WO2013060096A1 - Fireplace with power generation device - Google Patents

Abstract

A fireplace with a power generation device comprises a casing (1, 1") and a fireplace body (2, 2"). A firebox (21, 21") is disposed in the fireplace body (2, 2"). An outer wall of the fireplace body (2, 2") is provided with a power generation assembly (5, 5', 5") capable of sensing a temperature difference between the outer wall of the fireplace body (2, 2") and the ambience and converting the temperature difference into power. The power generation assembly (5, 5', 5") has an output terminal capable of providing working power for a load.

Description

 Fireplace with power generating unit

Technical field

 The present invention relates to a fireplace, and more particularly to a fireplace with a power generating device. Background technique

 The fireplace is a safe and efficient heating device. In addition to the heating function, the fireplace can also be used as a decorative item for better viewing.

 Traditional fireplaces generally only have the function of heating and heating, and the functions are relatively simple. With the continuous development of electrification technology, people have put forward new requirements for the use of fireplaces. For example, the Chinese utility model patent "a fireplace" of the patent number ZL201120028963.4 (publication number CN201954648U) provides an electric fireplace, comprising a frame having a vent hole, a heating device disposed inside the frame, and further comprising An atomizing device inside the frame, and a water container for providing a water source required for the atomizing device; further comprising a pumping device disposed inside the frame and having a pulling force on the water mist formed by the atomizing device; and the pumping device The exhaust end is connected to the heating device.

 The fireplaces referred to in the above patents not only provide heating, but also have the function of humidifying, but the additional atomizing device, air extracting device and the like in the patent must be connected to the mains power source during use, resulting in the use of the fireplace and The inconvenience of installation, especially for fireplaces with outdoor or mobile use requirements, may not provide the mains to these additional electrical equipment (such as electronic control components, lights, exhausts or exhausts, etc.). Therefore, the fireplace in the outdoor or mobile use state can not achieve the corresponding additional functions; secondly, due to the instability of the power supply, there is a possibility of commercial power interruption, usually, the ignition device only needs a lower voltage drive to work, general The ignition device can be powered by the mains or battery-powered, but in the event of a power outage, the additional electrical equipment cannot continue to operate without the power supply, which greatly limits the use of the fireplace. To achieve the use of these additional electrical equipment, additional equipment is required. The electric device not only increases the production and use cost, but also increases the difficulty of installation and maintenance. In addition, in addition to the heating generated by the fireplace, a large part of the heat is directly diffused into the air and is not effectively utilized. It will cause a certain amount of energy waste. Summary of the invention

 The technical problem to be solved by the present invention is to provide a fireplace with a power generating device which is simple in structure, convenient to install, and energy-saving and environmentally friendly in view of the above-mentioned state of the art.

The technical solution adopted by the present invention to solve the above technical problems is as follows: A fireplace with a power generating device includes a casing and a furnace body disposed in the casing, and the furnace body is provided with a furnace for burning fuel, wherein: Said The outer wall of the furnace body is provided with a power generation component capable of sensing a temperature difference between the outer wall of the furnace and the outside and converting the temperature difference into electrical energy, and the power generation assembly has an output end capable of supplying a working power to the load.

 Preferably, the power generating component may be a semiconductor thermoelectric power generation component or a steam engine power generating device.

 In order to obtain a better heat collecting effect, the heat collecting efficiency is improved, wherein the two sides of the semiconductor thermoelectric power generation assembly are respectively provided with a heat collecting sheet and a heat sink, and the heat collecting sheet is disposed on the outer wall of the furnace body. on.

 In order to obtain as large a temperature difference as possible between both ends of the semiconductor thermoelectric power generation assembly, preferably, a heat insulating sheet is further disposed between the heat sink and the outer wall of the furnace body. Therefore, the heat insulating sheet can isolate the temperature transfer between the heat sink and the furnace body, increase the temperature difference between the heat collecting sheet and the heat sink, and improve the power generation efficiency.

 In order to further increase the temperature difference between the heat collecting sheet and the heat sink, preferably, the heat sink may be provided with a fan device or a water circulation cooling device capable of performing forced cooling.

 In order to further improve the heat dissipation efficiency, as another preferred, the heat sink and the semiconductor thermoelectric power generation component may be connected by a heat pipe, and the heat pipe can effectively realize heat transfer, so that the heat sink can be arranged at a relatively low temperature. The underside of the fireplace is more conducive to heat dissipation.

