CN115180597A - Sulfur burner with heat cyclic utilization structure - Google Patents

Abstract

The invention provides a sulfur incinerator with a heat recycling structure, which belongs to the technical field of sulfur incinerators and comprises an incinerator body, a heat preservation component, a first water tank, a smoke exhaust pipe, a driving component and a second water tank, wherein the smoke exhaust pipe is arranged at one end of the incinerator body and communicated with the incinerator body and used for realizing the emission of combustion smoke in the incinerator body, the heat preservation component is attached to the outer wall of the incinerator body and used for heating and preserving heat of the outer wall of the incinerator body, the first water tank and the second water tank are movably arranged outside the smoke exhaust pipe and communicated with the heat preservation component, and the driving component is used for driving the second water tank and the first water tank to reciprocate along the length direction of the smoke exhaust pipe. Compared with the prior art, the high-efficiency recovery of the heat of the flue gas during combustion of the sulfur burning furnace can be realized, the average white loss of the heat of the flue gas is effectively avoided, and the energy-saving effect is good.

Description

Sulfur burner with heat cyclic utilization structure

Technical Field

The invention belongs to the technical field of sulfur incinerators, and particularly relates to a sulfur incinerator with a heat recycling structure.

Background

At present, sulfur burners are mostly operated by burning sulfur to generate SO ₂ Gas through the pair of SO ₂ The gas is further processed to produce a related product.

The sulfur burning furnace can produce a large amount of flue gases when burning sulfur, contains higher heat in the flue gas, among the prior art, to the heat in the sulfur burning flue gas adopt measures such as cooling of spraying generally to cool down and handle, and the heat can be flat white to run off among the cooling process, is unfavorable for energy-concerving and environment-protective requirement, needs urgent improvement.

Disclosure of Invention

In view of the above-mentioned deficiencies of the prior art, an embodiment of the present invention provides a sulfur burner with a heat recycling structure.

In order to solve the technical problems, the invention provides the following technical scheme:

a sulfur burning furnace with a heat recycling structure comprises a furnace body, a heat preservation component, a first water tank, a smoke exhaust pipe, a driving component and a second water tank,

the smoke exhaust pipe is arranged at one end of the furnace body and communicated with the furnace body for realizing the emission of combustion smoke in the furnace body,

the heat insulation component is attached to the outer wall of the furnace body and is used for heating and insulating the outer wall of the furnace body,

the first water tank and the second water tank are movably arranged outside the smoke exhaust pipe and are communicated with the heat preservation component,

the driving assembly is used for driving the second water tank and the first water tank to reciprocate along the length direction of the smoke exhaust pipe, and the moving directions of the second water tank and the first water tank are opposite all the time.

As a further improvement of the invention: the heat insulation component comprises a first annular heat insulation pipe, a second annular heat insulation pipe and a plurality of strip-shaped heat insulation pipes,

the first annular heat-insulating pipe and the second annular heat-insulating pipe are attached to the outer wall of the furnace body and are distributed at intervals, a plurality of strip-shaped heat-insulating pipes are arranged between the first annular heat-insulating pipe and the second annular heat-insulating pipe, two ends of each strip-shaped heat-insulating pipe are respectively communicated with the first annular heat-insulating pipe and the second annular heat-insulating pipe through communicating pipes,

a plurality of the bar insulating tube all with the furnace body outer wall pastes, first water tank and the second water tank all through the bellows with second annular insulating tube intercommunication.

As a further improvement of the invention: the outer wall of the smoke exhaust pipe is fixedly provided with a supporting plate,

the driving component comprises a motor, a rolling wheel, a traction rope, a transmission gear, a first rack and a second rack,

the motor is fixedly arranged on one side of the supporting plate, the winding wheel is arranged at the output end of the motor, one end of the traction rope is connected with the winding wheel, the other end of the traction rope is connected with the second water tank,

the transmission gear is rotatably installed on the outer wall of the smoke exhaust pipe, the first rack is arranged on one side of the second water tank, the second rack is arranged on one side of the first water tank, and the first rack and the second rack are respectively meshed with the two sides of the transmission gear.

As a further improvement of the invention: one side of the first water tank is connected with the outer wall of the furnace body through a first elastic piece.

As a still further improvement of the invention: the first water tank lateral wall is fixedly provided with a first guide rod, the second water tank lateral wall is fixedly provided with a second guide rod, and the first guide rod and the second guide rod all penetrate through the support plate and are in movable fit with the support plate.

