JP2010036105A - Blending apparatus of pellet and method of manufacturing blended pellet - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a blending apparatus of pellets for blending a plurality of kinds of pellets by using the gravity or transferring force in a pipe without using any driver, with simple apparatus structure and uniformly blending the plurality of kinds of pellets, and to provide a method of manufacturing the blended pellets for manufacturing the blended pellets with the plurality of kinds of pellets uniformly blended using the blending apparatus of pellets. <P>SOLUTION: The blending apparatus of pellets is provided with a feed pipe 1 for joining various kinds of pellets, and a distribution type blending device 2 added downstream of the feed pipe, the distribution type blending device comprising a porous structure like a lattice 3. The distribution type blending device 2 promotes the blending of the pellets by dispersion of the pellets when passing through the porous structure. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a pellet mixing apparatus and a mixed pellet manufacturing method, and more specifically, a pellet mixing apparatus having a simple apparatus configuration and capable of uniformly mixing a plurality of types of pellets, and the mixing apparatus. It is related with the manufacturing method of the used mixed pellet.

  For example, in the molding of resin products, mixed pellets composed of two or more kinds of resin pellets are often used as molding materials for the purpose of improving characteristics such as heat resistance and coloring. In mixing resin pellets, a rotating mixer, a mixer equipped with a stirring blade, a mixing device that combines a rotating barrel and a screw conveyor, etc. are often used, and a mixing device that drops and mixes pellets using gravity. Has also been proposed.

The above-described mixing device using gravity has the advantage that the device configuration is relatively simple because the number of driving parts is small, and maintenance management is also easy. As such an apparatus, for example, a shooter formed in an inverted frustum shape or an inverted truncated pyramid shape and having an inner wall surface designed at a predetermined inclination angle, and arranged on the upper part of the shooter corresponding to the type of pellet “Pellets that consist of multiple hoppers, mixed with multiple types of pellets dropped from each hopper while rebounding with the impact force against the inner wall of the shooter, and taking out the mixed pellets from the lower end of the shooter” Of mixing apparatus ”.
JP-A-5-103961

  By the way, in a shooter-type mixing device formed in an inverted frustum shape or the like, there is a situation that it cannot be uniformly mixed depending on the type of pellet because the flight distance by rebounding differs depending on the mass and size of the pellet. . In addition, there is a problem that the outer shape of the shooter is larger than the processing capability, and the device configuration cannot be sufficiently reduced.

  The present invention has been made in view of the above circumstances, and an object thereof is a mixing apparatus that mixes a plurality of types of pellets using gravity or a transfer force in a pipe without using a driving device. The object of the present invention is to provide a pellet mixing apparatus having a simple apparatus configuration and capable of uniformly mixing a plurality of types of pellets. Moreover, the other object of this invention is to provide the manufacturing method of the mixed pellet which can manufacture easily the mixed pellet in which the multiple types of pellet was mixed uniformly.

  In order to solve the above-mentioned problems, in the present invention, a plurality of types of pellets are preliminarily joined in the supply pipe, supplied to the dispersion mixer from above by gravity or a transfer force in the supply pipe, and dropped. The mixing of the pellets was promoted by scattering when passing through the porous structure of the dispersion mixer.

  That is, the first gist of the present invention is a mixing device that mixes a plurality of types of pellets, and is provided on the downstream side of the supply pipe that joins the various types of pellets and drops them downward. A dispersion mixer, and the dispersion mixer is composed of a porous structure in which a plurality of pellet dropping holes are arranged in the horizontal direction. The second gist of the present invention resides in a mixed pellet manufacturing method characterized by using the above-described pellet mixing apparatus and supplying a plurality of types of pellets from a supply pipe to manufacture mixed pellets.

