CN114798700A

CN114798700A - Heating pipe structure and organic garbage disposer applying same

Info

Publication number: CN114798700A
Application number: CN202210416219.4A
Authority: CN
Inventors: 褚柏山; 徐刚
Original assignee: Shenzhen Dashu Bioenvironmental Technology Co ltd
Current assignee: Shenzhen Dashu Bioenvironmental Technology Co ltd
Priority date: 2022-04-20
Filing date: 2022-04-20
Publication date: 2022-07-29

Abstract

The invention provides a heating pipe structure and an organic garbage disposer applying the same, wherein the heating pipe structure part is used for accommodating a heat-conducting medium and comprises a plurality of heating parts which are connected in sequence; the heating part comprises a plurality of groups of liquid storage pipes, one end of each liquid storage pipe is provided with a connecting pipe, and the other end of each liquid storage pipe is provided with a communicating pipe; wherein, the heating part is connected with the adjacent heating part through the connecting pipe, the heating parts at the head and the tail ends are also correspondingly provided with an inlet through pipe and an outlet through pipe, the inlet through pipe is positioned at one end of the connecting pipe, and the inlet through pipe is not communicated with the connecting pipe; the outlet through pipe is positioned at one end of the communicating pipe, and the outlet through pipe and the communicating pipe are not communicated with each other; through reasonable design, the heat-conducting medium flows into heating portion in proper order to flow to import siphunculus, liquid storage pipe, communicating pipe and linking pipe in proper order, and heating portion arranges in proper order at the internal storehouse, makes the internal temperature rise in storehouse rapidly, and the heat preservation effect is good, and then solves the problem in the current.

Description

Heating pipe structure and organic garbage disposer applying same

Technical Field

The invention belongs to the field of organic garbage disposer assembly, and particularly relates to a heating pipe structure and an organic garbage disposer applying the same.

Background

With the development of society, the living conditions of materials are more and more perfect, the generated organic garbage is more and more increased, and in the process of treating the organic garbage, the organic garbage can be fermented, transported, crushed and the like by an organic garbage processor; the organic garbage processor is provided with a bin body for storing organic garbage, and fermentation treatment is mainly divided into two steps, namely, the garbage in the bin body is subjected to harmful bacterial colony inactivation through high temperature, and the temperature in the bin body is kept in a constant interval, so that a temperature condition suitable for microbial growth is provided, and heating and constant temperature keeping are realized through a heating structure;

in the existing heating structure, the bin body is heated by adopting the patch type heating film, although the heating can quickly raise the temperature, the temperature is uneven in the bin body and the heat preservation performance is poor, so that the fermentation treatment effect is poor; and through laying the heating pipeline in storehouse body adjacent side, quote heat-conducting medium, this structure can reach the comparatively even technological effect of temperature, nevertheless, the both ends of pipeline generally adopt the return bend to link up, and the structure is comparatively single, appears the pipeline distribution interval sparsely easily, leads to the programming rate slower, consequently, need a neotype heating tube structure urgently, be applied to organic refuse treatment machine, and then solve the above-mentioned problem that appears.

Disclosure of Invention

Aiming at the defects in the technology, the invention provides the heating pipe structure, and through the ingenious design, the heat-conducting medium can be directly and sequentially led to the plurality of heating parts, so that the temperature in the bin body is rapidly and uniformly increased.

In order to achieve the above object, the present invention provides a heating tube structure for accommodating a heat conducting medium, comprising a plurality of heating portions connected in sequence; the heating part comprises a plurality of groups of liquid storage pipes, one end of each liquid storage pipe is provided with a connecting pipe, and the other end of each liquid storage pipe is provided with a communicating pipe;

the heating parts are connected with adjacent heating parts through linking pipes, the two heating parts at the head and tail ends are correspondingly provided with an inlet through pipe and an outlet through pipe, the inlet through pipe is positioned at one end of the linking pipe, and the inlet through pipe is not communicated with the linking pipes; the outlet through pipe is positioned at one end of the communicating pipe, and the outlet through pipe and the communicating pipe are not communicated with each other.

