CN117504445A - Microcrystalline glass sintering furnace system - Google Patents

Abstract

The invention relates to the technical field of waste gas treatment, in particular to a microcrystalline glass sintering furnace system, which comprises a sintering furnace and an exhaust port arranged on the sintering furnace, wherein an S-shaped ventilating duct is arranged on the exhaust port, dust scraping assemblies are arranged at the wave crest and the wave trough in the ventilating duct, each dust scraping assembly comprises sliding parts respectively arranged at the two sides of the wave crest and the wave trough, and the sliding parts are used for scraping dust particles attached to the inner wall of an arc-shaped duct. In this way, dust particles in the exhaust gas are effectively separated from the gas flow, thereby achieving purification of the exhaust gas.

Description

Microcrystalline glass sintering furnace system

Technical Field

The invention relates to the technical field of waste gas treatment, in particular to a microcrystalline glass sintering furnace system.

Background

The glass ceramic sintering furnace is a special device for preparing glass ceramic. The microcrystalline glass is a novel material, has the advantages of ceramics and glass, has excellent wear resistance, pressure resistance, corrosion resistance and other performances, and is widely applied to the fields of architectural decoration, furniture, artwork and the like. In the preparation process of the microcrystalline glass, the raw materials are required to be sintered at high temperature to form a uniform and fine grain structure, so that the excellent performance of the microcrystalline glass is ensured.

However, conventional sintering furnace systems have some problems. Firstly, a large amount of waste gas can be generated in the sintering process, if the waste gas cannot be effectively treated, the waste gas not only pollutes the environment, but also can influence the health of a human body, and secondly, dust particles in the waste gas can be attached to the inner wall of a pipeline to form dust accumulation due to the influence of factors such as the roughness of the inner wall of the pipeline, the flow rate of the waste gas, the particle size and the like. These deposits not only affect the flow of the exhaust gases, resulting in reduced treatment efficiency, but also require additional manpower and material resources during cleaning, increasing operating costs.

Disclosure of Invention

The invention aims to provide a microcrystalline glass sintering furnace system which is used for solving the problems.

The invention is realized by the following technical scheme:

the utility model provides a glass ceramic fritting furnace system, includes the fritting furnace and sets up the gas vent on the fritting furnace, is provided with the air pipe of S type on the gas vent, and crest and trough department in the air pipe all are provided with scrapes dirt subassembly, scrapes dirt subassembly including the sliding part that sets up in crest, trough both sides respectively, and sliding part is used for scraping the dust particle that moves the adhesion and be the arc pipeline inner wall.

Further, the sliding part comprises a sliding block and a through hole formed along the inner wall of the pipeline, first sliding grooves are formed in the opposite inner walls of the through hole, two ends of the sliding block are respectively located in the two first sliding grooves, a first positioning rod is arranged at the top of the sliding block, a second positioning rod is arranged at the bottom of the sliding block and located in the pipeline, flexible connection cloth is connected to the first positioning rod, the end portion of the flexible connection cloth is connected to the through hole, the flexible connection cloth covers the through hole, a sleeve is arranged on the first positioning rod, a second sliding groove is arranged in the pipeline, the sleeve is matched with the second sliding groove through a moving block, an arc plate is arranged on the sleeve, and the arc plate is in contact with the inner wall of the pipeline.

Further, a discharging hole is formed in the trough of the pipeline and is positioned between the two sliding parts, two overturning plates are hinged in the discharging hole respectively, guide blocks are fixedly connected to two sides of the bottom of each overturning plate respectively, limiting assemblies for limiting the overturning plates are arranged on the guide blocks, and the limiting assemblies are connected with the outer wall of the pipeline through connecting pieces.

