CN116576469B - Explosion-proof temperature control type heat accumulating incinerator - Google Patents

Abstract

The invention relates to the technical field of organic waste gas treatment, in particular to an explosion-proof temperature control type heat accumulating incinerator. Including the landing leg, the landing leg rigid coupling has the mounting, and the mounting is provided with inlet and outlet, and the mounting upside rigid coupling has the combustion jar, and the top of combustion jar is provided with driving motor, and driving motor's drive shaft rigid coupling has the dead lever, and the rigid coupling has first fixed disk in the combustion jar, and the dead lever rigid coupling has the fan-shaped heat accumulation piece of circumference equidistance distribution, and fan-shaped heat accumulation piece is provided with the through-hole, and the bore of through-hole is increased in proper order from the periphery of fan-shaped heat accumulation piece to the centre of a circle. According to the invention, the aperture of the through hole is changed, so that the amount of organic waste gas discharged from the through hole on the left side of the sector-shaped heat storage block is reduced, the upward flowing speed of the organic waste gas is increased, and the amount of organic waste gas discharged from the through hole on the right side of the sector-shaped heat storage block is increased, so that the upward flowing speed of the organic waste gas is reduced, and the organic waste gas discharged from the through hole on the right side of the sector-shaped heat storage block is fully contacted with flame.

Description

Explosion-proof temperature control type heat accumulating incinerator

Technical Field

The invention relates to the technical field of organic waste gas treatment, in particular to an explosion-proof temperature control type heat accumulating incinerator.

Background

The heat accumulating incinerator is one kind of waste gas treating apparatus with high temperature, and unlike conventional incinerator, the heat accumulating incinerator can decompose organic matter in waste into gas and ash, and the preheater is preheated with high temperature steam produced with waste gas to maintain the subsequent organic waste gas in high temperature state while entering the incinerator, so as to further reduce the treatment time of the organic waste gas.

The existing heat accumulating type incinerator is generally divided into: while the conventional rotary regenerative incinerator is used for treating organic waste gas, the flame of the rotary regenerative incinerator is lower than that of the burner, so that the flame sprayed by the burner cannot fully burn the organic waste gas which is relatively close to the burner when the organic waste gas is relatively close to the burner.

Disclosure of Invention

The invention provides an explosion-proof temperature-control type regenerative incinerator, which aims to solve the defect that flame sprayed by a burner cannot fully burn organic waste gas close to the burner.

The specific technical scheme is as follows: the utility model provides an explosion-proof control by temperature change formula heat accumulation formula incinerator, including the landing leg, the landing leg rigid coupling has the mounting, the mounting is provided with control terminal, the mounting intercommunication has the piece of admitting air and the piece of giving vent to anger, the upside rigid coupling of mounting has the burning jar, the burning jar is close to the one side rigid coupling of admitting air has the combustor, be provided with the temperature controller of being connected with control terminal electricity in the burning jar, the burning jar is provided with driving motor, driving motor's drive shaft rigid coupling has the dead lever, the rigid coupling has first fixed disk in the burning jar, the dead lever rigid coupling has the fan-shaped heat accumulation piece that circumference equidistance distributes, fan-shaped heat accumulation piece that circumference equidistance distributes all rotates with the burning jar to cooperate, fan-shaped heat accumulation piece is provided with the through-hole, the middle part intercommunication of fan-shaped heat accumulation piece has the coupling shell that the equidistance distributes, the bore of through-hole increases in proper order from the periphery to the centre of a circle, be used for with the abundant contact of burning jar spun flame, the mounting is provided with the air supplementing subassembly of supplementing gas in the burning jar, be provided with the clearance subassembly of fan-shaped heat accumulation piece in the fan-shaped heat accumulation piece, be provided with the guide assembly of extension gas and fan-shaped heat accumulation piece contact time in the fan-shaped heat accumulation piece, the control subassembly, the air flow guide assembly of control subassembly, the control subassembly of the control module of the circumference and the circumference of the air and the fan-shaped heat accumulation piece has, the control module, the control and the control module and the air and the control terminal all.

Further, a concentration monitoring module is arranged in the air outlet piece, a first fan-shaped air inlet cavity communicated with the air inlet piece is arranged on one side in the fixing piece, a first fan-shaped air outlet cavity communicated with the air outlet piece is arranged on the other side in the fixing piece, a first fan-shaped air inlet and a first fan-shaped air outlet are arranged on the first fixing plate, the first fan-shaped air inlet and the first fan-shaped air outlet are distributed in opposite directions, the first fan-shaped air inlet cavity is communicated with the first fan-shaped air inlet through adjacent through holes, and the first fan-shaped air outlet cavity is communicated with the first fan-shaped air outlet through adjacent through holes.

