CN220867271U - Sinking type material channel - Google Patents

Abstract

The utility model provides a sinking material channel, belongs to the technical field of glass production, and solves the technical problems that the existing material channel can cause incomplete homogenization in the transportation process, influence the appearance of a glass finished product and the like. This formula of sinking material way, including a plurality of silo units, through bolt fixed connection between the adjacent silo unit, silo unit fixedly connected with formula of sinking silo on right side has seted up left side subsidence tank and right subsidence tank in the formula of sinking silo, has seted up the feed chute between left side subsidence tank and the right subsidence tank, and the feed inlet has been seted up to left side subsidence tank upper end, and the discharge gate has been seted up to right side subsidence tank upper end, and the connecting slot of subsidence silo other end fixedly connected with spread groove, the discharge gate has been seted up to the spread groove downside. The utility model has the advantages of fully stirring the glass melt in the transportation process and avoiding incomplete homogenization.

Description

Sinking type material channel

Technical Field

The utility model belongs to the technical field of glass processing, and relates to a material channel, in particular to a sinking material channel.

Background

In the production process of glass, layering is easily caused in the process of transporting glass melt, or the broken glass occupies more, or the ingredient difference between the selected broken glass and the main glass is larger, the problem that the uniformity degree of mixing between the broken glass and the powder is poorer and the like can all cause serious stripe to influence the appearance of a glass finished product, even the direct scrapping treatment of the product is possibly caused, and a certain waste is caused.

When glass is produced, the bottom of the existing material channel is generally flat in the process of transporting glass melt, so that the vitreous inclusion is not diffused and homogenized in the process of transporting the glass, and stripe defects are generated.

Disclosure of utility model

The utility model aims at solving the problems in the prior art, and provides a sinking material channel, which aims at solving the technical problems that: how to realize fully stirring the glass melt in the transportation process, and avoid incomplete homogenization.

The aim of the utility model can be achieved by the following technical scheme:

The utility model provides a formula of sinking material way, includes a plurality of silo units, a plurality of through bolt fixed connection between the silo unit, silo unit fixedly connected with formula of sinking silo on right side has seted up left side subsidence tank and right subsidence tank in the formula of sinking silo, has seted up the feed chute between left side subsidence tank and the right subsidence tank, and the feed inlet has been seted up to left side subsidence tank upper end, and the discharge gate has been seted up to right side subsidence tank upper end, and the connecting slot of subsidence silo other end fixedly connected with, connecting slot other end fixedly connected with blown down tank, the feed opening has been seted up to the blown down tank downside.

The working principle of the utility model is as follows: during operation, the length of the feeding channel can be increased by connecting different numbers of trough units according to the length requirement of the conveying line, when glass melt flows through the sinking trough, the glass melt falls into the seat sinking trough from the feeding hole, flows through the feeding trough and the right sinking trough, finally flows out of the discharging hole, in the process, the glass melt is overturned and stirred in the fall of the feeding channel, so that the glass-state inclusion is diffused and homogenized, then flows into the discharging trough through the connecting trough, and then flows out of the discharging hole for further processing.

All be provided with stirring subassembly in feed inlet and the discharge gate, stirring subassembly includes the base, fixedly connected with support column on the base, support column upper end fixedly connected with mounting panel, the mounting panel left side is provided with bearing subassembly, mounting panel right-hand member fixedly connected with motor cabinet, fixedly connected with motor on the motor cabinet, the motor output axle head is provided with drive assembly, drive assembly is connected with the pivot, the pivot is connected with bearing subassembly, pivot lower extreme fixedly connected with roating seat, fixedly connected with stirring leaf on the roating seat, the stirring leaf of two stirring subassemblies stretches into respectively in left sink and the right sink.

By adopting the structure, during operation, the motor is started, the output shaft end of the motor drives the rotating shaft to rotate through the transmission component, the rotating shaft drives the stirring blade to rotate through the rotating seat, and the two stirring components stir glass molten liquid in the left sinking groove and the right sinking groove in the above mode respectively, so that the molten liquid can be further stirred uniformly, and the condition that glass-state inclusion is not diffused and homogenized is avoided.

The transmission assembly comprises a transmission shaft, the transmission shaft is fixedly connected with an output shaft of the motor, the other end of the transmission shaft is fixedly connected with a first bevel gear, a second bevel gear is meshed with the first bevel gear, the second bevel gear is fixedly connected to the rotation shaft, and a plurality of stabilizing assemblies are arranged on the transmission shaft.

With the adoption of the structure, during operation, the motor output shaft drives the transmission shaft to rotate, the transmission shaft drives the first bevel gear to rotate, the first bevel gear drives the second bevel gear to rotate, and the second bevel gear drives the rotating shaft to rotate.

