CN220629202U - Portable heat supply power generation device - Google Patents

Abstract

A portable heat supply power generation device belongs to the technical field of thermoelectricity. In order to solve the problems that the integrated graphite pad is not easy to fix and easy to generate channeling due to softer texture. The utility model comprises a combustor, a heat energy carrier, a power generation unit, a radiator, a casing and an oxygen supply and heat dissipation module, wherein the combustor is arranged in the heat energy carrier, the power generation unit and the radiator are circumferentially arranged on the outer annular wall of the heat energy carrier, each group of power generation units comprises an integrated graphite pad, a power generation module, a power generation unit fixing frame and a fixing assembly, and the power generation unit fixing frame is arranged between the two integrated graphite pads and is paved on the outer wall of the heat energy carrier along the axial direction of the heat energy carrier; the power generation unit fixing frame is provided with mounting openings, one power generation module is mounted in each mounting opening, and the radiator presses the integrated graphite pad, the plurality of power generation modules and the power generation unit fixing frame on the heat energy carrier. The utility model is mainly used for generating electricity and supplying heat.

Description

Portable heat supply power generation device

Technical Field

The utility model belongs to the technical field of thermoelectricity, and particularly relates to a portable heat supply and power generation device.

Background

In the open air, fuel oil heating equipment is generally adopted for heating, for example, chinese patent No. CN208393038U discloses a fuel oil heater which comprises a vaporization mechanism, a combustion mechanism, a blowing mechanism and a heat exchange mechanism; but the blower mechanism needs an additional external power supply to drive, no commercial power exists outdoors, a storage battery is needed to supply power, and the storage battery has the defects of large volume, large weight, small electric quantity storage, low charging speed and the like and has great defects.

The existing heat supply power generation device adopts fuel combustion to generate heat and supply power, and solves the defect of power supply of a storage battery, for example, a portable heat supply power generation device disclosed in China patent 2023204420887 is characterized in that fuel is conveyed into a combustor through an external oil supply system, then ignited by an igniter, a combustion-supporting impeller rotates to provide oxygen, the fuel is combusted in the combustor to provide heat energy, the heat is conducted to a heat energy carrier, the heat energy carrier is conducted to a thermoelectric power generation module through an integrated graphite pad, a radiator is arranged above the thermoelectric power generation module, so that the upper surface and the lower surface of the thermoelectric power generation module generate temperature difference, the thermoelectric power generation module generates electricity under the condition of not influencing the heat energy supply, the equipment can be used, and a starting battery can be recharged, so that the purpose of continuous work is achieved. However, the above patent suffers from several drawbacks: firstly, the integrated graphite pad is not easy to fix because of softer texture, and the problem of position shifting is easy to occur; secondly, the generated electric energy is not effectively managed, so that energy waste is caused.

Disclosure of Invention

The technical problems to be solved by the utility model are as follows: the existing fuel oil heater needs an additional external power supply, and the disadvantage of adopting a storage battery to supply power is large; further provided is a portable heat supply and power generation device.

The utility model adopts the technical scheme for solving the technical problems that:

the portable heat supply power generation device comprises a combustor, a heat energy carrier, a plurality of groups of power generation units, a plurality of radiators, a casing and an oxygen supply heat dissipation module, wherein the combustor, the heat energy carrier, the plurality of groups of power generation units, the plurality of radiators and the oxygen supply heat dissipation module are arranged in the casing; the oxygen supply and heat dissipation module is arranged at one side of the heat energy carrier and provides oxygen for the burner;

each group of power generation units comprises two integrated graphite pads, a plurality of power generation modules, a power generation unit fixing frame and a fixing assembly, wherein the two integrated graphite pads are arranged up and down oppositely, and the power generation unit fixing frame is arranged between the two integrated graphite pads and is paved on the outer wall of the heat energy carrier along the axis direction of the heat energy carrier; a plurality of mounting openings are formed in the power generation unit fixing frame along the length direction of the power generation unit fixing frame, a power generation module is mounted in each mounting opening, a separation belt is arranged between two adjacent mounting openings, a through hole is drilled in each separation belt, and two through holes are drilled at two ends of the power generation unit fixing frame along the length direction; the radiator is fixed on the heat energy carrier through the fixing component, and the integrated graphite pad, the plurality of power generation modules and the power generation unit fixing frame are pressed on the heat energy carrier.