Further, the caliber of the first fan-shaped air inlet cavity is smaller than that of the first fan-shaped air outlet cavity, and the caliber of the first fan-shaped air inlet is smaller than that of the first fan-shaped air outlet.

Further, the air supplementing assembly comprises an air draft piece, the air draft piece is arranged on one side of the fixing piece, the fixing piece is provided with a second fan-shaped air inlet cavity, the second fan-shaped air inlet cavity is communicated with the air draft piece through a connecting pipe, the first fixing disc is provided with a second fan-shaped air outlet, the second fan-shaped air outlet is communicated with the second fan-shaped air inlet cavity through an adjacent through hole, and the air draft piece is electrically connected with the control terminal.

Further, the cleaning assembly comprises a first fan, the first fan is arranged at the top of the combustion tank, a second fan is fixedly connected to one side of the fixing piece, the fixing piece is provided with a second fan-shaped air outlet cavity, the second fan-shaped air outlet cavity is communicated with the second fan through a connecting pipe, the first fixing disc is provided with a second fan-shaped air inlet, and the first fan and the second fan are electrically connected with the control terminal.

Further, the second fan-shaped air inlet is communicated with the second fan-shaped air outlet cavity through the adjacent through holes, and the first fan is located above the second fan-shaped air inlet.

Further, a heat conducting plate is fixedly connected in the fixing piece and is provided with a vent hole, one side of the heat conducting plate is positioned in the first fan-shaped air inlet cavity, and the other side of the heat conducting plate is positioned in the first fan-shaped air outlet cavity.

Further, the flow guide assembly comprises equidistant and staggered rotating plates, the equidistant and staggered rotating plates are respectively connected in adjacent through holes in a rotating mode, a sliding rod is connected in the through holes in a sliding mode, fixed blocks are fixedly connected with the sliding rods in a fixed mode, and the fixed blocks are in sliding fit with the adjacent rotating plates.

Further, the control assembly comprises an electric push rod, the electric push rod is arranged on the upper side face of the fixing piece, a second fixing disc is fixedly connected to the telescopic end of the electric push rod, limiting columns distributed at equal intervals in the circumferential direction are fixedly connected to the second fixing disc, connecting frames are slidably connected to the limiting columns of the second fixing disc, springs are arranged on the limiting columns of the second fixing disc in a sleeved mode, the springs are located between the second fixing disc and the adjacent connecting frames, sliding shells fixedly connected to the adjacent connecting frames are slidably connected to the connecting shells, sliding columns fixedly connected to the sliding shells are slidably connected to the sliding columns, and the sliding columns in the sliding shells are fixedly connected to the adjacent sliding rods and electrically connected to the control terminal.

Further, a limiting pin is fixedly connected to one side, close to the second fixing disc, of the connecting frame, a fixing cylinder is fixedly connected to the upper side face of the fixing piece, a protruding block is fixedly connected to the upper side face of the fixing cylinder, and the protruding block of the fixing cylinder is located below the second fan-shaped air inlet cavity.

Compared with the prior art, the invention has the following advantages:

1. according to the invention, the aperture of the through hole is changed, so that the amount of organic waste gas discharged from the through hole on the left side of the sector-shaped heat storage block is reduced, the upward flowing speed of the organic waste gas is increased, and the amount of organic waste gas discharged from the through hole on the right side of the sector-shaped heat storage block is increased, so that the upward flowing speed of the organic waste gas is reduced, and the organic waste gas discharged from the through hole on the right side of the sector-shaped heat storage block is fully contacted with flame.

The organic waste gas discharged from the through hole is fully contacted with the flame.

2. The air is injected into the combustion tank through the air supplementing assembly, the air supplementing assembly and the air inlet piece are further enabled to convey air in an amount equal to the air amount discharged by the air outlet piece, and organic waste gas in adjacent through holes is blown into the combustion tank through the air supplementing assembly, so that the organic waste gas completely enters the combustion tank, the organic waste gas is prevented from being carried out by the through holes, and untreated organic waste gas is directly discharged.

3. The circulation time of gas flowing through the through hole is prolonged through the flow guide assembly, so that the contact time of the through hole and the fan-shaped heat storage block with the gas is increased, the heating time of the through hole and the fan-shaped heat storage block is further increased, and the gas is enabled to fully heat the through hole.

4. Organic waste gas and ash in the combustion tank and the through hole are cleaned through the cleaning component, so that the organic waste gas and ash in the combustion tank are discharged, and the phenomenon that residual organic waste gas in the combustion tank contacts with flame when the burner is ignited to cause deflagration and tempering in the combustion tank to damage the burner is avoided.

Drawings

Fig. 1 is a front view of a three-dimensional structure of the present invention.

