CN215112648U - Low-heat-value salt-free waste liquid integrated incinerator - Google Patents

Abstract

The utility model discloses a low-heat value salt-free waste liquid integrated incinerator, which comprises a control combustion assembly, a waste liquid conveying assembly, a gas emission conversion assembly and a cooling conveying assembly, wherein the control combustion assembly comprises a first shell, a first through hole, a first plate body, a handle, a heat storage wall, a heat sensor, a smoke sensor, a second through hole, a burner, a medium pressure fan, a first connecting plate, a first pipe body, a fan, a leakage net, a combustion chamber and a controller; and the discharged gas with high heat is cooled through the water tank and the spraying water storage tank, so that purified water with certain heat can be manufactured, hot water is provided for a plant area, cyclic utilization is realized, the environment is protected, the exhaust chimney is connected with the second pipe body, the adaptability of the equipment is improved, the occupied area is small, and the equipment purchase cost of a plant is reduced.

Description

Low-heat-value salt-free waste liquid integrated incinerator

Technical Field

The utility model relates to a waste incinerator field specifically is low heat value salt-free waste liquid integral type incinerator.

Background

The waste liquid treatment comprises waste liquid incineration, organic waste liquid treatment or organic industrial waste liquid treatment, also called high-concentration organic waste water treatment, the treatment method comprises three treatment methods, namely a physical treatment method, a chemical treatment method and a biological treatment method, the chemical treatment method is generally combined with a physical process and also called a physical chemical treatment method, the physical treatment method is used for treating the waste liquid by physical or mechanical separation, the common methods comprise filtration, precipitation and floating, oil removal and centrifugal separation, wherein the chemical treatment method is a wastewater treatment method for separating and removing pollutants in a dissolved and colloidal state in wastewater or converting the pollutants into harmless substances through chemical reaction and mass transfer, and the biological treatment method is a wastewater treatment method for converting organic pollutants in a solution, colloid and fine suspension state in wastewater into stable and harmless substances through the metabolism of microorganisms;

the existing waste liquid treatment mostly uses a combustion furnace for treatment, and the waste liquid is evaporated through high temperature to generate gas for discharge, but the existing combustion furnace has certain defects;

firstly, the heat value of the waste liquid is low, and when the treatment capacity per hour is relatively large, the consumption of the adopted horizontal direct-fired furnace is increased relative to the consumption of auxiliary fuel, and the operation cost is increased;

secondly, gas generated after waste liquid incineration needs heat exchange and dust removal because the temperature is more than or equal to 900 ℃ and the gas contains ash and other particles, and a large amount of use area needs to be occupied because of a conventional treatment mode;

thirdly, for a waste liquid incinerator with relatively large treatment capacity, in order to enable harmful substances to be sufficiently combusted and decomposed, sufficient supplement of combustion-supporting air is difficult to ensure, and therefore combustion is insufficient;

for a waste liquid incinerator with relatively large treatment capacity, the surge flow degree and residence time of the smoke in the incinerator are insufficient to influence the incineration efficiency under the condition that the hearth space of the incinerator is not increased;

therefore, the low-calorific-value salt-free waste liquid integrated incinerator is proposed.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a low heat value does not have salt waste liquid integral type and burns burning furnace to solve the problem that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: the low-calorific-value salt-free waste liquid integrated incinerator comprises a control combustion assembly, a waste liquid conveying assembly, a gas emission conversion assembly and a cooling conveying assembly, wherein the control combustion assembly comprises a first shell, a first through hole, a first plate body, a handle, a heat storage wall, a heat sensor, a smoke sensor, a second through hole, a combustor, a medium pressure fan, a first connecting plate, a first pipe body, a fan, a leakage net, a combustion chamber and a controller;

a combustion chamber is arranged in the first shell, a heat storage wall is welded on the top wall in the first shell, a heat sensor is arranged on one side of the heat storage wall of the inner top wall of the first shell, a smoke sensor is arranged on the other side of the heat storage wall of the inner top wall of the first shell, the upper surface of the first shell is provided with a second through hole, one side of the first shell is provided with a burner, an output pipe of the combustor penetrates through one side of the first shell, a medium pressure fan is welded on one side of the first shell and below the combustor, an output pipe of the medium pressure fan penetrates through one side of the first shell, a first connecting plate is welded on the inner side wall of the first shell, one side welding of first connecting plate keeping away from first casing has first body, the upper surface welding of first casing has the controller.