Preferably, the radiator is a heat exchange fin plate, the heat exchange fin plate is composed of a horizontal pressing plate and a plurality of heat exchange fins which are vertically arranged on the horizontal pressing plate side by side, and the horizontal pressing plate is pressed on the upper surface of the power generation module and is fixed on the heat energy carrier through a fixing component.

Preferably, the fixing component comprises two long limit outer hexagonal double-ended screws, two short limit outer hexagonal double-ended screws, a plurality of nuts, a plurality of disc springs, a straight-line pressing sheet and an L-shaped pressing sheet, wherein the middle positions of the long limit outer hexagonal double-ended screws and the short limit outer hexagonal double-ended screws are respectively provided with a hexagonal abutting column; the lower threaded columns of the two long limiting outer hexagonal double-headed screws respectively penetrate through the through holes at two ends of the fixed frame of the power generation unit and are connected to the heat energy carrier in a threaded manner, the lower threaded columns of the two short limiting outer hexagonal double-headed screws respectively penetrate through the through holes at the middle part of the fixed frame of the power generation unit and the integrated graphite pad and are connected to the heat energy carrier in a threaded manner, the radiator is provided with two through holes along the length direction of the radiator, the radiator is sleeved on the upper threaded columns of the two short limiting outer hexagonal double-headed screws through the through holes and is fixed through nuts and three disc springs, the linear pressing sheet and the L-shaped pressing sheet are sleeved on the upper threaded columns of the two long limiting outer hexagonal double-headed screws respectively and are fixed through the nuts, one end of the linear pressing sheet or one end of the L-shaped pressing sheet is abutted to the heat energy carrier, and the other end of the linear pressing sheet or the other end of the L-shaped pressing sheet is abutted to the radiator.

Preferably, the oxygen supply and heat dissipation module comprises a driving motor, a combustion-supporting impeller and a heat dissipation impeller, wherein the combustion-supporting impeller and the heat dissipation impeller are respectively arranged at the output ends of the two ends of the driving motor, and the size of the combustion-supporting impeller is smaller than that of the heat dissipation impeller.

Preferably, the heat supply power generation device further comprises an electric energy management system, the electric energy management system comprises a battery pack and an electric energy distribution plate, and the electric energy distribution plate is electrically connected with the electric equipment in the plurality of groups of power generation units, the battery pack and the heat supply power generation device respectively.

Preferably, the heat supply power generation device further comprises a circulating heat exchange system; the circulating heat exchange system comprises a fixing plate, an air inlet pipe and an exhaust pipe, wherein two through holes are arranged on the fixing plate side by side, one end of the air inlet pipe is connected to one of the through holes on the fixing plate, the other end of the air inlet pipe is connected to the cold air inlet end of the shell, one end of the exhaust pipe is connected to the other through hole on the fixing plate, and the other end of the exhaust pipe is connected to the hot air exhaust end of the shell; the fixing piece is arranged on a space to be heated.

Preferably, the heat energy carrier is inserted with a curved smoke exhaust pipe which sequentially penetrates through the shell and the radiator, and the outlet end of the curved smoke exhaust pipe is sequentially connected with a silencing section, a first straight pipe section and a second straight pipe section, and the silencing section is used for silencing gas.

Preferably, the first straight pipe section and the second straight pipe section are respectively sleeved with a heat insulation pipe, and the two heat insulation pipes are connected together in an inserting mode.

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

1. this application is through outside oil feeding system, in carrying the combustor to the fuel, rethread igniter ignites, combustion-supporting impeller rotation provides oxygen, the fuel is in the combustor internal combustion, provide heat energy, heat conduction is to heat energy carrier, heat energy carrier is carrying for thermoelectric generation module through integral type graphite pad conduction, be the radiator above the thermoelectric generation module, lead to thermoelectric generation module upper and lower surface to produce the difference in temperature, under the condition that does not influence and provide heat energy, make thermoelectric generation module send out the electric quantity, the electric quantity that sends out is carried to electric energy management system, electric energy management system is in distributing the equipment to the electric quantity and is used, can also return to charge lithium cell group, reach continuous operation's purpose.