Fig. 2 is a rear view of the three-dimensional structure of the present invention.

Fig. 3 is a perspective structural sectional view of the burn pot of the present invention.

Fig. 4 is a bottom view of the three-dimensional structure of the present invention.

Fig. 5 is a top view of a three-dimensional structure of the fastener of the present invention.

Fig. 6 is an exploded view of the three-dimensional structure of the sector heat storage block and other parts of the present invention.

Fig. 7 is a schematic perspective view of the heat conducting plate, the fixing member and other parts of the present invention.

Fig. 8 is a schematic perspective view of the second fixing plate, the power of the connecting frame and other parts.

Fig. 9 is a schematic perspective view of the connector frame, the sliding shell and other parts of the present invention.

Fig. 10 is a schematic perspective view of the rotating plate, the fixed block and other parts of the present invention.

Reference numerals: 101-supporting legs, 102-fixing pieces, 1021-air inlet pieces, 1022-air outlet pieces, 1023-first fan-shaped air inlet cavities, 1024-first fan-shaped air outlet cavities, 103-combustion cans, 104-combustors, 105-driving motors, 1051-fixing rods, 106-first fixing plates, 1061-first fan-shaped air inlets, 1062-first fan-shaped air outlets, 107-fan-shaped heat storage blocks, 1071-through holes, 1072-connecting shells, 201-air suction pieces, 202-second fan-shaped air inlet cavities, 203-second fan-shaped air outlets, 301-first fans, 302-second fans, 303-second fan-shaped air outlet cavities, 304-second fan-shaped air inlets, 4-heat conducting plates, 501-rotating plates, 502-sliding rods, 503-fixing blocks, 601-electric push rods, 602-second fixing plates, 603-connecting frames, 604-sliding shells, 605-limiting pins and 606-fixing drums.

Description of the embodiments

Although the invention may be described with respect to a particular application or industry, those skilled in the art will recognize the broader applicability of the invention. Those of ordinary skill in the art will recognize such things as: terms such as above, below, upward, downward, etc. are used for describing the drawings, and do not represent limitations upon the scope of the present invention defined by the appended claims. Such as: any numerical designation of the first or second, etc. is merely exemplary and is not intended to limit the scope of the present invention in any way.

Example 1: the explosion-proof temperature control type heat accumulating incinerator, as shown in fig. 1-6, comprises a supporting leg 101, the supporting leg 101 is fixedly connected with a fixing piece 102, the fixing piece 102 is provided with a control terminal, the left side of the fixing piece 102 is provided with an air inlet piece 1021, the air inlet piece 1021 is composed of an air inlet pipe and an exhaust fan, the right side of the fixing piece 102 is provided with an air outlet piece 1022, the air outlet piece 1022 is composed of an air outlet pipe and an exhaust fan, the air inlet piece 1021 and the air outlet piece 1022 are respectively provided with a one-way valve, the air outlet piece 1022 is internally provided with a concentration monitoring module, the concentration monitoring module is used for monitoring the concentration of the air discharged by the air outlet piece 1022, the upper side of the fixing piece 102 is fixedly connected with a combustion tank 103, the air circulation is formed in the combustion tank 103 through the cooperation of the exhaust fan in the air inlet piece 1021 and the exhaust fan in the air outlet piece 1022, the left side of the combustion tank 103 is fixedly connected with a burner 104, the combustion tank 103 is internally provided with a temperature controller for monitoring the temperature in the combustion tank 103, the top of the combustion tank 103 is provided with a driving motor 105, a driving shaft of the driving motor 105 is fixedly connected with a fixing rod 1051, the combustion tank 103 is internally fixedly connected with a first fixing disc 106, the fixing rod 1051 is fixedly connected with fan-shaped heat accumulating blocks 107 distributed circumferentially at equal intervals, the fan-shaped heat accumulating blocks 107 are made of ceramic materials with high heat absorption degree, the heat of gas in the combustion tank 103 is absorbed by the fan-shaped heat accumulating blocks 107 to preheat the subsequent organic waste gas, the fan-shaped heat accumulating blocks 107 distributed circumferentially at equal intervals are in rotary fit with the combustion tank 103, the fan-shaped heat accumulating blocks 107 are provided with through holes 1071, the middle parts of the fan-shaped heat accumulating blocks 107 are fixedly connected and communicated with a connecting shell 1072, the caliber of the through holes 1071 is sequentially increased from the periphery of the fan-shaped heat accumulating blocks 107 to the circle center and is used for being fully contacted with flame sprayed out by the combustion tank 103, the flame is enabled to fully burn the organic waste gas, the fixing piece 102 is provided with a gas supplementing component, the amount of the gas supplied by the gas supplying component and the gas inlet component 1021 is equal to the amount of the gas discharged by the gas outlet component 1022, the gas supplying component is used for supplying gas into the combustion tank 103, and cleaning organic waste gas remained in the fan-shaped heat storage block 107 is carried out in the process of supplying gas, a cleaning component is arranged in the combustion tank 103 and is used for cleaning residues in the fan-shaped heat storage block 107, a flow guiding component is arranged in the fan-shaped heat storage block 107 and is used for prolonging the contact time between the gas and the fan-shaped heat storage block 107, a control component for controlling the flow guiding component is arranged on the fixing component 102, and the gas inlet component 1021, the gas outlet component 1022, the concentration monitoring module, the temperature controller, the combustor 104, the driving motor 105, the gas supplying component, the cleaning component and the control component are all electrically connected with a control terminal.

