阅读说明：本技术 一种玻璃珠过热筛选装置 (Glass bead overheating screening device ) 是由 房宜娜 于 2021-08-26 设计创作，主要内容包括：本发明涉及一种筛选装置,尤其涉及一种玻璃珠过热筛选装置。需要设计一种方便人们对玻璃珠进行筛选回收,工作效率高,且可对琉璃进行冷却,不易将人烫伤玻璃珠过热筛选装置。一种玻璃珠过热筛选装置,包括有：耐热底箱,耐热底箱一侧设有支撑底板；装料箱,装料箱安装在耐热底箱上；入料管,入料管安装在装料箱与耐热底箱之间。本发明在升降机构和冷却机构的配合下,玻璃珠通过入料管流入升降底箱内,加热模组将玻璃珠溶解成琉璃,进而启动电动推杆使得升降底箱向下移动带动琉璃向下移动,琉璃向下移动浸入清水进行冷却,如此,方便人们对玻璃珠进行筛选回收,工作效率高,且可对琉璃进行冷却,不易将人烫伤。(The invention relates to a screening device, in particular to a glass bead overheating screening device. Need design one kind and make things convenient for people to screen the glass pearl and retrieve, work efficiency is high, and can cool off colored glaze, is difficult for scalding glass pearl overheat screening device with the people. A glass bead overheating screening device comprises: a supporting bottom plate is arranged on one side of the heat-resistant bottom box; the charging box is arranged on the heat-resistant bottom box; and the feeding pipe is arranged between the charging box and the heat-resistant bottom box. According to the invention, under the matching of the lifting mechanism and the cooling mechanism, the glass beads flow into the lifting bottom box through the feeding pipe, the heating module dissolves the glass beads into the colored glaze, and then the electric push rod is started to enable the lifting bottom box to move downwards to drive the colored glaze to move downwards, and the colored glaze moves downwards to be immersed in clear water for cooling.)

1. The utility model provides a glass pearl is overheated sieving mechanism which characterized in that, including:

a supporting bottom plate (2) is arranged on one side of the heat-resistant bottom box (1);

the charging box (3), the charging box (3) is installed on the heat-resisting bottom box (1);

the feeding pipe (31), the feeding pipe (31) is arranged between the charging box (3) and the heat-resistant bottom box (1);

a heating button (41), wherein the heating button (41) is arranged on the heat-resistant bottom box (1);

the discharging button (42), the discharging button (42) is installed on the heat-resisting bottom box (1);

the liquid changing button (43), the liquid changing button (43) is arranged on the heat-resistant bottom box (1);

the heating modules (5), the heating modules (5) are symmetrically arranged on the heat-resistant bottom box (1);

the temperature sensor (51), the temperature sensor (51) is installed on one of the heating modules (5);

the lifting mechanism (6) is arranged on the heat-resistant bottom box (1) and is used for driving the glass beads to move;

and the cooling mechanism (7) is arranged on the heat-resistant bottom box (1) and is used for cooling the heated glass beads.

2. The apparatus for overheating glass beads according to claim 1, wherein the elevating means (6) comprises:

the first positioning bottom block (62), the first positioning bottom block (62) is installed on the heat-resisting bottom box (1) in a sliding mode;

the fixed connecting frame (63), the fixed connecting frame (63) is arranged on the first positioning bottom block (62);

the lifting bottom box (61), the lifting bottom box (61) is arranged on the fixed connecting frame (63);

the second positioning bottom block (64), the second positioning bottom block (64) is installed on the heat-resisting bottom box (1) in a sliding mode, and the second positioning bottom block (64) is rotatably connected with the fixed connecting frame (63);

the electric push rod (66), the electric push rod (66) is installed on the heat-resisting bottom box (1);

the lifting connecting rod (65), the lifting connecting rod (65) is installed on the electric push rod (66), and the lifting connecting rod (65) is fixedly connected with the second positioning bottom block (64);

the positioning bottom rod (67), the positioning bottom rod (67) is arranged on the heat-resisting bottom box (1);

the supporting spring (68), the supporting spring (68) is installed between the lifting connecting rod (65) and the positioning bottom rod (67);

and the photoelectric sensor (69), wherein the photoelectric sensor (69) is arranged on the heat-resistant bottom box (1).

3. A device for overheating screening of glass beads according to claim 2, wherein the cooling means (7) comprises:

a coolant tank (71), wherein the coolant tank (71) is mounted on the heat-resistant bottom box (1);

an immersion box (72), wherein the immersion box (72) is installed on the heat-resistant bottom box (1);

a water pump (73), wherein the water pump (73) is installed on the cooling liquid tank (71);

the liquid inlet pipe (74), the liquid inlet pipe (74) is installed between the water pump (73) and the immersion box (72);

a level sensor (75), the level sensor (75) being mounted on the immersion tank (72);

the spherical electromagnetic valve (76), the spherical electromagnetic valve (76) is installed in the heat-resisting bottom box (1), and the spherical electromagnetic valve (76) is communicated with the immersion box (72).

