CN114370640B - Improved structure of heat accumulating type incinerator - Google Patents

Abstract

The invention discloses an improved structure of a heat accumulating type incinerator, which comprises a furnace tank, wherein a cylindrical cavity and a conical cavity which are connected are arranged in the furnace tank, the inner wall of the furnace tank is respectively and annularly and symmetrically provided with a plurality of upper right-angle regenerators and a plurality of lower right-angle regenerators, the upper ends of the upper right-angle regenerators and the lower right-angle regenerators are communicated with the cylindrical cavity, the lower end of each upper right-angle regenerator is provided with an upper conical ash chute, and the lower end of each upper conical ash chute is provided with an upper back-blowing hole. Through the last right angle regenerator that adopts annular tangential distribution and right angle regenerator down realize utilizing waste gas power to produce the whirl in the retort, reach the separation emission of gas after handling and dust impurity, environmental protection more, and realize setting up more regenerator in the retort of less volume, heat accumulation efficiency is higher, and blast pipe, last blowback hole, lower blowback hole all set up in the retort, and the heat preservation effect is better, and the heat loss is lower, and the heat recovery rate is higher.

Description

Improved structure of heat accumulating type incinerator

Technical Field

The invention relates to the technical field of incinerators, in particular to an improved structure of a heat accumulating type incinerator.

Background

Current regenerator incinerator generally adopts inline regenerator and pipeline combination, and after the exhaust-gas combustion handles, dust impurity only can clean the heat accumulation bed after the blowback, and unable and the gas separation after handling, lead to the combustion gas cleanliness factor not up to standard, and inline regenerator is bulky, and the gas flow is through apart from longer, and the pipeline all is located the incinerator outside, and the heat preservation effect is relatively poor, leads to the incinerator overall heat loss great, then the heat recovery rate is lower.

Disclosure of Invention

The invention aims to solve the problems that in the prior art, the cleanliness of the discharged gas cannot reach the standard due to the fact that gas and dust impurities cannot be separated, and the heat recovery rate is low due to large heat loss, and provides an improved structure of a heat accumulating type incinerator.

In order to achieve the purpose, the invention adopts the following technical scheme:

the utility model provides an improvement structure of heat accumulation formula incinerator, includes the stove tank, be equipped with continuous cylindricality chamber and toper chamber in the stove tank, the inner wall of stove tank ring symmetry respectively has seted up a plurality of last right angle regenerator and a plurality of lower right angle regenerator, and is a plurality of go up the upper end of right angle regenerator and a plurality of lower right angle regenerator and all communicate the cylindricality chamber, every go up the lower extreme of right angle regenerator and all seted up conical ash chute, every go up the lower extreme of conical ash chute and all seted up the back-blowing hole, every lower conical ash chute has all been seted up to the lower extreme of lower right angle regenerator, every go up the lower extreme of back-blowing hole and a plurality of lower back-blowing hole and all communicate the cylindricality chamber, equally divide in every last right angle regenerator and the lower right angle regenerator and do not install heat accumulation bed and lower heat accumulation bed, respectively the symmetry insert on the lateral wall of stove tank respectively and be equipped with a plurality of first waste gas pipe and second waste gas pipe, it is a plurality of last cylindrical waste gas pipe and a plurality of lower of conical ash chute extend to the lower end of dust cover and the lower end of dust cover, the lower end of dust cover is slightly less than the inner diameter of the dust cover is inserted and is installed to the dust cover, the inner diameter of the exhaust pipe is less than the dust cover.

Furthermore, a gas cavity is formed in the side wall of the exhaust pipe, a plurality of flame spraying holes are uniformly formed in the side wall of the exhaust pipe and communicated with the gas cavity, the flame spraying holes are located in the cylindrical cavity, the upper end of the exhaust pipe extends to the upper portion of the furnace tank, a gas pipe is inserted into one section of side wall, located at the upper end of the furnace tank, of the exhaust pipe, and the gas pipe is communicated with the gas cavity.