2. According to the radiator, all parts are fixed by adopting the outer hexagonal double-ended screw, the outer hexagonal double-ended screw comprises a short limiting outer hexagonal double-ended screw and a long limiting outer hexagonal double-ended screw, the short limiting outer hexagonal double-ended screw has a yielding function, so that the radiator is prevented from being jacked, and the threaded part is inserted into the radiator; the long limiting outer hexagonal double-headed screw is long, and when the pressing sheets are pressed, the pressing sheets just prop against the end face of the hexagon to play a limiting role, so that the pressing force of each pressing sheet is ensured to be consistent.

3. Because the power generation unit is formed by adopting a plurality of thermoelectric power generation modules in series connection, the shape is irregular, and the power generation unit is difficult to fix; each module of the power generation unit is fixed through the power generation unit fixing frame, the integrated graphite pad and the power generation unit fixing frame are fixed on the heat energy carrier through the outer hexagonal double-head screws, and then the power generation unit is placed into the power generation unit fixing frame groove, so that the power generation unit is fixed in a positioning manner, the problem that the power generation unit is not easy to fix in a positioning manner is solved, and the efficiency of installation production is improved to a great extent.

4. The integrated graphite pads are arranged on the upper surface and the lower surface of the power generation module, the integrated graphite pads are soft in texture, soft filling between the heat energy carrier and the power generation module and between the power generation module and the radiator is realized, gaps are reduced, the contact area is increased, the heat conduction speed is high, the heat conduction quantity is large, and the optimal heat conduction performance is achieved; meanwhile, the integrated graphite pad has good longitudinal heat conduction performance, and the temperature of the high-temperature position of the integrated graphite pad can be longitudinally conducted to the low-temperature position, so that the purpose of temperature equalization is achieved, and the heat conduction performance is improved.

5. According to the thermoelectric generation module, the heat dissipation of the upper surface of the thermoelectric generation module is realized through the two stages of heat exchange fin plates, so that the thermoelectric generation module has a better heat dissipation effect, and the power generation efficiency of the thermoelectric generation module is improved; the heat dissipated by the heat exchange fin plates I and II is used for heating outdoors and various places, and the energy is fully utilized.

6. The power generation unit of this application sends out the electric quantity and carries to electric energy management system, and electric energy management system rethread judges and distributes, carries electric energy to the power consumption part and recharges lithium cell group, and lithium cell group is that many lithium cell combination forms, and during the deficient electricity, can pull out and take commercial power to charge and on-vehicle charge, convenient to use.

Drawings

The accompanying drawings are included to provide a further understanding of the utility model, and are incorporated in and constitute a part of this application.

FIG. 1 is a schematic view of a structure of a power generation unit fixing frame;

FIG. 2 is a schematic diagram of the overall structure of a heating power plant;

FIG. 3 is an assembly view of a thermal energy carrier, a power generation unit, and a heat sink;

FIG. 4 is a schematic illustration of the mounting of the securing assembly to the thermal energy carrier;

FIG. 5 is an enlarged view of a portion of FIG. 1 at A;

FIG. 6 is a side cross-sectional view of a heating power plant;

FIG. 7 is a side view of a heat sink;

FIG. 8 is a schematic diagram of a power management system;

FIG. 9 is a schematic view of the structure of the nut;

FIG. 10 is a schematic view of the structure of a disc spring;

FIG. 11 is a schematic view of the structure of a short limit external hexagonal double-ended screw;

FIG. 12 is a schematic view of the structure of a long limit external hexagonal double-ended screw;

FIG. 13 is a top view of an in-line tablet;

FIG. 14 is a side view of an in-line compression;

FIG. 15 is a top view of an L-shaped preform;

FIG. 16 is a side view of an L-shaped tablet;

FIG. 17 is a schematic diagram of a heating power plant for providing heat to the interior of a vehicle;

FIG. 18 is a schematic structural view of a stator;

fig. 19 is a schematic view of the structure of the exhaust duct.