As a still further improvement of the invention: the first water tank and the second water tank are both arc-shaped structures, and the first water tank and the second water tank are both attached to the outer wall of the smoke exhaust pipe.

As a still further improvement of the invention: the inner part of the smoke exhaust pipe is also provided with a flow limiting assembly, and the flow limiting assembly is used for limiting the flow of smoke flowing along the inner part of the smoke exhaust pipe.

As a still further improvement of the invention: the flow limiting assembly comprises a fixing plate and a flow limiting plate,

the fixed plate is fixedly arranged on the inner wall of the smoke exhaust pipe, a through hole is arranged in the middle of the fixed plate, the current limiting plate is attached to one side of the fixed plate,

one side of the fixed plate is fixedly provided with a guide post which penetrates through the flow restricting plate and is movably matched with the flow restricting plate, one end of the guide post, which is far away from the fixed plate, is fixedly provided with an end block,

the end block is connected with the flow limiting plate through a second elastic piece.

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

compared with the prior art, the high-efficiency recovery of the heat of the flue gas during combustion of the sulfur burning furnace can be realized, the average white loss of the heat of the flue gas is effectively avoided, and the energy-saving effect is good.

Drawings

FIG. 1 is a schematic view showing a structure of a sulfur burner having a heat recycling structure;

FIG. 2 is a schematic structural view of a first water tank and a second water tank outside a smoke exhaust pipe in a sulfur incinerator with a heat recycling structure;

FIG. 3 is a schematic view showing a heat retaining member of a sulfur furnace having a heat recycling structure;

FIG. 4 is an enlarged view of area A of FIG. 1;

FIG. 5 is an enlarged view of the area B in FIG. 1;

in the figure: 10-furnace body, 20-heat preservation assembly, 201-first annular heat preservation pipe, 202-strip heat preservation pipe, 203-communicating pipe, 204-second annular heat preservation pipe, 205-flexible hose, 30-first elastic piece, 40-first water tank, 401-first guide rod, 50-smoke exhaust pipe, 501-support plate, 60-flow limiting assembly, 601-end block, 602-guide column, 603-second elastic piece, 604-flow limiting plate, 605-fixing plate, 606-through hole, 70-drive assembly, 701-reel, 702-traction rope, 703-transmission gear, 704-first rack, 80-second water tank and 801-second guide rod.

Detailed Description

The technical solution of the present patent will be described in further detail with reference to the following embodiments.

Reference will now be made in detail to embodiments of the present patent, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary only for the purpose of explaining the present patent and are not to be construed as limiting the present patent.

Referring to fig. 1 and 2, the embodiment provides a sulfur incinerator with a heat recycling structure, including a furnace body 10, a heat preservation assembly 20, a first water tank 40, a smoke exhaust pipe 50, a driving assembly 70 and a second water tank 80, where the smoke exhaust pipe 50 is disposed at one end of the furnace body 10 and is communicated with the furnace body 10 for discharging combustion smoke inside the furnace body 10, the heat preservation assembly 20 is attached to an outer wall of the furnace body 10 for heating and preserving heat of the outer wall of the furnace body 10, the first water tank 40 and the second water tank 80 are both movably mounted outside the smoke exhaust pipe 50, the first water tank 40 and the second water tank 80 are both communicated with the heat preservation assembly 20, the driving assembly 70 is configured to drive the second water tank 80 and the first water tank 40 to reciprocate along a length direction of the smoke exhaust pipe 50, and moving directions of the second water tank 80 and the first water tank 40 are always opposite.

When the sulfur burner works, flue gas generated by combustion inside the furnace body 10 is discharged through the smoke exhaust pipe 50, heat in the flue gas can be transferred to the first water tank 40 and the second water tank 80 through the side wall of the smoke exhaust pipe 50 at the moment, and then water inside the first water tank 40 and the second water tank 80 is heated, initially, the height of the first water tank 40 outside the smoke exhaust pipe 50 is higher than that of the second water tank 80, at the moment, water inside the first water tank 40 flows into the second water tank 80 through the heat preservation component 20 under the action of gravitational potential energy until the water level inside the first water tank 40 is flush with the water level inside the second water tank 80, then the driving component 70 drives the second water tank 80 and the first water tank 40 to move, so that the height of the first water tank 40 is lower than that of the second water tank 80, at the moment, water inside the second water tank 80 reversely flows into the first water tank 40 under the action of gravitational potential energy until the water level inside the first water tank 40 is flush with the inside the second water tank 80, the water level inside the first water tank 40 is flush with the water level inside the second water tank 80 until the water level inside the second water tank 80 and the water tank 80, so that the heat can be repeatedly transferred to the outer wall of the furnace body 10, the heat preservation component, the heat can be recovered by the outer wall of the heat preservation component, thereby realizing the effect that the heat can be repeatedly absorbed by the heat exchange effect of the heat exchange between the outer wall of the heat preservation water tank 10, the heat exchange of the furnace body 10, and the furnace body 10, thereby realizing the heat exchange effect of the furnace body 10, the heat exchange effect of the heat recovery outer wall of the furnace body 10, and the heat recovery of the heat recovery furnace body can be reduced.

