end; A bypass diode 235 connected to the vibration means in parallel to bypass the counter voltage when the vibration means is turned off; Characterized by the capacitor 236 to block the AC noise generated from the vibration motor.

In addition, the vibration means 240, the shaft 245 is inserted into the upper center of the bracket 249, the donut which is spaced apart from the shaft 245 on the upper surface of the bracket 249 to surround the outer periphery of the shaft A magnet 248 having a shape is installed, and a brush 251 having a bending portion is in contact with the upper commutator substrate 243 in the space between the magnets, and the commutator substrate 243 is a rear surface of the rotor 242. The rotor 242 is provided on the upper side of the magnet 248, is supported by the bearing is rotated about the shaft 245, the upper surface of the rotor 242 where the commutator substrate 243 is located In this case, the winding coil 247 is separated from each other, and a weight body 253 for applying an eccentric force therebetween is characterized in that it is formed.

In addition, the lead wire 254 or the connector 255 is further provided to connect the power supply with the lower printed circuit board 250 formed on the upper surface of the bracket 249.

As described above, the present invention has an effect that the vibration puff can be used more conveniently by configuring the device so that the non-contact switching operation using the reed sensor or the hall sensor is possible in configuring the vibration puff.

In addition, the main body is provided with a magnetic signal that transmits an electrical signal to the hall sensor, and the vibration device and the battery are enclosed in a waterproof pack so as to be separately stored in the puff, thereby protecting the vibration means safely and replacing only the magnetic when the magnetic switch is damaged. It is effective to enhance troubleshooting.

1 is a perspective view of a cosmetic having a vibrating means in the prior art.
2 is a cross-sectional view of a cosmetic having vibration means in the prior art.
Figure 3 is a perspective view of the vibration means in the prior art.
Figure 4 is an exploded perspective view of the present invention cosmetics.
5 is a cross-sectional view of the present invention combined cosmetics.
Figure 6 is an embodiment of the present invention cosmetics.
7 is a circuit block diagram of the present invention.
8 is a reed sensor switch on state diagram of the present invention.
Figure 9 is a reed sensor switch off state diagram of the present invention.
10 is a block diagram of a hall sensor of the present invention.
Figure 11 is a plan view of the vibrating means rotor of the present invention.
12 is a cross-sectional view of the vibration means of the present invention.
Figure 13 is an embodiment of the vibration means terminal form of the present invention.
14 is another embodiment of the vibration means terminal form of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed.

Figure 4 is an exploded perspective view of the present invention cosmetics.

5 is a cross-sectional view of the present invention combined cosmetics.

Figure 6 is an embodiment of the present invention cosmetics.

7 is a circuit block diagram of the present invention;

The components of the present invention are largely composed of a puff structure 100, a vibration actuator 200, and a seating case 300. The puff structure 100 is a makeup tool, and the seating case 300 is It is a container for storing the puff structure 100, it is made by installing the magnetic body 310 in the center of the mounting case 300. In addition, the vibration actuator 200 is inserted into the puff structure 100 to detect the magnetic body 310 and the vibration actuator 200 operates when the puff structure 100 is used, thereby causing vibration in the puff structure 100. To be printed.

Looking at the puff structure 100 in more detail, it consists of an upper air cushion 110, the lower air cushion (120). The upper and lower cushions are means for touching the user's face by squeezing the cosmetic liquid as a makeup tool.

The vibrating actuator 200 includes a power supply unit 210, a non-contact magnetic sensing sensor 220, a control unit 230, and a vibration unit 240. In addition, the vibration actuator 200 may be accommodated by the sealing means 130 for waterproofing, the sealing means 130 is preferably to have a waterproof function. That is, since the vibrating actuator 200 is electrically operated, when water is soaked in the makeup puff structure 100, the water penetrates into the vibrating actuator 200, which may cause a failure. In the sealing means having a waterproof function to surround the vibration actuator 200 to protect various power supply and sensors from foreign matter.

Hereinafter, the vibration actuator 200 will be described in more detail.

The power supply unit 210 is inserted between the upper cushion 110 and the lower cushion 120 and is a means for supplying power to various devices.

The non-contact magnetic sensing sensor 220 detects the presence or absence of the magnetic body 310 inserted into the mounting case 300, and outputs an on switch signal and an off switch signal according to whether the magnetic body 310 is detected. .

The controller 230 is electrically connected to the non-contact magnetic sensing sensor 220, and when the on-switch signal is input according to the detection result of the sensor, it is determined that the puff structure 100 is inserted into the seating case 300, When the off switch signal is input, it is determined that the puff structure 100 is separated from the seating case 300 and outputs a control signal according to the puff structure 100. In general, the controller 230 forms a circuit pattern on the controller board and has a plurality of chips mounted on the circuit pattern. Since a plurality of resistors, capacitors, and chips are generally mounted in the configuration of the control unit as described above, the present invention will be collectively referred to as a control unit for convenience of description.

