CN214299991U - Energy-saving organic matter thermal decomposition equipment - Google Patents

Abstract

The utility model discloses an energy-saving organic matter pyrolysis equipment, include: a thermal decomposition device; the double-layer transmission heat exchange box structurally comprises a lower-layer heat exchange chamber and an upper-layer heat exchange chamber communicated with the lower-layer heat exchange chamber, wherein a low-temperature material transmission device is arranged in the upper-layer heat exchange chamber, and a high-temperature material transmission device is arranged in the lower-layer heat exchange chamber; a low-temperature material inlet is formed in one side of the upper-layer heat exchange chamber, a low-temperature material outlet is formed in the other side of the upper-layer heat exchange chamber, and the low-temperature material outlet is connected with a feeding hole of thermal decomposition equipment; a high-temperature material inlet is formed in one side of the lower-layer heat exchange chamber, a tailings outlet is formed in the other side of the lower-layer heat exchange chamber, and the high-temperature material inlet is connected with a slag outlet of the thermal decomposition equipment; the upper heat exchange chamber is also provided with an oil-gas outlet which is connected with an oil-gas collecting and separating system. The utility model provides a pyrolysis material can low temperature exhaust problem, utilize the heat energy of pyrolysis material again, practiced thrift the energy.

Description

Energy-saving organic matter thermal decomposition equipment

Technical Field

The utility model belongs to the technical field of waste gas organic matter pyrolysis equipment, more specifically say, the utility model relates to an energy-saving organic matter pyrolysis equipment.

Background

When carrying out thermal decomposition to fatlute, oil sand, viscous crude, domestic waste, domestic sludge, agriculture and forestry abandonment organic matter, the pyrolysis device is all from low temperature heating to high temperature with the material, discharges the surplus material under still being in the high temperature condition again, and when the surplus material was discharged at high temperature, not only unsafe, the waste of the energy was caused to the loss heat energy in addition. People have to adopt a method of arranging a region for reducing the temperature of residual materials in a pyrolysis region or increasing the length of equipment to solve the problems, but the method is limited by the spatial position of the area of an equipment installation region, and is limited particularly in the aspects of installing pyrolysis skid-mounted equipment, vehicle-mounted pyrolysis equipment and the like on a drilling platform.

Therefore, there is a need for a pyrolysis apparatus capable of solving the problem of low-temperature discharge of the remaining high-temperature material while avoiding waste of heat of the remaining high-temperature material.

SUMMERY OF THE UTILITY MODEL

An object of the present invention is to solve at least the above problems and/or disadvantages and to provide at least the advantages which will be described later.

To achieve these objects and other advantages in accordance with the present invention, there is provided an energy-saving organic matter thermal decomposition apparatus, comprising:

a thermal decomposition device;

the double-layer transmission heat exchange box structurally comprises a lower-layer heat exchange chamber and an upper-layer heat exchange chamber communicated with the lower-layer heat exchange chamber, wherein a low-temperature material transmission device is arranged in the upper-layer heat exchange chamber, and a high-temperature material transmission device is arranged in the lower-layer heat exchange chamber; a low-temperature material inlet is formed in one side of the upper-layer heat exchange chamber, a low-temperature material outlet is formed in the other side of the upper-layer heat exchange chamber, and the low-temperature material outlet is connected with a feeding hole of thermal decomposition equipment; a high-temperature material inlet is formed in one side of the lower-layer heat exchange chamber, a tailings outlet is formed in the other side of the lower-layer heat exchange chamber, and the high-temperature material inlet is connected with a slag outlet of the thermal decomposition equipment;

the upper heat exchange chamber is also provided with an oil-gas outlet which is connected with an oil-gas collecting and separating system.

Preferably, wherein the thermal decomposition apparatus has a structure including:

the thermal decomposition furnace is provided with a slag outlet and a feed inlet, the slag outlet is connected with a high-temperature material inlet of the double-layer transmission heat exchange box, and the feed inlet is connected with a low-temperature material outlet;

the heating bin is arranged at the bottom of the thermal decomposition furnace, and a plurality of groups of burners are fixedly arranged in the heating bin;

the multi-layer transmission chain belts are arranged inside the thermal decomposition furnace in a staggered mode, each group of transmission chain belts are connected with driving wheels, one end of the transmission chain belt on the uppermost layer is located below the feeding hole, and one end of the transmission chain belt on the lowermost layer is close to the slag hole; and the driving motor is arranged outside the thermal decomposition furnace, and a motor shaft of the driving motor extends into the thermal decomposition furnace and is fixedly connected with the driving wheel.