Referring to fig. 1 and fig. 3, in an embodiment, the heat insulation assembly 20 includes a first annular heat insulation pipe 201, a second annular heat insulation pipe 204, and a plurality of strip heat insulation pipes 202, the first annular heat insulation pipe 201 and the second annular heat insulation pipe 204 are attached to an outer wall of the furnace body 10 and are distributed at intervals, the plurality of strip heat insulation pipes 202 are disposed between the first annular heat insulation pipe 201 and the second annular heat insulation pipe 204, two ends of the strip heat insulation pipes 202 are respectively communicated with the first annular heat insulation pipe 201 and the second annular heat insulation pipe 204 through communication pipes 203, the plurality of strip heat insulation pipes 202 are attached to the outer wall of the furnace body 10, and the first water tank 40 and the second water tank 80 are both communicated with the second annular heat insulation pipe 204 through flexible hoses 205.

When the first water tank 40 is higher than the second water tank 80, the water body in the first water tank 40 flows into the second water tank 80 through the telescopic hose 205, the second annular heat preservation pipe 204, the strip-shaped heat preservation pipe 202 and the first annular heat preservation pipe 201; when the height of the first water tank 40 is lower than that of the second water tank 80, the water body in the second water tank 80 flows into the first water tank 40 through the telescopic hose 205, the second annular heat preservation pipe 204, the strip-shaped heat preservation pipe 202 and the first annular heat preservation pipe 201, so that the water body absorbing the heat of the flue gas repeatedly flows in the first annular heat preservation pipe 201, the strip-shaped heat preservation pipe 202 and the second annular heat preservation pipe 204, and the outer wall of the furnace body 10 is uniformly heated.

Referring to fig. 1, 2 and 4, in one embodiment, a support plate 501 is fixedly disposed on an outer wall of the smoke exhaust pipe 50, the driving assembly 70 includes a motor (not shown), a winding wheel 701, a pulling rope 702, a transmission gear 703, a first rack 704 and a second rack (not shown), the motor is fixedly mounted on one side of the support plate 501, the winding wheel 701 is mounted at an output end of the motor, one end of the pulling rope 702 is connected to the winding wheel 701, the other end of the pulling rope is connected to the second water tank 80, the transmission gear 703 is rotatably mounted on the outer wall of the smoke exhaust pipe 50, the first rack 704 is disposed on one side of the second water tank 80, the second rack is disposed on one side of the first water tank 40, and the first rack 704 and the second rack are respectively disposed on two sides of the transmission gear 703 in a meshing manner.

The winding wheel 701 is driven to rotate by the motor, the traction rope 702 is further wound, the second water tank 80 is pulled to move along the outer portion of the smoke exhaust pipe 50 when the traction rope 702 is wound, the transmission gear 703 is driven to rotate through the meshing action of the first rack 704 and the transmission gear 703, the first water tank 40 is driven to reversely move along the outer portion of the smoke exhaust pipe 50 through the meshing action of the transmission gear 703 and the second rack when the transmission gear 703 rotates, the height of the second water tank 80 is higher than that of the first water tank 40, after water in the second water tank 80 flows into the first water tank 40, the motor drives the winding wheel 701 to reversely rotate so as to unwind the traction rope 702, the second water tank 80 reversely moves along the outer portion of the smoke exhaust pipe 50 under the action of self gravity when the traction rope 702 is unwound, at the moment, the first water tank 40 moves along the outer portion of the smoke exhaust pipe 50 through the transmission action among the first rack 704, the transmission gear 703 and the second rack, so that the height of the first water tank 40 is higher than that the height of the second water tank 80, and water in the first water tank 40 flows into the inner portion of the second water tank 80.

