KR102553729B1 - Accurate transferring screw powder pump and the method thereof - Google Patents

Abstract

The present invention is a screw pump connector for powder having a powder supply port and a powder outlet and having a cylindrical powder transport path built in a screw in a straight line with the powder outlet, the inside of which is made up of a space of a predetermined size, wherein the cylindrical powder transport The upper side of the furnace is cut lengthwise in the longitudinal direction so that a portion of the screw is exposed to the upper side, and a screw pump connector for powder with improved conveying accuracy, in which a bead for rotation is installed on the upper part of the exposed screw.

Description

Screw pump and method for powder with improved transfer precision {Accurate transferring screw powder pump and the method thereof}

The technology of the present invention is a cylindrical powder transfer path in a screw pump connector for powder having a cylindrical powder transfer path having a built-in screw in a straight line with the powder discharge port and having a powder supply port and a powder discharge port although the interior is made of a space of a predetermined size. The upper side of is a long incision in the longitudinal direction so that a part of the screw is exposed to the upper side, and a screw pump connector for powder with improved conveying precision by installing a bead for rotation on the top of the exposed screw and a technology related to a pump using the same.

It is known that precise powder transfer is a very difficult problem because the exact amount of powder transferred using the screw pump for powder is not controlled at the discharge port. This is due to the problem of the pump itself, but it is more likely due to the physical properties of the powder. In addition to the technology using wind power in which external pressure is not applied to the powder supplied from the hopper, even when it is transported while falling by gravity, it is unit The amount of powder per area is not constant, and the amount of powder transferred varies greatly depending on causes such as size, weight, and surface condition of the powder.

In addition, even in the process of transporting the powder supplied from the hopper to the discharge pipe, frictional force between the powders acts on each other, so the powder supplied to the rotary screw is evenly distributed over the entire area of the screw and cannot be transported, so that the specific location is completely empty. Since cavities often occur, the amount of powder coming out of the discharge port is not always constant.

As a powder quantity supply device to improve this, Korean Patent Registration No. 10-0629126 discloses a means for defining a drug storage room (5a) capable of storing powdered drugs for multiple administration operations, and a lower part of the bottom of the drug storage room (5a) It is possible to move between the filling position and the administration position while maintaining contact between the medicine accommodating chamber (5b), which can accommodate the powdered medicine for single dose operation, installed in the medicine storage chamber (5a), and the bottom surface of the medicine storage chamber (5a), In the filling position, the opening means 2f opens the medicine storage chamber 5b to the medicine storage chamber 5a, and in the administration position, the medicine accommodation chamber 5b is closed to the medicine storage chamber 5a. At the same time, through the tubes 2g and 2d, the drug delivery unit 2 continuously passes the drug receiving chamber 5b to the outside of the device, and moving the drug delivery unit 2 between the filling position and the administration position a means (13) for operating the device from the outside, and a pump unit (3) capable of sending air to the drug accommodation chamber (5b) through a filter (6) installed at the bottom of the drug accommodation chamber (5b), The lead-out part 2 allows the powdered medicine in the medicine storage chamber 5a to be filled in the medicine accommodation chamber 5b through the opening means when in the filling position, and when moving from the filling position to the administration position, this medicine The powdered medicine in the storage chamber 5b is rubbed and weighed into a single dose operation, and by operating the pump part 3 at the administration position, the powdered medicine in the medicine accommodation chamber 5b is mixed with air into the tube 2g, 2d, 2c) to be sprayed to the outside of the device, and the drug storage chamber (5a) and the drug accommodation chamber (5b) are integrally molded with resin to define the device body (1). However, it is difficult to use widely in the industry because the technology is complicated and manufacturing and maintenance are difficult.

