KR20230108377A - Quantitative powder supplying device - Google Patents

Abstract

The present invention, the hopper unit 10 for supplying powder; a housing part 20 having a cylindrical structure and having first and second openings 21 and 23 formed on one upper side and one lower side, respectively, and located below the hopper unit 10; A plurality of inflow and discharge holes 311 are formed on one side of the housing unit 20 facing the first and second openings 21 and 23, respectively, and a guide plate 313 inclined at a predetermined angle is provided on the other side of the housing unit 20. Rotation consisting of a rotary drum 310 located inside the unit 20, a rotary shaft 320 penetrating the central axis of the rotary drum 310, and a first driving motor 330 axially connected to the other end of the rotary shaft 320 drum unit 30; a support body portion 40 having a lower end portion in contact with the ground and located below the housing portion 20; One part is located below the second opening 23 of the housing part 20, and the other part consists of a screw 51 extending a certain length and a second driving motor 55 axially connected to one end of the screw 51. transfer unit 50; Provides a powder quantity supply device including; a quantity supply unit 60 located below the other side of the screw 51 and supplying a certain amount of powder supplied through the screw 51.

Description

Quantitative powder supplying device {Quantitative powder supplying device}

The present invention relates to a device for supplying a quantity of powder, and more specifically, without adding a separate facility, it is possible to fundamentally prevent a phenomenon in which the powder is solidified in the supply process of the powder, and the density of the powder is constant. It relates to a powder quantity supply device capable of variously controlling the amount of powder supplied at one time and the supply timing of powder in a state in which the powder is maintained.

In the case of performing lapping and polishing work or injection work using plastic raw materials, the abrasives or additives required for each individual work step must be precisely weighed and injected in the amount calculated in advance. If the amount is input, the product may be defective, and the polishing tool or mold itself may be damaged.

In addition, the abrasives and additives used in these operations are composed of fine powders that are very vulnerable to moisture in the air, so if there is a temporary delay in the supply process through the hopper or the supply line is temporarily stagnant, the powders may become lumpy due to the penetration of moisture. A solidification phenomenon occurs. In this case, there is a problem in that productivity is remarkably lowered in that the operation of the feeding device must be stopped, then the solidified powder mass must be recovered, and the inside of the hopper must be cleaned.

To this end, various technologies capable of supplying powder in a quantity without delay have been proposed, and Korean Patent Registration No. 1895361 is one of them. As shown in FIG. 5, this technology uses a rotating bucket 302 in which a receiving portion 302d of a certain size is formed therein and an inlet 302c and an outlet 302e are formed on one side and the other side, respectively. It is a method of supplying a certain amount of powder.

That is, when a certain amount of powder is put into the receiving part 302d through the inlet 302c while the rotating bucket 302 rotates at a certain angle, then the rotating bucket 302 further rotates at a certain angle to discharge the outlet 302e. The powder filled in the receiving portion 302d is discharged through the supply pipe 301c, and this process is repeatedly performed during the rotation of the rotating bucket 302.

However, in this method, not only the amount of powder that can be supplied at one time is too small, but also the supply cycle of the powder is too long, so the fields where it can be used are very limited. In addition, this method is a device in that powder can be stagnant for a long time inside the hopper installed on the upper side of the rotating bucket, and means for preventing solidification of the powder, such as a rotating screw or a rotating bar, must be provided inside the hopper. There was a problem that complicates the

Republic of Korea Patent No. 1895361 Republic of Korea Public Utility No. 1997-0060718 Japanese Public Room No. 60-32281

The present invention has been proposed to improve these problems of the prior art, and an object of the present invention is to provide a device capable of immediately supplying a large amount of powder as much as necessary while maintaining a non-solidified state for a long time.

In order to achieve this object, the present invention includes a hopper unit 10 for supplying powder; a housing part 20 having a cylindrical structure and having first and second openings 21 and 23 formed on one upper side and one lower side, respectively, and located below the hopper unit 10; A plurality of inflow and discharge holes 311 are formed on one side of the housing unit 20 facing the first and second openings 21 and 23, respectively, and a guide plate 313 inclined at a predetermined angle is provided on the other side of the housing unit 20. Rotation consisting of a rotary drum 310 located inside the unit 20, a rotary shaft 320 penetrating the central axis of the rotary drum 310, and a first driving motor 330 axially connected to the other end of the rotary shaft 320 drum unit 30; a support body portion 40 having a lower end portion in contact with the ground and located below the housing portion 20; One part is located below the second opening 23 of the housing part 20, and the other part consists of a screw 51 extending a certain length and a second driving motor 55 axially connected to one end of the screw 51. transfer unit 50; Its technical feature is that it includes; a quantitative supply unit 60 located below the other side of the screw 51 and supplying a certain amount of powder supplied through the screw 51.

