CN115419899B - Sludge heat drying and garbage power generation odor treatment device - Google Patents

Abstract

The invention relates to a technology for treating stink, which is used for solving the problems that garbage contains foreign matters, so that the garbage cannot be completely combusted to generate a large amount of stink gas, a power generation boiler is influenced by the external environment temperature, the power generation efficiency is lower, and a smoke guide pipe is blocked to influence the smoke exhaust speed; according to the invention, the garbage is extruded and cut by the squeezing roller and the cutting knife on the squeezing roller, so that foreign matters in the garbage can be extruded out, the combustion of the garbage is more sufficient, the amount of foul gas generated in the combustion process is reduced, the water flow in the heating box is heated, and the heated water flow is transmitted from the position of the heat transfer pipe under the action of the telescopic hose, so that the heat dissipated to the external environment by the power generation boiler is reduced, the influence on the power generation efficiency of the power generation boiler is reduced, and the circulation space of smoke in the smoke guide pipe is not reduced by the arrangement of the dust guide hose and the first dust scraper, and the combustion of the combustion furnace is not adversely affected.

Description

Sludge heat drying and garbage power generation odor treatment device

Technical Field

The invention relates to a malodor treatment technology, in particular to a malodor treatment device for sludge heat drying and garbage power generation.

Background

The stink treatment refers to the treatment of various stink substances, and the purpose of the treatment method of various stink substances is to change the substance structure of the stink gas through the actions of physics, chemistry and biology and eliminate the stink;

in the prior art, when the garbage is used for incineration power generation, the garbage is mostly directly put into a combustion furnace to be directly combusted, and the garbage to be incinerated contains foreign matters which are not beneficial to combustion, so that the garbage is not sufficiently combusted in the combustion process of putting into the combustion furnace, a large amount of malodorous gas is generated, and adverse effects are caused to the environment; when the power generation boiler is used, due to the influence of the temperature of the external environment, and when the temperature difference between the external environment and the internal part of the power generation boiler is large, the power generation boiler conducts more heat to the external environment, so that the pushing acting force of the heat of steam on the internal equipment of the power generation boiler is reduced due to the rapid dissipation of the heat, and the power generation efficiency is influenced; when the smoke is transmitted to the smoke guide pipe for a long time, more smoke and dust are easily attached to the inner wall of the smoke guide pipe, so that the space for the smoke to flow is gradually reduced, the flowing speed of the smoke is reduced, the smoke in the combustion furnace is influenced and is difficult to quickly dissipate, the oxygen quantity obtained in the combustion furnace is reduced, the combustion effect is influenced, pollution gas harmful to the environment is easily generated, and when the smoke is transmitted to the smoke processor, the smoke contains more smoke and dust, and the processing effect of the smoke processor is influenced;

in view of the above technical problems, the present application proposes a solution.

Disclosure of Invention

The invention aims to extrude and cut garbage through a squeezing roller and a cutting knife on the squeezing roller, so that foreign matters in the garbage can be extruded, the garbage can be combusted more sufficiently, the amount of foul gas generated in the combustion process is reduced, water flow in a heating box is heated, the heated water flow is transmitted from the position of a heat transfer pipe under the action of a telescopic hose, so that the heat dissipated from a power generation boiler to the external environment is reduced, the influence on the power generation efficiency of the power generation boiler is reduced, the circulation space of flue gas in a flue gas guide pipe cannot be reduced through the arrangement of an ash guide hose and a first ash shoveling knife, and the problems that a large amount of foul gas is generated due to incomplete combustion caused by foreign matters in the garbage, the power generation boiler is low in power generation efficiency due to the influence of the temperature of the external environment, and the smoke discharge speed is influenced by the blockage of the flue gas guide pipe are solved, so that the sludge drying heat and the garbage power generation are provided.

The purpose of the invention can be realized by the following technical scheme:

the utility model provides a sludge heat drying and rubbish electricity generation are with foul smell processing apparatus, includes fires burning furnace, it is connected with smoke guide pipe to fire burning furnace upper end, smoke guide pipe keeps away from the one end of firing burning furnace is connected with leads the ash bin, it has smoke processor through the pipe connection to lead ash bin lower surface, smoke processor lateral wall one side has the power boiler through the pipe connection, it is connected with outer hopper to fire burning furnace lateral wall rear, outer hopper lateral wall is kept away from one side of firing burning furnace is connected with the material loading area, the material loading area upper surface is connected with braced frame, braced frame lateral wall one side is connected with the biography material area, braced frame upper surface both sides are rotated through the rotating turret and are connected with the squeeze roll, the squeeze roll lateral wall is connected with a plurality of evenly distributed's cutting knife, braced frame upper surface intermediate position department sets up a plurality of evenly distributed's hourglass dirty hole, pass the material loading area lateral wall with go up dirty hole position department and be connected with the filth case, outer hopper lateral wall corresponds filth case position department is connected with the blow off pipe, it is connected with the runner connection through the pivot rotation to go up the lateral wall, connect the runner through the runner transmission of runner on one end of runner.

