CN218019552U - Double-bucket energy-saving drying system for plastic raw materials - Google Patents

Abstract

The utility model discloses a double-bucket energy-saving drying system for plastic raw materials, which relates to the technical field of drying equipment, and comprises an equipment main body, wherein a supporting base is installed at the lower end of the equipment main body, a control box is arranged at the upper end of the equipment main body, a touch display screen is installed at the upper end of the control box, a first hopper is installed at the upper end of the supporting base, a second hopper is installed at the upper end of the first hopper, a material suction machine is installed at the upper end of the equipment main body, a first pipe is installed at one side of the material suction machine, a tapping device is installed at one end of the first pipe, a second pipe is installed at one side of the tapping device, and a communicating pipe is connected with one side of the second hopper; in the use of the equipment main body, the suction fan, the electric heating tube and the pressurizing fan are used, so that the plastic granules are dried through the first hopper and the second hopper, the plastic granules are dried conveniently, and the drying efficiency is improved.

Description

Double-bucket energy-saving drying system for plastic raw materials

Technical Field

The utility model relates to a drying equipment technical field specifically is an energy-conserving drying system of twin-bucket of plastic raw materials.

Background

The drying system is a device for drying plastic granules before injection molding; but current drying system has certain drawback in the use, and in equipment main part use, the moisture of plastic pellet surface needs to be dried, and it is hard to waste time and energy to dry, can't carry out hot-blast secondary recycle, causes thermal loss easily, reduces its drying efficiency, the subsequent injection moulding of plastic pellet of being not convenient for, and for this reason, the staff in this field has provided the energy-conserving drying system of two buckets of a plastic raw materials.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art, the utility model provides an energy-conserving drying system of twin-bucket of plastic raw materials has solved the problem that above-mentioned background art provided.

In order to achieve the above purpose, the utility model discloses a following technical scheme realizes: the utility model provides a two energy-conserving drying system of fill of plastic raw materials, includes the equipment main part, the support base is installed to the lower extreme of equipment main part, equipment main part upper end is provided with the control box, touch-control display screen is installed to the upper end of control box, support the upper end of base and install the hopper No. one, no. two hoppers are installed to the upper end of hopper No. one, the auto sucking machine is installed to the upper end of equipment main part, no. one pipe is installed to one side of auto sucking machine, no. two pipes are installed to the one end of No. one pipe, no. two pipes are installed to one side of tap, one side of No. two hoppers is connected with communicating pipe, the electrothermal tube is installed to one side of communicating pipe, the suction fan is installed to the upper end of electrothermal tube, one side surface mounting of suction fan has the filter core, the outside of No. two hoppers is provided with the connection support tube, the upper end of connection support tube is installed the pressurization fan, one side of pressurization fan is connected with the recovery tube, one side of No. two hoppers is provided with the discharge gate, the upper end of No. two hoppers is provided with the gas vent.

As a further technical scheme of the utility model, be fixed connection between equipment principal and the support base, the support base is the rectangle structure, be fixed connection between equipment principal and the control box, be electric connection between control box and the touch-control display screen, the touch-control display screen is the rectangle structure, support fixed connection between base and the hopper.

As a further technical scheme of the utility model, the inside of a hopper and No. two hoppers is linked together, the volume of No. two hoppers is greater than the volume of a hopper, be electric connection between control box and the auto sucking machine, be linked together between a pipe and the shunting ware, be linked together between shunting ware and No. two pipes, be linked together between No. two pipes and No. two hoppers.

As a further technical scheme of the utility model, be linked together between No. two hoppers and the communicating pipe, no. two hoppers and communicating pipe are connected through the welding, be linked together between communicating pipe and the electrothermal tube.

As a further technical scheme of the utility model, be electric connection between electrothermal tube and the touch-control display screen, be fixed connection between electrothermal tube and the suction fan, be electric connection between suction fan and the touch-control display screen, filter and connect for rotating between core and the suction fan, filter the core and play the filter effect.

As a further technical scheme of the utility model, be linked together between joint stay tube and a hopper, be fixed connection between joint stay tube and a hopper, joint stay tube is the hollow circular cylinder structure, be fixed connection between joint stay tube and the forced draught fan.

As a further technical scheme of the utility model, be electric connection between booster fan and the touch-control display screen, the both ends of recovery tube are linked together respectively with between No. two hoppers and the booster fan, and the recovery tube is heat-resisting material.

As the utility model discloses further technical scheme, the discharge gate is the hollow circular cylinder structure, be linked together between discharge gate and the hopper, discharge gate and a hopper connect through the welding, the discharge gate is metallic structure.

As a further technical scheme of the utility model, the gas vent is located the top edge of a hopper, be linked together between gas vent and a hopper, the gas vent is the curved column structure of cavity.

