KR102009507B1 - Incineration apparatus for dead livestock using liquefied gas burner - Google Patents

Abstract

Disclosed in the present invention is an incineration apparatus for livestock carcass treatment using a liquefied gas burner, which may greatly improve an incineration capacity of livestock carcasses with high efficiency by using liquefied gas as fuel while having a simplified structure. According to the present invention, the incineration apparatus for livestock carcass treatment comprises: a base frame on which at least one rotating roller is installed; an incineration module assembly seated on the rotating roller and rotated; a direct injection burner mounted inside the incineration module assembly; a sterilization mill connected to one end of the incineration module assembly, crushing livestock carcasses and supplying the crushed livestock carcasses into the incineration module assembly; and a waste heat recovery module connected to the other end of the incineration module assembly to suck heat inside the incineration module assembly to supply the heat as combustion air of the direct injection burner.

Description

Incinerator for waste livestock treatment using liquefied gas burner {INCINERATION APPARATUS FOR DEAD LIVESTOCK USING LIQUEFIED GAS BURNER}

The present invention relates to an incinerator for waste livestock treatment, and more particularly, to an incinerator for waste livestock treatment using a liquefied gas burner.

In general, foot-and-mouth disease, an acute infectious disease of livestock, has a mortality rate of 5 to 55%, and since the treatment has not been specifically suggested, once it occurs, a large amount of cow products are dead and buried.

On the other hand, avian influenza (AI), acute infectious diseases of poultry such as chickens, ducks, and wild birds, is also difficult to apply antiviral therapy to humans once it occurs in poultry farms. As a result, a large amount of poultry is being killed and buried.

Although the method of investing our livestock is the easiest way to prevent the spread of pathogens, the environmental pollution problem caused by the massive recurring investment is seriously presented, and various methods for effective treatment are suggested. It is becoming.

Among them, various devices have been developed so far to treat livestock mortality. For example, a mobile incineration process is disclosed in which an incineration treatment is performed by rapidly moving to a mortality area.

However, the conventional incinerator has its incineration rate of up to 600kg ~ 1,000kg per hour is not a practical alternative due to the lack of treatment capacity in emergency situations such as foot and mouth disease.

In addition, a rotary incinerator is disclosed as a means to increase the processing capacity, but because the large power is required to rotate a large incinerator, the apparatus is enlarged, and therefore, only a fixed type can be installed at the installation site. There is a difficult problem.

In addition, the conventional incinerator for waste livestock treatment uses diesel, etc. in order to obtain a relatively cheap and large power, so that the overall power equipment is enlarged and there is a problem of air pollution due to the generation of smoke during long-term operation.

<Previous Document 1>: Republic of Korea Patent Registration No. 1898152 (Notice date: September 12, 2018)

The present invention was devised to solve the above problems, and provides an incineration apparatus for waste livestock processing using a liquefied gas burner which can greatly improve the waste livestock incineration capacity with high efficiency by using liquefied gas as a fuel. There is a purpose.

According to an embodiment of the present invention for achieving the above object, at least one rotary roller is mounted to the base frame; An incineration module assembly seated on the rotary roller and rotated; A direct injection burner mounted inside the incineration module body; A sterilization mill for pulverizing livestock carcasses connected to one end of the incineration module assembly and supplying them to the incineration module assembly; And a waste heat recovery module connected to the other end of the incineration module assembly to suck heat from the inside of the incineration module assembly and supply the combustion air to the combustion air of the direct injection burner. do.

The waste heat recovery module may include a heat exchange pipe connected to an end of the incineration module assembly, a waste heat recovery pipe connected to one end of the heat exchange pipe and a blower connected to the other end, and connected between the blower and the incineration module assembly from the blower. It may be made to include a waste heat supply pipe for supplying waste heat to the direct injection burner.

The direct injection burner includes an injection nozzle having a nozzle hole formed at a tip thereof to receive liquid LPG and sprayed to the outside, and a nozzle rod that opens and closes the nozzle hole of the injection nozzle by being advanced back and forth within the injection nozzle. The nozzle rod may be opened by reversing the nozzle rod in a direction opposite to the injection direction of the injection nozzle from the state where the tip of the nozzle rod is blocking the nozzle hole of the injection nozzle.

According to the present invention, it is a simplified structure that does not require a separate vaporizer, and improves combustion efficiency by utilizing waste heat generated during incineration as combustion air, and greatly improves incineration capacity during waste livestock treatment using liquefied gas as fuel. It has an effect.