Reference numerals illustrate: 1-a burner; 2-heat energy carrier; 2-1-bending a smoke exhaust pipe; 2-2-a silencing section; 2-3-a first straight pipe section; 2-4-second straight pipe sections; 2-5-heat insulation pipes; 3-a power generation unit; 3-1-integral graphite pad; 3-2-power generation module; 3-3-a power generation unit fixing frame; 3-3-1-mounting opening; 3-3-2-separator; 3-3-3-through holes; 3-4-securing assembly; 3-4-1-long limiting outer hexagonal double-ended screws; 3-4-2-short limiting outer hexagonal double-ended screws; 3-4-3-nut; 3-4-4-disc springs; 3-4-5-straight tabletting; 3-4-6-L shaped tabletting; 4-a heat sink; 4-1-horizontal pressing plates; 4-2-heat exchange fins; 5-a casing; 6-an oxygen supply heat dissipation module; 6-1-driving motor; 6-2-combustion-supporting impellers; 6-3-heat dissipation impellers; 7-a power management system; 7-1-battery pack; 7-2-an electric energy distribution plate; 8-a circulating heat exchange system; 8-1-fixing sheets; 8-2-exhaust duct; 8-3-air inlet pipeline.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions in the embodiments will be clearly and completely described with reference to the accompanying drawings in the embodiments of the present utility model, and the following embodiments are used to illustrate the present utility model, but are not intended to limit the scope of the present utility model.

Referring to fig. 1 to 19, an embodiment of the present application provides a portable heat supply and power generation device, which includes a burner 1, a heat carrier 2, a plurality of groups of power generation units 3, a plurality of heat sinks 4, a casing 5, an oxygen supply and heat dissipation module 6, an electric energy management system 7 and a circulation heat exchange system 8;

referring to fig. 2, the burner 1 is inserted into the heat carrier 2 and is connected with the heat carrier 2 through a screw, and the burner 1 is connected with an oil pipe of an oil supply system and is provided with an ignition plug; the fuel supplied by the fuel supply system is combusted in the burner 1 by ignition of the ignition plug to generate heat.

Referring to fig. 2, the heat energy carrier 2 is in a barrel-shaped structure with an opening at one end, a plurality of groups of power generation units 3 and a plurality of groups of heat radiators 4 are sequentially and circumferentially and uniformly arranged on the outer annular wall of the heat energy carrier 2 from inside to outside, and each group of power generation units 3 is corresponding to one heat radiator 4; the heat energy carrier 2 is used for realizing heat exchange between the burner 1 and the power generation unit 3; a plurality of heat exchange fins are uniformly arranged on the inner wall of the heat energy carrier 2 along the circumferential direction, and the length direction of the heat exchange fins is the same as the length direction of the burner 1; the heat exchange fins are used for increasing the heat exchange area of the heat energy carrier 2 and the burner 1 and increasing the heat exchange efficiency.

Furthermore, the heat energy carrier 2 is designed into a hexagonal prism shape, so that the installation of the power generation units 3 and the heat radiator 4 is facilitated, wherein a plurality of screw holes are formed in each plane plate of the outer annular wall of the heat energy carrier 2 along the length direction, and each group of power generation units 3 and the heat radiator 4 are installed at the plane plates through fixing components; the thermal energy carrier 2 has small overall volume and large surface area, and can be assembled with more power generation units 3 to generate more electric energy.

Referring to fig. 3, each group of power generation units 3 comprises two integrated graphite pads 3-1, a plurality of power generation modules 3-2, a power generation unit fixing frame 3-3 and a fixing assembly 3-4 which are arranged up and down in an opposite manner, wherein the power generation unit fixing frame 3-3 is arranged between the two integrated graphite pads 3-1 and is paved on the outer wall of the heat energy carrier 2 along the axis direction of the heat energy carrier 2; the heat radiator 4 is fixed on the heat energy carrier 2 through a fixing component 3-4, and presses the integrated graphite pad 3-1, the plurality of power generation modules 3-2 and the power generation unit fixing frame 3-3 on the heat energy carrier 2.

