JPH04317782A - Apparatus for reducing volume of waste synthetic resin - Google Patents

Abstract

PURPOSE:To efficiently and uniformly reduce the volume of a waste synthetic resin by quantitatively supplying the waste synthetic resin to a heating volume reducing means by a simple structure. CONSTITUTION:A volume reducing apparatus is constituted by connecting a heating volume reducing means 2 to the discharge part of a supply means 1. The supply means 1 is formed by providing a screw shaft 4 in a supply cylinder 3 and a waste synthetic resin is supplied to the heating volume reducing means 2 by rotating the screw shaft 4. The supply cylinder 3 is vertically or obliquely arranged and the waste synthetic resin is fed downward under pressure by the screw shaft 4. A supply hopper 9 is connected to the side surface or upper part of the supply cylinder 3. The waste synthetic resin supplied to the supply hopper 9 is scraped off from the side part of the supply cylinder 3 by the screw shaft 4 to be quantitatively supplied to the heating volume reducing means 2.

Description

[Detailed description of the invention]

0001

BACKGROUND OF THE INVENTION 1. Field of the Invention This invention relates to an apparatus for reducing the solubility of waste synthetic resin so that it can be effectively reused.

0002

BACKGROUND OF THE INVENTION Currently, a huge amount of used synthetic resin is generated. Moreover, its amount is increasing significantly. Most used synthetic resin is disposed of by incineration. Incinerators for waste synthetic resin have a short lifespan, making incineration costs soar. Also, depending on the type of synthetic resin, toxic gas is generated when incinerated.

[0003] A part of used synthetic resin is utilized for molding recycled products. To reuse waste synthetic resin,
Dirty synthetic resin is washed, melted, molded into pellets, and reused. This method has the disadvantage that processing costs for processing waste synthetic resin into pellets are high.

[0004] In order to effectively recycle the enormous amount of waste synthetic resin generated, it is important to find a way to reduce the processing cost and reduce solubility. The waste synthetic resin that has been reduced in solubility can be remolded using a molding machine.

[0005] A device has been developed that reduces the solubility of waste synthetic resin by forcing it into a cylinder with a narrowly constricted tip (Japanese Patent Laid-Open Publication No. 82879/1982). This melt reduction device heats the tip of the cylinder to melt the extruded waste synthetic resin with heat. Waste synthetic resin is pushed into the cylinder with a piston, heated and melted at the tip, and extruded from the cylinder in a reduced-solute state.

[0006] This structure of the melt reduction device requires a large amount of thermal energy to heat the cylinder to a high temperature. This increases running costs. As a solution reducing device to solve this drawback, a device for heating synthetic resin with frictional heat has been developed (Japanese Utility Model Publication No. 62-22340). This device has a screw shaft built into the cylinder that pushes out the waste synthetic resin. The opening at the end of the cylinder is narrowed, and this part generates heat from the synthetic resin through frictional heat. The tip of the screw shaft is shaped to reduce the amount of synthetic resin transferred so that the amount of heat generated by the synthetic resin increases at the tip of the cylinder.

[0007] It is difficult for the solubility reduction device of this structure to efficiently reduce the solubility of various types of waste thermoplastic synthetic resins. This is because the amount of heat generated varies significantly depending on the type of synthetic resin and the water content.

[0008] In order to solve this drawback, the present inventor developed a melt reduction device shown in FIG.
No. 9917). In this solubility reduction device, a supply cylinder 3 and a solubility reduction cylinder 10 are connected in series. The supply cylinder 3 has a built-in screw shaft 4 for supplying the supplied waste synthetic resin to the solute reduction cylinder 10. A spline shaft 16 is built in parallel to the screw shaft 4 and close to the fins of the screw shaft. The solubility reduction cylinder 10 houses a rotating member 7 that heats and reduces the solubility of the synthetic resin supplied thereto. Solvent reduction cylinder 10
A narrow heating and melting reduction gap 6 is provided between the rotary member 7 and the rotating member 7 in order to frictionally heat the synthetic resin.

