CN215113927U - High-temperature sintering device for improving water gap firing efficiency - Google Patents

Abstract

The utility model discloses an efficiency is fired at improvement mouth of a river high temperature sintering device relates to machining technical field. The utility model discloses an unloading mechanism, melting mechanism, wait static pressure mechanism, sintering mechanism, transport mechanism, bottom mechanism and dust removal mechanism, wherein one side of unloading mechanism is provided with dust removal mechanism, the below and the melting mechanism fixed connection of unloading mechanism, the below and the isostatic pressure mechanism fixed connection of melting mechanism, the below and the sintering mechanism fixed connection of isostatic pressure mechanism, sintering mechanism's inside and transport mechanism swing joint, sintering mechanism's below and bottom mechanism fixed connection, the inside and the transport mechanism fixed connection of bottom mechanism. The utility model discloses an unloading mechanism, melting mechanism, wait static pressure mechanism, sintering mechanism, transport mechanism, bottom mechanism and dust removal mechanism have solved current mouth of a river preparation flow and have linked up inseparable, lack conveying tool and the inhomogeneous problem of sintering.

Description

High-temperature sintering device for improving water gap firing efficiency

Technical Field

The utility model belongs to the technical field of machining, especially, relate to an improve mouth of a river and fire high temperature sintering device of efficiency.

Background

The gate is a joint between a frame and a part formed when a mold is poured in a factory, and is also called a "gate" (gate), which means an inlet and an outlet through which a heated liquid material flows. The inclination angle types of the water ports are roughly divided into three types, wherein the stream inclination angle of the oval water port is the largest, the average value reaches 38 degrees, the stream impact depth is deeper, the formed lower reflux is developed, the upper reflux is relatively weaker, and the liquid level is calmer; on the contrary, the stream inclination angle of the square water gap is the smallest, the average value is about 21 degrees, the stream impact depth is shallow, a well-developed upper reflux is formed, and the liquid level fluctuation is the most severe; the inclination angle of the stream of the rectangular nozzle is centered, the stream can form upper and lower reflux with a more centered developed degree after impacting a narrow surface, and the liquid level fluctuation condition is also centered. As nozzles are often utilized in the construction and machinery fields, nozzles have been of interest in these fields and in connection with practical applications have found some drawbacks:

1. the existing water gap is lack of smooth flow in the production and manufacturing process, the connection between the processes is not tight, flaws are easy to remain when the water gap is manufactured, the water gap with the flaws can influence the use and water delivery effects of the water gap, the service life is greatly shortened, and the later-stage sale is not facilitated;

2. the existing nozzle lacks internal transportation means in the production and manufacturing process, and the lack of the tools also causes the non-connectability between the steps, only one step can be completed and then transferred to another step, but the transportation is not directly completed in the whole process, so that the time is wasted, and the risk of the nozzle is increased.

3. The nozzle in the prior nozzle production and manufacturing process is generally in a baking or hot drying mode during sintering, the nozzle in the device is fixed and cannot move, the bottom part is ignored during sintering, the whole nozzle can present different sintering schedules along with the sintering, the sintering time is prolonged, and the unevenness of internal substances can be caused.

Therefore, the prior nozzle can not meet the requirement in practical use, so that the improved technology is urgently needed in the market to solve the problems.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an improve high temperature sintering device of efficiency is fired at mouth of a river through unloading mechanism, melting mechanism, wait static pressure mechanism, sintering mechanism, transport mechanism, bottom mechanism and dust removal mechanism, has solved current mouth of a river preparation flow and has linked up inseparable, lack conveying tool and the inhomogeneous problem of sintering.

In order to solve the technical problem, the utility model discloses a realize through following technical scheme:

the utility model relates to an improve mouth of a river and fire high temperature sintering device of efficiency, including unloading mechanism, melting mechanism, isostatic pressing mechanism, sintering mechanism, transport mechanism, bottom mechanism and dust removal mechanism, one side of unloading mechanism is provided with dust removal mechanism, and unloading mechanism is the mechanism that mouth of a river raw materials drops into, is used for enlarging the port area of feeding, accelerates the input of concrete raw materials, prevents unrestrained of raw materials, and dust removal mechanism is the mechanism of flue gas dust fall, is used for detaching dust and harmful gas in the flue gas, prevents that harmful gas from getting into the space, influences the atmospheric environment, the below and the melting mechanism fixed connection of unloading mechanism, melting mechanism is the mechanism that mouth of a river raw materials melts, is used for receiving to melt the mouth of a river raw materials of input, provides raw materials supply for the preparation of mouth of a river, melting mechanism's below and isostatic pressing mechanism fixed connection, isostatic pressing mechanism is the comprehensive press forming mechanism of mouth of a river, the lower part of the isostatic pressing mechanism is fixedly connected with a sintering mechanism, the sintering mechanism is a fired structure of the nozzle and can comprehensively reinforce the nozzle to improve the overall stability of the nozzle, the inner part of the sintering mechanism is movably connected with a conveying mechanism, the conveying mechanism is fixed in the device and is an integral internal conveying mechanism used for assisting the structures to complete the manufacture of the nozzle, the lower part of the sintering mechanism is fixedly connected with a bottom mechanism, the inner part of the bottom mechanism is fixedly connected with the conveying mechanism, the bottom mechanism is a place for taking out products, fixing a fan and fixing a motor, and is a supporting base of the integral structure to play a role in supporting the whole.

Furthermore, the blanking mechanism comprises a hopper, a vibrator, a bracket, a communicating pipe, a sealing plate and a sliding plate structure, one side of the hopper is fixedly connected with a bracket, the upper part of the bracket is fixedly connected with a vibrator, one side of the vibrator is fixedly connected with the hopper through a communicating pipe, a sealing plate is connected below the hopper in a sliding way, the one end and the slide structure fixed connection of closing plate, the hopper is used for accepting and receiving the mouth of a river raw materials, provides the input for the raw materials, and the decline of raw materials can be accelerated to the vibrations effect of electromagnetic shaker, prevents that the transition of raw materials from piling up, and the support is used for providing support and fixed platform for the electromagnetic shaker, guarantees the stability of operation in-process, and the closing plate is used for sealing the material mouth, prevents that the gas in the hot melt storehouse is exported by the hopper, and the slide structure is the power end of closing plate, is used for providing power and holding power for the slide.

Further, the melting mechanism comprises a high-temperature resistant shell, a material port, a hot melting bin, a heating plate, a waste residue pipe, an oxidant pipe and an oxidation bin, the upper surface of the high-temperature resistant shell is provided with a material port, the lower part of the material port is communicated with the hot melting bin, a heating plate is arranged in the high-temperature resistant shell, a waste residue pipe is fixedly connected with one side of the high-temperature resistant shell, the utility model discloses a high temperature resistant shell, including high temperature resistant shell, oxidation storehouse, hot melt storehouse, heating plate, the below and the oxidation storehouse fixed connection of high temperature resistant shell, one side fixedly connected with oxidant pipe in oxidation storehouse, high temperature resistant shell is used for sealing the internal environment, prevents the diffusion of steam, and the material mouth is the port of raw materials input, and the hot melt storehouse is the molten space place of raw materials, and the heating plate is the heating device of melting mechanism, is used for providing sufficient temperature for the melting of raw materials, and the waste residue pipe is the pipeline of raw materials waste residue output, and the oxidant pipe is the pipeline of oxidant input, and the oxidation storehouse is the place of oxidant and molten raw materials oxidation reaction.

The isostatic pressing mechanism further comprises a high-pressure shell, a die frame, a rubber film for forming, a rubber film for pressurizing and a high-pressure gas pipe, wherein the high-pressure gas pipe is fixedly connected to one side of the high-pressure shell, the rubber film for pressurizing is fixedly connected to the inside of the high-pressure shell, the rubber film for forming is movably connected to the inside of the rubber film for pressurizing, the die frame is fixedly connected to the inside of the rubber film for forming, the high-pressure shell is used for sealing the internal high-pressure environment and preventing pressure leakage, the die frame is a die of a water gap, the rubber film for forming can compact the die and prevent the die from loosening under the action of external pressure, the rubber film for pressurizing is an outer stressed film and is used for receiving pressure and slowing down pressure transmission, and the high-pressure gas pipe is a pipeline for inputting high-pressure gas.

Further, sintering mechanism includes lagging casing, electrothermal tube, protection network, base station, tuber pipe and fan, lagging casing's inside fixedly connected with protection network, the below and the base station fixed connection of protection network, the inside of protection network is provided with the electrothermal tube, the below and the base station fixed connection of electrothermal tube, the below and the tuber pipe fixed connection of base station, the one end and the fan fixed connection of tuber pipe, lagging casing are used for preventing scattering and disappearing of the inside temperature of mechanism, and the electrothermal tube is used for providing sufficient heat for the sintering, and the protection network is the outside inoxidizing coating of electrothermal tube, and the base station is protection network and electrothermal tube fixed connection's base plate, and the tuber pipe is the pipeline that the wind was carried, and the fan is used for providing the wind regime for the sintering.