 Preferably, the load may include a fan assembly capable of improving the heat output of the fireplace, the fan assembly having a heat dissipating fan and a motor driving the heat dissipating fan, the power output end of the power generating assembly passing through the wire and the motor The power input is connected. Therefore, the electric energy obtained by the power generation component can directly supply the working power to the fan assembly, and the fan assembly can realize normal operation without an external power supply, thereby saving power consumption.

 Further preferably, the load may further include a decorative light bar, and the decorative light bar is provided with an illumination lamp, and the power output end of the power generating component is connected to the power input end of the illumination lamp on the decorative light bar via a wire. Therefore, the power generation component can also supply power to the decorative light bar, eliminating the trouble of external lighting power supply, so that the lighting of the decorative light bar can work normally even when the fireplace is used outdoors or in a moving occasion, and the use of the fireplace is more. flexible.

 Generally, the combustion methods of the fireplace include common solid fuel combustion, solid particulate fuel combustion, gaseous fuel combustion, and liquid fuel combustion, etc. The common solid fuel combustion method is relatively simple, and does not require equipment such as a burner and an ignition device. The solid fuel is directly burned in the furnace, and for the solid particulate fuel combustion mode, a particulate fuel automatic adding device, an automatic ignition device, a blower, and the like are required.

 Preferably, when the gas fuel combustion mode is used, the furnace body forms a chamber at the bottom of the furnace, and the chamber may be provided with a combustion device for realizing combustion of the gaseous fuel. At this time, the combustion device includes

 a burner connected to the gas supply device, the burner having a flame spray outlet;

 An ignition device disposed adjacent to the flame outlet of the burner;

 a control valve disposed on the air supply line of the air supply device and controlling the air supply amount of the air supply device; and an electric control module that controls the operation of the ignition device and the control valve.

Further preferably, the power generation component and the load may be controlled by an electronic control module, the load may include a fan assembly and a decorative light bar, and the fan assembly has a heat dissipation fan and a power for driving the heat dissipation fan The lighting strip is provided with an illumination lamp; the electronic control module has a power input end, a first output end, a second output end, and a third output end, wherein the power output end of the power generating component passes through the wire Connected to the power input end of the electronic control module, the electronic control module is connected to the power input end of the motor through the first output end, and the electronic control module is connected to the decorative light through the second output end The lighting power input terminal of the strip; the electronic control module is further connected with an output power socket capable of working for the external electrical device through the third output end, and the output power socket is fixedly disposed on the outer casing of the fireplace.

 When the liquid fuel combustion mode is adopted, preferably, the furnace body forms a chamber at the bottom of the furnace, and the chamber may accommodate a combustion device for realizing combustion of the liquid fuel. At this time, the combustion device includes

 a gasification chamber connected to the liquid supply device;

 a burner, in communication with the gasification chamber, the burner having a flame spray outlet;

 An ignition device disposed adjacent to the flame outlet of the burner;

 An electromagnetic pump disposed on a liquid supply line of the liquid supply device, the electromagnetic pump powering the delivery of the liquid fuel and controlling the liquid supply amount of the liquid supply device;

 An electronic control module controls the operation of the ignition device and the control valve.

 Further preferably, the power generation component and the load may also be controlled by an electronic control module, the load may include a fan assembly and a decorative light bar, the fan assembly having a heat dissipation fan and a motor for driving the heat dissipation fan, An illumination lamp is disposed on the decorative light bar; the electronic control module has a power input end, a first output end, a second output end, and a third output end, wherein the power output end of the power generation component passes through the wire and the electric Connected to the power input end of the control module, the electronic control module is connected to the power input end of the motor through the first output end, and the electronic control module connects the illumination light of the decorative light bar through the second output end The power control module is further connected to the output terminal of the third output terminal for outputting an external power supply, and the output power socket is fixedly disposed on the outer casing of the fireplace.