As a preferred embodiment of the invention, the position of the outer side wall of the feeding belt corresponding to the rotating roller is rotatably connected with a dirt screening driving gear through a rotating shaft, the position of the outer side wall of the feeding belt corresponding to the dirt screening driving gear is rotatably connected with a transmission gear rotating wheel through a rotating shaft, the transmission gear rotating wheel is in transmission connection with a speed regulating box through a transmission belt, the speed regulating box is in transmission connection with a transmission rotating wheel through a transmission belt, a driving gear is connected above the outer side wall of a transmission rotating wheel connecting shaft, and the upper end of the transmission rotating wheel connecting shaft is connected with a linkage rotating wheel.

As a preferred embodiment of the present invention, a sliding rail is integrally formed on the inner side wall of the outer hopper corresponding to the position of the driving gear, an inner hopper is slidably connected to the inner side of the outer hopper corresponding to the position of the sliding rail, a plurality of dirt seepage holes are uniformly distributed on the outer side wall of the inner hopper, an outer gear ring is connected to the outer side wall of the inner hopper corresponding to the position of the sliding rail, and a butt joint hole is formed on the outer side wall of the outer hopper corresponding to the position of the driving gear.

As a preferred embodiment of the present invention, the outer side wall of the power generation boiler is connected with a heat transfer tube, one end of the heat transfer tube is connected with a heating box, the other end of the heat transfer tube is connected with a flexible hose, the position of the outer side wall of the heating box corresponding to the flexible hose is connected with a support frame, one side of the inner side wall of the support frame close to the flexible hose is rotatably connected with a reciprocating screw, one end of the outer side wall of the reciprocating screw corresponding to the flexible hose is connected with a reciprocating plate, the position of the outer side wall of the reciprocating plate corresponding to the flexible hose is connected with a return pipe, the middle position of the inner side wall of the support frame is connected with a limit plate, one end of the reciprocating screw exposed to the outer side of the support frame is connected with a reciprocating gear, the upper surface of the support frame is rotatably connected with a heat transfer gear runner corresponding to the position of the reciprocating gear, the upper end of the power generation boiler is rotatably connected with a heat transfer driving runner through a rotating shaft, the outer side wall of the ash guide box is rotatably connected with a heat transfer driving runner, and the upper surface of the heating runner is rotatably connected through a rotating shaft.

As a preferred embodiment of the present invention, an ash guiding hose is arranged inside the ash guiding pipe, the outer side wall of the ash guiding hose is connected with a first ash shoveling knife, one end of the ash guiding hose, which is close to the inside of the ash guiding box, is connected with an ash guiding transmission runner, the outer side wall of the ash guiding hose, which is close to the ash guiding transmission runner, is connected with an ash blocking plate, the position of the ash guiding box, which corresponds to the position of the linkage runner at the upper end of the transmission runner, is also rotationally connected with a linkage runner through a connection rotating shaft, and the outer side wall of the connection rotating shaft, which corresponds to the position of the ash guiding transmission runner, is connected with an ash guiding driving runner.

As a preferred embodiment of the invention, a partition plate is integrally formed on the lower surface of the inner part of the ash guide box corresponding to the position of the linkage rotating wheel, a filter screen frame is connected to one side of the upper surface of the partition plate, an ash guide plate is connected to the upper surface of the partition plate close to the position of the filter screen frame in a sliding manner, limiting rods are connected to the four corners of the ash guide plate, and connecting springs are sleeved on the outer side walls of the limiting rods.

As a preferred embodiment of the invention, the lower surface inside the ash guiding box is also rotatably connected with a heat transfer transmission rotating wheel corresponding to the position of the heat transfer transmission rotating wheel rotatably connected with the outer side wall of the ash guiding box, the heat transfer transmission rotating wheel inside the ash guiding box is in transmission connection with a linkage rotating wheel through a transmission belt, the middle position of the lower surface inside the ash guiding box is rotatably connected with a rotating disc through a rotating disc shaft, one side of the upper surface of the rotating disc is connected with a guide column, the position of the outer side wall of the rotating disc shaft corresponding to the transmission belt is connected with a rotating disc rotating wheel, and the lower surface of the ash guiding box corresponding to the two sides of the rotating disc rotating wheel is connected with a squeezing plate.

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

1. the garbage is extruded and cut by the extrusion roller and the cutting knife on the extrusion roller, so that foreign matters in the garbage can be extruded out, and the garbage after cutting and extrusion can be discharged again by the action of centrifugal force in the inner hopper, so that the garbage is combusted more fully, and the amount of foul gas generated in the combustion process is reduced;

2. the heating rotor in the heating box is driven to rotate, water flow in the heating box is heated, the heated water flow is transmitted from the position of the heat transfer pipe under the action of the telescopic hose, the outer wall of the power generation boiler is protected, heat dissipated to the external environment by the power generation boiler is reduced, and the influence on the power generation efficiency of the power generation boiler is reduced;

3. through the setting of leading grey hose and first shovel ash sword, make the inside smoke and dust of leading the tobacco pipe get off by the clearance, the circulation space of leading the inside flue gas of tobacco pipe can not reduce, can not cause harmful effects to the burning of burning furnace, and the filter screen frame of leading the inside ash box can filter the smoke and dust in the air current, makes the smoke and dust that the flue gas that transmits to smoke processor position department contains reduce, reduces the influence to smoke processor treatment effect.

Drawings

In order to facilitate understanding for those skilled in the art, the present invention will be further described with reference to the accompanying drawings.