Wherein, the inlet through pipe is provided with a liquid inlet for the heat-conducting medium to enter.

Wherein, the inlet through pipe is also provided with a liquid inlet pipe, one end of the liquid inlet pipe is communicated with the liquid inlet, and the other end is provided with a switch valve port.

Wherein, the export siphunculus is equipped with the liquid outlet that is used for heat-conducting medium to flow out.

Wherein, the export siphunculus still is equipped with the drain pipe, and the one end and the liquid outlet of drain pipe are linked together, and the other end extends to first heating portion.

The invention also provides an organic garbage processor, which comprises a motor device, a bin body, a main shaft device, a heating device and the heating pipe structure, wherein the main shaft device and the heating pipe structure are assembled in the bin body; the heating device comprises an output pipe and a return pipe, the output pipe is communicated with the inlet through pipe, and the return pipe is communicated with the outlet through pipe.

The heating device comprises a main box body, a pump body and a heating cavity, wherein the heating cavity is accommodated in the main box body and is in adaptive connection with an inlet of the pump body; the heating cavity is internally provided with a heater and a heat-conducting medium.

Wherein, still include the propulsion oar that the multiunit set up, the propulsion oar is the heliciform and assembles respectively on spindle unit.

Wherein, the storehouse body still includes the grid of giving vent to anger that is used for discharging the produced gas of fermentation bacterial colony.

Wherein, the storehouse is internal still to be provided with the multiunit and be used for carrying out the baffle of separating the internal chamber of storehouse.

The invention has the beneficial effects that: compared with the prior art, the invention provides a heating pipe structure which is used for accommodating a heat-conducting medium and comprises a plurality of heating parts which are connected in sequence; the heating part comprises a plurality of groups of liquid storage pipes, one end of each liquid storage pipe is provided with a connecting pipe, and the other end of each liquid storage pipe is provided with a communicating pipe; the front heating part is connected with the adjacent heating part through a connecting pipe, the two heating parts at the head end and the tail end are correspondingly provided with an inlet through pipe and an outlet through pipe, the inlet through pipe is positioned at one end of the connecting pipe, and the inlet through pipe is not communicated with the connecting pipe; the outlet through pipe is positioned at one end of the communicating pipe, and the outlet through pipe and the communicating pipe are not communicated with each other; through reasonable design, the heat-conducting medium flows into heating portion in proper order to according to flow direction import siphunculus, liquid storage pipe, communicating pipe and linking pipe, and heating portion arranges in proper order at the internal storehouse, makes the internal temperature rise in storehouse rapidly, and the heat preservation effect is good, and then solves the problem in the current.

Drawings

FIG. 1 is a perspective view of a heating tube structure of the present invention;

FIG. 2 is a schematic view of a heater tube according to the present invention;

FIG. 3 is a front view of an organic waste disposer employing a heating tube structure of the present invention;

FIG. 4 is a perspective view of an organic waste disposer incorporating the heating tube structure of the present invention;

fig. 5 is a perspective view of a heating apparatus of an organic waste disposer employing the structure of the heating pipe of the present invention.

The main element symbols are as follows:

1. a first heating section; 11. a first heating group of tubes; 12. a first communication pipe; 13. an inlet pipe;

14. a first linking tube; 15. a liquid inlet pipe; 16. switching a valve buckle; 2. a second heating section;

21. a second heating bank; 22. a second linking tube; 23. a second communicating pipe; 3. a third heating section;

31. a third heating bank; 32. an outlet through pipe; 33. a liquid outlet pipe; 4. a motor device; 5. a bin body;

51. a partition plate; 52. an air outlet grid; 6. a spindle device; 61. a propulsion paddle; 7. a heating device;

71. an output pipe; 72. a return pipe; 73. a main box body; 74. a pump body; 75. a chamber is heated.

Detailed Description

In order to more clearly describe the present invention, the present invention will be further described with reference to the accompanying drawings.

In the following description, details of general examples are given to provide a more thorough understanding of the present invention. It is to be understood that the described embodiments are merely exemplary of the invention, and not restrictive of the full scope of the invention. It should be understood that the specific embodiments are illustrative of the invention and are not to be construed as limiting the invention.

