KR200479841Y1 - A Powder Transfer Hopper Having Vibration Measure - Google Patents

Abstract

The present invention relates to a hopper device for conveying a powder having a vibration means, in particular, a pressure sensor and a vibration means are provided outside a hopper device for conveying a powder, Wherein the hopper device is provided with a vibrating means for conveying the powder,
A hopper 10 for storing a powder; A first pressure sensor (20) installed at an inner upper end of the hopper; A second pressure sensor (30) installed at an inner lower end of the hopper; A vibration means (40, 40a, 40b) provided outside the hopper; And a control unit (50) for controlling the size of powder particles based on the data values of the first pressure sensor and the second pressure sensor so as to drive the vibration means at a frequency corresponding to the particle characteristics of the powder.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a powder transfer hopper device having vibration means,

The present invention relates to a hopper device for conveying a powder having a vibration means, in particular, a pressure sensor and a vibration means are provided on the outside of a hopper device for conveying a powder, and vibration is appropriately applied to the hopper device according to a pressure situation inside the hopper So that the powder can be transported smoothly. BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to a hopper for powder transfer.

Generally, the powder used by women as a cosmetic powder is made of a powder having a fine powder form and stored in a flat container.

The powder is contained in a storage hopper mainly composed of an upper light guide and discharged through a discharge port at a lower portion thereof. The powder is introduced into a receiving groove of a moving plate slidingly moved from a lower portion of a storage hopper, ), And then discharged to the guide hopper, and the powder discharged through the guide hopper is conveyed to the color tone mixer or the powder storage container.

However, the conventional guide hopper described above causes considerable problems.

That is, when the powder contained in the storage hopper is discharged to the guide hopper through the receiving groove of the moving plate, the powder is discharged very slowly due to the natural descent of the powder, so that the powder supply operation can not be performed smoothly. Particularly, A part of the powder was adhered to the inner wall of the guide hopper to delay the discharge speed of the whole powder, while the powder attached once did not easily fall off.

Therefore, a part of the powder is only partially discharged in the state of remaining on the inner wall of the guide hopper, and the amount of the powder supplied to the storage container which is conveyed to the next process can not be kept constant.

In addition, powder of fine powder is stored in a guide groove of a moving plate and drops in a loose state when the powder is dropped. As the powder agglomerates are introduced into a flat storage container, the powder is separated from the storage container In particular, when the powder discharged from the guide hopper is not directly introduced into the storage container but is introduced into the color mixer, there arises a problem that the color distribution is not uniformly formed.

To solve this problem, a guide hopper of a powder supply device for cosmetics has been proposed in a public utility model (Publication No. 1998-033093). When the powder contained in the storage hopper 10 is discharged through the receiving groove 21 of the moving plate 20 and flows into the inlet pipe 30a of the guide hopper 30, The lumps of the powder are crushed and filtered by the netting member 31 to be formed into a fine powder state and discharged to the lower guide pipe 30b. At the same time, the guide hopper 30 receives the vibration of the vibrator 32 and is quickly vibrated, thereby dropping the powders adhering to the inlet pipe 30a and the inner surface of the guide pipe 30b, thereby rapidly discharging the powder As a result, the efficiency of the supply operation can be maximized.

However, since the conventional structure uses only the vibrator oscillation, it does not grasp the amount of the contents contained in the actual hopper. Therefore, the conventional structure provides excessive vibration and causes noise.

That is, in order to provide appropriate vibration in accordance with the amount of the contents to be contained in the hopper, in the prior art, it is difficult to provide vibration corresponding to the amount of cosmetic material contained in the hopper, .

In order to solve the above problems, the present invention proposes an ultrasonic vibration means provided outside the hopper for conveying the powder, and continuously transmits the vibration in a predetermined time unit. The weight of the contents to be contained in the hopper is detected by a pressure sensor The purpose of the hopper is to provide vibration in a level appropriate to the amount of cosmetic material contained therein.

