KR20050015943A - A Cooling Apparatus and a Packing Apparatus for Divisionally packed material and a Manufacturing Method for Packages - Google Patents

Abstract

PURPOSE: A separate packing material cooling device, a packing apparatus and a package manufacturing method are provided to prevent outflow of granular objects in opening the package, and to pack the flowing granular objects easily by cooling the separate packing material filled with granular objects in transferring the package to the chute. CONSTITUTION: A particulate matter packing apparatus is composed of a cooling device(70), a metering unit measuring granular objects separately packed in a separate package(91), a charging unit charging metered granular object in a tube, a sealing unit sealing the tube filled with granular objects laterally, and a cutter manufacturing packing materials by cutting the sealing portion of the tube. The cooling device is composed of a remaining unit(72) maintaining, inclining and transferring the separate package, a guide horizontally pressing the separate package by interlocking with the remaining unit, and a chute transferring the separate package from the cooling device.

Description

A Cooling Apparatus and a Packing Apparatus for Divisionally packed material and a Manufacturing Method for Packages}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cooling device for a separated package containing particulate matter, a packaging device including the cooling device, and a method for producing a package by the packaging device. In particular, the present invention relates to a cooling apparatus for cooling a package packed with particulate matter without laying it down.

Separately packed articles of adsorbents such as spherical adsorbent coal may deform due to volume expansion or volume shrinkage caused by fluctuations in temperature after separate packing. Deformation of the separated packaging causes problems in box packaging, storage and transportation. In particular, when the temperature rises, there is a risk that breakage of the seal portion, tearing of the bag, formation of pinholes, etc. occur due to volume expansion of the contents. Therefore, countermeasures, such as filling a spherical adsorption coal at high temperature and sealing at pressure below atmospheric pressure, have been proposed (refer patent document 1).

However, there is almost no air in the interior of the separated packaging manufactured by taking measures such as filling at a high temperature or sealing at a pressure below atmospheric pressure. Therefore, in the case of a particulate matter close to a true spherical shape such as a spherical adsorbed coal, there is a problem that the particulate matter sticks out when it is opened if there is a particulate matter in the vicinity of the unsealed portion.

Therefore, in order to prevent this particulate matter from sticking out, countermeasures such as forming a seal portion such that a small hole for inflow of air is first formed in the packaging material of the separated packaging product have been proposed (see Patent Document 1).

[Patent Document 1]

Japanese Patent No. 2607422 (Page 3-4)

However, even when the seal portion is formed so that a small hole for inflow of air is first formed in the packaging material of the separated packaging when opening as described above, the particulate matter adhered to the inside of the packaging material of the separated packaging remains due to the charging of the particulate matter or the like. As a result, it may stick out at the time of opening. Therefore, it is necessary to put a particulate matter in the lower part at the time of opening. Accordingly, the present invention provides a cooling device for a separate packaging product, a packaging device provided with the cooling device, and a packaging device for cooling the particulate matter in the lower part of the separate packaging product in order to prevent the particulate matter from popping out. An object of the present invention is to provide a method for producing a package by the same.

In order to achieve the above object, the cooling device 70 of the separated packaging product that separates and packages the particulate matter according to the invention according to claim 1 holds the separated packaging article 91 at an angle, for example, as shown in FIG. 1. And a guide 72 for pressing the separating package 91 in a horizontal direction and the separating package 91 from the cooling device 70 in association with the holding hole 72 to move the plate and the holding hole 72. The chute 72 is provided.

In this configuration, since the separated packaging moves the milia cooling device to the guide while being held obliquely by the holder, and is cooled until it is sent out from the chute, the separated packaging is collected in the state where the particulate matter is collected at the lower portion. Is cooled. Moreover, the holding tool for holding and moving the separated packaging at an angle may also serve as a guide pushing in the horizontal direction. The holder may also serve as a chute for sending the separated packaging from the cooling device.

In addition, in the cooling apparatus which concerns on invention of Claim 2, as shown, for example in FIG. 1, the mounting stand 71 in which the separate packaging 91 is put is provided, and the holding tool 72 is equipped with a mounting stand ( Go along 71).

In this configuration, since the weight of the separated packaging is supported by the mounting table, and the holder moves along the mounting table, the separated packaging moves while the upper side of the mounting package is held in the holder.