The bearing assembly comprises a bearing ring, the bearing ring is fixedly connected to the left end of the mounting plate, a bearing groove is formed in the bearing ring, a thrust bearing is arranged in the bearing groove, a clamping ring is fixedly connected to the rotating shaft, and the lower side of the clamping ring is abutted to the thrust bearing.

By adopting the structure, during operation, the bearing assembly plays a supporting role on the rotating shaft, the rotating seat and the stirring blade, weight load is avoided on the transmission shaft, and friction force during rotating the rotating shaft is reduced.

The stabilizing assembly comprises a bearing seat, a radial bearing is arranged on the bearing seat, and a plurality of inner rings of the radial bearing are abutted against the transmission shaft.

By adopting the structure, the stability of the transmission shaft can be improved, and the first bevel gear and the second bevel gear are tightly meshed.

The rotating shaft comprises an upper rotating shaft and a lower rotating shaft, the upper rotating shaft is in threaded connection with the lower rotating shaft, the clamping ring is fixedly connected to the upper rotating shaft, and the rotating seat is fixedly connected to the lower end of the lower rotating shaft.

By adopting the structure, during installation, the upper rotating shaft is unscrewed, then the upper rotating shaft is placed into the supporting ring from the upper side of the supporting ring, and then the upper rotating shaft is in threaded connection with the lower rotating shaft, so that the rotating shaft is convenient to install and detach.

Two diagonal braces are fixedly connected to the support column, the upper ends of the two diagonal braces are fixedly connected with the mounting plate, and a balancing weight is fixedly connected to the lower side of the right end of the mounting plate.

By adopting the structure, the stability of the mounting plate can be increased, and the mounting plate is prevented from tilting to one side.

Compared with the prior art, the sinking material channel has the following advantages:

1. During operation, the length of the feeding channel can be increased by connecting different numbers of trough units according to the length requirement of the conveying line, when glass melt flows through the sinking trough, the glass melt falls into the seat sinking trough from the feeding hole, flows through the feeding trough and the right sinking trough, finally flows out of the discharging hole, in the process, the glass melt is overturned and stirred in the fall of the feeding channel, so that the glass-state inclusion is diffused and homogenized, then flows into the discharging trough through the connecting trough, and then flows out of the discharging hole for further processing.

2. The stirring component can further stir the melt uniformly, so that the condition that the glassy inclusions are not diffused and homogenized is avoided.

3. The bearing assembly can support the rotating shaft, the rotating seat and the stirring blade, so that weight load on the transmission shaft is avoided, and friction force during rotating the rotating shaft is reduced.

4. The stability of the transmission shaft can be improved by the stabilizing component, and the first bevel gear and the second bevel gear are tightly meshed.

5. The setting of bracing and balancing weight can increase the stability of mounting panel, avoids the mounting panel to topple over to one side.

Drawings

Fig. 1 is a schematic structural view of the present utility model.

Fig. 2 is a top view of the present utility model.

FIG. 3 is a schematic view of the structure of the sinking chute according to the present utility model.

FIG. 4 is a cross-sectional view of a submerged chute according to the present utility model.

Fig. 5 is a cross-sectional view of a transmission assembly of the present utility model.

In the figure, 1, a trough unit; 2. sinking type trough; 3. a left sinking groove; 4. a right sinking groove; 5. a feed chute; 6. a feed inlet; 7. a discharge port; 8. a connecting groove; 9. a discharge chute; 10. a feed opening; 11. a base; 12. a support column; 13. a mounting plate; 14. a motor base; 15. a motor; 16. a rotating shaft; 17. a rotating seat; 18. stirring the leaves; 19. a transmission shaft; 20. a support ring; 21. a first bevel gear; 22. a second bevel gear; 23. a bearing groove; 24. a thrust bearing; 25. a clasp; 26. a bearing seat; 27. a radial bearing; 28. an upper rotating shaft; 29. a lower rotating shaft; 30. diagonal bracing; 31. and (5) balancing weights.

Detailed Description

The following are specific embodiments of the present utility model and the technical solutions of the present utility model will be further described with reference to the accompanying drawings, but the present utility model is not limited to these embodiments.

As shown in fig. 1-5, the sinking type material channel comprises a plurality of material tank units 1, wherein the material tank units 1 are fixedly connected through bolts, the material tank unit 1 on the rightmost side is fixedly connected with a sinking type material tank 2, a left sinking tank 3 and a right sinking tank 4 are arranged in the sinking type material tank 2, a feeding tank 5 is arranged between the left sinking tank 3 and the right sinking tank 4, a feeding port 6 is arranged at the upper end of the left sinking tank 3, a discharging port 7 is arranged at the upper end of the right sinking tank 4, a connecting tank 8 is fixedly connected with the other end of the sinking type material tank 2, a discharging tank 9 is fixedly connected with the other end of the connecting tank 8, and a discharging port 10 is arranged at the lower side of the discharging tank 9.