In this embodiment, the power generation module 3-2 is a thermoelectric power generation module, because the integrated graphite pad 3-1 has a heat conduction function, the integrated graphite pad 3-1 on the upper surface of the power generation module 3-2 is used for conducting cold energy transferred by the radiator 4, the integrated graphite pad 3-1 on the lower surface of the power generation module 3-2 is used for conducting heat energy emitted by the burner 1 in the heat energy carrier 2, and the radiator 4 is used for transferring the cold energy, so that the heat on the upper surface and the lower surface of the thermoelectric power generation module are different, and power generation is realized through temperature difference; the power generation module 3-2 is connected with the power management system 7 through a power line.

In the embodiment, the integrated graphite pad 3-1 is soft in texture, so that soft filling between the heat energy carrier 2 and the power generation module 3-2 is realized, gaps are reduced, the contact area is increased, the heat conduction speed is high, the heat conduction quantity is large, and the optimal heat conduction performance is achieved; meanwhile, the integrated graphite pad 3-1 has good longitudinal heat conduction performance, and the temperature of the high-temperature position of the integrated graphite pad 3-1 can be longitudinally conducted to the low-temperature position, so that the purpose of temperature equalization is achieved, and the heat conduction performance is improved. Because the integral graphite pad 3-1 is soft in texture, and the power generation modules 3-2 are multiple, the power generation modules 3-2 are easy to generate a position shifting phenomenon and are not easy to install in the installation process of the power generation modules 3-2 and the radiator 4, the power generation modules 3-2 are fixed firstly by the power generation unit fixing frame 3-3, so that the function of positioning the power generation modules 3-2 is realized, and then the radiator 4 is fixed.

Further, referring to fig. 3, the fixing component 3-4 includes two long limit outer hexagonal double-ended screws 3-4-1, two short limit outer hexagonal double-ended screws 3-4-2, a plurality of nuts 3-4-3, a plurality of disc springs 3-4-4, a straight-line-shaped pressing piece 3-4-5 and an L-shaped pressing piece 3-4-6, wherein the middle position of the long limit outer hexagonal double-ended screws 3-4-1 and the middle position of the short limit outer hexagonal double-ended screws 3-4-2 are respectively provided with a hexagonal abutting column; the lower threaded columns of the two long limit outer hexagonal double-headed screws 3-4-1 respectively penetrate through holes 3-3-3 at two ends of the power generation unit fixing frame 3-3 and are screwed on the heat energy carrier 2, the lower threaded columns of the two short limit outer hexagonal double-headed screws 3-4-2 respectively penetrate through the through holes 3-3-3 at the middle part of the power generation unit fixing frame 3-3 and the integrated graphite gasket 3-1 and are screwed on the heat energy carrier 2, the radiator 4 is provided with two through holes along the length direction, the radiator 4 is sleeved on the upper threaded columns of the two short limit outer hexagonal double-headed screws 3-4-2 through the through holes, and is fixed through nuts 3-4-3 and three disc springs 3-4-4, the linear pressing sheet 3-4-5 and the L-4-6 are respectively sleeved on the upper threaded columns of the two long limit outer hexagonal double-headed screws 3-4-1 and are fixed through the nuts 3-4-3, the linear pressing sheet 3-4-5 or the L-4-6 is abutted against one end of the heat energy carrier 3-4-4, and the other end of the linear pressing sheet 3-4-6 is abutted against one end of the heat energy carrier 3-4-4.