As means for achieving the above object,

The present invention relates to a powder storage hopper (10); A first pressure sensor (20) installed at an inner upper end of the hopper; A second pressure sensor (30) installed at an inner lower end of the hopper; A vibration means (40, 40a, 40b) provided outside the hopper; And a control unit (50) for controlling the size of powder particles based on the data values of the first pressure sensor and the second pressure sensor so as to drive the vibration means at a frequency corresponding to the particle characteristics of the powder.

In addition, the control unit may include a program code for grasping the fine particles of cosmetic material when the difference value between the first pressure sensor 20 and the second pressure sensor 30 is large, When the difference between the sensor 20 and the second pressure sensor 30 is small, it is characterized by having a program code for grasping the cosmetic material of coarse particles and lowering the frequency to provide a low vibration.

The vibrating means 40a includes a lower substrate 421, a brush 425 for receiving external power, a stator 420 made of a magnet for supplying a magnetic field, And a brushless brushless brushless brushless brushless brushless brushless brushless brushless brushless brushless brushless brushless brushless brushless brushless motor. A rotor 410; And a housing 430 housing the rotor 410 and the stator 420 therein.

In addition, the vibration means 40b includes a case 481 having an internal space of a predetermined size; A magnet 482 mounted on the lower surface of the lower plate 483 and magnetized vertically; A yoke 484 to which the magnet 483 is mounted so as to form a magnetic circuit together with the lower plate 483 and the magnet 482; A spring member 486 mounted between the casing 481 and the yoke 484 to vibrate the vibrating body including the weight 485 mounted on the yoke 484; And a vibration generating coil 487 provided on the upper surface of the bracket 488 for sealing the lower portion of the casing 481.

As described above, in the present invention, the ultrasonic vibration means is additionally provided outside the hopper for conveying the powder, and the vibration is continuously transmitted in a predetermined time unit. The weight of the contents to be contained in the hopper is detected by the pressure sensor, It is possible to provide the hopper with the most suitable vibration for falling of the cosmetic material and to perform the powder storing operation without interruption since the vibration is provided at an intensity appropriate to the amount of the material.

1 is a hopper perspective view of the present invention;
2 is a hopper sectional view of the present invention;
3 is a hopper operation diagram of the present invention;
4 is a first embodiment of the vibrating means of the present invention.
5 is a second embodiment of the vibration means of the present invention.
6 is a circuit block diagram of the present invention.

The operation principle of the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings and description. It should be understood, however, that the drawings and the following description are provided for illustrative purposes only and are not intended to limit the scope of the present invention.

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 the following terms are defined in consideration of functions in the present invention, and may vary depending on the user, the intention or custom of the operator, and the like. Therefore, the definition should be based on the contents of this whole design.

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 and are incorporated in and constitute a part of this specification. The configuration is omitted as much as possible and the functional configuration that should be additionally provided for the present invention is mainly described.

Those skilled in the art will readily understand the functions of components that have been used in the prior art among the functional configurations not shown in the following description, The relationship between the elements and the added components for the present invention will also be clearly understood.

In order to efficiently explain the essential technical features of the present invention, the following embodiments will appropriately modify the terms so that those skilled in the art can clearly understand the present invention. However, It is by no means limited.

As a result, the technical idea of the present invention is determined by the claims, and the following examples are intended to illustrate the technical idea of the present inventive concept in a more effective manner to those skilled in the art, .

1 is a hopper perspective view of the present invention;

2 is a hopper sectional view of the present invention;

3 is a hopper operation diagram of the present invention;

4 is a first embodiment of the vibrating means of the present invention.

5 is a second embodiment of the vibration means of the present invention.

Fig. 6 is a circuit block diagram of the present invention,

A first pressure sensor 20 installed at one end of the inner upper end of the hopper; a second pressure sensor 30 installed at one end of an inner lower end of the hopper; And a second pressure sensor for detecting the particle size of the powder based on the data values of the first pressure sensor and the second pressure sensor so as to drive the vibration means at a frequency corresponding to the particle characteristics of the powder. And a control unit 50 for controlling the apparatus.