Further, transport mechanism is including accepting seat, push rod, sliding construction, spliced pole, mount and motor, accept one side and the push rod fixed connection of seat, the below and the sliding construction fixed connection of push rod, the below and the spliced pole fixed connection of sliding construction, the below and the motor fixed connection of spliced pole, the outside and the mount fixed connection of motor, the upper end swing joint of accepting the seat is used for providing the base for the mould in the inside of mould frame, and the push rod is used for pushing away the effect of rubber membrane for breaking away from at the mouth of a river, and sliding construction is the control mechanism and the power unit of push rod, and the connecting rod is lifting and rotatory motor connecting rod, and the mount is used for providing fixedly and supporting for the motor, and the motor is transport mechanism power unit.

Further, bottom mechanism includes the finished product storehouse, gets thing door and base, one side in finished product storehouse is provided with gets the thing door, the below and the base fixed connection in finished product storehouse, the finished product storehouse is the storage storehouse that the mouth of a river arrived at last, gets the thing door and is the port that the mouth of a river was taken out, and the base is the fixed place of motor and fan.

Furthermore, the dust removal mechanism comprises an air outlet, a dust remover, a melting pipe, a conveying pipe, a high-pressure pipe and a sintering pipe, wherein the lower part of the air outlet is fixedly connected with the dust remover, the lower part of the dust remover is fixedly connected with the hot melting pipe, one side of the dust remover is fixedly connected with the conveying pipe, one side of the conveying pipe is fixedly connected with the high-pressure pipe, one end of the conveying pipe is fixedly connected with the sintering pipe, the air outlet is a port for discharging dust-removed gas, the dust remover is used for treating dust gas and harmful gas and preventing the harmful gas from entering the atmosphere, the melting pipe is connected with the melting mechanism and used for outputting smoke of the melting mechanism, the conveying pipe is a conveying main pipe, the high-pressure pipe is connected with an isostatic pressure mechanism and used for outputting smoke of the isostatic pressure mechanism, and the sintering pipe is connected with the sintering mechanism and used for outputting smoke of the sintering mechanism.

The utility model discloses following beneficial effect has:

1. the utility model discloses a blanking mechanism, the melting mechanism, wait the hydrostatic pressure mechanism, the sintering mechanism, the transport mechanism, bottom mechanism and dust removal mechanism, the untight problem of present mouth of a river preparation flow linking has been solved, blanking mechanism is the mechanism that mouth of a river raw materials dropped into, a port area for enlarging the feeding, accelerate the input of concrete raw materials, prevent unrestrained of raw materials, dust removal mechanism is the mechanism of flue gas dust fall, be used for detaching dust and harmful gas in the flue gas, prevent that harmful gas from getting into the space, influence the atmospheric environment, the melting mechanism is the mechanism that mouth of a river raw materials melts, a mouth of a river raw materials for receiving to melt and put in, provide raw materials for the preparation of mouth of a river, pressing mechanism is the mechanism of mouth of a river comprehensive press forming, be used for carrying out the primary forming to the mouth of a river, and be used for promoting the whole hole scouring performance of mouth of a river, sintering mechanism is the firing structure of mouth of a river, can consolidate comprehensively the mouth of a river, promote the whole steadiness of mouth of a river, transport mechanism fixes the inside at the device, be the inside transport mechanism of integral structure, be used for assisting each structure and accomplish the preparation to the mouth of a river, bottom mechanism is that the product takes out, the fixed place with the motor of fan, be overall structure's supporting pedestal, play to holistic supporting role, through unloading mechanism, melting mechanism, wait that static pressure mechanism, sintering mechanism, transport mechanism, cooperation between bottom mechanism and the dust removal mechanism, the design of integrated integration, can strengthen the compact type between the structure greatly, the efficiency of preparation is improved.