Further, a sealing ring and a ventilation frame are fixedly mounted on the inner wall of the exhaust pipe respectively, the ventilation frame is located above the sealing ring, a guide rod is arranged on the ventilation frame in a sliding mode in the middle, a sealing plug is fixedly mounted at the lower end of the guide rod and arranged on the sealing ring in a plugging mode, and a sealing spring is sleeved on the guide rod, wherein two ends of the sealing spring are fixed on the sealing plug and the ventilation frame respectively.

Further, every all install first control valve on the first exhaust gas pipe, every all install the second control valve on the second exhaust gas pipe, it is a plurality of the one end that stove tank was kept away from to first exhaust gas pipe and a plurality of second exhaust gas pipe is installed annular exhaust gas pipe jointly, insert on the annular exhaust gas pipe and be equipped with the intake pipe.

Furthermore, the upper end of each upper right-angle regenerator and the upper end of each lower right-angle regenerator are tangentially communicated with the cylindrical cavity, the tangential rotation directions of the upper right-angle regenerators and the lower right-angle regenerators are consistent with that of the cylindrical cavity, the lower ends of the upper blowback holes and the lower blowback holes are tangentially communicated with the cylindrical cavity, the tangential rotation directions of the upper blowback holes and the lower blowback holes and the cylindrical cavity are consistent, the heights of the joints of the upper blowback holes and the lower blowback holes and the cylindrical cavity are the same, and the lower end of the dust cover is positioned below the upper blowback holes and the lower blowback holes.

Further, a dust collecting box is fixedly mounted at the lower end of the furnace tank, an ash falling pipe is mounted at the upper end of the dust collecting box, the upper end of the ash falling pipe extends to the bottom of the conical cavity, and an ash discharging pipe is mounted at the lower end of the dust collecting box.

Has the advantages that: through the last right angle regenerator that adopts annular tangential distribution and right angle regenerator down realize utilizing waste gas power to produce the whirl in the retort, reach the separation emission of gas after handling and dust impurity, environmental protection more, and realize setting up more regenerator in the retort of less volume, heat accumulation efficiency is higher, and blast pipe, last blowback hole, lower blowback hole all set up in the retort, and the heat preservation effect is better, and the heat loss is lower, and the heat recovery rate is higher.

Drawings

Fig. 1 is a schematic structural view of an improved structure of a regenerative incinerator according to the present invention;

FIG. 2 is a schematic view of a sectional view of a pot of a regenerative incinerator with an improved structure according to the present invention;

FIG. 3 is a schematic view of a portion of an exhaust pipe of a regenerative incinerator with an improved structure according to the present invention;

FIG. 4 is an enlarged view of a portion of a lower right-angle regenerator of an improved structure of a regenerative incinerator according to the present invention;

fig. 5 is an enlarged view of a portion of an upper right-angle regenerator of a regenerative incinerator according to the present invention.

In the figure: 1 furnace pot, 11 cylindrical cavities, 12 conical cavities, 2 first exhaust gas pipes, 21 first control valves, 3 second exhaust gas pipes, 31 second control valves, 4 annular exhaust gas pipes, 41 air inlet pipes, 5 dust collecting boxes, 51 ash falling pipes, 52 ash discharge pipes, 6 exhaust pipes, 61 dust covers, 62 gas cavities, 63 flame spraying holes, 64 sealing rings, 65 ventilation frames, 66 guide rods, 67 sealing plugs, 68 sealing springs, 7 upper right-angle regenerative chambers, 71 upper conical ash chutes, 72 upper back blowing holes, 73 upper regenerative beds, 8 lower right-angle regenerative chambers, 81 lower conical ash chutes, 82 lower back blowing holes, 83 lower regenerative beds and 9 gas pipes.