Preferably, a screw conveyer is connected between the feeding port of the thermal decomposition equipment and the low-temperature material outlet of the double-layer transmission heat exchange box, and the screw conveyer structurally comprises:

the device comprises a device shell, a double-layer transmission heat exchange box and a thermal decomposition device, wherein a feeding port and a discharging port are arranged on the device shell, the feeding port is connected with a low-temperature material outlet of the double-layer transmission heat exchange box, and the discharging port is connected with a feeding hole of the thermal decomposition device;

and the driving screw is rotatably installed in the device shell, one end of the driving screw is close to the discharge port of the device shell, and the other end of the driving screw is connected with a motor.

Preferably, the device shell is externally provided with a heat insulation layer.

Preferably, the structure of the oil-gas collecting and separating system comprises:

the condenser is connected with the oil gas outlet through a pipeline, the condenser is also connected with a transfer tank through a pipeline, and the transfer tank is provided with a water-oil outlet and a gas outlet;

a plurality of baffle plates which are arranged in a staggered mode are arranged in the transfer tank, and a filter screen is arranged above the baffle plates.

Preferably, the structure of the transfer tank comprises a lower tank body and an upper tank body, the upper tank body is hinged with the lower tank body, an annular sealing groove is formed in the lower tank body, and an annular sealing ring is arranged in the annular sealing groove;

go up jar body and lower jar of body junction and all be provided with flange seal spare, go up jar body and the flange seal spare of lower jar of body and realize fixed connection through the bolt.

Preferably, wherein, be provided with round spacing layer in the lower tank body, the filter screen is circular filter screen, and the filter screen external fixation has the collar, spacing layer and collar pass through bolt fastening and meet.

Preferably, wherein the double-layer transmission heat exchange box may be one of square, round and oval; the high-temperature material transmission device and the high-temperature material transmission device are conveying chain belts.

Preferably, the thermal decomposition equipment is a thermal decomposition furnace for spiral feeding, a feeding port and a slag outlet are arranged on the thermal decomposition furnace, a conveying screw rod is arranged in the thermal decomposition furnace in a rotating manner, the conveying screw rod is connected with a feeding motor, and the feeding motor is positioned outside the thermal decomposition furnace.

Preferably, wherein the thermal decomposition apparatus has a structure including:

the thermal decomposition furnace is provided with a feed inlet and a slag outlet, and a plurality of layers of staggered transmission chain belts are arranged inside the thermal decomposition furnace;

and the heat insulation layer is arranged outside the thermal decomposition furnace, and electric heating pipes which are spirally arranged are arranged between the heat insulation layer and the thermal decomposition furnace.

The utility model discloses at least, include following beneficial effect: the utility model discloses an increase a double-deck transmission heat exchange case by thermal decomposition equipment, lower floor's heat transfer chamber in the double-deck transmission heat exchange case is used for transmitting by thermal decomposition equipment exhaust surplus high temperature material, and upper heat transfer chamber is used for transmitting the low temperature raw material of treating the decomposition, and surplus high temperature material can further cool down the back and discharge, still can utilize high temperature material to preheat low temperature raw material simultaneously, and the heat energy of make full use of surplus high temperature material has solved surplus high temperature material low temperature exhaust problem.

Additional advantages, objects, and features of the invention will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the invention.

Description of the drawings:

FIG. 1 is a schematic structural view of an energy-saving organic thermal decomposition apparatus provided by the present invention;

FIG. 2 is an enlarged view taken at A in FIG. 1;

FIG. 3 is a schematic structural view of the dual-layer heat exchange box for conveying the original low-temperature material and the residual high-temperature material in the same direction;

FIG. 4 is a schematic top view of the double-layer transmission heat exchange box and the pyrolysis furnace of the present invention in a back-to-back connection manner;

FIG. 5 is a schematic structural view of the thermal decomposition furnace according to the present invention, which is heated by an electric heating tube;

FIG. 6 is a schematic structural view of the thermal decomposition furnace according to the present invention using spiral feeding;

FIG. 7 is a schematic view of the internal structure of a spiral-fed thermal decomposition furnace.

The specific implementation mode is as follows:

the present invention is further described in detail below with reference to the drawings so that those skilled in the art can implement the invention with reference to the description.