Compared with the prior art, the invention has the advantages that: a thermoelectric power generation assembly is arranged on the outer wall of the furnace, since one side of the power generation assembly is placed close to the outer wall of the furnace, and the other side is not in contact with the outer wall of the furnace, so that A temperature difference is formed between the two surfaces of the power generating component, and the temperature difference is converted into electrical energy by using the principle of the Seebeck effect, which can provide power for loads such as fan components and decorative light bars used in the fireplace, eliminating these Electrical equipment requires additional power supply, which increases the flexibility of the fireplace, allowing the fireplace to work outdoors or in an environment where there is no utility supply. On the other hand, the power generation assembly is simple in structure and easy to install, so easy to implement. When the fireplace burns a certain amount of heat to increase the temperature of the furnace body, it can use the temperature difference between the furnace body and the outside world to generate electricity. It not only realizes efficient recycling of energy, but also saves energy and environmental protection, which can save the consumption of the fireplace power supply and reduce The cost of using the fireplace; in addition, the electrical energy generated by the fireplace, in addition to In addition to the electrical accessories used, it can also be used for external electrical equipment, providing more convenience for the lack of electricity, less electricity and electrical equipment in the field. DRAWINGS 1 is a partial exploded perspective view of a first embodiment of the present invention.

 2 is a schematic diagram showing the connection structure between a power generation component and a load according to Embodiment 1 of the present invention.

 3 is a schematic view showing a connection structure between a power generation assembly, a gas combustion device, and a load according to Embodiment 2 of the present invention. 4 is a partial exploded perspective view of a third embodiment of the present invention.

 FIG. 5 is a schematic structural view of a gasification apparatus according to a third embodiment of the present invention.

 Fig. 6 is a schematic view showing the connection structure between a power generating assembly, a liquid burning device and a load according to a third embodiment of the present invention. detailed description

 The invention will be further described in detail below with reference to the embodiments of the drawings.

 Embodiment 1:

 As shown in FIG. 1 and FIG. 2, the fireplace of the present embodiment adopts a method of burning solid fuel (coal, carbon, wood, etc.), and the fireplace includes a casing 1 and a furnace body 2 disposed in the casing 1. The furnace body 2 is provided with a furnace 21 for accommodating fuel. The furnace 21 has an air inlet port 211 and a flue gas discharge port 212. The top of the furnace body 2 is provided with a flue 3, and the flue gas discharge port 212 communicates with the flue 3. A furnace door 4 is further mounted on the front portion of the furnace body 2, and a flame observation port 41 communicating with the furnace 21 is opened on the furnace door 4.

 The outer wall of the furnace body 2 is provided with a power generation component capable of inducing a temperature difference between the furnace 21 and the outside and converting the temperature difference into electric energy. The power generation assembly can generate power by utilizing various thermal effects principles in the prior art. The power generation component used in this embodiment is a semiconductor thermoelectric power generation component 5 having an output terminal capable of providing a working power supply for a load; for better heat collection, considering a simple structure and ease of installation. Effect, the power generation efficiency is improved, and the semiconductor thermoelectric power generation unit 5 is provided with a heat collecting sheet 51 made of aluminum material on one side thereof, the heat collecting sheet 51 being in close contact with the outer wall of the furnace body 2; another semiconductor temperature difference power generation unit 5 The heat sink 52 is disposed on the side, and the heat sink 52 can be configured to have a plurality of heat dissipation ribs. To further improve the heat dissipation efficiency, the heat sink and the semiconductor thermoelectric power generation component can be connected by a heat pipe, and the heat pipe can be The heat on the semiconductor thermoelectric power generation component is quickly transferred to the heat sink, improving the dispersion of the semiconductor thermoelectric power generation component Thermal capacity; a heat insulating sheet may be disposed between the furnace body 2 and the semiconductor thermoelectric power generation assembly 5 to ensure heat insulation between the heat sink 52 and the furnace body 2, and to improve the temperature difference between the ends of the semiconductor thermoelectric power generation assembly 5, Further, a fan device or a water circulation cooling device may be further disposed on the heat sink 52 to forcibly cool the heat sink 52 to further increase the temperature difference between the heat sink 52 and the heat collecting fins 51.

The fireplace of the present embodiment is equipped with a fan assembly 6 as a load, and the fan assembly 6 can be installed at the bottom of the furnace body 2. The fan assembly 6 generally includes a cooling fan 61 and a motor 62 that drives the cooling fan 61 to operate. 61, the heat in the furnace 21 can be blown out to improve the heat output of the fireplace; the power output end of the semiconductor thermoelectric power generation assembly 5 can be directly connected to the power input end of the motor 62 via the wire 53 to provide work for the motor 62 of the fan assembly 6. Considering that the voltage generated by the semiconductor thermoelectric power generation component 5 may not be very stable, a voltage stabilizing circuit may be disposed at the power output end of the power generating component, so that the motor 62 can obtain a continuously stable power supply voltage; In addition, for the motor 62 having a large power, the plurality of semiconductor thermoelectric power generation modules 5 can be combined in series and parallel to obtain a working power source having a larger power, and the motor 62 of the fan assembly 6 is ensured to operate normally.

