CN108253783B

CN108253783B - Small mesh belt presintering furnace

Info

Publication number: CN108253783B
Application number: CN201810187506.6A
Authority: CN
Inventors: 许锋; 沈在兵; 金宏山
Original assignee: Yangzhou Weida Machinery Co ltd
Current assignee: Yangzhou Weida Machinery Co ltd
Priority date: 2018-03-07
Filing date: 2018-03-07
Publication date: 2023-10-31
Anticipated expiration: 2038-03-07
Also published as: CN108253783A

Abstract

The application discloses a small mesh belt presintering furnace. The device belongs to calcination technical field, has solved among the prior art problem that burn-in stove heating is uneven, sintering quality is low, sintering speed is slow, including the furnace body, run through the guipure of furnace body and locate the drive mechanism at guipure both ends, the furnace body includes the stove outer covering, locates the furnace in the stove outer covering and locates the heating mechanism in the furnace, drive mechanism is including locating the drive structure of furnace front end and locating the driven structure of furnace rear end. According to the application, the spiral heating body is utilized to uniformly heat the green body, so that the quality of a product is improved, the cooling structure is utilized to rapidly cool the workpiece, the requirements of different sintering temperatures are met, the workpiece is conveyed through the mesh belt, the uniformity of the mesh belt pores is utilized, the workpiece is uniformly heated, the deformation of the workpiece is reduced, and the quality of the product is improved.

Description

Small mesh belt presintering furnace

Technical Field

The application belongs to the technical field of calcining devices, and particularly relates to a small mesh belt presintering furnace.

Background

The mesh belt presintering furnace mainly passes through a heating area with temperature control through mechanical transmission to meet the heat treatment or roasting requirements, and mainly comprises a furnace body structure, a mesh belt conveying system, a heating system, a hot air circulation system, a tail gas emission system, an automatic control system and the like, wherein the mesh belt presintering furnace has the characteristics of high production efficiency, low energy consumption, easiness in operation control and the like. The existing mesh belt presintering furnace cannot ensure sintering uniformity, so that uneven workpiece holes or overhigh porosity are easily caused by local temperature difference, and when different types of workpieces are sintered, the hearth temperature is required to be reduced, the consumed time is long, and the production efficiency is low.

Disclosure of Invention

The application aims to provide a small mesh belt presintering furnace which is uniform in heating, high in sintering quality and high in sintering speed.

In order to achieve the technical purpose, the small mesh belt presintering furnace adopts the following technical scheme:

the utility model provides a small-size guipure presintering stove, includes the furnace body, runs through the guipure of furnace body and locates the drive mechanism at guipure both ends, the furnace body includes the stove outer covering, locates the furnace in the stove outer covering and locates the heating mechanism in the furnace, heating mechanism includes the spiral heating member of locating the guipure surface, detects furnace temperature's temperature sensor and reduces furnace temperature's cooling structure, cooling structure is including the cooling chamber of locating the guipure bottom, the cooling chamber bottom is equipped with the flow chamber that is right trapezoid and places, flow chamber surface equipartition has a plurality of flow holes, the flow hole is linked together with the flow post, the flow post height is by high to low the degressive, the flow post surface is equipped with one-way osmotic membrane and its driven structure of arranging in the flow chamber surface, drive mechanism is including locating the drive structure of furnace front end and locating the driven structure of furnace rear end, the main seat surface is around being equipped with the guipure, upper end guipure is connected with driven structure through the guipure, lower end guipure is equipped with the flow channel through the flow channel middle part and is equipped with the flow channel, the end is equipped with the pressure roller from the stand from the bottom through the side of the die, the end is equipped with the outlet from the stand bottom through the pressure roller.

Preferably, the driving structure and the driven structure are provided with supporting seats at the bottoms, universal wheels are arranged at the bottoms of the supporting seats, the supporting seats are respectively arranged at two ends of the fixing seat, the fixing seat is arranged in the furnace body, and the universal wheels are arranged at the bottom of the furnace body. Through setting up the universal wheel, make whole device be convenient for remove, guaranteed the planarization of guipure simultaneously.

Preferably, the heating body is a ceramic body rotating in a spiral shape, heating strips are penetrated in the ceramic body, and a plurality of heat storage holes are distributed on the surface of the ceramic body. The heating body is arranged in a spiral shape, so that the workpiece is heated uniformly, the sintering effect is improved, and meanwhile, the heat storage holes are used for collecting sintering waste heat so as to reduce the loss of reprocessing.