Preferably: the fan is characterized in that the inner side wall of the first pipe body is hinged to a fan through a pin shaft, the inner side wall of the first pipe body is located at the rear side of the fan, a leakage net is welded to the inner side wall of the first pipe body, a first through hole is formed in the other side of the first shell, a first plate body penetrates through the inner portion of the first through hole, and a handle is welded to one side, away from the first shell, of the first plate body.

Preferably: the waste liquid conveying assembly comprises a second shell, a waste liquid inlet pipe, a third shell, a motor, a rod body, a second plate body, a fourth shell, a first water pump, an L-shaped water inlet pipe, a first Z-shaped water outlet pipe and a liquid flowmeter;

the utility model discloses a combustor, including first casing, second casing, motor, body of rod, second plate body, first shell, second shell, the welding of the inside roof of second casing has the third casing, the welding of the inside roof of third casing has the motor, the output shaft of motor passes through the bearing and rotates to be connected in the lower surface of third casing, the welding of the output shaft of motor has the body of rod, the even welding in both sides of the body of rod has the second plate body, one side welding that the second casing is close to first casing has the fourth casing, the lower surface of combustor welds in the upper surface of fourth casing.

Preferably: the utility model discloses a water pump, including first casing, second casing, fourth casing, water inlet and outlet pipes, the second casing is kept away from one side of fourth casing and is run through there is the waste liquid admission pipe, the welding of the inside diapire of fourth casing has first water pump, the water inlet intercommunication of first water pump has L type inlet tube, the lateral wall of L type inlet tube runs through in the inside wall of fourth casing and second casing in proper order, the delivery port intercommunication of first water pump has first Z type outlet pipe, the lateral wall of first Z type outlet pipe runs through in proper order in the inside wall of fourth casing and first casing, one side that first water pump was kept away from to first Z type outlet pipe welds in one side that first body was kept away from to first connecting plate, fluidflowmeter is installed to the lateral wall of first Z type outlet pipe.

Preferably: the gas emission conversion assembly comprises a second pipe body, a water-cooling heat exchange wall, an inclined plate, a fifth shell, a drain pipe, a cylinder, a second connecting plate and an exhaust chimney;

the upper surface of first casing just is located the top welding of second through-hole has the second body, the water-cooling heat transfer wall is installed to the inside wall of second body, the inside wall welding of water-cooling heat transfer wall has two swash plates, and the inclination of swash plate is thirty-five degrees of horizontal direction, the inside wall welding of water-cooling heat transfer wall has the fifth casing, one side that the fifth casing is close to the water-cooling heat transfer wall is run through there is the drain pipe, the lateral wall of drain pipe runs through in proper order in the inside wall of second body and water-cooling heat transfer wall.

Preferably: the upper surface welding of first casing has the cylinder, the piston rod of cylinder runs through in the inside wall of second body and water-cooling heat transfer wall in proper order, the piston rod welding of cylinder has the second connecting plate, the lateral wall laminating of second connecting plate in the second through-hole, the upper surface welding of second body has the exhaust chimney.

Preferably: the cooling and conveying assembly comprises a water tank, a ball float valve, a second water pump, an L-shaped connecting pipe, a second Z-shaped water outlet pipe, a first water purification connecting pipe, a spraying water storage tank, a third water pump, a water inlet pipe, a water outlet pipe, a fourth pipe body, a spiral spray head and a second water purification connecting pipe;

the welding of the opposite side of first casing has the water tank, the welding of the inside diapire of water tank has the ball-cock assembly, the delivery port intercommunication of ball-cock assembly has L type connecting pipe, the inside wall welding of water tank has the second water pump, one side that the ball-cock assembly was kept away from to L type connecting pipe communicates in the water inlet of second water pump, the delivery port intercommunication of second water pump has second Z type outlet pipe, the lateral wall of second Z type outlet pipe runs through in the inside wall of water tank and second body in proper order, the lower surface of water tank runs through there is first water purification connecting pipe.