1A is a perspective view of an incinerator for waste livestock processing using a liquefied gas burner according to an embodiment of the present invention;
1b is a schematic process diagram of an incineration apparatus for waste livestock processing using a liquefied gas burner according to an embodiment of the present invention;
Figure 2 is a perspective view showing the installation state of the waste heat recovery module of the incinerator for waste livestock processing using a liquefied gas burner according to an embodiment of the present invention,
3 is a plan view showing the installation state of the waste heat recovery module of the incinerator for waste livestock processing using a liquefied gas burner according to an embodiment of the present invention,
4 is a partially enlarged view showing an installation state of a waste heat recovery module of an incinerator for waste livestock processing using a liquefied gas burner according to an embodiment of the present invention;
5 is a partially enlarged view showing a connection state of a waste heat recovery module of an incineration apparatus for waste livestock using a liquefied gas burner according to an embodiment of the present invention;
6a and 6b is a state diagram showing the operating state of the direct injection burner of the waste heat recovery module of the waste livestock incineration apparatus using the liquefied gas burner according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in more detail the present invention. Prior to this, terms or words used in the present specification and claims should not be construed as being limited to the ordinary or dictionary meanings, and the inventors should properly explain the concept of terms in order to best explain their own inventions. Based on the principle that it can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention. In addition, unless there is another definition in the technical terms and scientific terms used, it has the meaning that is commonly understood by those of ordinary skill in the art. In the following description and the accompanying drawings, descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted. The accompanying drawings are provided by way of example so as to fully convey the spirit of the invention to those skilled in the art. Accordingly, the present invention is not limited to the drawings presented below and may be embodied in other forms. Also, like reference numerals denote like elements throughout the specification. It should be noted that the same elements in the figures are represented by the same numerals wherever possible.

1A and 2, an incineration apparatus for waste livestock processing using a liquefied gas burner of the present invention includes a base frame 50, an incineration module assembly 10, a sterile grinder 30, and a dust collector 70. . At this time, the incineration module assembly 10 is rotatably mounted on the base frame 50. That is, the incineration module assembly 10 is mounted with a drive tooth 40 so that a drive motor (not shown) rotates the drive tooth 40 so that the incineration module assembly 10 is rotated on the base frame 50. At this time, a plurality of rotating rollers (not shown) are installed on the base frame 50 to facilitate the rotation of the incineration module assembly 10. In addition, a plurality of incineration modules (cylindrical modules) of the incineration module assembly 10 is connected to the connection line 17 (Fig. 3) through a plurality of bolts are connected in series. In addition, corresponding to the base frame 50, a plurality of frames are arranged in series by fastening the bolt to the connection portion.

On the other hand, the front of the incineration module assembly 10 is equipped with a sterile grinder 30 is connected to the contaminated air supply pipe. The sterile grinder 30 functions to crush the dead livestock of the waste livestock and supply it to the incineration module assembly 10. Specifically, the blower 30b is connected to the sterile grinder 30 through the contaminated air intake pipe 31 to suck the contaminated gas generated when the carcass is crushed and supplied to the incineration module assembly 10 through the contaminated air discharge pipe 32. To burn at a high temperature inside the incineration module assembly 10.

In addition, the heat exchange pipe 60 is installed at the rear of the incineration module assembly 10 to recover the waste heat generated in the incineration module assembly 10 and circulate back to the inside of the incineration module assembly 80 through the waste heat recovery pipe 80. . At this time, the dust collector 70 is mounted at the end of the heat exchange pipe 60 to filter out foreign substances or contaminants in the air introduced through the heat exchange pipe 60 to discharge a part of the air.

Referring to Figure 1b, the incineration apparatus for waste livestock treatment using the liquefied gas burner of the present invention to put the carcass carcass into the sterile grinder 30 to crush the carcass. The crushed carcasses are then fed into the incineration module assembly 10. At this time, the contaminated air containing the pathogen generated during the crushing process is re-supplied to the incineration module assembly 10 through the blower 30b to be sterilized by burning. In addition, the injected carcass crushed product is removed by burning through the direct injection burner 20 installed in front of the incineration module assembly 10. At this time, the incineration module assembly 10 is rotated, the incineration of the crushed body is made, and after incineration, the incineration material is moved in the incineration module assembly 10 to be discharged to the outside through an outlet (not shown).