 In this embodiment, an output power socket 7 can be disposed under the side wall of the casing 1 of the fireplace. The output power socket 7 and the power output terminal of the semiconductor thermoelectric power generation assembly 5 can be connected through a connection terminal, and the external electrical equipment can utilize the output. The power socket 7 obtains an operating voltage, so that the electric energy generated by the semiconductor thermoelectric power generation unit 5 can be used not only for the load of the fireplace, but also for external electrical equipment.

 When the fireplace is working, the combustion of the fuel in the furnace 21 generates a large amount of heat, and the outer wall of the furnace body 2 is heated. Since the heat collecting fins 51 are disposed to be attached to the outer wall of the furnace body 2, the heat on the outer wall of the furnace body 2 is It is conducted to the heat collecting sheet 51 to form a high temperature environment on one side of the semiconductor thermoelectric power generation unit 5; and the heat sink 52 on the other side of the semiconductor thermoelectric power generation unit 5 is away from the outer wall of the furnace body 2, and the temperature is far. Lower than the temperature of the heat collecting sheet 51, thereby forming a relative low temperature on the other side of the semiconductor thermoelectric power generation unit 5; once a temperature difference is formed on both sides of the semiconductor thermoelectric power generation unit 5, according to the Seebeck effect, A voltage is formed on both sides of the semiconductor thermoelectric power generation unit 5, and the electric energy generated by the semiconductor thermoelectric power generation unit 5 is connected to the power supply terminal of the motor 62 through the wire, so that the rotation of the motor 62 can be driven, and the rotation speed of the heat dissipation fan 61 can also generate electricity according to the semiconductor temperature difference. The voltage generated by component 5 varies from one to another.

 Therefore, the rotation of the motor 62 causes the heat-dissipating fan 61 to work, and the heat generated by the combustion of the fuel in the fireplace is radiated to the heating space. As the degree of combustion of the fireplace changes, the temperature and flow rate of the hot air blown by the cooling fan 61 also change: That is to say, when the combustion is severe, the temperature difference generated is also large, the voltage (electric energy) generated by the semiconductor thermoelectric power generation unit 5 is high, and the rotation speed of the heat dissipation fan 61 is also accelerated, so that the fireplace can be better dissipated, thereby The temperature of the outer wall of the furnace 21 and the fireplace casing 1 is not too high; similarly, when the fireplace is weakly burned or stops working, the temperature difference between the two sides of the semiconductor thermoelectric power generation assembly 5 is small or the temperature is the same, and the voltage (electric energy) generated by the semiconductor thermoelectric power generation unit 5 is relatively low. When the temperature is small or zero, the speed of the cooling fan 61 is small or stopped, and the temperature in the furnace 21 can be effectively maintained, the fuel in the furnace 21 is fully burned, and the "cool breeze" is not blown, which makes people feel more comfortable. .

 In addition, the load in this embodiment can also provide power for other electrical equipment such as a decorative light bar, a humidifying device, etc.; wherein the decorative light bar can be provided with an illumination lamp, and for energy saving, an LED light source can be used as the illumination lamp, the illumination lamp The power input end can be directly connected to the power output end of the semiconductor thermoelectric power generation component 5 through the wire to realize continuous illumination, or a control switch can be installed at the power input end of the illumination lamp, and the illumination lamp can be turned on, off or brightness adjusted by the control switch. operating.

 The semiconductor thermoelectric power generation component 5, the fan assembly 6, the decorative light bar, the humidifying device, and the like in the present embodiment are all prior art, and the specific internal structure and working principle are not described herein. Embodiment 2:

As shown in FIG. 3, the external structure of the fireplace in the second embodiment and the first embodiment is basically the same, and the structure of the power generating component disposed on the fireplace is also the same, except that the gas fuel (natural gas, liquefied gas) is used in the second embodiment. Combustible Gas burning, the furnace body of the present embodiment forms a chamber at the bottom of the furnace, and the chamber is provided with a combustion device for gas fuel combustion, the combustion device includes a gas supply device (not shown), and the burner 1 ', Ignition device 2', control wide 3' and electronic control module 4', the furnace body of the fireplace is also provided with a fan assembly 6' and a decorative light bar 8', in order to reduce power consumption, the decorative light bar 8' is provided with a plurality of energy-saving LED illuminators 81', the fan assembly 6' includes a heat-dissipating fan 61' and a motor 62' that drives the heat-dissipating fan 61'. In order to adjust the speed of the heat-dissipating fan 61' in time, the furnace body can also be A temperature sensor 9' is provided on the side wall.