The first pressure sensor 20 can be positioned at the upper end of the hopper to determine whether the cosmetic material exists up to the upper end of the hopper.

The second pressure sensor 30 is located at the lower end of the hopper to check the pressure generated due to the cosmetic material present in the hopper.

The reason why the first pressure sensor 20 and the second pressure sensor 30 are provided in the present invention is that the pressure value may differ due to particles of the cosmetic material.

The characteristics of the cosmetic material can be grasped by the difference between the first pressure sensor 20 and the second pressure sensor 30 so that the difference between the first pressure sensor 20 and the second pressure sensor 30 If the value is large, it can be grasped as a cosmetic material of fine particles. The finer the cosmetic material, the greater the influence on the pressure sensor, and the larger the pressure value obtained by the first pressure sensor 20 and the second pressure sensor 30 , So that the difference between the first pressure sensor 20 and the second pressure sensor 30 becomes larger.

As described above, if the difference between the first pressure sensor 20 and the second pressure sensor 30 is large, there is a high possibility that the fine particles are cosmetics, and furthermore, the cosmetic material of fine particles may have strong aggregation characteristics. The oscillation pressure of the oscillator is increased to transmit a stronger vibration so that the cosmetic material present in the hopper 10 can be lowered smoothly.

On the contrary, if the difference between the first pressure sensor 20 and the second pressure sensor 30 is small, the control unit 50 grasps the relatively large particles of cosmetic material, So that the large-sized cosmetic material is smoothly lowered.

That is, in the present invention, a large-sized cosmetic material applies a relatively small vibration pressure to sufficiently lower the cosmetic material present in the hopper 10 even with a small vibration, while a small-sized cosmetic material exerts a relatively large direct- The particles are not bundled together by a large vibration, and the cosmetic material is guided to descend smoothly.

A capacitive pressure sensor applied to the present invention forms a parallel plate capacitor between a silicon thin film diaphragm and a support so that the silicon thin film diaphragm The capacitance value due to the change of the gap between the two electrodes due to the deflection (deformation of the membrane) is used.

Such a capacitive pressure sensor is divided into an absolute pressure type and a relative pressure type. The absolute pressure type is manufactured in a condition that the diaphragm is kept in a hermetically sealed condition. Based on a constant pressure in the reference pressure chamber, It is a pressure sensor that can measure the pressure. It is completely blocked from the outside and is not influenced by surrounding substances. However, the air inside the reference pressure chamber is compressed and nonlinearity occurs. As the temperature increases, And the relative pressure is a pressure sensor that can measure the relative pressure of the two parts, that is, the pressure difference between the upper and lower diaphragms, because the reference pressure chamber is opened by making a hole in the glass part. . However, since the inside of the standard pressure chamber is not in an airtight state, air compression And there is no effect on swelling.

Capacitive type pressure sensors that detect the capacitance between two electrodes using diaphragm bending (deformation of the membrane) have a sensitivity value of several tens to several hundred times (higher sensitivity) than the pressure resistance type pressure sensor In addition, it has the advantages of excellent stability (lower temperature coefficient, stronger structure) and lower power consumption (lower power consumption).

The vibration means 40 applied to the present invention is configured to output a vibration having an appropriate intensity in accordance with a control signal of the control unit and can be applied to the left and right vibration type and vertical vibration type. As shown in the figure, a flat or coin type vibration motor 40a is mounted on a stator (not shown) of a stator (not shown) A rotor 410 rotatably provided around the shaft 431 with respect to the rotor 420 and a housing 430 housing the rotors 410 and the stator 420 therein.

When power is supplied from the outside through the brush 425 mounted on the lower substrate 421 of the stator 420, currents of different polarities are induced in the pair of brushes 425, The upper end of the rotor 410 is elastically contacted with the commutator 415 provided on the lower surface of the upper base 411 of the rotor 410. The upper end of the rotator 410 is connected to the brush 425 through the commutator 415, And supplies the power to the winding coils 412 provided in the coil.