2. The utility model discloses a conveying mechanism and bottom mechanism, the problem of current mouth of a river preparation lack conveying tool has been solved, conveying mechanism is including accepting the seat, the push rod, sliding structure, the spliced pole, mount and motor, the upper end swing joint who accepts the seat is in the inside of mould frame, be used for providing the base for the mould, the push rod is used for pushing away the effect of rubber membrane, accelerate breaking away from at the mouth of a river, sliding structure is control mechanism and the power unit of push rod, the connecting rod is lifting and rotatory motor connecting rod, the mount is used for providing fixed and support for the motor, the motor is conveying mechanism power unit, base mechanism is used for the fixed motor, provide power through the motor, the spliced pole pulls, realize the transportation at the mouth of a river.

3. The utility model discloses a sintering mechanism and transport mechanism, the inhomogeneous problem of current mouth of a river preparation sintering has been solved, sintering mechanism includes lagging casing, the electrothermal tube, the protection network, the base station, tuber pipe and fan, lagging casing is used for preventing scattering and disappearing of the inside temperature of mechanism, the electrothermal tube is used for providing sufficient heat for the sintering, the protection network is the outside inoxidizing coating of electrothermal tube, the base station is protection network and electrothermal tube fixed connection's base plate, the tuber pipe is the pipeline that the wind was carried, the fan is used for providing the wind regime for the sintering, the drive of rethread transport mechanism's motor is rotatory, can evenly fire the surface at the mouth of a river, in order to reach the best effect of firing.

Of course, it is not necessary for any particular product to achieve all of the above-described advantages at the same time.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without creative efforts.

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

FIG. 2 is a schematic view of the present invention;

FIG. 3 is a schematic view of the blanking mechanism of the present invention;

FIG. 4 is a schematic view of the melting mechanism of the present invention;

FIG. 5 is a schematic view of the isostatic pressing mechanism of the present invention;

fig. 6 is a schematic view of the sintering mechanism and the transportation mechanism of the present invention.

In the drawings, the components represented by the respective reference numerals are listed below:

1. a blanking mechanism; 101. a hopper; 102. a vibrator; 103. a support; 104. a communicating pipe; 105. a closing plate; 106. a slide plate structure; 2. a melting mechanism; 201. a high temperature resistant housing; 202. a material port; 203. a hot melting bin; 204. heating plates; 205. a waste pipe; 206. an oxidant tube; 207. an oxidation bin; 3. an isostatic mechanism; 301. a high pressure housing; 302. a mold frame; 303. a rubber film for molding; 304. a rubber film for pressurization; 305. a high pressure gas pipe; 4. a sintering mechanism; 401. a heat-insulating shell; 402. an electric heating tube; 403. a protective net; 404. a base station; 405. an air duct; 406. a fan; 5. a transport mechanism; 501. a bearing seat; 502. a push rod; 503. a sliding structure; 504. connecting columns; 505. a fixed mount; 506. a motor; 6. a bottom mechanism; 601. a finished product warehouse; 602. a fetching door; 603. a base; 7. a dust removal mechanism; 701. an air outlet; 702. a dust remover; 703. a fusion pipe; 704. a delivery pipe; 705. a high pressure pipe; 706. and (4) sintering the tube.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Referring to fig. 1-6, the present invention relates to a high temperature sintering device for improving the firing efficiency of a nozzle, which comprises a blanking mechanism 1, a melting mechanism 2, an isostatic pressing mechanism 3, a sintering mechanism 4, a transporting mechanism 5, a bottom mechanism 6 and a dust removing mechanism 7, wherein one side of the blanking mechanism 1 is provided with the dust removing mechanism 7, one side of a hopper 101 of the blanking mechanism 1 is provided with an air outlet 701 and a dust remover 702 of the dust removing mechanism 7, the lower part of the blanking mechanism 1 is fixedly connected with the melting mechanism 2, the lower part of the hopper 101 of the blanking mechanism 1 is fixedly connected with a high temperature resistant shell 201 of the melting mechanism 2, the lower part of the melting mechanism 2 is fixedly connected with the isostatic pressing mechanism 3, the lower part of an oxidation bin 207 of the melting mechanism 2 is fixedly connected with a high pressure shell 301 of the isostatic pressing mechanism 3, the lower part of the isostatic pressing mechanism 3 is fixedly connected with the sintering mechanism 4, the lower part of the high pressure shell 301 of the isostatic pressing mechanism 3 is fixedly connected with a heat preservation shell 401 of the sintering mechanism 4, the inside of the sintering mechanism 4 is movably connected with the conveying mechanism 5, the bearing seat 501, the push rod 502, the sliding structure 503 and the connecting column 504 of the conveying mechanism 5 are placed in the heat insulation shell 401 of the sintering mechanism 4, the lower portion of the sintering mechanism 4 is fixedly connected with the bottom mechanism 6, the lower portion of the heat insulation shell 401 of the sintering mechanism 4 is fixedly connected with the finished product bin 601 of the bottom mechanism 6, the inside of the bottom mechanism 6 is fixedly connected with the conveying mechanism 5, and the inside of the base 603 of the bottom mechanism 6 is fixedly connected with the motor 506 of the conveying mechanism 5.

