KR20100083937A - The waste plastic materials extruding machine for cooling apparatus has a antipollution function - Google Patents

Abstract

PURPOSE: A cooling device with an antipollution function for a waste resin extruding machine is provided to ensure smooth cooling and transfer of resin through rollers. CONSTITUTION: A cooling device with an antipollution function for a waste resin extruding machine comprises cooling rollers(210), a blower unit(230), and a driving unit(220). The cooling roller has a cooling pipe(212) through which coolant circulates to help cooling resin discharged from a forming head(150). The blower unit is formed in one side of the cooling rollers and blows cold air to rapidly cool resin. The driving part drives the cooling rollers.

Description

The waste plastic materials extruding machine for cooling apparatus has a antipollution function}

The present invention relates to a cooling device for a waste resin extruder, and in particular, to prevent the contamination of the resin to be melted and discharged for reuse, and at the same time to cool the resin quickly and easily by using a refrigerant and wind so that there is no environmental pollution. A cooling device for waste resin extruders having a function.

In general, since thermoplastic resins can be repeatedly formed by applying heat, products made of thermoplastic resins are recycled through recycling after use.

Accordingly, in order to reduce resources and protect the environment, a conventional extruder which melts the waste resin, which is a regeneration device of thermoplastic resin, by applying pressure and heat to form a reusable form is required. Extruders are being presented.

As shown in FIG. 1, a conventional waste resin recycling extruder includes a hopper 110 for introducing waste resin pulverized to a predetermined size and a heater 120 for melting waste resin introduced from the hopper 110. ), A screw 140 driven by a motor 130 as a power source to transfer the molten resin, and a molten resin mixed and extruded and moved by the screw 140 into a plurality of long pellets. The molding head 150 to be molded, the cooling device 160 for cooling the resin 180 discharged through the molding head 150 and the resin 180 cooled through the cooling device 160 to a predetermined length It comprises a cutter 170 to cut.

However, since the cooling device 1600 used in the conventional extruder 100 cools the resin 180 that is extruded in a pellet shape using the water tank 161 containing the cooling water 162, the molten resin 180 Since the coolant 162 is contaminated because harmful substances are eluted, there is a problem in that a high cost is required to purify the contaminated coolant 162.

In addition, when the contaminated cooling water 162 used for cooling the molten resin 180 is discarded into a sewer without purification, there is a problem such as accelerating the pollution of the water environment.

Accordingly, the present invention has been made to solve the above problems, an object of the present invention is to allow the cooling of the melt-extruded resin to be cooled while passing naturally through the cooling roller for transporting, without immersion in water directly, so that the smooth resin It is to provide a cooling device for waste resin extruder to prevent water pollution by cooling.

It is another object of the present invention to provide a cooling device for a waste resin extruder in which regenerated resin extruded through a forming head is cooled and conveyed without sticking to each other while being transported through a cooling roller.

The present invention for achieving the above object is a screw having a hopper for injecting waste resin, a heater for melting waste resin introduced from the hopper, a screw having a motor as a power source to transfer the molten resin, and is moved by the screw In a waste resin extruder comprising a molding head for extruding resin into pellets and a cooling device for cooling the resin discharged from the molding head, the cooling device is a resin discharged from the molding head. A cooling roller having a cooling pipe through which the refrigerant circulates for easy cooling; A blower formed on one side of the cooling roller to achieve more rapid and reliable cooling of the resin to be cooled and transported; A driving unit for driving the cooling roller; Characterized in that comprises a.

The cooling roller is characterized in that a plurality of guide jaws for separating accommodation is formed to prevent each resin discharged from the molding head from sticking together.

The blower is characterized by consisting of a blower forcibly sending the cold air discharged from the air conditioner, and a cold air distribution pipe for uniformly supplying the cold air forcibly transferred by the blower to each resin transferred to the upper portion of the cooling roller. .

The driving unit may include a motor as a power source, a plurality of sprockets connected to a shaft of the motor and a cooling pipe of the cooling roller and formed of a single or double, and a plurality of chains connected to the respective sprockets.

As described above, the present invention allows the cooling of the resin that is melt-extruded and regenerated to be cooled while naturally passing through a roller for transport without directly immersing in water, thereby preventing pollution of the water environment through smooth cooling of the resin.