In the embodiment, after the integrated graphite gasket 3-1, the plurality of power generation modules 3-2 and the power generation unit fixing frame 3-3 are placed, the long limit outer hexagonal double-headed screw 3-4-1 and the two short limit outer hexagonal double-headed screws 3-4-2 are screwed on the heat energy carrier 2, wherein the two short limit outer hexagonal double-headed screws 3-4-2 are screwed on screw holes at the middle position of the heat energy carrier 2, and hexagonal abutting columns on the short limit outer hexagonal double-headed screws 3-4-2 are abutted on the integrated graphite gasket 3-1 and the power generation unit fixing frame 3-3, so that the fixing of the two positions is realized; meanwhile, the two short limiting outer hexagonal double-headed screws 3-4-2 also have a separation effect on the power generation module 3-2, so that the position shifting of the power generation module 3-2 is prevented; the long limiting outer hexagonal double-headed screw 3-4-1 is in threaded connection with screw holes at two ends of the heat energy carrier 2 and is positioned at two sides of the radiator 4. Referring to fig. 1, the heat radiator 4 is a heat exchange fin plate, the heat exchange fin plate is composed of a horizontal pressing plate 4-1 and a plurality of heat exchange fins 4-2 vertically arranged on the horizontal pressing plate 4-1 side by side, and the horizontal pressing plate 4-1 is pressed on the upper surface of the power generation module 3-2 and is fixed on the heat energy carrier 2 through a fixing component 3-4.

Referring to fig. 2, the oxygen supply and heat dissipation module 6 is disposed at one side of the heat carrier 2 and provides oxygen for the burner 1; the oxygen supply and heat dissipation module 6 comprises a driving motor 6-1, a combustion-supporting impeller 6-2 and a heat dissipation impeller 6-3, wherein the combustion-supporting impeller 6-2 and the heat dissipation impeller 6-3 are respectively arranged at the output ends of the two ends of the driving motor 6-1, and the size of the combustion-supporting impeller 6-2 is smaller than that of the heat dissipation impeller 6-3.

In the present embodiment, in order to ensure the normal combustion of the burner 1, the air outside the casing 5 is brought into the casing 5 and the burner 1 by the rotation of the combustion-supporting impeller 6-2, so that the normal combustion of the fuel in the burner 1 is realized; the heat dissipation impeller 6-3 brings air into the shell 5 and flows through the heat exchange fins 4-2 to realize the cooling of the heat exchange fins 4-2.

Referring to fig. 8, the power management system 7 includes a battery 7-1 and a power distribution board 7-2, the power distribution board 7-2 is electrically connected with a plurality of power generating units 3, the battery 7-1 and some electric devices in the heat supply power generating device, the power distribution board 7-2 is used for redistribution of power, a part of the power is mainly used for supplying power to the electric devices in the heat supply power generating device, the redundant power is used for recharging the battery, and if the rest of the power is available, the power can be supplied by connecting with external electric devices.

Referring to fig. 17, the casing 5 has a cylindrical structure, and a port of one end of the casing 5 close to the oxygen supply and heat dissipation module 6 is used as a cool air inlet end, and the other end is used as a hot air exhaust end and is used for connecting the circulating heat exchange system 8; the circulating heat exchange system 8 comprises a fixing plate 8-1, an air inlet pipe 8-2 and an exhaust pipe 8-3, wherein two through holes are arranged on the fixing plate 8-1 side by side, one end of the air inlet pipe 8-2 is connected to one of the through holes on the fixing plate 8-1, the other end of the air inlet pipe 8-2 is connected to the cold air inlet end of the casing 5, one end of the exhaust pipe 8-3 is connected to the other through hole on the fixing plate 8-1, and the other end of the exhaust pipe 8-3 is connected to the hot air exhaust end of the casing 5; the fixing piece 8-1 is arranged on a space to be heated, such as a tent or a vehicle window opening position, the oxygen supply and heat dissipation module 6 sucks cool air in the space to be heated from the air inlet pipe 8-2 into the shell 5, and pushes hot air into the vehicle or the tent from the exhaust pipe 8-3 to realize heating.