It will be understood that the terms "comprises" and/or "comprising," when used in this specification, specify the presence of stated features, integers, steps, operations, elements, or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or groups thereof.

In the current, through laying the heating tube way in storehouse body adjacent side, quote heat-conducting medium, this structure can reach the comparatively even technological effect of temperature, but, the both sides of pipeline generally adopt the return bend to link up, and the structure is comparatively single, and it is sparse to appear the pipeline distribution interval easily, leads to the programming rate slower, consequently, needs a neotype heating tube structure urgently, is applied to organic refuse treatment machine, and then solves the above-mentioned problem that appears.

In order to solve the above problems, the present invention provides a heating tube structure for accommodating a heat conducting medium, comprising a plurality of heating portions connected in sequence; the heating part comprises a plurality of groups of liquid storage pipes, one end of each liquid storage pipe is provided with a connecting pipe, and the other end of each liquid storage pipe is provided with a communicating pipe; the former heating part is connected with the adjacent heating part through a connecting pipe, the two heating parts at the head end and the tail end are correspondingly provided with an inlet through pipe 13 and an outlet through pipe 32, the inlet 31 through pipe is positioned at one end of the connecting pipe, and the inlet through pipe 13 is not communicated with the connecting pipe; the outlet through pipe 32 is positioned at one end of the communicating pipe, and the outlet through pipe 31 is not communicated with the communicating pipe; in order to further accurately explain and facilitate understanding of the present solution, the present embodiment includes a first heating portion 1, a second heating portion 2, and a third heating portion 3, which are connected in sequence, please refer to fig. 1 to 2;

the first heating part 1 comprises a first heating pipe group 11 consisting of a plurality of liquid storage pipes, one end of the first heating pipe group 11 is provided with a first communication pipe 12, the other end of the first heating pipe group is provided with an inlet communication pipe 13 and a first connecting pipe 14, the inlet communication pipe 13 is not communicated with the first connecting pipe 14, and the first connecting pipe 14 is connected to the second heating part 2;

the second heating part 2 comprises a second heating pipe group 21 consisting of a plurality of liquid storage pipes, a second connecting pipe 22 is arranged at one end of the second heating pipe group 21 connected with the first connecting pipe 14, and the second connecting pipe 22 is not communicated with the first connecting pipe 14; a second communication pipe 23 provided at the other end of the second heating pipe group 21, the second communication pipe 23 and the second connection pipe 22 being connected to the third heating part 3;

the third heating part 3 comprises a third heating pipe group 31 consisting of a plurality of liquid storage pipes, one end of the third heating pipe group 31 is connected with the second connecting pipe 22, the other end of the third heating pipe group 31 is connected with the second communicating pipe 23, an outlet through pipe 32 is further arranged, and the outlet through pipe 32 is not communicated with the second communicating pipe 23;

it can be understood that, in this embodiment, after the heat-conducting medium is heated, the heat-conducting medium is pumped to the inlet through pipe 13, the inlet through pipe 13 is communicated with a part of the pipes of the first heating pipe set 11, and the inlet through pipe 13 is not communicated with the first connecting pipe 14, so that the flow direction of the heat-conducting medium in the first heating portion 1 is: an inlet through pipe 13, a first heating pipe group communicated with the inlet through pipe, a first communication pipe 12, a first heating pipe group not connected with the inlet through pipe, and a first connecting pipe 14; the first connecting pipe 14 extends to the second heating pipe group 21, is connected to a part of the pipe of the second heating pipe group 21, and is not communicated with the second connecting pipe 22, and the flow direction of the heat transfer medium in the second heating part 2 is: a first connection pipe 14, a second heating pipe group connected to the first connection pipe, a second connection pipe 23, a second heating pipe group not connected to the first connection pipe, and a second connection pipe 22; the second connecting pipe 22 and the second communicating pipe 23 are both connected to the third heating pipe group 31, wherein the second connecting pipe 22 is connected to all the pipes of the third pipe group 31, the other end is provided with an outlet pipe 32, and the flow direction of the heat transfer medium in the third heating part 3 is: a second connecting pipe 22, a second connecting pipe 23, a third heating pipe group communicated with the second connecting pipe, a third heating pipe group not communicated with the second connecting pipe, and an outlet pipe 32; returning to the heat-conducting medium source through the outlet through pipe 32, thereby realizing circulation; furthermore, according to different specific structures in the bin body, corresponding heating tube sets, connecting tubes and communicating ports can be added or reduced appropriately, and the positions of the pipelines can be changed appropriately to provide avoidance positions; in this scheme, through ingenious design, the heat-conducting medium can directly be access to first heating portion 1, second heating portion 2 and third heating portion 3 in proper order, compares traditional use return bend and links up, and interval between this scheme can effectual compression heating calandria has just solved heat-conducting medium's flow direction circulation problem for the temperature in the storehouse is heated up rapidly and is even.