As shown in fig. 1-3, the blanking mechanism 1 includes a hopper 101, a vibrator 102, a bracket 103, a communicating pipe 104, a sealing plate 105 and a sliding plate structure 106, the bracket 103 is fixedly connected to one side of the hopper 101, the upper side of the bracket 103 is fixedly connected to the vibrator 102, one side of the vibrator 102 is fixedly connected to the hopper 101 through the communicating pipe 104, the sealing plate 105 is slidably connected to the lower side of the hopper 101, one end of the sealing plate 105 is fixedly connected to the sliding plate structure 106, one side of the hopper 101 is fixedly connected to the vibrator 102 through the communicating pipe 104, the sliding plate structure 106 is arranged below the bracket 103, the sliding plate structure 106 is slidably connected to the sealing plate 105, and one end of the sealing plate 105 is semicircular.

As shown in fig. 1, 2 and 4, the melting mechanism 2 includes a high temperature resistant housing 201, a material port 202, a hot melting bin 203, a heating plate 204, a waste residue pipe 205, an oxidant pipe 206 and an oxidation bin 207, the upper surface of the high temperature resistant housing 201 is provided with the material port 202, the lower part of the material port 202 is communicated with the hot melting bin 203, the heating plate 204 is arranged inside the high temperature resistant housing 201, one side of the high temperature resistant housing 201 is fixedly connected with the waste residue pipe 205, the lower part of the high temperature resistant housing 201 is fixedly connected with the oxidation bin 207, one side of the oxidation bin 207 is fixedly connected with the oxidant pipe 206, a small semicircular pore passage of the heating plate 204 is arranged inside the high temperature resistant housing 201, a fixing space of the waste residue pipe 205 is reserved between the two heating plates 204, the material port 202 is arranged in the middle of the upper surface of the melting mechanism 2 and is communicated, the space inside the oxidation bin 207 is provided with a melting raw material pore on the upper surface, and a pore corresponding to the isostatic pressing mechanism 3 on the lower surface, the upper end is provided with a gas outlet 701 which is communicated with a melting pipe 703.

As shown in fig. 1, 2 and 5, the isostatic pressing mechanism 3 includes a high-pressure housing 301, a mold frame 302, a molding rubber film 303, a pressurizing rubber film 304 and a high-pressure gas pipe 305, wherein one side of the high-pressure housing 301 is fixedly connected with the high-pressure gas pipe 305, the inside of the high-pressure housing 301 is fixedly connected with the pressurizing rubber film 304, the inside of the pressurizing rubber film 304 is movably connected with the molding rubber film 303, the inside of the molding rubber film 303 is fixedly connected with the mold frame 302, the mold frame 302 in the high-pressure housing 301 corresponds to a hole of the oxidation bin 207, the bottom of the mold frame 302 is movably connected with a receiving seat 501 of the transportation mechanism 5, one half of the receiving seat 501 is submerged into the mold frame 302, and one side of the high-pressure housing 301 is fixedly connected and communicated with a high-pressure pipe 705 of the dust removal mechanism 7.

As shown in fig. 1, 2, and 6, the sintering mechanism 4 includes a thermal insulation housing 401, an electric heating pipe 402, a protective net 403, a base 404, an air pipe 405, and a fan 406, the protective net 403 is fixedly connected to the interior of the thermal insulation housing 401, the lower portion of the protective net 403 is fixedly connected to the base 404, the electric heating pipe 402 is disposed inside the protective net 403, the lower portion of the electric heating pipe 402 is fixedly connected to the base 404, the lower portion of the base 404 is fixedly connected to the air pipe 405, one end of the air pipe 405 is fixedly connected to the fan 406, one side of the thermal insulation housing 401 is fixedly connected to and intercommunicated with a sintering pipe 706 of the dust removing mechanism 7, the bottom of the electric heating pipe 402 is fixed to the base 404, the protective net 403 surrounds the periphery of the base 404, the middle of the base 404 is hollow, the base 404 is fixedly connected to and intercommunicated with the air pipe 405, and the fan 406 is fixed to the base 603 of the bottom mechanism 6.