Referring to fig. 1 and 2, in one embodiment, one side of the first water tank 40 is connected to the outer wall of the furnace body 10 through a first elastic member 30, and when the pulling rope 702 is unwound and the second water tank 80 moves along the outside of the smoke exhaust pipe 50 in the opposite direction, the first elastic member 30 provides elastic support to the first water tank 40, so that the first elastic member 30 can provide thrust to the first water tank 40 to assist the first water tank 40 to move along the outside of the smoke exhaust pipe 50.

Referring to fig. 1 and 2, in an embodiment, a first guide rod 401 is fixedly disposed on a sidewall of the first water tank 40, a second guide rod 801 is fixedly disposed on a sidewall of the second water tank 80, and both the first guide rod 401 and the second guide rod 801 penetrate through the supporting plate 501 and are movably engaged with the supporting plate 501.

Through the movable fit between the first guide rod 401 and the second guide rod 801 and the support plate 501, a guiding effect is provided for the movement of the first water tank 40 and the second water tank 80, and the moving stability is improved.

Referring to fig. 2, in one embodiment, the first water tank 40 and the second water tank 80 are both arc-shaped, and both the first water tank 40 and the second water tank 80 are attached to the outer wall of the smoke exhaust pipe 50.

Referring to fig. 1, in an embodiment, a flow limiting assembly 60 is further disposed inside the smoke exhaust pipe 50, and the flow limiting assembly 60 is configured to limit flow of smoke flowing along the inside of the smoke exhaust pipe 50 to reduce flow rate of the smoke, so that the smoke can be in contact with a side wall of the smoke exhaust pipe 50 more sufficiently, thereby improving a recovery effect of heat of the smoke.

Referring to fig. 5, in an embodiment, the flow limiting assembly 60 includes a fixing plate 605 and a flow limiting plate 604, the fixing plate 605 is fixedly installed on the inner wall of the smoke exhaust pipe 50, a through hole 606 is formed in the middle of the fixing plate 605, the flow limiting plate 604 is attached to one side of the fixing plate 605, a guide post 602 is fixedly disposed on one side of the fixing plate 605, the guide post 602 penetrates through the flow limiting plate 604 and is movably engaged with the flow limiting plate 604, an end block 601 is fixedly disposed at one end of the guide post 602 away from the fixing plate 605, and the end block 601 is connected to the flow limiting plate 604 through a second elastic member 603.

The second elastic member 603 provides elastic support for the restrictor plate 604, so that the restrictor plate 604 is attached to one side of the fixing plate 605 to seal the through hole 606, when smoke flows along the inside of the smoke discharge pipe 50, the smoke passes through the through hole 606 and acts on the restrictor plate 604, so that the restrictor plate 604 is pushed to slide along the guide post 602, and then the smoke passes through a gap between the restrictor plate 604 and the fixing plate 605 and is discharged from the port of the smoke discharge pipe 50; the flow limiting plate 604 is used for blocking the smoke flowing along the inside of the smoke exhaust pipe 50, so that the flow limitation of the smoke is realized, the follow-up smoke can be better contacted with the side wall of the smoke exhaust pipe 50, and the recovery effect of the heat of the smoke is improved.

In an embodiment, the first elastic element 30 and the second elastic element 603 may be a spring or a metal spring, which is not limited herein.

In the embodiment of the invention, when the sulfur burner works, flue gas generated by combustion in the furnace body 10 is discharged through the smoke exhaust pipe 50, at the moment, heat in the flue gas can be transferred to the first water tank 40 and the second water tank 80 through the side wall of the smoke exhaust pipe 50, and then water bodies in the first water tank 40 and the second water tank 80 are heated, initially, the height of the first water tank 40 outside the smoke exhaust pipe 50 is higher than that of the second water tank 80, at the moment, the water body in the first water tank 40 flows into the second water tank 80 through the heat preservation component 20 under the action of gravitational potential energy until the water level in the first water tank 40 is flush with the water level in the second water tank 80, then the driving component 70 drives the second water tank 80 and the first water tank 40 to move, so that the height of the first water tank 40 is lower than that of the second water tank 80, at the moment, the water body in the second water tank 80 reversely flows into the first water tank 40 through the heat preservation component 20 under the action of gravitational potential energy, until the water level in the first water tank 40 is flush with the water level in the second water tank 80, the driving component 70 drives the second water tank 80 and the first water tank 40 to move again, so that the height of the first water tank 40 is higher than that of the second water tank 80 again, the water in the first water tank 40 flows into the second water tank 80 again through the heat insulation component 20, and the reciprocating circulation can realize the repeated flow of the heated water in the heat insulation component 20, because the heat insulation component 20 is attached to the outer wall of the furnace body 10, the water absorbing the heat of the flue gas can transfer the heat to the outer wall of the furnace body 10 through the heat insulation component 20, so as to realize the heating and heat insulation of the outer wall of the furnace body 10, reduce the temperature difference of the inner wall and the outer wall of the furnace body 10, further reduce the heat exchange effect between the inner part of the furnace body 10 and the external environment, avoid the heat loss in the furnace body 10, and realize the recycling of the waste heat of the flue gas, compared with the prior art, the high-efficiency recovery of the heat of the flue gas during combustion of the sulfur burning furnace can be realized, the average white loss of the heat of the flue gas is effectively avoided, and the energy-saving effect is good.