Detailed Description

Referring to fig. 1-5, an improved structure of a regenerative incinerator, including a furnace 1, be equipped with continuous cylindricality chamber 11 and toper chamber 12 in the furnace 1, the inner wall of furnace 1 has seted up a plurality of upper right angle regenerators 7 and a plurality of lower right angle regenerators 8 of annular symmetry respectively, the upper end of a plurality of upper right angle regenerators 7 and a plurality of lower right angle regenerators 8 all communicates columnar cavity 11, upper conical ash chute 71 has all been seted up to the lower extreme of every upper right angle regenerator 7, upper back-blowing hole 72 has all been seted up to the lower extreme of every upper conical ash chute 71, lower conical ash chute 81 has all been seted up to the lower extreme of every lower right angle regenerator 8, back-blowing hole 82 has all been seted up to the lower extreme of every lower conical ash chute 81, the lower extreme of a plurality of upper back-blowing holes 72 and a plurality of lower back-blowing holes 82 all communicates columnar cavity 11, upper back-blowing bed 73 and lower back-blowing bed 83 have respectively been installed to the lower right angle regenerators 7 and lower right angle regenerators 8 respectively, the upper end of a plurality of upper right angle regenerators 7 and lower back-blowing pipe 3 and the lower dust cover 11 is installed to a plurality of lower back-blowing pipe 3 and is equal to the lower dust cover 6 and is inserted to the equal to the lower dust cover 6 of a plurality of the upper end of the lower exhaust pipe 3 and is installed to the lower exhaust pipe 3 respectively, the upper end of a plurality of the exhaust pipe 3 and is inserted to the exhaust pipe 3 respectively, the exhaust pipe 3 and is installed to the lower dust cover 6 respectively, the exhaust pipe in the exhaust pipe 3 and is equal to the exhaust pipe extension of a plurality of the ash chute 11, the exhaust pipe in the ash chute 11, the exhaust pipe of a plurality of the exhaust pipe extension of the exhaust pipe in the ash chute 11.

The upper right-angle regenerators 7 and the lower right-angle regenerators 8 are annularly distributed in the inner wall of the furnace tank 1, so that compared with a common linear incinerator, the number of the regenerators is increased, the volume of the incinerator is reduced, and the incineration efficiency is higher;

the first exhaust gas pipe 2 and the second exhaust gas pipe 3 are opened and closed alternately, after the exhaust gas enters the upper conical ash chute 71 from the first exhaust gas pipe 2, the exhaust gas is heated by the upper heat accumulation bed 73 and flows upwards into the cylindrical cavity 11, the pressure in the cylindrical cavity 11 is increased, the diameter of the lower end of the dust cover 61 is too large, so that the gas flow cannot directly flow downwards into the conical cavity 12, a part of the gas flow flows into the lower rectangular heat accumulation chamber 8 from the upper end and flows upwards into the cylindrical cavity 11 again through the lower conical ash chute 81 and the lower back-blowing hole 82, similarly, after the exhaust gas enters the lower conical ash chute 81 from the second exhaust gas pipe 3, the gas flow is heated by the lower heat accumulation bed 83 and flows upwards into the cylindrical cavity 11, the pressure in the cylindrical cavity 11 is increased, the diameter of the lower end of the dust cover 61 is too large, so that the gas flow cannot directly flow downwards into the conical cavity 12, a part of the gas flow flows into the upper rectangular heat accumulation chamber 7 from the upper end and flows into the cylindrical cavity 11 again through the upper conical ash chute 71 and the upper back-blowing hole 72, so that the dust accumulation capacity of the upper heat accumulation bed 83 and the lower heat accumulation bed 83 are avoided.

Offer the gas chamber 62 in the lateral wall of blast pipe 6, evenly seted up a plurality of flame holes 63 of spouting on the lateral wall of blast pipe 6, a plurality of flame holes 63 intercommunication gas chamber 62 of spouting, a plurality of flame holes 63 of spouting are located cylindrical cavity 11, and the upper end of blast pipe 6 extends to the top of stove jar 1, and blast pipe 6 is located and inserts on one section lateral wall of stove jar 1 upper end and is equipped with gas pipe 9, and gas pipe 9 intercommunication gas chamber 62.