The vibration means 240 is supplied with power in response to a control signal to the controller 230 to generate vibration while rotating itself. Then, the user by the vibration of the vibration means 240 can make the makeup more convenient.

Hereinafter, the non-contact magnetic sensor 220 will be described in more detail.

The non-contact magnetic sensing sensor 220 applied to the present invention includes, for example, a reed sensor 220a, a hall sensor 220b, and the like.

First, referring to the operation of the lead sensor 220a, when the lead sensor 220a is close to the magnetic body installed in the seating case, that is, the puff structure 100 in which the lead sensor 220a is installed is placed on the seating case 300. When inserted, the reed sensor 220a outputs a switching signal short-circuited by the magnetic force of the magnetic body 310 as shown in FIG. 8, and when the user separates it from the seating case 300 to use the puff structure 100. As the lead sensor 220a and the magnetic body 310 are separated from each other as shown in FIG. 9, the magnetic force of the magnetic body does not reach the lead sensor 220a to reach an open state, thereby outputting an off switching signal.

Accordingly, when the lead sensor 220a is shorted, the controller 230 stops the operation of the vibration means 240 because the puff structure 100 is stored in the seating case 300 and will no longer be used. When the 220a) is opened, the puff structure 100 is to be separated from the seating case 300 so that the puff structure 100 is vibrated by operating the vibration means 240.

In addition, the non-contact magnetic sensing sensor 220 may be classified into various types according to the area of the magnetic field to be measured, and may also be classified into various types according to the material used for the sensor [Proceedings of the IEEE, Vol. . 78, No. 6, 973 (1990).

In order to measure minute magnetic field changes of several tens of fT to nT, SQUID (Superconducting Quantum Interference Device), search coil magnetometer, and magnetometer by optical method are used. And so on. In addition, when measuring a large magnetic field of about several tens of mT, a sensor such as a hall sensor, a magnetic diode (magnetodiode), a magnetic transistor (magnetotransistor) is used. The Hall sensor is one of the sensors widely used as a magnetic sensor, and is widely used in automobile parts, switches, and the like.

Since the Hall sensor 220b is easy to use and inexpensive, if the magnetic field can be measured with high sensitivity using the hall sensor 220b, a high-sensitivity measuring device can be configured without using an expensive sensor, thereby improving the added value of the product. In addition to the large economic value, the technical value is also great.

In addition, the Hall sensor 220b is widely used to measure a magnetic field of several tens of mG or more, and the Hall element mainly used is composed of elements such as GaAs, InSb, InAs, and Ge. FIG. 10 is an explanatory diagram showing an operation principle of a hall sensor including such a hall element, and the operation principle will be described below with reference to FIG. 10.

As shown in FIG. 10, when a constant current or voltage is applied to both ends of the Hall element, the charge q in the element moves at a constant speed v, and in this state, the magnetic field B is applied perpendicularly to the Hall element. The moving charge then receives the Lorentz force (F = q (v × B)). The direction of the force is the direction perpendicular to the direction of the charge rate and the direction of the magnetic field. If a long, flat conductor is placed in the magnetic field, the movement of the charge is forced to move in the direction perpendicular to the direction of the current and the magnetic field. This force causes electrons to collect on one edge of the conductor and cations collect on the other edge. An electric field is generated by electrons and cations distributed at both edges, and a force (F = qE) is generated in a direction to cancel the Lorentz force caused by the magnetic field.

The present invention detects the magnetic body 310 using the Hall sensor 220b having the structure as described above, when the puff structure 100 in which the Hall sensor 220b is installed is inserted into the seating case 300, the Hall sensor ( 220b) is the induced current is generated by the magnetic force of the magnetic material 310 and thereby outputs a switching signal that has been conducted, while the user is separated from the mounting case 300 to use the puff structure 100 As the Hall sensor 220b and the magnetic body 310 are separated from each other, the magnetic force of the magnetic body 310 does not reach, and thus the Hall sensor 220b reaches an open state, thereby outputting an off switching signal.

Accordingly, the control unit 230 stops the operation of the vibration means 240 because the induction current is generated in the hall sensor 220b so that the puff structure 100 is accommodated in the seating case 300 and no longer used. When the hall sensor 220b outputs an off signal, the puff structure 100 is to be separated from the seating case 300 so that the puff structure 100 is vibrated by operating the vibration means 240.

On the other hand, Figure 11 is a vibration means driving circuit embodiment of the non-contact magnetic sensor and the control unit, it shows a configuration for automatically operating the vibration means 240 in accordance with the output of the Hall sensor 220b according to the detection of the magnetic body (310).