Although the preferred embodiments of the present patent have been described in detail, the present patent is not limited to the above embodiments, and various changes can be made without departing from the spirit of the present patent within the knowledge of those skilled in the art.

Claims (8)

1. A sulfur burning furnace with a heat recycling structure is characterized by comprising a furnace body, a heat preservation component, a first water tank, a smoke exhaust pipe, a driving component and a second water tank,

the smoke exhaust pipe is arranged at one end of the furnace body and communicated with the furnace body for realizing the emission of combustion smoke in the furnace body,

the heat insulation component is attached to the outer wall of the furnace body and is used for heating and insulating the outer wall of the furnace body,

the first water tank and the second water tank are movably arranged outside the smoke exhaust pipe and are communicated with the heat preservation component,

the driving assembly is used for driving the second water tank and the first water tank to reciprocate along the length direction of the smoke exhaust pipe, and the moving directions of the second water tank and the first water tank are opposite all the time.

2. The incinerator with heat recycling structure according to claim 1, wherein said heat-insulating member comprises a first ring-shaped heat-insulating pipe, a second ring-shaped heat-insulating pipe and a plurality of strip-shaped heat-insulating pipes,

the first annular heat-preserving pipe and the second annular heat-preserving pipe are attached to the outer wall of the furnace body and are distributed at intervals, a plurality of strip-shaped heat-preserving pipes are arranged between the first annular heat-preserving pipe and the second annular heat-preserving pipe, two ends of each strip-shaped heat-preserving pipe are respectively communicated with the first annular heat-preserving pipe and the second annular heat-preserving pipe through communicating pipes,

a plurality of the bar insulating tube all with the furnace body outer wall pastes, first water tank and the second water tank all through the bellows with second annular insulating tube intercommunication.

3. The sulfur burner with heat recycling structure as claimed in claim 1, wherein the outer wall of the smoke discharging pipe is fixedly provided with a supporting plate,

the driving component comprises a motor, a rolling wheel, a traction rope, a transmission gear, a first rack and a second rack,

the motor is fixedly arranged on one side of the supporting plate, the winding wheel is arranged at the output end of the motor, one end of the traction rope is connected with the winding wheel, the other end of the traction rope is connected with the second water tank,

the transmission gear is rotatably installed on the outer wall of the smoke exhaust pipe, the first rack is arranged on one side of the second water tank, the second rack is arranged on one side of the first water tank, and the first rack and the second rack are respectively meshed with the two sides of the transmission gear.

4. The incinerator with heat recycling structure according to claim 3, wherein one side of said first water tank is connected to the outer wall of said furnace body by a first elastic member.

5. The incinerator with heat recycling structure as claimed in claim 3, wherein a first guide rod is fixedly arranged on the side wall of the first water tank, a second guide rod is fixedly arranged on the side wall of the second water tank, and the first guide rod and the second guide rod both penetrate through the support plate and are movably matched with the support plate.

6. The incinerator of claim 1, wherein the first and second water tanks are of an arc-shaped configuration and are attached to the outer wall of the flue pipe.

7. The incinerator with heat recycling structure according to claim 1, wherein a flow restriction member is further provided inside said flue gas duct, said flow restriction member being adapted to restrict flow of flue gas flowing along the inside of said flue gas duct.

8. The incinerator of claim 7, wherein the flow restricting member comprises a fixing plate and a flow restricting plate,

the fixed plate is fixedly arranged on the inner wall of the smoke exhaust pipe, a through hole is arranged in the middle of the fixed plate, the current limiting plate is attached to one side of the fixed plate,

one side of the fixed plate is fixedly provided with a guide post which penetrates through the flow restricting plate and is movably matched with the flow restricting plate, one end of the guide post, which is far away from the fixed plate, is fixedly provided with an end block,

the end block is connected with the flow limiting plate through a second elastic piece.

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