The gas pipe 9 lets in the gas through the gas chamber 62 in the blast pipe 6 to spout from flame spraying hole 63 and ignite in the cylindricality chamber 11, make waste gas in the cylindricality chamber 11 heated combustion and handle, need not additionally to increase and ignite the structure, make the incinerator structure simpler, and blast pipe 6 is located cylindricality chamber 11, then the heat preservation effect is better, and exhaust gas temperature loss is littleer, makes the incinerator heat recovery efficiency increase.

The inner wall of the exhaust pipe 6 is fixedly provided with a sealing ring 64 and a ventilation frame 65, the ventilation frame 65 is positioned above the sealing ring 64, a guide rod 66 is inserted in the middle of the ventilation frame 65 in a sliding manner, the lower end of the guide rod 66 is fixedly provided with a sealing plug 67, the sealing plug 67 is plugged on the sealing ring 64, and the guide rod 66 is sleeved with a sealing spring 68, the two ends of which are respectively fixed on the sealing plug 67 and the ventilation frame 65.

The sealing plug 67 blocks the sealing ring 64 through the sealing spring 68, so that the exhaust pipe 6 needs a certain pressure to open, the cylindrical cavity 11 and the conical cavity 12 in the furnace tank 1 are in a high-pressure state, the combustion reaction is more sufficient, and more heat energy is released and stored.

All install first control valve 21 on every first exhaust gas pipe 2, all install second control valve 31 on every second exhaust gas pipe 3, annular exhaust gas pipe 4 is installed jointly to the one end that stove tank 1 was kept away from to a plurality of first exhaust gas pipes 2 and a plurality of second exhaust gas pipe 3, inserts on the annular exhaust gas pipe 4 and is equipped with intake pipe 41.

The first control valve 21 and the second control valve 31 control the opening and closing of the first exhaust pipe 2 and the second exhaust pipe 3, the first control valve 21 and the second control valve 31 are opened alternately, and the air inlet pipe 41 is connected with an external fan to input exhaust gas into the annular exhaust pipe 4.

The upper end of each upper right-angle regenerator 7 and the upper end of each lower right-angle regenerator 8 are communicated with the cylindrical cavity 11 in a tangential manner, the tangential rotation directions of the upper right-angle regenerators 7 and the lower right-angle regenerators 8 are consistent with that of the cylindrical cavity 11, the lower ends of each upper blowback hole 72 and the lower blowback hole 82 are communicated with the cylindrical cavity 11 in a tangential manner, the tangential rotation directions of the upper blowback holes 72 and the lower blowback holes 82 are consistent with that of the cylindrical cavity 11, the heights of the joints of the upper blowback holes 72 and the lower blowback holes 82 and the cylindrical cavity 11 are the same, and the lower end of the dust cover 61 is located below the upper blowback holes 72 and the lower blowback holes 82.

The upper end of the upper right-angle regenerator 7 and the upper end of the lower right-angle regenerator 8 are communicated with the cylindrical cavity 11 in a tangential manner, so that when the upper right-angle regenerator 7 or the lower right-angle regenerator 8 conveys gas into the cylindrical cavity 11, the gas flows in along the tangential angle of the cylindrical cavity 11, the gas swirls in the cylindrical cavity 11, impurities such as dust and the like sink, the sinking dust impurities fall along the dust cover 61 and fall into the conical cavity 12 along the gap between the dust cover 61 and the inner wall of the cylindrical cavity 11, the collection and purification of the dust impurities are realized, and the gas discharged from the exhaust pipe 6 is prevented from containing a large amount of dust impurities;

go up blowback hole 72 and lower extreme tangential intercommunication cylindrical cavity 11 of blowback hole 82 down, then during the air current blowback, the gaseous tangential flow that contains a large amount of dust is in cylindrical cavity 11, accelerate gaseous rotational velocity in cylindrical cavity 11, make dust impurity can subside fast, behind dust impurity and gaseous inner wall clearance through dust cover 61 and cylindrical cavity 11, the whirl is blockked, make gaseous from dust cover 61 to blast pipe 6 flow, and dust impurity then falls to the bottom in toper chamber 12 downwards, realize the separation of dust impurity and gas.