As shown in fig. 3-5, a first fan-shaped air inlet cavity 1023 is disposed on the left side of the fixing member 102, the first fan-shaped air inlet cavity 1023 is communicated with the air inlet member 1021, a first fan-shaped air outlet cavity 1024 is disposed on the right side of the fixing member 102, the first fan-shaped air outlet cavity 1024 is communicated with the air outlet member 1022, a first fan-shaped air inlet 1061 is disposed on the left side of the first fixing plate 106, a first fan-shaped air outlet 1062 distributed opposite to the first fan-shaped air inlet 1061 is disposed on the right side of the first fixing plate 106, the first fan-shaped air inlet cavity 1023 is communicated with the first fan-shaped air inlet 1061 through adjacent through holes 1071, the first fan-shaped air outlet cavity 1024 is communicated with the first fan-shaped air outlet 1062 through adjacent through holes 1071, the caliber of the first fan-shaped air inlet cavity 1023 is smaller than the caliber of the first fan-shaped air outlet cavity 1024, and the caliber of the first fan-shaped air inlet 1061 is smaller than the caliber of the first fan-shaped air outlet 1062.

Before the organic waste gas is treated, the control terminal controls the cleaning component to clean residual organic waste gas and ash in the combustion tank 103 so as to ensure the safety of the burner 104 during ignition, and after the cleaning is finished, the cleaning component is closed through the control terminal.

After the cleaning of the combustion tank 103 is completed, the burner 104 is started through the control terminal, flame is sprayed to the upper part in the combustion tank 103 by the burner 104, then the exhaust fan in the air inlet piece 1021, the exhaust fan in the air outlet piece 1022 and the driving motor 105 are started through the control terminal, and the fan-shaped heat storage block 107 and parts on the fan-shaped heat storage block are driven to rotate through the driving motor 105.

When organic waste gas is treated, an exhaust fan in the air inlet member 1021 pumps the organic waste gas into the first fan-shaped air inlet cavity 1023 on the left side of the fixing member 102, the fixing member 102 conveys the organic waste gas to the left side of the upper part in the combustion tank 103 through the adjacent through holes 1071, an exhaust fan in the air outlet member 1022 pumps the organic waste gas into the first fan-shaped air outlet cavity 1024 on the right side of the fixing member 102, the air is conveyed into the right side of the fixing member 102 through the right adjacent through holes 1071, and finally the air is discharged through the air outlet member 1022, so that the air circulation is formed in the combustion tank 103, and in the process of treating the organic waste gas, the check valves in the air inlet member 1021 and the air outlet member 1022 are in an open state.

The organic waste gas enters the combustion tank 103 through the left through hole 1071 and the left first fan-shaped air inlet 1061, the organic waste gas entering the combustion tank 103 contacts with flame sprayed by the burner 104, the flame burns the organic waste gas, so that the organic waste gas is decomposed into oxide and water, and the water is influenced by high temperature in the combustion tank 103 to form water vapor.

In the process of burning the organic waste gas, the amount of the organic waste gas discharged from the left through hole 1071 of the sector-shaped heat storage block 107 is reduced through the difference of the apertures of the through holes 1071, so that the upward flowing speed of the organic waste gas is increased, the amount of the organic waste gas discharged from the right through hole 1071 of the sector-shaped heat storage block 107 is increased, the upward flowing speed of the organic waste gas is reduced, the organic waste gas discharged from the right through hole 1071 of the sector-shaped heat storage block 107 is fully contacted with flame, and the flame fully burns the organic waste gas discharged from the right through hole 1071 of the sector-shaped heat storage block 107.

The organic waste gas with a higher left flow velocity flows downward in a turned-back manner under the action of the air outlet 1022, and the organic waste gas flowing downward is contacted with the flame sprayed from the burner 104 again, and the flame sprayed from the burner 104 burns the organic waste gas again, so that all the organic waste gas discharged from the through holes 1071 of the fan-shaped heat storage block 107 is burnt.

