CN110966650B

CN110966650B - Automatic temperature control device for thermal image detection of heating furnace based on image data processing

Info

Publication number: CN110966650B
Application number: CN201911349950.4A
Authority: CN
Inventors: 不公告发明人
Original assignee: Individual
Current assignee: Chen Xiaolan
Priority date: 2019-12-24
Filing date: 2019-12-24
Publication date: 2021-04-30
Anticipated expiration: 2039-12-24
Also published as: CN110966650A; JP2021103071A

Abstract

The invention discloses a heating furnace thermal image detection automatic temperature control device based on image data processing, which comprises a shell, wherein a heating cavity is arranged in the shell, a heating mechanism is arranged in the heating cavity, a temperature control mechanism is arranged on the upper side of the shell, a heating mechanism is arranged on the lower side of the temperature control mechanism, a water absorption mechanism is arranged on the lower side of the heating mechanism, and a transmission mechanism is connected between the heating mechanism and the water absorption mechanism as well as between the heating mechanism and the temperature control mechanism.

Description

Automatic temperature control device for thermal image detection of heating furnace based on image data processing

Technical Field

The invention relates to the technical field of image data processing, in particular to a heating furnace thermal image detection automatic temperature control device based on image data processing.

Background

At present stage, because arrival winter, the use of radiator is more and more extensive, current radiator heating is equipped with and is mostly intelligent furniture ization, carry out digital signal control etc. nevertheless lack and carry out automatically regulated control according to heating safe temperature, need carry out manually temperature regulation and keep constant temperature, and when the high temperature, lead to the scald to human skin easily, the power used is too big, lead to easily that the inflammable matter such as household electrical appliances is high in temperature and fire, arouse the conflagration to cause financial damage and casualties.

Disclosure of Invention

The invention aims to provide an automatic temperature control device for thermal image detection of a heating furnace based on image data processing, which is used for overcoming the defects.

The automatic temperature control device for thermal image detection of the heating furnace based on image data processing comprises a shell, wherein a heating cavity is arranged in the shell, a heating mechanism is arranged in the heating cavity, a temperature control mechanism is arranged on the upper side of the shell, a heating mechanism is arranged on the lower side of the temperature control mechanism, a water absorption mechanism is arranged on the lower side of the heating mechanism, and a transmission mechanism is connected among the heating mechanism, the water absorption mechanism and the temperature control mechanism;

the temperature control mechanism comprises a thermal image display monitor with the upper end face of the shell fixed, a magnetic sensing cavity is arranged in the left end wall of the heating cavity, an electromagnet is fixed on the right end wall of the magnetic sensing cavity, the right end face of the electromagnet is electrically connected with a sensing wire on the lower end face of the thermal image display monitor, a magnetic coil is fixedly connected with the left end face of the electromagnet, one end of the magnetic coil, which is far away from the electromagnet, penetrates through the upper end face of the magnetic sensing cavity and is electrically connected with the lower end face of the thermal image display monitor, the temperature of the heating mechanism is detected and controlled through the thermal image display monitor, and therefore the temperature is automatically adjusted and controlled through the.

On the basis of the technical scheme, the right end face of the electromagnet is fixedly provided with a copper guide pipe which penetrates through the magnetic coil and is fixed on the left end wall of the magnetic induction cavity, the copper guide pipe is connected with a metal magnetic block in a sliding manner, the lower end wall of the magnetic induction cavity is internally provided with an adjusting cavity, the upper end wall of the adjusting cavity is fixedly provided with a sensor which is in contact with the left end wall of the adjusting cavity, the right end wall of the adjusting cavity is internally provided with a driving cavity, the right end wall of the driving cavity is fixedly provided with a motor, the left end face of the motor is in power connection with a power shaft, the left end of the motor penetrates through the left end wall of the driving cavity and is positioned in the adjusting cavity and is in rotation connection with the left end wall of the adjusting cavity, the power shaft is in splined connection with a spline sleeve, the spline sleeve is fixedly provided with a friction wheel, the left, the left end face of the sliding block is fixedly provided with a pull rope, the left end of the pull rope penetrates through the left end face of the adjusting cavity and is located in the magnetic induction cavity, the pull rope is fixed to the left end face of the metal magnetic block, the right end face of the adjusting cavity is rotatably connected with a conical friction wheel shaft, the conical friction wheel shaft is located on the lower side of the power shaft, the right end of the conical friction wheel shaft penetrates through the wall of the right end of the adjusting cavity and is located in the driving cavity, a conical friction wheel located in the adjusting cavity and meshed with the friction wheel is fixed to the conical friction wheel shaft, and a first bevel.