Further, a curved smoke exhaust pipe 2-1 sequentially penetrating through the shell 5 and the radiator 4 is inserted into the heat energy carrier 2, a silencing section 2-2, a first straight pipe section 2-3 and a second straight pipe section 2-4 are sequentially connected to the outlet end of the curved smoke exhaust pipe 2-1, the first straight pipe section 2-3 and the second straight pipe section 2-4 are used for exhausting tail gas and waste gas, and silencing cotton is arranged in the silencing section 2-2 and used for silencing gas; wherein the first straight pipe section 2-3 and the second straight pipe section 2-4 are connected together in a plugging manner, and the first straight pipe section 2-3 can be inserted into the second straight pipe section 2-4, so that the storage space is reduced.

Furthermore, the first straight pipe section 2-3 and the second straight pipe section 2-4 are respectively sleeved with a heat insulation pipe 2-5, and the two heat insulation pipes 2-5 are connected together in a plugging manner so as to prevent the outer walls of the first straight pipe section 2-3 and the second straight pipe section 2-4 from being hot and scalding a user.

Although the utility model herein has been described with reference to particular embodiments, it is to be understood that these embodiments are merely illustrative of the principles and applications of the present utility model. It is therefore to be understood that numerous modifications may be made to the illustrative embodiments and that other arrangements may be devised without departing from the spirit and scope of the present utility model as defined by the appended claims. It should be understood that the different dependent claims and the features described herein may be combined in ways other than as described in the original claims. It is also to be understood that features described in connection with separate embodiments may be used in other described embodiments.

Claims (8)

1. The utility model provides a portable heat supply power generation facility which characterized in that: the heat energy carrier comprises a combustor (1), a heat energy carrier (2), a plurality of groups of power generation units (3), a plurality of radiators (4), a casing (5) and an oxygen supply heat dissipation module (6), wherein the combustor (1), the heat energy carrier (2), the plurality of groups of power generation units (3), the plurality of radiators (4) and the oxygen supply heat dissipation module (6) are arranged in the casing (5), the combustor (1) is coaxially arranged in the heat energy carrier (2), the plurality of groups of power generation units (3) and the plurality of groups of radiators (4) are sequentially and circumferentially and uniformly arranged on the outer annular wall of the heat energy carrier (2) from inside to outside, and each group of power generation units (3) corresponds to one group of radiators (4); the oxygen supply and heat dissipation module (6) is arranged at one side of the heat energy carrier (2) and provides oxygen for the burner (1);

each group of power generation units (3) comprises two integrated graphite pads (3-1), a plurality of power generation modules (3-2), a power generation unit fixing frame (3-3) and a fixing assembly (3-4) which are arranged up and down in an opposite mode, wherein the power generation unit fixing frame (3-3) is arranged between the two integrated graphite pads (3-1) and is paved on the outer wall of the heat energy carrier (2) along the axis direction of the heat energy carrier (2); a plurality of mounting openings (3-3-1) are formed in the power generation unit fixing frame (3-3) along the length direction of the power generation unit fixing frame, a power generation module (3-2) is mounted in each mounting opening (3-3-1), a separation belt (3-3-2) is arranged between two adjacent mounting openings (3-3-1), a through hole (3-3-3) is drilled in each separation belt (3-3-2), and two through holes (3-3-3) are drilled at two ends of the power generation unit fixing frame (3-3) along the length direction; the radiator (4) is fixed on the heat energy carrier (2) through the fixing component (3-4), and presses the integrated graphite pad (3-1), the plurality of power generation modules (3-2) and the power generation unit fixing frame (3-3) on the heat energy carrier (2).

2. A portable heating power generation apparatus according to claim 1, wherein: the radiator (4) is a heat exchange fin plate, the heat exchange fin plate is composed of a horizontal pressing plate (4-1) and a plurality of heat exchange fins (4-2) which are vertically arranged on the horizontal pressing plate (4-1) side by side, and the horizontal pressing plate (4-1) is pressed on the upper surface of the power generation module (3-2) and is fixed on the heat energy carrier (2) through a fixing component (3-4).

