CN220211237U

CN220211237U - Gas type self-turbulence orchard temperature compensation furnace

Info

Publication number: CN220211237U
Application number: CN202321311932.9U
Authority: CN
Inventors: 曲同建; 范红年
Original assignee: Ningxian Hongjianxing Technology Co ltd
Current assignee: Ningxian Hongjianxing Technology Co ltd
Priority date: 2023-05-29
Filing date: 2023-05-29
Publication date: 2023-12-22
Anticipated expiration: 2033-05-29

Abstract

The utility model relates to the field of frostbite prevention of fruit trees, in particular to a gas type self-turbulence orchard temperature compensating furnace. A shell is also arranged in the middle of the shell of the furnace, a first rising cavity (10) is arranged in the shell, and hot gas burnt at the furnace mouth can continuously rise along the first rising cavity (10); the caliber of the partition plate (11) is larger than the caliber of the uppermost part of the first ascending cavity (10); a guide partition plate (12) is arranged above more than one partition plate (11), and the guide partition plate (12) comprises a lifting hole in the middle part and descending guide plates around the guide partition plate (12); a plurality of annular side cooling fins (6) protruding outwards are arranged on the outer shell outside the furnace. The beneficial effects are that: the fire is controlled within a certain range, so that the fire can be taken away by blowing wind, and surrounding farmlands are ignited. Can increase area of contact with peripheral air, let more heat distribute around the fruit tree, and then let the fruit tree be difficult for by the frostbite.

Description

Gas type self-turbulence orchard temperature compensation furnace

Technical Field

The utility model relates to the field of frostbite prevention of fruit trees, in particular to a gas type self-turbulence orchard temperature compensating furnace.

Background

The 'cold in the spring of the early spring' damages the normal growth of the fruit tree, and the flower generation is a serious problem which is long plagued for fruit growers in northwest areas of China, and can cause large-area yield reduction and even absolute yield of apples; there has long been no good solution.

However, the fruit growers can adopt various heating means to avoid loss, but a great deal of manpower and energy waste is caused.

For example, when the waste fruit tree branches are used for ignition, people can see the waste fruit tree branches overnight, so that the temperature around the fruit tree can be properly increased, but the defect is that hot air quickly spreads in the air and flows upwards, and heat exchange with the periphery cannot be performed as much as possible.

The later-stage greenhouse arrangement for heat preservation is not practical, and some fruit trees are not suitable for the greenhouse.

The cold-proof device for fruit tree cultivation disclosed in CN213784466U has high cost, and the direct contact structure can limit other operations to a certain extent, such as local pesticide spraying, root irrigation, branch trunk of the foundation part and the like.

Disclosure of Invention

The purpose of the utility model is that: in order to provide a gas type self-turbulence orchard temperature compensating furnace with better effect and a temperature dispersing method, specific purposes are shown in a plurality of substantial technical effects of a specific implementation part.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the gas type self-turbulence orchard temperature compensating furnace is characterized by comprising a bracket, wherein the bottom wall of the furnace is supported above the bracket 1, a furnace mouth 2 is arranged above the bottom wall, a shell is also arranged in the middle of the shell of the furnace, a first rising cavity 10 is arranged in the shell, and hot gas burnt at the furnace mouth can continuously rise along the first rising cavity 10;

above the first lifting chamber 10 is a partition plate 11, the partition plate 11 comprising more than one; the caliber of the partition plate 11 is larger than the caliber of the uppermost part of the first ascending cavity 10;

above one or more partition plates 11 is a guide partition plate 12, the guide partition plate 12 comprises a rising hole in the middle and a descending guide plate around the guide partition plate 12;

a plurality of outwardly projecting annular side fins 6 are included on the outer shell of the furnace.

The utility model further adopts the technical scheme that an upper cavity is arranged above the guide partition plate 12.

The utility model further adopts the technical scheme that the upper cavity 4 is wholly cylindrical.

The further technical scheme of the utility model is that an upper heat dissipation head is arranged above the upper cavity 4, the upper heat dissipation head 5 comprises a structure formed by combining a plurality of groups of curved lamellar structures, and gaps are arranged between a plurality of adjacent curved lamellar structures for upward hot air discharge.

The utility model further adopts the technical scheme that the heat dissipation device also comprises side brackets 7, wherein the side brackets 7 are of vertical rod-shaped structures, and a plurality of side cooling fins are connected in series by the vertical rod-shaped structures.

A further solution of the utility model consists in arranging a burner disc 8 in the furnace mouth 2.

The utility model further provides that the combustion disk 8 has a structure capable of placing combustible materials for combustion.

The utility model further provides that the combustion disk 8 is of a combustion structure connected with natural gas through a pipe 9, and that the combustion disk is provided with a flame nozzle.

A further solution of the utility model consists in arranging a plurality of heat-dissipating holes 3 in the housing of the furnace.

