Energy-saving integrated combustion furnace
By introducing lifting and insulation components into the integrated combustion furnace, the problems of fixed height and heat loss are solved, achieving highly flexible adjustment and energy saving.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- CHANGSHA HUARUN ENERGY SAVING TECH CO LTD
- Filing Date
- 2025-05-28
- Publication Date
- 2026-06-19
AI Technical Summary
The height of existing household integrated combustion stoves is fixed and cannot be adjusted according to the operator's height, resulting in limited use and significant heat loss, leading to energy waste.
An energy-saving integrated combustion furnace including a lifting component and an insulation component was designed. The height of the combustion furnace is adjusted by an external controller, and the insulation component is made of materials such as alumina, rock wool and fumed silica nanoplatelets to reduce heat loss.
It enables flexible adjustment of the combustion furnace height, making it suitable for operators of different heights, and saves energy by reducing heat loss.
Smart Images

Figure CN224381583U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of heating equipment technology, and in particular to an energy-saving integrated combustion furnace. Background Technology
[0002] Fire is essential to people's daily lives, mainly used for heating water, cooking food, and raising indoor temperatures. Currently, natural gas is widely used as fuel in cities, but because rural areas have readily available resources, many families still use firewood.
[0003] However, in existing technologies, household integrated combustion stoves are commonly used in rural areas for heating water, cooking food, and raising indoor temperature. However, the height of household integrated combustion stoves is generally fixed and cannot be adjusted according to the operator's height, which limits their use. Utility Model Content
[0004] The purpose of this invention is to solve the problems existing in the prior art.
[0005] To achieve the above objectives, this utility model adopts the following technical solution: an energy-saving integrated combustion furnace, comprising: a combustion furnace, a combustion chamber formed at the top of one end of the combustion furnace, hinges fixedly connected to both ends near the edge of one side of the combustion furnace cavity, and doors fixedly connected to the other ends of the two hinges; an ash chamber formed at the bottom of one end of the combustion furnace, a plurality of through holes formed through the top of the ash chamber cavity, the combustion chamber cavity communicating with the ash chamber cavity through the plurality of through holes, an ash storage drawer movably embedded in the ash chamber cavity, and a pot seat formed through the top of the combustion chamber cavity, the pot seat containing... A cover is movably fitted at the top of the combustion chamber. A storage trough is opened at the other end of the top of the combustion furnace. A cover is movably fitted at the top of the inner cavity of the storage trough. The inner cavity of the combustion furnace has insulation trough 1, insulation trough 2, insulation trough 3, and insulation trough 4. The inner cavities of insulation trough 1, insulation trough 2, insulation trough 3, and insulation trough 4 are interconnected. Insulation trough 1 and insulation trough 4 are respectively located on the left and right sides of the combustion chamber. Insulation trough 2 is located above the combustion chamber. Insulation trough 3 is located on the rear side of the combustion chamber. Insulation components are provided in the inner cavities of insulation trough 1, insulation trough 2, insulation trough 3, and insulation trough 4. A lifting component is provided at the bottom of the combustion furnace.
[0006] Furthermore, an inlet is provided on one side of the bottom of the storage tank cavity, and an auger feeding trough is provided at the other end of the inlet cavity. An outlet is provided on the other side of the top of the auger feeding trough cavity. The outlet communicates with the cavity of the combustion chamber. A motor plate is fixedly connected to the top of the combustion furnace. Mounting holes are provided on both sides of the outlet cavity. Gravity-type flap valves are movably installed in the cavities of the two mounting holes. Augers are installed at both ends of the auger feeding trough cavity via bearings. A motor is fixedly connected to the center of the top of the auger. The surface of the motor is fixedly connected to the side of the motor plate. An exhaust pipe is installed on the side wall of the combustion furnace above one side of the combustion chamber cavity. The exhaust pipe communicates with the cavity of the combustion chamber. A flexible metal hose is fixedly sleeved on the top of the exhaust pipe surface. Through holes are provided on both sides of one end of the bottom cavity of the combustion furnace. Moving slots are provided on both sides of the other end of the bottom cavity of the combustion furnace.