Further, spacing subassembly includes first dwang, movable plate and articulates the first deflector on the guide block, first hole of placing has been seted up respectively on two first deflectors, the both ends of first dwang respectively with two first hole sliding connection of placing, and set up on the guide block with first dwang matched with recess, two first deflectors are connected through the second deflector, still set up the second hole of placing on first deflector, the both ends of movable plate are respectively with two second hole sliding connection of placing, and first dwang passes through the bracing piece and is connected with the movable plate, and be provided with first spring and second deflector on the first dwang and be connected, still be provided with the movable assembly on the movable plate, can drive the movable plate through the movable assembly and remove when first locating lever slides.

Further, the movable assembly comprises a first wedge block, a second wedge block and a bearing shell arranged on the outer wall of the pipeline, the first wedge block is connected with a first connecting rod, the first connecting rod movably penetrates through the bearing shell and then outwards extends, a second spring is arranged at the bottom in the bearing shell and sleeved on the first connecting rod, the end part of the second spring is connected with the first wedge block, the second wedge block is fixedly connected with a second connecting rod, the second connecting rod movably penetrates through the bearing shell and then outwards extends, the axes of the first connecting rod and the second connecting rod are vertical, the first wedge block and the second wedge block are matched with each other, the first wedge block and the second wedge block are both in sliding connection with the inner wall of the bearing shell, a third placing hole is formed in the second guide plate, and the first wedge block is connected with the second guide plate after penetrating through the third placing hole through the first connecting rod.

Compared with the prior art, the invention has the following advantages and beneficial effects:

the utility model provides a through the air pipe of S type can increase dust particle and pipeline inner wall' S contact chance, because centrifugal force and inertial effect, contact and attach on pipeline inner wall with pipeline inner wall more easily. In this way, dust particles in the exhaust gas are effectively separated from the airflow, thereby realizing the purification of the exhaust gas; and when the second locating rod drives the sleeve to clean the inner wall of the pipeline, the second locating rod applies acting force to the second connecting rod in the moving process of the second locating rod, so that the second connecting rod drives the first connecting rod to move downwards through the matching of the first wedge block and the second wedge block, and the first connecting rod drives the moving plate to move downwards, so that the situation that the groove on the guide plate is limited by the first rotating rod is relieved, the limit of the turnover plate can be relieved when the inner wall of the pipeline is scraped, the operation is simplified, the task of cleaning the pipeline and removing the limit of the turnover plate can be simultaneously completed in the process of one action operation, the operation time is saved, and the work efficiency is improved.

Drawings

The accompanying drawings, which are included to provide a further understanding of embodiments of the invention and are incorporated in and constitute a part of this application, illustrate embodiments of the invention. In the drawings:

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a schematic view of the structure of the interior of the trough of the pipe according to the present invention;

FIG. 3 is a schematic view of an assembled structure of a first positioning rod and a sleeve according to the present invention;

FIG. 4 is a schematic view of another embodiment of the present invention;

FIG. 5 is a schematic view showing an assembled structure of a first connecting rod and a moving plate according to the present invention;

FIG. 6 is a schematic view of the mating structure of the first and second connection plates of the present invention;

fig. 7 is a schematic diagram of a fitting structure of the pipe and the second positioning rod according to the present invention.

In the drawings, the reference numerals and corresponding part names:

1-a sintering furnace; 2-exhaust port; 3-ventilation ducts; 4-sliding blocks; 5-a through hole; 6-a first chute; 7-a first positioning rod; 8-a second positioning rod; 9-flexible connecting cloth; 10-sleeve; 11-arc-shaped plate; 12-a third placement hole; 13-a flipping panel; 14-a guide block; 15-a first rotating lever; 16-a moving plate; 17-a first guide plate; 18-a first placement hole; 19-grooves; 20-a second guide plate; 21-a second placement hole; 22-supporting rods; 23-a first spring; 24-a first wedge; 25-a second wedge; 26-a carrier shell; 27-a first connecting rod; 28-a second spring; 29-a second connecting rod; 30-a second rotating lever; 31-a first plate; 32-a second plate; 33-a third plate; 34-a first connection plate; 35-a second connection plate; 36-triggering a block; 37-positioning columns; 38-connecting block.