The lower end of the furnace pot 1 is fixedly provided with a dust collecting box 5, the upper end of the dust collecting box 5 is provided with an ash falling pipe 51, the upper end of the ash falling pipe 51 extends to the bottom of the conical cavity 12, and the lower end of the dust collecting box 5 is provided with an ash discharging pipe 52.

The dust impurities gathered at the bottom of the conical cavity 12 enter the dust collection box 5 through the dust falling pipe 51, and when a certain amount of dust is collected in the dust collection box 5, the dust discharging pipe 52 is opened, so that the dust in the dust collection box 5 is discharged, and the dust collection is more convenient.

The gas pipe 9 is filled with gas, the gas is sprayed and ignited in the cylindrical cavity 11 through the gas cavity 62 and the flame spraying hole 63, so that the temperature in the cylindrical cavity 11 rises rapidly, the fan discharges waste gas into the annular waste gas pipe 4 through the gas inlet pipe 41, the first control valve 21 is opened, the second control valve 32 is closed, the waste gas enters the upper conical ash groove 71 through the first waste gas pipe 2 and flows towards the upper right-angle regenerator 7, the waste gas flows tangentially into the cylindrical cavity 11, so that the waste gas in the cylindrical cavity 11 forms a rotational flow and is combusted, the pressure in the cylindrical cavity 11 is gradually increased, part of the gas flow flows to the conical cavity 12 from a gap between the dust cover 61 and the inner wall of the cylindrical cavity 11, the other part of the gas flow flows to the upper end of the lower right-angle regenerator 8, the lower regenerator 83 stores heat through the lower regenerator 83, the gas continues to flow to the lower conical ash groove 81 and enters the cylindrical cavity 11 through the lower back blowing hole 82, the rotational flow speed is increased, the rotational flow is enabled to sink dust to fall to the gap between the inner wall of the dust cover 61 and the inner wall of the cylindrical cavity 11 to fall to the bottom of the conical cavity 12, then to enter the ash pipe 51, impurities in the dust box 5, and the dust is separated and is further to be cleaned and discharged;

when the first control valve 21 is closed and the second control valve 31 is opened, the waste gas enters the lower conical ash groove 81 through the second waste gas pipe 3, is heated by the lower heat accumulation bed 83 and flows upwards to the cylindrical cavity 11 to form a rotational flow, and is combusted again in the cylindrical cavity 11, and as above, the combusted gas enters and heats the upper heat accumulation bed 73 from the upper end of the upper right-angle heat accumulation chamber 7, and then enters the cylindrical cavity 11 along the upper conical ash groove 71 and the upper back-blowing hole 72 to accelerate the rotational flow, and the dust on the upper heat accumulation bed 73 is blown back into the cylindrical cavity 11 by the air flow, so that the upper heat accumulation bed 73 is cleaned, and when the waste gas is switched again to be discharged, the lower heat accumulation bed 83 is cleaned, back-blowing cleaning of the upper heat accumulation bed 73 and the lower heat accumulation bed 83 is realized, and the heat accumulation efficiency is prevented from being reduced.

Claims (4)