4. The device for overheating glass beads according to claim 3, further comprising a stop mechanism (8), wherein the stop mechanism (8) comprises:

the first positioning guide rod (82), the first positioning guide rod (82) is symmetrically arranged on the heat-resisting bottom box (1);

the limiting baffle (81), the limiting baffle (81) is arranged on the two first positioning guide rods (82) in a sliding manner;

the first return spring (83), the first return spring (83) winds on the first positioning guide rod (82), one end of the first return spring is connected with the limit baffle (81), and the other end of the first return spring is connected with the heat-resisting bottom box (1);

the limiting cross rod (85), the limiting cross rod (85) is symmetrically arranged on the heat-resisting bottom box (1);

the feeding baffle (84), the feeding baffle (84) is installed between the two limiting cross rods (85) in a sliding manner;

the limiting spring (816) is wound on the limiting cross rod (85), one end of the limiting spring (816) is connected with the feeding baffle (84), and the other end of the limiting spring is connected with the heat-resistant bottom box (1);

the limiting bottom block (86), the limiting bottom block (86) is installed on the limiting baffle (81);

the positioning roller (87), the positioning roller (87) is rotatably arranged on the feeding baffle (84), and the positioning roller (87) is in contact fit with the limiting bottom block (86);

the positioning clamp columns (88), the positioning clamp columns (88) are symmetrically arranged on the lifting bottom box (61);

the spring clamping blocks (89) are arranged on the limiting baffle (81) in a sliding mode at intervals;

the compression spring (810), the compression spring (810) is symmetrically arranged between the spring clamping block (89) and the limit baffle (81);

the second positioning guide rod (813), the second positioning guide rod (813) is symmetrically installed on the heat-resisting bottom box (1);

the limiting fixture block (811), the limiting fixture block (811) is slidably mounted between the two second positioning guide rods (813);

the limiting bottom pillar (812), the limiting bottom pillar (812) is installed on the limiting fixture block (811);

one end of the second return spring (814) wound on the second positioning guide rod (813) is connected with the limiting fixture block (811), and the other end of the second return spring (814) is connected with the heat-resistant bottom box (1);

the jacking bottom block (815) is arranged on the limiting baffle (81).

5. The glass bead overheating screening apparatus according to claim 4, further comprising a blanking mechanism (9), wherein the blanking mechanism (9) comprises:

the discharging guide plate (91), the discharging guide plate (91) is arranged on the heat-resisting bottom box (1);

the material receiving box (92), the material receiving box (92) is arranged on the supporting bottom plate (2);

the material blocking vertical plate (93), the material blocking vertical plate (93) is arranged on the heat-resisting bottom box (1);

the connecting blocks (94), the connecting blocks (94) are symmetrically arranged on the discharging guide plate (91);

the guide sloping plate (95), the guide sloping plate (95) is installed on the heat-resisting bottom case (1) in a rotating way;

the limiting clamping jaw (96), the limiting clamping jaw (96) is installed on the inclined guide plate (95);

the tightening spring (97), the tightening spring (97) is installed between the inclined guide plate (95) and the heat-resisting bottom box (1);

the blanking guide plate (98), the blanking guide plate (98) is installed on the heat-resisting bottom box (1) in a sliding way;

the driven rack (99), the driven rack (99) is embedded on the blanking guide plate (98);

the reversing gear (910) is rotatably arranged on the lifting bottom box (61), and the reversing gear (910) is meshed with the driven rack (99);

the third positioning guide rod (912), the third positioning guide rod (912) is symmetrically installed on the lifting bottom box (61);

the driving rack (911), the driving rack (911) is installed between the two third positioning guide rods (912) in a sliding manner;

a third return spring (913), the third return spring (913) is wound on the third positioning guide rod (912), one end of the third return spring (913) is connected with the driving rack (911), and the other end of the third return spring (913) is connected with the heat-resistant bottom box (1);

and the limiting short rod (914), and the limiting short rod (914) is arranged on the driving rack (911).

6. The apparatus for overheating glass beads according to claim 5, further comprising a stirring mechanism (10), wherein the stirring mechanism (10) comprises:

the servo motor (101), the servo motor (101) is installed on the heat-resisting bottom case (1);

the driving shaft (102), the driving shaft (102) is installed on the servo motor (101);

the six-side driving vertical shaft (104), and the six-side driving vertical shaft (104) is rotatably arranged on the immersion box (72);

the reversing bevel gear component (103), the reversing bevel gear component (103) is arranged between the driving shaft (102) and the six-side driving vertical shaft (104);

the hollow rotating shaft (105), the hollow rotating shaft (105) is rotatably installed on the lifting bottom box (61), the hollow rotating shaft (105) is sleeved on the hexagonal driving vertical shaft (104), and the hollow rotating shaft (105) is in sliding fit with the hexagonal driving vertical shaft (104);

the positioning sliding blocks (106) are arranged on the hollow rotating shaft (105) in a sliding mode at intervals;

the hinged connecting rod (107), the hinged connecting rod (107) is mounted between the two positioning sliding blocks (106) in a hinged mode;

the positioning connecting plate (108) is symmetrically and slidably arranged on the hollow rotating shaft (105), and the positioning connecting plate (108) is fixedly connected with the positioning sliding block (106);

and the fourth return spring (109), and the fourth return spring (109) is arranged between the two positioning connecting plates (108).

7. The apparatus for overheating glass beads according to claim 6, further comprising a filtering means (11), wherein the filtering means (11) comprises:

the filtering bottom net (111), the filtering bottom net (111) is arranged on the material receiving box (92);

the filtering bottom cover (112), the filtering bottom cover (112) is arranged on the discharging guide plate (91);

the sponge roller (113), the sponge roller (113) is installed on the discharging guide plate (91) in a symmetrical rotary mode;

the return pipe (114), the return pipe (114) is symmetrically installed between the filtering bottom cover (112) and the material receiving box (92).

8. The glass bead overheating screening device according to claim 7, further comprising an electric cabinet (4), wherein the electric cabinet (4) is installed on one side of the heat-resistant bottom box (1) far away from the charging box (3), a switching power supply, a power supply module and a control module are included in the electric cabinet (4), the switching power supply supplies power to the screening device, the power supply module is connected with a power supply main switch through a circuit, and the control module is electrically connected with the power supply module; the control module is connected with a DS1302 clock circuit and a 24C02 circuit; heating button (41), ejection of compact button (42), trade liquid button (43), photoelectric sensor (69), temperature sensor (51) and level sensor (75) all with control module electric connection, electric putter (66), heating module (5), spherical solenoid valve (76) and water pump (73) all pass through peripheral circuit with control module and are connected.