Preferably, an auxiliary agent spraying structure is arranged above the heating body, the auxiliary agent spraying structure comprises a through pipe arranged on the upper portion of the hearth, one end of the through pipe is a movable cavity, the other end of the through pipe is a liquid storage cavity, a spraying cavity is arranged between the movable cavity and the liquid storage cavity, a plurality of spraying holes are formed in the bottom of the spraying cavity, and sintering auxiliary agents are filled in the liquid storage cavity. Through setting up auxiliary agent spray structure to whether carry out auxiliary agent and spray according to the production condition decision, so as to promote sintering speed.

Preferably, the movable plug is arranged at the side part of the movable cavity, the pull rod is arranged at the outer side of the movable plug, and the inserted link arranged in the spraying cavity is arranged at the inner side of the movable plug. The movable plug is pulled by the pull rod, so that the auxiliary agent flows into the spraying cavity.

Preferably, the side part of the liquid storage cavity is provided with a one-way spigot matched with the spigot.

Preferably, the end part of the inlet pipeline is provided with an inlet flange, the inner side of the inlet flange is provided with a pressure equalizing valve, the inner side of the pressure equalizing valve is provided with a chimney, and a protective cover is arranged below the chimney. Through setting up the equalizing valve, guarantee the homogeneity of protective atmosphere and burning atmosphere pressure, avoid the big problem of sintering porosity, utilize the chimney, make the gas that produces in the sintering process effectively discharge.

Preferably, the included angle formed between the inlet flange and the horizontal plane is 45 degrees. By obliquely arranging the inlet flange, the workpiece is slowly adapted to the temperature of the furnace body, and the possibility of overflowing of smoke is reduced.

Preferably, the end part of the outlet pipeline is provided with an outlet flange, and the inner side of the outlet flange is provided with a protective cover. By arranging the protective cover, the surface of the sintered workpiece is prevented from adhering impurities.

Preferably, the included angle formed between the secondary stand and the horizontal plane is 60 degrees. The secondary stand is arranged obliquely, so that the net belt is in slow transition, and the problem of fracture caused by overhigh perpendicularity of the net belt is avoided.

Compared with the prior art, the application has the beneficial effects that:

according to the application, the green body is uniformly heated by the spiral heating body, so that the quality of the product is improved, and the sintering porosity of the product is reduced; the workpiece is rapidly cooled by utilizing the cooling structure, so that the requirements of different sintering temperatures are met, the production efficiency is improved, and the application range is enlarged; the workpieces are transmitted through the mesh belt, the uniformity of the mesh belt holes is utilized, so that the workpieces are heated uniformly, the deformation of the workpieces is reduced, and the quality of products is improved; by arranging the auxiliary agent spraying structure, the sintering speed of the workpiece is accelerated, and the production efficiency is greatly improved.

Drawings

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

fig. 2 is a schematic view of the internal structure of the present application.

In the figure: 1. a mesh belt; 2. a furnace shell; 3. a furnace; 4. a heating body; 5. a temperature sensor; 6. a cooling cavity; 7. a flow chamber; 8. a flow hole; 9. a flow column; 10. a unidirectional osmosis membrane; 11. a main vertical seat; 12. an inlet duct; 13. an isolation frame; 14. a pinch roller; 15. a motor; 16. an outlet conduit; 17. a slave vertical seat; 18. a support base; 19. a universal wheel; 20. a fixing seat; 21. a heat storage hole; 22. a movable cavity; 23. a liquid storage cavity; 24. a spray chamber; 25. spraying holes; 26. a movable plug; 27. a pull rod; 28. a rod; 29. a one-way spigot; 30. an inlet flange; 31. a pressure equalizing valve; 32. a chimney; 33. a protective cover; 34. and an outlet flange.

Detailed Description

The present application is further illustrated in the accompanying drawings and detailed description which are to be understood as being merely illustrative of the application and not limiting of its scope, and various modifications of the application, which are equivalent to those skilled in the art upon reading the application, fall within the scope of the application as defined in the appended claims.

