CN215062242U - Novel plant fuel heating furnace - Google Patents

Abstract

The utility model discloses a novel plant fuel heating furnace, which comprises a furnace frame, wherein two furnace ends are symmetrically arranged on the furnace frame, a heat dissipation device is arranged on each furnace end, the heat dissipation device comprises annular cylindrical alloy, the annular cylindrical alloy is sleeved on the outer wall of each furnace end, an annular cavity is arranged in the pipe wall of the annular cylindrical alloy, a baffle is arranged in the annular cavity, the annular cavity is divided into arc-shaped cavities by the baffle, one ends of the two arc-shaped cavities are communicated through a metal pipe, the other end of one arc-shaped cavity is provided with a water inlet, the other end of the other arc-shaped cavity is provided with a water outlet, the water outlet is connected with a cooling pipe, the other end of the cooling pipe is connected with the water inlet of a water pump, the problem that the plant fuel has high heat value and generates extremely large heat during combustion is solved, so that the traditional furnace needs to continuously water to cool the surface of a cooking bench when in use, not only wasting a large amount of water resources, but also influencing the problems of working efficiency and the like.

Description

Novel plant fuel heating furnace

Technical Field

The utility model relates to a commercial gas kitchen range technical field specifically is a novel plant fuel heating furnace.

Background

The vegetable fuel oil is a low-density and high-heat-value fuel product formed by utilizing animal and vegetable oil, fat, waste edible oil, hogwash oil, kitchen waste oil and industrial palm oil after esterification or transesterification, and is also a biochemical product with chemical properties basically consistent with the properties of mineral diesel oil, namely fatty acid methyl ester, the existing vegetable oil stove needs to be preheated for a long time to heat the vegetable fuel oil into vegetable oil gas to be ignited by an igniter when being used every time, and the heat generated during combustion is extremely high due to the extremely high heat value of the vegetable fuel oil, so that the surface of a cooking bench needs to be cooled by watering when the traditional cooking stove is used, a large amount of water resources are wasted, and the working efficiency is influenced.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome prior art not enough, provide a novel plant fuel heating furnace, solved the problem of mentioning in the background art.

The purpose of the utility model is realized through the following technical scheme: a novel plant fuel oil heating furnace comprises a furnace frame, wherein two furnace ends are symmetrically arranged on the furnace frame, and heat dissipation devices are arranged on the furnace ends;

the heat dissipation device comprises an annular cylindrical alloy, the annular cylindrical alloy sleeve is arranged on the outer wall of the furnace end, an annular cavity is formed in the pipe wall of the annular cylindrical alloy, a partition plate is arranged in the annular cavity and divides the annular cavity into an arc-shaped cavity, two arc-shaped cavities are formed in one ends of the arc-shaped cavities through metal pipes, one is arranged at the other ends of the arc-shaped cavities and the other is arranged at the other ends of the arc-shaped cavities, a water outlet is formed in the other ends of the arc-shaped cavities and connected with a cooling pipe, the other end of the cooling pipe is connected with the water inlet end of the water pump, and the water outlet end of the water pump is connected with the water inlet.

Furthermore, an insulation can is arranged below the furnace end and used for containing cooling media, the cooling pipe is arranged in the insulation can, and the cooling pipe is a spiral coil pipe.

Furthermore, the cooling pipe is provided with a first spiral type cooling fin on the pipe wall in the heat insulation box.

Further, the bottom of the heat insulation box is provided with a water outlet, the water outlet is connected with a valve, the valve is used for being connected with water utilization equipment, the heat insulation box is further provided with a water filling port, the water filling port is connected with the output end of the pipeline booster pump through a second water pipe, and the input end of the pipeline booster pump is communicated with a tap water pipe.

Furthermore, a pressure transmitter is arranged on the heat insulation box.

Furthermore, a second spiral radiating fin is further arranged in the annular cavity of the annular cylindrical alloy, and the second spiral radiating fin is fixed on the inner pipe wall of the annular cylindrical alloy in a surrounding mode.

Furthermore, the surface of the annular cylindrical alloy is coated with a high-temperature-resistant heat-insulating coating.