Detailed Description

For the purpose of making apparent the objects, technical solutions and advantages of the present invention, the present invention will be further described in detail with reference to the following examples and the accompanying drawings, wherein the exemplary embodiments of the present invention and the descriptions thereof are for illustrating the present invention only and are not to be construed as limiting the present invention.

Examples:

as shown in fig. 1 to 7, a glass ceramic sintering furnace system comprises a sintering furnace 1 and an exhaust port 2 arranged on the sintering furnace 1, wherein an S-shaped ventilation pipeline 3 is arranged on the exhaust port 2, dust scraping assemblies are arranged at the wave crests and wave troughs in the ventilation pipeline 3, each dust scraping assembly comprises sliding parts respectively arranged at the two sides of the wave crests and the wave troughs, and the sliding parts are used for scraping dust particles attached to the inner wall of an arc-shaped pipeline.

The utility model provides a through air pipe 3 of S type can increase dust particle and pipeline inner wall' S contact chance, because centrifugal force and inertial effect, contact and attach on the pipeline inner wall with the pipeline inner wall more easily. In this way, dust particles in the exhaust gas are effectively separated from the airflow, thereby realizing the purification of the exhaust gas; however, as the speed of the airflow is reduced at the wave crest, the particles are more likely to be deposited therein under the action of gravity; when the particle is at the trough, the particles are easier to deposit under the action of inertia due to the change of the airflow direction. Thus, if cleaned at irregular intervals, dust or particles from both locations accumulate more and more, which may affect the ventilation effect and even cause clogging of the pipes. Therefore, dust particles adhered to the inner wall of the pipeline can be scraped off periodically or continuously by arranging dust scraping assemblies at the wave crests and wave troughs, and ventilation blockage caused by excessive accumulation of dust particles can be prevented. The sliding part can enable the dust scraping assembly to better contact with the inner wall of the pipeline, so that dust scraping efficiency is improved; and dust particles scraped off by the pipeline at the wave crest can fall into the wave trough under the action of gravity. Therefore, the dust particles at the trough often can be more, the sliding pull plate communicated with the outside can be arranged at the trough, and the pull plate is pulled to recover the dust particles at the trough, so that the dust particles are recovered, on one hand, the pollution to the environment can be reduced, on the other hand, the resources can be saved, and the production cost is reduced. The recovery may be by physical means such as sieving, magnetic separation, etc., or by chemical means such as dissolution, precipitation, etc. The recovered particles may be used directly in production or after further processing. After dust particles at the wave trough and the wave crest are removed, pollutants in pollution in waste gas are reduced, and the waste gas treatment effect is improved.

It should be noted that, the sliding part includes sliding block 4 and along the through-hole 5 that the pipeline inner wall was seted up, first spout 6 has been seted up on the relative inner wall of through-hole 5, the both ends of sliding block 4 are located two first spouts 6 respectively, the top of sliding block 4 is provided with first locating lever 7, the bottom of sliding block 4 is provided with second locating lever 8, first locating lever 7 is located the pipeline, second locating lever 8 is located the pipeline outward, and be connected with flexonics cloth 9 on first locating lever 7, flexonics cloth 9's end connection is in through-hole 5, and flexonics cloth 9 covers through-hole 5, be provided with sleeve 10 on first locating lever 7, be equipped with the second spout in the pipeline, sleeve 10 cooperatees through the movable block with the second spout, be provided with arc 11 on the sleeve 10, arc 11 and pipeline inner wall contact.

After the sintering furnace 1 stops working, the second positioning rod 8 can be pulled to drive the sleeve 10 to move on the inner wall of the pipeline through the first positioning rod 7, and the first positioning rod 7 only exceeds the through hole 5 by a small distance, so that the distance between the sleeve 10 and the inner wall of the pipeline can be minimized, the dust particle effect of cleaning the inner wall of the pipeline can be best, the sleeve 10 is matched with the second chute through the moving block, the sleeve 10 can be better adapted to the curvature of the inner wall of the pipeline, and a certain guiding and positioning effect is provided for the sleeve 10; the arc 11 contacts with the pipeline inner wall, can improve and scrape dirt effect, and after the first locating lever 7 of trough department both sides had all been pulled, the dust particle that trough department accumulated is the most this moment, is convenient for clear away together.