In addition, in the cooling apparatus which concerns on invention of Claim 3, as shown, for example in FIG. 1, the mounting stand 71 in which the separated packing material 91 is put is provided, and the mounting stand 71 is a holding tool ( 72).

In such a configuration, since the mounting table and the holder are interlocked with each other, the bottom of the separated packaging can move without dragging, thereby preventing damage to the seal portion of the bottom of the separated packaging.

In order to achieve the above object, the packaging device for particulate matter according to the invention according to claim 4 is separated from the cooling device 70 according to any one of claims 1 to 3, for example, as shown in FIG. The metering device 20 for weighing the particulate matter separated and packaged in the package 91, the filling device 30 for filling the tube 90 with the particulate matter measured by the metering device 20, and the particulate matter are filled. The sealing device 40 which seals the tube 90 in the transverse direction, and the cutting device 60 which cut | disconnects the tube 90 in the said seal | sticker area | region are made into the package 92 are provided.

In such a configuration, since the separated package is cooled while being kept at an angle, the packaging apparatus is provided by collecting the particulate matter in the lower portion of the separated package and cooling the package to produce a package in which the particulate matter is prevented from popping out when opened.

Moreover, in order to achieve the said objective, the manufacturing method of the package which concerns on invention of Claim 5 is a process of supplying a particulate matter to the packaging apparatus of the particulate matter of Claim 4, for example, as shown in FIG. And a step of packing the particulate matter with a packaging device and a step of picking up the package.

In this configuration, by supplying the granular material to the packaging device which cools down the separated packaging by cooling it while keeping the separated packaging at an angle, the granular material is packaged by the packaging device, and packed. Since the package is picked up, a packaging method suitable for the production of a package in which the protruding particulate matter is prevented at the time of opening is provided.

Embodiment of the Invention

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described with reference to drawings. In addition, in each figure, the same code | symbol is attached | subjected to the same or corresponding apparatus mutually, and the overlapping description is abbreviate | omitted.

First, with reference to FIG. 1, the cooling device 70 of the separated packaging of the spherical adsorption coal which is 1st Embodiment of this invention is demonstrated. (A) is a top view, FIG. 1 (b) is a front view, FIG. 1 (c) is a right side view, and FIG. 1 (d) is a partial view seen from the arrow X direction. In the cooling device 70, a holder 72 is disposed on a so-called belt conveyor 71. In the holding | maintenance tool 72, the surface of a board faces a progressing direction, and the upper part is inclined backward and is installed obliquely. Forming the surface of the plate with a slippery material such as rubber is preferable for keeping the separated packaging 91 oblique. It is not necessary to be a board to be installed obliquely, and it may be a rod which supports the separated packing material 91. The plate may be installed so as to stand vertically rather than at an acute angle with respect to the horizontal plane. In addition, between the plate and the plate, as shown in Fig. 1 (d), a projection 72a for preventing slippage of the separated packaging article 91 may be provided.

The plate of the holder 72 is erected and installed so that the spherical adsorbed coal moves at an angle so that the spherical adsorbed coal does not move in the lower portion of the bag of the separated packing 91. In order to prevent the spherical adsorption coal from moving, the holding angle θ of the separated package 91 is set to 10 degrees or more and 90 degrees or less from the conveyor 71 surface (horizontal surface). Preferably they are 45 degrees or more and 90 degrees or less, More preferably, they are 70 degrees or more and 80 degrees or less.

Here, as shown in the cross-sectional view of FIG. 2 (a), the holding angle θ of the separated packaging article 91 is the upper end a of the bottom side seal and the top side seal when the separated packaging article held at an angle is viewed from the side. The angle between the straight line connecting the bottom b and the horizontal plane shall be referred to. In addition, the "tilt" in the case of "keeping the separated packaging at an angle" shall include vertical (θ = 90 degrees). That is, the spherical adsorption coal is collected on one side of the bag of the separated packaging, and the side where the spherical adsorption coal is collected is kept downward. In addition, as will be described later, the separated packaging is pressed by a pressing device, and as shown in Fig. 2B, the pressed flat surface p crosses at right angles to the traveling direction s and further advances the thinned surface q. Hold in the direction s.