In addition, the new technology disclosed in Korean Patent Registration No. 10-2284834 is a cylindrical pesticide injector body with an open upper surface and an empty inside to distribute powdered pesticides in measured amounts, a main body disposed in the center of the main body, and a drive motor inside. A central pillar including a rotation shaft, a plurality of coupling bars coupled to the lower inner surface of the main body and the lower outer surface of the central pillar to structurally couple the main body and the central pillar and spaced apart from each other and disposed radially, of the central pillar A rotary plate that is placed on the lower surface to close the lower part of the main body and rotates in close contact with the lower part of the main body according to the operation of the driving motor. A divider including a plurality of dividing bars extending vertically and radially disposed with respect to the central opening of the upper plate, at least one vibrator disposed adjacent to the outer surface of the body and applying vibration to the body, and the rotating plate having an opening at a portion thereof Is formed, further comprising an opening and closing plate for opening or closing the opening, the divider is inserted into the main body so that the side surface of the dividing bar is in contact with the inner surface of the main body and the outer surface of the central pillar, and the lower surface of the dividing bar is the plurality of It is a powder pesticide metering dispenser characterized by dividing the space in the body into a plurality of unit spaces in contact with the upper surface of the coupling bar or rotating plate, but the main feature of using the dividing bar is that the technology is complicated and the production cost is expected to be high. There was a rather difficult problem to use as a pump technology.

Another Korean Patent Registration No. 10-1524080 is also a system for quantitative supply of powder, comprising: a powder collecting device that collects and discharges powder by quantity from the supply unit; a measuring unit measuring the weight of the powder discharged from the powder collecting device; And a first control unit for verifying whether the weight of the powder measured by the measuring unit is quantitative, wherein the powder collecting device has a first air intake line for sucking in air and an air discharge line for discharging air, and the A second control unit having an insertion groove formed on an outer circumferential surface to be connected to each of the first air intake line and the air discharge line; It is inserted into the insertion grooves of the second control unit and is movably coupled in the insertion direction, the inside is hollow, the upper side is open, and a communication hole is formed on the side surface to be connected to the first air intake line and the air discharge line, respectively. connector; an elastic means interposed below the connector; a rotation unit inserted into and rotatably coupled to the outside of the second control unit, closely coupled to the outer surface of the connector to the inner circumferential surface, and having a plurality of air intake/discharge holes formed along the circumferential direction on the outer circumferential surface; a powder suction plate coupled to an outer circumferential surface of the rotation unit, located on the same line as the air intake/discharge hole, and having a plurality of powder intake holes communicating with the air intake/discharge hole; and a porous filter interposed between the air intake and discharge hole and the powder intake and made of a porous material having a particle diameter smaller than the size of the powder to pass air sucked and discharged through the air intake and discharge hole, wherein the supply unit We disclose a powder quantity supply system that sucks in air so that powder is collected from the air and discharges air so that the collected powder is discharged to the measurement unit. It is expected that the production cost will be high to be widely used for general purposes.

As described above, there has been a lot of demand from the industry to control and transfer powders of various sizes and physical properties handled in industrial settings, but there is little known technology that can satisfy them.

- Korea Patent Registration No. 10-2284834 (Announced on July 30, 2021) - Korea Patent Registration No. 10-1524080 (Announced on June 1, 2015)

The present invention is to propose a screw pump technology that can accurately secure the powder transfer amount.

The present invention is intended to propose a method capable of effective powder transfer simply by adding a connector to a screw pump discharge pipe for powder currently in use.

In addition, the present invention is to suggest a new method for effectively reducing the void between the transported powder.

In addition, the present invention is to suggest a transfer method for controlling a constant amount of powder per hour to be discharged through a discharge pipe.

In addition, the present invention is to provide a powder transfer technology capable of effective transfer regardless of the amount of the transferred powder.

In addition, the present invention is to provide a new transfer technology that accurately supplies the same powder amount at a constant speed regardless of the screw rotation amount (RPM) of the pump.