It will be understood that terms such as "having," "including," and "comprising," as used herein, do not preclude the presence or addition of one or more other elements or groups thereof.

It should be noted that in the description of the present invention, the terms indicating the orientation or the positional relationship are based on the orientation or the positional relationship shown in the drawings, and are only for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the indicated device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "sleeved/connected," "connected," and the like are to be construed broadly, such as "connected," which may be a fixed connection, a detachable connection, or an integral connection, a mechanical connection, an electrical connection, a direct connection, an indirect connection via an intermediate medium, or a connection between two elements, and those skilled in the art will understand the specific meaning of the terms in the present invention in a specific context.

Furthermore, in the present disclosure, unless explicitly stated or limited otherwise, a first feature may be "on" or "under" a second feature in direct contact with the first and second features, or in indirect contact with the first and second features through an intermediate. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

As shown in fig. 1-7: the utility model discloses an energy-saving organic matter pyrolysis equipment, include:

a thermal decomposition device;

the double-layer transmission heat exchange box 2 structurally comprises a lower-layer heat exchange chamber 3 and an upper-layer heat exchange chamber 4 positioned above the lower-layer heat exchange chamber 3, wherein a low-temperature material transmission device 41 is arranged in the upper-layer heat exchange chamber 4, and a high-temperature material transmission device 31 is arranged in the lower-layer heat exchange chamber 3; a low-temperature material inlet 42 is formed in one side of the upper-layer heat exchange chamber 4, a low-temperature material outlet 43 is formed in the other side of the upper-layer heat exchange chamber, and the low-temperature material outlet 43 is connected with a feeding hole of the thermal decomposition equipment 1; a high-temperature material inlet 32 is formed in one side of the lower-layer heat exchange chamber 3, a tailings outlet 33 is formed in the other side of the lower-layer heat exchange chamber, and the high-temperature material inlet 32 is connected with a slag outlet of the thermal decomposition equipment 1;

the upper layer heat exchange chamber 4 is also provided with an oil gas outlet 44, and the oil gas outlet 44 is connected with an oil gas collecting and separating system.

The working principle is as follows: discharging the residual high-temperature materials discharged from the pyrolysis equipment 1 into the lower-layer heat exchange chamber 3 of the double-layer transmission heat exchange box 2 through the high-temperature material inlet 32, and transmitting the high-temperature materials to the tailings outlet 33 from the high-temperature material inlet 32 by the high-temperature material transmission device 31; meanwhile, the original low-temperature material to be preheated is loaded into the upper-layer heat exchange chamber 4 from the low-temperature material inlet 42, and the low-temperature material conveying device 41 conveys the original low-temperature material from the low-temperature material inlet 42 to the low-temperature material outlet 43; in the process that the residual high-temperature materials and the original low-temperature materials are conveyed and transmitted, the heat of the residual high-temperature materials effectively preheats the original low-temperature materials, the temperature of the residual high-temperature materials is also obviously reduced, and the preheated original low-temperature materials enter the thermal decomposition equipment 1 from the feeding hole, so that the material decomposition efficiency of the thermal decomposition equipment is improved. Therefore the utility model discloses a set up double-deck transmission heat exchange box 2 by pyrolysis equipment 1, not only solved the low temperature discharge problem of surplus high temperature material, but also reasonable make full use of the heat energy in the surplus high temperature material, avoided the waste of energy, improved pyrolysis equipment 1's pyrolysis efficiency, reduced pyrolysis equipment 1's production and use cost. The oil gas outlet is used for discharging oil water vapor decomposed after the original low-temperature material is heated, the discharged oil water vapor enters the oil gas collecting and separating system, and the oil gas collecting and separating system is convenient for recycling after separating oil water from gas. Fig. 1 is a schematic diagram of a thermal decomposition apparatus and a double-layer conveying heat exchange box 2 in a butt joint type connection manner, wherein the arrow direction indicates the conveying direction of the residual high-temperature materials and the original low-temperature materials, and the conveying direction of the residual high-temperature materials and the original low-temperature materials in the double-layer conveying heat exchange box 2 is opposite, namely, the residual high-temperature materials are conveyed from left to right in the double-layer conveying heat exchange box 2, and the original low-temperature materials are conveyed from right to left in the double-layer conveying heat exchange box 2; fig. 4 and 5 are schematic diagrams of the thermal decomposition equipment and the double-layer conveying heat exchange box 2 in a back-to-back connection mode, and in fig. 4, the conveying directions of the residual high-temperature materials and the original low-temperature materials in the double-layer conveying heat exchange box 2 are the same, namely, the residual high-temperature materials and the original low-temperature materials are conveyed from left to right in the double-layer conveying heat exchange box 2.