  According to the pellet mixing apparatus of the present invention, a plurality of types of pellets are supplied to the dispersion type mixer from above and mixed by scattering when passing through the porous structure by the dropping force. In addition, it is possible to mix them, and it is possible to make a very simple device configuration without a driving device and to reduce the size. Moreover, according to the method for producing mixed pellets according to the present invention, the above-described pellet mixing apparatus is used to mix a plurality of types of pellets by scattering when passing through the porous structure of the dispersion mixer. It is possible to easily produce mixed pellets that are uniformly mixed.

  An embodiment of a pellet mixing apparatus according to the present invention will be described with reference to the drawings. FIG. 1 is a side view showing a partially broken outline of an example of a pellet mixing apparatus according to the present invention. In the following description, the pellet mixing device is abbreviated as “mixing device”.

  The mixing apparatus of the present invention is a mixing apparatus for mixing a plurality of types of pellets. For example, in order to mix two or more types of pellets and store them in a container for transportation, etc., a storage place for pellets such as a silo (storage tank) It is installed in the pipeline from the shipping port such as the filling port to the container. Examples of pellets to which the present invention is applied include resin pellets used for molding materials such as polyethylene, polypropylene, polystyrene, polyvinyl chloride, polyamide, polycarbonate, and polyester.

  Usually, the resin pellets as described above have a short-axis cylindrical outer shape with a circular section whose section perpendicular to the length is somewhat distorted, and the average maximum length of the resin pellets (both end faces of the pellet). The diagonal length between them is about 1 to 5 mm. For example, as an example, PBT (polybutylene terephthalate) pellets have an average major axis (maximum length of the above circular cross section) of 3.2 mm and an average minor axis (minimum length of the above circular cross section) of 2.4 mm. The average length (the length of the center line) is 2.7 mm, and the average maximum length (the diagonal length between both end faces of the pellet) is 4.2 mm. In addition, this invention is applicable also to mixing of various pellets, such as a fertilizer, besides a resin pellet.

  As shown in FIG. 1 (a), the mixing apparatus of the present invention is provided with a supply pipe (1) for joining a plurality of types of pellets, for example, two types of pellets, and dropping them downward, and downstream of the supply pipe. And the distributed mixer (2). The above-described silo for storing pellets is installed for each type of pellet, and the above-described supply pipe (1) is configured by collecting individual supply pipes extended from each silo into one by Y joints. And connected to a distributed mixer (2).

  As shown in the drawing, the supply pipe (1) is extended, for example, in the vertical direction on the downstream side, and two types of pellets are merged and dropped into the dispersion mixer (2). The supply pipe (1) may be configured to supply the pellets to the dispersion mixer (2) by a transfer force (air pressure) when the pellets are transferred by air. In addition, the code | symbol (11) and (12) in a figure shows supply valves, such as a rotary valve provided in separate supply piping, in order to control supply of a pellet.

  The dispersion mixer (2) is composed of a porous structure in which a large number of pellet dropping holes are arranged in the horizontal direction. The pellet dropping hole of the porous structure is usually a hole that penetrates in the vertical direction and has a size through which the pellet can pass. The planar shape of the pellet dropping hole can be designed in various shapes such as a polygonal shape and a circular shape, but they need to be arranged so as not to cause retention and blockage at the entrance. Further, the pellet dropping hole needs to have an appropriate depth so that it collides with the wall surface of the hole while the pellet passes and is scattered in multiple directions when it passes.

  Specifically, the dispersion mixer (2) is formed in a ring shape following the shape of the flange, as shown in FIG. 1 (b), for example, in order to flange-connect to the supply pipe (1). A porous structure is arranged inside the frame (20). From the viewpoint of manufacturing, the porous structure is formed by arranging strip-shaped blades (elongate plate-like members) (31), (32) vertically and horizontally so that the width is the depth of the pellet dropping hole. A grid (3) is used. Such a lattice (3) is preferably made of a metal such as steel or stainless steel so as to withstand the impact force of the pellets supplied from the supply pipe (1). And, in order to fly the pellet in multiple directions by the repulsive force due to the contact when passing through the pellet drop hole, the width of the vertical blade (31) and the horizontal blade (32) is the lattice plane (the lattice is flat) It is arrange | positioned in the state orthogonal to the end surface at the time of seeing.