In the process of air circulation in the combustion tank 103, air is input into the combustion tank 103 through the air supplementing assembly, the amount of air conveyed by the air supplementing assembly and the air inlet member 1021 is equal to the amount of air discharged by the air outlet member 1022, in the process of air input into the combustion tank 103 through the air supplementing assembly, organic waste gas in adjacent through holes 1071 is blown into the combustion tank 103, and the organic waste gas in the through holes 1071 is prevented from being brought to the right side in the rotating process of the fan-shaped heat storage block 107 and is directly pumped out by the air outlet member 1022 on the right side.

The waste gas after incineration treatment flows downwards under the action of the gas in the combustion tank 103 extracted by the gas outlet 1022, the high-temperature gas flowing downwards is conveyed into the first fan-shaped gas outlet cavity 1024 through the through hole 1071 and finally is discharged by the gas outlet 1022, and the high-temperature gas flows through the through hole 1071 to heat the through hole 1071 and the fan-shaped heat storage block 107 in the process of flowing through the through hole 1071, so that when the fan-shaped heat storage block 107 rotates to the left side, the organic waste gas flowing through the left side is preheated, and the incineration time of the organic waste gas is further shortened.

In the process of treating the organic waste gas, the control component controls the flow guiding component to prolong the circulation time of the organic waste gas passing through the through hole 1071, so that the contact time between the through hole 1071 and the fan-shaped heat storage block 107 and the gas is increased, and the gas is enabled to fully heat the through hole 1071.

In the process of exhausting the gas from the gas outlet member 1022, the concentration of the gas is monitored by the concentration monitoring module in the gas outlet member 1022, so that a worker can timely master the concentration of the gas, when the organic waste gas is not burnt continuously, the terminal is controlled to be closed, the exhaust fan in the gas inlet member 1021, the exhaust fan in the gas outlet member 1022, the burner 104 and the driving motor 105 are controlled, and when the organic waste gas is not treated any more, the check valves in the gas inlet member 1021 and the gas outlet member 1022 are all in a closed state.

Example 2: on the basis of embodiment 1, as shown in fig. 2 and fig. 4-6, the air supplementing assembly comprises an air extracting member 201, the air extracting member 201 is arranged at the rear side of the fixing member 102, a second fan-shaped air inlet cavity 202 is arranged at the rear part of the fixing member 102, the second fan-shaped air inlet cavity 202 is communicated with the air extracting member 201 through a connecting pipe, the first fixing disc 106 is provided with a second fan-shaped air outlet 203, the second fan-shaped air outlet 203 is communicated with the second fan-shaped air inlet cavity 202 through an adjacent through hole 1071, air is injected into the combustion tank 103 through the air extracting member 201, the air supplementing assembly and the air inlet member 1021 deliver the air with the same amount as the air exhausted by the air outlet member 1022, and the air extracting member 201 blows the organic waste gas in the adjacent through hole 1071 into the combustion tank 103 in the process of injecting the air into the combustion tank 103, so that the organic waste gas completely enters the combustion tank 103, and the air extracting member 201 is electrically connected with a control terminal.

As shown in fig. 1 and fig. 3-6, the cleaning assembly comprises a first fan 301, the first fan 301 is disposed at the top of the front side of the combustion tank 103, a second fan 302 is fixedly connected to the front side of the fixing member 102, check valves are disposed in the first fan 301 and the second fan 302, the fixing member 102 is provided with a second fan-shaped air outlet cavity 303, the second fan-shaped air outlet cavity 303 is communicated with the second fan 302 through a connecting pipe, the first fixing plate 106 is provided with a second fan-shaped air inlet 304, the second fan-shaped air inlet 304 is communicated with the second fan-shaped air outlet cavity 303 through adjacent through holes 1071, the first fan 301 is located above the second fan-shaped air inlet 304, air circulation is formed in the combustion tank 103 through cooperation of the first fan 301 and the second fan 302, residual organic waste gas and ash residues in the combustion tank 103 and the heat storage block 107 are cleaned through wind blown out by the first fan 301, and the second fan 302 are electrically connected with the control terminal.

As shown in fig. 5 and 7, the middle part in the fixing piece 102 is fixedly connected with a heat conducting plate 4, the left side and the right side of the heat conducting plate 4 are respectively provided with a vent hole, the left side of the heat conducting plate 4 is positioned in the first fan-shaped air inlet cavity 1023, the right side of the heat conducting plate 4 is positioned in the first fan-shaped air outlet cavity 1024, and the heat conducting plate 4 on the right side is preheated through high-temperature gas, so that the heat conducting plate 4 conducts the inlet heat to the left side and heats the left organic waste gas.