In this embodiment, the inlet through pipe 13 is provided with a liquid inlet, and the liquid inlet is communicated with the inner cavity of the inlet through pipe; the heat-conducting medium enters the first heating part 1 through the liquid inlet; the inlet through pipe 13 is also provided with a liquid inlet pipe 15, one end of the liquid inlet pipe is communicated with the liquid inlet, and the other end is provided with a switch valve port 16; the opening and closing of the valve port 16 can realize the opening and closing of the flow of the heat-conducting medium, or realize the stable regulation of the flow rate of the heat-conducting medium.

In this embodiment, the outlet through pipe 32 is provided with a liquid outlet, and the liquid outlet is communicated with the inner cavity of the outlet through pipe 32; the outlet through pipe is also provided with a liquid outlet pipe 33, one end of the liquid outlet pipe 33 is communicated with the liquid outlet, and the other end of the liquid outlet pipe extends to the first heating part 1; through adopting and setting up drain pipe 33 for the export and the export of heat-conducting medium can the apposition be settled, save equipment and put the space.

The invention also provides an organic garbage disposer, which refers to the attached drawings 3 to 5 and comprises a motor device 4, a bin body 5, a spindle device 6, a heating device 7 and the heating pipe structure, wherein the spindle device 6 and the heating pipe structure are assembled in the bin body, the motor device 4 is provided with an output shaft, and the output shaft is fixedly connected with the spindle device 6; the heating device 7 comprises an output pipe 71 and a return pipe 72, the output pipe 71 is communicated with the liquid inlet pipe 15, and the return pipe 72 is communicated with the liquid outlet pipe 16; the even assembly of heating tube structure is in storehouse body 5, heating device 7 heats heat-conducting medium, and pass to first heat-conducting part 1 through the output tube, retrieve the heat-conducting medium of third heat-conducting part 3 through back flow 72, and then realize holistic circulation, realize adjusting and keeping the temperature of storehouse body 5, it is preferential, heat-conducting medium chooses to be oil, the temperature of oil can reach 130 degrees centigrade, can kill the further high temperature of the bacterium in the storehouse body 5, and the heat preservation ability is strong, there is the fermentation for the microorganism to provide good environment.

In this embodiment, the heating device 7 includes a main box 71, a pump body 72 and a heating cavity 73, the heating cavity 73 is accommodated in the main box 71 and is connected with an inlet of the pump body 72 in a matching manner; a heater and a heat transfer medium are accommodated in the heating chamber 73; preferably, a heater and a control module are arranged in the heating cavity 73, the control module is electrically connected with the heater, the heater is a flange-type heater, the structure is compact and stable, the heat-conducting medium is heated up in an electric heating mode, the pump body 72 pumps the heat-conducting medium to the first heating part 1, and the heat-conducting medium of the third heating part 3 is recycled to the heater, so that circulation is realized.

In this embodiment, the device further comprises a plurality of groups of propelling paddles 61, wherein the propelling paddles 61 are spirally and respectively assembled on the main shaft device 6; in the organic garbage is treated, the fermentation effect is better due to stirring, and the organic garbage is spirally assembled on the main shaft device 6, so that the organic garbage is pushed in the bin body 5.