Preferably: the welding of one side that first casing was kept away from to the water tank has the storage water tank that sprays, the inside wall welding that sprays the storage water tank has the third water pump, the water inlet intercommunication of third water pump has the inlet tube, the delivery port intercommunication of third water pump has the outlet pipe, the lateral wall of outlet pipe runs through in the upper surface that sprays the storage water tank, one side that the outlet pipe is close to exhaust chimney evenly runs through there is the fourth body, the lateral wall of fourth body runs through in exhaust chimney's inside, the lower surface of fourth body evenly installs spiral shower nozzle, one side that the storage water tank was kept away from to the storage water tank that sprays runs through there is second water purification connecting pipe.

Compared with the prior art, the beneficial effects of the utility model are that:

firstly, the material made by the equipment is a common material, so that the purchase cost during the production of the equipment is reduced, the temperature in the combustion chamber is monitored by the thermal sensor, the temperature in the combustion chamber is controlled by the combustor and the medium-pressure fan, the concentration of gas generated by evaporation of waste liquid in the combustion chamber is monitored by the smoke sensor, when the discharge amount is reached, the gas is discharged through the second through hole, the debugging cost for different burning amounts is reduced by a highly automatic operating system, and the equipment can run automatically without manual intervention after being started normally;

two, absorb the heat in the flue gas through the heat accumulation wall, preserve the temperature in the furnace, reduce calorific loss, reduce fuel consumption, improve the burn-up rate, and cool off the gas that has high heat that discharges through the water tank and spray the storage water tank, thereby can make certain thermal water purification, for the factory provides hot water, thereby realize cyclic utilization and environmental protection, exhaust chimney is connected with the second body, thereby improve equipment's adaptability is wide, area is little, reduce the equipment purchase cost of mill.

Drawings

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

fig. 2 is a schematic sectional structure of the present invention;

FIG. 3 is a schematic structural view of a cooling and conveying assembly of the present invention;

fig. 4 is a schematic sectional view of the first tube of the present invention;

fig. 5 is a circuit diagram of the thermal sensor and the controller according to the present invention;

fig. 6 is a circuit diagram of the smoke sensor and the controller according to the present invention.

In the figure: 1. controlling the combustion assembly; 101. a first housing; 11. a first through hole; 12. a first plate body; 13. a handle; 14. a heat storage wall; 15. a thermal sensor; 16. a smoke sensor; 17. a second through hole; 18. a burner; 19. a medium pressure fan; 20. a first connecting plate; 21. a first pipe body; 2101. a fan; 2102. a leakage net; 22. a combustion chamber; 23. a controller; 3. a waste liquid conveying assembly; 301. a second housing; 31. a waste liquid inlet pipe; 32. a third housing; 33. a motor; 34. a rod body; 35. a second plate body; 36. a fourth housing; 37. a first water pump; 38. an L-shaped water inlet pipe; 39. a first Z-shaped water outlet pipe; 40. a liquid flow meter; 5. a gas discharge conversion assembly; 501. a second tube body; 51. a water-cooled heat exchange wall; 52. a sloping plate; 53. a fifth housing; 54. a drain pipe; 55. a cylinder; 56. a second connecting plate; 57. an exhaust stack; 6. a cooling conveyor assembly; 601. a water tank; 61. a float valve; 62. a second water pump; 63. an L-shaped connecting pipe; 64. a second Z-shaped water outlet pipe; 65. a first water purification connecting pipe; 66. a spray water storage tank; 67. a third water pump; 68. a water inlet pipe; 69. a water outlet pipe; 70. a fourth tube body; 71. a spiral spray head; 72. the second pure water connecting pipe.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Examples