At the position opposite to the position where the separate packing 91 is inserted into the cooling device 70, that is, the position where the pedestal 61 and the shock prevention roller 62 are installed, the holder 72 is a conveyor ( According to the rotation of 71, it rotates as if it covered in the direction of the separated packaging 91. Therefore, the separated packing article 91 slides the holder 72 and the conveyor 71 on the back side of the holder 72 in front of the holder 72 which has been held so far. Since the holder 72 rotates further downward, the separated packing article 91 slides on the back surface of the holder 72 and falls. In front of the drop, a box 95 for storing the separated package 91 is provided. In this way, the holder 72 serves as a chute for sending the separated packing article 91 from the cooling device 70.

Subsequently, the operation of the cooling device will be described with reference to FIG. 1. The spherical adsorption coal is separated and packaged, and the package 92 cut every several separated packages 91 slides down the pedestal 61, and the fall speed is reduced by the shock prevention roller 62, and the cooling device It falls on the conveyor 71 of 70. At that time, in the separated packaging 91, the portion in which the spherical adsorption coal is accommodated is placed downward. Here, the separated packaging 91 refers to one bag containing the particulate matter and sealed, and the package 92 is a state in which the separated packaging 91 is cut off at a seal portion every one or several. I say that.

When falling on the conveyor 71, the drop speed is reduced in the pedestal 61 and the shock prevention roller 62, and the impact on the bottom part at the time of the drop is alleviated, so that the seal portion at the bottom of the package 92 is damaged. In addition, the spherical adsorption coal housed in the bag bottom portion of the separated packaging 91 can be prevented from moving in the bag.

The package 92 dropped on the conveyor 71 is held obliquely by the holder 72 on the conveyor 71 with the portion where the spherical adsorption coal is accommodated down. If the surface of the holder 72 is formed of a slippery material, the holding angle of the separated package can be prevented from slipping by sliding on the holder 72. Alternatively, even if the holder 72 is provided with not only a plate installed at an angle, but also a projection 72a on the conveyor 71, the lower portion of the package 92 is slid on the conveyor 71 so that the package 92 Can be prevented from decreasing. The same effect can be obtained even by attaching a slippery material such as rubber to the surface of the conveyor 71.

With respect to the advancing direction of the conveyor 71, the package 92 is held obliquely by the holder 72 with the flat surface pressed in at right angles to the advancing direction and the thinned surface as the advancing direction. In this way, since the package 92 is placed obliquely with the thinned surface in the advancing direction, many packages 92 can be placed on the conveyor 71.

In addition, the conveyor 71 and the holder 72 do not support the package 92, but the holder 72 is provided with a mechanism for supporting the weight of the package 92, and only the holder 72 is provided. It is good also as a structure which supports the weight of a package.

The package 92 held obliquely by the holder 72 on the conveyor 71 is simultaneously with the conveyor 71 by the conveyor 71 and the holder 72 moving in association with the conveyor 71. Move. That is, the holder 72 not only holds the package 92 at an angle, but also serves as a guide for pushing in the horizontal direction. Thus, since the package 92 moves simultaneously with the holder 72 on the conveyor 71, the bottom part is not rubbed and is not damaged. Particularly, since the package 92 is immediately after being sealed and is easily damaged when a force is applied to the seal portion, as described above, the speed of falling from the pedestal 61 and the shock prevention roller 62 is reduced to the cooling device 70. It is preferable to mitigate the impact on the bottom part during the fall and to prevent rubbing at the bottom part during cooling.

The package 92 advances slowly on the conveyor 71. Cooling air is blown out by the cooler (not shown) in the cooling device 70, and the package 92 is cooled while advancing on the conveyor 71. As shown in FIG. As the separated package 91 is cooled, the air in the container shrinks. In addition, the spherical adsorbed coal in the separated packaging 91 is cooled, so that the amount of air that can be adsorbed by the spherical adsorbed coal increases, so that the air in the separated package 91 is adsorbed. The amount of air in the interior decreases, and the separated packaging 91 collapses. As the separated packing article 91 is retracted, the spherical adsorption coal is stable at the lower part of the bag and does not move.