  Moreover, in the dispersion type mixer (2), the opening width of the pellet dropping hole and the pellet falling so that the pellet passing through the porous structure is scattered more widely at the outlet of the pellet dropping hole (lower end of the porous structure). The depth of the hole is designed to a predetermined size. In addition, the opening width of a pellet drop hole means the diameter of the circle | round | yen inscribed in the shape, when the pellet drop hole is a polygon.

  In the case of the dispersive mixer (2) shown in FIG. 1B, the opening width (grid spacing) of the lattice (3), that is, the distance between the blades (31) and (31) and the blades (32) and (32 ) Is set to 3 to 50 times the average maximum length of the pellets. Specifically, it is usually set to 3 to 300 mm, preferably 10 to 100 mm. The reason why the opening width of the lattice (3) is set in the above range is as follows. That is, if the opening width is less than 3 times the average maximum length of the pellet, there is a possibility that the pellet dropping hole may be blocked, and if the opening width is larger than 50 times the average length of the pellet, Since the pellet passes through the pellet dropping hole without colliding with the inner wall (blade width portion) of each pellet dropping hole, there is a possibility that sufficient mixing cannot be performed.

  The depth of the holes in the lattice (3), that is, the width of the blades (31) and (32) in the direction orthogonal to the paper surface in the drawing is set to 0.5 to 100 times the average maximum length of the pellets. The Specifically, it is usually set to 1 to 600 mm, preferably 5 to 100 mm. The reason for setting the depth of the holes of the lattice (3) in the above range is as follows. That is, when the depth of the holes in the lattice (3) is less than 0.5 times the average maximum length of the pellets, the amount of collision with the inner wall (blade width portion) of each pellet dropping hole is small, and The dispersibility of the resin may deteriorate. On the other hand, when the depth of the holes in the lattice (3) is larger than 100 times the average maximum length of the pellets, a rectifying action occurs on the pellets when passing through the lattice (3), and the dispersibility is similarly poor. May be. By setting the opening width of the lattice (3) and the depth of the holes as described above, the dispersibility of the pellets can be improved and mixing can be performed efficiently.

  In the present invention, in order to mix the pellets more uniformly, a sliding-type mixer may be disposed on the upstream side or the downstream side of the dispersion-type mixer (2). As indicated by reference numeral (4) in FIG. 1 (a), the sliding-down mixer is usually disposed on the downstream side of the dispersion-type mixer (2).

The sliding-type mixer (4) includes a cylindrical device main body having a horizontal cross-section, for example, a quadrangle and sealed at the upper and lower ends, and a pellet inlet (41) connected to the mixer (2) It has in the upper end of an apparatus main body, and has a pellet discharge port (42) in a lower end. Reference numeral (43) in the figure denotes a discharge valve such as a rotary valve attached to the pellet discharge port (42) in order to adjust the discharge amount of the mixed pellets. The internal volume of the sliding-type mixer (4) varies depending on the processing amount, but is usually designed to be about 0.01 to 100 m ³ .

  Inside the apparatus main body of the sliding mixer (4), a dropping path (5) is formed in a zigzag manner in the vertical direction from the pellet introduction port (41) to the pellet discharge port (42). Specifically, when viewed from the side, the falling path (5) is constructed along one width direction of the apparatus main body (direction orthogonal to the paper surface in the figure) and the other width direction of the apparatus main body (left and right in the figure). Zigzag by several plate-like members arranged in a state inclined with respect to (the direction of) in the figure (the constituent member of the bottom portion indicated by reference numeral (51) and the constituent member of the ceiling portion indicated by reference numeral (52) in the figure). It is configured as a duct-shaped flow path space that is continuous with the other. In the above-described dropping path (5), the pellets are sequentially slid by their own weight with respect to the bottom surface portion (31) of each step of the zigzag, and the mixing of the pellets is further promoted during that time.