On the other hand, the high-temperature gas generated in the incineration process is recovered along the heat exchange pipe 60, and some of the gas is discharged to the outside in a state in which foreign substances and contaminants are filtered out by the dust collector 70, and the remaining gas is discharged to the waste heat recovery pipe 80. It is fed back to the direct injection burner 20 and utilized as combustion air (hot air).

Meanwhile, the present invention includes a waste heat recovery module connected to the other end of the incineration module assembly 10 to suck in the heat inside the incineration module assembly 10 and supply it as combustion air of the direct injection burner 20.

3 to 4, the waste heat recovery module includes a heat exchange pipe 60 connected to the discharge end of the incineration module assembly 10, a waste heat recovery pipe 80 having one end connected to the heat exchange pipe 60, and It is composed of a blower (80a) connected to the other end of the waste heat recovery pipe (80). At this time, the blower 80a and the incineration module assembly 10 are connected through a waste heat supply pipe 82. Therefore, the waste heat in the incineration module assembly 10 may be supplied through the blower 80a to provide the combustion air of the direct injection burner 20.

Specifically, the front end of the incineration module assembly 10 is equipped with a direct injection burner 20 is incinerated for the livestock carcass crushed material is injected into the incineration module assembly 10. At this time, the heat generated in the incineration module assembly 10 is cooled to a predetermined temperature (the action of cooling the high temperature heat in the combustion chamber) through the heat exchange pipe 60. At this time, a heat treatment type dust collector 70 is adopted as the heat exchange pipe 60. For example, the dust collector 70 is a cyclone dust collector is applied to filter foreign matter and contaminants contained in the heat during the incineration process. Referring to FIG. 5, the dust collector 70 is fixed by the supporter 75, and an exhaust port 71 through which hot air filtered to one side is exhausted is formed, and a centrifugal separator 72 separates and discharges foreign substances and contaminants on the lower side. Is provided in the formed configuration.

On the other hand, the heat exchanged heat is introduced into the waste heat recovery pipe (80) connected to the heat exchange pipe (60). At this time, the blower (80a) is connected to the end side of the heat exchange pipe (60) serves to suck the heat of the heat exchange pipe (60) to the waste heat recovery pipe (80). The hot air introduced in this way is provided to the direct injection burner 20 by the waste heat supply pipe 82 connected to the discharge side of the blower 80a.

That is, the combustion heat (waste heat) generated in the incineration module assembly 10 is cooled through a heat exchange pipe 60 and is provided through the waste heat recovery pipe 80 in a state in which foreign matter is removed through the dust collector 70. It is provided as combustion air to the direct injection burner 20 through the waste heat supply pipe 82. In this case, since the supplied waste heat is hotter than the atmosphere, the combustion efficiency of the direct injection burner 20 may be improved (the waste heat for incineration heat is provided as combustion air).

6A and 6B, the direct injection burner 20 is connected through a fuel supply pipe 95 connected to the liquefied gas supply tank 90, and includes an injection nozzle 21c and a nozzle rod 22. The injection nozzle 21 is provided with a nozzle hole 21ca at the front end to receive the liquid LPG and to spray to the outside. The nozzle rod 22 opens and closes in the spray nozzle 21c to open and close the nozzle hole 21ca of the spray nozzle 21c.

Through such a configuration, the direct injection burner 20 has the nozzle rod 21ca and the injection direction of the injection nozzle 21c from the state where the tip of the nozzle rod 22 is blocking the nozzle hole 21ca of the injection nozzle 21c. The nozzle hole 21ca is opened by reversing in the opposite direction.

Specifically, the direct injection burner 20 includes an LPG supply pipe 21, a nozzle rod 22, a nozzle cooling air supply pipe 23, and a combustion air supply pipe 24. At this time, the combustion air supply pipe 24 is connected to the waste heat supply pipe 82 to receive the high temperature waste heat through the waste heat supply pipe 82 to provide the combustion air supply pipe 24. Therefore, the combustion efficiency can be improved by utilizing the waste heat of high temperature as the combustion air than when applying the outside air as the combustion air.

Meanwhile, the LPG supply pipe 21 is connected to the connection pipe 11 to serve as a passage for supplying the liquid LPG. At this time, the injection nozzle 21c having the nozzle hole 21ca formed at the end of the LPG supply pipe 21 may be connected.

The fuel regulator central shaft 21a is connected to the distal end of the flow controller 21b, and a supply hole 21aa through which the LPG liquid is supplied is formed on the upper side thereof, and a fluid supplied from the supply hole 21aa is provided on the side. A discharge hole 21ab to be discharged is formed.