[0007] Furthermore, the insulation component includes a flame-retardant groove, an insulation layer one fixedly connected to the outside of the flame-retardant groove, an insulation layer two fixedly connected to the outside of the insulation layer one, and a heat insulation layer fixedly connected to the outside of the insulation layer two. The flame-retardant groove is made of alumina, the insulation layer one is made of rock wool, the insulation layer two is made of aluminum silicate fiber, and the heat insulation layer is made of fumed silica nanoplate.
[0008] Furthermore, the lifting assembly includes a base plate and two lifting plates. Braked swivel casters are fixedly connected to the four corners of the bottom of the base plate. Handles are fixedly connected to both sides of one end of the base plate. A support plate is fixedly connected to the middle of the inner cavity of the base plate. A motor plate is fixedly connected to one end of the base plate. Through holes are formed on both sides of one end of the inner cavity of the base plate. Moving grooves are formed on both sides of the other end of the inner cavity of the base plate. Threaded rods are embedded in the inner cavities of the support plate and the base plate via bearings. A forward and reverse motor is fixedly connected to the center of one end of the threaded rod. The bottom of the forward and reverse motors is fixedly connected to the surface of the motor plate.
[0009] Furthermore, T-shaped connecting rods 1 are fixedly connected to both ends of one side and the middle part of the other side of the two lifting plates 1. T-shaped connecting rods 2 are fixedly connected to the other ends of the two T-shaped connecting rods 1 at the bottom. Push plates are movably sleeved on the surfaces of the two T-shaped connecting rods 2. The internal threads of the push plates are sleeved on the surface of the threaded rods. Lifting plates 2 are movably sleeved on the surfaces of the two T-shaped connecting rods 1 at the middle part. T-shaped connecting rods 3 are fixedly connected to both ends of one side of the two lifting plates 2. The surfaces of the two T-shaped connecting rods 3 at the bottom are movably embedded in the interior of the two through holes 3. The surfaces of the two T-shaped connecting rods 1 at the bottom are movably embedded in the interior of the two moving slots 2.
[0010] Furthermore, one side of the four flame-retardant grooves is fixedly connected to the side of the inner cavity of insulation groove one, insulation groove two, insulation groove three and insulation groove four near the combustion chamber, and one side of the four heat insulation layers is fixedly connected to the side of the inner cavity of insulation groove one, insulation groove two, insulation groove three and insulation groove four away from the combustion chamber.
[0011] Furthermore, the surfaces of the two T-shaped connecting rods at the top are movably embedded inside the two through holes, and the surfaces of the two T-shaped connecting rods at the top are movably embedded inside the two moving slots.
[0012] Compared with the prior art, the advantages and positive effects of this utility model are as follows:
[0013] 1. This utility model uses an external controller to start the forward and reverse motors, which raise the height of the combustion furnace. Reverse control of the forward and reverse motors lowers the height of the combustion furnace. This design allows the height of the integrated combustion furnace to be adjusted according to needs, making it suitable for operators of different heights.
[0014] 2. In this utility model, the heat insulation component can reduce the heat loss in the combustion chamber. Less heat loss means less fuel is needed to reach the same temperature. This integrated combustion furnace design can achieve energy saving. Attached Figure Description
[0015] Figure 1 A schematic diagram of the overall structure of an energy-saving integrated combustion furnace provided by this utility model;
[0016] Figure 2 A schematic diagram of the base plate of an energy-saving integrated combustion furnace provided by this utility model;
[0017] Figure 3 A partial schematic diagram of the lifting assembly of an energy-saving integrated combustion furnace provided by this utility model;
[0018] Figure 4 A partial exploded view of an energy-saving integrated combustion furnace provided by this utility model;
[0019] Figure 5 A front sectional view of an energy-saving integrated combustion furnace provided by this utility model;
[0020] Figure 6 A cross-sectional view of the insulation component of an energy-saving integrated combustion furnace provided by this utility model;
[0021] Figure 7 A side sectional view of an energy-saving integrated combustion furnace provided by this utility model.