For example, in the case of a separated package containing 2 g of spherical adsorbed coal warmed to 60 to 80 ° C. before packing, the separated package is moved by moving the air cooled at 25 ° C. or lower, preferably 15 ° C. or more for 5 seconds or more. The article 91 is sufficiently cooled and retracted, and the spherical adsorption coal is stable at the bottom of the bag and does not move.

In addition, even if the package 92 moves at room temperature without cooling air being blown out by the cooling device 70, it functions as a cooling device in the case of cooling the heated particulate matter to about room temperature. For example, in the case of a separated package containing 2 g of the above-described spherical adsorbent coal, the separated package 91 is sufficiently cooled and retracted by moving at room temperature for 1 to 5 minutes, and the spherical adsorbed coal is stable at the bottom of the bag. It will not move. In other words, in the cooling device 70, the separated packaging is cooled by including the spherical adsorbed coal in the space between the spherical adsorbed coal and the spherical adsorbed coal so that the spherical adsorbed coal does not move stably at the bottom of the bag. do.

When the package 92 moves to the end of the conveyor 71, the back side of the holder 72 in front of the holder 72 held so far is slid along the rotation of the conveyor 71. It falls to the box 95 and is put in the box 95. When the box 95 is filled with the package 92, the box 95 is sent to the next process and a new box 95 is placed at the position where the package 92 falls from the conveyor 71. In addition, although the package 92 on the conveyor 71 was shown to be conveyed in 1 row in the above description and FIG. 1, when the package 92 is conveyed by cooling in parallel with several rows, many packages 92 will be conveyed. Since cooling can be performed simultaneously and the progress of the conveyor 71 can be slowed down and cooling time can be lengthened, it is preferable.

Next, with reference to the perspective view of FIG. 3, the cooling apparatus 170 which is a modification of 1st Embodiment of this invention is demonstrated. In the cooling device 170 shown in FIG. 3, the holding | maintenance 72 is arrange | positioned on the conveyor 75 which moves a funnel-shaped path | route. In addition, a path | route may not be circular, elliptical, or other manor form.

The package 92 slides down on the pedestal 61, and the package 92 at which the drop speed is reduced in the shock prevention roller 62 falls on the conveyor 75. The package 92 is supported by the conveyor 75 from below and is held obliquely by the holder 72.

The package 92 inclined and held by the holder 72 moves in a manor-shaped path by the conveyor 75. The chute 73 is provided where the package 92 rotates the cooling device 170 almost once. The chute 73 is a plate arranged from the outer edge of the conveyor 75 toward the outside and below, and is provided with a box 95 for storing the packaged product. The holding tool 72 is comprised so that it may face outward toward the chute 73. By holding the holder 72 facing outward, the package 92 that is held is pushed out to the outer chute 73. The package 92 pushed out by the chute 73 slides over the chute 73 and is stored in the box 95.

In the cooling device 170 which is a modification of the first embodiment of the invention, the package 92 can be cooled while the conveyor 75 rotates about one rotation of the cooling device. Therefore, the cooling device 170 can be made compact.

In addition, the cooling apparatus 171 which is a modification of 1st Embodiment of this invention is demonstrated with reference to the perspective view of FIG. In the cooling device 171 shown in FIG. 4, the path | route 76 of the package 92 is formed in the shape of a manor, and the inclination board 77 for holding the package 92 obliquely along the inside of the path | route 76 is carried out. ) It is shaped like a sofa with a back. On the inclined plate 77, a guide 78 protruding from the top to the bottom of the inclined plate 77 is provided. The inclined plate 77 and the guide 78 move along the oblong path 76. Moreover, you may comprise so that the path | route 76 may move with the inclination board 77 and the guide 78. FIG.

The package 92 which slid | drops the base 61, and the fall speed was decelerated by the shock prevention roller 62 falls on the package conveyance machine 66. As shown in FIG. The package conveyer 66 has a plate for receiving the package 92 and an actuator for pressing the plate toward the inclined plate 77 of the cooling device 70. The package 92 dropped on the plate of the package conveyer 66 is pushed so as to be held obliquely on the inclined plate 77 on the path 76 by the movement of the plate. The package 92 is supported by the path 76 from below and is held obliquely by the inclination plate 77.