FIG. 1 is a main body structure view of the present invention;

FIG. 2 is a diagram of a conveyor belt of the present invention;

FIG. 3 is a view of the construction of the upper belt of the present invention;

FIG. 4 is an enlarged view of the portion A of FIG. 3 according to the present invention;

FIG. 5 is a view of the internal hopper structure of the present invention;

FIG. 6 is a structural view of a heat transfer tube of the present invention;

FIG. 7 is a structural view of the dust guiding hose of the present invention;

FIG. 8 is a view showing the internal structure of the dust guiding box according to the present invention;

FIG. 9 is a structural view of the ash guide driving pulley of the present invention;

in the figure: 1. a combustion furnace; 21. a material conveying belt; 22. a dirt box; 23. a transmission belt; 24. a support frame; 25. a sewage discharge pipe; 26. an outer hopper; 27. feeding a material belt; 28. a cutting knife; 29. a sewage leakage hole; 210. a squeeze roll; 211. a sewage screening driving gear; 212. a transmission runner; 213. a transmission gear wheel; 214. a speed regulating box; 215. driving the gear; 216. a linkage rotating wheel; 217. a sliding rail; 218. a sewage seepage hole; 219. an inner hopper; 220. an outer ring gear; 31. a heating box; 32. a reciprocating plate; 33. heating the rotating wheel; 34. a return pipe; 35. a flexible hose; 36. a heat transfer toothed wheel; 37. a heat transfer drive wheel; 38. a heat transfer tube; 39. a heat transfer drive pulley; 310. a reciprocating gear; 311. a reciprocating screw; 312. a support frame; 41. a dust blocking plate; 42. the ash guiding transmission rotating wheel; 43. a dust guiding hose; 44. a first plaster shoveling knife; 45. a screen frame; 46. a connecting spring; 47. a dust guide plate; 48. connecting the rotating shaft; 49. a limiting rod; 410. a turntable; 411. the ash guide drives the rotating wheel; 412. a turntable shaft; 5. a smoke guide pipe; 6. a dust guiding box; 7. a smoke processor; 8. a power generation boiler.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the following embodiments, and it should be understood that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1:

referring to fig. 1-5, a foul smell processing device for sludge heat drying and garbage power generation comprises a combustion furnace 1, a smoke guiding pipe 5 is connected to the upper end of the combustion furnace 1, an ash guiding box 6 is connected to one end of the smoke guiding pipe 5 away from the combustion furnace 1, a smoke processor 7 is connected to the lower surface of the ash guiding box 6 through a pipeline, a power generation boiler 8 is connected to one side of the outer side wall of the smoke processor 7 through a pipeline, an outer hopper 26 is connected to the rear side of the outer side wall of the combustion furnace 1, a feeding belt 27 is connected to one side of the outer side wall of the outer hopper 26 away from the combustion furnace 1, a supporting frame 24 is connected to the upper surface of the feeding belt 27, a material conveying belt 21 is connected to one side of the outer side wall of the supporting frame 24, extrusion rollers 210 are rotatably connected to two sides of the upper surface of the supporting frame 24 through rotating frames, a plurality of uniformly distributed cutting knives 28 are connected to the outer side wall of the extrusion rollers 210, the cutting knives 28 can cut garbage when the garbage is extruded by the cutting knives 210, a plurality of evenly distributed dirt leaking holes 29 are formed in the middle position of the upper surface of the supporting frame 24, the positions of the inner side wall of the conveying belt 21 and the inner side wall of the upper belt 27, which correspond to the dirt leaking holes 29, are connected with the dirt box 22, the position of the outer side wall of the outer hopper 26, which corresponds to the dirt box 22, is connected with the dirt discharge pipe 25, the dirt discharge pipe 25 is connected with the outer hopper 26 and the dirt box 22, dirt in the dirt box 22 can be transmitted to the inside of the dirt box 22 along the inclined dirt discharge pipe 25, the position of the outer side wall of the upper belt 27, which corresponds to the rotating roller, is rotatably connected with the connecting rotating wheel through a rotating shaft, the connecting rotating wheel is in transmission connection with the connecting rotating wheel on one end of the extruding roller 210 through the driving belt 23, so that the upper belt 27 drives the extruding roller 210 to rotate, the position of the outer side wall of the upper belt 27, which corresponds to the rotating roller, is rotatably connected with the dirt sieving driving gear 211 through the rotating shaft, the dirt sieving driving gear 211 can be mutually perpendicular to and mutually embedded with the rotating wheel 213, the outer side wall of the upper material belt 27 is connected with a transmission gear rotating wheel 213 in a rotating mode through a rotating shaft at a position corresponding to the dirt screening driving gear 211, the transmission gear rotating wheel 213 is in transmission connection with a speed regulating box 214 through a transmission belt 23, the speed regulating box 214 connected with the outer side wall of the upper material belt 27 can regulate the rotating speed, the speed regulating box 214 is in transmission connection with the transmission rotating wheel 212 through the transmission belt 23, a driving gear 215 is connected above the outer side wall of a connecting shaft of the transmission rotating wheel 212, the driving gear 215 is mutually embedded with an outer gear ring 220 at the outer side of an inner hopper 219 and drives the transmission rotating, the upper end of the connecting shaft of the transmission rotating wheel 212 is connected with a linkage rotating wheel 216, a sliding rail 217 is integrally formed at a position corresponding to the driving gear 215 on the inner side wall of the outer hopper 26, the inner hopper 219 is connected with the inner hopper at a position corresponding to the sliding rail 217 on the inner side of the outer hopper 26 in a sliding mode, a position of a feeding port where the upper material belt 27 is connected with the outer hopper 26 is located above the inner hopper 219, a plurality of dirt infiltration holes 218 which are uniformly distributed are formed in the outer side wall of the inner hopper 219, an outer side wall of the inner hopper 219 is connected with an outer hopper 217 corresponding to the sliding rail 217, and an outer hopper 217, and an abutment hole is formed at a position of the outer hopper 26;