In operation, the different numbers of trough units 1 can be connected according to the length requirement of a conveying line, so that the length of a feed channel is increased, when glass melt flows through the sinking trough 2, the glass melt falls into the seat sinking trough 3 from the feed inlet 6, then flows through the feed trough 5 and the right sinking trough 4, finally flows out from the discharge outlet 7, in the process, the glass melt is overturned and stirred in the fall of the feed channel, so that the glass state inclusions are diffused and homogenized, then the melt flows into the discharge trough 9 through the connecting trough 8, and then the glass melt flows out from the discharge opening 10 for further processing.

All be provided with stirring subassembly in feed inlet 6 and the discharge gate 7, stirring subassembly includes base 11, fixedly connected with support column 12 on the base 11, support column 12 upper end fixedly connected with mounting panel 13, mounting panel 13 left side is provided with bearing subassembly, mounting panel 13 right-hand member fixedly connected with motor cabinet 14, fixedly connected with motor 15 on the motor cabinet 14, motor 15 output shaft end is provided with drive assembly, drive assembly is connected with pivot 16, pivot 16 is connected with bearing subassembly, pivot 16 lower extreme fixedly connected with roating seat 17, fixedly connected with stirring leaf 18 on the roating seat 17, the stirring leaf 18 of two stirring subassemblies stretches into respectively in left sink 3 and the right side sink 4.

By adopting the structure, during operation, the motor 15 is started, the output shaft end of the motor 15 drives the rotating shaft 16 to rotate through the transmission component, the rotating shaft 16 drives the stirring blade 18 to rotate through the rotating seat 17, and the two stirring components respectively stir glass molten liquid in the left sinking tank 3 and the right sinking tank 4 in the mode, so that the molten liquid can be further stirred uniformly, and the condition that glass-state inclusion is not diffused and homogenized is avoided.

The transmission assembly comprises a transmission shaft 19, the transmission shaft 19 is fixedly connected with an output shaft of the motor 15, the other end of the transmission shaft 19 is fixedly connected with a first bevel gear 21, the first bevel gear 21 is meshed with a second bevel gear 22, the second bevel gear 22 is fixedly connected to the rotating shaft 16, and a plurality of stabilizing assemblies are arranged on the transmission shaft 19.

With the above structure, during operation, the output shaft of the motor 15 drives the transmission shaft 19 to rotate, the transmission shaft 19 drives the first bevel gear 21 to rotate, the first bevel gear 21 drives the second bevel gear 22 to rotate, and the second bevel gear 22 drives the rotating shaft 16 to rotate.

The bearing assembly comprises a bearing ring 20, the bearing ring is fixedly connected to the left end of the mounting plate 13, a bearing groove 23 is formed in the bearing ring 20, a thrust bearing 24 is arranged in the bearing groove 23, a clamping ring 25 is fixedly connected to the rotating shaft 16, and the lower side of the clamping ring 25 is abutted against the thrust bearing 24.

With the above structure, in operation, the supporting member supports the shaft 16, the rotary base 17 and the stirring blade 18, thereby avoiding weight load on the transmission shaft 19 and reducing friction force when rotating the shaft 16.

The stabilizing assembly comprises a bearing seat 26, a radial bearing 27 is arranged on the bearing seat 26, and the inner rings of the radial bearings 27 are in contact with the transmission shaft 19.

With the above structure, the stability of the drive shaft 19 can be increased, and the first bevel gear 21 and the second bevel gear 22 can be ensured to be tightly meshed.

The rotating shaft 16 comprises an upper rotating shaft 28 and a lower rotating shaft 29, the upper rotating shaft 28 is in threaded connection with the lower rotating shaft 29, the clamping ring 25 is fixedly connected to the upper rotating shaft 28, and the rotating seat 17 is fixedly connected to the lower end of the lower rotating shaft 29.

With the above structure, when in installation, the upper rotating shaft 28 is unscrewed, then the upper rotating shaft 28 is put into the supporting ring 20 from the upper side of the supporting ring 20, and then the upper rotating shaft 28 is in threaded connection with the lower rotating shaft 29, so that the rotating shaft 16 is convenient to install and detach.

Two diagonal braces 30 are fixedly connected to the support column, the upper ends of the two diagonal braces 30 are fixedly connected with the mounting plate 13, and a balancing weight 31 is fixedly connected to the lower side of the right end of the mounting plate 13.

By adopting the structure, the stability of the mounting plate 13 can be increased, and the mounting plate 13 is prevented from tilting to one side.

