CN214436633U - Locate high-efficient discharging device of photoinitiator crystallizer discharge gate - Google Patents

Abstract

The utility model discloses a locate high-efficient discharging device of photoinitiator crystallizer discharge gate, vertical pipe including connecting the crystallizer discharge gate, vertical intraductal axis of rotation that upwards extends to the crystallizer discharge gate that is equipped with, the upper end of axis of rotation is equipped with the crushing pole of radial extension, it is located the crystallizer discharge gate to smash the pole, the periphery of axis of rotation is equipped with auger blade, auger blade is located vertical intraductal, the lower terminal surface of vertical pipe is equipped with the apron, the lower extreme of axis of rotation passes the apron, the lower extreme of axis of rotation is connected with the motor, the lower extreme of vertical pipe is equipped with the slope pipe, the lower extreme of slope pipe is equipped with the first charging pipe that sets up side by side respectively, the second charging pipe, be equipped with first control valve on the first charging pipe, be equipped with the second control valve on the second charging pipe. The utility model discloses a smash the interior caking of pole with the crystallizer discharge gate and smash to pieces to export the crystalline solid through the auger blade, can improve discharging efficiency.

Description

Locate high-efficient discharging device of photoinitiator crystallizer discharge gate

Technical Field

The utility model relates to a photoinitiator production technical field, more specifically say, it relates to a locate high-efficient discharging device of photoinitiator crystallizer discharge gate.

Background

Photoinitiator probably can block at the phenomenon of caking after the gathering receives the extrusion in crystallizer discharge gate department, caking in discharge gate department to influence ejection of compact speed, need the manual work to use the stock to stretch into the discharge gate and pound the caking to pieces, the operation is inconvenient, influences efficiency.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is not enough to the above-mentioned of prior art, the utility model aims at providing a can improve the high-efficient discharging device of locating photoinitiator crystallizer discharge gate of discharging efficiency.

The technical scheme of the utility model is that: the utility model provides a locate high-efficient discharging device of photoinitiator crystallizer discharge gate, is including the vertical pipe of connecting the crystallizer discharge gate, vertical intraductal upwards extending to that is equipped with the axis of rotation in the crystallizer discharge gate, the upper end of axis of rotation is equipped with the crushing pole of radially extending, smash the pole and be located in the crystallizer discharge gate, the periphery of axis of rotation is equipped with auger blade, auger blade is located vertical intraductal, the lower terminal surface of vertical pipe is equipped with the apron, the lower extreme of axis of rotation passes the apron, the lower extreme of axis of rotation is connected with the motor, the lower extreme of vertical pipe is equipped with the slope pipe, the lower extreme of slope pipe is equipped with first charging pipe, the second charging pipe that sets up side by side respectively, be equipped with first control valve on the first charging pipe, be equipped with the second control valve on the second charging pipe.

As a further improvement, the device further comprises a control module, a first charging table is arranged below the first charging pipe, a first weighing sensor is arranged at the bottom of the first charging table, a second charging table is arranged below the second charging pipe, a second weighing sensor is arranged at the bottom of the second charging table, and the control module is electrically connected with the motor, the first control valve, the second control valve, the first weighing sensor and the second weighing sensor.

Furthermore, a speed reducing mechanism is arranged between the rotating shaft and the motor.

Further, the speed reducing mechanism comprises a driving pulley connected with the motor, a driven pulley connected with the rotating shaft, and a belt connecting the driving pulley and the driven pulley.

Further, the outer wall of the upper end of the vertical pipe is provided with a vibrator which is electrically connected with the control module.

Furthermore, the smashing rod is of a structure with a large root part and a sharp top part.

Further, a support frame is arranged at the bottom of the vertical pipe.

Advantageous effects

Compared with the prior art, the utility model, the advantage that has does:

the utility model discloses a set up vertical pipe, axis of rotation outside the crystallizer discharge gate, set up in the intraoral axis of rotation of crystallizer discharge and smash the pole, set up auger blade in the intraoral axis of rotation of vertical intraductal, smash the pole and smash the intraoral caking of crystallizer discharge and smash to export the crystal through auger blade, can improve discharging efficiency.

Drawings

Fig. 1 is a perspective schematic view of the present invention;

fig. 2 is a schematic structural view of the first charging pipe and the second charging pipe in the direction a in fig. 1.

Wherein: 1-a crystallizer discharge port, 2-a vertical pipe, 3-a rotating shaft, 4-a smashing rod, 5-a packing auger blade, 6-a cover plate, 7-a motor, 8-an inclined pipe, 9-a first charging pipe, 10-a second charging pipe, 11-a first control valve, 12-a second control valve, 13-a first charging platform, 14-a first weighing sensor, 15-a second charging platform, 16-a second weighing sensor, 17-a driving belt wheel, 18-a driven belt wheel, 19-a belt, 20-a vibrator and 21-a support frame.

Detailed Description

The invention will be further described with reference to specific embodiments shown in the drawings.

Referring to fig. 1 and 2, the high-efficiency discharging device arranged at the discharge port of the photoinitiator crystallizer comprises a vertical pipe 2 connected with the discharge port 1 of the crystallizer. Be equipped with the axis of rotation 3 that upwards extends to in the crystallizer discharge gate 1 in the vertical pipe 2, the upper end of axis of rotation 3 is equipped with the pole 4 of smashing to pieces of radial extension, smashes pole 4 and is located crystallizer discharge gate 1, and the periphery of axis of rotation 3 is equipped with auger blade 5, and auger blade 5 is located vertical pipe 2, and the lower terminal surface of vertical pipe 2 is equipped with apron 6, and the apron 6 is passed to the lower extreme of axis of rotation 3, and the lower extreme of axis of rotation 3 is connected with motor 7. The lower end of the vertical pipe 2 is provided with an inclined pipe 8, the lower end of the inclined pipe 8 is respectively provided with a first charging pipe 9 and a second charging pipe 10 which are arranged in parallel, the first charging pipe 9 is provided with a first control valve 11, and the second charging pipe 10 is provided with a second control valve 12. Smash the caking of smashing in crystallizer discharge gate 1 to 4 to export the crystalline solid through auger blade 5, can improve discharging efficiency.