in the prior art, when the garbage is used for incineration power generation, the garbage is mostly directly put into the combustion furnace 1 for direct combustion, and the garbage to be incinerated mostly contains foreign matters which are not beneficial to combustion, so that the garbage is not sufficiently combusted in the combustion process of putting into the combustion furnace 1, a large amount of malodorous gas is generated, and adverse effects are caused to the environment;

when the garbage to be incinerated is transmitted to the position of the supporting frame 24 on the material conveying belt 21, the garbage is pushed to the position of the squeezing roller 210 by the pushing action force of the material conveying belt 21, the squeezing roller 210 is driven by the material conveying belt 27 to rotate to squeeze the garbage, the garbage is cut by the cutting knife 28 on the squeezing roller 210, so that foreign matters contained in the garbage can be discharged from the position of a cutting opening which is cut under the action of the squeezing action force, the discharged foreign matters fall into the inside of the sewage box 22 below from the position of the sewage leakage hole 29, the garbage after being squeezed and cut falls onto the material conveying belt 27 from the supporting frame 24 and is transmitted to the inside of the inner hopper 219 inside the outer hopper 26 along with the rotation of the material conveying belt 27, and the sewage screening driving gear 211 connected with the rotating roller of the material conveying belt 27 drives the rotating wheel 213 to rotate in the rotating process, the transmission gear rotating wheel 213 and the transmission rotating wheel 212 are in transmission connection with the speed regulating box 214, so that the speed regulating box 214 can regulate the rotating speed of the transmission gear rotating wheel 213 transmitted to the position of the transmission rotating wheel 212, the driving gear 215 connected to the connecting shaft of the transmission rotating wheel 212 is embedded with the outer gear ring 220 on the inner hopper 219, the inner hopper 219 is driven to rotate at a high speed, the garbage in the inner hopper 219 is discharged with the internal foreign matters again under the action of centrifugal force, the discharged foreign matters flow downwards along the inner wall of the outer hopper 26 and are discharged into the dirt box 22 from the position of the drain pipe 25, the garbage cut in the inner hopper 219 can be discharged into the combustion furnace 1 from the lower end of the inner hopper 219 for combustion, the cut garbage is easier to combust, the combustion is free from the internal foreign matters to obstruct the combustion, harmful gas generated by the combustion is greatly reduced, and the adverse effect on the environment is reduced.

Example 2:

referring to fig. 1 and 6, the outer side wall of the power generation boiler 8 is connected with a heat transfer pipe 38, the heat transfer pipe 38 is spirally wound on the outer side of the power generation boiler 8, one end of the heat transfer pipe 38 is connected with a heating box 31, the outer side of a connecting shaft of a heat transfer driving runner 37 inside the heating box 31 is connected with a heating rotor, the inner wall of the heating box 31 is connected with a plurality of uniformly distributed heating stators, the heating rotor stirs water flow inside the heating box 31 in the rotating process along with the heat transfer driving runner 37 to generate vortex, so that the water flow collides with the heating stators to generate heat, the temperature of the water flow is raised, the other end of the heat transfer pipe 38 is connected with a flexible hose 35, two ends of the flexible hose 35 are respectively provided with a check valve, the outer side wall of the heating box 31 is connected with a support frame 312 corresponding to the position of the flexible hose 35, one side of the inner side wall of the support frame 312 close to the flexible hose 35 is rotatably connected with a reciprocating screw 311, one end of the outer side wall of the reciprocating screw 311, which corresponds to the telescopic hose 35, is connected with a reciprocating plate 32, the reciprocating plate 32 performs reciprocating motion in the rotating process of the reciprocating screw 311, the telescopic hose 35 is extruded and stretched, the position of the outer side wall of the reciprocating plate 32, which corresponds to the telescopic hose 35, is connected with a return pipe 34, the other end of the return pipe 34 is connected with the heating box 31, the middle position of the inner side wall of the support frame 312 is connected with a limit plate, the limit plate limits the movement of the reciprocating plate 32 to prevent the position deviation, one end of the reciprocating screw 311, which is exposed to the outer side of the support frame 312, is connected with a reciprocating gear 310, the upper surface of the support frame 312 is rotatably connected with a heat transfer gear wheel 36, the heat transfer gear wheel 36 and the reciprocating gear wheel 310 are mutually vertical and are mutually embedded and driven to rotate, the upper end of the power generation boiler 8 is rotatably connected with a heat transfer driving wheel 37 through a rotating shaft, the internal equipment of the power generation boiler 8 is driven to rotate by the pushing of steam, the heat transfer driving rotating wheel 37 is driven to rotate, the position, corresponding to the heat transfer driving rotating wheel 37, of the outer side wall of the ash guide box 6 is rotatably connected with a heat transfer driving rotating wheel 39, the heat transfer driving rotating wheel 37 is in transmission connection with the heat transfer driving rotating wheel 39 through a transmission belt 23, the upper surface of the heating box 31 is rotatably connected with a heating rotating wheel 33 through a rotating shaft, and the heating rotating wheel 33 is in transmission connection with a heat transfer rotating wheel at the lower end of a connecting shaft of the heat transfer driving rotating wheel 39;