Technical Field

The invention relates to a screening device, in particular to a glass bead overheating screening device.

Background

The method is characterized in that a large amount of waste glass beads are generally generated in ordinary life, a long time is needed for complete degradation of the glass beads, the waste glass beads can only be buried after being turned into garbage, but the burying treatment cannot change the existence of the waste glass beads, and the natural environment can still be influenced, so the waste glass beads are generally screened and recycled.

How to design one kind and make things convenient for people to screen the glass pearl and retrieve, work efficiency is high, and can cool off colored glaze, is difficult for scalding the overheated sieving mechanism of glass pearl with the people to solve prior art problem.

Disclosure of Invention

In order to overcome the defects that after the glass beads are poured into a boiler and burned, the glass beads are dissolved into colored glaze, the operation is troublesome, the working efficiency is low, and the glass beads can generate very high temperature after being dissolved, so that people can be easily scalded, the technical problems of the invention are as follows: the utility model provides a make things convenient for people to screen the glass pearl and retrieve, work efficiency is high, and can cool off the coloured glaze, is difficult for scalding glass pearl overheat screening device with the people.

The technical implementation scheme of the invention is as follows: a glass bead overheating screening device comprises: a supporting bottom plate is arranged on one side of the heat-resistant bottom box; the charging box is arranged on the heat-resistant bottom box; the feeding pipe is arranged between the charging box and the heat-resistant bottom box; the heating button is arranged on the heat-resistant bottom box; the discharging button is arranged on the heat-resistant bottom box; the liquid changing button is arranged on the heat-resistant bottom box; the heating modules are symmetrically arranged on the heat-resistant bottom box; the temperature sensor is arranged on one of the heating modules; the lifting mechanism is arranged on the heat-resistant bottom box and is used for driving the glass beads to move; and the cooling mechanism is arranged on the heat-resistant bottom box and used for cooling the heated glass beads.

Optionally, the lifting mechanism comprises: the first positioning bottom block is arranged on the heat-resisting bottom box in a sliding manner; the fixed connecting frame is arranged on the first positioning bottom block; the lifting bottom box is arranged on the fixed connecting frame; the second positioning bottom block is arranged on the heat-resisting bottom box in a sliding mode and is rotationally connected with the fixed connecting frame; the electric push rod is arranged on the heat-resistant bottom box; the lifting connecting rod is arranged on the electric push rod and is fixedly connected with the second positioning bottom block; the positioning bottom rod is arranged on the heat-resistant bottom box; the supporting spring is arranged between the lifting connecting rod and the positioning bottom rod; and the photoelectric sensor is arranged on the heat-resistant bottom box.

Optionally, the cooling mechanism comprises: the cooling liquid box is arranged on the heat-resistant bottom box; the immersion box is arranged on the heat-resistant bottom box; the water pump is arranged on the cooling liquid tank; the liquid inlet pipe is arranged between the water pump and the immersion box; the liquid level sensor is arranged on the immersion box; the spherical electromagnetic valve is arranged in the heat-resistant bottom box and communicated with the immersion box.

Optionally, still including stock stop, stock stop includes: the first positioning guide rods are symmetrically arranged on the heat-resistant bottom box; the limiting baffle is arranged on the two first positioning guide rods in a sliding manner; the first return spring is wound on the first positioning guide rod, one end of the first return spring is connected with the limiting baffle, and the other end of the first return spring is connected with the heat-resistant bottom box; the limiting cross rods are symmetrically arranged on the heat-resistant bottom box; the feeding baffle is arranged between the two limiting cross rods in a sliding manner; the limiting spring is wound on the limiting cross rod, one end of the limiting spring is connected with the feeding baffle, and the other end of the limiting spring is connected with the heat-resistant bottom box; the limiting bottom block is arranged on the limiting baffle; the positioning roller is rotatably arranged on the feeding baffle and is in contact fit with the limiting bottom block; the positioning clamp columns are symmetrically arranged on the lifting bottom box; the spring clamping blocks are arranged on the limiting baffle in a sliding mode at intervals; the compression springs are symmetrically arranged between the spring clamping blocks and the limiting baffle; the second positioning guide rods are symmetrically arranged on the heat-resisting bottom box; the limiting fixture block is arranged between the two second positioning guide rods in a sliding manner; the limiting bottom pillar is arranged on the limiting fixture block; one end of the second return spring wound on the second positioning guide rod is connected with the limiting fixture block, and the other end of the second return spring is connected with the heat-resistant bottom box; the jacking bottom block is arranged on the limiting baffle.

Optionally, still including unloading mechanism, unloading mechanism is including: the discharging guide plate is arranged on the heat-resistant bottom box; the material receiving box is arranged on the supporting bottom plate; the material blocking vertical plate is arranged on the heat-resistant bottom box; the connecting blocks are symmetrically arranged on the discharging guide plate; the guide inclined plate is rotatably arranged on the heat-resistant bottom box; the limiting clamping jaw is arranged on the guide inclined plate; the tightening spring is arranged between the guide inclined plate and the heat-resistant bottom box; the blanking guide plate is arranged on the heat-resistant bottom box in a sliding manner; the driven rack is embedded on the blanking guide plate; the reversing gear is rotatably arranged on the lifting bottom box and meshed with the driven rack; the third positioning guide rods are symmetrically arranged on the lifting bottom box; the driving rack is arranged between the two third positioning guide rods in a sliding manner; a third return spring, wherein the third return spring is wound on a third positioning guide rod, one end of the third return spring is connected with the driving rack, and the other end of the third return spring is connected with the heat-resistant bottom box; and the limiting short rod is arranged on the driving rack.

