CN108224479B

CN108224479B - Biological particle furnace

Info

Publication number: CN108224479B
Application number: CN201810336859.8A
Authority: CN
Inventors: 赵凯
Original assignee: Individual
Current assignee: Individual
Priority date: 2018-04-16
Filing date: 2018-04-16
Publication date: 2024-02-13
Anticipated expiration: 2038-04-16
Also published as: CN108224479A

Abstract

The invention discloses a biological particle furnace, wherein a furnace hearth is arranged in a furnace body, an ash bin is arranged below a furnace hearth, the furnace hearth is large and small in upper part and is in a ladder shape, a wind box is arranged between a furnace hearth wall and a furnace body wall, a wind outlet hole is formed in the furnace hearth wall between the wind box and the furnace hearth, a feeding pipe is arranged on the furnace hearth and extends out of the furnace body, the feeding pipe is connected with a feeding device, the wind box is externally connected with a blower, an ignition rod is arranged at the bottom of the furnace hearth, a grate is arranged between the furnace hearth and the ash bin, the grate is fixed at the bottom of the furnace hearth through a grate bracket, a blast pipe for blowing towards the grate is arranged in the ash bin, and the blast pipe is communicated with the wind box. The air supply in the hearth of the biological particle furnace is rotary air supply, and air outlet holes are formed in the hearth from top to bottom, so that the granular materials are fully combusted, thoroughly combusted, discharged in a smokeless manner, environment-friendly and pollution-free manner, and the combustion efficiency is high, and is 50% lower than that of other biological particle furnaces.

Description

Biological particle furnace

Technical Field

The invention relates to a particle furnace, in particular to a biological particle furnace.

Background

The biological particle furnace is generally a large boiler used in industry and a living heating furnace used for heating in winter, is rarely used in families, and is generally coal-fired or gas-fired, so that the manufacturing cost is high and the environment is not protected. At present, the straws in many rural areas are burned in situ and then applied to the land as fertilizer, thereby wasting resources and polluting the environment. Some biological particle furnaces burn particles made of straw insufficiently, and a large amount of flue gas is discharged, so that the biological particle furnaces are environment-friendly and waste of certain particles is caused.

Disclosure of Invention

In order to solve the problems in the prior art, the invention provides a biological particle furnace.

The invention is realized by the following technical scheme: the utility model provides a biological particle stove, includes the furnace body, is provided with the furnace in the furnace body, sets up the ash bin below the furnace, big-end-up and be the echelonment, set up bellows between furnace wall and the furnace wall, be provided with the apopore on the furnace wall between bellows and the furnace, be provided with the heat dissipation chamber above the bellows, be provided with the heat pipe on the heat dissipation chamber, be provided with the heat conduction window between heat dissipation chamber and the furnace, be provided with the inlet pipe on the furnace and stretch to the furnace outside, the inlet pipe is connected with loading attachment, the external air-blower of bellows, furnace's bottom is provided with the ignition stick, is provided with the grate between furnace and the ash bin, and the grate passes through the grate support to be fixed in furnace bottom, is provided with the blast pipe to the grate blast in the ash bin, blast pipe and bellows UNICOM.

In the scheme, the heat insulation ring is arranged in the air box, the heat insulation ring divides the air box into the inner air box and the outer air box, the outer air box is communicated with the blower, the inner air box is divided into a plurality of layers of air boxes through the partition plates according to the step shape of the hearth, and the heat insulation ring is provided with the air inlet hole to communicate the inner air box with the outer air box.

In the scheme, the axis bellows end of the air outlet hole on the hearth wall at the lower end of the hearth is arranged in a low hearth end high-inclination mode, and meanwhile, the axis of the air outlet hole is also arranged in an inclination mode along the circumference of the hearth wall, so that wind entering the hearth rotates along the hearth wall.

In the scheme, the grate support is arranged oppositely in two horizontally arranged U-shaped slideways, the grate is arranged in the slideways, the grate is provided with the leak holes, and the leak holes are taper holes with large upper parts and small lower parts.

In the scheme, the periphery of the hearth opening on the upper top end surface of the furnace body is provided with three uniformly distributed pot supports, and a fire baffle plate is arranged on one side, between the two pot supports, which is convenient for a person to stand, so that the flame is prevented from jumping out from one side, on which the person stands.