A scraper 315 for recovering powder introduced into the space between the other inner surface of the housing 20 and the other outer surface of the rotary drum 310 may be provided on the outer surface of the other side of the rotary drum 310 .

The quantitative supply unit 60 includes a discharge hopper 61 located on the lower side of the other side of the screw 51; A hydraulic cylinder 65 positioned at a predetermined distance from the other side of the discharge hopper 61, and an opening/closing plate 67 that is axially connected to the rod of the hydraulic cylinder 65 and opens and closes the flow path of the discharge hopper 61; can

A level sensor unit 70 may be installed on one surface of the lower side of the housing unit 20 to detect the degree of stacking of the powder introduced into the rotating drum 310 .

In the present invention, the powder supplied through the hopper is stacked at a certain amount or more in the inner space of the rotary drum, and the rotary drum is rotated at a constant speed to continuously stir the stacked powder, so that no additional equipment is added. Even if the powder is not solidified, it is possible to fundamentally prevent the phenomenon of solidification, and of course, it allows the powder to be supplied while maintaining a constant density.

In addition, according to the present invention, it is possible to continuously supply powder to the working space through the linkage configuration between the rotating drum and the transfer unit, and the amount of powder supplied at one time by appropriately adjusting the operating cycle of the opening and closing plate. And it is possible to control the supply timing of the powder in various ways.

1 is a schematic overall configuration diagram of a quantitative supply device according to the present invention.
Figure 2 is a schematic internal configuration diagram of a metered supply device according to the present invention.
Figure 3a is a schematic perspective configuration diagram of the rotating drum in the quantitative supply device according to the present invention.
Figure 3a is a schematic cross-sectional configuration of the rotating drum in the quantitative supply device according to the present invention.
Figure 4 is a schematic configuration diagram of the quantitative supply unit in the quantitative supply device according to Figure 3a is the present invention.
Figure 5 is a schematic configuration diagram of a conventional powder quantity supply device.

Looking at the preferred embodiment according to the present invention in detail with reference to the accompanying drawings, as follows, in detailing the embodiment of the present invention, there is no direct relationship with the technical features of the present invention, or A detailed description will be omitted for matters that are obvious to those skilled in the art.

The present invention is a device capable of supplying powder in a fixed amount, and includes a hopper part 10, a housing part 20, a rotary drum part 30, a support part 40, a transfer part 50, and a fixed quantity supply part 60. There are features that include. Each of these configurations will be described in detail below.

The hopper part 10 is a part to which powder is supplied. Similar to a conventional hopper, it is preferable to be configured such that the cross-sectional area becomes narrower toward the lower side. At this time, there is no need to install any means for preventing solidification of the supplied powder such as a rotating screw or a rotating bar inside the hopper unit 10 .

The housing part 20 is located on the lower side of the hopper part 10, and preferably has a cylindrical structure as shown in the drawing, and first and second openings 21 and 23 are formed on one upper side and one lower side, respectively. The first opening 21 communicates with the lower end of the hopper unit 10, and the second opening 23 communicates with the transfer unit 50 to be described later.

The rotary drum unit 30 is a part that temporarily stores the powder supplied from the hopper unit 10 by a predetermined amount and then continuously supplies the powder by a predetermined amount to the transfer unit 50. It consists of a first driving motor (330).

As shown in FIG. 3A , the rotary drum 310 has a cylindrical structure with one surface opened and is located inside the housing part 20 . A plurality of inlet/outlet holes 311 are formed on one side of the rotary drum 310 facing the first and second openings 21 and 23 of the housing 20, respectively.

The inlet-discharge hole 311 is a part through which powder particles falling through the first opening 21 of the hopper part 10 and the housing part 20 are introduced, introduced into the inner space of the rotary drum 310 and stacked. A portion of the existing powder body is a portion discharged through the second opening 23 of the housing portion 20 .

At this time, each of the inflow and discharge holes 311 formed in the rotary drum 310 may be formed in a parallelogram shape as shown in FIG. 2 . This is to guide the powder falling through the first opening 21 to more easily flow into the inner space of the rotary drum 310 when the rotary drum 310 rotates at a constant speed.

Inside the other side of the rotating drum 310, a guide plate 313 inclined at a predetermined angle is provided. The guide plate 313 is preferably provided in an annular shape along the inside of the rotary drum 310 . The guide plate 313 is a means for guiding and stacking the powder introduced into the inner space of the rotary drum 310 to one side of the rotary drum 313 where the second opening 23 is located.

The rotating shaft 320 passes through the central axis of the rotating drum 310, and both ends thereof are exposed through one outer surface and the other outer surface of the housing 20, respectively. The first driving motor 330 is axially connected to the other end of the rotating shaft 320 . A speed reducer (not shown) may be interposed between the first driving motor 330 and the other end of the rotating shaft 320 .