The further technical scheme of the utility model is that a liquid storage barrel 13 is arranged above the upper radiating head, a liquid pipe 15 extends out of the liquid storage barrel 13, a valve 14 is arranged on the liquid pipe 15, the valve 14 is guided to a transpiration space 16, and the transpiration space 16 is positioned above the guide partition plate 12.

The further technical proposal of the utility model is that the guide separation plate 12 is used as a drip tray, a plurality of micropores are arranged on the drip tray, and the middle part of the guide separation plate 12 is provided with a liquid containing part 17.

The method for supplementing the temperature of the gas type self-turbulence orchard is characterized by comprising the following steps of,

after combusting combustible substances or natural gas, the hot gas rises along the first rising cavity 10, then locally rises and locally descends after passing through the partition plate 11, and the contact surface between the hot gas and the surrounding environment is increased by prolonging the hot gas passing path, so that the temperature of the surrounding air is gradually increased, and the hot gas is prevented from being rapidly emitted to the high altitude. Compared with the prior art, the utility model adopting the technical scheme has the following beneficial effects: besides the effects of temperature compensation and self-turbulence of the first-generation gas self-turbulence orchard temperature compensation furnace, a liquid storage barrel is additionally arranged above the furnace body, and the liquid storage barrel is automatically instilled to a liquid dropping disc arranged in the middle of the furnace body through a drainage tube. Through the micropores on the drip tray, the liquid can be slowly instilled into the high-temperature furnace chamber for gasification, and part of the liquid can generate smoke effect which is dispersed along with the high-temperature gas, so that the effects of spraying the foliar fertilizer, applying medicine, sterilizing and the like are generated in the environment. Meanwhile, part of water in the liquid can react with insufficiently combusted carbon components in the furnace chamber to generate water gas, so that more violent combustion is formed. Aiming at the defects of the prior art, the ignition of waste fruit tree branches is utilized, people look at the fruit tree branches overnight, one of the main reasons is that the fire is not controlled, the flame is small, the heating effect is not achieved, the flame is large, the fruit trees are easy to burn, and the gaps between the fruit trees are very small and controlled. The outstanding advantage of this patent lies in: the fire is controlled within a certain range, so that the fire can be taken away by blowing wind, and surrounding farmlands are ignited. The utility model uses gas combustion as a heat source, and the special structure of the furnace body is used for effectively controlling the combustion and the heat dissipation of the gas, so that the temperature compensation operation is carried out on places needing temperature compensation, such as orchards, vegetable gardens and the like, with low cost and high efficiency. Meanwhile, different solutions are filled in a special cavity at the upper part of the furnace to form steam, so that the effects such as combustion supporting, leaf fertilizer spraying, pesticide application, disinfection and the like are generated, and the labor effect is improved.

The defect that the hot air rapidly spreads in the air to flow upwards and cannot exchange heat with the periphery as much as possible is overcome in the prior art. The outstanding advantage of this patent is: can increase area of contact with peripheral air, let more heat distribute around the fruit tree, and then let the fruit tree be difficult for by the frostbite. The cold-proof device for fruit tree cultivation disclosed by CN213784466U is not limited to other operations, and does not affect local pesticide spraying, root irrigation, branch trunk of a base part and the like.

Drawings

For further explanation of the utility model, reference is made to the following further description, taken in conjunction with the accompanying drawings:

FIG. 1 is a schematic diagram of the structure of the utility model;

FIG. 2 is a schematic view of the internal structure thereof, partially cut away;

FIG. 3 is a further improved block diagram of the utility model;

FIG. 4 is another view block diagram of FIG. 3 of the utility model;

1. the furnace comprises a bracket, a furnace mouth, a heat dissipation hole, an upper cavity, an upper heat dissipation head, side heat dissipation fins, side brackets, a combustion disk, a pipeline, a first lifting cavity, a partition plate and a guide partition plate, wherein the furnace mouth, the heat dissipation hole, the upper cavity, the upper heat dissipation head, the side heat dissipation fins, the side brackets, the combustion disk, the pipeline, the first lifting cavity, the partition plate and the guide partition plate are arranged in sequence, and the furnace mouth, the heat dissipation hole, the upper cavity, the upper heat dissipation head, the side heat dissipation fins, the side brackets, the combustion disk, the upper heat dissipation plate and the guide partition plate are arranged in sequence; 13 a liquid storage barrel; 14. a valve; 15. a liquid tube; 16. a transpiration space; 17. a liquid containing portion.