In the above technical solution, the structure of the thermal decomposition apparatus includes:

the pyrolysis furnace 1 is provided with a slag outlet 102 and a feed inlet 101, the slag outlet 102 is connected with the high-temperature material inlet 32 of the double-layer transmission heat exchange box 2, and the feed inlet 101 is connected with the low-temperature material outlet 43;

the heating bin 5 is arranged at the bottom of the thermal decomposition furnace 1, and a plurality of groups of burners 6 are fixedly arranged in the heating bin 5;

the plurality of layers of transmission chain belts 7 are arranged inside the thermal decomposition furnace 1 in a staggered mode, each group of transmission chain belts 7 is connected with a driving wheel 71, one end of the transmission chain belt 71 on the uppermost layer is positioned below the feeding hole 101, and one end of the transmission chain belt on the lowermost layer is positioned at the slag hole 102; and the driving motor 8 is arranged outside the thermal decomposition furnace 1, and a motor shaft of the driving motor 8 extends into the thermal decomposition furnace 1 and is fixedly connected with the driving wheel 71.

The original low-temperature materials preheated in the double-layer transmission heat exchange box 2 enter the thermal decomposition furnace from the feed inlet and enter the surface of the transmission chain belt 7 at the uppermost layer; the driving motor 8 drives the transmission chain belt to move so as to convey the original low-temperature materials in the thermal decomposition furnace 1; the original low-temperature materials are conveyed and fall in the thermal decomposition furnace layer by layer, the flame sprayed by the burner 6 heats and decomposes the original low-temperature materials, and finally the original low-temperature materials which are heated and decomposed are changed into residual high-temperature materials which are discharged from the slag outlet 102; the residual high-temperature materials enter the lower heat exchange chamber 3 of the double-layer transmission heat exchange box 2 through the slag outlet 102, and the next part of the original low-temperature materials needing thermal decomposition is preheated. The arrangement of the multi-layer transmission chain belts 7 in the thermal decomposition furnace 1 in a staggered manner realizes the conveying of the original low-temperature materials in the thermal decomposition furnace, prolongs the decomposition and retention time of the original low-temperature materials in the thermal decomposition furnace 1, and is more sufficient for the thermal decomposition of the original low-temperature materials.

In the above technical solution, a screw conveyer is connected between the feeding port 101 of the pyrolysis apparatus and the low-temperature material outlet 43 of the double-layer transmission heat exchange box 2, and the screw conveyer has a structure including:

the device comprises a device shell 10, wherein a feed port 1001 and a discharge port 1002 are arranged on the device shell, the feed port 1001 is connected with a low-temperature material outlet 43 of the double-layer transmission heat exchange box 2, and the discharge port 1002 is connected with a feed inlet 101 of the thermal decomposition equipment;

the driving screw 11 is rotatably installed in the device shell 10, one end of the driving screw 11 is close to the discharge port 1002 of the device shell 10, and the other end of the driving screw is connected with the motor 12; the preheated original low-temperature material enters the spiral conveying device from the low-temperature material outlet 43 and the feeding port 1001, the motor 12 rotates the driving screw 11, so that the original low-temperature material is driven to move towards the discharging port 1002, and therefore the original low-temperature material enters the thermal decomposition equipment under the action of the driving screw 11. The arrangement can accelerate the transmission speed of the original low-temperature material and simultaneously avoid a large amount of heat loss.

In the above technical scheme, the heat insulation layer 111 is arranged outside the device shell 10, and the heat insulation layer 111 has a heat insulation effect on the original low-temperature material in the device shell 10, so that heat dissipated from the original low-temperature material to the outside can be effectively reduced.