On the basis of the technical scheme, the heating mechanism comprises an isolation net embedded on the right end face of the shell, the upper and lower end walls at the center of the heating cavity are fixed with metal tubes, the upper and lower end walls of the heating cavity are also fixed with heating tubes which are symmetrical left and right based on the metal tubes, a pipeline which vertically surrounds the heating cavity and penetrates through the metal pipe is arranged in the shell, a base is arranged at the lower side of the shell, the shell and the base are connected with a sleeve, a water cavity is arranged in the base, a water drain pipe with the right end penetrating through the right end wall of the water cavity and the right end positioned outside is fixed on the right end wall of the water cavity, a water inlet pipe with the left end penetrating through the left end wall of the water cavity and the left end positioned outside is fixed on the left end wall of the water cavity, the inlet tube with the outlet pipe is located external and all has set firmly the valve, the water cavity upper end wall is fixed with the upper end and runs through the water cavity upper end wall with the sleeve and with the drain pipe of pipeline delivery port department intercommunication.

On the basis of the technical scheme, the warm air mechanism comprises a warm air cavity arranged in the lower end wall of the adjusting cavity, the warm air cavity is communicated with the outside through a filter screen, the warm air cavity is communicated with the heating cavity through a metal heat absorption net, fixing columns are fixed on the upper end wall and the lower end wall of the warm air cavity, a transmission cavity is arranged in each fixing column, the left end wall of the transmission cavity is rotatably connected with a fan shaft, the left end of the fan shaft penetrates through the left end wall of the transmission cavity and is located in the warm air cavity, a second bevel gear located in the transmission cavity is fixed on the right end of the fan shaft, a fan located in the warm air cavity is fixed on the left end of the fan shaft, and the warm air mechanism provides.

On the basis of the technical scheme, the water absorption mechanism comprises a water absorption pump fixedly connected to the upper end wall of the water cavity, the lower end of the water absorption pump is fixedly provided with a water absorption pipe, a driven cavity is arranged in the water absorption pump, the upper end of the left end wall of the driven cavity is communicated with a water inlet of the pipeline, the lower end of the left end wall of the driven cavity is communicated with a water absorption cavity of the water absorption pipe, the left end wall of the water absorption cavity is rotatably connected with a transmission shaft, the left end of the transmission shaft penetrates through the left end wall of the water absorption cavity, the left end of the transmission shaft is located in the driven cavity, a turbofan located in the water absorption cavity is fixed to the right end of the transmission shaft, a third bevel gear located in the driven cavity.

On the basis of the technical scheme, the transmission mechanism comprises a first driven shaft, wherein the lower end wall of the transmission cavity is rotatably connected with the first driven shaft, the lower end of the first driven shaft penetrates through the lower end wall of the transmission cavity, the lower end of the first driven shaft is located in the driven cavity, the fourth bevel gear is meshed with the second bevel gear and is fixed at the upper end of the first driven shaft, the fifth bevel gear is located in the driven cavity and is meshed with the third bevel gear, the upper end wall of the transmission cavity is rotatably connected with a second driven shaft, the upper end of the second driven shaft penetrates through the upper end wall of the transmission cavity, the upper end of the second driven shaft is located in the driving cavity, the sixth bevel gear is meshed with the first bevel gear, and the seventh bevel gear is located in the transmission cavity and is meshed with the second bevel gear.

The invention has the beneficial effects that: the temperature control device can automatically adjust and control the heating furnace to keep the temperature constant through thermal image detection, the temperature of the heating furnace is constant through the water temperature, the use power of the heating furnace is reduced, the temperature is effectively controlled, and the problems that the human skin is scalded due to overhigh temperature and the financial loss and the casualties are caused by fire due to overhigh use power are avoided.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

FIG. 1 is a schematic structural view of a heating furnace thermal image detection automatic temperature control device based on image data processing according to the present invention;

FIG. 2 is a left view of an automatic temperature control device for thermal image detection of a heating furnace based on image data processing according to the present invention;

FIG. 3 is an enlarged view taken at A in FIG. 1 according to the present invention;