That is, the Hall IC 232 including the circuit operating voltage applying means 231, the Hall sensor 220b, and the sensor stabilizing elements R1 and C1, and a voltage amplifier for amplifying the voltage signal output from the Hall IC 232. 233 and a power transistor 234 for switching the base end by being activated by the output of the voltage amplifier 233 and supplying power to the vibration means 240 connected to the collector end to induce vibration. And a bypass diode 235 connected in parallel with the vibration means to bypass the counter electromotive voltage when the vibration means is turned off.

The driving circuit of the non-contact magnetic sensor and the control unit as described above is a type in which the voltage applying means 231 is connected to the hall sensor so that power is always supplied. When the puff is lifted from the case, the ON signal from the hall IC 232 is output. Is generated and input to the voltage amplifier 233, and the signal amplified by the voltage amplifier 233 activates the base end of the power transistor 234 to provide the Vcc voltage to the vibration means to vibrate the vibration means 240. The operation is made. When the puff is seated in the case, the off signal is output from the hall IC 232, and the Vcc voltage is stopped from being provided to the vibration means 240 without activating the base end of the power transistor 234. The operation is stopped. At this time, the counter electromotive voltage generated when the power supplied to the vibrating unit is turned off is bypassed while flowing through the diode 235.

12 is a vibrating means driving circuit of the non-contact magnetic sensor and the control unit, and shows a configuration in which the vibrating means is automatically operated according to the output of the hall sensor according to the magnetic body detection.

That is, the switching circuit is activated while the base terminal is activated in accordance with the Hall IC 232 including the circuit operating voltage applying unit 231, the Hall sensor 220b, and the sensor stabilizing elements R1 and C1. A power transistor 234 for turning on the vibration means 240 connected to the collector end, a bypass diode 235 connected in parallel to the vibration means to bypass the counter voltage when the vibration means is turned off, and the vibration motor. Capacitor 236 to block the AC noise generated from the circuit.

In the driving circuit of the control unit as described above, when the puff is lifted from the case, the ON signal is output from the Hall IC 232 so that the vibration means is operated while directly turning on the power transistor 234, and vice versa. When it is seated, the OFF signal is output from the hall IC 232, and the power transistor 234 is turned off, thereby stopping the operation of the vibration means.

13 to 16 illustrate vibration means, and FIG. 13 shows a plan view of the rotor mold part formed integrally with the rotor located inside the vibration motor, and FIG. 14 shows a cross-sectional view taken along line A-A 'of FIG. 15 is a cross-sectional view of a coin-type vibration motor including FIG. 15 and FIG. 16 are plan views illustrating a terminal form located below the vibration motor.

 As shown in FIG. 13 and FIG. 14. A shaft 245 is inserted and installed in the upper center of the bracket 249, and a donut-shaped magnet 248 spaced apart from the shaft 245 and wrapped around the outer circumference of the shaft is installed on an upper surface of the bracket 249. In the space between the magnets, a brush 251 having a bending portion contacts the upper commutator substrate 243.

  In addition, the commutator substrate 243 is provided on the rear surface of the rotor 242, the rotor 242 is located on the upper side of the magnet 248, is supported by a bearing is rotated about the shaft 245, The winding coil 247 is separately formed on the upper surface of the rotor 242 in which the commutator substrate 243 is located, and a weight body 253 is installed to apply an eccentric force therebetween.

  In addition, the lead wire 254 and the connector 255 are generally used to connect a power supply with the lower printed circuit board 250 formed on the upper surface of the bracket 249 of the coin type vibration motor. 3 is shown.

Finally, the upper portion of the bracket 249 is combined with the case 241 to form a space portion therebetween.

  Hereinafter, the operation of the vibration means will be described.

  When external power is applied to the vibration motor through the lead wire 254 and the connector 255 as shown in FIGS. 15 and 16, the rotor 242 eccentric through the brush 251 and the commutator substrate 243. A current flows through the winding coil 247 disposed therein, and the rotor 242 eccentrically formed by the weight body 253 is formed by the interaction between the magnet 248 and the field formed of the case 241. Vibration is caused by rotating around the axis 105 with 246 therebetween.

Hereinafter, the overall operation of the present invention will be described.

First, the present invention arranges the non-contact magnetic sensing sensor between the cosmetic puffs, and outputs an on switching signal or an off switching signal according to the proximity of the magnetic material installed in the seating case.

At this time, the control unit operates the vibration means in accordance with the output of the non-contact magnetic sensing sensor, when the magnetic material is close to output the signal from the non-contact magnetic sensing sensor, the vibration means does not operate by disconnecting the power between the vibration means and the power supply device. The control unit is controlled to control the power supply of the power supply device to the vibration means when the off signal is output from the non-contact magnetic sensing sensor.