[0009] This solubility reduction device can reduce the solubility of waste synthetic resin under the following conditions. ■ Put the waste synthetic resin into the supply hopper of the supply cylinder 3. (2) The synthetic resin in the supply hopper is sandwiched between the fins of the screw shaft 4 and the protrusions of the spline shaft 16, and is fed under pressure to the heating and dissolving means 2. (2) The waste synthetic resin fed into the melt-reducing cylinder 10 is rubbed in the heating melt-reducing gap 6 to generate heat and its melt is reduced. The waste synthetic resin generates heat in the heat-reducing gap 6 because it is rubbed by the rotating member 7 in a pressed state.

0010

The solubility reduction device having this structure has the advantage that the synthetic resin charged into the supply hopper can be cut into small pieces and then fed under pressure to the heating and solubility reduction means. However, this structure of the melt reduction device does not have the ability to transport the synthetic resin using the spline shaft, so there is a drawback that the cut synthetic resin tends to accumulate in this part. Therefore, after using it for a certain period of time,
It is necessary to disassemble the supply cylinder and remove the clogged synthetic resin, which has the disadvantage of requiring time and effort for maintenance. In addition, the synthetic resin stuck between the spline shaft and the supply cylinder is pressed very strongly, so it takes a lot of effort to remove it.

[0011]Furthermore, the solubilization device having this structure has the disadvantage that it cannot efficiently reduce the dissolution of waste synthetic resin in a uniform state. The reason for this is that the screw shaft and the spline shaft cannot quantitatively supply the synthetic resin charged into the supply hopper to the heat-reducing means. The supply means having this structure has a characteristic that the spline shaft engages the synthetic resin supplied to the supply hopper at one time and pressure-feeds it to the melt reduction cylinder. The spline shaft having protrusions in the axial direction has the property of biting the synthetic resin in the supply hopper at once. When a large amount of synthetic resin is temporarily fed into the melt reduction cylinder from the supply means, the large amount of synthetic resin is press-fitted into the heating melt reduction gap. A large amount of synthetic resin significantly increases the rotational torque of the rotating member,
Overload the driving motor, etc. For this reason, it is necessary to use an extremely high output motor for driving the rotating members, which increases equipment costs and reduces the efficiency of electric power use. Furthermore, a large amount of synthetic resin press-fitted into the heat-reducing gap has the disadvantage that its temperature rises abnormally due to frictional heat, and the synthetic resin is overheated and deteriorated before being discharged.

[0012] This drawback can be overcome by omitting the spline shaft. However, depending on the type of waste synthetic resin, a solute reduction device that is not equipped with a spline shaft may
There is a drawback that friction and melt reduction cannot be efficiently achieved in the heat-reduced gap. This is because synthetic resins that are too large or too long will rub against each other in the narrow heat-reducing gap and will not be rubbed efficiently. In order for the synthetic resin to be efficiently rubbed and dissolved in the heat-reducing gap, a shape that facilitates friction in the narrow heat-reducing gap is required. Unlike new synthetic resin pellets, waste synthetic resin comes in a variety of shapes. By cutting the waste synthetic resin into small pieces, the spline shaft can efficiently reduce friction and melting in the heat-reducing gap.

[0013] As described above, the spline shaft has the advantage of improving the friction and melt reduction efficiency in the heating melt reduction gap, but
Unless a fixed amount of waste synthetic resin is supplied to the supply hopper, the synthetic resin deteriorates and cannot be reused effectively. In addition, if the amount of synthetic resin input is small, the amount of synthetic resin fed into the heating and dissolution gap will decrease, making it impossible to efficiently friction and reduce dissolution, and the heating temperature will become low, resulting in the disadvantage that it is discharged without being sufficiently reduced. There is also.