FIG. 4 is an enlarged view of the invention at B of FIG. 1;

FIG. 5 is an enlarged view of FIG. 1 at C according to the present invention;

FIG. 6 is an enlarged view of the invention at D in FIG. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-6, for convenience of description, the following orientations will now be defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

Referring to fig. 1 to 6, an automatic temperature control device for thermal image detection of a heating furnace based on image data processing according to an embodiment of the present invention includes a housing 10, a heating cavity 64 is disposed in the housing 10, a heating mechanism 70 is disposed in the heating cavity 64, a temperature control mechanism 71 is disposed on an upper side of the housing 10, a warm air mechanism 72 is disposed on a lower side of the temperature control mechanism 71, a water absorption mechanism 73 is disposed on a lower side of the warm air mechanism 72, a transmission mechanism 74 is connected between the warm air mechanism 72 and the water absorption mechanism 73 as well as between the temperature control mechanism 71, the temperature control mechanism 71 includes a thermal image display monitor 27 fixed on an upper end surface of the housing 10, a magnetic sensing cavity 30 is disposed in a left end wall of the heating cavity 64, an electromagnet 35 is fixed on a right end wall of the magnetic sensing cavity 30, a sensing line 26 is electrically connected between a right end surface of the electromagnet 35 and a lower end surface of the thermal image display monitor 27, one end of the magnetic coil 34, which is far away from the electromagnet 35, penetrates through the upper end face of the magnetic induction cavity 30 and is electrically connected with the lower end face of the thermal image display monitor 27, the temperature of the heating mechanism 70 is detected and controlled through the thermal image display monitor 27, and therefore the temperature is automatically adjusted and controlled through the temperature control mechanism 71.

In addition, in an embodiment, the right end face of the electromagnet 35 is fixed with a copper conduit 32 penetrating through the magnetic coil 34 and the left end wall of the magnetic induction cavity 30, the copper conduit 32 is connected with a metal magnetic block 33 in a sliding manner, the lower end wall of the magnetic induction cavity 30 is provided with an adjusting cavity 36, the upper end wall of the adjusting cavity 36 is fixed with a sensor 65 contacting with the left end wall of the adjusting cavity 36, the right end wall of the adjusting cavity 36 is provided with a driving cavity 42, the right end wall of the driving cavity 42 is fixed with a motor 45, the left end face of the motor 45 is connected with a power shaft 37, the left end of the power shaft is connected with the left end wall of the driving cavity 42 in a rotating manner, the left end of the adjusting cavity 36 is connected with the power shaft 37 in a rotating manner, the power shaft 37 is connected with a spline housing 47, the spline housing 47 is fixed with a friction wheel 48, the left end face of the friction wheel 48 is fixed with a fixing block 39, a sliding block 49 is connected in the annular sliding groove 46 in a sliding manner, a pull rope 31 is fixed on the left end face of the sliding block 49, the left end of the pull rope penetrates through the left end face of the adjusting cavity 36 and is located in the magnetic induction cavity 30, the pull rope 31 is fixed on the left end face of the sliding block 49 and is fixed on the left end face of the metal magnetic block 33, a conical friction wheel shaft 40 is connected on the right end face of the adjusting cavity 36 in a rotating manner, the right end of the adjusting cavity 36 penetrates through the right end wall of the adjusting cavity 36 and is located in the driving cavity 42, a conical friction wheel 41 which is located in the adjusting cavity 36 and is meshed with the friction wheel 48 is fixed on the conical friction wheel shaft 40, and a first.

In addition, in one embodiment, the heating mechanism 70 includes an isolation net 13 embedded on the right end face of the housing 10, a metal pipe 14 is fixed on the upper and lower end walls of the center of the heating cavity 64, a heating pipe 12 based on bilateral symmetry of the metal pipe 14 is further fixed on the upper and lower end walls of the heating cavity 64, a pipeline 11 which surrounds the heating cavity 64 from top to bottom and penetrates through the metal pipe 14 is arranged in the housing 10, a base 17 is arranged on the lower side of the housing 10, the housing 10 and the base 17 are connected with a sleeve 15, a water cavity 18 is arranged in the base 17, a drain pipe 19 with a right end penetrating through the right end wall of the water cavity 18 and a right end positioned outside is fixed on the right end wall of the water cavity 18, a water inlet pipe 20 with a left end penetrating through the left end wall of the water cavity 18 and a left end positioned outside is fixed on the left end wall of the water cavity 18, valves 21 are arranged on the water, a drain pipe 16 with the upper end penetrating through the upper end wall of the water cavity 18 and the sleeve 15 and communicated with the water outlet of the pipeline 11 is fixed on the upper end wall of the water cavity 18.