Optionally, the stirring device further comprises a stirring mechanism, wherein the stirring mechanism comprises: the servo motor is arranged on the heat-resistant bottom box; the driving shaft is arranged on the servo motor; the six-side driving vertical shaft is rotatably arranged on the immersion box; the reversing bevel gear component is arranged between the driving shaft and the hexagonal driving vertical shaft; the hollow rotating shaft is rotatably arranged on the lifting bottom box, is sleeved on the hexagonal driving vertical shaft and is in sliding fit with the hexagonal driving vertical shaft; the positioning sliding blocks are arranged on the hollow rotating shaft at intervals in a sliding manner; the hinged connecting rod is hinged between the two positioning sliding blocks; the positioning connecting plate is symmetrically and slidably arranged on the hollow rotating shaft and is fixedly connected with the positioning sliding block; and the fourth return spring is arranged between the two positioning connecting plates.

Optionally, still include filter mechanism, filter mechanism includes: the filtering bottom net is arranged on the material receiving box; the filtering bottom cover is arranged on the discharging guide plate; the sponge roller is symmetrically and rotatably arranged on the discharging guide plate; the backflow guide pipe is symmetrically arranged between the filtering bottom cover and the material receiving box.

Optionally, the screening device further comprises an electric cabinet, the electric cabinet is arranged on one side of the heat-resistant bottom box far away from the charging box, a switching power supply, a power supply module and a control module are arranged in the electric cabinet, the switching power supply supplies power to the screening device, the power supply module is connected with a power main switch through a circuit, and the control module is electrically connected with the power supply module; the control module is connected with a DS1302 clock circuit and a 24C02 circuit; heating button, ejection of compact button, trade liquid button, photoelectric sensor, temperature sensor and level sensor all with control module electric connection, electric putter, heating module, spherical solenoid valve and water pump all pass through peripheral circuit with control module and are connected.

The invention has the following advantages:

1. according to the invention, under the matching of the lifting mechanism and the cooling mechanism, the glass beads flow into the lifting bottom box through the feeding pipe, the heating module dissolves the glass beads into the colored glaze, and then the electric push rod is started to enable the lifting bottom box to move downwards to drive the colored glaze to move downwards, and the colored glaze moves downwards to be immersed in clear water for cooling.

2. Under the action of the blanking mechanism, the limit clamping jaws enable the lifting bottom box to swing rightwards to be in an inclined state, so that the colored glaze flows onto the discharging guide plate through the blanking guide plate and then flows into the material receiving box, and therefore people can collect the colored glaze conveniently.

3. Under the action of the stirring mechanism, the hollow rotating shaft rotates to enable the hinged connecting rod to rotate, and the rotation of the hinged connecting rod enables the cooling efficiency of the colored glaze to be increased, so that the cooling efficiency of the colored glaze can be increased.

Drawings

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

FIG. 2 is a schematic view of a first partial body structure according to the present invention.

FIG. 3 is a schematic view of a second partial body structure according to the present invention.

Fig. 4 is a schematic view of a first partially-separated body structure of the lifting mechanism of the present invention.

Fig. 5 is a schematic diagram of a second partial body structure of the lifting mechanism of the present invention.

Fig. 6 is a schematic view of a first partial body structure of the cooling mechanism of the present invention.

Fig. 7 is an enlarged schematic view of part a of the present invention.

Fig. 8 is a schematic view of a second partial body structure of the cooling mechanism of the present invention.

Fig. 9 is a perspective view of a third embodiment of the present invention.

Fig. 10 is a schematic view of a first partial solid structure of the stock stop of the present invention.

Fig. 11 is a second partial solid structure diagram of the stock stop of the present invention.

Fig. 12 is an enlarged view of part B of the present invention.

Fig. 13 is a perspective view of a third part of the striker mechanism of the present invention.

Fig. 14 is a schematic view of a first partially separated body structure of the blanking mechanism of the present invention.

Fig. 15 is a schematic view of a second partial body structure of the blanking mechanism of the present invention.

Fig. 16 is an enlarged schematic view of part C of the present invention.

Fig. 17 is a schematic perspective view of a third part of the blanking mechanism of the present invention.

Fig. 18 is a schematic view of a first partial body configuration of an agitation mechanism of the present invention.

Fig. 19 is a schematic view of a second partial body configuration of an agitation mechanism of the present invention.

Fig. 20 is an enlarged view of portion D of the present invention.

Fig. 21 is a schematic perspective view of a portion of the filter mechanism of the present invention.

FIG. 22 is a block circuit diagram of the present invention.

Fig. 23 is a schematic circuit diagram of the present invention.

In the reference symbols: 1-heat-resistant bottom box, 2-supporting bottom plate, 3-charging box, 31-feeding pipe, 4-electric control box, 41-heating button, 42-discharging button, 43-liquid changing button, 5-heating module, 51-temperature sensor, 6-lifting mechanism, 61-lifting bottom box, 62-first positioning bottom block, 63-fixed connecting frame, 64-second positioning bottom block, 65-lifting connecting rod, 66-electric push rod, 67-positioning bottom rod, 68-supporting spring, 69-photoelectric sensor, 7-cooling mechanism, 71-cooling liquid box, 72-immersion box, 73-water pump, 74-liquid inlet pipe, 75-liquid level sensor, 76-spherical electromagnetic valve, 8-material stopping mechanism, 81-limit baffle, 82-a first positioning guide rod, 83-a first return spring, 84-a feeding baffle, 85-a limiting cross rod, 86-a limiting bottom block, 87-a positioning roller, 88-a positioning clamp column, 89-a spring clamp block, 810-a pressing spring, 811-a limiting clamp block, 812-a limiting bottom column, 813-a second positioning guide rod, 814-a second return spring, 815-a jacking bottom block, 816-a limiting spring, 9-a blanking mechanism, 91-a discharging guide plate, 92-a material receiving box, 93-a material blocking vertical plate, 94-a connecting block, 95-a guiding inclined plate, 96-a limiting claw, 97-a tightening spring, 98-a blanking guide plate, 99-a driven rack, 910-a reversing gear, 911-a driving rack and 912-a third positioning guide rod, 913-a third return spring, 914-a limit short rod, 10-a stirring mechanism, 101-a servo motor, 102-a driving shaft, 103-a reversing bevel gear component, 104-a hexagonal driving vertical shaft, 105-a hollow rotating shaft, 106-a positioning slide block, 107-a hinged connecting rod, 108-a positioning connecting plate, 109-a fourth return spring, 11-a filtering mechanism, 111-a filtering bottom net, 112-a filtering bottom cover, 113-a sponge roller and 114-a return conduit.