As shown in fig. 8 and 10, the diversion component comprises a rotating plate 501, the rotating plate 501 is rotationally connected in an adjacent through hole 1071, the rotating plate 501 is equidistantly and misplaced in the adjacent through hole 1071, a sliding rod 502 is slidably connected in the through hole 1071, a fixed block 503 is fixedly connected to the sliding rod 502 and is distributed at equal intervals, the fixed block 503 is slidably matched with the adjacent rotating plate 501, the adjacent rotating plate 501 is driven to swing through the sliding rod 502 and the fixed block 503, the rotating plate 501 shields a part of the through hole 1071, the flow area of the through hole 1071 is reduced, the contact time between the through hole 1071 and the fan-shaped heat storage block 107 and the gas is increased, and the heating time of the through hole 1071 and the fan-shaped heat storage block 107 is further increased.

As shown in fig. 5 and 7, the control assembly includes an electric push rod 601, the electric push rod 601 is disposed on the upper side of the fixing member 102, a second fixing plate 602 is fixedly connected to the telescopic end of the electric push rod 601, a limit post circumferentially and equidistantly distributed is fixedly connected to the second fixing plate 602, a connecting frame 603 is fixedly connected to the limit post of the second fixing plate 602, a limit pin 605 is fixedly connected to one side of the connecting frame 603, which is close to the second fixing plate 602, of the second fixing plate 602, springs are disposed between the second fixing plate 602 and the adjacent connecting frame 603, the number of the connecting frames 603 is consistent with that of the fan-shaped heat storage blocks 107, the inner diameter of the connecting shell 1072 is sequentially increased from the position close to the center of the fan-shaped heat storage blocks 107 to the position far from the center of the fan-shaped heat storage blocks 107, a sliding shell 604 is slidingly connected to the connecting shell 1072, the sliding shell 604 is fixedly connected to the adjacent connecting frame 603, the sliding post in the sliding shell 1072 is fixedly connected to the sliding shell 604, the sliding post in the sliding shell 604 is fixedly connected to the adjacent sliding rod 502, a limit pin 605 is fixedly connected to one side of the connecting frame 603, the upper side of the fixing member 102 is fixedly connected to the upper side of the fixing cylinder 606, the upper side of the fixing cylinder 606 is fixedly connected to the fan-shaped heat storage blocks 606 is provided with a boss 606, and the electric exhaust gas flowing through the fan-shaped cylinder 1071 is in a direction of the largest through the fan-shaped air inlet end of the fan-shaped heat storage block 201, and the fan-shaped heat storage block is arranged at the end of the fan-shaped heat storage device is a through the largest through the fan-shaped air inlet opening, and the air inlet space is formed in the air inlet space, and the air flow space is the air flow control device.

Before organic waste gas is treated, drive motor 105 is started through the control terminal, drive fan-shaped heat accumulation piece 107 and upper part thereof through drive motor 105 and rotate, then start first fan 301 and second fan 302 through the control terminal, carry outside air to the combustion tank 103 in first fan 301, the gas in the combustion tank 103 is drawn to cooperation second fan 302, form the air cycle in the messenger combustion tank 103, in the course of operation of first fan 301 and second fan 302, check valves in first fan 301 and the second fan 302 are the open condition, blow down gas and the outside air in the combustion tank 103 through first fan 301, outside air gets into adjacent through-hole 1071 by the second fan-shaped air inlet 304 of first fixed disk 106 front side, cooperation fan-shaped heat accumulation piece 107 and through-hole 1071's rotation, blow the organic waste gas in the adjacent through-hole 1071 to the below, when outside air flows in the adjacent through-hole 1071, with the residual blowing down side in the through-hole 1071, take place ash and slag by second fan 302, thereby to take out organic waste gas and ash, when to heat accumulation piece 107, in the combustion tank 103 and the second fan 302 carry out the combustion tank 104, when guaranteeing that the combustion tank 103 and the fire-back combustion engine 104 are closed, and the fire protection device 301 is closed, and the fire protection device is closed, and the combustion engine is closed to the combustion tank 301 is carried out to the combustion engine is in the combustion engine is closed to the second fan 301 when the end-down, and the combustion engine is closed to the end-down, and is closed to the combustion valve is guaranteed to the combustion engine 301, and is closed to the combustion engine is in the combustion engine and is closed and the combustion device is in the end and is closed to the combustion end of the combustion device 104.

In the process of burning the organic waste gas, the air suction member 201 is started through the control terminal, the air suction member 201 conveys external gas into the second fan-shaped air inlet cavity 202, the second fan-shaped air inlet cavity 202 conveys the gas upwards through the adjacent through holes 1071, the upwards conveyed gas is discharged from the second fan-shaped air outlet 203, and the organic waste gas in the air flow through the adjacent through holes 1071 is conveyed upwards, so that the organic waste gas completely enters the combustion tank 103.