The cooling apparatus of the present invention can achieve the effect of allowing the recycled resin extruded through the forming head to be cooled and conveyed without sticking to the rollers and to each other.

Hereinafter, a preferred embodiment of the cooling device for waste resin extruder having an environmental pollution prevention function according to the present invention will be described in more detail with reference to the accompanying drawings.

Here, in all the drawings below, the components having the same functions are not repeated, using the same reference numerals, and the following terms are defined in consideration of functions in the present invention, which are inherently commonly used. It should be interpreted as meaning.

2 is an exploded perspective view showing a cooling apparatus according to a preferred embodiment of the present invention, Figure 3 is a perspective view showing a combined state of Figure 2, Figure 4 is a state diagram of the use of the cooling apparatus according to a preferred embodiment of the present invention.

As shown in FIG. 2 to FIG. 4, the present invention is roughly composed of a cooling roller 210, a driving unit 220, and a blowing unit 230.

The cooling roller 210 is formed of a cylindrical shape using a metal material to facilitate thermal conductivity quickly and to prevent the resin 180 from adhering, and the outer circumference is discharged in the form of a plurality of strands from the forming head 150. A plurality of guide jaws 211 are formed for separate accommodation so as to prevent the resin 180 from sticking together.

In addition, a cooling pipe 212 for cooling each resin 180 discharged from the forming head 150 is formed in the inner axial direction of the cooling roller 210, and is provided at both ends of the cooling pipe 212. Is formed such that the refrigerant circulation pipe 213 for supply circulation of the liquid refrigerant such as ammonia or water having a low boiling point communicates with the cooling pipe 212 of the other cooling roller 210.

Here, a cooling device (not shown) is connected to one end of the refrigerant circulation pipe 213 to maintain the refrigerant supplied to the cooling pipe 212 at a constant low temperature even after heat exchange with the molten resin 180.

Such a cooling device is conventional and a detailed description thereof will be omitted.

In addition, the cooling pipe 212 is mounted on a bearing 241 formed on the roller support frame 240 to facilitate rotation.

In this case, the cooling pipe 212 is formed to rotate together with the cooling roller 210, but the refrigerant circulation pipe 213 is stopped without rotation to form a supply of the refrigerant to the cooling pipe 212. As described above, the configuration in which one member rotates and the other member connected to the rotating member is stopped is generally applied, and a detailed description thereof will be omitted.

Here, the cooling pipe 212 may be configured to stop without rotating with the cooling roller 210. For example, the outer side of the cooling pipe 212 is wrapped in a bearing (not shown) to rotate only the cooling roller 210, the cooling pipe 212 is configured to be fixed.

The driving unit 220 is connected to a motor 221 as a power source, a shaft of the motor 221 and a cooling pipe 212 of the cooling roller 210, and a plurality of sprockets formed in a single or double. 222, and a plurality of chains 223 connected to each of the sprockets 222.

The sprocket 222 is fitted to each of the cooling pipes 212 formed to be integrally rotatable with the shaft of the motor 221 and the plurality of cooling rollers 210, and the chain 223 is attached to the sprocket 222. This is mounted so that the plurality of cooling rollers 210 are interlocked when the motor 221 is driven.

The blower 230 may include a blower 231 forcibly sending cold air discharged from an air conditioner (not shown), which is one of devices generating cold air, and cold air forcibly transferred by the blower 231. It consists of a cold air distribution pipe 232 to evenly supply to each of the resin 180 is transferred to the upper portion of the cooling roller (210).

The blower 230 is integrally fixed to the roller support frame 240 of the cooling device 200, or by installing a separate frame (not shown) on one side of the cooling device 200, cold air discharge grill of the air conditioner It can also be fixed so that it can be positioned as the front part.

Here, the apparatus for generating the cold wind may be formed of various apparatuses for generating cold wind, such as a cold air apparatus for storing ice and providing cold wind as well as air conditioner.

The cold air distribution pipe 232 has a cold air inlet 232a having the same size as the diameter of the blower 231, and the cold air inlet 232a to discharge the cold air downward to the upper surface of the plurality of cooling rollers 210, respectively. It is formed of a plurality of cold air outlets 232b having a small diameter.

The cold air distribution pipe 232 is evenly distributed so that the cold air forced from the blower 231 is not concentrated in one place to achieve a more effective cooling of the molten resin 180.

The operation state of the present invention having the above-described structure will now be described.