In addition, in one embodiment, the warm air mechanism 72 includes a warm air cavity 23 provided in a lower end wall of the adjusting cavity 36, the warm air cavity 23 communicates with the outside through a filter screen 22, the warm air cavity 23 communicates with the heat generating cavity 64 through a metal heat absorbing net 28, fixing posts 29 are fixed on upper and lower end walls of the warm air cavity 23, a transmission cavity 51 is provided in the fixing posts 29, a fan shaft 53 with a left end penetrating through a left end wall of the transmission cavity 51 and located in the warm air cavity 23 is rotatably connected to a left end wall of the transmission cavity 51, a second bevel gear 52 located in the transmission cavity 51 is fixed on a right end of the fan shaft 53, a fan 24 located in the warm air cavity 23 is fixed on a left end of the fan shaft 53, and the warm air mechanism 72 provides warm air.

In addition, in one embodiment, the water suction mechanism 73 includes a water suction pump 56 fixedly connected to the upper end wall of the water cavity 18, a water suction pipe 61 is fixed to the lower end of the water suction pump 56, a driven cavity 58 is arranged in the water suction pump 56, a water suction cavity 62 with an upper end communicated with the water inlet of the pipeline 11 and a lower end communicated with the water suction pipe 61 is arranged in the left end wall of the driven cavity 58, a transmission shaft 59 with a left end penetrating through the left end wall of the water suction cavity 62 and a left end located in the driven cavity 58 is rotatably connected to the left end wall of the water suction cavity 62, a turbo fan 63 located in the water suction cavity 62 is fixed to the right end of the transmission shaft 59, a third bevel gear 60 located in the driven cavity 58 is fixed to the left end of the transmission shaft 59, and the temperature in the heat generating cavity 64 is adjusted by.

In addition, in one embodiment, the transmission mechanism 74 includes a first driven shaft 55 rotatably connected to the lower end wall of the transmission chamber 51, the lower end of the first driven shaft penetrates through the lower end wall of the transmission chamber 51 and is located in the driven chamber 58, a fourth bevel gear 54 which is positioned in the transmission cavity 51 and meshed with the second bevel gear 52 is fixed at the upper end of the first driven shaft 55, a fifth bevel gear 57 which is positioned in the driven cavity 58 and meshed with the third bevel gear 60 is fixed at the lower end of the first driven shaft 55, the upper end wall of the transmission cavity 51 is rotatably connected with a second driven shaft 25, the upper end of the second driven shaft penetrates through the upper end wall of the transmission cavity 51 and is positioned in the driving cavity 42, a sixth bevel gear 44 which is positioned in the driving cavity 42 and meshed with the first bevel gear 43 is fixed at the upper end of the second driven shaft 25, a seventh bevel gear 50 which is positioned in the transmission cavity 51 and meshed with the second bevel gear 52 is fixed at the lower end of the second driven shaft 25.

Sequence of mechanical actions of the whole device:

in the initial state, the magnetic coil 34 is not electrified, the spring 38 is in a relaxed state, the elastic force of the spring 38 is slightly smaller than the magnetic attraction force generated by the magnetic coil 34, the water cavity 18 is filled with water, the tapered friction wheel 41 is a tapered friction wheel with a smaller left end diameter and a larger right end diameter, the inductor 65 is electrically connected with an external power supply, the motor 45 is electrically connected with the external power supply, and the friction wheel 48 is positioned at the rightmost end of the tapered friction wheel 41 and is meshed with the tapered friction wheel;