3. A portable heating power generation apparatus according to claim 1, wherein: the fixing assembly (3-4) comprises two long limit outer hexagonal double-ended screws (3-4-1), two short limit outer hexagonal double-ended screws (3-4-2), a plurality of nuts (3-4-3), a plurality of disc springs (3-4-4), a straight-line tabletting (3-4-5) and an L-shaped tabletting (3-4-6), wherein the middle position of the long limit outer hexagonal double-ended screws (3-4-1) and the middle position of the short limit outer hexagonal double-ended screws (3-4-2) are provided with hexagonal butt columns; the lower threaded columns of the two long limit outer hexagonal double-headed screws (3-4-1) respectively penetrate through holes (3-3-3) at two ends of the power generation unit fixing frame (3-3) and are screwed on the heat energy carrying device (2), the lower threaded columns of the two short limit outer hexagonal double-headed screws (3-4-2) respectively penetrate through the through holes (3-3-3) and the integrated graphite pad (3-1) at the middle part of the power generation unit fixing frame (3-3) and are screwed on the heat energy carrying device (2), the radiator (4) is provided with two through holes along the length direction, the radiator (4) is sleeved on the upper threaded columns of the two short limit outer hexagonal double-headed screws (3-4-2) through the through holes and is fixed through nuts (3-4-3) and three disc springs (3-4-4), the straight-shaped tabletting (3-4-5) and the L-shaped disc springs (3-4-6) are respectively sleeved on the two long limit outer hexagonal double-headed screws (3-4-1) and are screwed on the heat energy carrying device (2), the straight-shaped tabletting (3-4-4) is screwed on one end of the straight-shaped compression sheet (3-4-4) through the screw, the straight-shaped compression sheet is screwed on the straight-shaped compression sheet (3-4-6) and the straight-shaped compression sheet is fixed on the straight-line, the other end of the straight-shaped pressing piece (3-4-5) or the L-shaped pressing piece (3-4-6) is abutted against the radiator (4).

4. A portable heating power generation apparatus according to claim 1, wherein: the oxygen supply and heat dissipation module (6) comprises a driving motor (6-1), a combustion-supporting impeller (6-2) and a heat dissipation impeller (6-3), wherein the combustion-supporting impeller (6-2) and the heat dissipation impeller (6-3) are respectively arranged at the output ends of the two ends of the driving motor (6-1), and the size of the combustion-supporting impeller (6-2) is smaller than that of the heat dissipation impeller (6-3).

5. A portable heating power generation apparatus according to claim 1, wherein: the heat supply power generation device also comprises an electric energy management system (7), wherein the electric energy management system (7) comprises a battery pack (7-1) and an electric energy distribution plate (7-2), and the electric energy distribution plate (7-2) is electrically connected with a plurality of groups of power generation units (3), the battery pack (7-1) and electric equipment in the heat supply power generation device respectively;

the battery pack (7-1) is formed by connecting a plurality of lithium batteries in series.

6. A portable heating power generation apparatus according to claim 1, wherein: the heat supply power generation device also comprises a circulating heat exchange system (8); the circulating heat exchange system (8) comprises a fixing piece (8-1), an air inlet pipe (8-2) and an exhaust pipe (8-3), wherein two through holes are arranged on the fixing piece (8-1) side by side, one end of the air inlet pipe (8-2) is connected to one of the through holes on the fixing piece (8-1), the other end of the air inlet pipe (8-2) is connected to the cold air inlet end of the casing (5), one end of the exhaust pipe (8-3) is connected to the other through hole on the fixing piece (8-1), and the other end of the exhaust pipe (8-3) is connected to the hot air exhaust end of the casing (5); the fixing piece (8-1) is arranged on a space to be heated.

7. A portable heat and power generation device according to claim 6, wherein: the heat energy carrier (2) is inserted with a bent smoke exhaust pipe (2-1) which sequentially penetrates through the shell (5) and the radiator (4), the outlet end of the bent smoke exhaust pipe (2-1) is sequentially connected with a silencing section (2-2), a first straight pipe section (2-3) and a second straight pipe section (2-4), and the silencing section (2-2) is used for silencing gas.

8. A portable heating power generation apparatus in accordance with claim 7, wherein: the first straight pipe section (2-3) and the second straight pipe section (2-4) are respectively sleeved with a heat insulation pipe (2-5), and the two heat insulation pipes (2-5) are connected together in an inserting mode.