As such, the present invention stacks the powder supplied from the hopper unit 10 in the inner space of the rotary drum 310 having a certain size, and rotates the rotary drum 310 at a constant speed so that the inner space of the rotary drum 310 By inducing continuous stirring of the powders stacked on the surface, it is possible to fundamentally prevent the solidification of the powders even when exposed to the air, and the density of the powders can be maintained at a constant state.

At this time, the present invention does not exclude the case where the scraper 315 is provided on the outer surface of the other side of the rotary drum 310, as shown in FIGS. 2 and 3B, respectively. When the powder is supplied through the first opening 21 of the housing part 20, some of the powder may flow into the space between the inner surface of the other side of the housing part 20 and the outer surface of the other side of the rotary drum 310.

This phenomenon occurs in the process of rotating along the outer surface of the rotating drum 310 without being directly introduced into the inlet-discharge hole 311 of the rotating drum 310 rotating at a constant speed. If this is maintained for a long time, the operation of the rotary drum 310 may not be easy.

Therefore, by providing the scraper 315 on the other outer surface of the rotary drum 310, the powder flowing into the space between the other inner surface of the housing part 20 and the other outer surface of the rotary drum 310 is removed from the housing part 20. To move in the direction of the second opening 23 of the. As shown in the drawing, the scraper 315 may be installed at a plurality of points while changing the position at each predetermined angle.

On the other hand, when the scraper 315 is installed so as to be inclined at a predetermined angle on the outer surface of the rotary drum 310 as shown in FIG. 310), it is possible to more easily move the powder bodies located in the space between the outer surfaces of the other side to one side of the rotating drum 313 where the second opening 23 is located.

The support body part 40 is a part that is located on the lower side of the housing part 20 to support the quantitative supply device according to the present invention, and its lower end is in contact with the ground. The support body 40 may be formed of a left and right side plate structure as shown in the drawing.

The conveying unit 50 is a part that transfers the powder supplied from the rotary drum unit 30 to the quantitative supply unit 60, and includes a screw 51 and a second driving motor 55. As shown in FIG. 2, one side of the screw 51 is located below the second opening 23 of the housing 20, and the other side extends a predetermined length. The second driving motor 55 is axially connected to one end of the screw 51. Reference numeral 53 denotes a speed reducer and may be interposed between the screw 51 and the second driving motor 55.

Quantitative supply unit 60 is a portion that supplies a certain amount of powder supplied through the screw 51 and is located below the other side of the screw 51. At this time, the quantitative supply unit 60 according to the present invention may include a discharge hopper 61, a hydraulic cylinder 65, and an opening and closing plate 67 as shown in FIGS. 2 and 4, respectively.

The discharge hopper 61 is located below the other side of the screw 51. Reference numeral 63 denotes a discharge pipe located below the discharge hopper 61. The hydraulic cylinder 65 is located on the other side of the discharge hopper 61 at a predetermined interval. The opening and closing plate 67 is axially connected to a rod (not shown) of the hydraulic cylinder 65 and opens and closes the discharge hopper 61 and the discharge pipe 63.

On the other hand, the present invention proposes a case in which the level sensor unit 70 is additionally installed in the quantitative supply device having such a configuration. The level sensor unit 70 is a means for detecting the degree of stacking of the powder body injected into the rotary drum 310, and may be installed on one surface of the lower side of the housing unit 20 as shown in FIGS. 1 and 2, respectively.

In the present invention, when powder is introduced into the inner space of the rotary drum 310 through the hopper unit 10, a certain amount of powder is stirred while being stacked in the inner space of the rotary drum 310, and the powder is continuously transferred to the transfer unit ( 50), and if the supply of powder through the hopper unit 10 does not continue, the supply of powder through the quantitative supply unit 60 may be stopped.

Therefore, if the level sensor unit 70 is installed as a means for detecting the amount of powder that is introduced into the inner space of the rotating drum 310 and is stacked, and through this, the supply of powder is controlled without stopping the work. Through the supply unit 60, it is possible to continuously supply as much powder as needed.

An example of the level sensor unit 70 composed of a rotor 73 and a sensor 71 is disclosed in the drawing. This example detects whether the rotor 73 rotates together with the powder, and if the rotation of the rotor 73 is not detected, it is determined that the inner space of the rotary drum 310 is stacked with powder that does not meet the standard. It is a composition that

That is, if the rotation of the rotor 73 is not sensed even though the rotary drum 310 rotates normally, the sensing body 71 detects that the amount of the powder body stacked inside the rotary drum 310 is lower than the standard, so that the rotor ( 73) is judged to be stopped, and the result is transmitted to the control unit to promptly supply the powder through the hopper unit 10. At this time, the operations of the conveying unit 50 and the quantitative supply unit 60 may be temporarily suspended.