It should be noted that, the trough of the pipeline is provided with a discharging hole, the discharging hole is positioned between the two sliding parts, two overturning plates 13 are hinged in the discharging hole respectively, two sides of the bottom of each overturning plate 13 are fixedly connected with guide blocks 14 respectively, the guide blocks 14 are provided with limiting components for limiting the overturning plates 13, and the limiting components are connected with the outer wall of the pipeline through connecting pieces.

The two turnover plates 13 are contacted in the initial state, a relative structure can be arranged on the end face of one turnover plate 13 opposite to the other turnover plate 13 to ensure certain tightness, the structure can be that a first connecting plate 34 is arranged on the upper end face of one turnover plate 13, a second connecting plate 35 is arranged on the lower end face of the other turnover plate 13, and the first connecting plate 34 is in contact fit with the second connecting plate 35, so that tightness is improved. The connecting piece can be a first plate 31, a second plate 32 and a third plate 33, wherein the two ends of the first plate 31 are respectively and vertically connected with the second plate 32 and the third plate 33, and the second plate 32 and the third plate 33 are fixedly connected to the outer wall of the trough of the pipeline, so that the limiting component of the connecting piece is fixed through the first plate 31; because the discharging holes are arranged at the wave troughs, most of dust particles are accumulated on the overturning plates 13, and the two overturning plates 13 are arranged for overturning, so that the dust particles can directly fall into the outside of a pipeline and can be received by a recovery box for recovery; although the pulling plate can open the orifice of the discharging hole to clean the inside of the trough, the dust particles on the pulling plate can move to other places of the pipeline while the pulling plate is pulled, and the overturning plate 13 can directly overturn the accumulated dust particles outside the pipeline instead of moving the dust particles to other places of the pipeline through the pulling plate. Therefore, the cleaning efficiency can be improved, and the pollution to other parts in the cleaning process is reduced.

The two contact-fit turnover plates 13 can form better tightness when closed, and can effectively prevent dust particles from escaping from the discharge hole when not cleaned. The pull plate can not completely conform to the shape of the discharge hole due to the shape, the size and the like, and can not be completely sealed; and the design of the two overturning plates 13 matched with each other in a contact way is relatively simple, and the maintenance is convenient. The pulling plate may be mechanically worn by frequent pulling, requiring more frequent maintenance and replacement.

It should be noted that, the limiting component includes a first rotating rod 15, a moving plate 16 and a first guide plate 17 hinged on the guide block 14, the two first guide plates 17 are respectively provided with a first placement hole 18, two ends of the first rotating rod 15 are respectively connected with the two first placement holes 18 in a sliding manner, the guide block 14 is provided with a groove 19 matched with the first rotating rod 15, the two first guide plates 17 are connected with each other through a second guide plate 20, the first guide plate 17 is also provided with a second placement hole 21, two ends of the moving plate 16 are respectively connected with the two second placement holes 21 in a sliding manner, the first rotating rod 15 is connected with the moving plate 16 through a support rod 22, the first rotating rod 15 is provided with a first spring 23 connected with the second guide plate 20, the moving plate 16 is also provided with a moving component, and the moving plate 16 is driven to move by the moving component when the second positioning rod 8 slides.

The first deflector 17 of this application is connected on first plate body 31, consequently, first deflector 17 carries out fixed connection through first plate body 31 and the outer wall of pipeline, two turndown levers 13 initial condition is the contact down, consequently, first turndown lever 15's initial position is also located recess 19, thereby first turndown lever 15 just can restrict turndown lever 13 through restricting the removal of recess 19 and overturn, pulling second locating lever 8 now, second locating lever 8 can drive movable plate 16 through the removal subassembly when sliding, movable plate 16 slides on second place hole 21 through second turndown lever 30, and because movable plate 16 carries out fixed connection through bracing piece 22 and first turndown lever 15 on movable plate 16, consequently, movable plate 16 can drive first turndown lever 15 and slide in first place hole 18, then first turndown lever 15 has broken away from recess 19 this moment, after the object to recess 19 restriction, turndown lever 13 can drive the guide board and carry out the upset, can set up the handle on the turndown lever 13, conveniently pull turndown lever 13, make it opens two turndown levers 13.