in the prior art, when the power generation boiler 8 is in use, due to the influence of the external environment temperature, and the temperature difference between the external environment and the inside of the power generation boiler 8 is large, the power generation boiler 8 conducts more heat to the outside, so that the pushing acting force of the heat of steam on the internal equipment of the power generation boiler 8 is reduced due to the rapid dissipation of the heat, and the power generation efficiency is influenced;

the heat transfer transmission rotating wheel 39 in the ash guiding box 6 drives the heat transfer rotating wheel at the lower end of the connecting shaft of the heat transfer transmission rotating wheel 39 on the outer side wall of the ash guiding box 6 to rotate, the heat transfer rotating wheel at the lower end of the connecting shaft of the heat transfer transmission rotating wheel 39 drives the heating rotating wheel 33 to rotate through the driving belt 23, so that the heating rotor on the connecting shaft of the heating rotating wheel 33 stirs the water flow in the heating box 31 to generate heat, the heat transfer rotating wheel at the lower end of the connecting shaft of the heat transfer transmission rotating wheel 39 is also in transmission connection with the heat transfer gear rotating wheel 36 through the driving belt 23, the heat transfer gear rotating wheel 36 drives the reciprocating lead screw 311 connected with the reciprocating gear 310 to rotate, so that the reciprocating plate 32 can transmit and stretch the flexible hose 35 in the extruding and stretching process, the water flow with the increased temperature in the heating box 31 is transmitted through the heat transfer pipe 38, the water flow can be transmitted back to the inside of the heating box 31 from the other end of the heat transfer pipe 38 to circulate outside the power generation boiler 8, the power generation boiler 8 can be protected, the heat dissipated to the outside of the power generation boiler 8 is reduced due to the effect of the power generation boiler 8.

Example 3:

referring to fig. 7-9, an ash guiding hose 43 is disposed inside the ash guiding pipe 5, a second ash shoveling knife is connected to a position of the inner wall of the ash guiding hose 5 corresponding to the ash guiding hose 43, the second ash shoveling knife can clean the smoke dust on the inner wall of the ash guiding hose 43 during the rotation of the ash guiding hose 43, a first ash shoveling knife 44 is connected to the outer side wall of the ash guiding hose 43, the outer diameter of the ash guiding hose 43 is smaller than the inner diameter of the ash guiding pipe 5, the width of the first ash shoveling knife 44 is equal to the distance between the ash guiding hose 43 and the ash guiding pipe 5, an ash guiding transmission wheel 42 is connected to one end of the ash guiding hose 43 near the inner portion of the ash guiding box 6, the ash guiding transmission wheel 42 is in transmission connection with the ash guiding driving wheel 411 through a transmission belt 23, an ash blocking plate 41 is connected to a position of the outer side wall of the ash guiding hose 43 near the ash guiding transmission wheel 42, the ash blocking plate 41 is in contact with the upper surface of the ash guiding box 23, the soot falling on the transmission belt 23 can be pushed to fall under the action of the soot blocking plate 41, the position of the linkage runner 216 corresponding to the upper end of the transmission runner 212 in the soot guide box 6 is also rotationally connected with the linkage runner 216 through the connection rotating shaft 48, the linkage runner 216 in the soot guide box 6 is in transmission connection with the linkage runner 216 at the upper end of the transmission runner 212 through the transmission belt 23, the position of the outer side wall of the connection rotating shaft 48 corresponding to the soot guide transmission runner 42 is connected with the soot guide driving runner 411, the position of the inner lower surface of the soot guide box 6 corresponding to the linkage runner 216 is integrally formed with a partition plate, the transmission between the lower runners cannot be influenced by the soot above due to the partition plate, one side of the upper surface of the partition plate is connected with the filter screen frame 45, the position of the upper surface of the partition plate close to the filter screen frame 45 is in sliding connection with the soot guide plate 47, both sides of the outer side wall of the soot guide box 6 are rotationally connected with the turnstiles through the traction spring and the inner wall of the soot guide box 6, the position of the revolving door is at the position close to the filter screen frame 45, the width of the revolving door is smaller, only partial smoke dust can be discharged from the position of the revolving door when the revolving door rotates to open, other positions are difficult to discharge because of being blocked by extruded smoke dust, and the high-temperature gas in the revolving door can not be discharged outwards to cause the leakage of heat, the four corner positions of the dust guide plate 47 are connected with limit rods 49, the outer side wall of each limit rod 49 is sleeved with a connecting spring 46, the lower surface in the dust guide box 6 is also rotatably connected with heat transfer transmission rotating wheels 39 corresponding to the positions of the heat transfer transmission rotating wheels 39 rotatably connected with the outer side wall of the dust guide box 6, the heat transfer transmission rotating wheels 39 in the dust guide box 6 are in transmission connection with the heat transfer transmission rotating wheels 39 on the outer side wall of the dust guide box 6 through a transmission belt 23, the heat transfer transmission rotating wheel 39 in the ash guiding box 6 is in transmission connection with the linkage rotating wheel 216 in the ash guiding box 6 through the transmission belt 23, the inner side wall of the transmission belt 23 connecting the heat transfer transmission rotating wheel 39 in the ash guiding box 6 with the linkage rotating wheel 216 is provided with convex teeth, the middle position of the lower surface in the ash guiding box 6 is in rotation connection with the rotating disc 410 through the rotating disc shaft 412, one side of the upper surface of the rotating disc 410 is connected with a guide post, the position of the outer side wall of the rotating disc shaft 412, corresponding to the transmission belt 23, is connected with a rotating disc rotating wheel, the outer side wall of the rotating disc rotating wheel is provided with an embedded tooth groove, the convex teeth and the embedded tooth groove on the transmission belt 23 are embedded mutually and are always attached to each other under the limitation of an extrusion plate, and the two sides of the lower surface of the ash guiding box 6, corresponding to the rotating disc rotating wheels, are connected with extrusion plates;