  Furthermore, in the present invention, the sliding mixer (4) has a fine powder removing function in order to remove fine resin particles generated during the transfer and mixing operations, or fine foreign matters mixed during storage or transfer. May be. Specifically, the sliding mixer (4) has a structure in which these fine powders and foreign matters (hereinafter referred to as “fine powder”) are classified by, for example, wind power during the mixing operation, that is, fine powder by air blowing. It has a structure that separates.

  In the sliding mixer (4), the dropping path (5) has a bottom surface portion (51) of each step of the zigzag which is a pellet sliding surface made of a mesh member. An air nozzle (6) for blowing air from the lower surface side toward the bottom surface portion (51) of the dropping path (5) is provided inside the apparatus main body, and the upper end of the apparatus main body An exhaust pipe (7) for discharging fine powder together with the air supplied to is provided.

  As the mesh member constituting the bottom surface portion (51) of each step of the drop path (5), a metal mesh made of steel, stainless steel, aluminum alloy or the like, or a mesh made of various resins excellent in wear resistance and heat resistance is used. used. Moreover, in order to discharge the air blown to the bottom surface part (51) of the dropping path (5) together with the fine powder at the upstream part of the dropping path (5), the upper part of each stage except the uppermost stage of the dropping path (5) It is covered with a ceiling (52) that shields air. That is, in each step of the zigzag duct-shaped dropping path (5), the bottom surface portion (51) is composed of a mesh member, and the ceiling portion (52) is composed of a shielding plate. The air nozzle (6) is normally disposed below the bottom surface portion (51) of each stage of the drop path (5). Each air nozzle (6) is supplied with a constant pressure of air from a pressurized air supply device such as an air compressor.

  By using the mixing apparatus of the present invention as described above and supplying and mixing a plurality of types of pellets from the supply pipe (1), uniformly mixed pellets can be produced. In the production of mixed pellets, first, for example, two kinds of pellets are joined together in advance in the supply pipe (1), and then the two kinds of pellets are dispersed by a transfer force (pneumatic force) in the supply pipe or the weight of the pellets. (2) is passed through the grid (3) of the dispersion mixer.

  The pellets passing through the lattice (3) of the dispersion mixer (2) bounce back in contact with the side wall portion of the pellet drop hole of the lattice (3), in other words, the width portion of the blades (31) and (32). Then it falls and scatters in an arbitrary direction at the exit (lower end) of the lattice (3). As a result, two types of pellets are mixed below the lattice (3). That is, in the present invention, mixing of the pellets is promoted by scattering when passing through the lattice (3) which is the porous structure of the dispersion mixer (2).

  Next, the mixed pellets are supplied to the sliding-type mixer (4) on the downstream side, and further mixed and the fine powder is removed. In the sliding mixer (4), the pellets dropped from the pellet introduction port (41) into the dropping path (5) slide down the bottom part (31) of each stage of the zigzag and fall down each stage sequentially. To do. At that time, the pellets fly as if jumping, and the mixing of the pellets is further promoted. Further, in the sliding mixer (4), air is blown from the lower surface side to the bottom surface portion (31) of each step of the dropping path (5) to separate the fine powder mixed or adhered to the pellet. Then, it is discharged from the exhaust pipe (7) along with the air flow. And the pellet from which fine powder was removed is taken out from a pellet discharge port (42), and is further accommodated in a downstream container etc.

  As described above, according to the mixing device of the present invention, a plurality of types of pellets are supplied to the dispersion mixer (2) from above through the supply pipe (1), and the lattice (3 ), The pellets can be mixed uniformly. And since it is comprised by the supply piping (1) which joins multiple types of pellets, and the dispersion | distribution type mixer (2) which consists of a porous structure, it can be set as a very simple apparatus structure without a drive equipment, The configuration can be further reduced in size. In addition, since the sliding-type mixer (4) is disposed on the downstream side of the dispersion-type mixer (2), it is possible to produce clean mixed pellets to which fine powder is not attached.