As shown in fig. 1, 2 and 6, the transportation mechanism 5 includes a bearing seat 501, a push rod 502, a sliding structure 503, a connecting column 504, a fixing frame 505 and a motor 506, one side of the bearing seat 501 is fixedly connected with the push rod 502, the lower part of the push rod 502 is fixedly connected with the sliding structure 503, the lower part of the sliding structure 503 is fixedly connected with the connecting column 504, the lower part of the connecting column 504 is fixedly connected with the motor 506, the outer side of the motor 506 is fixedly connected with the fixing frame 505, the outer side of the bearing seat 501 is movably connected with four push rods 502, the connecting end of the push rod 502 and the bearing seat 501 is provided with a sliding chute, the sliding chute is arranged at a position close to the upper surface of the bearing seat 501 and is not exposed, the sliding chute of the sliding structure 503 is arranged at the upper surface, the maximum lifting length of the connecting column 504 corresponding to the sliding slot on the bearing seat 501 can be up to the bottom of the mold frame 302, and the fixing frame 505 and the motor 506 are fixed in the base 603 of the bottom mechanism 6.

As shown in fig. 1-2, the bottom mechanism 6 includes a finished product bin 601, an object taking door 602 and a base 603, the object taking door 602 is disposed on one side of the finished product bin 601, the lower portion of the finished product bin 601 is fixedly connected to the base 603, a pipeline of an air pipe 405 and a pipeline of a connecting column 504 are disposed at the bottom of the finished product bin 601, the object taking door 602 is parallel to the bottom of the lowered nozzle, the height of the object taking door is the same as that of the nozzle, and the base 603 is hollow.

As shown in fig. 1-2, the dust removing mechanism 7 includes an air outlet 701, a dust remover 702, a melting pipe 703, a delivery pipe 704, a high-pressure pipe 705 and a sintering pipe 706, the lower portion of the air outlet 701 is fixedly connected with the dust remover 702, the lower portion of the dust remover 702 is fixedly connected with the melting pipe 703, one side of the dust remover 702 is fixedly connected with the delivery pipe 704, one side of the delivery pipe 704 is fixedly connected with the high-pressure pipe 705, one end of the delivery pipe 704 is fixedly connected with the sintering pipe 706, the air outlet 701 is an exhaust pipe disposed on the upper surface of the dust remover 702, one side of the melting pipe 703 is communicated with the delivery pipe 704, and the delivery pipe 704 is sequentially fixedly communicated with the high-pressure pipe 705 and the sintering pipe 706.

One specific application of this embodiment is: the starting device is used for pouring raw materials into the hopper 101, the raw materials rapidly slide into the hot melting bin 203 under the action of the vibrator 102 by the hopper 101, after the raw materials enter, the sealing plate 105 is sealed, the raw materials entering the hot melting bin 203 are heated continuously by the heating plate 204 and gradually heated to melt, the melted raw materials enter the oxidation bin 207, the mixed raw materials are input into the mold frame 302 through the oxidant shaping substance input through the oxidant pipe 206, the mixed raw materials are input into the mold frame 302, the high-pressure gas is input through the high-pressure gas pipe 305 to gradually increase the pressure, the pressure firstly acts on the rubber film 304 for pressurization, the pressure is received and the pressure is reduced to be transmitted to the rubber film 303 for molding, the rubber film 303 for molding is used for compacting the mold frame 302 under the action of the external pressure, the compacted raw materials are pulled to descend by the conveying mechanism 5 and descend into the sintering mechanism 4 for the first time, the electric heating pipe 402 in the sintering mechanism 4 generates heat, and the wind generated by the wind machine 406 is blown to the periphery, in the baking process, the connecting column 504 slowly rotates under the action of the motor 506, and after the baking is finished, the connecting column is lowered into the finished product bin 601 for the second time, so that the water gap manufacturing is finished.

The above is only the preferred embodiment of the present invention, and the present invention is not limited thereto, any technical solutions recorded in the foregoing embodiments are modified, and some technical features thereof are replaced with equivalent ones, and any modification, equivalent replacement, and improvement made thereby all belong to the protection scope of the present invention.