Due to the interaction between the electric field generated by the current flowing in the winding coils 412 and 413 and the magnetic field generated by the magnet 422 of the stator 420, 431 as a center.

At this time, since the contact point between the brush 425 and the segment of the commutator 415 contacting with the brush 425 is changed every time the rotor 410 rotates, the polarity of power supply is continuously changed, Thereby causing vibration as an incoming signal.

In FIG. 3, reference numeral 414 denotes an insulator surrounding the winding coil and the weight, reference numeral 432 denotes a bearing member, and reference numeral 435 denotes a bracket for sealing the opened lower portion of the housing 430.

When the external power is supplied to the vibration motor 401, the rotor 410 having the weight arranged eccentrically is rotated to obtain mechanical vibration. The rotational force of the rotor 410 is mostly transmitted to the brush 425 And a commutator 415, and supplies current to the coil of the rotor 410 through a rectifying function through a contact between the commutator and the commutator 415.

4 is a cross-sectional view of a vertical oscillator that is simple in structure and generates vertical vibration in the vertical direction. As shown in the figure, the vertical oscillator 40b is a vertical oscillator, A case 481 having an inner space of a predetermined size and a lower plate 483 mounted on the lower surface and having a vertically magnetized magnet 482, a lower plate 483, a magnet 482, Between the casing 481 and the yoke 484 so as to vibrate the vibrating body including the yoke 484 on which the magnet 483 is mounted and the weight 485 mounted on the yoke 484 And a vibration generating coil 487 provided on the upper surface of the bracket 488 for sealing the lower portion of the casing 481. [

The operation of the vertical oscillator 40b having such a configuration is the same as the operation of the magnetic circuit formed of the magnet 482, the lower plate 483 and the yoke 484 when the vibration generating coil 487 is supplied with power The vibrating body including the magnet 482, the lower plate 483, the yoke 484 and the weight 485 is pressed against the spring member 486 by the interaction between the magnetic field and the electric field generated in the vibration generating coil 487, So that it vibrates in the vertical direction.

10: Hopper
20: first pressure sensor
30: Second pressure sensor
40: vibration means
50:

Claims (4)

A hopper 10 for storing a powder;
A first pressure sensor (20) installed at an inner upper end of the hopper;
A second pressure sensor (30) installed at an inner lower end of the hopper;
A vibration means (40, 40a, 40b) provided outside the hopper;
And a control unit (50) for controlling the size of the particles of the powder based on the data values of the first pressure sensor and the second pressure sensor and driving the vibration means at a frequency corresponding to the particle characteristics of the powder. Hopper device for powder transfer with vibrating means. The method according to claim 1,
Wherein,
A program code for grasping the fine particles of cosmetic material and increasing the frequency thereof so as to cause rapid vibration when the difference value between the first pressure sensor 20 and the second pressure sensor 30 is large; And a program code for grasping the coarse-grained cosmetic material when the difference value of the two-pressure sensor (30) is small and lowering the frequency to provide a low vibration. The method according to claim 1,
The vibrating means (40a)
A lower substrate 421, a brush 425 for receiving external power, a stator 420 made of a magnet for supplying a magnetic field,
And a brushless brushless brushless brushless brushless brushless brushless brushless brushless brushless brushless brushless brushless brushless brushless brushless motor. A rotor 410;
And a housing (430) for internally housing the rotor (410) and the stator (420). The method according to claim 1,
The vibrating means (40b)
A case 481 having an internal space of a predetermined size;
A magnet 482 mounted on the lower surface of the lower plate 483 and magnetized vertically;
A yoke 484 to which the magnet 483 is mounted so as to form a magnetic circuit together with the lower plate 483 and the magnet 482;
A spring member 486 mounted between the case 481 and the yoke 484 to vibrate the vibrating body including the weight 485 mounted on the yoke 484;
And a vibration generating coil (487) provided on an upper surface of a bracket (488) for sealing a lower portion of the case (481).

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