Advantageous effects

The utility model provides a two fill energy-conserving drying system of plastic raw materials. Compared with the prior art, the method has the following beneficial effects:

a double-hopper energy-saving drying system for plastic raw materials is characterized in that when the drying system is used, a user firstly starts a material suction machine through a touch display screen, and plastic particles are sucked into a second hopper through the material suction machine; secondly, the electric heating tube is started through the touch display screen, then the suction fan is started, and hot air of the electric heating tube is infused into the second hopper through the communicating tube; the heated hot gas is recycled, the hot gas is sent to the pressurizing fan again through the recycling pipe, and the pressurizing fan dries the plastic particles in the first hopper again through the recycled hot gas; the plastic particles are heated for the second time in the first hopper after being heated for the first time in the second hopper, so that the moisture of the plastic particles can be fully dried; the steam of the inside second time utilization of last No. hopper discharges after through gas vent or discharge gate unloading, and in the drying system use, the stoving of the plastic pellet of being convenient for improves drying efficiency.

Drawings

FIG. 1 is a schematic structural diagram of a dual-hopper energy-saving drying system for plastic raw materials;

FIG. 2 is another perspective view of a twin-bucket energy-saving drying system for plastic materials;

FIG. 3 is an enlarged view of A in FIG. 2 of a twin-bucket energy-saving drying system for plastic materials;

FIG. 4 is a side view of a dual hopper energy efficient drying system for plastic materials;

FIG. 5 is a rear view of FIG. 4 of a dual hopper energy efficient drying system for plastic materials;

FIG. 6 is a flow diagram of a dual hopper energy efficient drying system for plastic materials.

In the figure: 1. an apparatus main body; 2. a support base; 3. a control box; 4. a touch display screen; 5. a first hopper; 6. a second hopper; 7. a material suction machine; 8. a first pipe; 9. a tap; 10. a second pipe; 11. a communicating pipe; 12. an electric heating tube; 13. a suction fan; 14. a filter element; 15. connecting the supporting tube; 16. a booster fan; 17. a recovery pipe; 18. a discharge port; 19. and (7) an exhaust port.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-6, the present invention provides a technical solution of a twin-bucket energy-saving drying system for plastic materials: a double-hopper energy-saving drying system for plastic raw materials comprises an equipment main body 1, a supporting base 2 is installed at the lower end of the equipment main body 1, a control box 3 is arranged at the upper end of the equipment main body 1, a touch display screen 4 is installed at the upper end of the control box 3, a hopper 5 is installed at the upper end of the supporting base 2, a hopper 6 is installed at the upper end of the hopper 5, a material suction machine 7 is installed at the upper end of the equipment main body 1, a first pipe 8 is installed at one side of the material suction machine 7, a tapping device 9 is installed at one end of the first pipe 8, a second pipe 10 is installed at one side of the tapping device 9, a communicating pipe 11 is connected to one side of the second hopper 6, an electric heating pipe 12 is installed at one side of the communicating pipe 11, a suction fan 13 is installed at the upper end of the electric heating pipe 12, a filter core 14 is installed on the outer surface of one side of the suction fan 13, a connecting support pipe 15 is arranged on the outer side of the second hopper 6, a pressurizing fan 16 is installed at the upper end of the connecting support pipe 15, a recovering pipe 17 is connected to one side of the pressurizing fan 16, a discharge port 18 is arranged at one side of the second hopper 6, and a discharge port 18 is arranged at the upper end of the second hopper 6, and a discharge port 19 is arranged at the upper end of the hopper 19.

Referring to fig. 1-4, further, the main body 1 is fixedly connected to the supporting base 2, the supporting base 2 is of a rectangular structure, the main body 1 is fixedly connected to the control box 3, the control box 3 is electrically connected to the touch display screen 4, the touch display screen 4 is of a rectangular structure, the supporting base 2 is fixedly connected to the first hopper 5, the first hopper 5 is communicated with the second hopper 6, the volume of the second hopper 6 is larger than that of the first hopper 5, the control box 3 is electrically connected to the suction machine 7, the first pipe 8 is communicated with the tap 9, the tap 9 is communicated with the second pipe 10, and the second pipe 10 is communicated with the second hopper 6.

Referring to fig. 2-3 and 5, the second hopper 6 is communicated with the communicating pipe 11, the second hopper 6 is connected with the communicating pipe 11 by welding, the communicating pipe 11 is communicated with the electric heating pipe 12, the electric heating pipe 12 is electrically connected with the touch display screen 4, the electric heating pipe 12 is fixedly connected with the suction fan 13, the suction fan 13 is electrically connected with the touch display screen 4, the filter element 14 is rotatably connected with the suction fan 13, and the filter element 14 achieves a filtering effect.

Referring to fig. 1-6, the connection support tube 15 is communicated with the first hopper 5, the connection support tube 15 is fixedly connected with the first hopper 5, the connection support tube 15 is of a hollow cylindrical structure, the connection support tube 15 is fixedly connected with the pressurization fan 16, the pressurization fan 16 is electrically connected with the touch display screen 4, two ends of the recovery tube 17 are respectively communicated with the second hopper 6 and the pressurization fan 16, the recovery tube 17 is made of a heat-resistant material, the discharge port 18 is of a hollow cylindrical structure, the discharge port 18 is communicated with the first hopper 5, the discharge port 18 is connected with the first hopper 5 by welding, the discharge port 18 is of a metal structure, the exhaust port 19 is located at the top edge of the first hopper 5, the exhaust port 19 is communicated with the first hopper 5, and the exhaust port 19 is of a hollow bent structure.