A schematic operation configuration of the present invention composed of such a configuration will be reviewed with reference to the above description and accompanying FIG. 2 .

Powder is supplied through the hopper unit 10 in a situation where the first driving motor 330 is operated according to an operation of a control unit (not shown) (see ①). The powder falls through the lower end of the hopper part 10 and the first opening 21 of the housing part 20 to one outer surface of the rotating drum 310 rotating at a constant speed in one direction.

The powder falling to one side of the outer surface of the rotary drum 310 through the first opening 21 is sequentially introduced through the inlet-discharge hole 311 formed on one side of the rotary drum 310, and the rotary drum ( 310) is stacked in the inner space (see ②). When a certain amount of powder is deposited in the inner space of the rotary drum 310 (which can be detected through the level sensor unit 70), the second driving motor 55 is operated.

Among the powders falling to one outer surface of the rotary drum 310, the powders introduced into the space between the other inner surface of the housing 20 and the other outer surface of the rotary drum 310 are the other outer surface of the rotary drum 310. As described above, the rotating drum 310 is naturally moved in the direction of the second opening 23 of the housing part 20 while the rotary drum 310 rotates by the scraper 315 provided thereon.

While the second drive motor 55 is operating, some of the powders stacked in the inner space of the rotary drum 310 are discharged through the inlet-discharge hole 311 and the second opening 23 of the housing part 20 When falling to one side of the screw 51 rotating in one direction through (see ③), the fallen powder is supplied to the quantitative supply unit 60 while moving in the other direction along the outer surface of the screw 31 (④) reference).

At this time, the opening and closing plate 67 is in a closed state between the discharge hopper 61 and the discharge pipe 63, and the powder supplied by the screw 51 is in the inner space of the opening and closing plate 67 and the discharge hopper 61. are layered When a certain amount of powder is stacked between the opening/closing plate 67 and the inner space of the discharge hopper 61, the hydraulic cylinder 65 operates according to a signal from the control unit, and the opening/closing plate 67 retracts, moving the discharge hopper 61 and the discharge pipe. (63) is opened, and the powder is supplied while being discharged to the work space through the discharge pipe (63) (see ⑤).

As described above, the present invention can fundamentally prevent the phenomenon of solidification of the powder by laminating the powder in the inner space of the rotary drum and rotating the rotary drum at a constant speed, and continuously supplying the powder through the rotary drum and the transfer unit. It is possible, and it is possible to change the amount of powder supplied at one time and the supply timing of powder in various ways by adjusting the operation cycle of the opening and closing plate.

In the above, the description has been limited to the preferred embodiments of the present invention, but this is only an example, and the present invention is not limited thereto and can be modified and implemented in various ways, and furthermore, separate technical features are provided based on the disclosed technical idea. It will be obvious that it can be added and implemented.

10: hopper part 20: housing part
30: rotary drum part 40: support body part
50: transfer unit 60: fixed amount supply unit
70: level sensor unit

Claims (4)

A hopper unit 10 for supplying powder;
a housing part 20 having a cylindrical structure and having first and second openings 21 and 23 formed on one upper side and one lower side, respectively, and located below the hopper unit 10;
A plurality of inflow and discharge holes 311 are formed on one side of the housing unit 20 facing the first and second openings 21 and 23, respectively, and a guide plate 313 inclined at a predetermined angle is provided on the other side of the housing unit 20. Rotation consisting of a rotary drum 310 located inside the unit 20, a rotary shaft 320 penetrating the central axis of the rotary drum 310, and a first driving motor 330 axially connected to the other end of the rotary shaft 320 drum unit 30;
a support body portion 40 having a lower end portion in contact with the ground and positioned below the housing portion 20;
One part is located below the second opening 23 of the housing part 20, and the other part consists of a screw 51 extending a certain length and a second driving motor 55 axially connected to one end of the screw 51. transfer unit 50;
A fixed quantity supply unit 60 located on the lower side of the other side of the screw 51 and supplying a certain amount of powder supplied through the screw 51;
Powder quantity supply device comprising a. According to claim 1,
A scraper 315 is provided on the other outer surface of the rotary drum 310 to recover powder flowing into the space between the other inner surface of the housing part 20 and the other outer surface of the rotary drum 310. Powder quantity supply device. According to claim 1,
The quantitative supply unit 60 includes a discharge hopper 61 located on the lower side of the other side of the screw 51; A hydraulic cylinder 65 positioned at a predetermined distance from the other side of the discharge hopper 61, and an opening/closing plate 67 that is axially connected to the rod of the hydraulic cylinder 65 and opens and closes the flow path of the discharge hopper 61; Powdery quantity supply device, characterized in that. According to claim 1,
A level sensor unit 70 for detecting the stacking level of the powder introduced into the rotating drum 310 is installed on one surface of the lower side of the housing unit 20.

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