As shown in fig. 1-2, a small mesh belt presintering furnace comprises a furnace body, a mesh belt 1 penetrating through the furnace body and transmission mechanisms arranged at two ends of the mesh belt 1, wherein the furnace body comprises a furnace shell 2, a furnace chamber 3 arranged in the furnace shell 2 and a heating mechanism arranged in the furnace chamber 3, the heating mechanism comprises a spiral heating body 4, a temperature sensor 5 and a cooling structure, wherein the spiral heating body 4 is arranged on the surface of the mesh belt 1, the temperature sensor 5 is used for detecting the temperature of the furnace chamber 3, the cooling structure is used for reducing the temperature of the furnace chamber 3, the heating body 4 is a ceramic body which rotates spirally, heating strips are penetrated in the ceramic body, a plurality of heat storage holes 21 are distributed on the surface of the heating body, an auxiliary agent spraying structure is arranged above the heating body 4, the auxiliary agent spraying structure comprises a through pipe arranged at the upper part of the furnace chamber 3, one end of the through pipe is a movable cavity 22, the other end of the through pipe is a liquid storage cavity 23, a spraying cavity 24 is arranged between the movable cavity 22 and the liquid storage cavity 23, a plurality of spraying holes 25 are arranged at the bottom of the spraying cavity 24, the sintering aid is filled in the liquid storage cavity 23, the movable plug 26 is arranged at the side part of the movable cavity 22, the pull rod 27 is arranged at the outer side of the movable plug 26, the inserting rod 28 arranged in the spraying cavity 24 is arranged at the inner side of the movable plug, the unidirectional inserting nozzle 29 matched with the inserting rod 28 is arranged at the side part of the liquid storage cavity 23, the cooling structure comprises a cooling cavity 6 arranged at the bottom of the mesh belt 1, a flow cavity 7 arranged in a right trapezoid shape is arranged at the bottom of the cooling cavity 6, a plurality of flow holes 8 are uniformly distributed on the surface of the flow cavity 7, the flow holes 8 are communicated with the flow column 9, the height of the flow column 9 decreases from high to low, the unidirectional permeable membrane 10 is arranged on the surface of the flow column 9 and is arranged on the surface of the flow cavity 7, the transmission mechanism comprises a driving structure arranged at the front end of the furnace body and a driven structure arranged at the rear end of the furnace body, the driving structure comprises a main vertical stand 11, the utility model provides a fire-fighting equipment, including main seat 11, upper end guipure 1, lower extreme guipure 1, isolation frame 13, pinch roller 14 are passed through furnace 3 bottom and are connected with driven structure after crossing inlet duct 12 and being connected with the driven structure, isolation frame 13 bottom is equipped with motor 15, driven structure is including locating the outlet duct 16 of furnace body lateral part, be equipped with guipure 1 in the outlet duct 16, guipure 1 is around locating from seat 17 tip and is pressed through the pinch roller 14 from the inboard of seat 17, the contained angle that forms between seat 17 and the horizontal plane is 60, inlet duct 12 tip is equipped with inlet flange 30, and inlet flange 30 inboard is equipped with pressure equalizing valve 31, and pressure equalizing valve 31 inboard is equipped with chimney 32, and the chimney 32 below is equipped with protection casing 33, the contained angle that forms between inlet flange 30 and the horizontal plane is 45, outlet duct 16 tip is equipped with outlet flange 34, and outlet flange 34 inboard is equipped with protection casing 33. Wherein, driving structure and driven structure bottom all are equipped with supporting seat 18, and supporting seat 18 bottom is equipped with universal wheel 19, and fixing base 20 both ends are located respectively to supporting seat 18, and in the furnace body was located to fixing base 20, the furnace body bottom was equipped with universal wheel 19.

When the device is used, a workpiece is placed on the surface of the mesh belt 1, the motor 15 is started, the mesh belt 1 enters from the inlet pipeline 12 and moves towards the outlet pipeline 16, the workpiece on the surface of the mesh belt 1 enters into the hearth 3, the heating body 4 is heated, the temperature sensor 5 detects the current temperature, the heating body 4 is controlled to keep warm and sinter, and the green compact contains carbon elements, so that carbon dioxide and other gases are generated after sintering and are discharged through the chimney 32;

when different products are sintered, the sintering temperature is changed, at the moment, condensate is injected into the flow cavity 7, and flows into the flow column 9 from the flow hole 8, and the height of the flow column 9 decreases from high to low, so that the condensate reaches the top end of the flow column 9 at the same time to absorb heat, the effect of uniform cooling is realized, and gas generated after heat absorption is oozed out from the unidirectional osmosis membrane 10;

in order to accelerate the sintering speed, a liquid phase sintering aid is added into the liquid storage cavity 23, the pull rod 27 pulls the movable plug 26 to move along the liquid storage cavity 23, the insert rod 28 is separated from the one-way insert nozzle 29, the sintering aid flows into the spraying cavity 24 from the liquid storage cavity 23, and then is sprayed on the surface of a workpiece through the spraying holes 25, so that the sintering speed is greatly improved.