Furthermore, a water storage tank is arranged between the two furnace ends, and a faucet is arranged above the water storage tank.

The utility model has the advantages that:

1. annular cylindrical alloy furnace end in close contact with, lead annular cylindrical alloy to the heat absorption of furnace end, annular cylindrical alloy internal energy increases, because there is flowing water in the annular cylindrical alloy, the internal energy of annular cylindrical alloy is shifted to in the water to mobile water, take out in the water follow arc cavity with absorbing heat that the water pump does not stop, discharge into the arc cavity of another annular cylindrical alloy again after the cooling, because two arc cavity one end are passed through the tubular metal resonator and are linked together each other, and then the endless takes hot water out, discharge into again after the cooling, reach the cooling to the furnace end, the spiral fin of second that sets up in the annular cavity of annular cylindrical alloy, the spiral fin of second encircles and fixes on the interior pipe wall of annular cylindrical alloy, make the internal energy of annular cylindrical alloy more easy transfer to aquatic.

2. Become hot water behind the water absorption internal energy, via the cooling tube in the inside spiral of incubator wriggle, increase the time of at the incasement cooling of insulation, the first spiral fin that the cooling tube set up on the pipe wall of the incasement portion of insulation helps in the cold water that shifts the hot-water internal energy in the cooling tube to the insulation can, and then slowly makes the insulation can cold water become hot, has realized the thermal recycle of furnace end.

3. The pipeline booster pump pours into the insulation can with cold water from the water filling port, the temperature of control insulation can internal water, simultaneously, the pipeline booster pump carries out the pressure boost to the insulation can inside, and then after opening the valve, the water in the insulation can just can automatic discharge to in other water equipment's use, the water of emission is hot water mostly, the pressure transmitter that sets up on the insulation can monitor the pressure in the insulation can, and then realize opening to opening of pipeline booster pump, make the water yield and the water pressure in the insulation can keep at certain within range.

Drawings

FIG. 1 is a schematic structural view of a novel plant fuel oil heating furnace of the present invention;

FIG. 2 is a top cross-sectional view of the novel plant fuel oil heating furnace ring-shaped cylindrical alloy of the present invention;

FIG. 3 is a front sectional view of the annular cylindrical alloy of the novel plant fuel oil heating furnace of the present invention;

in the figure, 1, a furnace frame, 2, a furnace end, 3, annular cylindrical alloy, 4, a partition plate, 5, an arc-shaped cavity, 6, a metal pipe, 7, a water inlet, 8, a water outlet, 9, a cooling pipe, 10, a water pump, 11, an insulation box, 12, a first spiral type radiating fin, 13, a water outlet, 14, a valve, 15, a first water pipe, 16, a water inlet, 17, a second water pipe, 18, a pipeline booster pump, 19, a pressure transmitter, 20, a second spiral type radiating fin, 21, a water storage tank, 22 and a water tap.

Detailed Description

The technical solution of the present invention will be described in further detail with reference to the accompanying drawings, but the protection scope of the present invention is not limited to the following description, and the indicated orientation or positional relationship is based on the orientation or positional relationship shown in the drawings, and is only for convenience of description and simplification of description, and does not indicate or imply that the indicated device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that, unless explicitly stated or limited otherwise, the terms "mounted," "connected" and "disposed" are to be interpreted broadly, and may be, for example, fixedly connected, disposed, detachably connected, disposed, or integrally connected and disposed; the utility model discloses in provide only supply the reference with the model of electrical apparatus. For those skilled in the art, different types of electrical appliances with the same function can be replaced according to actual use conditions, and for those skilled in the art, the specific meaning of the above terms in the present invention can be understood in specific situations.

