WATER REGULATED TEMPERATURE CONTROLLED RESIN DRYING

Abstract

Apparatus and method for drying thermoplastic resin prior to molding into plastic parts comprises a continuous loop liquid circuit for furnishing liquid at a prescribed temperature to a mold in which the plastic parts are fabricated; a continuous loop air circuit for passing heated dry air through a hopper containing the thermoplastic resin thereby drying the thermoplastic resin to a prescribed level of dryness; and a coupling thermally connecting the two circuits for heat transfer from the liquid to the drying air; the liquid is selected from the group comprising water and ethylene glycol; microprocessor control facilitates generation and retention of custom water temperature and resin dryness/temperature optionally based on machine learning principles.

Claims

1. Apparatus for drying thermoplastic resin prior to molding into plastic parts, comprising: a. a continuous loop liquid circuit for furnishing liquid at a prescribed temperature to a mold in which the plastic parts are fabricated; b. a continuous loop air circuit for passing heated dry air through a hopper containing the thermoplastic resin thereby drying the thermoplastic resin to a prescribed level of dryness; c. a coupling thermally connecting the two circuits for heat transfer from the liquid to the drying air.

2. Apparatus of claim 1 wherein the liquid is selected from the group comprising water and ethylene glycol.

3. A method for drying thermoplastic resin prior to molding into plastic parts while maintaining temperature of the mold within a preselected range, comprising: a. a microprocessor; b. an a continuously circulating loop liquid circuit, furnishing liquid within a temperature range specified by the microprocessor to the plastic part mold; c. an a continuously circulating loop air circuit, passing heated dry air through a hopper containing the thermoplastic resin thereby drying the thermoplastic resin to a level of dryness prescribed by the microprocessor.

4. The method of claim 3 further comprising thermally coupling the circuits for heat transfer from the liquid to the drying air.

5. The method of claim 3 wherein the liquid is selected from the group comprising water and ethylene glycol.

6. Apparatus of claim 1 further comprising a. a plurality of continuous loop liquid circuits for furnishing liquid at prescribed temperatures to a plurality of molds in which the plastic parts are fabricated; and b. couplings thermally connecting the liquid loop circuits to the air circuit for heat transfer from the liquid to the air.

Description

[0014] FIG. 1 is a schematic flow chart illustrating operation of a desiccant wheel dryer with an integral process temperature control unit water circuit according to the invention.

[0015] In FIG. 1:

[0016] 10 is a water supply.

[0017] 12 is a water return.

[0018] 14 is a mixing chamber.

[0019] 16 is a water pump.

[0020] 18 is a water heater.

[0021] 20 is a mold of an injection molding machine.

[0022] 22 is a solenoid water cooling valve.

[0023] 24 is a regeneration heater.

[0024] 26 is a regeneration blower.

[0025] 28 is a regeneration filter.

[0026] 30 is a process filter.

[0027] 32 is a process fan or blower.

[0028] 34 is a process heater.

[0029] 36 is a material drying hopper.

[0030] 38 is a post process water to air heat exchanger.

[0031] 40 is an entire desiccant wheel.

[0032] 42 is a regeneration portion of the desiccant wheel.

[0033] 44 is a process portion of the desiccant wheel.

[0034] 46 is a cooling air portion of the desiccant wheel.

[0035] Referring to FIG. 1, cold water enters at point 10, goes through mixing chamber 14, water pump 16, water heater 18, then through mold 20 of an injection molding machine and returns to mixing chamber 14, traveling all the while in a closed loop. Temperature sensors monitor the temperature of water going into the mold. If the water temperature is too cold, water heater 18 is energized; if the water temperature is too hot, solenoid water cooling valve 22 is opened to permit hot water to drain. This hot water is replenished from a colder water supply that lowers the temperature of the water going into mold 20 of an injection molding machine.

[0036] Still referring to FIG. 1, moist process air leaves material hopper 36, goes through process filter 30 and post process air cooler 38. After passing through pump 32, this moist process air splits. One portion passes through process portion 44 of the desiccant wheel 40 where it becomes dry and rejoins the air leaving hopper 36 going to post-process water-to-air heat exchanger 38. The other portion passes through process heater 34 and returns to material hopper 36 to remove additional moisture from the plastic pellets. Post-process air cooler (water-to-air heat exchanger) 38 cools the air and allows water vapor in the air to be more rapidly adsorbed on molecular sieve material and allows gaseous volatiles to condense (so as not to contaminate the desiccant) on the process portions of desiccant wheel 40. A supply of cool water is necessary for operation of the post process air cooler 38. The desiccant wheel 40 rotates slowly to allow water vapor to be absorbed and regenerated in a continuous process.

[0037] Still referring to FIG. 1, the most air is split after process blower 32. A portion of the air cools desiccant wheel 40 and rejoins the moist process air that is leaving drying hopper 36 before entering process filter 30.

[0038] Yet still referring to FIG. 1, the input ambient air is filtered using regeneration filter 28, then is pumped by fan or blower 26, then is heated by regeneration heater 24. This hot regeneration air excites water bound to the desiccant and removes water vapor from the regeneration portion 42 of the desiccant wheel 40. This wet, hot regeneration air is vented to atmosphere.