in the prior art, when the flue gas is transmitted for a long time in the smoke guide pipe 5, more smoke and dust are easily attached to the inner wall, so that the space for the circulation of the flue gas is gradually reduced, the circulation speed of the flue gas is reduced, the quick dissipation of the flue gas in the combustion furnace 1 is influenced, the amount of oxygen obtained in the combustion furnace 1 is reduced, the combustion effect is influenced, and pollution gas harmful to the environment is easily generated, and when the flue gas is transmitted to the smoke processor 7, more smoke and dust are contained in the flue gas, and the processing effect of the smoke processor 7 is influenced;

when the connecting rotating shaft 48 is driven by the upper material belt 27 to rotate, the ash guiding driving rotating wheel 411 connected to the connecting rotating shaft 48 drives the ash guiding driving rotating wheel 42 to rotate through the transmission belt 23, so that the ash guiding hose 43 connected to the ash guiding driving rotating wheel 42 rotates, when the ash guiding hose 43 rotates, the soot on the inner wall of the ash guiding pipe 5 can be scraped, the scraped soot is transmitted to the inside of the ash guiding box 6 along the first soot shoveling knife 44 which is spirally arranged, the soot on the inner wall of the ash guiding hose 43 can be cleaned by the second soot shoveling knife connected to the inner wall of the ash guiding pipe 5, when the rotating disc 410 rotates under the driving of the rotating disc shaft 412, the ash guiding plate 47 is pushed to move under the limitation of the four limiting rods 49 through the guiding column on the rotating disc 410, the ash guide plate 47 extrudes the connecting spring 46 when moving to one side, so that the ash guide plate 47 can reversely move under the action of the rebounding connecting spring 46, smoke dust falls into the interior of the ash guide box 6, the smoke dust on one side of the filter screen frame 45 in the ash guide box 6 is extruded when the ash guide plate 47 moves back and forth, the attached smoke dust on the filter screen frame 45 can be cleaned, the smoke dust at the position of the rotating shaft 48 connected in the ash guide box 6 is driven by airflow to flow to the position of the filter screen frame 45, the smoke dust is extruded and compacted in the moving process of the ash guide plate 47, the compacted smoke dust extrudes the revolving door under the pushing of the ash guide plate 47, the revolving door rotates and opens under the action of pressure, part of the smoke dust is discharged outwards, and the smoke dust stored in the ash guide box 6 is reduced.

When the invention is used, when the garbage to be incinerated is transmitted to the position of the supporting frame 24 on the material conveying belt 21, the garbage is pushed to the position of the extrusion roller 210 by the pushing action force of the material conveying belt 21, the extrusion roller 210 rotates under the driving of the material conveying belt 27 to extrude the garbage, the cutting knife 28 on the extrusion roller 210 cuts the garbage, so that the foreign matters contained in the garbage can be discharged from the position of the cut opening under the action of the extruding action force, the discharged foreign matters fall into the lower dirt box 22 from the position of the dirt leaking hole 29, the extruded and cut garbage falls onto the material conveying belt 27 from the supporting frame 24 and is transmitted to the inner hopper 219 in the outer hopper 26 along with the rotation of the material conveying belt 27, the dirt screening driving gear 211 connected with the rotating roller of the material conveying belt 27 drives the gear rotating wheel 213 to rotate in the rotating process, the transmission gear rotating wheel 213 and the transmission rotating wheel 212 are in transmission connection with the speed adjusting box 214, so that the speed adjusting box 214 can adjust the rotating speed of the transmission gear rotating wheel 213 transmitted to the position of the transmission rotating wheel 212, the driving gear 215 connected to the connecting shaft of the transmission rotating wheel 212 is embedded with the outer gear ring 220 on the inner hopper 219, so that the inner hopper 219 is driven to rotate at a high speed, the garbage in the inner hopper 219 is discharged with the action of centrifugal force again, the discharged foreign matters flow downwards along the inner wall of the outer hopper 26 and are discharged into the dirt box 22 from the position of the drain pipe 25, the garbage cut in the inner hopper 219 can be discharged from the lower end of the inner hopper 219 to the inside of the combustion furnace 1 for combustion, the cut garbage is easier to combust, the combustion is free from foreign matters in the inner hopper to obstruct the combustion, harmful gas generated by the combustion is greatly reduced, and the adverse effect on the environment is reduced;