In order to solve this problem, the present invention consists of a space of a predetermined size, but has a powder supply port and a powder outlet, and has a cylindrical powder transfer path in which a screw is embedded in a straight line with the powder outlet. In the connector for a screw pump, The upper side of the cylindrical powder transport path is cut lengthwise in the longitudinal direction so that a portion of the screw is exposed upward, and a rotating bead is installed on the exposed screw top, the size of the bead being 60% to 90% of the diameter of the built-in screw Characterized in that, it is possible to provide a screw pump connector for powder with improved conveying precision.
In addition to this, the present invention further provides a screw pump connector for powder with improved conveying precision, characterized in that a limiting panel for limiting the movement of beads to the left and right upper portions of the powder transfer path is provided, and the limiting panel is both side panels constituting the connector. can provide
In addition, the connector of the present invention may be provided with a pressure adjusting hole to remove the internal pressure.
In addition, the present invention can provide a screw pump for powder with improved conveying precision, in which a screw-embedded discharge pipe is fastened to the powder discharge port of the screw pump connector for powder with improved conveying precision, and the powder supply port of the connector is coupled to the hopper. there is.
In addition, in the present invention, the screw-embedded discharge pipe fastened to the powder discharge port is made by combining two or more screws and the discharge pipe, and can be mutually fastened by providing an intermediate coupling portion, and the intermediate coupling portion has a pressure regulating hole and a screw-embedded powder conveying path. It consists of an intermediate connector provided, but is characterized in that a bead for rotation is installed on the upper part of the intermediate connector-embedded screw, or the diameter of the connector-embedded screw is at least 1.2 times that of the screw diameter of the screw-embedded discharge pipe fastened to the powder outlet. It is possible to provide a screw pump for powder with improved conveying precision, characterized in that it is up to 8 times larger.

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The present invention proposes a screw pump technology for powder that accurately secures the amount of powder conveyed.

In addition, the present invention suggests an effective powder transfer method that can be applied immediately by simply adding a connector to a screw pump discharge pipe for powder currently in use.

In addition, the present invention suggests a precise powder transfer method that effectively reduces powder voids, and an effective transfer method that controls a constant amount of powder to be discharged per hour.

In addition, the present invention provides a powder transfer technology capable of effective transfer regardless of the amount of powder, and provides a new transfer technology that accurately supplies the same amount of powder at a constant speed regardless of the screw rotation amount (RPM) of the pump.

1 shows the basic components of the present invention, a connector having a predetermined inner space, a discharge pipe fastened to the powder discharge port of the connector, and a large diameter screw and a medium diameter screw embedded in the connector and the discharge pipe, respectively (diameter ratio) ratio of up to 8:1).
Figure 2 is an embodiment in which a hopper is detachably fastened to the top of the connector to function as a powder supply port, a power supply port for supplying power to one side of the connector is provided, and a screw is built-in to the other side of the connector and a powder outlet is provided. is shown.
3 shows a state in which the connector of the present invention, the two-stage screw, and the discharge pipe are all coupled.
FIG. 4 is a view in which beads 600 are installed on top of the connector built-in screw in addition to FIG. 3, and FIG. 5 is a perspective view seen from the top.
6 is a scraper of the present invention in which beads move in conjunction from the top of the screw to the inlet of the powder outlet, prevent cavities that may occur on the screw surface, and rotate while stopping at the inlet of the powder outlet to scrape the powder supplied more than necessary. It will be described providing a pressurizing function that removes voids between the powder and the powder.
7 shows a case in which the discharge tube of the present invention extends into two stages and more precisely controls the powder transfer, and shows the use of an intermediate connector as an intermediate coupling between the first and second discharge tubes. . When using a two-stage discharge pipe, the screw rotates and transfers the powder while being embedded in the connector, the first discharge pipe, and the second discharge pipe in a state where large, medium, and small diameter screws are sequentially fastened to each other, and the connector and each connector It functions to stabilize the powder being transported using beads.

The present invention will be described in detail.

In the present invention, the "hopper" 100 is for supplying powder, and is generally fastened to the connector 200 with a built-in screw at the top of the screw pump, and refers to a device that supplies powder by its own weight using an agitator as needed. .