That is, the present invention recognizes that when the non-contact magnetic sensor is close to the magnetic body, the cosmetic puff is stored in the seating case, and the vibration means of the cosmetic puff are stopped. When the non-contact magnetic sensor is separated from the magnetic body, the cosmetic puff It is determined that the use to take out from the seating case, thereby operating the vibration means to enable the user to use the cosmetic puff immediately generated vibration.

Therefore, when using the present invention, the vibration means immediately acts out when the cosmetic puff is removed from the seating case, so that the cosmetic puff can be used more conveniently, and the cosmetic puff is automatically vibrated when the cosmetic puff is stored in the seating case. Since the means are off, there is no need to perform a separate power off operation, which is very convenient to use.

100: puff structure
200: vibration actuator
210: power supply
220: non-contact magnetic sensor
230:
240: vibration means
300: seating case
310: magnetic material

Claims (7)

A puff structure 100;
A vibration actuator 200 inserted into the puff structure to generate vibration;
A mounting case (300) for mounting the puff structure and having a magnetic material for generating a switching signal of the vibrating actuator;
The vibration actuator 200,
A power supply unit 210 inserted into the puff structure 100 and supplying power to the apparatus;
A non-contact magnetic sensing sensor 220 for sensing the presence or absence of a magnetic substance inserted into the seating case and outputting an on switch signal and an off switch signal according to whether the magnetic substance is detected;
The puff structure is electrically connected to the non-contact magnetic sensing sensor, and when the on-switch signal is input, the puff structure is inserted into the seating case. When the off-switch signal is input, the puff structure is separated from the seating case. A controller 230 for determining that it is determined and outputting a control signal corresponding thereto;
Cosmetics that are vibrated by magnetic sensing, characterized in that it comprises a vibration means 240 for generating vibration while the power is supplied to the control unit according to the control signal itself. The method of claim 1,
The non-contact magnetic sensor 220 is,
Magnetic sensing, characterized in that it is any one selected from SQUID (Superconducting Quantum Interference Device), search coil magnetometer (magnet coil), magnetoresistive sensor, hall sensor, magnetic diode (magnetodiode), magnetic transistor (magnetotransistor), reed sensor Cosmetic vibrated by. The method of claim 1,
The vibration actuator 200,
Cosmetics vibrated by magnetic sensing, characterized in that it is stored in the sealing means for waterproofing. The method of claim 1,
The non-contact magnetic sensor 220 and the control unit 230,
A Hall IC 232 composed of a circuit operating voltage applying means 231, a Hall sensor 220b, and sensor stabilizing elements R1 and C1;
A voltage amplifier 233 for amplifying the voltage signal output from the hall IC 232;
A power transistor 234 which is switched while the base end is activated by the output of the voltage amplifier 233 and supplies power to the vibration means 240 connected to the collector end so as to generate vibration;
Cosmetics vibrated by magnetic sensing, characterized in that the bypass diode (235) is connected in parallel with the vibration means to bypass the counter voltage when the vibration means off. The method of claim 1,
The non-contact magnetic sensor 220 and the control unit 230,
A Hall IC 232 composed of a circuit operating voltage applying means 231, a Hall sensor 220b, and sensor stabilizing elements R1 and C1;
A power transistor 234 for switching while the base end is activated according to the output of the hall sensor and turning on the vibration means 240 connected to the collector end;
A bypass diode 235 connected to the vibration means in parallel to bypass the counter voltage when the vibration means is turned off;
Cosmetics vibrated by magnetic sensing, characterized in that the capacitor 236 to block the AC noise generated from the vibration motor. The method of claim 1,
The vibration means 240,
The shaft 245 is inserted into the upper center of the bracket 249,
A donut-shaped magnet 248 spaced apart from the shaft 245 on the upper surface of the bracket 249 and surrounding the outer circumference of the shaft is installed.
In the space between the magnets, the brush 251 having the bending portion is in contact with the upper commutator substrate 243,
The commutator substrate 243 is provided on the back of the rotor 242,
The rotor 242 is located above the magnet 248,
Supported by the bearing and rotated about the shaft 245,
Winding coils 247 are separately formed on the upper surface of the rotor 242 in which the commutator substrate 243 is located.
Cosmetics vibrated by magnetic sensing, characterized in that the weight body 253 is provided for acting the eccentric force between them. The method according to claim 6,
Cosmetics vibrated by magnetic sensing, characterized in that the lead wire 254 or connector 255 is further provided to connect the lower printed circuit board 250 formed on the upper surface of the bracket (249) and the power supply.

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