the heat transfer transmission rotating wheel 39 in the ash guiding box 6 drives the heat transfer rotating wheel at the lower end of the connecting shaft of the heat transfer transmission rotating wheel 39 on the outer side wall of the ash guiding box 6 to rotate, the heat transfer rotating wheel at the lower end of the connecting shaft of the heat transfer transmission rotating wheel 39 drives the heating rotating wheel 33 to rotate through the driving belt 23, so that the heating rotor on the connecting shaft of the heating rotating wheel 33 stirs and heats water flow in the heating box 31, the heat transfer rotating wheel at the lower end of the connecting shaft of the heat transfer transmission rotating wheel 39 is also in transmission connection with the heat transfer gear rotating wheel 36 through the driving belt 23, the heat transfer gear rotating wheel 36 drives the reciprocating lead screw 311 connected with the reciprocating gear 310 to rotate, the reciprocating plate 32 is used for extruding and stretching the flexible hose 35, so that the water flow with increased temperature in the heating box 31 is transmitted through the heat transfer pipe 38, the water flow can be transmitted back to the inside the heating box 31 from the other end of the heat transfer pipe 38 to circulate, when the water flow carrying heat flows outside the power generation boiler 8, the power generation boiler 8 can be protected, heat loss of the power generation boiler 8 is reduced due to the obstruction effect of the heat transfer pipe 38, the power generation efficiency of the power generation boiler 8 is reduced, and the heat of the heat transfer pipe 31 can be used for carrying water flow to carry out heat drying sludge;

when the connecting rotating shaft 48 rotates under the driving of the upper material belt 27, the ash guiding driving wheel 411 connected to the connecting rotating shaft 48 drives the ash guiding driving wheel 42 to rotate through the transmission belt 23, so that the ash guiding hose 43 connected to the ash guiding driving wheel 42 rotates, when the ash guiding hose 43 rotates, the soot on the inner wall of the ash guiding pipe 5 can be scraped, the scraped soot is transmitted to the inside of the ash guiding box 6 along the first soot shoveling knife 44 arranged spirally, the second soot shoveling knife connected to the inner wall of the ash guiding pipe 5 can clean the soot on the inner wall of the ash guiding hose 43, when the rotating disc 410 rotates under the driving of the rotating disc shaft 412, the ash guiding plate 47 is pushed to move under the restriction of the four limiting rods 49 through the guiding column on the rotating disc 410, the dust guide plate 47 extrudes the connecting spring 46 when moving to one side, so that the dust guide plate 47 can reversely move under the action of the rebounded connecting spring 46, smoke dust falls to the inside of the dust guide box 6, the smoke dust on one side of the filter screen frame 45 in the dust guide box 6 is extruded when the dust guide plate 47 moves back and forth, the attached smoke dust on the filter screen frame 45 can be cleaned, the smoke dust at the position of the connecting rotating shaft 48 in the dust guide box 6 is driven by airflow to flow to the position of the filter screen frame 45, the smoke dust is extruded and compacted in the moving process of the dust guide plate 47, the compacted smoke dust extrudes the revolving door under the pushing of the dust guide plate 47, the revolving door is rotated and opened under the pressure action, part of the smoke dust is discharged outwards, and the smoke dust stored in the dust guide box 6 is reduced.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise forms disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best understand the invention for and utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims (1)

1. The stink treatment device for sludge heat drying and garbage power generation comprises a combustion furnace (1), wherein the upper end of the combustion furnace (1) is connected with a smoke guide pipe (5), one end, far away from the combustion furnace (1), of the smoke guide pipe (5) is connected with an ash guide box (6), the lower surface of the ash guide box (6) is connected with a smoke processor (7) through a pipeline, one side of the outer side wall of the smoke processor (7) is connected with a power generation boiler (8) through a pipeline, the stink treatment device is characterized in that an outer hopper (26) is connected behind the outer side wall of the combustion furnace (1), one side, far away from the combustion furnace (1), of the outer side wall of the outer hopper (26) is connected with a feeding belt (27), the upper surface of the feeding belt (27) is connected with a supporting frame (24), braced frame (24) lateral wall one side is connected with and passes material area (21), braced frame (24) upper surface both sides are rotated through the rotating turret and are connected with squeeze roll (210), squeeze roll (210) lateral wall is connected with a plurality of evenly distributed's cutting knife (28), braced frame (24) upper surface intermediate position department sets up a plurality of evenly distributed's hourglass dirty hole (29), pass material area (21) inside wall with go up material area (27) inside wall and correspond hourglass dirty hole (29) position department is connected with filth case (22), outer hopper (26) lateral wall corresponds filth case (22) position department is connected with blow off pipe (22) 25 The outer side wall of the feeding belt (27) is rotatably connected with a connecting rotating wheel through a rotating shaft at a position corresponding to the rotating roller, and the connecting rotating wheel is in transmission connection with a connecting rotating wheel at one end of the extrusion roller (210) through a transmission belt (23);