Referring to fig. 1-6, the present invention provides a technical solution: the low-calorific-value salt-free waste liquid integrated incinerator comprises a control combustion assembly 1, a waste liquid conveying assembly 3, a gas emission conversion assembly 5 and a cooling conveying assembly 6, wherein the control combustion assembly 1 comprises a first shell 101, a first through hole 11, a first plate body 12, a handle 13, a heat storage wall 14, a heat sensor 15, a smoke sensor 16, a second through hole 17, a combustor 18, a medium pressure fan 19, a first connecting plate 20, a first pipe body 21, a fan 2101, a leakage net 2102, a combustion chamber 22 and a controller 23;

the combustor 22 is arranged in the first shell 101, the heat storage wall 14 is welded on the top wall in the first shell 101, the thermal sensor 15 is arranged on one side, located on the heat storage wall 14, of the top wall in the first shell 101, the smoke sensor 16 is arranged on the other side, located on the heat storage wall 14, of the top wall in the first shell 101, the second through hole 17 is formed in the upper surface of the first shell 101, the combustor 18 is arranged on one side of the first shell 101, an output pipe of the combustor 18 penetrates through one side of the first shell 101, the medium-pressure fan 19 is welded on one side of the first shell 101 and below the combustor 18, the output pipe of the medium-pressure fan 19 penetrates through one side of the first shell 101, the first connecting plate 20 is welded on the inner side wall of the first shell 101, the first pipe body 21 is welded on one side, away from the first shell 101, and the controller 23 is welded on the upper surface of the first shell 101.

In this embodiment, specifically: the inside wall of first body 21 has fan 2101 through the round pin axle is articulated, the inside wall of first body 21 and the rear welding that is located fan 2101 have the hourglass net 2102, first through-hole 11 has been seted up to the opposite side of first casing 101, first plate body 12 has been run through to the inside of first through-hole 11, one side welding that first casing 101 was kept away from to first plate body 12 has handle 13, through setting up first plate body 12, be used for holding the surplus dust of the inside burning of combustion chamber 22, thereby guarantee the inside clean and tidy of combustion chamber 22, with the help of fan 2101 in the first body 21, can accelerate the circulation of waste liquid in first body 21, and realize spun waste liquid atomizing through leaking the net 2102, thereby reach abundant burning.

In this embodiment, specifically: the waste liquid conveying assembly 3 comprises a second shell 301, a waste liquid inlet pipe 31, a third shell 32, a motor 33, a rod body 34, a second plate body 35, a fourth shell 36, a first water pump 37, an L-shaped water inlet pipe 38, a first Z-shaped water outlet pipe 39 and a liquid flow meter 40;

the welding of the inside roof of second casing 301 has third casing 32, the welding of the inside roof of third casing 32 has motor 33, the output shaft of motor 33 passes through the bearing and rotates to be connected in the lower surface of third casing 32, the welding of the output shaft of motor 33 has the body of rod 34, the even welding of the both sides of the body of rod 34 has second plate body 35, one side welding that second casing 301 is close to first casing 101 has fourth casing 36, the lower surface of combustor 18 welds in the upper surface of fourth casing 36, the output shaft through motor 33 drives the body of rod 34 and rotates, the second plate body 35 of connection on the body of rod 34 links, thereby stir the waste liquid, avoid depositing at the inside impurity that produces of second casing 301.

In this embodiment, specifically: a waste liquid inlet pipe 31 penetrates through one side, far away from the fourth shell 36, of the second shell 301, a first water pump 37 is welded on the bottom wall inside the fourth shell 36, a water inlet of the first water pump 37 is communicated with an L-shaped water inlet pipe 38, the outer side wall of the L-shaped water inlet pipe 38 sequentially penetrates through the inner side walls of the fourth shell 36 and the second shell 301, a water outlet of the first water pump 37 is communicated with a first Z-shaped water outlet pipe 39, the outer side wall of the first Z-shaped water outlet pipe 39 sequentially penetrates through the inner side walls of the fourth shell 36 and the first shell 101, one side, far away from the first water pump 37, of the first Z-shaped water outlet pipe 39 is welded on one side, far away from the first pipe body 21, of the first connecting plate 20, a liquid flow meter 40 is installed on the outer side wall of the first Z-shaped water outlet pipe 39, waste liquid inside the second shell 301 is conveyed to the inside of the first shell 101 through the first water pump 37 by utilizing the L-shaped water inlet pipe 38 and the first Z-shaped water outlet pipe 39 to be combusted, a liquid flow meter 40 is installed for measuring the amount of water flowing to the inside of the first housing 101.