  Moreover, according to the manufacturing method of the mixing pellet which concerns on this invention using said mixing apparatus, in said dispersion | distribution type mixer (2), when passing the grating | lattice (3) which is a porous structure, ( Since a plurality of types of pellets are mixed by scattering), uniformly mixed pellets can be easily manufactured. And since this invention mixes a pellet in a scattering state in a dispersion | distribution type mixer (2), even when the mixing ratio of the other kind of pellet with respect to a main pellet is small, it can mix uniformly. In particular, the present invention is suitable when one or more different types of pellets are mixed with the main pellets at a ratio of 10% by weight or less of the total amount of the pellets.

Using the supply pipe (1) and the dispersion mixer (2) of the mixing apparatus illustrated in the figure, the mixing effect was confirmed. As pellets to be mixed, PBT pellets (A) (main pellets) and colored PBT pellets (B) were prepared. And these 98.0: was fed to the feed pipe at a weight ratio of 2.0 (1), perform the mixing operation in a distributed mixer (2) was taken up in the flexible container of capacity 1 m ^3. As the porous structure of the dispersion mixer (2), a grid (3) having a grid interval of 50 mm, a pellet dropping hole depth of 15 mm, and a number of pellet dropping holes of 45 was used. The obtained mixed pellets were collected 200 g from the four corners and the center of the flexible container, sorted into pellets (A) and pellets (B) by visual inspection, and the mixing ratio was confirmed. The mixing ratio of B) was 1.95 to 2.08% by weight, and it was confirmed that the mixture was uniformly mixed in any place of the flexible container.

It is a side view which shows the outline | summary of an example of the mixing apparatus of the pellet which concerns on this invention partially fractured | ruptured.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1: Supply piping 2: Dispersion type mixer 20: Frame body 3: Lattice 31: Longitudinal blade 32: Horizontal blade 4: Sliding type mixer 41: Pellet inlet 42: Pellet outlet 5: Falling path 51 : Bottom part of each step of the fall path 52: Ceiling part of each stage of the fall path 6: Air nozzle 7: Exhaust pipe

Claims (7)

  A mixing device for mixing a plurality of types of pellets, comprising a supply pipe that joins the various types of pellets and drops them downward, and a dispersion mixer attached downstream of the supply pipe, the dispersion type The mixer is composed of a porous structure in which a plurality of pellet dropping holes are arranged in a horizontal direction.   2. The pellet mixing apparatus according to claim 1, wherein the porous structure is a lattice formed by arranging strip-shaped blades vertically and horizontally.   Each pellet drop hole has an opening width of 3 to 50 times the average maximum length of the pellet, and a depth of 0.5 to 100 times the average maximum length of the pellet. Pellet mixing equipment.   A sliding-type mixer is disposed upstream or downstream of the dispersion-type mixer, and the sliding-type mixer has a cylindrical apparatus body having a pellet inlet at the upper end and a pellet outlet at the lower end. The pellet according to any one of claims 1 to 3, wherein a dropping path having a zigzag flow path is provided in the apparatus main body from the pellet introduction port to the pellet discharge port. Mixing equipment.   The falling path of the sliding mixer is composed of a net-like member at the bottom of each stage of the zigzag that is the pellet sliding surface, and the inside of the apparatus main body of the sliding mixer is directed toward the bottom of the dropping path. The pellet mixing apparatus according to claim 4, wherein an air nozzle for blowing air from a lower surface side thereof is provided, and an exhaust pipe is provided at an upper end of the apparatus main body.   A method for producing mixed pellets, comprising using the pellet mixing apparatus according to any one of claims 1 to 5 and supplying a plurality of types of pellets from a supply pipe to produce mixed pellets.   The manufacturing method of the mixed pellet of Claim 6 which mixes one or more types of different types of pellets with respect to the main pellet at a ratio of 10% by weight or less of the total amount of the pellets.

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