The power generation component used in this embodiment is also a semiconductor thermoelectric power generation component 5'. The semiconductor temperature difference component has a power supply output terminal capable of providing an operating voltage to the load, and the semiconductor thermoelectric power generation component 5' is made of aluminum material on one side thereof. The heat collecting sheet 51', the heat collecting sheet 51' is closely attached to the outer wall of the furnace body; the other side of the semiconductor thermoelectric power generation unit 5' is provided with a heat sink 52'_{; in} order to improve heat dissipation efficiency, the heat sink 52' and the semiconductor The thermoelectric power generation modules 5' are connected by a heat pipe. In order to increase the temperature difference between the heat sink 52' and the heat collecting fins 5', a heat insulating sheet may be disposed between the furnace body and the semiconductor thermoelectric power generation unit 5', and the heat sink may be disposed. A fan unit and/or a circulating water cooling device with forced cooling are provided on the 52'.

 Wherein, the burner Γ is connected to the gas supply device, the control valve 3' is arranged on the gas supply line 3 of the gas supply device and controls the gas supply amount of the gas supply device, the burner is opened with a flame discharge port, and the ignition device 2' The ignition device is disposed near the burner ,, and the ignition device 2 is powered by the battery 21' (such as a lithium battery); the electronic control module 4 has a power input terminal, a battery connection terminal, a first input terminal, and a first output terminal. The second output terminal, the third output terminal, the fourth output terminal and the fifth output terminal, in order to ensure the stability of the output voltage of the semiconductor thermoelectric power generation component 5', a voltage stabilization circuit and/or a voltage regulation circuit may be disposed in the electronic control module 4'. Or boost circuit;

 Wherein, the power output end of the semiconductor thermoelectric power generation component 5' is connected to the power input end of the electronic control module 4' via the wire 53'; the first input end of the electronic control module 4' is connected to the output end of the temperature sensor 9'; The module 4' is connected to the power input end of the motor through the first output end, and the electronic control module 4' is connected to the power input end of the LED illuminator 81' of the decorative light strip 8' through the second output end, and the electronic control module 4' passes the third The output end is also connected with an output power socket 7' for the external electrical appliance to work. The output power socket 7' is fixedly disposed on the side wall of the casing of the fireplace, and the electronic control module 4' is controlled by the fourth output terminal and the control valve 3'. The terminal is connected; the electronic control module 4' is connected to the ignition device 2' through the fifth output terminal; the electronic control module 4' is connected to the battery 2 through the battery connection terminal.

When it is necessary to start the working of the fireplace, the switch of the electronic control module 4' is turned on, and the electronic control module 4' uses the electric quantity in the battery 21' to start the ignition device 2' in the fireplace for ignition, and the air supply amount is controlled by the control valve 3'. Control; after the fireplace is operated, the combustion of the fuel generates a large amount of heat, the outer wall of the furnace body is heated, and the temperature difference is generated on both sides of the semiconductor thermoelectric power generation assembly 5' to generate electric energy; thus, the semiconductor thermoelectric power generation assembly 5 'The generated electric energy is input into the electronic control module 4' through the wire 53', one part can supplement the power consumed by the battery 21', and the other part can be used to maintain the operation of the electronic control module 4' and the control valve 3', and another part can also be used. It is used to drive the decorative light strip 8', motor 62' and other loads on the fireplace, and the rest is converted to the external electrical equipment by the conversion circuit (DC-DC, DC-AC, etc.) in the electronic control module 4'. Voltage, output out through the output power socket 7', can drive lamps, IT Products and other external loads work.

 The electronic control module 4 of the embodiment can control the operation of the decorative light bar 8 by using the electric energy generated by the semiconductor thermoelectric power generation component 5', so that the flame of the fireplace is more colorful; the electronic control module 4' is connected with the temperature sensor 9'. According to the temperature (room temperature) detected by the temperature sensor 9', the rotation speed of the motor 62' and the air supply amount of the control valve 3' are automatically adjusted to keep the room temperature within a preset temperature range, that is, when the temperature sensor 9 'When the detected temperature is too high, reduce the fuel supply (reduce the gas supply) and reduce the speed of the cooling fan, thereby reducing the heat output of the fireplace to the heating space; when the temperature detected by the temperature sensor 9' is low, Increasing the fuel supply (increasing the gas supply) and increasing the rotational speed of the cooling fan 61, thereby increasing the heat output of the fireplace to the heating space; when the fireplace needs to be turned off, the electronic control module 4' cuts off the intake air through the control valve 3'. Then the fireplace stops working.