In the process of burning the organic waste gas, the air outlet 1022 extracts the high-temperature air in the combustion tank 103, heats the right side of the heat conducting plate 4 when the high-temperature air flows through the right side of the heat conducting plate 4, and conducts heat to the left side of the heat conducting plate 4 through heat conduction of the heat conducting plate 4 itself, thereby preheating the organic waste gas flowing through the left side of the heat conducting plate 4, and further shortening the burning time of the organic waste gas.

In the process of burning the organic waste gas, the control terminal controls the electric push rod 601 to downwards pull the second fixed disc 602, the surrounding connecting frame 603, the sliding shell 604 and the limiting pin 605, the sliding shell 604 downwards moves to downwards pull the adjacent sliding rod 502 and the fixed block 503 through the sliding column in the sliding shell, the adjacent rotating plate 501 is driven to swing through the movement of the fixed block 503, the rotating plate 501 shields a part of the area of the through hole 1071 when rotating to 90 degrees, so that the flow area of the through hole 1071 is reduced, the flow time of gas flowing through the through hole 1071 is prolonged, the contact time of the through hole 1071 and the fan-shaped heat storage block 107 with the gas is prolonged, and the heating time of the through hole 1071 and the fan-shaped heat storage block 107 is further prolonged.

When the second fixed disc 602 and the upper part thereof rotate until the limit pin 605 contacts with the lug of the fixed cylinder 606, the lug of the fixed cylinder 606 extrudes the limit pin 605 and the sliding shell 604 and the upper part thereof, so that the limit pin 605 and the sliding shell 604 and the upper part thereof move upwards, and compress the adjacent springs, and in the process of moving the sliding shell 604 upwards, the adjacent sliding rod 502 and the fixed block 503 move upwards, and the fixed block 503 moves upwards to drive the adjacent rotating plate 501 to swing and reset, thereby increasing the flow area of the through holes 107 and further increasing the flow quantity of the organic waste gas flowing through the through holes 107.

When the through hole 1071 is at the maximum flow rate, the second fan-shaped air inlet cavity 202 and the second fan-shaped air outlet 203 are both communicated with the adjacent through holes 1071, so that the through holes 1071 are located in the areas of the adjacent second fan-shaped air inlet cavity 202 and the second fan-shaped air outlet 203, the flow area of the through holes 107 is increased, the flow rate of the organic waste gas flowing through the through holes 107 is increased, and under the effect of the maximum flow rate of the through holes 1071, the air draft piece 201 blows the organic waste gas in the through holes 1071 into the combustion tank 103, so that the cleaning time of the adjacent through holes 1071 is reduced.

When the organic waste gas is no longer treated, the air suction member 201 is closed by the control terminal.

The foregoing is merely illustrative of the present invention, and the present invention is not limited thereto, and any person skilled in the art will readily recognize that variations or substitutions are within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (3)

1. An explosion-proof control by temperature change formula heat accumulation formula burns burning furnace, its characterized in that: comprises a supporting leg (101), wherein the supporting leg (101) is fixedly connected with a fixing piece (102), the fixing piece (102) is provided with a control terminal, the fixing piece (102) is communicated with an air inlet piece (1021) and an air outlet piece (1022), the upper side of the fixing piece (102) is fixedly connected with a combustion tank (103), one side of the combustion tank (103) close to the air inlet piece (1021) is fixedly connected with a combustor (104), a temperature controller electrically connected with the control terminal is arranged in the combustion tank (103), the combustion tank (103) is provided with a driving motor (105), a driving shaft of the driving motor (105) is fixedly connected with a fixing rod (1051), a first fixing disc (106) is fixedly connected in the combustion tank (103), the fixed rod (1051) is fixedly connected with sector heat storage blocks (107) which are distributed circumferentially and equidistantly, the sector heat storage blocks (107) which are distributed circumferentially and equidistantly are in running fit with the combustion tank (103), the sector heat storage blocks (107) are provided with through holes (1071), connecting shells (1072) which are distributed equidistantly are communicated with the middle part of the sector heat storage blocks (107), the caliber of each through hole (1071) is sequentially increased from the periphery of each sector heat storage block (107) to the circle center and is used for being fully contacted with flame sprayed out of the combustion tank (103), the fixed piece (102) is provided with an air supplementing component for supplementing air into the combustion tank (103), the combustion tank (103) is internally provided with a cleaning component for cleaning the sector heat storage blocks (107), the fan-shaped heat storage block (107) is internally provided with a flow guide assembly for prolonging the contact time of gas and the fan-shaped heat storage block (107), the fixing piece (102) is provided with a control assembly for controlling the flow guide assembly, and the air inlet piece (1021), the air outlet piece (1022), the concentration monitoring module, the burner (104), the driving motor (105), the air supplementing assembly, the cleaning assembly and the control assembly are all electrically connected with the control terminal;