[0014] However, it is extremely difficult to uniformly control the amount of synthetic resin supplied to the dissolution reduction device for waste synthetic resin. This is because waste synthetic resins come in various shapes. Synthetic resins in a certain shape, such as synthetic resin pellets, can be supplied in fixed quantities. However, in reality, it is almost impossible to supply a fixed amount of waste synthetic resin that is in the form of a long film or has irregular sizes and significantly different shapes.

[0015] This invention was developed for the purpose of efficiently and uniformly reducing the solubility of waste synthetic resin, which is difficult to supply in a quantitative manner.An important objective of this invention is to reduce the solubility of waste synthetic resin with a simple structure. It is an object of the present invention to provide a dissolution device for waste synthetic resin that can efficiently reduce the dissolution of the waste synthetic resin, and can uniformly reduce the dissolution of the synthetic resin by supplying a fixed amount of synthetic resin to the heating dissolution gap. moreover,
Another important object of the present invention is to provide a dissolution reduction device for waste synthetic resin that can smoothly transfer the synthetic resin inside the supply means, eliminate the trouble of disassembly, etc., and simplify maintenance.

[0016]

[Means for Solving the Problems] The waste synthetic resin dissolution reduction apparatus of the present invention has the following configuration in order to achieve the above-mentioned object. The solubility reduction device includes a waste synthetic resin supply means 1 and a heating solubility reduction means 2 that heats the waste synthetic resin fed from the supply means 1 to reduce the solubility. The supply means 1 includes a supply cylinder 3 and a supply cylinder 3.
The screw shaft 4 includes a screw shaft 4 extending in the axial direction and a driving means 5 for rotating the screw shaft 4. Furthermore, the heat-reducing means 2 includes a rotating member 7 that rotates relative to each other and pushes out the waste synthetic resin from the heat-reducing gap 6. The waste synthetic resin fed into the supply means 1 is supplied to the heating melt reducing means 2 by the rotating screw shaft 4, and is passed through the heating melt reducing gap 6 of the heating melt reducing means 2.
The structure is such that the solution is reduced and extruded.

Furthermore, the solubility reduction apparatus of the present invention is characterized by having the following configuration. (a) The supply cylinder 3 has a plurality of screw shafts 4 built therein. (b) The screw shaft 4 has spiral fins 8 on its surface.
has. (c) The plurality of screw shafts 4 have fins 8 with opposite pitches. (d) The plurality of screw shafts 4 are arranged parallel to each other with the fins 8 meshing with each other. (e) The plurality of screw shafts 4 are connected to a driving means 5 and rotated in mutually opposite directions. (f) The supply cylinder 3 is machined into a cylindrical shape that approaches the outer periphery of the fins 8 of the screw shaft 4. (g) A supply hopper 9 is connected to the supply cylinder 3.

[0018]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Examples of the present invention will be described below with reference to the drawings. However, the embodiments shown below are illustrative of a melt reducing device for embodying the technical idea of the present invention, and the melt reducing device of the present invention has different materials, shapes, structures, and arrangements of component parts. It is not specific to the structure below. Various changes can be made to the solute reduction device of the present invention within the scope of the claims.

Further, in order to make the claims easier to understand, this specification uses numbers corresponding to members shown in the examples as "claims" and "means for solving the problem". It is added to the members shown in the "Column". However, the members shown in the claims are by no means limited to the members of the embodiments.

The apparatus for reducing the dissolution of waste synthetic resin shown in the schematic cross-sectional views of FIGS. 1 and 2 includes a supply means 1 and a heating means 2 for reducing the dissolution.

The supply means 1 includes a supply cylinder 3, a screw shaft 4, and a motor serving as a drive means 5 for rotating the screw shaft 4.

The heating melt reducing means 2 includes a melt reducing cylinder 10, a rotating member 7 rotatably provided in the heat generating melt reducing opening 17 of the melt reducing device, and a moving table 12 to which the rotating member 7 is rotatably attached. , and position control means 15 for moving the movable table 12.