Detailed Description

The above-described scheme is further illustrated below with reference to specific examples. It should be understood that these examples are for illustrative purposes and are not intended to limit the scope of the present application. The conditions used in the examples may be further adjusted according to the conditions of the particular manufacturer, and the conditions not specified are generally the conditions in routine experiments.

Example 1

A glass bead overheating screening device is shown in figures 1-9 and comprises a heat-resistant bottom box 1, a supporting bottom plate 2, a charging box 3, a feeding pipe 31, a heating button 41, a discharging button 42, a liquid changing button 43, a heating module 5, a temperature sensor 51, a lifting mechanism 6 and a cooling mechanism 7, wherein the bottom of the heat-resistant bottom box 1 is fixedly connected with the supporting bottom plate 2, the charging box 3 is fixedly connected to the left side of the upper part of the heat-resistant bottom box 1, the feeding pipe 31 is communicated between the charging box 3 and the heat-resistant bottom box 1, the heating button 41 is fixedly connected to the middle part of the front side surface of the heat-resistant bottom box 1, the discharging button 42 is fixedly connected to the middle part of the front side surface of the heat-resistant bottom box 1, the liquid changing button 43 is fixedly connected to the middle part of the front side surface of the heat-resistant bottom box 1, the heating module 5 is fixedly connected to the left side of the upper part of the heat-resistant bottom box 1 in a left-right symmetry manner, the temperature sensor 51 is fixedly connected to the upper side of the heating module 5, the heat-resistant bottom box 1 is provided with a lifting mechanism 6, and the heat-resistant bottom box 1 is also provided with a cooling mechanism 7.

The lifting mechanism 6 comprises a lifting bottom box 61, a first positioning bottom block 62, a fixed connecting frame 63, a second positioning bottom block 64, a lifting connecting rod 65, an electric push rod 66, a positioning bottom rod 67, a supporting spring 68 and a photoelectric sensor 69, the first positioning bottom block 62 is arranged on the upper portion of the heat-resisting bottom box 1 in a sliding mode in the front middle side, the left portion of the rear side of the first positioning bottom block 62 is fixedly connected with the fixed connecting frame 63, the lifting bottom box 61 is fixedly connected to the inner side of the fixed connecting frame 63, the second positioning bottom block 64 is arranged on the upper portion of the heat-resisting bottom box 1 in a sliding mode in the rear middle side, the second positioning bottom block 64 is rotatably connected with the fixed connecting frame 63, the electric push rod 66 is fixedly connected to the right lower portion of the rear side of the heat-resisting bottom box 1, the lifting connecting rod 65 is fixedly connected with the lifting connecting rod 64, the positioning bottom rod 67 is fixedly connected to the left lower portion of the rear side of the heat-resisting bottom box 1, the supporting spring 68 is wound between the left portion of the bottom of the lifting connecting rod 65 and the lower portion of the positioning bottom rod 67, the upper right rear side of the heat-resistant bottom case 1 is provided with a photoelectric sensor 69.

The cooling mechanism 7 comprises a cooling liquid tank 71, an immersion tank 72, a water pump 73, a liquid inlet pipe 74, a liquid level sensor 75 and a spherical electromagnetic valve 76, the cooling liquid tank 71 is fixedly connected to the lower portion of the right side face of the heat-resistant bottom tank 1, the immersion tank 72 is fixedly connected to the lower portion in the heat-resistant bottom tank 1, the water pump 73 is communicated with the rear portion of the cooling liquid tank 71, the liquid inlet pipe 74 is communicated between a water inlet of the water pump 73 and the immersion tank 72, the liquid level sensor 75 is fixedly connected to the lower right portion of the rear side face in the immersion tank 72, the spherical electromagnetic valve 76 is arranged on the lower right side of the front portion of the heat-resistant bottom tank 1, and the spherical electromagnetic valve 76 is communicated with the immersion tank 72.