The package 92 held obliquely on the inclined plate 77 moves along the path 76 by the guide 78. In a place where the path 76 is rotated almost once, a hole is provided in the path 76, and the package 92 is transported to the chute 73 through the hole to slide the chute 73 down. It is accommodated in the box 95 below it.

When the path 76 moves along the guide 78, the bottom of the package is not rubbed during movement, which is preferable. However, since it is not easy to provide a hole in the path 76, an apparatus is provided for pushing the package 92 to the chute 73 side at the chute 73 position.

Next, with reference to the schematic diagram of FIG. 5, the packaging apparatus which is 2nd Embodiment of this invention is demonstrated. FIG. 5: shows the packing apparatus of the spherical adsorption coal provided with the cooling device 70 which is 1st Embodiment of this invention.

On the cooling device 70, a hopper 10, a metering device 20, a filling device 30, a sealing device 40, a pressing device 50 and a cutting device 60 are provided. The hopper 10 is a container in which the opened upper part becomes wider and narrows as it goes down, and the lower end is opened and is in contact with the filling nozzle 16. The heater 12 is provided in the hopper, and the spherical adsorption coal which is the contents of a hopper is heated at 60-80 degreeC. Alternatively, the spherical adsorption coal may be heated to 60 to 80 ° C through the warm air from the heating apparatus in the hopper 10.

The filling nozzle 16 under the hopper 10 is a narrow tube, and is configured to gradually send spherical adsorption coal stored in the hopper. The lower end of the filling nozzle 16 is inserted into the through hole 22a of the holder 22 and opened.

The holder 22 is combined with a metering container 21 reciprocating horizontally beneath it and a shutter 24 beneath it, and a spring 23 for pushing the holder 22 to the metering container 21 beneath it. ) And the metering device 20 is configured. The spring 23 is provided in order to prevent the spherical adsorption coal from entering and damaging the surface by bringing the holder 22 and the metering container 21 into close contact with each other. The spring 23 may not be provided.

The metering container 21 has a volume 21a of a volume suitable for the volume of the spherical adsorbed coal to be metered. The space 21a is connected in series with the through-hole 22a of the holder 22, and the measuring container 21 moves horizontally and communicates with the through-hole 24a of the shutter 24.

The lower opening of the through hole 24a of the shutter 24 of the metering device 20 is in contact with the chute pipe 31 as the filling device. The chute pipe 31 has a wide funnel shape in order to receive spherical adsorption coal falling from the through-hole 24a of the shutter 24, and the lower portion is a tapered tube. The lower end of the chute pipe 31 is opened.

Under the chute pipe 31, a tubular tube 90 for wrapping the spherical adsorption coal is placed in the state where the inlet is opened. The tube 90 is formed by forming a flat tape-like sheet in a tubular shape under the chute pipe 31. The tube 90 is sealed in the transverse direction as described below, and is made like a bag with the sealed portion at the bottom.

Below the opening of the chute pipe 31, a sealing device 40 for sealing the sheet 90 in the transverse direction is provided. The sealing apparatus 40 heat-presses the tube 90 in which spherical adsorption coal entered into the transverse direction by predetermined length by pinching by the top seal bar 41. As shown in FIG. The top seal bar 41 is configured such that the tube 90 is fitted from both sides while the two metal blocks whose ends are flat in order to heat-press the tube 90 are heated by a heater. The top seal bar 41 is pulled downward with the tube 90 inserted so that the seal portion is at the bottom of the next bag for spherical adsorption.

Following the movement of the top seal bar 41 of the seal device 40, the clamping device 50 disposed immediately below the seal device operates. In order to prevent the package after the packaging from expanding due to a temperature rise, the fitting device inserts a portion of the tube 90 which is closed by the sealing device 40 of the tube 90 in the air releasing guide 51. It is a device for pushing air. Air squeeze guide 51, the bag of the tube 90 into which the spherical adsorption coal was inserted, puts the spherical adsorption coal into the bottom part, and the upper part is crushed flat so that nothing may enter, The upper part protrudes and has the shape which the lower part entered. The top seal bar 41 and the air bleeding guide 51 are arranged to sandwich the tube 90 in the same direction.