[0023] The supply cylinder 3 is arranged horizontally, and the solute reduction cylinder 10 is connected to its discharge side, so that the supply cylinder 3 and the solute reduction cylinder 10 are connected in series. The supply cylinder 3 is machined into a cylindrical shape and has two screw shafts 4 built therein. The inner surface of the supply cylinder 3 is machined to have an inner diameter approaching the outer peripheral edge of the fins 8 of the screw shaft 4. The gap between the inner surface of the supply cylinder 3 and the outer periphery of the fins of the screw shaft 4 is usually 0.1 to 30 mm.
, preferably adjusted to a range of 0.3 to 20 mm.

The supply cylinder 3 has an open upper surface, and a synthetic resin supply hopper 9 is connected to the opening. The supply hopper 9 is connected between the two screw shafts 4 so as to supply waste synthetic resin onto the two screw shafts 4. The two screw shafts 4 are rotatably arranged inside the supply cylinder 3. The two screw shafts 4 are rotated in opposite directions by a motor 4, and force-feed the synthetic resin charged into the supply hopper 9 to the melt reduction cylinder 10. A spiral fin 8 is provided on the surface of the screw shaft 4. The fins 8 have a spiral shape with mutually opposite pitches. The two screw shafts 4 are rotated with the fins 8 meshing with each other, and the synthetic resin in the supply hopper 9 is transferred to the melt reduction cylinder 10.

The two screw shafts 4 crush or cut the synthetic resin at the meshing portions of the fins 8, and efficiently force-feed the synthetic resin to the heat-reducing gap 6. The waste synthetic resin in the form of a long string, sheet, bag, or various shapes, which has been put into the supply hopper, is processed into a shape that can be efficiently rubbed in the heat-reduced gap and then transported.

[0026] The minimum gap between the fins in the mutually engaged parts is usually 10 mm or less, preferably 5 mm or less from the contact state.
Adjusted to a range of mm or less. More preferably, the minimum interval between the fins is adjusted to be approximately equal to or narrower than the maximum interval of the heat-reducing gap 6.

The two screw shafts 4 have gears 11 fixed to their upper ends that mesh with each other and rotate in opposite directions. One screw shaft 4 is connected to a motor, and both screw shafts 4 are rotationally driven by the motor. However, although not shown, it is also possible to connect and drive motors separately to the two screw shafts.

Although the supply means 1 shown in FIGS. 1 and 2 incorporates two screw shafts 4, the present invention can also use a supply means having three or more screw shafts. Further, in the melt reduction apparatus shown in the figure, the supply cylinder is arranged horizontally, but as shown in Figs. 3 to 5, it can also be arranged vertically or inclined. The vertical feed cylinder 3 carries waste synthetic resin from the feed hopper 9 connected to the side.
It can be scraped off from the side, taken in between the fins 8 and sent to the heat-reducing gap 6.

The vertical feed cylinder 3 connects to the side a feed hopper 9. The bottom surface of the supply hopper 9 is inclined downwardly toward the supply cylinder 3. The waste synthetic resin put into the supply hopper 9 is pressed against the side surface of the screw shaft 4 by its own weight, and the screw shaft 4 scrapes off the waste synthetic resin from the side surface and supplies it to the heat-reducing gap 6. The force with which the waste synthetic resin is pressed against the side surface of the screw shaft 4 can be adjusted by adjusting the slope with respect to the bottom surface of the supply hopper 9. When the bottom surface of the supply hopper 9 approaches the vertical direction, the force with which the waste synthetic resin is pressed against the screw shaft 4 becomes stronger, and on the contrary, when the bottom surface of the supply hopper 9 approaches the horizontal direction, the pressing force becomes weaker. The angle of inclination of the bottom of the supply hopper 9 with respect to the horizontal plane is usually adjusted to a range of 40 to 80 degrees, preferably 45 to 70 degrees.