It should be noted that the moving assembly includes a first wedge block 24, a second wedge block 25, and a bearing shell 26 disposed on an outer wall of the pipeline, where the first wedge block 24 is connected with a first connecting rod 27, the first connecting rod 27 movably penetrates through the bearing shell 26 and then extends outwards, a second spring 28 is disposed at the bottom in the bearing shell 26, the second spring 28 is sleeved on the first connecting rod 27, an end of the second spring 28 is connected with the first wedge block 24, the second wedge block 25 is fixedly connected with a second connecting rod 29, the second connecting rod 29 movably penetrates through the bearing shell 26 and then extends outwards, axes of the first connecting rod 27 and the second connecting rod 29 are perpendicular, the first wedge block 24 and the second wedge block 25 are matched with each other, the first wedge block 24 and the second wedge block 25 are both slidably connected with an inner wall of the bearing shell 26, a third placement hole 12 is formed in the second guide plate 20, and the first wedge block 24 is connected with the second guide plate 20 after penetrating through the third placement hole 12.

According to the method, the trigger block 36 can be arranged on the second positioning rod 8, the contact area of the trigger block 36 is mainly enlarged, the trigger block 36 has a certain weight, when the inner wall of a pipeline needs to be cleaned, the second positioning rod 8 drives the trigger block 36 to move, the trigger block 36 contacts with the second connecting rod 29 along a track, the second connecting rod 29 is pushed, so that the second wedge block 25 is driven to move forwards, the second wedge block 25 applies downward pressure to the first wedge block 24, at the moment, the first connecting rod 27 connected to the first wedge block 24 moves downwards, the first connecting rod 27 is an L-shaped rod, the vertical end of the L-shaped rod is connected with the first wedge block 24, the horizontal end of the L-shaped rod is connected with the moving plate 16, therefore, the first connecting rod 27 can drive the moving plate 16 to move downwards, and because the trigger block 36 has a certain weight, a force is constantly generated on the second connecting rod 29, a structure for limiting the movement of the second positioning rod 8 can be arranged on the outer wall of the pipeline in the direction far away from the moving plate 16, the first connecting rod 37 can be arranged, a positioning rod 37 can be arranged, and a connecting rod 38 is matched with the positioning rod 38. When the outer wall is cleaned, the second positioning rod 8 is pulled to an initial state at the beginning, that is, the position where the second positioning rod 8 is matched with the clamping groove, at the moment, no pushing force is applied to the second connecting rod 29, then the overturning plate 13 can be overturned manually, because the first spring 23 returns the elastic force, the first rotating rod 15 slides to the initial position on the first placing hole 18 and is matched with the groove 19, and the first wedge block 24 and the second wedge block 25 are both in sliding connection with the inner wall of the bearing shell 26 so as to ensure the movement track of the first wedge block 24 and the second wedge block 25, and no deviation occurs.

The above-mentioned structure setting can be when only needing clearance pipeline department, pulling second locating lever 8, and when second locating lever 8 drove sleeve 10 clearance pipeline inner wall, second locating lever 8 still has the effect to the effort of second connecting rod 29 production, makes it can remove the spacing condition of guide board upper groove 19 by first swivelling lever 15.

The foregoing description of the embodiments has been provided for the purpose of illustrating the general principles of the invention, and is not meant to limit the scope of the invention, but to limit the invention to the particular embodiments, and any modifications, equivalents, improvements, etc. that fall within the spirit and principles of the invention are intended to be included within the scope of the invention.