Initially, a proper amount of clean water is filled in the immersion box 72, people press a power supply main switch to electrify the device, firstly, an operator pours a proper amount of glass beads into the charging box 3, the glass beads flow into the lifting bottom box 61 through the feeding pipe 31, the heating button 41 is pressed once to send a signal, the control module receives the signal and controls the heating module 5 to work, the heating module 5 works to heat and melt the glass beads into colored glaze, the temperature sensor 51 monitors the temperature, when the temperature sensor 51 detects that the temperature is higher than a rated value in the control module, the temperature sensor 51 sends a signal, the control module receives the signal and controls the heating module 5 to stop, the control module also controls the electric push rod 66 to contract for 5 seconds, the electric push rod 66 contracts to drive the lifting connecting rod 65 to move downwards, the lifting connecting rod 65 moves downwards to drive the second positioning bottom block 64 to move downwards, the second positioning bottom block 64 moves downwards to be matched with the first positioning bottom block 62 to drive the lifting bottom box 61 to move downwards, the lifting bottom box 61 moves downwards to drive the colored glaze to move downwards, the colored glaze moves downwards to be immersed in clear water for cooling, after 5 seconds, the control module controls the electric push rod 66 to extend and reset, the lifting connecting rod 65 drives the second positioning bottom block 64 to move upwards for resetting, the lifting bottom box 61 also moves upwards for resetting, the photoelectric sensor 69 detects that the lifting bottom box 61 moves to a proper position, the photoelectric sensor 69 sends a signal, the control module receives the signal and controls the electric push rod 66 to stop, if necessary, the colored glaze is taken out for subsequent treatment, the discharging button 42 is pressed once, the discharging button 42 sends a signal, the control module receives the signal and controls the electric push rod 66 to extend for 5 seconds, the electric push rod 66 drives the lifting connecting rod 65 to move upwards, and then the lifting bottom box 61 also drives the colored glaze to move upwards, taking out the colored glaze for subsequent treatment, after 5 seconds, the control module controls the electric push rod 66 to contract, the photoelectric sensor 69 detects that the lifting bottom box 61 moves to a proper position, the photoelectric sensor 69 sends a signal, the control module receives the signal and controls the electric push rod 66 to stop, the process is repeated, glass beads are continuously heated and melted, if the clear water is turbid after being used for a long time, the liquid changing button 43 is pressed once, the liquid changing button 43 sends a signal, the control module receives the signal and controls the spherical electromagnetic valve 76 to be opened, the clear water is discharged, the liquid level sensor 75 monitors the water level, when the liquid level sensor 75 detects that the clear water is lower than a rated value in the control module, the liquid level sensor 75 sends a signal, the control module receives the signal and controls the spherical electromagnetic valve 76 to be closed, the control module also controls the water pump 73 to work after receiving the signal, the water pump 73 operates to discharge the clear water into the immersion box 72 through the liquid inlet pipe 74, when the water level reaches the rated value in the control module, the liquid level sensor 75 sends out a signal again, and the control module controls the water pump 73 to stop after receiving the signal.

Example 2

On the basis of embodiment 1, as shown in fig. 10-17, the heat-resisting bottom box further comprises a material blocking mechanism 8, the material blocking mechanism 8 comprises a limiting baffle 81, a first positioning guide rod 82, a first return spring 83, a feeding baffle 84, a limiting cross rod 85, a limiting bottom block 86, a positioning roller 87, a positioning clamp column 88, a spring clamp block 89, a pressing spring 810, a limiting clamp block 811, a limiting bottom column 812, a second positioning guide rod 813, a second return spring 814, a jacking bottom block 815 and a limiting spring 816, the first positioning guide rod 82 is symmetrically and fixedly connected to the left portion of the heat-resisting bottom box 1 from front to back, the limiting baffle 81 is slidably arranged between the first positioning guide rods 82 on the front side and the rear side, the first return spring 83 is wound on the first positioning guide rod 82, one end of the first return spring 83 is connected to the limiting baffle 81, the other end of the first return spring 83 is connected to the heat-resisting bottom box 1, the limiting cross rod 85 is symmetrically and fixedly connected to the upper and lower side of the left portion of the heat-resisting bottom box 1 from top to bottom, a feeding baffle 84 is slidably arranged between the limiting cross rods 85 at the upper side and the lower side, a limiting spring 816 is wound on the limiting cross rod 85, one end of the limiting spring 816 is connected with the feeding baffle 84, the other end is connected with the heat-resistant bottom box 1, a limiting bottom block 86 is fixedly connected with the upper front part of the left side surface of the limiting baffle 81, a positioning roller 87 is rotatably arranged at the front middle part of the feeding baffle 84, the positioning roller 87 is in contact fit with the limiting bottom block 86, positioning clamp columns 88 are symmetrically and fixedly connected with the front and the back of the upper part of the outer side surface of the lifting bottom box 61, spring clamp blocks 89 are arranged at the upper part of the limiting baffle 81 in an interval sliding manner, two compression springs 810 are fixedly connected between the inner side surface of the spring clamp block 89 and the limiting baffle 81, two second positioning guide rods 813 are arranged at the upper rear side of the left part of the heat-resistant bottom box 1, a limiting clamp block 811 is arranged between the two second positioning guide rods 813 in a sliding manner, a second return spring 814 is wound on the second positioning guide rod 813, one end of the second return spring 814 is connected with the limiting clamp block 811, the other end is connected with the heat-resistant bottom box 1, the bottom of the limiting fixture block 811 is fixedly connected with a limiting bottom column 812, and the lower part of the rear side surface of the limiting baffle 81 is fixedly connected with a jacking bottom block 815.

The blanking mechanism 9 comprises a discharge guide plate 91, a material receiving box 92, a material blocking vertical plate 93, a connecting block 94, a guide inclined plate 95, a limit claw 96, a tightening spring 97, a blanking guide plate 98, a driven rack 99, a reversing gear 910, a driving rack 911, a third positioning guide rod 912, a third return spring 913 and a limit short rod 914, the discharge guide plate 91 is fixedly connected to the upper part of the outer right side surface of the heat-resistant bottom box 1, the material receiving box 92 is fixedly connected to the right side of the top of the supporting bottom plate 2, the connecting blocks 94 are fixedly connected to the front side and the rear side of the left part of the discharge guide plate 91, the material blocking vertical plate 93 is fixedly connected between the upper parts of the front side and the rear side of the connecting blocks 94, the guide inclined plate 95 is rotatably arranged on the upper middle side of the right part of the heat-resistant bottom box 1, the tightening spring 97 is arranged between the lower part of the left side surface of the guide inclined plate 95 and the inside of the heat-resistant bottom box 1, the limit claw 96 is fixedly connected to the top of the guide inclined plate 95, the right part of the heat-resistant bottom box 1 is slidably provided with the blanking guide plate 98, the middle of the blanking guide plate 98 is provided with a driven rack 99 in an embedded manner, the middle of the right part of the lifting bottom box 61 is provided with a reversing gear 910 in a rotating manner, the reversing gear 910 is meshed with the driven rack 99, the upper middle of the right part of the lifting bottom box 61 is fixedly connected with third positioning guide rods 912 in a front-back symmetrical manner, a driving rack 911 is arranged between the third positioning guide rods 912 on the front side and the rear side in a sliding manner, the driving rack 911 is meshed with the reversing gear 910, the driving rack 911 is connected with the lifting bottom box 61 in a sliding manner, a third return spring 913 is wound on the third positioning guide rods 912, one end of the third return spring 913 is connected with the driving rack 911, the other end of the third return spring 913 is connected with the heat-resistant bottom box 1, and the upper part of the right side face of the driving rack 911 is fixedly connected with a limit short rod 914.