In the above technical solution, the structure of the oil-gas collecting and separating system comprises:

the condenser 13 is connected with the oil gas outlet 44 through a pipeline, the condenser 13 is also connected with a transfer tank 14 through a pipeline, and the transfer tank 14 is provided with an oil water outlet 141 and a gas outlet 142;

a plurality of baffle plates 15 which are arranged in a staggered mode are arranged in the transfer tank 14, and a filter screen 16 is arranged above the baffle plates 15. Oil water and gas are separated by the condensation action of the condenser 13, the separated oil water and gas enter the transfer tank 14, and the oil water flows downwards along the surface of the baffle plate 15, so that the flow path of the oil water is increased by the baffle plate 15, and a certain cooling effect is achieved on the oil water; meanwhile, part of the oil and water which are not separated in the gas can be condensed on the surface of the baffle plate 15 after encountering the baffle plate, so that the oil-water separation rate can be improved; the filter screen 16 is used to filter particulate impurities in the oil and gas.

In the above technical solution, the structure of the transit tank 14 includes a lower tank 143 and an upper tank 144, the upper tank 144 and the lower tank 143 are connected by a hinge, an annular sealing groove 145 is formed on the lower tank 143, and an annular sealing ring 17 is disposed in the annular sealing groove 145;

the joint of the upper tank 144 and the lower tank 143 is provided with a flange sealing element 18, and the flange sealing elements 18 of the upper tank 144 and the lower tank 143 are fixedly connected through bolts. This arrangement facilitates the mounting and dismounting of the filter screen 16 while also ensuring the internal sealing performance of the relay tank 14.

In the above technical scheme, a circle of limiting layer 146 is arranged in the lower tank body 143, the filter screen 16 is a circular filter screen, the mounting ring 161 is fixed outside the filter screen 16, and the limiting layer 146 and the mounting ring 161 are fixedly connected through bolts.

In the above technical solution, the double-layer transmission heat exchange box 2 may be one of a square, a circle and an ellipse; the high-temperature material conveying device 31 and the high-temperature material conveying device 41 are conveying chain belts.

The thermal decomposition equipment is a thermal decomposition furnace 1 for spiral feeding, a feeding hole 101 and a slag hole 102 are arranged on the thermal decomposition furnace 1, a conveying screw 21 is rotatably arranged in the thermal decomposition furnace 1, the conveying screw 21 is connected with a feeding motor 20, and the feeding motor 20 is positioned outside the thermal decomposition furnace 1. In this technical scheme, the residual high-temperature material is driven by the conveying screw to be discharged into the double-layer transmission heat exchange box 1 from the slag outlet, and the original low-temperature material preheated by the double-layer transmission heat exchange box 2 enters the thermal decomposition furnace 1 from the feed inlet 101. The heating decomposition mode in the thermal decomposition furnace can adopt burner heating or spiral heating pipe heating.

In the above technical solution, the structure of the thermal decomposition apparatus includes:

the thermal decomposition furnace 1 is provided with a feeding hole 101 and a slag hole 102, and a plurality of layers of transmission chain belts 7 which are arranged in a staggered mode are arranged inside the thermal decomposition furnace 1;

thermal insulation layer 19, its setting is in thermal decomposition furnace 1 is outside, just be provided with the electric heating pipe 18 that the spiral was arranged between thermal insulation layer 19 and the thermal decomposition furnace 1, heat the material in the thermal decomposition furnace through electric heating pipe, only listed two kinds of thermal decomposition furnace structures and two kinds of heating methods here, the utility model provides a technical scheme is applicable to the thermal decomposition furnace of other structures equally.

The number of apparatuses and the scale of the process described here are intended to simplify the description of the present invention. Applications, modifications and variations of the present invention will be apparent to those skilled in the art.

While the embodiments of the invention have been described above, it is not intended to be limited to the details shown, or described, but rather to cover all modifications, which would come within the scope of the appended claims, and all changes which come within the meaning and range of equivalency of the art are therefore intended to be embraced therein.

Claims (10)

1. An energy-saving organic matter thermal decomposition apparatus, comprising:

a thermal decomposition device;

the double-layer transmission heat exchange box structurally comprises a lower-layer heat exchange chamber and an upper-layer heat exchange chamber communicated with the lower-layer heat exchange chamber, wherein a low-temperature material transmission device is arranged in the upper-layer heat exchange chamber, and a high-temperature material transmission device is arranged in the lower-layer heat exchange chamber; a low-temperature material inlet is formed in one side of the upper-layer heat exchange chamber, a low-temperature material outlet is formed in the other side of the upper-layer heat exchange chamber, and the low-temperature material outlet is connected with a feeding hole of thermal decomposition equipment; a high-temperature material inlet is formed in one side of the lower-layer heat exchange chamber, a tailings outlet is formed in the other side of the lower-layer heat exchange chamber, and the high-temperature material inlet is connected with a slag outlet of the thermal decomposition equipment;

the upper heat exchange chamber is also provided with an oil-gas outlet which is connected with an oil-gas collecting and separating system.