a concentration monitoring module is arranged in the air outlet piece (1022), a first fan-shaped air inlet cavity (1023) communicated with the air inlet piece (1021) is arranged on one side in the fixing piece (102), a first fan-shaped air outlet cavity (1024) communicated with the air outlet piece (1022) is arranged on the other side in the fixing piece (102), a first fan-shaped air inlet (1061) and a first fan-shaped air outlet (1062) are arranged on the first fixing disc (106), the first fan-shaped air inlet (1061) and the first fan-shaped air outlet (1062) are distributed in opposite directions, the first fan-shaped air inlet cavity (1023) is communicated with the first fan-shaped air inlet (1061) through adjacent through holes (1071), and the first fan-shaped air outlet cavity (1024) is communicated with the first fan-shaped air outlet (1062) through adjacent through holes (1071).

The caliber of the first fan-shaped air inlet cavity (1023) is smaller than that of the first fan-shaped air outlet cavity (1024), and the caliber of the first fan-shaped air inlet (1061) is smaller than that of the first fan-shaped air outlet (1062);

a heat conducting plate (4) is fixedly connected in the fixing piece (102), the heat conducting plate (4) is provided with a vent hole, one side of the heat conducting plate (4) is positioned in the first fan-shaped air inlet cavity (1023), and the other side of the heat conducting plate (4) is positioned in the first fan-shaped air outlet cavity (1024); the flow guide assembly comprises equidistant and staggered rotating plates (501), the equidistant and staggered rotating plates (501) are respectively connected in adjacent through holes (1071) in a rotating mode, sliding rods (502) are connected in the through holes (1071) in a sliding mode, fixed blocks (503) which are distributed at equal intervals are fixedly connected with the sliding rods (502), and the fixed blocks (503) are in sliding fit with the adjacent rotating plates (501);

the control assembly comprises an electric push rod (601), the electric push rod (601) is arranged on the upper side face of a fixing piece (102), a second fixing disc (602) is fixedly connected to the telescopic end of the electric push rod (601), limit columns distributed at equal intervals in the circumferential direction are fixedly connected to the second fixing disc (602), connecting frames (603) are connected to the limit columns of the second fixing disc (602) in a sliding mode, springs are sleeved on the limit columns of the second fixing disc (602) and located between the second fixing disc (602) and the adjacent connecting frames (603), sliding shells (604) fixedly connected to the adjacent connecting frames (603) are connected to the connecting shells (1072) in a sliding mode, sliding columns fixedly connected to the sliding shells (604) are fixedly connected to the adjacent sliding rods (502), and the electric push rod (601) is electrically connected to the control terminal;

one side of the connecting frame (603) close to the second fixed disc (602) is fixedly connected with a limiting pin (605), the upper side surface of the fixing piece (102) is fixedly connected with a fixing cylinder (606), the upper side surface of the fixing cylinder (606) is fixedly connected with a protruding block, and the protruding block of the fixing cylinder (606) is positioned below the second fan-shaped air inlet cavity (202).

2. The explosion-proof temperature-controlled heat accumulating type incinerator according to claim 1, wherein: the air supplementing assembly comprises an air draft member (201), the air draft member (201) is arranged on one side of the fixing member (102), the fixing member (102) is provided with a second fan-shaped air inlet cavity (202), the second fan-shaped air inlet cavity (202) is communicated with the air draft member (201) through a connecting pipe, the first fixing disc (106) is provided with a second fan-shaped air outlet (203), the second fan-shaped air outlet (203) is communicated with the second fan-shaped air inlet cavity (202) through an adjacent through hole (1071), and the air draft member (201) is electrically connected with the control terminal.

3. The explosion-proof temperature-controlled heat accumulating type incinerator according to claim 1, wherein: the cleaning assembly comprises a first fan (301), the first fan (301) is arranged at the top of the combustion tank (103), a second fan (302) is fixedly connected to one side of the fixing piece (102), the fixing piece (102) is provided with a second fan-shaped air outlet cavity (303), the second fan-shaped air outlet cavity (303) is communicated with the second fan (302) through a connecting pipe, the first fixing disc (106) is provided with a second fan-shaped air inlet (304), and the first fan (301) and the second fan (302) are electrically connected with the control terminal;

the second fan-shaped air inlet (304) is communicated with the second fan-shaped air outlet cavity (303) through adjacent through holes (1071), and the first fan (301) is located above the second fan-shaped air inlet (304).