[0022] Legend:
[0023] 1. Combustion furnace; 101. Combustion chamber; 102. Hinge; 103. Door; 104. Ash chamber; 105. Through hole one; 106. Ash storage drawer; 107. Boiler base; 108. Cover one; 109. Storage trough; 110. Cover two; 111. Feed inlet; 112. Screw feed trough; 113. Discharge outlet; 114. Motor plate one; 115. Mounting hole; 116. Gravity flap valve; 117. Screw; 118. Motor; 119. Exhaust pipe; 120. Flexible metal hose; 121. Insulation tank one; 122. Insulation tank two; 123. Insulation tank three; 124. 1. Temperature bath four; 125. Through hole two; 126. Moving groove one; 2. Insulation component; 201. Flame retardant groove; 202. Insulation layer one; 203. Insulation layer two; 204. Heat insulation layer; 3. Lifting component; 301. Base plate; 302. Brake universal caster; 303. Handle; 304. Support plate; 305. Motor plate two; 306. Through hole three; 307. Moving groove two; 308. Threaded rod; 309. Forward and reverse motor; 310. Lifting plate one; 311. T-shaped connecting rod one; 312. T-shaped connecting rod two; 313. Push plate; 314. Lifting plate two; 315. T-shaped connecting rod three. Detailed Implementation
[0024] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0025] Please see Figure 1-7This utility model provides a technical solution: an energy-saving integrated combustion furnace, comprising: a combustion furnace 1, a combustion chamber 101 formed at the top of one end of the combustion furnace 1, hinges 102 fixedly connected to both ends of one side of the combustion furnace 1 near the edge, and doors 103 fixedly connected to the other ends of the two hinges 102, an ash chamber 104 formed at the bottom of one end of the combustion furnace 1, multiple through holes 105 formed through the top of the ash chamber 104, the inner cavity of the combustion chamber 101 communicating with the inner cavity of the ash chamber 104 through the multiple through holes 105, an ash storage drawer 106 movably embedded in the inner cavity of the ash chamber 104, a pot seat 107 formed through the top of the inner cavity of the combustion chamber 101, and a cover 108 movably embedded in the top of the inner cavity of the pot seat 107, the combustion... A storage trough 109 is provided at the other end of the top of the furnace 1. A cover 110 is movably installed on the top of the inner cavity of the storage trough 109. The inner cavity of the combustion furnace 1 is provided with a heat preservation trough 121, a heat preservation trough 222, a heat preservation trough 33, and a heat preservation trough 44. The inner cavities of the heat preservation troughs 121, 222, 33, and 44 are interconnected. The heat preservation troughs 121 and 4124 are respectively located on the left and right sides of the combustion chamber 101. The heat preservation trough 22 is located above the combustion chamber 101, and the heat preservation trough 323 is located on the rear side of the combustion chamber 101. The inner cavities of the heat preservation troughs 121, 222, 33, and 4124 are all provided with heat preservation components 2. A lifting component 3 is provided at the bottom of the combustion furnace 1.
[0026] Specifically: the height of the combustion furnace 1 is raised by starting the forward and reverse motor 309 through an external controller, and the height of the combustion furnace 1 is lowered by controlling the forward and reverse motor 309 to rotate. This design allows the height of the integrated combustion furnace to be adjusted according to needs, making it suitable for operators of different heights and reducing the labor intensity of the operators; the heat preservation component 2 can reduce the heat loss in the combustion chamber 101. Less heat loss means less fuel is needed to reach the same temperature, so this integrated combustion furnace can achieve energy saving; the top of the inner cavity of the pot base 107 and the storage tank 109 is T-shaped, which facilitates the installation of the first cover 108 and the second cover 110.