The solubility reduction cylinder 10 heats the waste synthetic resin while rubbing it to reduce the solubility. The melt reduction cylinder 10 is
Waste synthetic resin is heated to reduce its solubility and discharged. The melt reducing cylinder 10 has an exothermic melt reducing opening 17 opened therein. The exothermic melt-reducing opening 17 has a tapered opening with a cross-sectional area increasing toward the opening end. This shape of exothermic melt-reducing opening 17
This method has the advantage that it can efficiently reduce the dissolution of waste synthetic resin, and that the heat generation state can be adjusted depending on the type and moisture content of the supplied waste synthetic resin.

The cross-sectional shape of the exothermic melt-reducing opening 17 is shown in FIG. As shown in this figure, the exothermic and melt-reducing opening 17 is provided with a plurality of grooves 14. The groove 14 is provided on the inner surface of the exothermic and melt-reducing opening 17 so as to extend in the axial direction. Groove 1
4, 5 to 50 strips are provided on the inner surface of the exothermic and melt-reducing opening 17. The depth and width of the groove 14 are designed to be in the range of 1 to 10 mm. The cross-sectional shape of the groove 14 may be semicircular as shown in FIG. 3, or rectangular or trapezoidal (not shown). In this way, the heat-generating melt-reducing opening 17 provided with the groove 14 can reduce slippage of the waste synthetic resin and efficiently generate heat by itself.

[0032] By the way, this melt reduction device ideally reduces the melt by completely melting the waste synthetic resin, but it is not necessarily necessary to completely melt the waste synthetic resin by heating it above the melting temperature. . This is because even if the waste synthetic resin is in a semi-molten state or a partially melted state, the dissolution can be sufficiently reduced.

A rotary member 7 is disposed coaxially with the exothermic melt-reducing opening 17 of the melt-reducing cylinder 10 . The rotating member 7 is shown in FIGS. 3 and 4. The rotating member 7 shown in these figures has four protrusions 13 extending in the axial direction on its surface. The protrusions 13 reduce the solubility by rubbing the waste synthetic resin sent into the heat-reducing gap, and forcibly discharge the reduced solubility. The protrusions 13 are inclined with respect to the axial direction of the rotating member 7, as shown in FIG. The angle of inclination determines the discharge state of the synthetic resin reduced in solubility in the heat-reduced gap. When the angle of inclination is large, the synthetic resin in the heat-reduced gap is quickly discharged. Therefore, the ability to reduce the dissolution of waste synthetic resin is increased. On the other hand, if the inclination angle is small, the passage time of the synthetic resin in the heat-reducing gap becomes long. Therefore, the waste synthetic resin can be sufficiently reduced in solubility at high temperatures. The inclination angle of the protruding strip 13 is adjusted to an optimum value in consideration of the processing capacity of the waste synthetic resin and the state of reduced solubility. The inclination angle is usually designed to be in the range of 1 to 15 degrees, preferably in the range of 2 to 10 degrees.

Further, the inclined protruding strip 13 forcibly discharges the synthetic resin from the heat-reducing gap when the rotating member 7 rotates. Therefore, as shown in FIG. 4, the direction of inclination of the protrusions 13 is designed such that when the rotating member 7 rotates, the synthetic resin is forcibly discharged from the heat-reduced gap.

Furthermore, FIG. 5 shows an enlarged cross-sectional view of the protruding strip 13.
It is shown in The protrusion 13 shown in this figure is the front side surface 13A.
The slope is different between the front side 13A and the rear side 13B, and the front side 13A is a slope with a gentle upward slope, and the rear side 13B is a slope with a gentle upward slope.
It has a steeper descending slope.

The front side surface 13A has a curved surface whose slope gradually becomes steeper. Preferably, the front side surface 13A of the protrusion has a curved surface having a predetermined radius of curvature. The length L of the inclined portion of the front side surface 13A of the protrusion is adjusted to an optimum value in consideration of the height H of the protrusion. Further, the height H of the protrusion gradually decreases toward the tip of the rotating member 7, and is designed to be 3 to 40 mm at the highest portion.