Firstly, an operator pours a proper amount of glass beads into a charging box 3, the glass beads flow into a lifting bottom box 61 through a feeding pipe 31, a heating module 5 works to heat and melt the glass beads into colored glaze, a temperature sensor 51 monitors the temperature, when the temperature sensor 51 detects that the temperature is higher than a rated value in a control module, the temperature sensor 51 sends a signal, the control module receives the signal and controls the heating module 5 to stop, the control module receives the signal and controls an electric push rod 66 to contract for 5 seconds, the lifting bottom box 61 moves downwards to drive the colored glaze to move downwards, the colored glaze moves downwards to be immersed in clear water for cooling, meanwhile, the lifting bottom box 61 moves downwards and also drives a positioning clamp column 88 to move downwards, the positioning clamp column 88 moves downwards to drive a spring clamp block 89 to move downwards, the spring clamp block 89 moves downwards to drive a limiting baffle 81 to move downwards, and a first return spring 83 is compressed, the limiting baffle 81 moves downwards to drive the limiting bottom block 86 to move downwards, the limiting bottom block 86 moves downwards to enable the positioning roller 87 to move backwards, the positioning roller 87 moves backwards to drive the feeding baffle 84 to move backwards, the limiting spring 816 is compressed, the feeding baffle 84 moves backwards to be in contact with the limiting fixture block 811, due to the action of the second reset spring 814, the feeding baffle 84 moves backwards to slide over the limiting fixture block 811, the limiting fixture block 811 limits the feeding baffle 84, the feeding baffle 84 blocks the feeding pipe 31, after 5 seconds, the control module controls the electric push rod 66 to extend and reset, the lifting bottom box 61 also moves upwards to reset, the positioning fixture column 88 drives the limiting baffle 81 to move upwards to reset, the first reset spring 83 plays a boosting role, the discharging button 42 is pressed once, the discharging button 42 sends a signal, the control module receives the signal and controls the electric push rod 66 to extend for 5 seconds, the electric push rod 66 drives the lifting connecting rod 65 to move upwards, the lifting bottom box 61 drives the colored glaze to move upwards, the lifting bottom box 61 also drives the positioning clamp column 88 to move upwards, the positioning clamp column 88 moves upwards to drive the spring clamp block 89 to move upwards, the spring clamp block 89 moves upwards to drive the limiting baffle 81 to move upwards, the first return spring 83 is stretched, the limiting baffle 81 moves upwards to drive the jacking bottom block 815 to move upwards, the jacking bottom block 815 moves upwards to be in contact with the limiting bottom column 812, the jacking bottom block 815 drives the limiting bottom column 812 to move upwards, the second return spring 814 is stretched, the limiting bottom column 812 moves upwards to drive the limiting clamp block 811 to move upwards, the limiting clamp block 811 moves upwards to stop limiting the limiting baffle 81, the feeding baffle 84 moves forwards to reset to stop limiting the feeding pipe 31 due to the action of the limiting spring 816, and the positioning clamp column 88 continues to move upwards to be separated from the spring clamp block 89, because of the effect of first reset spring 83, limit baffle 81 moves down and resets, and limit baffle 81's hole does not correspond with feeding baffle 84's hole, take out coloured glaze and carry out subsequent processing, after 5 seconds, control module control electric putter 66 contracts, lift under casing 61 drives locator card post 88 and moves down and resets, locator card post 88 moves down and blocks in spring fixture block 89, thereby locator card post 88 drives spring fixture block 89 and moves down, limit baffle 81 just also moves down and corresponds with feeding baffle 84, the glass pearl is in flowing into lift under casing 61 through pan feeding tube 31 once more, so, need not people to carry out the material loading.

If the colored glaze needs to be taken out for subsequent treatment, the discharging button 42 is pressed once, the discharging button 42 sends a signal, the control module receives the signal and then controls the electric push rod 66 to extend for 5 seconds, the lifting bottom box 61 drives the driving rack 911, the reversing gear 910, the driven rack 99 and the discharging guide plate 98 to move upwards, meanwhile, the driving rack 911 moves upwards to drive the limiting short rod 914 to move upwards, the limiting short rod 914 moves upwards to contact with the limiting claw 96, the limiting claw 96 enables the lifting bottom box 61 to swing rightwards to be in an inclined state, the driving rack 911 does not move upwards any more, the lifting bottom box 61, the reversing gear 910, the driven rack 99 and the discharging guide plate 98 continue to move upwards, the third return spring 913 is compressed, the reversing gear 910 rotates clockwise in the process of moving upwards, the driven rack 99 and the discharging guide plate 98 are driven to move upwards, and the colored glaze flows into the discharging guide plate 91 through the discharging guide plate 98, the direction swash plate 95 plays the guide effect, and in the coloured glaze reentrant material receiving box 92, after 5 seconds, control module control electric putter 66 shrink, spacing quarter butt 914 breaks away from with spacing jack catch 96, and lift under casing 61 swings left and resets, and lift under casing 61 drives drive rack 911 and moves down and resets, and unloading baffle 98 just also moves down and resets, is equipped with the appropriate amount coloured glaze in the material receiving box 92, takes out and carries out subsequent processing, so, can make things convenient for people to collect the coloured glaze.