In addition, the “screw” 400 is a spiral tool in which the thread and the thread formed on the outer circumferential surface of the rotating shaft are continuous for a predetermined length, and refers to a device that linearly moves the powder dropped on the surface at a certain distance during rotation. In the present invention, the screw may be classified into a large-diameter screw, a medium-diameter screw, and a small-diameter screw.

In addition, the “bead” (ball, 600) refers to an object whose outer circumference is all curved and rotates freely when force is applied from the outside, and in the present invention, steel beads and glass beads can be exemplified.

In addition, the “discharge tube” 300 refers to a discharge port or a cylindrical body for transporting the powder transferred from the discharge tube 300 in the previous step. In the present invention, the inner circumference of the discharge tube 300 of different diameters It can be exemplified so that the feeding screws are each embedded. The present invention may basically consist of a connector 200 having a predetermined internal space, having a power supply port 230 to which power is supplied to one side of the connector, and using powder using a screw.

That is, the connector 200 of the present invention is a cylindrical powder transfer path having a powder supply port 230 and a powder outlet 220 inside and having a built-in screw in a straight line with the powder outlet 220. As a screw pump connector 200 for powder, the upper side of the cylindrical powder transfer path is cut lengthwise in the longitudinal direction so that a portion of the screw is exposed upward, and a bead 600 for rotation is installed on the top of the exposed screw. To provide a screw pump connector 200 for powder with improved conveying precision.

The material of the connector 200 is a general material and is not limited to materials such as iron, plastic, and wood.

In addition, in the present invention, the screw is a spiral and is not limited to materials such as iron, plastic, and wood, but an elastic plastic material is preferable to achieve the object of the present invention.

In addition, in the present invention, the screw 400 can be classified into a large-diameter screw 410, a medium-diameter screw 420, and a small-diameter screw 430 according to the size of the diameter.

In addition, the surface of the spiral screw of the present invention is preferably made of Teflon resin, and most preferably made of PFA resin among Teflon resins.

PFA resin not only has excellent standard roughness compared to PTFE, commonly known as Teflon, but also has smaller frictional force, so powder does not adhere to the surface easily, and it is much lighter than metal, so it is possible to provide a lightweight pump through miniaturization of the motor, Due to its water-repellent effect, it is easy to clean and is much more advantageous than other materials in terms of maintenance. In addition, since the PFA resin holds the impact of the input beads 600 much more effectively than other materials, a good effect on the life of the device is expected.

The present invention improves the internal structure of the connector 200 that pushes the powder transferred to the powder discharge port 220 in the powder transfer screw pump, and installs the bead 600 on the top of the screw to keep the amount of discharged powder constant. can be achieved

That is, in the powder screw pumps that have been used so far, the powder supplied from the upper hopper 100 is not accurately filled on the surface of the rotating screw, and even some sections are transported in an empty state. had gaps between powders, making it difficult to control for precise transfer.

Accordingly, in the first step of the present invention, a screw-embedded cylindrical powder transfer path is provided in a straight line with the powder discharge port 220 in the connector 200 having a predetermined internal space, and the cylindrical powder transfer path is cut lengthwise in the longitudinal direction. When a part of the screw is prepared so that the upper side is exposed, the bead 600 is installed on the top of the exposed screw inside the connector 200 in the second step, and the screw is rotated in the third step, the bead 600 moves in the powder transport direction The bead 600 reaches the powder discharge port 220 according to the action of the screw helix formed to be pushed out. At the top of the screw of the powder discharge port 220, the bead 600 rotates by itself in conjunction with the linear motion of the screw, thereby scraping off the powder that is accumulated and transported in the screw thread, and using the weight of the bead 600 to void the powder Remove

That is, when a bead 600 of a predetermined size and weight is put into the upper part of the built-in screw of the powder transfer screw pump connector 200, the bead 600 rotates to the powder discharge port 220 inside the connector 200 by screw thread rotation and makes a straight line. Since it moves, it functions to prevent the formation of a cavity on the screw during this process, and the powder outlet 220 rotates and scrapes so that the amount of powder to be supplied to the powder outlet 220 does not overflow, and at the same time uses the weight of the bead 600 will grind Through this, the state of the powder transferred to the outside of the connector 200 can be stabilized.