[0039] FIG. 2 is a schematic flow chart illustrating operation of a dual bed pellet desiccant dryer with an integral water process temperature control unit circuit according to the invention.

[0040] In FIG. 2:

[0041] 110 is a water supply.

[0042] 112 is a water return.

[0043] 114 is a mixing chamber.

[0044] 116 is a water pump.

[0045] 118 is a water heater.

[0046] 120 is a mold of an injection molding machine.

[0047] 122 is a solenoid water cooling valve.

[0048] 124 is a regeneration heater.

[0049] 126 is a regeneration blower.

[0050] 128 is a regeneration filter.

[0051] 130 is a process filter.

[0052] 132 is a process fan or blower.

[0053] 134 is a process heater.

[0054] 136 is a material drying hopper.

[0055] 138 is a post process water to air heat exchanger.

[0056] 150 is a process air precooler.

[0057] 152 is a rotary valve assembly.

[0058] 154 is a desiccant pellet bed supplying dry air to the process.

[0059] 156 is a desiccant pellet bed undergoing regeneration.

[0060] Referring to FIG. 2, cold water enters at point 110, goes to mixing chamber 114, water pump 116, water heater 118, then through the mold 120 of an injection molding machine, and returns to mixing chamber 114, traveling all the while in a closed loop. Temperature sensors monitor the temperature of water going to the mold. If water temperature is too low, the water heater is energized, if the water temperature is too high, solenoid water cooling valve 122 is opened to permit hot water to drain. This hot water is replenished from a colder water supply that lowers temperature of water going into mold 120.

[0061] Still referring to FIG. 2, moist process air leaves material hopper 136, goes through post process air cooler 138 while allowing gaseous volatiles to condense (so as not to contaminate the desiccant) and then through process filter 130. This moist air is pumped by blower 132 through a rotary valve assembly 152 where the moist process air is diverted to the desiccant pellet bed supplying dry air to process 154 (the desiccant pellet bed) where the process air is optionally cooled in a process air pre-cooler 150 prior to being heated by process heater 134, if low process temperatures are required. Pre-cooler 150 eliminates the temperature spike of the process air when rotary valve 152 is shifted and a freshly regenerated desiccant bed 154 or 156 comes on line. This temperature spike may cause bridging of the material in hopper 136 if the material melts at lower temperatures.

[0062] Yet still referring to FIG. 2, ambient air is filtered by regeneration filter 128, then is pumped by blower 126, then is heated with regeneration heater 124 where the heated ambient air is diverted with rotary valve 152 to the desiccant pellet bed 156 undergoing regeneration. This hot regeneration air excites water bound to the desiccant and removes water vapor from desiccant bed 156. This wet, hot regeneration air is diverted by rotary valve 152 and vented to atmosphere.

[0063] FIG. 3 is a schematic flow chart illustrating operation of a membrane dryer with an integral water process temperature control unit circuit according to the invention

[0064] In FIG. 3:

[0065] 210 is a water supply

[0066] 212 is a water return

[0067] 214 is a mixing chamber

[0068] 216 is a water pump

[0069] 218 is a water heater

[0070] 220 is an injection mold

[0071] 222 is a solenoid water cooling valve

[0072] 230 is a process filter

[0073] 234 is a process heater

[0074] 236 is a material drying hopper

[0075] 260 is a 1 micron coalescing air filter

[0076] 262 is a 0.01 micron coalescing air filter

[0077] 264 is a compressed gas membrane air dryer

[0078] 266 is a venturi air amplifier

[0079] 268 is a secondary process heater

[0080] Referring to FIG. 3, cold water enters at point 210, goes to mixing chamber 214, water pump 216, water heater 218, then through the mold of an injection molding machine and returns to mixing chamber 214, all the while traveling in a closed loop. Temperature sensors monitor the temperature of water going to the mold. If the water temperature is too low, the heater is energized, if the temperature is too high, solenoid water cooling valve 222 is opened to permit hot water to drain. This hot water is replenished from a colder water supply that lowers the temperature of the water going to mold 220.

[0081] Still referring to FIG. 3, compressed air is supplied to the drying circuit and is filtered with a preferably 1 micron coalescing air filter 260 and with a preferably 0.01 micron coalescing air filter 262. The compressed air is split into two portions, one portion flowing to compressed gas membrane dryer 264, where the air is dried, then through process heater 234, where the dried air is heated, then to hopper 236 where the heated, dried air passes over the resin pellets to be dried. A second portion of the compressed air goes to Venturi air amplifier 266 where the compressed air mixes with and invades flow of moist return process air. The resulting air stream is reheated by secondary process heater 268 and enters the center of hopper 236 where this air pre-dries the resin material, and is recirculated through process filter 230 and air amplifier 266 in a continuous loop.

[0082] FIG. 4 is a flow chart similar to FIG. 1, using the same item numbering scheme and illustrating operation of a desiccant wheel dryer in combination with multiple integral water temperature control unit circuits which heat the cavity and core sections of the mold of an injection molding machine.