Detailed Description

The present utility model is further illustrated in the following drawings and detailed description, which are to be understood as being merely illustrative of the utility model and not limiting the scope of the utility model. In the description of the present utility model, it should be noted that the positional or positional relationship indicated by the terms such as "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", "top", "bottom", etc. are based on the positional or positional relationship shown in the drawings, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model. Furthermore, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

The patent provides a plurality of parallel schemes, and the different expressions belong to an improved scheme based on a basic scheme or a parallel scheme. Each scheme has its own unique features. In addition, the technical features of the different embodiments of the present utility model described below may be combined with each other as long as they do not collide with each other. The fixing manner not described herein may be any fixing manner such as screw fixing, bolt fixing or glue bonding.

Embodiment one: with reference to the entire drawing; the gas type self-turbulence orchard temperature compensating furnace is characterized by comprising a bracket, wherein the bottom wall of the furnace is supported above the bracket 1, a furnace mouth 2 is arranged above the bottom wall, a shell is also arranged in the middle of the shell of the furnace, a first rising cavity 10 is arranged in the shell, and hot gas burnt at the furnace mouth can continuously rise along the first rising cavity 10;

The essential technical effects and the realization process thereof, namely the basic functions, played by the technical proposal are as follows: the method for supplementing the temperature of the gas type self-turbulence orchard is characterized by comprising the following steps of burning combustible materials or natural gas, enabling hot gas to ascend along the first ascending cavity 10, enabling the hot gas to locally ascend and locally descend through the partition plate 11, increasing the contact surface between the hot gas and the surrounding environment in a mode of prolonging the passing path of the hot gas, and further enabling the surrounding air to gradually heat up so that the hot gas cannot be rapidly emitted to the high altitude.

Compared with the prior art, the method is as follows:

aiming at the defects of the prior art, the ignition of waste fruit tree branches is utilized, people look at the fruit tree branches overnight, one of the main reasons is that the fire is not controlled, the flame is small, the heating effect is not achieved, the flame is large, the fruit trees are easy to burn, and the gaps between the fruit trees are very small and controlled. The outstanding advantage of this patent lies in: the fire is controlled within a certain range, so that the fire can be taken away by blowing wind, and surrounding farmlands are ignited.

Embodiment two: as a further improvement or juxtaposition or alternatively independent, the guide partition plate 12 has an upper cavity above. The essential technical effects and the realization process thereof, namely the basic functions, played by the technical proposal are as follows: the upper cavity is used as one of the transfer spaces of the hot air, and is essentially used for increasing the contact area with the air as much as possible after the hot air rising last time is blocked again.

Embodiment III: as a further development or juxtaposition or alternatively independent, the upper cavity 4 is entirely cylindrical. The essential technical effects and the realization process thereof, namely the basic functions, played by the technical proposal are as follows: the upper part of the upper cavity 4 is used for connecting an upper heat radiating head 5.

Embodiment four: as a further improvement, a parallel arrangement or an alternative independent arrangement, an upper heat dissipation head is arranged above the upper cavity 4, and the upper heat dissipation head 5 comprises a structure formed by combining a plurality of groups of bent arc-shaped sheet structures, wherein gaps are arranged between a plurality of adjacent bent arc-shaped sheet structures for upward hot air discharge. The essential technical effects and the realization process thereof, namely the basic functions, played by the technical proposal are as follows: therefore, the hot air can be guided to different directions as much as possible while the heat is sufficiently dissipated from the periphery. The turbulent flow effect of the furnace, the heat dissipation head rotates to play a role of automatic turbulent flow, the periphery of the hot air is stirred, and the problems of energy waste and low local temperature far away from the fire source due to direct rising of hot air are avoided. The heat dissipation head is an autorotation ventilator of a factory workshop, namely an exhaust ball; also called exhaust hood air ball, also called hood exhaust ball. The upper heat sink 5 can be rotated or not rotated. Non-rotatable, to further implement embodiments eight and nine.

Fifth embodiment: as a further improvement or juxtaposition or alternatively independent, the heat exchanger further comprises side brackets 7, wherein the side brackets 7 are in a vertical rod-like structure, and a plurality of side heat radiating fins are strung together by the vertical rod-like structure. The essential technical effects and the realization process thereof, namely the basic functions, played by the technical proposal are as follows: the overall stability of the structure of this embodiment is better, conveniently moves.

Example six: as a further development or juxtaposition or alternatively independent, a burner disc 8 is arranged in the furnace mouth 2. The essential technical effects and the realization process thereof, namely the basic functions, played by the technical proposal are as follows: the following embodiments are any of the following: 1. the combustion plate 8 is configured to be capable of holding combustible materials for combustion. 2. A flame nozzle is arranged on the combustion disk.

Embodiment seven: as a further development or juxtaposition or alternatively independent, a plurality of heat dissipation openings 3 are arranged in the housing of the furnace. The essential technical effects and the realization process thereof, namely the basic functions, played by the technical proposal are as follows: the heat dissipation holes facilitate heat dissipation.