The utility model discloses a theory of operation: when the drying system is used, a user firstly starts the material suction machine 7 through the touch display screen 4, and plastic particles are sucked into the second hopper 6 through the material suction machine 7; secondly, the electric heating tube 12 is started through the touch display screen 4, then the suction fan 13 is started, and hot air of the electric heating tube 12 is infused into the second hopper 6 through the communicating tube 11; the heated hot gas is recycled, the hot gas is sent to the booster fan 16 through the recycling pipe 17 again, and the booster fan 16 dries the plastic particles in the first hopper 5 again through the recycled hot gas; the plastic particles are heated for the second time in the first hopper 5 after being heated for the first time in the second hopper 6, so that the moisture of the plastic particles can be fully dried; the hot gas of the inside second time of No. 5 last hopper discharges after through gas vent 19 or discharge gate 18 unloading, and in the drying system use, the stoving of the plastic pellet of being convenient for improves drying efficiency.

Claims (9)

1. The double-hopper energy-saving drying system for the plastic raw materials comprises an equipment main body (1) and is characterized in that a supporting base (2) is installed at the lower end of the equipment main body (1), a control box (3) is arranged at the upper end of the equipment main body (1), a touch display screen (4) is installed at the upper end of the control box (3), a hopper (5) is installed at the upper end of the supporting base (2), a hopper (6) is installed at the upper end of the hopper (5), a suction machine (7) is installed at the upper end of the equipment main body (1), a pipe (8) is installed at one side of the suction machine (7), a tapping device (9) is installed at one end of the pipe (8), a pipe (10) is installed at one side of the tapping device (9), a communicating pipe (11) is connected to one side of the hopper (6), an electric heating pipe (12) is installed at one side of the communicating pipe (11), a suction fan (13) is installed at the upper end of the electric heating pipe (12), a filter core (14) is installed on the outer surface of one side of the suction fan (13), a fan (15) is connected with a supporting pipe (15), and a pressurizing pipe (16) is installed at one side connected with a fan (16), a discharge hole (18) is formed in one side of the second hopper (6), and an exhaust port (19) is formed in the upper end of the second hopper (6).

2. The double-bucket energy-saving drying system for plastic materials as claimed in claim 1, wherein the equipment main body (1) is fixedly connected with the supporting base (2), the supporting base (2) is of a rectangular structure, the equipment main body (1) is fixedly connected with the control box (3), the control box (3) is electrically connected with the touch display screen (4), the touch display screen (4) is of a rectangular structure, and the supporting base (2) is fixedly connected with the first hopper (5).

3. The double-hopper energy-saving drying system for plastic raw materials as claimed in claim 1, wherein the first hopper (5) is communicated with the second hopper (6), the volume of the second hopper (6) is larger than that of the first hopper (5), the control box (3) is electrically connected with the suction machine (7), the first pipe (8) is communicated with the tap (9), the tap (9) is communicated with the second pipe (10), and the second pipe (10) is communicated with the second hopper (6).

4. The double-hopper energy-saving drying system for plastic materials as claimed in claim 1, wherein the second hopper (6) is communicated with the communicating pipe (11), the second hopper (6) is connected with the communicating pipe (11) by welding, and the communicating pipe (11) is communicated with the electric heating pipe (12).

5. The double-bucket energy-saving drying system for plastic raw materials as claimed in claim 1, wherein the electric heating tube (12) is electrically connected with the touch display screen (4), the electric heating tube (12) is fixedly connected with the suction fan (13), the suction fan (13) is electrically connected with the touch display screen (4), the filter core (14) is rotatably connected with the suction fan (13), and the filter core (14) has a filtering effect.

6. The double-hopper energy-saving drying system for plastic materials as claimed in claim 1, wherein the connection support pipe (15) is communicated with the first hopper (5), the connection support pipe (15) is fixedly connected with the first hopper (5), the connection support pipe (15) is of a hollow cylindrical structure, and the connection support pipe (15) is fixedly connected with the pressurizing fan (16).

7. The double-bucket energy-saving drying system for plastic raw materials as claimed in claim 1, wherein the pressurizing fan (16) is electrically connected with the touch display screen (4), two ends of the recovery pipe (17) are respectively communicated with the second hopper (6) and the pressurizing fan (16), and the recovery pipe (17) is made of heat-resistant material.

8. The double-bucket energy-saving drying system for plastic raw materials as claimed in claim 1, wherein the discharge port (18) is of a hollow cylindrical structure, the discharge port (18) is communicated with the first hopper (5), the discharge port (18) is connected with the first hopper (5) through welding, and the discharge port (18) is of a metal structure.

9. The double-bucket energy-saving drying system for plastic raw materials as claimed in claim 1, wherein the exhaust port (19) is located at the top edge of the first hopper (5), the exhaust port (19) is communicated with the first hopper (5), and the exhaust port (19) is of a hollow bent structure.

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