Under the presser device 50, the tube 90 containing the spherical adsorption coal is cut from the sealed portion, and the separated packing articles 91 containing the spherical adsorption coal are separated one by one or several packages ( 92 is provided with a cutting device 60. The cutting device 60 is comprised so that two blades may fit the tube 90 and cut | disconnect. In addition, in the package 92 in which the separated packing articles 91 containing spherical adsorption coals are connected to each other, a sewing machine scale may be placed so that the seal portion which is not cut is easily removed by hand, and the cutting device 60 is provided. In some cases, the cutting edges may be provided with notched blades at the same interval at the cutting edges that operate at different timings from the cutting blades.

Under the cutting device 60, the base 61 is arrange | positioned. The base 61 obliquely drops the package 92 cut | disconnected with the flat plate installed at an angle, and softens the impact at the time of fall as mentioned above. The pedestal 61 is provided with a shock prevention roller 62 for further reducing the falling speed. The shock prevention roller 62 is provided so that the package 92 may pass between two cylindrical rollers when the package 92 slips and falls on the base 61. As shown in FIG. Since the package 92 rotates a roller as it passes between the two rollers, the fall speed is reduced. In addition, the roller of the shock prevention roller 62 may be one, and instead of providing the shock prevention roller 62, a method for reducing the falling speed, for example, increasing the friction on the pedestal 61 Measures may be taken for this purpose.

At the end of the pedestal 61, a cooling device 70 is provided, and as described above, after the separated packing 91 is cooled, the spherical adsorbed coal in the interior is not stabilized and moved at the bottom thereof. It is configured to be box packed.

Next, with reference to FIG. 5, the manufacturing method of the package 92 of spherical adsorption coal is demonstrated. The spherical adsorption coal is supplied to the hopper 10 from the opened upper portion and temporarily stored in the hopper 10. The spherical adsorbed coal stored in the hopper 10 is heated to 60 to 80 ° C. by the heater 12 while being stored. In order to prevent the contents from expanding due to the increase in temperature after the packaging and to form a gap in the separated packaging 91, and to prevent the spherical adsorbed coal from moving inside, it is to be packaged after raising to the highest temperature assumed in advance.

The spherical adsorption coal slowly descends into the hopper 10 and flows into the filling nozzle 16 from the lower end. The inner diameter of the filling nozzle 16 is selected so that the amount of spherical adsorption coal passes through the filling nozzle 16 and is sent from the hopper 10 is appropriate. A valve for adjusting the amount sent into the filling nozzle 16 may be provided.

The spherical adsorption coal is stored in the space 21a of the measuring container 21 through the holder 22 from the filling nozzle 16. When the space 21a is filled with the spherical adsorption coal, the metering container 21 moves horizontally, and the spherical adsorption coal in the space 21a passes through the through hole 24a of the shutter 24, and the chute pipe Are sent to (31). The spherical adsorption coal is metered by the metering device 20 in the volume of the space 21a.

As the spherical adsorbed coal is fed to the hopper 10, the sheet wound on the roll is drawn out at a predetermined speed, and is formed into a cylindrical shape near the lower end of the chute pipe 31, and the overlapped portion is heated. By compression, the tube 90 is formed. As described later, the tube 90 is sealed in the transverse direction at a predetermined portion by the sealing device 40. The tube 90 is formed in a bag shape with the sealed portion as a bottom, and is placed in the shape of opening the inlet in the lower opening direction of the chute pipe 31.

The spherical adsorption coal measured by the metering device 20 is dropped from the chute pipe 31 into the bag-shaped tube 90, and accumulated in the bag bottom part. Then, the air bleeding guide 51 of the clamping device 50 pinches the bag-shaped part from both sides, and pushes in the air inside. Almost simultaneously with bleeding air from the presser 50, the portion immediately above the portion from which the air is drawn out from the presser 50 is sealed in the transverse direction by the sealer 40. In addition, the tube 90 is made of a multilayer film having a sealable plastic film in its inner layer, and can be heat-compressed by being sandwiched by a heated top seal bar 41.

The top seal bar 41 moves downward by the length of one spherical adsorption coal with the tube 90 fitted. By this movement, the seal portion in which the spherical adsorption coal is sealed becomes the bottom of the next bag portion of the tube 90.