Example eight: as a further improvement or juxtaposition or alternative independent solution, a liquid storage barrel 13 is arranged above the upper heat dissipation head, a liquid pipe 15 extends out of the liquid storage barrel 13, a valve 14 is arranged on the liquid pipe 15, the valve 14 leads to a transpiration space 16, and the transpiration space 16 is arranged above the guide partition plate 12. The essential technical effects and the realization process thereof, namely the basic functions, played by the technical proposal are as follows: besides the effects of temperature compensation and self-turbulence of the first-generation gas self-turbulence orchard temperature compensation furnace, a liquid storage barrel is additionally arranged above the furnace body, and the liquid storage barrel is automatically instilled to a liquid dropping disc arranged in the middle of the furnace body through a drainage tube. Through the micropores on the drip tray, the liquid can be slowly instilled into the high-temperature furnace chamber for gasification, and part of the liquid can generate smoke effect which is dispersed along with the high-temperature gas, so that the effects of spraying the foliar fertilizer, applying medicine, sterilizing and the like are generated in the environment. Meanwhile, part of water in the liquid can react with insufficiently combusted carbon components in the furnace chamber to generate water gas, so that more violent combustion is formed.

Example nine: as a further development or juxtaposition or alternatively independent, the guide partition plate 12 serves as a drip tray on which a plurality of micro-holes are arranged, and the middle of the guide partition plate 12 is provided with a liquid containing portion 17.

The effects are independently provided, and the combination of the effects can be achieved by a set of structures.

It should be noted that, the multiple schemes provided in this patent include the basic schemes of itself, are independent of each other and are not restricted to each other, but they can also be combined with each other under the condition of no conflict, so as to achieve multiple effects together.

The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the foregoing embodiments, which have been described in the foregoing description merely illustrates the principles of the utility model, and that various changes and modifications may be made therein without departing from the spirit and scope of the utility model, which is defined in the appended claims.

Claims

1. The gas type self-turbulence orchard temperature compensating furnace is characterized by comprising a bracket, wherein the bottom wall of the furnace is supported above the bracket (1), a furnace mouth (2) is arranged above the bottom wall, a shell is also arranged in the middle of the shell of the furnace, a first rising cavity (10) is arranged in the shell, and hot gas burnt at the furnace mouth can continuously rise along the first rising cavity (10);

a partition plate (11) is arranged above the first lifting cavity (10), and the partition plate (11) comprises more than one; the caliber of the partition plate (11) is larger than the caliber of the uppermost part of the first ascending cavity (10);

a guide partition plate (12) is arranged above more than one partition plate (11), and the guide partition plate (12) comprises a lifting hole in the middle part and descending guide plates around the guide partition plate (12);

a plurality of annular side cooling fins (6) protruding outwards are arranged on the outer shell outside the furnace.

2. The gas type self-turbulence orchard temperature compensating furnace as claimed in claim 1, wherein the upper part of the guide partition plate (12) is an upper cavity.

3. A gas-fired self-turbulent orchard temperature compensating furnace according to claim 2, wherein the upper cavity (4) is cylindrical in shape as a whole.

4. A gas-fired self-turbulent orchard temperature compensating furnace as claimed in claim 3, wherein an upper heat dissipating head is arranged above the upper cavity (4), the upper heat dissipating head (5) comprises a structure formed by combining a plurality of groups of curved sheet structures, and gaps are formed between a plurality of adjacent curved sheet structures for upward hot gas discharge.

5. The gas-fired self-turbulent orchard temperature-compensating furnace according to claim 1, further comprising side brackets (7), wherein the side brackets (7) are of a vertical rod-like structure, and a plurality of side cooling fins are connected in series by the vertical rod-like structure.

6. The gas-fired self-turbulent orchard temperature-compensating furnace according to claim 1, wherein a combustion disc (8) is arranged in the furnace mouth (2).

7. The gas-fired self-turbulence orchard temperature compensating furnace as claimed in claim 6, wherein the combustion disc (8) has a structure capable of placing combustible materials for combustion; the combustion disk (8) is a combustion structure connected with natural gas through a pipeline (9), and a flame nozzle is arranged on the combustion disk; a plurality of heat dissipation holes (3) are arranged on the shell of the furnace.

8. The gas type self-turbulence orchard temperature supplementing furnace according to claim 4, wherein a liquid storage barrel (13) is arranged above the upper radiating head, a liquid pipe (15) extends out of the liquid storage barrel (13), a valve (14) is arranged on the liquid pipe (15), the valve (14) is guided to a transpiration space (16), and the transpiration space (16) is located above the guide partition plate (12).

9. The gas-fired self-turbulent orchard temperature compensating furnace according to claim 8, wherein the guide partition plate (12) is used as a drip tray, a plurality of micro-holes are arranged on the drip tray, and a liquid containing part (17) is arranged in the middle of the guide partition plate (12).