2. The energy-saving organic matter thermal decomposition device according to claim 1, wherein the thermal decomposition device is structured to include:

the thermal decomposition furnace is provided with a slag outlet and a feed inlet, the slag outlet is connected with a high-temperature material inlet of the double-layer transmission heat exchange box, and the feed inlet is connected with a low-temperature material outlet;

the heating bin is arranged at the bottom of the thermal decomposition furnace, and a plurality of groups of burners are fixedly arranged in the heating bin;

the multi-layer transmission chain belts are arranged inside the thermal decomposition furnace in a staggered mode, each group of transmission chain belts are connected with driving wheels, one end of the transmission chain belt on the uppermost layer is located below the feeding hole, and one end of the transmission chain belt on the lowermost layer is close to the slag hole; and the driving motor is arranged outside the thermal decomposition furnace, and a motor shaft of the driving motor extends into the thermal decomposition furnace and is fixedly connected with the driving wheel.

3. The energy-saving organic matter thermal decomposition device according to claim 1, wherein a screw conveyor is connected between the feed inlet of the thermal decomposition device and the low-temperature material outlet of the double-layer transfer heat exchange box, and the screw conveyor has a structure comprising:

the device comprises a device shell, a double-layer transmission heat exchange box and a thermal decomposition device, wherein a feeding port and a discharging port are arranged on the device shell, the feeding port is connected with a low-temperature material outlet of the double-layer transmission heat exchange box, and the discharging port is connected with a feeding hole of the thermal decomposition device;

and the driving screw is rotatably installed in the device shell, one end of the driving screw is close to the discharge port of the device shell, and the other end of the driving screw is connected with a motor.

4. The apparatus for energy-saving organic matter pyrolysis according to claim 3, wherein a heat insulating layer is provided outside the device case.

5. The apparatus for energy-saving organic matter thermal decomposition according to claim 1, wherein the oil-gas collecting and separating system is constructed by:

the condenser is connected with the oil gas outlet through a pipeline, the condenser is also connected with a transfer tank through a pipeline, and the transfer tank is provided with a water-oil outlet and a gas outlet;

a plurality of baffle plates which are arranged in a staggered mode are arranged in the transfer tank, and a filter screen is arranged above the baffle plates.

6. The energy-saving organic matter thermal decomposition device according to claim 5, wherein the structure of the intermediate tank comprises a lower tank body and an upper tank body, the upper tank body and the lower tank body are hinged, an annular sealing groove is formed in the lower tank body, and an annular sealing ring is arranged in the annular sealing groove;

go up jar body and lower jar of body junction and all be provided with flange seal spare, go up jar body and the flange seal spare of lower jar of body and realize fixed connection through the bolt.

7. The energy-saving organic matter thermal decomposition device according to claim 6, wherein a circle of limiting layer is arranged in the lower tank body, the filter screen is a circular filter screen, a mounting ring is fixed outside the filter screen, and the limiting layer and the mounting ring are fixedly connected through bolts.

8. The energy saving type organic matter pyrolysis apparatus according to claim 1, wherein the double-layer transfer heat exchange box may be one of a square, a circle, and an oval; the high-temperature material transmission device and the high-temperature material transmission device are conveying chain belts.

9. The apparatus for energy-saving thermal decomposition of organic substances according to claim 1, wherein the apparatus is a screw-feeding thermal decomposition furnace, the thermal decomposition furnace is provided with a feed inlet and a slag outlet, a conveying screw is rotatably provided in the thermal decomposition furnace, the conveying screw is connected to a feeding motor, and the feeding motor is located outside the thermal decomposition furnace.

10. The energy-saving organic matter thermal decomposition device according to claim 1, wherein the thermal decomposition device is structured to include:

the thermal decomposition furnace is provided with a feed inlet and a slag outlet, and a plurality of layers of staggered transmission chain belts are arranged inside the thermal decomposition furnace;

and the heat insulation layer is arranged outside the thermal decomposition furnace, and electric heating pipes which are spirally arranged are arranged between the heat insulation layer and the thermal decomposition furnace.

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