 In this embodiment, the electronic control module 4' can be implemented by using various single-chip microcomputers (or control chips) in the prior art with additional sensors and actuators, and the specific control circuit will not be described in detail. Embodiment 3:

As shown in FIG. 4 to FIG. 6, the fireplace of the third embodiment also includes a casing 1" and a furnace body 2" disposed in the casing 1". The furnace body 2" is provided with a furnace 21 for accommodating fuel. The furnace 21" has an air inlet port 211" and a smoke exhaust port 212", the top of the furnace body 2" is provided with a flue 3", the flue gas exhaust port 212" is connected with the flue 3", and the front of the furnace body 2" The furnace door 4" is also installed, and the furnace door 4" is provided with a flame observation port 41" which is connected with the furnace 21"; the furnace body 2" is also provided with a fan assembly 6" and a decorative light bar 8", a decorative lamp A strip 8" is provided with a plurality of energy-saving LED illuminators 81", and the fan assembly 6" includes a heat-dissipating fan 61" and a motor 62" that drives the heat-dissipating fan 61"; a semiconductor is disposed on the outer wall of the furnace body 2" The thermoelectric power generation unit 5", in order to increase the heat collection rate, increase the temperature difference between the two sides of the semiconductor thermoelectric power generation assembly 5", the semiconductor thermoelectric power generation assembly 5" is provided with a heat collecting sheet 51" and a heat sink ₅₂ ", respectively, The heat collecting sheet 51 "closes to the outer wall of the furnace body 2".

Different from the first two embodiments, in the third embodiment, the liquid fuel (alcohol, kerosene, diesel, etc.) is burned, and the furnace body 2" forms a chamber at the bottom of the furnace 21", and the liquid fuel combustion device is arranged. In the chamber, the combustion apparatus of the present embodiment includes a liquid supply device 91 (built-in liquid fuel), a gasification chamber 92" in communication with the liquid supply device 91", and a burner connected to the gasification chamber 92"93", ignition device 94", electromagnetic pump 95" and electronic control module 96", wherein the burner 93" is provided with a flame discharge port, and the ignition device 94 is disposed adjacent to the flame discharge port of the burner 93", the ignition device 94 "Power supply by battery 941" (such as a lithium battery, etc.), electromagnetic pump 95" is disposed on the liquid supply line of the liquid supply device 91" and controls the supply amount of the liquid supply device 91", and the gasification chamber 92" is provided therein. The heating device 921" is further mounted with a first temperature sensor 971" on the outer wall of the gasification chamber 92", and the outer casing 1 is also mounted with a second temperature sensor 972", a shock sensor 98" and a carbon dioxide detector on the inner side wall. 99", the outer wall of the outer casing 1 is also provided with an output power socket 7"; The control module 96" has a power input terminal, a battery connection terminal, a first input terminal, a second input terminal, a third input terminal, a fourth input terminal, a fifth input terminal, a first output terminal, a second output terminal, and a third The output terminal, the fourth output terminal and the fifth output terminal, in order to ensure the stability of the output voltage of the semiconductor thermoelectric power generation component 5", in the electronic control mode A voltage regulator circuit can also be provided in the block 96";

 Wherein, the power output end of the semiconductor thermoelectric power generation component 5" is connected to the power input end of the electronic control module 96" via the wire 53"; the first input end of the electronic control module 96" is connected to the liquid level meter 922", and the electronic control module 96 "The second input is connected to the output of the first temperature sensor 971", the third input of the electronic control module 96" is connected to the second temperature sensor 972", the fourth input of the electronic control module 96" and the shock sensor 98" is connected, the fifth input of the electronic control module 96" is connected to the carbon dioxide detector 99"; the electronic control module 96" is connected to the power input end of the motor 62" through the first output, and the electronic control module 96" passes the second output The end is connected to the power input end of the LED illuminator 81" of the decorative light bar 8", and the electronic control module 96" is connected through a third output terminal to an output power socket 7" fixed on the side wall of the casing 1 of the fireplace, the output The power socket 7" can provide working power for the external electrical equipment, the electronic control module 96" is connected to the control end of the electromagnetic pump 95" through the fourth output terminal, and the electronic control module 96" is connected to the ignition device 94 through the fifth output terminal. Electronic control module 96" is connected to the battery 941 via the battery connection.