The rotating member 7 is connected to the tip of the screw shaft 4. The rotating member 7 is rotationally driven by a motor separate from the screw shaft 4. In order that the rotating member 7 and the screw shaft 4 can rotate at different rotational speeds, the tip of the screw shaft 4 is inserted into the center of the rotating member 7 so as to be rotatable and movable in the axial direction. Therefore,
A cylindrical hole is provided at the center of the rotating member 7, through which the tip of the screw shaft 4 can be inserted rotatably. The tip of the screw shaft 4 has a cylindrical shape that can be rotatably inserted into the hole of the rotating member 7.

The rotating member 7 and the screw shaft 4 are connected in a straight line. The rotating member 7 is supported by a moving table 12 so as to be movable in the axial direction. The rotating member 7 is
It is moved in the axial direction by a moving table 12. Therefore, the rotating member 7 is supported by the movable table 12.

The movable table 12 is movably set on a base. The movable table 12 is slidably mounted in a dovetail groove (not shown) provided on the base. The dovetail groove is provided to extend in the axial direction of the rotating member 7 and the screw shaft 4. The movable table 12 is moved in the axial direction by the position control means 15. When the rotating member 7 is inserted into the melt reduction cylinder 10 by the moving table 12, the heating melt reduction gap 6 becomes narrower. On the other hand, when the rotating member 7 is pulled out from the melt-reducing cylinder 10 by the moving stage 12, the heating melt-reducing gap 6 becomes wider. The stop position of the movable table 12 is adjusted to a position where the synthetic resin can be optimally reduced. When the heat-reducing gap 6 is narrowed, the heating temperature of the synthetic resin increases, and the rotational torque of the rotating member 7 increases. When the heat-reducing gap 6 is widened, the heating temperature is lowered, the rotational torque of the rotating member 7 is lowered, and a large amount of synthetic resin can be discharged.

The heating melt reduction means 2 shown in FIGS. 1 and 2 is as follows:
Since the synthetic resin is caused to self-heat to reduce its solubility, the solubility reduction cylinder 10 does not necessarily require a heating means such as a heater. However, by equipping this part with a heater, the waste synthetic resin can be heated and dissolved more efficiently.

The melt reduction device shown in the above figures has two rotating members 7 disposed coaxially with two screw shafts 4. However, it is also possible to transport the waste synthetic resin using a plurality of screw shafts, collect it in one place, and use a single rotating member to perform friction and reduce solubility.

[0042]

[Effect of the invention] The dissolution reduction device for waste synthetic resin of this invention has the following features:
It has the advantage that synthetic resins of various shapes can be efficiently rubbed and dissolved in the heat-reduced gap without using a spline shaft to cut the waste synthetic resin into a predetermined shape. The reason for this is that the waste synthetic resin from the supply hopper is forced into the heating and melt-reducing gap using multiple screw shafts whose fins engage with each other. The synthetic resin fed from the supply hopper between the fins of the screw shaft is crushed into a thin layer at the meshing portion of the fins, or is cut and press-fitted into the heat-reduced gap. The synthetic resin in this shape and press-fitted into the heat-reducing gap is efficiently rubbed in the narrow heat-reducing gap. This is because they have a shape that makes it easy for them to rub against each other in the heat-reduced gap. For this reason, the waste synthetic resins of various shapes put into the supply hopper are shaped to be easily rubbed in the heat-reduced gap by the screw shaft in which the fins engage with each other, and are efficiently rubbed, reduced, and discharged. For this reason, the solubility reduction device of the present invention has the advantage of being able to charge various types of waste synthetic resins into the supply hopper and reduce the solubility by efficiently rubbing them in the heat-reducing gap.