In addition, in the present invention, it is more preferable to provide limiting panels on the upper left and right sides of the powder transfer path in order to limit the horizontal and vertical motions of the marbles 600.

The bead 600 of the present invention bounces, is pushed, or even falls off to the lower part of the screw according to the fast frictional action of the rotating screw, causing an interaction that may not support the desired action. Because of this, the bead 600 It is desirable to limit the movement width of the necessary minimum. For this purpose, it is necessary to narrow the movement range to the extent that it moves linearly at the top of the screw and rotates at the powder discharge port 220.

To this end, in the present invention, the limiting panels may be provided as both side panels constituting the connector 200 . That is, when the powder is introduced through the connector 200 and the screw pump acts on the introduced powder to discharge it to the outside of the connector 200, the panel on both sides of the connector 200 is provided by narrowly arranging the panel without separate installation. can do. Even the present invention can utilize the currently used narrow screw pump connector 200 as it is.

In addition, in the present invention, the material of the beads 600 may be made of iron or glass. The beads 600 act so that the powder supplied from the hopper 100 spreads evenly in the process of being supplied, and through this, so-called cavities are prevented from occurring. In addition, the bead 600 also provides a scraper to scrape the powder so that it does not clump and a pressing function to press. For this reason, it is advantageous that the bead 600 material has low frictional force with the powder and does not generate static electricity, and through this, a completely different effect from that of the rubber bead 600 can be provided.

In addition, it is preferable to provide a graphene coating on the surface of the bead 600 of the present invention. Through this, it is possible to preferably provide an effect according to the physical properties of graphene, such as removing static electricity on the surface of the bead 600 in which the powder is continuously in contact.

In addition, in the present invention, the size of the bead 600 is preferably 60% to 90% of the diameter of the lower screw of the embedded bead 600. The diameter of the powder discharge pipe 300 discharged from the connector 200 is often about 60% to 90% of the diameter of the screw of the connector 200 when considering efficiency, and because of this, beads that are too large or small compared to the screw ( 600) When installing, the stabilization function may not be smooth on the powder.

In addition, it is preferable that a pressure adjusting hole is provided in the connector 200 of the present invention to remove internal pressure. In the powder transfer screw pump, since the rotating screw constantly pushes the powder injected into the closed space and the pressure in the space gradually increases over time, it becomes difficult to drive the device itself if the generated pressure is not properly relieved. For this reason, the connector 200 of the present invention functions as a pressure control hole through the powder supply port 230, or when the discharge pipe 300 and the discharge pipe 300 form an intermediate coupling part with the intermediate connector 500 It is preferable to provide a separate pressure control hole in the connector 500.

More preferably, the powder supply rate of the present invention together with the pressure regulating ball is controlled using a PLC. The amount of powder coming in and out of the connector 200 in a certain space can be programmed and provided using a computer. Through this, it is possible to provide a more precise screw pump technology for powder.

In addition, a discharge pipe 300 having a built-in screw may be fastened to the powder discharge port 220 of the screw pump connector 200 for powder having improved transfer precision according to the present invention. The present invention is to provide a screw pump for powder, in which a screw built-in discharge pipe (300) is added to the screw pump connector (200) for powder in which beads (600) are installed on top of the screw so that precisely controlled powder is supplied to the outside. By further fastening, it functions as a powder pump for the first time. In addition, the other end of the discharge pipe 300, one end of which is fastened to the powder discharge port 220, may function as a powder discharge port, and long-distance transfer may be supported by replacing the discharge port and combining the discharge pipe 300 with a built-in screw once more.

In addition, the powder supply port 230 of the screw pump connector 200 for powder of the present invention may be provided to be fastened with the hopper 100 at the top. In the present invention, the hopper 100 can be provided to be fastened to the top or side of the powder screw pump connector 200 of the present invention as a conventional powder supply device.