 When the fireplace operation needs to be started, the switch of the electronic control module 96" is turned on, and the electronic control module 96" uses the electric quantity starting electromagnetic pump 95" in the battery 941" to deliver the liquid fuel to the gasification chamber 92", and vaporizes the liquid fuel. The electronic control module 96" simultaneously controls the ignition device 94" to ignite; when the ignition is successful, the combustion of the fuel generates a large amount of heat under normal working conditions, and the outer wall of the furnace body 2" is heated, the semiconductor temperature difference power generation component A temperature difference is formed on both sides to generate a voltage, thereby outputting electric energy; a part of the electric energy generated by the semiconductor thermoelectric power generation component replenishes the electric power consumed by the battery 941; another part of the electric energy is used to drive the electronic control module 96", the electromagnetic pump 95", and the heating device 921 on the fireplace. "Electrical components such as "decorative light bar 8", motor 62"; wherein, the rotation of the motor 62" can drive the heat-dissipating fan 61 to "operate and output hot air outward, and the LED illuminator 81 on the decorative light bar 8" illuminates After that, the flame that burns the fireplace is more colorful; the remaining part of the electric energy is converted to an external voltage through a DC-DC or DC-AC conversion circuit. Voltage required, a power socket 7 through the output "output externally, so as to drive other loads work lamps, IT equipment like.

 The gasification chamber 92" is also provided with a liquid level gauge 922" connected to the electronic control module 96". The electronic control module 96" adjusts the electromagnetic pump 95" to the liquid fuel according to the liquid level detected by the liquid level gauge 922". The amount of delivery; the electronic control module 96" adjusts the heating power of the heating device 921" in the gasification chamber 92" according to the temperature detected by the first temperature sensor 971"; the electronic control module 96" is detected according to the second temperature sensor 972" Temperature regulation of the supply of liquid fuel and gasification temperature to adjust the severity of combustion, and adjust the speed of the cooling fan 61" to increase or decrease the heat dissipation rate; In addition, the electronic control module 96" is connected with a vibration sensor 98", carbon dioxide detection The device 99", once it detects that the carbon dioxide concentration is too high or vibrates, the electronic control module 96" controls the heating device 921", the electromagnetic pump 95", the decorative light bar 8", and the motor 62" to stop working in sequence.

 When it is necessary to close the fireplace, the electrical equipment such as the electromagnetic control module 96", the heating device 921", the motor 62", the decorative light bar 8", etc. can be stopped in sequence.

Claims

Rights request

 A fireplace with a power generating device comprising a casing (1; 1") and a furnace body (2; 2") disposed in the casing (1; 1"), the furnace body (2; 2" The inside is provided with a furnace (21; 21") for burning fuel, characterized in that: the outer wall of the furnace body (2; 2") is provided with an outer wall capable of sensing the furnace body (2; 2") and the outside The power difference between the temperature difference and the power generation component (5; 5'; 5"), the power generation component (5; 5'; 5") has an output capable of supplying a working power to the load.

 A fireplace with a power generating unit according to claim 1, characterized in that said power generating component (5; 5'; 5") is a semiconductor thermoelectric power generating component (5; 5,; 5").

 The fireplace with a power generating device according to claim 2, wherein: the two sides of the semiconductor thermoelectric power generation assembly (5; 5,; 5") are respectively provided with heat collecting sheets (51; 51'; 51 And a heat sink (52; 52'; 52"), which is disposed on the outer wall of the furnace body (2; 2").

 The fireplace with a power generating device according to claim 3, characterized in that: between the heat sink (52; 52'; 52") and the outer wall of the furnace body (2; 2") Insulation sheet.

 A fireplace with a power generating unit according to claim 3, wherein said heat sink (52; 52'; 52") is provided with a fan unit and/or a water circulation cooling device capable of performing forced cooling.

 6. A fireplace with a power generating unit according to claim 3, wherein said heat sink (52; 52'; 52") and said semiconductor thermoelectric power generation component (5; 5'; 5") Connected by a heat pipe.