[0027] In one embodiment, an inlet 111 is provided on one side of the bottom end of the inner cavity of the storage tank 109, and an auger feeding trough 112 is provided at the other end of the inner cavity of the inlet 111. An outlet 113 is provided on the other side of the top end of the inner cavity of the auger feeding trough 112. The outlet 113 communicates with the inner cavity of the combustion chamber 101. A motor plate 114 is fixedly connected to the top of the combustion furnace 1. Mounting holes 115 are provided on both sides of the inner cavity of the outlet 113. Gravity flap valves 116 are movably installed in the inner cavities of the two mounting holes 115. The two ends of the inner cavity of the auger feeding trough 112 are connected by bearings. An auger 117 is embedded and installed. A motor 118 is fixedly connected to the center of the top of the auger 117. The surface of the motor 118 is fixedly connected to the side of the motor plate 114. An exhaust pipe 119 is installed on the side wall of the combustion furnace 1 above one side of the inner cavity of the combustion chamber 101. The exhaust pipe 119 communicates with the inner cavity of the combustion chamber 101. A flexible metal hose 120 is fixedly sleeved on the top of the surface of the exhaust pipe 119. Through holes 125 are opened on both sides of one end of the bottom inner cavity of the combustion furnace 1. Moving slots 126 are opened on both sides of the other end of the bottom inner cavity of the combustion furnace 1.
[0028] Specifically, such as Figure 5 As shown: The motor 118 is fixedly connected to the side of the motor plate 114 to prevent the motor 118 from shaking during operation and affecting the normal use of the combustion furnace; the flexible metal hose 120 is a commonly used pipe that can be bent within a small range and has an adjustable length, and its specific structure will not be described here; the gravity flap valve 116 is a commonly used unloading device that uses the weight of the material and the internal mechanical structure of the valve to achieve automatic opening and closing, and its specific structure will not be described here.
[0029] In one embodiment, the thermal insulation component 2 includes a flame-retardant groove 201, a thermal insulation layer 202 fixedly connected to the outside of the flame-retardant groove 201, a thermal insulation layer 203 fixedly connected to the outside of the thermal insulation layer 202, and a heat insulation layer 204 fixedly connected to the outside of the thermal insulation layer 203. The flame-retardant groove 201 is made of alumina, the thermal insulation layer 202 is made of rock wool, the thermal insulation layer 203 is made of aluminum silicate fiber, and the heat insulation layer 204 is made of fumed silica nanoplate.
[0030] Specifically, such as Figure 6-7 As shown: The heat insulation component 2 can reduce the heat loss in the combustion chamber 101. Less heat loss means less fuel is needed to reach the same temperature, directly saving energy costs.
[0031] In one embodiment, the lifting assembly 3 includes a base plate 301 and two lifting plates 310. Braked universal casters 302 are fixedly connected to the four corners of the bottom of the base plate 301. Handles 303 are fixedly connected to both sides of one end of the base plate 301. A support plate 304 is fixedly connected to the middle part of the inner cavity of the base plate 301. A motor plate 305 is fixedly connected to one end of the base plate 301. Through holes 306 are opened through both sides of one end of the inner cavity of the base plate 301. Moving grooves 307 are opened through both sides of the other end of the inner cavity of the base plate 301. A threaded rod 308 is embedded and installed in the inner cavity of the support plate 304 and one end of the inner cavity of the base plate 301 through bearings. A forward and reverse motor 309 is fixedly connected to the center of one end of the threaded rod 308. The bottom of the forward and reverse motor 309 is fixedly connected to the surface of the motor plate 305.
[0032] Specifically, such as Figure 2 As shown: The forward and reverse motor 309 is fixedly connected to the surface of the motor plate 305 to prevent the forward and reverse motor 309 from shaking during operation and affecting the normal operation of the combustion furnace.