In this embodiment, specifically: the gas discharge conversion assembly 5 comprises a second pipe body 501, a water-cooled heat exchange wall 51, an inclined plate 52, a fifth shell 53, a drain pipe 54, a cylinder 55, a second connecting plate 56 and an exhaust chimney 57;

a second tube 501 is welded on the upper surface of the first shell 101 and above the second through hole 17, a water-cooling heat exchange wall 51 is installed on the inner side wall of the second tube 501, two inclined plates 52 are welded on the inner side wall of the water-cooling heat exchange wall 51, and the inclined angle of the inclined plate 52 is thirty-five degrees in the horizontal direction, the inner side wall of the water-cooled heat exchange wall 51 is welded with a fifth shell 53, a drain pipe 54 penetrates through one side of the fifth shell 53 close to the water-cooled heat exchange wall 51, the outer side wall of the drain pipe 54 penetrates through the second pipe body 501 and the inner side wall of the water-cooled heat exchange wall 51 in sequence, make the exhaust gas temperature reduce through setting up water-cooling heat transfer wall 51, through setting up swash plate 52, guarantee that the water of conversion heating enters into inside the fifth casing 53, borrow by drain pipe 54 and connect fifth casing 53, realize the hot water drainage, the water-cooling heat transfer wall 51 of setting produces hot water through the heat transfer to the hot water that provides the factory uses.

In this embodiment, specifically: the upper surface welding of first casing 101 has cylinder 55, and the piston rod of cylinder 55 runs through in the inside wall of second body 501 and water-cooling heat transfer wall 51 in proper order, and the piston rod welding of cylinder 55 has second connecting plate 56, and the lateral wall laminating of second connecting plate 56 is in second through-hole 17, and the upper surface welding of second body 501 has exhaust chimney 57, and the second connecting plate 56 that drives the connection through setting up cylinder 55 carries out horizontal migration to utilize second connecting plate 56 to control exhaust through second through-hole 17.

In this embodiment, specifically: the cooling and conveying assembly 6 comprises a water tank 601, a ball float valve 61, a second water pump 62, an L-shaped connecting pipe 63, a second Z-shaped water outlet pipe 64, a first purified water connecting pipe 65, a spraying water storage tank 66, a third water pump 67, a water inlet pipe 68, a water outlet pipe 69, a fourth pipe body 70, a spiral spray head 71 and a second purified water connecting pipe 72;

the welding of the opposite side of first casing 101 has water tank 601, the welding of the inside diapire of water tank 601 has ball-cock assembly 61, the delivery port intercommunication of ball-cock assembly 61 has L type connecting pipe 63, the welding of the inside wall of water tank 601 has second water pump 62, one side that L type connecting pipe 63 kept away from ball-cock assembly 61 communicates in the water inlet of second water pump 62, the delivery port intercommunication of second water pump 62 has second Z type outlet pipe 64, the lateral wall of second Z type outlet pipe 64 runs through in the inside wall of water tank 601 and second body 501 in proper order, the lower surface of water tank 601 runs through first water purification connecting pipe 65, realize replenishing the water yield by oneself through setting up ball-cock assembly 61, guarantee the inside water of water tank 601, the second water pump 62 that sets up is inside through the water inlet of ball-cock assembly 61 and the inside log raft of second Z type outlet pipe 64 with water tank 601.