In addition, the LPG leak prevention cover 25 is installed on the opposite side of the discharge hole 21ab formed in the central axis 21a of the fuel control device, and the nozzle rod 22 is coupled to the center of the LPG leak prevention cover 25. At this time, the flow controller 21b is connected to the discharge hole 21ab of the central axis 21a of the fuel regulator. In addition, the injection nozzle 21c is connected to the flow controller 21b, and a nozzle hole 21ca is formed at the end thereof.

The direct injection burner 20 having such a configuration is provided with a cone-shaped nozzle rod 22, and the cone-shaped nozzle rod 22 blocks and closes the nozzle hole 21ca while advancing inside the injection nozzle 21c. (State of FIG. 6A).

In addition, the conical nozzle rod 22 can open the nozzle hole 21ca while reversing (specifically, moving in the direction opposite to the injection direction of the injection nozzle) inside the injection nozzle 21c (state of FIG. 6B).

Specifically, when the nozzle bar 22 is retracted to the inside of the injection nozzle 21c (that is, when the nozzle hole is to be opened), the cone-shaped end of the nozzle bar 22 is jetted by drawing the inside of the injection nozzle 21c. The tip of the nozzle rod 22 is not exposed to the outside of the nozzle 21c (see FIG. 6B).

 As described above, the direct injection burner 20 of the present invention has the end of the nozzle rod 22 fully introduced into the injection nozzle when the nozzle hole 21ca is opened, and thus, the nozzle rod 22 is particularly used during LPG injection (combustion). The end of is positioned in the LPG liquid (that is, inside the injection nozzle 21c to which the liquid LPG is supplied). Therefore, by preventing a part of the nozzle rod 22 from being located in the injection region, the icing phenomenon (phenomena in which ice is generated at the tip of the nozzle rod) can be prevented.

In addition, by using a liquefied gas such as LPG as fuel, it is possible to prevent air pollution due to soot, etc., it is possible to ensure a high thermal efficiency as a simplified configuration excluding the separate vaporizer.

As described above, the present invention can improve the combustion efficiency by utilizing the waste heat generated during incineration as the combustion air, and the incineration capacity during the waste livestock treatment can be greatly improved by using the waste heat generated during the incineration. .

Although the present invention has been illustrated and described with respect to specific embodiments thereof, the present invention is not limited to the above-described embodiments, and a person skilled in the art to which the present invention pertains has the present invention described in the following claims. Various changes may be made without departing from the spirit of the technical idea of the invention.

10: incineration module assembly
20: direct injection burner
30: sterile grinder
31: contaminated air suction line
32: contaminated air discharge pipe
35a: air supply
40: drive tooth part
50: base frame
60: heat exchange frame
70: dust collector
71: exhaust port
72: centrifuge
75: support
80: waste heat recovery tube
82: waste heat supply pipe
90: liquefied gas supply tank
95: fuel supply pipe

Claims (3)

A base frame on which at least one rotating roller is mounted;
An incineration module assembly seated on the rotary roller and rotated;
A direct injection burner mounted inside the incineration module body;
A sterilization mill for pulverizing livestock carcasses connected to one end of the incineration module assembly and supplying them to the incineration module assembly; And
A waste heat recovery module connected to the other end of the incineration module assembly to suck heat from the inside of the incineration module assembly and supply it to the combustion air of the direct injection burner,
The sterile grinder is provided with a contaminated air supply pipe, the contaminated air supply pipe is connected to the incineration module assembly, the combustion of the contaminated gas generated in the sterile grinder when the livestock carcasses to the incineration module assembly to burn. Incinerator for waste livestock treatment using liquefied gas burner. The method of claim 1,
The waste heat recovery module,
A heat exchange pipe connected to an end of the incineration module assembly,
A waste heat recovery tube having one end connected to the heat exchange pipe and a blower connected to the other end, and
And a waste heat supply pipe connected between the blower and the incineration module assembly to receive waste heat from the blower and supply the waste heat to the direct injection burner. The method according to claim 1 or 2,
The direct injection burner,
An injection nozzle having a nozzle hole formed at a tip thereof to receive liquid LPG and sprayed to the outside; and
It includes a nozzle rod for opening and closing the nozzle hole of the injection nozzle to be advanced back and forth in the injection nozzle,
A waste livestock using a liquefied gas burner, wherein the nozzle hole is opened by reversing the nozzle rod in a direction opposite to the injection direction of the injection nozzle while the tip of the nozzle rod is blocking the nozzle hole of the injection nozzle. Incinerator for treatment.

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