Referring to fig. 1 to 3, the present invention provides a technical solution: as shown in fig. 1, a novel plant fuel heating furnace comprises a furnace frame 1, two furnace ends 2 are symmetrically arranged on the furnace frame 1, and heat dissipation devices are arranged on the furnace ends 2;

the heat dissipation device comprises an annular cylindrical alloy 3, the annular cylindrical alloy 3 is sleeved on the outer wall of the furnace end 2, an annular cavity is formed in the pipe wall of the annular cylindrical alloy 3, a partition plate 4 is arranged in the annular cavity, the partition plate 4 partitions the annular cavity into arc-shaped cavities 5, one ends of the two arc-shaped cavities 5 are communicated through a metal pipe 6, a water inlet 7 is formed in the other end of one arc-shaped cavity 5, a water outlet 8 is formed in the other end of the other arc-shaped cavity 5, the water outlet 8 is connected with a cooling pipe 9, the other end of the cooling pipe 9 is connected with the water inlet end of a water pump 10, the water outlet end of the water pump 10 is connected with the water inlet 7, a second spiral type heat dissipation fin 20 is further arranged in the annular cavity of the annular cylindrical alloy 3, and the second spiral type heat dissipation fin 20 is fixed on the inner pipe wall of the annular cylindrical alloy 3 in a surrounding mode; as shown in fig. 1-3, in specific implementation, the annular cylindrical alloy 3 and the burner 2 are in close contact with each other, the heat absorption of the burner 2 is guided to the annular cylindrical alloy 3, the internal energy of the annular cylindrical alloy 3 is increased, flowing water is in the annular cylindrical alloy 3, the internal energy of the annular cylindrical alloy 3 is transferred to the water by the flowing water, when the surface of the hearth is overheated, the water pump 10 is turned on, the water which absorbs heat is continuously pumped out from one arc-shaped cavity along with the water pump 10, the cooled water is then pumped into the arc-shaped cavity 5 of the other annular cylindrical alloy 3, one end of each of the two arc-shaped cavities 5 is communicated with each other through the metal pipe 6, the hot water is further pumped out in a circulating manner, the cooled water is then pumped into the furnace burner 2, the second spiral type cooling fins 20 are arranged in the annular cavity of the annular cylindrical alloy 3, the second spiral type cooling fins 20 are fixed on the inner pipe wall of the annular cylindrical alloy 3 in a surrounding manner, the internal energy of the annular cylindrical alloy 3 is more easily transferred into water.

An insulation can 11 is arranged below the furnace end 2, the insulation can 11 is used for containing a cooling medium, the cooling pipe 9 is arranged in the insulation can 11, the cooling pipe 9 is a spiral coil pipe, and a first spiral radiating fin 12 is arranged on the pipe wall of the cooling pipe 9 in the insulation can 11; as shown in fig. 1, in the specific implementation, water absorbs internal energy and becomes hot water, and the water spirally meanders in the heat preservation box 11 through the cooling pipe 9, so that the cooling time in the heat preservation box is prolonged, and the first spiral type cooling fins 12 arranged on the pipe wall of the cooling pipe 9 in the heat preservation box 11 are beneficial to transferring the internal energy of the hot water in the cooling pipe to the cold water in the heat preservation box 11, so that the cold water in the heat preservation box 11 is gradually heated, and the heat of the burner 2 is recycled.

A water outlet 13 is arranged at the bottom of the heat preservation box 11, the water outlet 13 is connected with a valve 14, the valve 14 is used for being connected with water using equipment, a water injection port 16 is further arranged on the heat preservation box 11, the water injection port 16 is connected with the output end of a pipeline booster pump 18 through a second water pipe 17, the input end of the pipeline booster pump 18 is communicated with a tap water pipe, and a pressure transmitter 19 is arranged on the heat preservation box 11; as shown in fig. 1, in specific implementation, the pipe booster pump 18 injects cold water into the thermal insulation box 11 from the water injection port 16 to control the temperature of water in the thermal insulation box 11, and meanwhile, the pipe booster pump 18 boosts the inside of the thermal insulation box 11, so that after the valve 14 is opened, the water in the thermal insulation box 11 can be automatically discharged, so as to facilitate the use of other water-using equipment, most of the discharged water is hot water, the pressure transmitter 19 arranged on the thermal insulation box 11 can monitor the pressure in the thermal insulation box 11, thereby realizing the start and stop of the pipe booster pump, and keeping the water volume and the water pressure in the thermal insulation box within a certain range.