First, after removing the foreign matter from the waste resin in the hopper 110 of the extruder 100 is equipped with a cooling device 200 according to the present invention, washing and drying to grind into a predetermined size to operate the extruder 100 The waste molten resin 180 introduced from the hopper 110 is melted by the heater 120 while being pressurized and mixed at a constant pressure.

At the same time, the molten resin 180 is mixed and conveyed by the screw 140 coupled to the motor 130 as the power source.

The molten resin 180 moved by the screw 140 is extruded through the forming head 150 to be discharged in a plurality of pellets.

Subsequently, the resin 180 molded and discharged in a pellet shape is transported while being separately received by the cooling roller 210 of the cooling apparatus 200.

At this time, the cooling roller 210 is rotated by the sprocket 222 and the chain 223 to be interlocked by the drive motor 221, the resin 180 is discharged by the refrigerant circulating in the cooling pipe 212 ) And a plurality of guide jaws 211 protruding from the outer circumference to separate and receive a plurality of resins 180 discharged from the forming head 150 to prevent them from sticking to each other.

Next, the resin 180 transferred through the cooling roller 210 is more reliably cooled by the operation of the blower 230.

That is, when the blower 231 of the blower 230 is supplied to supply cold air through the cold air inlet 232a of the cold air distribution pipe 232, the cold air is formed to be positioned above the plurality of cooling rollers 210. As it is discharged to the cold air outlet 232b, the resin 180 transferred by the cooling roller 210 is more surely cooled.

Subsequently, the resin 180 that is cooled and transported is cut into a predetermined size by a cutter (not shown) installed at one end of the cooling device 200, and then packaged into a reused product.

By continually repeating these actions, it is possible to quickly and easily cool down the resin to be melted and regenerated without using the cooling water, thereby preventing water pollution, thereby increasing the cost of installing a purification device for water purification. Can be saved.

In addition, since the resin is cooled and conveyed without sticking to each other while passing through the cooling roller, it is possible to bring about an improvement in quality and a rapid and easy cooling conveyance to improve productivity.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various changes, modifications, and changes to other exemplary embodiments may be made without departing from the technical spirit of the present invention. It will be apparent to those skilled in the art to which the invention pertains.

1 is a view schematically showing a conventional waste resin extruder.

2 is an exploded perspective view showing a cooling apparatus according to a preferred embodiment of the present invention.

3 is a perspective view illustrating a coupling state of FIG. 2.

4 is a state diagram of use of the cooling apparatus according to a preferred embodiment of the present invention.

[Description of Reference Numerals]

200: cooling device 210: cooling roller

211: guide jaw 212: cooling pipe

213: refrigerant circulation tube 220: drive unit

221 motor 222 sprocket

223 chain 230 blower

231: blower 232: cold air distribution pipe

232a: cold air inlet 232b: cold air inlet

Claims (4)

A plurality of pellets are used to form a plurality of pellets in which a hopper for introducing waste resin, a heater for melting waste resin introduced from the hopper, a screw having a motor as a power source for transferring the melted resin, and a resin moved by the screw are formed. In the waste resin extruder comprising a molding head for extrusion molding and a cooling device for cooling the resin discharged from the molding head, The cooling device includes a cooling roller having a cooling pipe in which a refrigerant is circulated for easy cooling of the resin discharged from the molding head; A blower formed on one side of the cooling roller to send cold air to achieve more rapid and reliable cooling of the resin to be cooled and transported; A driving unit for driving the cooling roller; Cooling apparatus for waste resin extruder having a pollution prevention function, characterized in that comprises a. The cooling roller of claim 1, wherein the cooling roller is provided with a plurality of guide jaws for separating accommodation to prevent each resin discharged from the molding head from sticking to each other. Device. The air blower of claim 1, wherein the blower comprises a blower forcibly sending cold air discharged from the air conditioner, and a cold air distribution pipe to uniformly supply the cold air forcibly transferred by the blower to each resin transferred to the upper portion of the cooling roller. Cooling apparatus for waste resin extruder having a pollution prevention function, characterized in that made. The method of claim 1, wherein the drive unit is composed of a motor that is a power source, a plurality of sprockets connected to the shaft of the motor and the cooling pipe of the cooling roller and formed in a single or double, and a plurality of chains connected to the respective sprockets. Cooling apparatus for waste resin extruder having a pollution prevention function, characterized in that.

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