In this embodiment, specifically: one side welding that first casing 101 was kept away from to water tank 601 has the storage water tank 66 that sprays, the inside wall welding that the storage water tank 66 that sprays has third water pump 67, the water inlet intercommunication of third water pump 67 has inlet tube 68, the delivery port intercommunication of third water pump 67 has outlet pipe 69, the lateral wall of outlet pipe 69 runs through in the upper surface that the storage water tank 66 sprays, one side that outlet pipe 69 is close to exhaust chimney 57 evenly runs through has fourth body 70, the lateral wall of fourth body 70 runs through in the inside of exhaust chimney 57, spiral shower nozzle 71 is evenly installed to the lower surface of fourth body 70, it has second water purification connecting pipe 72 to run through in one side that the storage water tank 66 that sprays kept away from water tank 601, through setting up third water pump 67, spray the inside water of storage water tank 66 through the spiral shower nozzle 71 that fourth body 70 is connected through inlet tube 68 and outlet pipe 69 and spray in the exhaust chimney 57.

In this embodiment, a switch set for controlling the start and the stop of the motor 33, the first water pump 37, the second water pump 62, the third water pump 67 and the cylinder 55 is installed on one side of the second casing 301, and the switch set is connected with an external commercial power to supply power to the motor 33, the first water pump 37, the second water pump 62, the third water pump 67 and the cylinder 55.

In this embodiment: the motor 33 is model number YE2-160M 1-2.

In this embodiment: the first water pump 37 is model number ISG 50-160.

In this embodiment: the second water pump 62 is model TPH4T 4K.

In this embodiment: the third water pump 67 is of the type IHG 20-110.

In this embodiment: the medium pressure fan 19 is of the type CX-75.

In this embodiment: the burner 18 is an integrated automatic adjusting burner, and the model of the burner 18 is Xx-0067.

In this embodiment: the heat sensor 15 is of model JL-403C.

In this embodiment: the smoke sensor 16 is model GQQ 5.

In this embodiment: the controller 23 is of the type DR 1-2000.

Working principle or structural principle: during use, the waste liquid is conveyed into the second shell 301 through the waste liquid inlet pipe 31, the switch group is turned on to start the motor 33 in the third shell 32, the output shaft of the motor 33 drives the rod body 34 to rotate, so that the second plate body 35 connected to the rod body 34 is linked, the waste liquid in the second shell 301 is stirred, impurity precipitation is avoided, the switch group is turned on to start the first water pump 37, the first water pump 37 conveys the waste liquid in the second shell 301 into the first shell 101 through the L-shaped water inlet pipe 38 and the first Z-shaped water outlet pipe 39, the flow of the waste liquid is accelerated by the fan 2101 in the first tube body 21, the waste liquid is atomized through the leakage net 2102, combustion is better performed, and the amount of the waste liquid entering the first shell 101 from the second shell 301 can be monitored in real time through the liquid flow meter 40 arranged on the first Z-shaped water outlet pipe 39;

the temperature inside the combustion chamber 22 is monitored in real time through the thermal sensor 15, when the temperature is reduced or increased, the thermal sensor 15 transmits a received signal to the controller 23, the controller 23 drives the opening and closing of the combustor 18 and the medium pressure fan 19, so that the time for observing and adjusting by personnel is saved, the heat in the evaporated gas can be preserved by utilizing the heat storage wall 14, the temperature inside the hearth is preserved, the heat loss is reduced, the fuel consumption is reduced, the gas concentration inside the combustion chamber 22 is monitored in real time through the arranged smoke sensor 16, when the gas concentration reaches the discharge amount, the smoke sensor 16 transmits the received signal to the controller 23, the controller 23 drives the cylinder 55, the piston rod of the cylinder 55 drives the connected second connecting plate 56 to horizontally move, so that the gas is discharged through the second through hole 17;