 7. The fireplace with a power generating device according to claim 1, wherein: said load comprises a fan assembly (6; 6'; 6") capable of improving the heat output of the fireplace, said fan assembly (6; 6';6") has a cooling fan (61; 61'; 61") and a motor (62; 62'; 62") that drives the cooling fan (61; 6 Γ; 6 Γ,), the power generating component (5) The output of the 5';5") is connected via a wire (53; 53,; 53") to the power input of the motor (62; 62'; 62").

 8. A fireplace with a power generating device according to claim 1, wherein: said load comprises a decorative light strip (8,; 8"), said decorative light strip (8'; 8") being provided with illumination a lamp, the output end of the power generating component (5; 5'; 5") is connected to the power input end of the illumination lamp on the decorative light bar (8,; 8") via a wire (53; 53'; 53") .

 A fireplace with a power generating device according to any one of claims 1 to 6, wherein: the furnace body (2; 2") forms a chamber at the bottom of the furnace (21; 21") The chamber is provided with a combustion device for realizing combustion of the gaseous fuel, and the combustion device includes

 a burner (1'; 93"), connected to a gas supply device, the burner (1 '; 93") is provided with a flame discharge port; an ignition device (2'; 94"), adjacent to the burner (1 ' ; 93") flame outlet setting;

 a control valve (3') disposed on a gas supply line of the gas supply device and controlling a gas supply amount of the gas supply device (not shown);

 The electronic control module (4'; 96") controls the operation of the ignition device (2'; 94") and the control valve (3').

10. A fireplace with a power generating unit according to claim 9, wherein: said load comprises a fan assembly (6; 6';6") and a decorative light bar (8';8"), said The fan assembly (6; 6';6") has a cooling fan (61; 61';61") and a motor (62; 62';62") that drives the cooling fan (61; 6Γ; 6Γ'), the decorative light bar (8';8") is provided with an illumination lamp; the electronic control module (4) ';96") has a power input terminal, a first output terminal, a second output terminal, and a third output terminal, wherein the power output terminal of the power generating component (5; 5';5") passes through the wire (53; 53) , 53") is connected to the power input terminal of the electronic control module (4';96"), the electronic control module (4';96") is connected to the motor through the first output terminal (62; a power input terminal of the 62';62"), the electronic control module (4';96") is connected to the illumination light input end of the decorative light bar (8';8") through the second output end; The electronic control module (4';96") is further connected with an output power socket (7; 7';7") for the external electrical device through the third output end, the output power socket (7; 7) ';7") is fixedly disposed on the outer casing (1; 1") of the fireplace.

 11. A fireplace with a power generating device according to any one of claims 1 to 6, wherein - the furnace body forms a chamber at the bottom of the furnace (21; 21"), the chamber contents Provided with a combustion device that achieves combustion of a liquid fuel, the combustion device including

 a gasification chamber (92") connected to the liquid supply device;

 a burner (1'; 93"), in communication with the gasification chamber (92"), the burner (1'; 93") is provided with a flame discharge port; an ignition device (2'; 94"), close a flame discharge port of the burner (1'; 93");

 An electromagnetic pump (95") is disposed on a supply line of the liquid supply device, the electromagnetic pump (95") powering the delivery of the liquid fuel and controlling the amount of liquid discharged from the liquid supply device;

 The electronic control module (4'; 96") controls the operation of the ignition device (2'; 94") and the control valve (3').

 12. The fireplace with a power generating device according to claim 11, wherein: said load comprises a fan assembly (6; 6, 6") and a decorative light bar (8'; 8"), said The fan assembly (6; 6'; 6") has a cooling fan (61; 61'; 61") and a motor (62; 62'; 62") that drives the cooling fan (61; 61 '; 61"), The decorative light bar (8,; 8") is provided with an illumination lamp; the electronic control module (4,; 96") has a power input end, a first output end, a second output end, and a third output end, The power output end of the power generating component (5; 5'; 5") is connected to the power input end of the electronic control module (4'; 96") via a wire (53; 53'; 53"), An electric control module (4'; 96") is connected to a power input end of the motor (62; 62'; 62") through the first output end, and the electronic control module (4'; 96") passes the The second output end is connected to the illumination lamp power input end of the decorative light bar (8'; 8"); the electronic control module (4'; 96") is further connected through the third output end to provide a supply The output power socket (7; 7'; 7") of the external electrical device is working, and the output power socket (7; 7'; 7") is fixedly installed in the office. On; (1 '1) housing fireplace.