[0033] In one embodiment, T-shaped connecting rods 311 are fixedly connected to both ends of one side and the middle of the other side of the two lifting plates 310. T-shaped connecting rods 312 are fixedly connected to the other ends of the two T-shaped connecting rods 311 at the bottom. Push plates 313 are movably sleeved on the surfaces of the two T-shaped connecting rods 312. The internal threads of the push plates 313 are sleeved on the surface of the threaded rods 308. Lifting plates 314 are movably sleeved on the surfaces of the two T-shaped connecting rods 311 at the middle. T-shaped connecting rods 315 are fixedly connected to both ends of one side of the two lifting plates 314. The surfaces of the two T-shaped connecting rods 315 at the bottom are movably embedded in the interior of the two through holes 306. The surfaces of the two T-shaped connecting rods 311 at the bottom are movably embedded in the interior of the two moving slots 307.
[0034] Specifically, such as Figure 3 As shown: T-shaped connecting rod 311 is designed in a T-shape to prevent it from detaching from the interior of the moving slot 307 and the through hole 125, and also to prevent the lifting plate 314 from detaching; T-shaped connecting rod 315 is designed in a T-shape to prevent it from detaching from the interior of the through hole 306 and the moving slot 126; the movement of the push plate 313 is restricted by the T-shaped connecting rods 312 at both ends to prevent the threaded rod 308 from driving the push plate 313 to rotate, ensuring that the push plate 313 can only move horizontally; both ends of the push plate 313 are provided with T-shaped movable slots that are adapted to the T-shaped connecting rods 312, and the surface of the T-shaped connecting rods 312 is embedded in the T-shaped movable slots.
[0035] In one embodiment, the surfaces of one side of the four flame-retardant grooves 201 are fixedly connected to the inner cavities of the first insulation groove 121, the second insulation groove 122, the third insulation groove 123, and the fourth insulation groove 124 near the combustion chamber 101, and the surfaces of one side of the four heat insulation layers 204 are fixedly connected to the inner cavities of the first insulation groove 121, the second insulation groove 122, the third insulation groove 123, and the fourth insulation groove 124 away from the combustion chamber 101.
[0036] Specifically, such as Figure 6-7 As shown: The heat insulation component 2 can reduce the heat loss in the combustion chamber 101. Less heat loss means less fuel is needed to reach the same temperature, directly saving energy costs.
[0037] In one embodiment, the surfaces of the two top T-shaped connecting rods 311 are movably embedded inside the two through holes 125, and the surfaces of the two top T-shaped connecting rods 315 are movably embedded inside the two moving slots 126.
[0038] Specifically, such as Figure 1 As shown: T-shaped link 311 is designed to prevent it from detaching from the inside of moving slot 307 and through hole 125, and also to prevent the lifting plate 314 from detaching; T-shaped link 315 is designed to prevent it from detaching from the inside of through hole 306 and moving slot 126.
[0039] Working principle: Push the integrated combustion furnace to the required position by holding the handle 303 and using the brake swivel caster 302 and connect it to the external power supply equipment. Then lock the brake swivel caster 302 to fix the integrated combustion furnace. The external power supply equipment provides power to the integrated combustion furnace. The external controller is associated with the motor 118 and the forward and reverse motor 309 for control. Connect the top end of the flexible metal hose 120 to the external exhaust pipe.
[0040] The forward and reverse motors 309 can be started by an external controller according to the required height. The output end of the forward and reverse motors 309 drives the threaded rod 308 to rotate. The rotating threaded rod 308 drives the push plate 313 to move. The push plate 313 pushes the bottom of the two lifting plates 310 to move, so that the lifting plates 310 and 314 open, and the height of the combustion furnace 1 rises. By controlling the forward and reverse motors 309 to rotate in the opposite direction, the height of the combustion furnace 1 can be controlled to fall, and the integrated combustion furnace can be adjusted to the required height.
[0041] This design allows for adjustment of the height of the integrated combustion furnace, making it suitable for operators of different heights.