when the device is started, the motor 45 drives the spline housing 47 to drive the friction wheel 48 to rotate through the power shaft 37, and then the conical friction wheel 41 drives the conical friction wheel shaft 40 to rotate, and further the first bevel gear 43 drives the sixth bevel gear 44 to rotate, the seventh bevel gear 50 is driven to rotate by the second driven shaft 25, so that the second bevel gear 52 drives the fan 24 to rotate out by the fan shaft 53, so as to convey the temperature generated in the heating cavity 64 to the outside through the metal heat absorption net 28 and the filter screen 22 for heating, and the fourth bevel gear 54 is driven to rotate by the second bevel gear 52, the fifth bevel gear 57 is driven by the first driven shaft 55 to rotate, so that the third bevel gear 60 drives the turbo fan 63 to rotate by the transmission shaft 59, so that the water in the water cavity 18 circulates in the inner wall of the heat generating cavity 64 through the pipeline 11;

when the thermal image display monitor 27 detects that the temperature in the heating cavity 64 is too high, the current is increased to increase the magnetism of the electromagnet 35 through the sensing wire 26, the magnetic induction strength is controlled in real time through the magnetic coil 34, the metal magnetic block 33 moves on the copper guide tube 32, the pulling rope 31 pulls the sliding block 49 to drive the friction wheel 48 to move, the friction wheel 48 drives the fixed block 39 compression spring 38 to move on the power shaft 37 through the spline housing 47, so that the meshing diameter ratio of the friction wheel 48 and the tapered friction wheel 41 is adjusted, the tapered friction wheel 41 drives the first bevel gear 43 to rotate through the tapered friction wheel shaft 40, the sixth bevel gear 44 drives the seventh bevel gear 50 to rotate through the second driven shaft 25, the second bevel gear 52 drives the fan 24 to rotate through the fan shaft 53, so that the rotating speed of the fan 24 is adjusted, and the negative influence caused by the hot air with too high temperature is further controlled to be reduced, and the second bevel gear 52 makes the fourth bevel gear 54 drive the fifth bevel gear 57 to rotate through the first driven shaft 55, and further makes the third bevel gear 60 drive the turbo fan 63 to rotate through the transmission shaft 59, so that the water in the water cavity 18 enters the pipeline 11 through the water suction pipe 61 and the water suction cavity 62, and further adjusts the speed of the pipeline 11 circulating and flowing in the metal pipe 14 and the end wall of the heat generating cavity 64 by controlling the rotation speed of the turbo fan 63, so that the temperature in the heat generating cavity 64 can be kept constant for a long time, and when the temperature is too high, the magnetic coil 34 generates a large magnetic field, so that the metal magnet 33 is attracted with the electromagnet 35, and further the metal magnet 33 pulls the pull rope 31 to drive the friction wheel 48 to contact with the left end wall of the adjustment cavity 36 through the slider 49, so that the friction wheel 48 is disengaged from the tapered friction wheel 41, and further the sensor 65 detects that the friction wheel 48 disconnects the power supply of the device, thereby saving the waste of use cost caused by the excessive heat energy emission of the device and the damage caused by the scald to human body and the fire of inflammable materials caused by overhigh temperature.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims

1. The utility model provides a warm stove thermal imagery detects automatic temperature regulating device based on image data handles, includes the casing, its characterized in that: a heating cavity is arranged in the shell, a heating mechanism is arranged in the heating cavity, a temperature control mechanism is arranged on the upper side of the shell, a warm air mechanism is arranged on the lower side of the temperature control mechanism, a water absorption mechanism is arranged on the lower side of the warm air mechanism, and a transmission mechanism is connected among the warm air mechanism, the water absorption mechanism and the temperature control mechanism;