In the scheme, the ignition rod is arranged at the lower end of the hearth and close to the grate, and penetrates into the hearth from the outside of the furnace body.

In the above-mentioned scheme, loading attachment is including erect circular charging tray, and the equipartition has a plurality of penetrating storage holes on the charging tray, and the charging tray outside is provided with the charging tray shell, and the discharge opening has been seted up on the inboard upper portion of charging tray shell with the inlet pipe is connected, and the feed inlet has been seted up to the outside lower part of charging tray shell, the hopper is connected to the feed inlet.

In the scheme, the feeding disc can be driven by a motor or manually rotated.

As another preferable scheme, the feeding device comprises a packing auger mechanism, a discharge hole of the packing auger mechanism is connected with a feed pipe, a storage hopper is arranged on the packing auger mechanism, and the packing auger mechanism is driven by a motor.

Compared with the prior art, the biological particle furnace has the beneficial effects that:

1. the air supply in the hearth of the biological particle furnace is rotary air supply, and air outlet holes are formed in the hearth from top to bottom, so that combustible gases such as carbon monoxide generated by gasification of combustible particles are fully mixed with air again, and further the gasified gases are fully combusted, so that the particles are fully combusted, and the furnace is thorough in combustion, smokeless to discharge, environment-friendly and pollution-free.

2. The fire power is large, the combustion efficiency is high, and the material is saved by 50 percent compared with other biological particle furnaces.

3. The biological particle furnace is provided with the heat dissipation cavity, can collect redundant heat for reuse, and does not waste heat energy.

4. The biological particle furnace grate is detachable, so that the caked slag at the grate can be conveniently cleaned.

Drawings

FIG. 1 is a schematic structural view of a biological particle furnace according to the present invention.

Fig. 2 is a top view of fig. 1.

Fig. 3 is a sectional view A-A in fig. 1.

Fig. 4 is a B-B cross-sectional view in fig. 1.

Fig. 5 is a C-C cross-sectional view of fig. 1.

FIG. 6 is a schematic view of another construction of the bio-particle furnace of the present invention.

In the figure: 1. the furnace body, 2, the ignition rod, 3, the outer air box, 4, the lower air inlet hole, 5, the blower, 6, the middle air inlet hole, 7, the upper air inlet hole, 8, the heat dissipation cavity, 9, the heat dissipation cavity, 10, the fire baffle plate, 11, the heat conduction window, 12, the upper air box, 13, the upper air box, 14, the middle air box, 15, the middle air box, 16, 17, the pot support, 18, the feeding pipe, 19, the feeding pipe, 20, the storage hole, 21, the discharging hole, 22, the upper tray, 23, the upper tray motor, 24, the hopper, 25, the upper tray housing, 26, the feeding hole, 27, the heat insulation ring, 28, 29, the air box bottom plate, 30, the lower air box, 31, the air supply pipe, 32, the furnace chamber wall, 33, the grate bracket, 34, 35, the leakage hole, 36, 37, the partition plate, 38, the auger mechanism, 39, the auger motor.

Detailed Description

The biological particle furnace according to the invention is further described below with reference to the accompanying drawings and specific examples:

fig. 1 is a schematic view of the structure of the bio-particle furnace of the present invention, fig. 2 is a plan view of fig. 1, fig. 3 is a sectional view A-A of fig. 1, fig. 4 is a sectional view B-B of fig. 1, and fig. 5 is a sectional view C-C of fig. 1. In the figure, a furnace chamber 16 is arranged in a furnace body 1 of the biological particle furnace, an ash bin 36 is arranged below the furnace chamber 16, a wind box is arranged between a furnace chamber wall 32 and the furnace body 1, a heat insulation ring 27 is arranged in the wind box, the wind box is divided into an inner wind box and an outer wind box by the heat insulation ring 27, the outer wind box 3 is communicated with a blower 5, the inner wind box is divided into an upper wind box 12, a middle wind box and a lower wind box 12, 14 and 28 by a partition plate 37 according to the stair shape of the furnace chamber, and the heat insulation ring 27 is respectively provided with an upper wind inlet hole 7, a middle wind box and a lower wind inlet hole 6 and 4 at the three wind boxes to respectively communicate the outer wind box 3 with the upper wind box 12, the middle wind box and the lower wind box 28. The upper wind box 12 and the hearth 16 are provided with five-ring wind box wind outlet holes 13 on the hearth wall, four-ring wind box wind outlet holes 15 are arranged on the hearth wall between the middle wind box 14 and the hearth 16, three-ring lower wind box wind outlet holes 30 are arranged on the hearth wall between the lower wind box 28 and the hearth 16, the axes of the wind outlet holes on the vertical section below the hearth wall 32 are obliquely arranged, the wind box end is low, the hearth end is high, and meanwhile, the axes of the wind outlet holes are obliquely arranged along the circumference of the hearth wall, so that wind entering the hearth rotates along the hearth wall, the wind outlet holes of the two rings above the wind outlet holes of the vertical section below the hearth wall 32 are larger than the wind outlet holes of the two rings below the wind outlet holes, a heat dissipation cavity 8 is arranged above the outer wind box 3, a heat dissipation pipe 9 is arranged on the heat dissipation cavity 8, a heat dissipation pipe 9 can be connected to a heating radiator or a hot water tank, a heat dissipation window 11 is arranged between the heat dissipation cavity 8 and the hearth 16, and the upper flame in the hearth can enter the cavity 8 through the heat dissipation window 11, heat dissipation energy can be fully utilized, and unnecessary heat dissipation is avoided. The upper end of furnace 16 is provided with inlet pipe 19 and stretches to the outside of furnace body 1, inlet pipe 19 is connected with loading attachment, this loading attachment is including erect circular charging tray 22, four penetrating storage holes 20 have been evenly distributed on the charging tray 22, the charging tray 22 outside is provided with charging tray shell 25, discharge hole 21 and inlet pipe 19 UNICOM have been seted up to the inboard upper portion of charging tray shell 25, feed hole 26 has been seted up to the outside lower part of charging tray shell 25, feed hole 26 connects hopper 24, charging tray 22 passes through charging tray motor 23 drive rotation, when storage hole 20 and feed hole 26 are in the face up, granule material in the hopper just falls to in the storage hole 20, along with the rotation of charging tray 22, be blocked by charging tray shell 25 between storage hole 20 and the hopper 24, when storage hole 20 and discharge hole 21 are in the face up, granule material in the storage hole 20 will slide in furnace 16 along with inlet pipe 19 and burn. The loading tray 22 may be rotated by a motor or may be manually rotated. The outer bellows 3 communicates with a blower 5, and air is blown into the bellows by the blower. A grate 34 is arranged between the hearth 16 and the ash bin 36, the grate 34 is fixed on the bellows bottom plate 29 at the bottom of the hearth through a grate support 33, the grate support 33 is arranged oppositely for two horizontally arranged U-shaped slideways, the grate 34 is arranged in the slideways, the grate is provided with a drain hole 35, the drain hole 35 is a taper hole with a large upper part and a small lower part, the grate can be freely taken out from the slideways, and the grate is detachable, so that the agglomerated slag at the grate can be conveniently cleaned. An air supply pipe 31 for blowing air to the grate 34 is arranged in the ash bin 36, and the air supply pipe 31 is communicated with the outer air box 3. Three uniformly distributed pot supports 17 are arranged on the periphery of a hearth opening on the upper top end surface of the furnace body 1, and a fire baffle 10 is arranged on one side between the two pot supports, which is convenient for a person to stand, so that the fire is prevented from jumping out from one side where the person stands. An ignition rod 2 is arranged at the bottom of the hearth 16 near the grate, and the ignition rod 2 passes through the hearth from the outside of the furnace body. The granule material is piled up to the lower part of furnace 16, stretches ignition stick 2 to the granule material centre, and the resistance wire is heated to the circular telegram, and the resistance wire of fever red ignites the granule material, and the air-blower blows the wind and provides sufficient oxygen in the furnace, makes granule material fully burn.

FIG. 6 is a schematic view of another construction of the bio-particle furnace of the present invention. As another feeding structure, an auger mechanism 38 is arranged at the inlet end of the feeding pipe 19, an auger hopper 39 is arranged above the auger mechanism 38, and the auger mechanism is driven by an auger motor 40 to convey the granular materials into the hearth through the rotation of the auger.