Furthermore, the solubilization apparatus of the present invention has the advantage of being able to efficiently reduce the solubility of the waste synthetic resin supplied to the supply hopper without deteriorating it at high temperatures. Unlike a spline shaft, the screw shaft does not scrape off the synthetic resin in the supply hopper at once with a protrusion extending in the axial direction, but instead has spiral fins that are inclined with respect to the transport direction. This is because the waste synthetic resin placed in the hopper is taken in in order by scraping it off from the bottom. The synthetic resin supplied in a fixed amount from the supply means is heated to a constant temperature in the heat-reducing gap and is discharged without deteriorating at high temperatures. The amount of heat generated in the heat-reduced gap changes depending on the amount of synthetic resin supplied. When a large amount of synthetic resin is supplied to the heat-reduced gap at one time, the synthetic resin is strongly rubbed, generates a large amount of heat, and is heated to a high temperature. On the other hand, when the amount of synthetic resin supplied decreases, the pressure with which the synthetic resin is rubbed becomes low, the amount of heat generated decreases, the heating temperature becomes low, and the synthetic resin cannot be sufficiently melted and dissolved. Further, when a large amount of synthetic resin is supplied to the heat-reduced gap, the rotational torque of the rotating member increases rapidly, and the motor temporarily becomes extremely overloaded. If a large-capacity motor is used to rotate a rotating member when excessive torque is applied, the motor will run lightly under normal operating conditions, reducing work efficiency. For this reason, although it is difficult to supply a fixed quantity of waste synthetic resin to the supply hopper, it is extremely important to supply a fixed quantity to the heating and dissolution gap. The melt reduction device of the present invention achieves this with an extremely simple structure in which a spline shaft is omitted and a plurality of screw shafts are provided side by side with their fins interlocking. By using a small-capacity motor, we can efficiently reduce the solubility of waste synthetic resin while preventing high-temperature deterioration.

[Brief explanation of drawings]

[Fig. 1] Cross-sectional view of a waste synthetic resin dissolution reduction device showing an embodiment of the present invention

[Fig. 2] Cross-sectional view of a waste synthetic resin dissolution reduction device showing an embodiment of the present invention

[Figure 3] Cross-sectional view of the melt reduction cylinder and rotating members

[Figure 4] Side view of rotating member

[Figure 5] Enlarged sectional view of main parts of melt reduction cylinder and rotating member

[Figure 6] Cross-sectional view showing an example of a conventional solute reduction device

[Explanation of symbols]

1... Supply means 2
…Heating melt reduction means 3…Supply cylinder
4...Screw shaft 5...Driving means
6... Heating melt reduction gap 7... Rotating member
8... Fin 9... Supply hopper 10... Melt reduction cylinder 11... Gear
12...Moving table 13...Convex strip
14...Groove 15...Position control means
16... Spline shaft 17... Exothermic melt reduction opening

Claims (1)

[Claims] 1. A supply means (1) for supplying waste synthetic resin, and a heating and dissolving means (2) for heating and reducing the solubility of the waste synthetic resin fed from the supply means (1), the supply means (1) includes a supply cylinder (3), a screw shaft (4) disposed extending in the axial direction inside the supply cylinder (3), and a drive means (4) for rotating the screw shaft (4). Furthermore, the heating melt reduction means (2) has a rotating member (7) that rotates relative to each other and pushes out the waste synthetic resin from the heating melt reduction gap, ) is supplied to the heating melt reducing means (2) by the rotating screw shaft (4), and is reduced in melt melt in the heating melt reducing gap (6) of the heating melt reducing means (2). An apparatus for reducing the solubility of waste synthetic resin, which is configured to be extruded and is characterized by having the following configuration. (a) The supply cylinder (3) has a plurality of screw shafts (4) built therein. (b) The screw shaft (4) has spiral fins (8) on its surface. (c) The plurality of screw shafts (4) have fins (8) with opposite pitches. (d) The multiple screw shafts (4) have fins (8
) are arranged parallel to each other in an interlocking state. (e) The plurality of screw shafts (4) are driven by a driving means (
5) and are rotated in opposite directions. (f) The supply cylinder (3) is connected to the screw shaft (4
) is machined into a cylindrical shape that approaches the outer periphery of the fin (8). (g) The supply cylinder (3) has a supply hopper (
9) are connected.