the temperature control mechanism comprises a thermal image display monitor fixed on the upper end face of the shell, a magnetic sensing cavity is arranged in the left end wall of the heating cavity, an electromagnet is fixed on the right end wall of the magnetic sensing cavity, the right end face of the electromagnet is electrically connected with a sensing wire with the lower end face of the thermal image display monitor, a magnetic coil is fixedly connected with the left end face of the electromagnet, one end of the magnetic coil, which is far away from the electromagnet, penetrates through the upper end face of the magnetic sensing cavity and is electrically connected with the lower end face of the thermal image display monitor, the temperature of the heating mechanism is detected and controlled through the thermal image display monitor, and therefore the temperature is automatically adjusted and controlled through the; electromagnet right-hand member face is fixed with and runs through magnetic coil with the fixed copper pipe of chamber left end wall is felt to magnetism, sliding connection has the metal magnetic path on the copper pipe, be equipped with in the chamber lower extreme wall is felt to magnetism and adjust the chamber, adjust chamber upper end wall be fixed with adjust the inductor of chamber left end wall contact, be equipped with the drive chamber in the chamber right-hand member wall, drive chamber right-hand member wall is fixed with the motor, motor left end face power connection has the left end to run through drive chamber left end wall and left end are located adjust the intracavity with adjust the chamber left end wall and rotate the power shaft of connecting, splined connection has the spline housing on the power shaft, be fixed with the friction pulley on the spline housing, friction pulley left end face is fixed with the fixed block, be equipped with the annular spout that the opening is towards left in the friction pulley, sliding connection has the slider in the annular spout, slider left end face is fixed with the left end runs through adjust chamber left end face and be located in the magnetism feel the The right end face of the adjusting cavity is rotatably connected with a conical friction wheel shaft which is positioned on the lower side of the power shaft, penetrates through the right end wall of the adjusting cavity and is positioned in the driving cavity, a conical friction wheel which is positioned in the adjusting cavity and is meshed with the friction wheel is fixed on the conical friction wheel shaft, and a first bevel gear which is positioned in the driving cavity is fixed at the right end of the conical friction wheel; the heating mechanism comprises an isolation net embedded on the right end face of the shell, metal tubes are fixed on the upper end wall and the lower end wall of the center of the heating cavity, the upper and lower end walls of the heating cavity are also fixed with heating tubes which are symmetrical left and right based on the metal tubes, a pipeline which vertically surrounds the heating cavity and penetrates through the metal tubes is arranged in the shell, a base is arranged at the lower side of the shell, the shell and the base are connected with a sleeve, a water cavity is arranged in the base, a drain pipe with the right end penetrating through the right end wall of the water cavity and the right end positioned outside is fixed on the right end wall of the water cavity, a water inlet pipe with the left end penetrating through the left end wall of the water cavity and the left end positioned outside is fixed on the left end wall of the water cavity, valves are fixedly arranged at the external ends of the water inlet pipe and the water drain pipe, and a water drain pipe with the upper end penetrating through the upper end wall of the water cavity and the sleeve and communicated with the water outlet of the pipeline is fixed at the upper end wall of the water cavity; the warm air mechanism comprises a warm air cavity arranged in the lower end wall of the adjusting cavity, the warm air cavity is communicated with the outside through a filter screen, the warm air cavity is communicated with the heating cavity through a metal heat absorption net, fixing columns are fixed on the upper end wall and the lower end wall of the warm air cavity, a transmission cavity is arranged in each fixing column, the left end wall of each transmission cavity is rotatably connected with a fan shaft, the left end of each fan shaft penetrates through the left end wall of each transmission cavity and is located in the corresponding warm air cavity, a second bevel gear located in each transmission cavity is fixed at the right end of each fan shaft, a fan located in each warm air cavity is fixed at the left end of each fan shaft, and the warm air mechanism provides; the water sucking mechanism comprises a water sucking pump fixedly connected to the upper end wall of the water cavity, a water sucking pipe is fixed at the lower end of the water sucking pump, a driven cavity is arranged in the water sucking pump, a water sucking cavity with the upper end communicated with the water inlet of the pipeline and the lower end communicated with the water sucking pipe is arranged in the left end wall of the driven cavity, the left end wall of the water sucking cavity is rotatably connected with a transmission shaft with the left end penetrating through the left end wall of the water sucking cavity and the left end positioned in the driven cavity, a turbo fan positioned in the water sucking cavity is fixed at the right end of the transmission shaft, a third bevel gear positioned in the driven cavity is fixed at the left end of the transmission shaft, and the temperature in the heating cavity is; the transmission mechanism comprises a first driven shaft, wherein the lower end wall of the lower end of the transmission cavity is rotatably connected with the transmission cavity, the lower end of the first driven shaft penetrates through the lower end wall of the transmission cavity, the lower end of the first driven shaft is located in the driven cavity, a fourth bevel gear is fixed at the upper end of the first driven shaft and is located in the transmission cavity and meshed with the second bevel gear, a fifth bevel gear is fixed at the lower end of the first driven shaft and is located in the driven cavity and meshed with the third bevel gear, the upper end wall of the transmission cavity is rotatably connected with a second driven shaft, the upper end of the second driven shaft penetrates through the upper end wall of the transmission cavity, the upper end of the second driven shaft is located in the driving cavity and meshed with the first bevel gear, and a seventh bevel gear is fixed at the lower end of the.