The discharging device further comprises a control module, a first charging table 13 is arranged below the first charging pipe 9, a first weighing sensor 14 is arranged at the bottom of the first charging table 13, a second charging table 15 is arranged below the second charging pipe 10, a second weighing sensor 16 is arranged at the bottom of the second charging table 15, and the control module is electrically connected with the motor 7, the first control valve 11, the second control valve 12, the first weighing sensor 14 and the second weighing sensor 16. Preferably, the control module is a PLC controller with the model number of S7-200. The photoinitiator bin is placed on the first loading platform 13, after the first weighing sensor 14 detects that the photoinitiator bin exists, the control module controls the motor 7 and the first control valve 11 to be opened, the photoinitiator bin on the first loading platform 13 is loaded, when the first weighing sensor 14 detects that the photoinitiator bin is full, the control module controls the first control valve 11 to be closed and the second control valve 12 to be opened, the photoinitiator bin on the second loading platform 15 is loaded, uninterrupted loading can be realized by switching the first loading pipe 9 and the second loading pipe 10, and the loading efficiency can be improved. When detecting that neither the first loading table 13 nor the second loading table 15 has a photoinitiator bin, the control module controls the motor 7, the first control valve 11 and the second control valve 12 to be closed.

A speed reducing mechanism is arranged between the rotating shaft 3 and the motor 7. In the present embodiment, the speed reducing mechanism includes a driving pulley 17 to which the motor 7 is connected, a driven pulley 18 to which the rotating shaft 3 is connected, and a belt 19 connecting the driving pulley 17 and the driven pulley 18. The motor 7 drives the rotating shaft 3 to rotate through the belt transmission mechanism, and the belt transmission mechanism has the characteristics of capability of relaxing impact, reducing vibration and realizing stable transmission and also has the advantages of low cost, simple maintenance and convenient replacement.

The outer wall of the upper end of the vertical pipe 2 is provided with a vibrator 20 electrically connected with the control module, so that the vertical pipe 2 and the crystallizer discharge port 1 can vibrate, and the discharge is smoother. The smashing rod 4 is of a structure with a large root part and a sharp top part, and is favorable for smashing and caking. The bottom of the vertical pipe 2 is provided with a support frame 21, so that the working stability of the discharging device can be ensured.

The above is only a preferred embodiment of the present invention, and it should be noted that for those skilled in the art, without departing from the structure of the present invention, several modifications and improvements can be made, which will not affect the utility of the invention and the utility of the patent.

Claims (7)

1. The utility model provides a locate high-efficient discharging device of photoinitiator crystallizer discharge gate, its characterized in that, including vertical pipe (2) of connecting crystallizer discharge gate (1), be equipped with in vertical pipe (2) and upwards extend to axis of rotation (3) in crystallizer discharge gate (1), the upper end of axis of rotation (3) is equipped with the pole of smashing (4) of radially extending, smash pole (4) and be located in crystallizer discharge gate (1), the periphery of axis of rotation (3) is equipped with auger blade (5), auger blade (5) are located in vertical pipe (2), the lower terminal surface of vertical pipe (2) is equipped with apron (6), the lower extreme of axis of rotation (3) passes apron (6), the lower extreme of axis of rotation (3) is connected with motor (7), the lower extreme of vertical pipe (2) is equipped with slope pipe (8), the lower end of the inclined pipe (8) is provided with a first charging pipe (9) and a second charging pipe (10) which are arranged in parallel, the first charging pipe (9) is provided with a first control valve (11), and the second charging pipe (10) is provided with a second control valve (12).

2. The high-efficiency discharging device arranged at the discharging port of the photoinitiator crystallizer according to claim 1, further comprising a control module, wherein a first charging platform (13) is arranged below the first charging pipe (9), a first weighing sensor (14) is arranged at the bottom of the first charging platform (13), a second charging platform (15) is arranged below the second charging pipe (10), a second weighing sensor (16) is arranged at the bottom of the second charging platform (15), and the control module is electrically connected with the motor (7), the first control valve (11), the second control valve (12), the first weighing sensor (14) and the second weighing sensor (16).

3. The high-efficiency discharging device arranged at the discharging port of the photoinitiator crystallizer according to claim 1, wherein a speed reducing mechanism is arranged between the rotating shaft (3) and the motor (7).

4. The high-efficiency discharging device arranged at the discharging port of the photoinitiator crystallizer according to claim 3, wherein the speed reducing mechanism comprises a driving pulley (17) connected with the motor (7), a driven pulley (18) connected with the rotating shaft (3), and a belt (19) connecting the driving pulley (17) and the driven pulley (18).

5. The high-efficiency discharging device arranged at the discharging port of the photoinitiator crystallizer according to claim 2, wherein the outer wall of the upper end of the vertical pipe (2) is provided with a vibrator (20) electrically connected with the control module.

6. The high-efficiency discharging device arranged at the discharging port of the photoinitiator crystallizer according to claim 1, wherein the smashing rod (4) is of a structure with a large root part and a sharp top part.

7. The high-efficiency discharging device arranged at the discharging port of the photoinitiator crystallizer according to any one of claims 1 to 6, wherein a support frame (21) is arranged at the bottom of the vertical pipe (2).

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