Claims (8)

1. The utility model provides an efficiency is fired at improvement mouth of a river high temperature sintering device, includes unloading mechanism (1), melting mechanism (2), waits hydrostatic pressure mechanism (3), sintering mechanism (4), transport mechanism (5), bottom mechanism (6) and dust removal mechanism (7), its characterized in that: one side of unloading mechanism (1) is provided with dust removal mechanism (7), the below and the melting mechanism (2) fixed connection of unloading mechanism (1), the below and the quiet pressure mechanism (3) fixed connection of melting mechanism (2), the below and the sintering mechanism (4) fixed connection of quiet pressure mechanism (3) wait, the inside and transport mechanism (5) swing joint of sintering mechanism (4), the below and bottom mechanism (6) fixed connection of sintering mechanism (4), the inside and transport mechanism (5) fixed connection of bottom mechanism (6).

2. The high-temperature sintering device for improving the firing efficiency of the nozzle as claimed in claim 1, wherein the blanking mechanism (1) comprises a hopper (101), a vibrator (102), a bracket (103), a communicating pipe (104), a closing plate (105) and a sliding plate structure (106), the bracket (103) is fixedly connected to one side of the hopper (101), the upper side of the bracket (103) is fixedly connected to the vibrator (102), one side of the vibrator (102) is fixedly connected to the hopper (101) through the communicating pipe (104), the closing plate (105) is slidably connected to the lower side of the hopper (101), and one end of the closing plate (105) is fixedly connected to the sliding plate structure (106).

3. The high-temperature sintering device for improving the firing efficiency of the nozzle of.

4. The high-temperature sintering device for improving the firing efficiency of the nozzle according to claim 1, wherein the isostatic pressing mechanism (3) comprises a high-pressure housing (301), a mold frame (302), a molding rubber membrane (303), a pressurizing rubber membrane (304) and a high-pressure gas pipe (305), the high-pressure gas pipe (305) is fixedly connected to one side of the high-pressure housing (301), the pressurizing rubber membrane (304) is fixedly connected to the inside of the high-pressure housing (301), the molding rubber membrane (303) is movably connected to the inside of the pressurizing rubber membrane (304), and the mold frame (302) is fixedly connected to the inside of the molding rubber membrane (303).

5. The high-temperature sintering device for improving the nozzle firing efficiency according to claim 1, wherein the sintering mechanism (4) comprises a heat-insulating housing (401), an electric heating pipe (402), a protective screen (403), a base (404), an air pipe (405) and a fan (406), the protective screen (403) is fixedly connected to the inside of the heat-insulating housing (401), the lower portion of the protective screen (403) is fixedly connected to the base (404), the electric heating pipe (402) is arranged inside the protective screen (403), the lower portion of the electric heating pipe (402) is fixedly connected to the base (404), the lower portion of the base (404) is fixedly connected to the air pipe (405), and one end of the air pipe (405) is fixedly connected to the fan (406).

6. The high-temperature sintering device for improving the nozzle firing efficiency as claimed in claim 1, wherein the transportation mechanism (5) comprises a bearing seat (501), a push rod (502), a sliding structure (503), a connecting column (504), a fixing frame (505) and a motor (506), one side of the bearing seat (501) is fixedly connected with the push rod (502), the lower part of the push rod (502) is fixedly connected with the sliding structure (503), the lower part of the sliding structure (503) is fixedly connected with the connecting column (504), the lower part of the connecting column (504) is fixedly connected with the motor (506), and the outer side of the motor (506) is fixedly connected with the fixing frame (505).

7. The high-temperature sintering device for improving the nozzle firing efficiency as claimed in claim 1, wherein the bottom mechanism (6) comprises a finished product bin (601), an extraction door (602) and a base (603), the extraction door (602) is arranged on one side of the finished product bin (601), and the lower part of the finished product bin (601) is fixedly connected with the base (603).

8. The high-temperature sintering device for improving the nozzle firing efficiency according to claim 1, wherein the dust removing mechanism (7) comprises an air outlet (701), a dust remover (702), a melting pipe (703), a delivery pipe (704), a high-pressure pipe (705) and a sintering pipe (706), the lower part of the air outlet (701) is fixedly connected with the dust remover (702), the lower part of the dust remover (702) is fixedly connected with the melting pipe (703), one side of the dust remover (702) is fixedly connected with the delivery pipe (704), one side of the delivery pipe (704) is fixedly connected with the high-pressure pipe (705), and one end of the delivery pipe (704) is fixedly connected with the sintering pipe (706).

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