Claims (5)

1. The utility model provides a microcrystalline glass fritting furnace system, includes fritting furnace (1) and sets up gas vent (2) on fritting furnace (1), its characterized in that is provided with air pipe (3) of S type on gas vent (2), and crest and trough department in air pipe (3) all are provided with scrapes dirt subassembly, and it includes the sliding part that sets up in crest, trough both sides respectively to scrape dirt subassembly, and sliding part is used for scraping the dust particle that adheres to being the arc pipeline inner wall.

2. The glass ceramic sintering furnace system according to claim 1, wherein the sliding component comprises a sliding block (4) and a through hole (5) formed along the inner wall of the pipeline, the opposite inner wall of the through hole (5) is provided with a first sliding groove (6), two ends of the sliding block (4) are respectively positioned in the two first sliding grooves (6), the top of the sliding block (4) is provided with a first positioning rod (7), the bottom of the sliding block (4) is provided with a second positioning rod (8), the first positioning rod (7) is positioned in the pipeline, the second positioning rod (8) is positioned outside the pipeline, the first positioning rod (7) is connected with a flexible connecting cloth (9), the end part of the flexible connecting cloth (9) is connected in the through hole (5), the flexible connecting cloth (9) covers the through hole (5), the first positioning rod (7) is provided with a sleeve (10), the pipeline is internally provided with a second sliding groove, the sleeve (10) is matched with the second sliding groove through the moving block, the sleeve (10) is provided with an arc-shaped plate (11), and the arc-shaped plate (11) is contacted with the inner wall of the pipeline.

3. The glass ceramic sintering furnace system according to claim 1, wherein a discharging hole is formed in a trough of the pipeline, the discharging hole is positioned between two sliding parts, two overturning plates (13) are hinged in the discharging hole respectively, guide blocks (14) are fixedly connected to two sides of the bottom of each overturning plate (13), limiting components for limiting the overturning plates (13) are arranged on the guide blocks (14), and the limiting components are connected with the outer wall of the pipeline through connecting pieces.

4. A glass ceramic sintering furnace system according to claim 3, characterized in that the limiting component comprises a first rotating rod (15), a moving plate (16) and first guide plates (17) hinged on the guide blocks (14), wherein the two first guide plates (17) are respectively provided with a first placing hole (18), two ends of the first rotating rod (15) are respectively connected with the two first placing holes (18) in a sliding mode, the guide blocks (14) are provided with grooves (19) matched with the first rotating rod (15), the two first guide plates (17) are connected through second guide plates (20), the first guide plates (17) are also provided with second placing holes (21), two ends of the moving plate (16) are respectively connected with the two second placing holes (21) in a sliding mode, the first rotating rod (15) is connected with the moving plate (16) through support rods (22), the first rotating rod (15) is provided with a first spring (23) to be connected with the second guide plates (20), and the moving plate (16) is further provided with a second guide plate (20) to drive the moving component (8) to move when the moving component (8) is arranged on the moving plate.

5. The glass ceramic sintering furnace system according to claim 4, wherein the moving assembly comprises a first wedge block (24), a second wedge block (25) and a bearing shell (26) arranged on the outer wall of the pipeline, the first wedge block (24) is connected with a first connecting rod (27), the first connecting rod (27) movably penetrates through the bearing shell (26) and then extends outwards, a second spring (28) is arranged at the bottom in the bearing shell (26), the second spring (28) is sleeved on the first connecting rod (27), the end part of the second spring (28) is connected with the first wedge block (24), the second wedge block (25) is fixedly connected with a second connecting rod (29), the second connecting rod (29) movably penetrates through the bearing shell (26) and then extends outwards, the axes of the first connecting rod (27) and the second connecting rod (29) are perpendicular, the first wedge block (24) and the second wedge block (25) are matched with the bearing shell, the first wedge block (24) and the second wedge block (25) are both connected with the inner wall of the bearing shell (26) in a sleeved mode, the second wedge block (25) and a third guide plate (20) is arranged on the second wedge block (20) in a sliding mode, and the second guide plate (20) is arranged on the second guide plate (20) and penetrates through the third guide plate (20).