The air supply in the hearth of the biological particle furnace is rotary air supply, and air outlet holes are formed in the hearth from top to bottom, so that the granular materials are fully combusted, thoroughly combusted, discharged in a smokeless manner and environment-friendly and pollution-free. The biological particle furnace has large firepower and high combustion efficiency, and saves 50% of materials compared with other biological particle furnaces.

The present invention is not limited to the above-mentioned embodiments, but is intended to be limited to the above-mentioned embodiments, and any person skilled in the art will readily appreciate that many modifications, equivalent changes and modifications are possible in the embodiments without departing from the scope of the present invention.

Claims

1. The utility model provides a biological particle stove, includes the furnace body, is provided with furnace in the furnace body, sets up ash bin, its characterized in that under the furnace: the furnace is large and small in upper part and small in lower part and is in a ladder shape, an air box is arranged between the furnace wall and the furnace body wall, a heat insulation ring is arranged in the air box, the air box is divided into an inner air box and an outer air box by the heat insulation ring, the outer air box is communicated with a blower, the inner air box is divided into an upper layer of air box, a middle layer of air box and a lower layer of air box by a partition plate according to the ladder shape of the furnace, and an upper air inlet hole, a middle air inlet hole and a lower air inlet hole are respectively arranged at the three air boxes on the heat insulation ring to respectively communicate the outer air box with the upper air box, the middle air box and the lower air box; the furnace wall between the upper air box and the furnace is provided with five-ring air outlet holes, the furnace wall between the middle air box and the furnace is provided with four-ring middle air outlet holes, the furnace wall between the lower air box and the furnace is provided with three-ring lower air outlet holes, the axis of the air outlet holes on the vertical section below the furnace wall is obliquely arranged, the end of the air box is low, the end of the furnace is high, and simultaneously, the axis of the air outlet holes is obliquely arranged along the circumference of the furnace wall, so that the air entering the furnace rotates along the furnace wall, the two-ring air outlet holes above the air outlet holes on the vertical section below the furnace wall are larger than the two-ring air outlet holes below the air outlet holes, a heat dissipation cavity is arranged above the air box, a heat dissipation pipe is arranged on the heat dissipation cavity, a heat conduction window is arranged between the heat dissipation cavity and the furnace, a feeding pipe is arranged on the furnace and extends outside the furnace body, the feeding pipe is connected with a feeding device, the bottom of the furnace is externally connected with a blower, a furnace rod is arranged at the bottom of the furnace, a grate is fixedly arranged on the bottom of the furnace through a furnace bracket, the furnace is communicated with an ignition grate, and an air supply pipe is arranged in the furnace chamber.

2. A biological particle furnace according to claim 1, wherein: the grate support is arranged in a manner that two horizontally arranged U-shaped slideways are opposite, the grate is arranged in the slideways, the grate is provided with a drain hole, and the drain hole is a taper hole with a big upper part and a small lower part.

3. A biological particle furnace according to claim 1, wherein: the furnace mouth periphery on the upper top end face of the furnace body is provided with three uniformly distributed pot supports, and one side between two of the pot supports, which is convenient for a person to stand, is provided with a fire baffle plate to prevent the flame from jumping out from one side where the person stands.

4. A biological particle furnace according to claim 1, wherein: an ignition rod is arranged at the lower end of the hearth and close to the grate, and the ignition rod penetrates into the hearth from the outside of the furnace body.

5. A biological particle furnace according to claim 1, wherein: the feeding device comprises a vertical circular feeding disc, a plurality of through storage holes are uniformly distributed in the feeding disc, a feeding disc shell is arranged on the outer side of the feeding disc, a discharging hole is formed in the upper portion of the inner side of the feeding disc shell and is connected with the feeding pipe, a feeding hole is formed in the lower portion of the outer side of the feeding disc shell, and the feeding hole is connected with the hopper.

6. A biological particle furnace as claimed in claim 5, wherein: the feeding disc can be driven by a motor or manually rotated.

7. A biological particle furnace according to claim 1, wherein: the feeding device comprises a packing auger mechanism, a discharge hole of the packing auger mechanism is connected with the feed pipe, a storage hopper is arranged on the packing auger mechanism, and the packing auger mechanism is driven by a motor.