The separated packing article 91 sealed with the spherical adsorption coal and sealed in the transverse direction is integrated in one or three bags and cut at the seal portion by the cutting device 60. When a plurality of bags are integrated and cut as one, a sewing machine scale for easy hand peeling may be attached to the seal portion between the bags by inserting the blades notched at the same intervals at the blade edges. .

The package 92 cut | disconnected by the cutting device 60 falls down on the base 61, falls to the cooling device 70 after the fall speed is decelerated by the shock prevention roller 62, and is mentioned above. As described above, after being cooled in the cooling apparatus, it is housed in a box for every predetermined quantity and moved out for each box.

Here, spherical adsorption coals cooled by the cooling device of the first embodiment of the present invention or packaged by the packaging device of the second embodiment will be described. Spherical adsorption coal is a porous spherical carbonaceous substance, its diameter is 0.05-1 mm, and its bulk density is 0.51 ± 0.04 g / ml. Since the spherical adsorbed coal has a real spherical shape and high fluidity, the spherical adsorption coal is easily blown off when the separated package is opened. In addition, the amount of air contained is large, the amount varies greatly with temperature, and, for example, about 1.46 ml of air is released per 1 g at an elevated temperature from 0 ° C to 30 ° C. Therefore, since it is warmed to 60 to 80 ° C. in advance, and after it is sufficiently cooled and sealed as a separate package, it is cooled, and the bag of the separated package is vacuumed, and the spherical adsorbed coal is packed in the bag of the separated package. It is stable and does not move.

In addition, although the spherical adsorption coal was mentioned and demonstrated as a particulate matter measured and packaged so far, the measuring apparatus, the packaging apparatus, and the manufacturing method of the package which were applied to this invention are applicable also to other particulate matter. In particular, it can be suitably used for the separated packaging product which superheats and fills high fluidity particle | grains, and is cooled and manufactured after that.

As described above, since the cooling apparatus of the separated packaging according to the present invention cools the separated package while keeping the separated packaging at an angle, the separated package is cooled with the particulate matter in the lower portion, thereby preventing the particulate matter from being popped out when opened. . In addition, the packaging apparatus of the package having the cooling device is preferable for packaging the highly fluid particulate matter because the separated package is cooled while the particulate matter is put in the lower portion.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure explaining the cooling device which is 1st Embodiment of this invention, FIG. 1 (a) is a top view, FIG. 1 (b) is a front view, FIG. 1 (c) is a right side view, FIG. 1 (d). Is a partial view from arrow X direction.

2 is a perspective view illustrating a sectional view of a bag illustrating an angle of holding the separated package at an angle and a holding direction of the separated package;

3 is a perspective view illustrating a modification of the cooling device according to the first embodiment of the present invention.

4 is a perspective view illustrating a modification of the cooling device according to the first embodiment of the present invention.

It is a schematic diagram explaining the packaging apparatus which is 2nd Embodiment of this invention.

<Description of the symbols for the main parts of the drawings>

20: metering device 30: charging device

40: sealing device 50: pressing device

60: cutting device 61: pedestal

62: shock prevention roller 70: cooling device

71: conveyor 72: holder

73: chute 75: conveyor

76: route 77: inclined plate

78: guide 170,171: cooling device

Claims (5)

As a cooling device for separate packaging in which the particulate matter is separately packaged, A holder for moving the separated packaging at an angle; A guide for pushing the separated packaging in a horizontal direction in association with the holder; And a chute for sending said separate package from a cooling device. 2. The apparatus of claim 1, further comprising: a mount for placing the separate package; The holder is moved according to the mounting device. 2. The apparatus of claim 1, further comprising: a mount for placing the separate package; Cooling device that the mount is interlocked with the holder. A cooling device according to any one of claims 1 to 3; A metering device for weighing the particulate matter separately packed and packaged in the separated package; A filling device for filling the tube with the particulate matter measured by the measuring device; A sealing device for sealing the tube filled with the particulate matter in a transverse direction; And a cutting device for cutting the tube in the sealed area to form a package. Supplying the particulate matter to the packaging apparatus according to claim 4; Packaging the particulate matter in the packaging device; A method for producing a package comprising the step of picking up the package.