[0042] Open the cover 110 to add solid fuel to the inner cavity of the storage tank 109, open the door 103 to add fuel to the inner cavity of the combustion chamber 101 and ignite it, then close the door 103. The heat insulation component 2 can reduce the heat loss in the inner cavity of the combustion chamber 101. Less heat loss means less fuel is needed to reach the same temperature.
[0043] This integrated combustion furnace design enables energy conservation.
[0044] The operator can start the motor 118 via an external controller as needed. The output of the motor 118 drives the auger 117 to rotate. The rotating auger 117 transports the solid fuel inside the feed port 111 to the top of the auger feeding trough 112. Then, the fuel is fixed and falls to the gravity flap valve 116 inside the discharge port 113. When the mass of the falling solid fuel is greater than that of the gravity flap valve 116, the gravity flap valve 116 tilts, and the solid fuel falls into the inner cavity of the combustion chamber 101 for combustion.
[0045] The above description is merely a preferred embodiment of the present utility model and is not intended to limit the present utility model in any other way. Any person skilled in the art may make changes or modifications to the above-disclosed technical content to create equivalent embodiments for application in other fields. However, any simple modifications, equivalent changes, and modifications made to the above embodiments based on the technical essence of the present utility model without departing from the technical solution of the present utility model shall still fall within the protection scope of the technical solution of the present utility model.
Claims
1. An energy-saving integrated combustion furnace, characterized in that, include: A combustion furnace (1) has a combustion chamber (101) at the top of one side. Hinges (102) are fixedly connected to both ends of the inner cavity of the combustion furnace (1) near the edge. Doors (103) are fixedly connected to the other ends of the two hinges (102). An ash chamber (104) is provided at the bottom of one side of the combustion furnace (1). Multiple through holes (105) are provided through the top of the inner cavity of the ash chamber (104). The inner cavity of the combustion chamber (101) communicates with the inner cavity of the ash chamber (104) through the multiple through holes (105). An ash storage drawer (106) is movably embedded in the inner cavity of the ash chamber (104). A pot seat (107) is provided through the top of the inner cavity of the combustion chamber (101). A cover (108) is movably embedded in the top of the inner cavity of the pot seat (107). A material storage trough (109) is provided at the other end of the top of the combustion furnace (1). The top of the inner cavity of the storage tank (109) is movably fitted with a second cover (110). The inner cavity of the combustion furnace (1) is provided with a heat preservation tank 1 (121), a heat preservation tank 2 (122), a heat preservation tank 3 (123), and a heat preservation tank 4 (124). The inner cavities of the heat preservation tank 1 (121), the heat preservation tank 2 (122), the heat preservation tank 3 (123), and the heat preservation tank 4 (124) are interconnected. The inner cavities of the heat preservation tank 1 (121) and the heat preservation tank 4 (124) are connected. 4) Corresponding to the left and right sides of the combustion chamber (101), the second heat insulation groove (122) is located above the combustion chamber (101), the third heat insulation groove (123) is located behind the combustion chamber (101), and the inner cavities of the first heat insulation groove (121), the second heat insulation groove (122), the third heat insulation groove (123) and the fourth heat insulation groove (124) are all equipped with heat insulation components (2), and the bottom of the combustion furnace (1) is equipped with a lifting component (3).
2. The energy-saving integrated combustion furnace according to claim 1, characterized in that: A feed inlet (111) is provided on one side of the bottom of the inner cavity of the storage tank (109). A screw conveyor feeding trough (112) is provided at the other end of the inner cavity of the feed inlet (111). A discharge outlet (113) is provided on the other side of the top of the inner cavity of the screw conveyor feeding trough (112). The discharge outlet (113) is connected to the inner cavity of the combustion chamber (101). A motor plate (114) is fixedly connected to the top of the combustion furnace (1). Mounting holes (115) are provided on both sides of the inner cavity of the discharge outlet (113). Gravity flap valves (116) are movably installed in the inner cavities of the two mounting holes (115). The two ends of the inner cavity of the screw conveyor feeding trough (112) are installed by bearings. There is an auger (117), and a motor (118) is fixedly connected to the center of the top of the auger (117). The surface of the motor (118) is fixedly connected to the side of the motor plate (114). A flue pipe (119) is installed on the side wall of the combustion furnace (1) above the inner cavity of the combustion chamber (101). The flue pipe (119) is connected to the inner cavity of the combustion chamber (101). A flexible metal hose (120) is fixedly sleeved on the top of the surface of the flue pipe (119). Two through holes (125) are opened through both sides of one end of the bottom inner cavity of the combustion furnace (1). Two moving grooves (126) are opened through both sides of the other end of the bottom inner cavity of the combustion furnace (1).