The working principle of the utility model is that when the glass melting device works, different numbers of trough units 1 can be connected according to the length requirement of a conveying line, so that the length of a feed channel is increased, when the glass melting liquid flows through a sinking trough 2, the glass melting liquid falls into a seat sinking trough 3 from a feed inlet 6, then flows through a feed trough 5 and a right sinking trough 4 and finally flows out of a discharge outlet 7, in the process, the glass melting liquid is overturned and stirred in the fall of the feed channel, meanwhile, a motor 15 is started, an output shaft of the motor 15 drives a transmission shaft 19 to rotate, the transmission shaft 19 drives a first bevel gear 21 to rotate, the first bevel gear 21 drives a second bevel gear 22 to rotate, the second bevel gear 22 drives a rotating shaft 16 to rotate, the rotating shaft 16 drives stirring blades 18 to rotate through a rotating seat 17, and the two stirring blades 18 stir the glass melting liquid in the left sinking trough 3 and the right sinking trough 4 in the manner respectively, so that the glass inclusion is diffused and homogenized, the glass inclusion is prevented from being diffused and stirred, then the melting liquid flows into the discharge trough 9 through the connecting trough 8, and then the melting liquid flows out of the discharge outlet 10 to perform next processing.

In sum, through motor 15, drive assembly, stirring leaf 18, sinking formula silo 2, realize carrying out intensive mixing to the glass melt transportation in-process, avoid appearing the incomplete function of homogenization.

The specific embodiments described herein are offered by way of example only to illustrate the spirit of the utility model. Those skilled in the art may make various modifications or additions to the described embodiments or substitutions thereof without departing from the spirit of the utility model or exceeding the scope of the utility model as defined in the accompanying claims.

Claims (7)

1. The utility model provides a formula of sinking material way, includes a plurality of silo units (1), its characterized in that, a plurality of pass through bolt fixed connection between silo unit (1), silo unit (1) fixedly connected with sinking chute (2) on right side, left side sinking chute (3) and right side sinking chute (4) have been seted up in sinking chute (2), feed chute (5) have been seted up between left side sinking chute (3) and right side sinking chute (4), feed inlet (6) have been seted up to left side sinking chute (3) upper end, discharge gate (7) have been seted up to right side sinking chute (4) upper end, connecting groove (8) of sinking chute (2) other end fixedly connected with, connecting groove (8) other end fixedly connected with blown down tank (9), feed opening (10) have been seted up to blown down tank (9) downside.

2. The sinking material channel according to claim 1, characterized in that stirring components are arranged in the feeding hole (6) and the discharging hole (7), each stirring component comprises a base (11), a supporting column (12) is fixedly connected to the base (11), a mounting plate (13) is fixedly connected to the upper end of each supporting column (12), a supporting component is arranged on the left side of each mounting plate (13), a motor base (14) is fixedly connected to the right end of each mounting plate (13), a motor (15) is fixedly connected to the motor base (14), a transmission component is arranged at the output shaft end of each motor (15), a rotating shaft (16) is connected to the corresponding transmission component, a rotating seat (17) is fixedly connected to the corresponding rotating shaft (16), stirring blades (18) of the corresponding rotating seat (17), and the stirring blades (18) of the two stirring components extend into the left sinking groove (3) and the right sinking groove (4) respectively.

3. A sinking material channel according to claim 2, characterized in that the transmission assembly comprises a transmission shaft (19), the transmission shaft (19) is fixedly connected with the output shaft of the motor (15), the other end of the transmission shaft (19) is fixedly connected with a first bevel gear (21), the first bevel gear (21) is meshed with a second bevel gear (22), the second bevel gear (22) is fixedly connected with the rotating shaft (16), and a plurality of stabilizing assemblies are arranged on the transmission shaft (19).

4. A sinking material channel according to claim 3, characterized in that the supporting assembly comprises a supporting ring (20), the supporting ring is fixedly connected to the left end of the mounting plate (13), a bearing groove (23) is formed in the supporting ring (20), a thrust bearing (24) is arranged in the bearing groove (23), a clamping ring (25) is fixedly connected to the rotating shaft (16), and the lower side of the clamping ring (25) is abutted against the thrust bearing (24).

5. A sinking chute according to claim 3, characterized in that the stabilizing assembly comprises a bearing block (26), a radial bearing (27) is arranged on the bearing block (26), and the inner rings of the radial bearings (27) are in contact with the transmission shaft (19).

6. The sinking material channel according to claim 5, wherein the rotating shaft (16) comprises an upper rotating shaft (28) and a lower rotating shaft (29), the upper rotating shaft (28) is in threaded connection with the lower rotating shaft (29), the clamping ring (25) is fixedly connected to the upper rotating shaft (28), and the rotating seat (17) is fixedly connected to the lower end of the lower rotating shaft (29).

7. The sinking material channel according to claim 2, wherein two diagonal braces (30) are fixedly connected to the support column, the upper ends of the two diagonal braces (30) are fixedly connected with the mounting plate (13), and a balancing weight (31) is fixedly connected to the lower side of the right end of the mounting plate (13).