In addition, two or more screw-embedded discharge tubes 300 of the present invention are coupled, but are mutually fastened using an intermediate coupling portion, and the intermediate coupling portion is provided with a pressure adjusting ball and a screw-embedded powder transfer path, and a rotating bead (600 ) can be used. That is, in the present invention, multi-stage discharge tubes 300 may be connected in series to extend two or more discharge tubes 300 . At this time, the conveying powder can be fine-adjusted more precisely by interposing an intermediate connector 500 between the discharge tubes 300 and the discharge tubes 300 .

In addition, in the present invention, the diameter of the built-in screw of the screw pump connector 200 for powder is at least 1.2 times to a maximum of 8 times larger than the diameter of the built-in screw of the discharge pipe 300 to be fastened later, characterized in that, improved conveying precision A screw pump for powder can be provided. As a result of the experiment of the present applicant, in the case of a screw pump in which the connector 200 and the discharge pipe 300 are fastened in two steps, when the diameter of the screw in the previous step is 1.2 times or less, the surface of the screw passing through the powder discharge port 220 of the connector 200 There was a case where the powder was not properly distributed, and when it was 8 times or more, the size of the connector 200 and the bead 600 became excessively large, which was not preferable in terms of cost and transfer efficiency.

As another example, a screw pump for powder composed of a connector 200 and a multi-stage discharge tube 300 of the present invention includes the connector 200, the first discharge tube 300, the first discharge tube 300 and the second discharge tube. (300), when the second discharge pipe 300 and the third discharge pipe 300 are connected in series to extend the transfer distance, a screw is built into each connector and the discharge pipe 300 to move the powder in one direction. At this time, if a sufficient amount of powder is not supplied in the previous step, the beads 600 functioning at the top of the screw cannot optimally provide the amount of powder to go to the next step. It is preferable to make the screw diameter of at least 1.2 times to a maximum of 8 times larger than the screw diameter of the step to be connected later.

100: Hopper 200: Connector
210: powder supply port 220: powder outlet
230: power supply port 300: discharge pipe
400: screw 410: large diameter screw
420: medium diameter screw 430: small diameter screw
500: intermediate connector 600: bead
700: pressure regulator

Claims (8)

In the connector for a screw pump, the inside of which is made up of a space of a predetermined size, has a powder supply port and a powder outlet, and has a cylindrical powder transfer path for embedding a screw in a straight line with the powder outlet,
The upper side of the cylindrical powder transfer path is cut lengthwise in the longitudinal direction so that a part of the screw is exposed to the upper side,
A screw pump connector for powder with improved feed precision, characterized in that a bead for rotation is installed on the top of the exposed screw, and the size of the bead is 60% to 90% of the diameter of the built-in screw. According to claim 1,
A screw pump connector for powder with improved transfer precision, characterized in that a limiting panel for limiting the motion of beads is further provided on the left and right upper portions of the powder transfer path. According to claim 2,
The limiting panel is a screw pump connector for powder with improved transfer precision, characterized in that both side panels constituting the connector According to any one of claims 1 to 3,
Screw pump connector for powder with improved transfer precision, characterized in that the connector is provided with a pressure control hole to remove the internal pressure A screw built-in discharge pipe is fastened to the powder discharge port of the screw pump connector for powder with improved transfer precision of any one of claims 1 to 3,
The powder supply port of the connector is characterized in that it is made to be fastened with the hopper, screw pump for powder with improved transfer precision According to claim 5,
The screw-embedded discharge pipe is made by combining two or more screws and the discharge pipe, and can be mutually fastened by providing an intermediate coupling part,
The intermediate coupling part is composed of a pressure adjusting ball and an intermediate connector equipped with a screw-internal powder transfer path, and a screw pump for powder with improved transfer precision, characterized in that a rotating bead is installed on the upper part of the intermediate connector-embedded screw. According to claim 6,
The diameter of the built-in screw of the connector is at least 1.2 times to a maximum of 8 times larger than the screw diameter of the screw-embedded discharge pipe fastened to the powder discharge port, characterized in that, a screw pump for powder with improved conveying precision
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