In this embodiment, the chamber body 5 further comprises an air outlet grid 52 for discharging gas generated by the fermented bacterial colonies; specifically, the air outlet grid 52 is located at one end of the bin body 5 close to the motor device 4, or at the top of the bin body 5, which is not limited.

In this embodiment, a plurality of groups of partition boards 51 for separating the inner cavity 5 of the bin body are further arranged in the bin body 5; the cabin body 5 is divided into a plurality of groups by the partition boards 51, and the heating pipe structure is made into an adaptive avoiding position, so that the cabin body 5 is divided into a plurality of small areas, and the implementation of a subsequent drying process is facilitated.

The invention has the advantages that:

1) through the ingenious design, the heat-conducting medium can directly and sequentially lead to the first heating part, the second heating part and the third heating part, compared with the traditional mode that bent pipes are used for connection, the scheme can effectively compress and heat intervals among the pipe banks, and solves the problem of flow direction circulation of the heat-conducting medium, so that the temperature in the bin body is rapidly and uniformly increased;

2) the heat-conducting medium is selected from oil, the temperature of the oil can reach 130 ℃, bacteria in the bin body can be further killed at high temperature, the heat-preserving capacity is strong, and a good environment is provided for the fermentation of the microorganisms.

The above disclosure is only for a few specific embodiments of the present invention, but the present invention is not limited thereto, and any variations that can be made by those skilled in the art are intended to fall within the scope of the present invention.

Claims

1. A heating pipe structure is used for accommodating a heat-conducting medium and is characterized by comprising a plurality of heating parts which are connected in sequence; the heating part comprises a plurality of groups of liquid storage pipes, one end of each liquid storage pipe is provided with a connecting pipe, and the other end of each liquid storage pipe is provided with a communicating pipe;

wherein, the heating part is connected with the adjacent heating part through the connecting pipe, the heating parts at the head and the tail ends are also correspondingly provided with an inlet through pipe and an outlet through pipe, the inlet through pipe is positioned at one end of the connecting pipe, and the inlet through pipe is not communicated with the connecting pipe; the outlet through pipe is positioned at one end of the communicating pipe, and the outlet through pipe and the communicating pipe are not communicated with each other.

2. The heating tube structure according to claim 1, characterized in that the inlet duct is provided with a liquid inlet for the heat transfer medium.

3. The heating tube structure according to claim 2, wherein the inlet duct further comprises a liquid inlet tube, one end of the liquid inlet tube is connected to the liquid inlet, and the other end of the liquid inlet tube is provided with a switch valve port.

4. The heating tube structure according to claim 1, characterized in that the outlet duct is provided with a liquid outlet for the outflow of the heat transfer medium.

5. A heating tube structure as claimed in claim 4, wherein the outlet pipe is further provided with a liquid outlet, one end of the liquid outlet is connected to the liquid outlet, and the other end of the liquid outlet extends to the first heating portion.

6. An organic garbage disposer is characterized by comprising a motor device, a bin body, a main shaft device, a heating device and the heating pipe structure as claimed in any one of claims 1 to 5, wherein the main shaft device and the heating pipe structure are assembled in the bin body, the motor device is provided with an output shaft, and the output shaft is fixedly connected with the main shaft mechanism; the heating device comprises an output pipe and a return pipe, the output pipe is communicated with the inlet through pipe, and the return pipe is communicated with the outlet through pipe.

7. The organic waste disposer of claim 6, wherein the heating device comprises a main housing, a pump body, and a heating chamber, the heating chamber is accommodated in the main housing and is adapted to be connected to the inlet of the pump body; the heating cavity is internally provided with a heater and a heat-conducting medium.

8. The organic waste disposer of claim 6, further comprising a plurality of sets of propulsion paddles, wherein the propulsion paddles are spirally and uniformly mounted on the spindle assembly.

9. The organic waste disposer of claim 6, wherein the bin body further comprises an air outlet grid for discharging gas produced by the fermenting colonies.

10. The organic waste disposer of claim 6, wherein a plurality of groups of baffles are disposed in the bin body for separating the inner cavity of the bin body.