1. An improved structure of a heat accumulating type incinerator comprises a furnace tank (1) and is characterized in that a cylindrical cavity (11) and a conical cavity (12) which are connected are arranged in the furnace tank (1), a plurality of upper right-angle regenerators (7) and a plurality of lower right-angle regenerators (8) are respectively and annularly and symmetrically arranged on the inner wall of the furnace tank (1), the upper ends of the upper right-angle regenerators (7) and the lower ends of the lower right-angle regenerators (8) are communicated with the cylindrical cavity (11), an upper conical ash chute (71) is arranged at the lower end of each upper right-angle regenerator (7), an upper back-blowing hole (72) is arranged at the lower end of each upper conical ash chute (71), the lower end of each lower right-angle regenerator (8) is provided with a lower conical ash groove (81), the lower end of each lower conical ash groove (81) is provided with a lower back-blowing hole (82), the lower ends of a plurality of upper back-blowing holes (72) and a plurality of lower back-blowing holes (82) are communicated with a cylindrical cavity (11), an upper heat storage bed (73) and a lower heat storage bed (83) are respectively arranged in each upper right-angle regenerator (7) and the lower right-angle regenerator (8), a plurality of first waste gas pipes (2) and a plurality of second waste gas pipes (3) are respectively and symmetrically inserted on the outer side wall of the furnace tank (1), the plurality of first waste gas pipes (2) respectively extend into the plurality of upper conical ash grooves (71), the plurality of second waste gas pipes (3) extend into the plurality of lower conical ash grooves (81) respectively, an exhaust pipe (6) is inserted into the upper end of the furnace tank (1), the lower end of the exhaust pipe (6) extends into the cylindrical cavity (11) and is provided with a dust cover (61), and the diameter of the lower end of the dust cover (61) is slightly smaller than the inner diameter of the cylindrical cavity (11);

a first control valve (21) is installed on each first exhaust gas pipe (2), a second control valve (31) is installed on each second exhaust gas pipe (3), an annular exhaust gas pipe (4) is installed at one end, away from the furnace tank (1), of each first exhaust gas pipe (2) and one end, away from the furnace tank (1), of each second exhaust gas pipe (3), and an air inlet pipe (41) is inserted into each annular exhaust gas pipe (4);

the upper end of each upper right-angle heat storage chamber (7) and the upper end of each lower right-angle heat storage chamber (8) are communicated with a cylindrical cavity (11) in a tangential mode, the tangential rotation directions of the upper right-angle heat storage chambers (7) and the lower right-angle heat storage chambers (8) are consistent with that of the cylindrical cavity (11), the lower ends of each upper blowback hole (72) and the lower blowback hole (82) are communicated with the cylindrical cavity (11) in a tangential mode, the tangential rotation directions of the upper blowback holes (72) and the lower blowback holes (82) are consistent with that of the cylindrical cavity (11), the heights of the joints of the upper blowback holes (72) and the lower blowback holes (82) and the cylindrical cavity (11) are the same, and the lower end of the dust cover (61) is located below the upper blowback holes (72) and the lower blowback holes (82).

2. The improved structure of a heat accumulating type incinerator according to claim 1, wherein a gas cavity (62) is formed in the side wall of the exhaust pipe (6), a plurality of flame spraying holes (63) are uniformly formed in the side wall of the exhaust pipe (6), the flame spraying holes (63) are communicated with the gas cavity (62), the flame spraying holes (63) are located in the cylindrical cavity (11), the upper end of the exhaust pipe (6) extends to the upper side of the incinerator tank (1), a gas pipe (9) is inserted into one section of the side wall of the upper end of the incinerator tank (1) of the exhaust pipe (6), and the gas pipe (9) is communicated with the gas cavity (62).

3. An improved structure of a heat accumulating incinerator according to claim 2, wherein the inner wall of the exhaust pipe (6) is fixedly provided with a sealing ring (64) and a ventilation frame (65) respectively, the ventilation frame (65) is positioned above the sealing ring (64), a guide rod (66) is inserted on the ventilation frame (65) in a sliding manner in the middle, the lower end of the guide rod (66) is fixedly provided with a sealing plug (67), the sealing plug (67) is plugged on the sealing ring (64), and the guide rod (66) is sleeved with a sealing spring (68) with two ends respectively fixed on the sealing plug (67) and the ventilation frame (65).

4. An improved structure of a regenerative incinerator according to claim 1, characterized in that a dust collecting box (5) is fixedly installed at the lower end of the incinerator body (1), an ash falling pipe (51) is installed at the upper end of the dust collecting box (5), the upper end of the ash falling pipe (51) extends to the bottom of the conical cavity (12), and an ash discharging pipe (52) is installed at the lower end of the dust collecting box (5).

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