when the discharged gas passes through the second pipe 501, the gas is cooled by means of the water-cooling heat exchange wall 51, the switch group is turned on to simultaneously start the second water pump 62 in the water tank 601 and the third water pump 67 in the spray water storage tank 66, the second water pump 62 conveys the purified water to the inside of the second pipe 501 through the L-shaped connecting pipe 63 and the second Z-shaped water outlet pipe 64 which are connected with the water outlet of the float valve 61 to cool the gas, the third water pump 67 utilizes the water in the spray water storage tank 66 through the water inlet pipe 68 and the water outlet pipe 69, the purified water is discharged into the exhaust chimney 57 to cool the gas through the spiral nozzle 71 arranged on the fourth pipe 70 connected with the water outlet pipe 69, the purified water is mixed with the gas, the mixed water enters the inside of the fifth shell 53 through the two inclined plates 52, and is discharged by means of the water outlet pipe 54.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. Low heat value does not have salt class waste liquid integral type and burns burning furnace, including control combustion assembly (1), waste liquid conveyor components (3), gas emission conversion subassembly (5) and cooling conveyor components (6), its characterized in that: the combustion control assembly (1) comprises a first shell (101), a first through hole (11), a first plate body (12), a handle (13), a heat storage wall (14), a heat sensor (15), a smoke sensor (16), a second through hole (17), a combustor (18), a medium pressure fan (19), a first connecting plate (20), a first pipe body (21), a fan (2101), a leakage net (2102), a combustion chamber (22) and a controller (23);

the combustor (22) has been seted up to the inside of first casing (101), the welding of the inside roof of first casing (101) has heat accumulation wall (14), the inside roof of first casing (101) just is located thermal sensor (15) are installed to one side of heat accumulation wall (14), the inside roof of first casing (101) just is located smoke sensor (16) are installed to the opposite side of heat accumulation wall (14), second through-hole (17) have been seted up to the upper surface of first casing (101), one side of first casing (101) is equipped with combustor (18), the output tube of combustor (18) runs through in one side of first casing (101), one side of first casing (101) just is located the welding of the below of combustor (18) has medium pressure fan (19), the output tube of medium pressure fan (19) runs through in one side of first casing (101), the welding of the inside wall of first casing (101) has first connecting plate (20), one side welding that first casing (101) were kept away from in first connecting plate (20) has first body (21), the upper surface welding of first casing (101) has controller (23).

2. The low-heating-value, salt-free liquid waste integrated incinerator according to claim 1, wherein: the utility model discloses a fan, including first body (21), fan (2101), first through-hole (11) have been seted up to the opposite side of first casing (101), first plate body (12) have been run through to the inside of first through-hole (11), one side welding that first casing (101) were kept away from to first plate body (12) has handle (13), the inside wall of first body (21) has fan (2101) through the round pin axle is articulated, the inside wall of first body (21) just is located the rear welding of fan (2101) has hourglass net (2102), first through-hole (11) have been seted up to the opposite side of first casing (101).

3. The low-heating-value, salt-free liquid waste integrated incinerator according to claim 1, wherein: the waste liquid conveying assembly (3) comprises a second shell (301), a waste liquid inlet pipe (31), a third shell (32), a motor (33), a rod body (34), a second plate body (35), a fourth shell (36), a first water pump (37), an L-shaped water inlet pipe (38), a first Z-shaped water outlet pipe (39) and a liquid flowmeter (40);

the welding of the inside roof of second casing (301) has third casing (32), the welding of the inside roof of third casing (32) has motor (33), the output shaft of motor (33) passes through the bearing and rotates the lower surface of connecting in third casing (32), the welding of the output shaft of motor (33) has the body of rod (34), the even welding in both sides of the body of rod (34) has second plate body (35), one side welding that second casing (301) is close to first casing (101) has fourth casing (36), the lower surface of combustor (18) welds in the upper surface of fourth casing (36).