the outer side wall of the feeding belt (27) is rotatably connected with a dirt screening driving gear (211) through a rotating shaft at a position corresponding to the rotating roller, the outer side wall of the feeding belt (27) is rotatably connected with a transmission gear rotating wheel (213) through a rotating shaft at a position corresponding to the dirt screening driving gear (211), the transmission gear rotating wheel (213) is in transmission connection with a speed regulating box (214) through a transmission belt (23), the speed regulating box (214) is in transmission connection with a transmission rotating wheel (212) through the transmission belt (23), a driving gear (215) is connected above the outer side wall of a connecting shaft of the transmission rotating wheel (212), and the upper end of the connecting shaft of the transmission rotating wheel (212) is connected with a linkage rotating wheel (216);

a sliding rail (217) is integrally formed at the position, corresponding to the driving gear (215), of the inner side wall of the outer hopper (26), an inner hopper (219) is slidably connected to the position, corresponding to the sliding rail (217), of the inner side wall of the outer hopper (26), a plurality of dirt permeating holes (218) are uniformly distributed in the outer side wall of the inner hopper (219), an outer gear ring (220) is connected to the position, corresponding to the sliding rail (217), of the outer side wall of the inner hopper (219), the driving gear (215) and the outer gear ring (220) on the outer side of the inner hopper (219) are mutually embedded and driven to rotate, and a butt joint hole is formed at the position, corresponding to the driving gear (215), of the outer side wall of the outer hopper (26);

electricity generation boiler (8) lateral wall is connected with heat-transfer pipe (38), the one end of heat-transfer pipe (38) is connected with heating cabinet (31), the other end of heat-transfer pipe (38) is according to being connected with expansion hose (35), heating cabinet (31) lateral wall corresponds expansion hose (35) position department is connected with support frame (312), support frame (312) inside wall is close to expansion hose (35) one side is rotated and is connected with reciprocal lead screw (311), reciprocal lead screw (311) lateral wall corresponds expansion hose (35) one end is connected with reciprocating plate (32), reciprocating plate (32) lateral wall corresponds expansion hose (35) position department is connected with back flow (34), support frame (312) inside wall intermediate position department is connected with the limiting plate, reciprocal lead screw (311) expose to the one end in support frame (312) outside and are connected with reciprocating gear (310), support frame (312) upper surface corresponds reciprocating gear (310) position department rotates and is connected with heat transfer gear runner (36), electricity generation boiler (8) upper end rotates through the pivot and is connected with heat transfer drive runner (37), it corresponds to lead runner (6) lateral wall (37) transmission runner (37) position department rotation of heat transfer gear (39) lower surface connection ash runner (6) lower surface connection ash bin (6) the heat transfer ash guide box (6) the other side wall (39) A heat transfer transmission rotating wheel (39) is also rotatably connected to the position, the heat transfer transmission rotating wheel (39) in the ash guide box (6) is in transmission connection with the heat transfer transmission rotating wheel (39) on the outer side wall of the ash guide box (6) through a transmission belt (23), the upper surface of the heating box (31) is rotatably connected with a heating rotating wheel (33) through a rotating shaft, the heat transfer transmission rotating wheel (39) in the ash guide box (6) drives the heat transfer rotating wheel at the lower end of a connecting shaft of the heat transfer transmission rotating wheel (39) on the outer side wall of the ash guide box (6) to rotate, the heat transfer rotating wheel at the lower end of the connecting shaft of the heat transfer transmission rotating wheel (39) drives the heating rotating wheel (33) to rotate through the transmission belt (23), and the heat of water flow in the heating box (31) is used for carrying out heat drying operation on sludge;

an ash guide hose (43) is arranged inside the ash guide pipe (5), a first ash shoveling knife (44) is connected to the outer side wall of the ash guide hose (43), an ash guide transmission rotating wheel (42) is connected to one end, close to the inner part of the ash guide box (6), of the ash guide hose (43), an ash blocking plate (41) is connected to the position, close to the ash guide transmission rotating wheel (42), of the outer side wall of the ash guide hose (43), a partition plate is also rotationally connected to the position, corresponding to the position of the ash guide transmission rotating wheel (42), of the ash guide box (6) and corresponding to the upper end of the transmission rotating wheel (212), of the linkage rotating wheel (216) through a connection rotating shaft (48), a filter screen frame (45) is connected to one side of the upper surface of the partition plate, a dust guide plate (47) is slidably connected to the position of the ash guide transmission rotating wheel (42) through the outer side wall of the connection rotating shaft (48), four transmission corner positions of the ash guide plate (47) are connected with limiting rods (49), a spring (46) is connected to the outer side wall of the ash guide rotating wheel (23) through a spring sleeve, and a heat transmission belt (23), lead inside lower surface intermediate position department of ash bin (6) and rotate through carousel axle (412) and be connected with carousel (410), carousel (410) upper surface one side is connected with the guide post, carousel axle (412) lateral wall corresponds drive belt (23) position department is connected with the carousel runner, it is connected with the stripper plate to lead ash bin (6) lower surface to correspond carousel runner both sides.

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