The surface of the annular cylindrical alloy 3 is coated with high-temperature-resistant heat-insulating coating; as shown in figure 1, in the concrete implementation, 8mm of high-temperature-resistant heat-insulating coating is coated on the surface of an object at 1100 ℃, so that the surface temperature of the object can be reduced from 1100 ℃ to within 100 ℃. In addition, the high-temperature-resistant heat-insulating coating has the characteristics of insulation, light weight, convenience in construction, long service life and the like, can be used as an inorganic material high-temperature-resistant acid-base-resistant adhesive, is firm in attachment, and prevents heat of the annular cylindrical alloy 3 from being dissipated into the air and being incapable of being utilized.

A water storage tank 21 is arranged between the two furnace ends 2, and a water tap 22 is arranged above the water storage tank 21; as shown in FIG. 1, in the specific implementation, when cooking or washing, water can be taken from the water storage tank 21 quickly, so that the problems of slow water receiving flow rate of the water faucet 22 and the like are avoided, and the water faucet 22 can provide water for the water storage tank 21.

The foregoing is illustrative of the preferred embodiments of the present invention, and it is to be understood that the invention is not limited to the precise forms disclosed herein, and that various other combinations, modifications, and environments may be resorted to, falling within the scope of the invention as defined by the appended claims. But that modifications and variations may be effected by those skilled in the art without departing from the spirit and scope of the invention, which is to be limited only by the claims appended hereto.

Claims (8)

1. The novel plant fuel oil heating furnace is characterized by comprising a furnace frame (1), wherein two furnace ends (2) are symmetrically arranged on the furnace frame (1), and heat dissipation devices are arranged on the furnace ends (2);

the heat dissipation device comprises an annular cylindrical alloy (3), wherein the annular cylindrical alloy (3) is sleeved on the outer wall of the furnace end (2), an annular cavity is formed in the pipe wall of the annular cylindrical alloy (3), a partition plate (4) is arranged in the annular cavity, the partition plate (4) separates the annular cavity into an arc-shaped cavity (5) and two, one end of the arc-shaped cavity (5) is communicated with one end of the metal pipe (6), one end of the arc-shaped cavity (5) is provided with a water inlet (7) and the other end of the arc-shaped cavity (5) is provided with a water outlet (8), the water outlet (8) is connected with a cooling pipe (9), the other end of the cooling pipe (9) is connected with the water inlet end of a water pump (10), and the water outlet end of the water pump (10) is connected with the water inlet (7).

2. The novel plant fuel oil heating furnace according to claim 1, characterized in that an insulation can (11) is arranged below the furnace head (2), the insulation can (11) is used for containing a cooling medium, the cooling pipe (9) is arranged in the insulation can (11), and the cooling pipe (9) is a spiral coil pipe.

3. The novel plant fuel oil heating furnace according to claim 2, characterized in that the cooling pipe (9) is provided with a first spiral type cooling fin (12) on the pipe wall inside the heat preservation box (11).

4. The novel plant fuel oil heating furnace according to claim 3, characterized in that a water outlet (13) is arranged at the bottom of the heat preservation box (11), the water outlet (13) is connected with a valve (14), the valve (14) is used for connecting water consumption equipment, a water injection port (16) is further arranged on the heat preservation box (11), the water injection port (16) is connected with an output end of a pipeline booster pump (18) through a second water pipe (17), and an input end of the pipeline booster pump (18) is communicated with a tap water pipe.

5. The novel plant fuel oil heating furnace according to claim 4, characterized in that the heat preservation box (11) is provided with a pressure transmitter (19).

6. The novel plant fuel oil heating furnace according to claim 1, characterized in that a second spiral type radiating fin (20) is further arranged in the annular cavity of the annular cylindrical alloy (3), and the second spiral type radiating fin (20) is fixed on the inner pipe wall of the annular cylindrical alloy (3) in a surrounding manner.

7. The novel plant fuel oil heating furnace according to claim 6, characterized in that the surface of the annular cylindrical alloy (3) is coated with a high temperature resistant heat insulation coating.

8. The novel plant fuel oil heating furnace according to claim 1, characterized in that a water storage tank (21) is arranged between the two furnace ends (2), and a water tap (22) is arranged above the water storage tank (21).

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