Claims

1. The utility model provides a small-size guipure presintering furnace, includes the furnace body, runs through the guipure of furnace body and locates the drive mechanism at guipure both ends, the furnace body includes the stove outer covering, locates the furnace in the stove outer covering and locates the heating mechanism in the furnace, its characterized in that: the heating mechanism comprises a spiral heating body, a temperature sensor and a cooling structure, wherein the spiral heating body is annularly arranged on the surface of a mesh belt, the temperature sensor is used for detecting the temperature of a hearth and the cooling structure is used for reducing the temperature of the hearth, the cooling structure comprises a cooling cavity arranged at the bottom of the mesh belt, a flow cavity which is arranged in a right trapezoid shape is arranged at the bottom of the cooling cavity, a plurality of flow holes are uniformly distributed on the surface of the flow cavity, the flow holes are communicated with a flow column, the height of the flow column decreases from high to low, a unidirectional permeable membrane is arranged on the surface of the flow column and is arranged on the surface of the flow cavity, the transmission mechanism comprises a driving structure arranged at the front end of a furnace body and a driven structure arranged at the rear end of the furnace body, the driving structure comprises a vertical main stand arranged vertically, the surface of the main stand is wound with the mesh belt, the upper end mesh belt traverses the inlet pipeline and is connected with the driven structure through the middle part of the hearth, the lower end mesh belt traverses the isolation frame and is connected with the driven structure through the bottom of the hearth after being pressed by a pressing wheel, the bottom of the isolation frame is provided with a motor, the driven structure comprises an outlet pipeline arranged at the side of the furnace body, the mesh belt is arranged in the outlet pipeline, and the driving structure is wound on the inner side of the slave stand and is pressed by the slave stand; the bottom of the driving structure and the bottom of the driven structure are respectively provided with a supporting seat, the bottoms of the supporting seats are provided with universal wheels, the supporting seats are respectively arranged at two ends of a fixed seat, the fixed seat is arranged in the furnace body, and the bottoms of the furnace bodies are provided with universal wheels; the heating member top is equipped with the auxiliary agent and sprays the structure, and auxiliary agent sprays the structure and including locating the siphunculus on furnace upper portion, siphunculus one end is movable chamber, and the other end is the stock solution chamber, is equipped with between movable chamber and the stock solution chamber and sprays the chamber, sprays the chamber bottom and is equipped with a plurality of holes that spray, and the stock solution intracavity is filled with sintering auxiliary agent.

2. The small mesh belt burn-in furnace of claim 1, wherein: the heating body is a ceramic body which rotates spirally, heating strips are arranged inside the ceramic body in a penetrating mode, and a plurality of heat storage holes are distributed in the surface of the ceramic body.

3. The small mesh belt burn-in furnace of claim 1, wherein: the movable plug is arranged on the side of the movable cavity, the pull rod is arranged on the outer side of the movable plug, and the inserted link arranged in the spraying cavity is arranged on the inner side of the movable plug.

4. A compact web burn-in furnace as claimed in claim 3, wherein: the lateral part of the liquid storage cavity is provided with a one-way spigot matched with the spigot.

5. The small mesh belt burn-in furnace of claim 1, wherein: the end part of the inlet pipeline is provided with an inlet flange, the inner side of the inlet flange is provided with a pressure equalizing valve, the inner side of the pressure equalizing valve is provided with a chimney, and a protective cover is arranged below the chimney.

6. The small mesh belt burn-in furnace of claim 5, wherein: the included angle formed between the inlet flange and the horizontal plane is 45 degrees.

7. The small mesh belt burn-in furnace of claim 1, wherein: the end part of the outlet pipeline is provided with an outlet flange, and the inner side of the outlet flange is provided with a protective cover.

8. The small mesh belt burn-in furnace of claim 1, wherein: the included angle formed between the secondary stand and the horizontal plane is 60 degrees.