3. The energy-saving integrated combustion furnace according to claim 1, characterized in that: The heat insulation component (2) includes a flame-retardant groove (201), a heat insulation layer (202) is fixedly connected to the outside of the flame-retardant groove (201), a heat insulation layer (203) is fixedly connected to the outside of the heat insulation layer (202), and a heat insulation layer (204) is fixedly connected to the outside of the heat insulation layer (203). The flame-retardant groove (201) is made of alumina, the heat insulation layer (202) is made of rock wool, the heat insulation layer (203) is made of aluminum silicate fiber, and the heat insulation layer (204) is made of fumed silica nanoplate.
4. The energy-saving integrated combustion furnace according to claim 2, characterized in that: The lifting assembly (3) includes a base plate (301) and two lifting plates (310). Brake casters (302) are fixedly connected to the four corners of the bottom of the base plate (301). Handles (303) are fixedly connected to both sides of one end of the base plate (301). A support plate (304) is fixedly connected to the middle of the inner cavity of the base plate (301). A motor plate (305) is fixedly connected to one end of the base plate (301). Both sides of the end are provided with through holes three (306), and both sides of the other end of the cavity of the bottom plate (301) are provided with moving grooves two (307). The inner cavity of the support plate (304) and one end of the inner cavity of the bottom plate (301) are fitted with threaded rods (308) through bearings. A forward and reverse motor (309) is fixedly connected to the center of one end of the threaded rod (308), and the bottom of the forward and reverse motor (309) is fixedly connected to the surface of the motor plate two (305).
5. The energy-saving integrated combustion furnace according to claim 4, characterized in that: T-shaped connecting rods 1 (311) are fixedly connected to both ends of one side and the middle part of the other side of the two lifting plates 1 (310). T-shaped connecting rods 2 (312) are fixedly connected to the other end of the two T-shaped connecting rods 1 (311) at the bottom. Push plates 313 are movably sleeved on the surface of the two T-shaped connecting rods 2 (312). The internal threads of the push plates 313 are sleeved on the surface of the threaded rod (308). Lifting plates 2 (314) are movably sleeved on the surface of the two T-shaped connecting rods 1 (311) at the middle part. T-shaped connecting rods 3 (315) are fixedly connected to both ends of one side of the two lifting plates 2 (314). T-shaped connecting rods 3 (315) are movably embedded in the inside of the two through holes 3 (306) at the bottom. T-shaped connecting rods 1 (311) are movably embedded in the inside of the two moving slots 2 (307) at the bottom.
6. The energy-saving integrated combustion furnace according to claim 3, characterized in that: The surfaces of the four flame-retardant grooves (201) are fixedly connected to the inner cavities of the first (121), second (122), third (123) and fourth (124) of the heat insulation groove near the combustion chamber (101), and the surfaces of the four heat insulation layers (204) are fixedly connected to the inner cavities of the first (121), second (122), third (123) and fourth (124) of the heat insulation groove away from the combustion chamber (101).
7. The energy-saving integrated combustion furnace according to claim 5, characterized in that: The surfaces of the two T-shaped connecting rods 1 (311) at the top are movably embedded inside the two through holes 2 (125), and the surfaces of the two T-shaped connecting rods 3 (315) at the top are movably embedded inside the two moving slots 1 (126).