4. The incinerator of claim 3, wherein said incinerator further comprises: a waste liquid inlet pipe (31) penetrates through one side of the second shell (301) far away from the fourth shell (36), a first water pump (37) is welded on the bottom wall of the inner part of the fourth shell (36), a water inlet of the first water pump (37) is communicated with an L-shaped water inlet pipe (38), the outer side wall of the L-shaped water inlet pipe (38) sequentially penetrates through the inner side walls of the fourth shell (36) and the second shell (301), the water outlet of the first water pump (37) is communicated with a first Z-shaped water outlet pipe (39), the outer side wall of the first Z-shaped water outlet pipe (39) sequentially penetrates through the inner side walls of the fourth shell (36) and the first shell (101), one side of the first Z-shaped water outlet pipe (39) far away from the first water pump (37) is welded on one side of the first connecting plate (20) far away from the first pipe body (21), and a liquid flow meter (40) is arranged on the outer side wall of the first Z-shaped water outlet pipe (39).

5. The low-heating-value, salt-free liquid waste integrated incinerator according to claim 1, wherein: the gas emission conversion assembly (5) comprises a second pipe body (501), a water-cooling heat exchange wall (51), an inclined plate (52), a fifth shell (53), a drain pipe (54), a cylinder (55), a second connecting plate (56) and an exhaust chimney (57);

the upper surface of first casing (101) just is located the top welding of second through-hole (17) has second body (501), water-cooling heat transfer wall (51) is installed to the inside wall of second body (501), the inside wall welding of water-cooling heat transfer wall (51) has two swash plates (52), and the inclination of swash plate (52) is thirty-five degrees of horizontal direction, the inside wall welding of water-cooling heat transfer wall (51) has fifth casing (53), one side that fifth casing (53) are close to water-cooling heat transfer wall (51) runs through drain pipe (54), the lateral wall of drain pipe (54) runs through in proper order in the inside wall of second body (501) and water-cooling heat transfer wall (51).

6. The low-heating-value salt-free liquid waste integrated incinerator according to claim 5, wherein: the upper surface welding of first casing (101) has cylinder (55), the piston rod of cylinder (55) runs through in the inside wall of second body (501) and water-cooling heat transfer wall (51) in proper order, the piston rod welding of cylinder (55) has second connecting plate (56), the lateral wall laminating of second connecting plate (56) is in second through-hole (17), the upper surface welding of second body (501) has exhaust chimney (57).

7. The low-heating-value, salt-free liquid waste integrated incinerator according to claim 1, wherein: the cooling and conveying assembly (6) comprises a water tank (601), a ball float valve (61), a second water pump (62), an L-shaped connecting pipe (63), a second Z-shaped water outlet pipe (64), a first purified water connecting pipe (65), a spraying water storage tank (66), a third water pump (67), a water inlet pipe (68), a water outlet pipe (69), a fourth pipe body (70), a spiral spray head (71) and a second purified water connecting pipe (72);

the opposite side welding of first casing (101) has water tank (601), the inside diapire welding of water tank (601) has ball-cock assembly (61), the delivery port intercommunication of ball-cock assembly (61) has L type connecting pipe (63), the inside wall welding of water tank (601) has second water pump (62), one side that ball-cock assembly (61) was kept away from in L type connecting pipe (63) communicates in the water inlet of second water pump (62), the delivery port intercommunication of second water pump (62) has second Z type outlet pipe (64), the lateral wall of second Z type outlet pipe (64) runs through the inside wall in water tank (601) and second body (501) in proper order, the lower surface of water tank (601) runs through there is first water purification connecting pipe (65).

8. The low-heating-value, salt-free liquid waste integrated incinerator according to claim 7, wherein: one side welding that first casing (101) was kept away from in water tank (601) has the storage water tank (66) that sprays, the inside wall welding that sprays storage water tank (66) has third water pump (67), the water inlet intercommunication of third water pump (67) has inlet tube (68), the delivery port intercommunication of third water pump (67) has outlet pipe (69), the lateral wall of outlet pipe (69) runs through in the upper surface that sprays storage water tank (66), one side that outlet pipe (69) are close to exhaust stack (57) evenly runs through fourth body (70), the lateral wall of fourth body (70) runs through in the inside of exhaust stack (57), the lower surface of fourth body (70) evenly installs spiral spray nozzle (71), one side that the storage water tank (66) was kept away from water tank (601) runs through there is second water purification connecting pipe (72).

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