Example 3

On the basis of the embodiments 1 and 2, as shown in fig. 18-21, the stirring device 10 further comprises a stirring mechanism 10, wherein the stirring mechanism 10 comprises a servo motor 101, a driving shaft 102, a reversing bevel gear assembly 103, a hexagonal driving vertical shaft 104, a hollow rotating shaft 105, a positioning slider 106, a hinged connecting rod 107, a positioning connecting plate 108 and a fourth return spring 109, the servo motor 101 is arranged at the lower side of the front part of the heat-resistant bottom box 1, the driving shaft 102 is connected to an output shaft of the servo motor 101, the hexagonal driving vertical shaft 104 is rotatably arranged at the middle side of the immersion box 72, the reversing bevel gear assembly 103 is arranged between the lower part of the hexagonal driving vertical shaft 104 and the rear part of the driving shaft 102, the hollow rotating shaft 105 is arranged at the middle side of the lower part of the lifting bottom box 61, the hollow rotating shaft 105 is sleeved on the hexagonal driving vertical shaft 104, the hollow rotating shaft 105 is in sliding fit with the hexagonal driving vertical shaft 104, the hollow rotating shaft 105 is provided with the positioning slider 106 at intervals in a sliding manner, a hinged connecting rod 107 is hinged between the upper and lower positioning sliding blocks 106, two positioning connecting plates 108 are arranged in the hollow rotating shaft 105 in a sliding manner, the positioning connecting plates 108 are fixedly connected with the positioning sliding blocks 106, and a fourth return spring 109 is fixedly connected between the upper and lower positioning sliding blocks 106.

Still including filtering mechanism 11, filtering mechanism 11 is including filtering end net 111, filter end cover 112, sponge cylinder 113 and return conduit 114, and the inboard lower part rigid coupling of material receiving box 92 has filtering end net 111, and ejection of compact baffle 91 bottom right side rigid coupling has filtering end cover 112, two sponge cylinders 113 of ejection of compact baffle 91 right part rotary type, and the symmetry intercommunication has return conduit 114 around filtering end cover 112 and the material receiving box 92 between.

After the device is powered on, the servo motor 101 starts to work, when the glass beads are melted into colored glaze, the lifting bottom box 61 moves downwards to drive the colored glaze to move downwards, the colored glaze moves downwards to be immersed in clear water for cooling, meanwhile, the lifting bottom box 61 drives the hollow rotating shaft 105 to move downwards, the hollow rotating shaft 105 moves downwards to drive the positioning connecting plate 108 to move inwards, the fourth reset spring 109 is compressed, the positioning connecting plate 108 moves inwards to drive the positioning slide block 106 to move inwards, the positioning slide block 106 moves inwards to fold the hinged connecting rod 107, the hollow rotating shaft 105 moves downwards to be sleeved on the six-edge driving vertical shaft 104, the servo motor 101 drives the driving shaft 102 to rotate, the driving shaft 102 rotates to drive the reversing bevel gear assembly 103 to rotate, the reversing bevel gear assembly 103 rotates to drive the six-edge driving vertical shaft 104 to rotate, the six-edge driving vertical shaft 104 rotates to drive the middle idle shaft 105 to rotate, the hollow rotating shaft 105 rotates to drive the hinged connecting rod 107 to rotate, the articulated connecting rod 107 rotates to increase the cooling efficiency of the colored glaze, and then the lifting bottom box 61 drives the hollow rotating shaft 105 to move upwards for resetting, the hollow rotating shaft 105 is separated from the hexagonal driving vertical shaft 104, the positioning connecting plate 108 moves outwards for resetting under the action of the fourth reset spring 109, the articulated connecting rod 107 also stretches for resetting, and after the device is powered off, the servo motor 101 also stops working, so that the cooling efficiency of the colored glaze can be increased.

When the coloured glaze flows into from ejection of compact baffle 91 and connects in the workbin 92, sponge cylinder 113 clears up the coloured glaze, and the clearance produces waste water and discharges into through backflow pipe 114 and connect in the workbin 92, and the coloured glaze drops to connect in the workbin 92, filters end net 111 and just also filters just also the coloured glaze, is equipped with appropriate amount coloured glaze in the workbin 92, takes out and carries out subsequent processing, and also carries out subsequent processing to waste water, so, can avoid remaining the water stain on the coloured glaze.

As shown in fig. 2, 22 and 23, the screening device further comprises an electric cabinet 4, wherein the electric cabinet 4 is installed on the lower side of the left part of the heat-resistant bottom case 1, a switching power supply, a power supply module and a control module are arranged in the electric cabinet 4, the switching power supply supplies power to the screening device, the power supply module is connected with a power supply main switch through a circuit, and the control module is electrically connected with the power supply module; the control module is connected with a DS1302 clock circuit and a 24C02 circuit; the heating button 41, the discharging button 42, the liquid changing button 43, the photoelectric sensor 69, the temperature sensor 51 and the liquid level sensor 75 are all electrically connected with the control module, and the electric push rod 66, the heating module 5, the spherical electromagnetic valve 76 and the water pump 73 are all connected with the control module through peripheral circuits.

It should be understood that the above description is for exemplary purposes only and is not meant to limit the present invention. Those skilled in the art will appreciate that variations of the present invention are intended to be included within the scope of the claims herein.