KR101017454B1 - An apparatus for carbonize for wet waste - Google Patents

Abstract

PURPOSE: A wet waste carbonization apparatus is provided to enable rapid carbonization processes by stirring waste horizontally and vertically. CONSTITUTION: A wet waste carbonization apparatus comprises a housing(10) and an operating shaft(40). The external air flows in the bottom part of the housing through the operating shaft, thereby supplying air to mixed wet waste. Accordingly, bubbles are increased between the wet wastes. The delay of the carbonization processes is prevented when wastes are agglomerated or stuck in the housing. The wet waste on the bottom part of the housing is pushed up, thereby maintaining uniform stirring effects. The operating shaft is rotated forwardly and reversely inside a housing using electro-motive force of a drive motor(M).

Description

Wet Waste Carbonization Unit {AN APPARATUS FOR CARBONIZE FOR WET WASTE}

The present invention relates to an improved invention of a pre-applied livestock manure processing device for drying and carbonizing wet waste, for example, manure containing a large amount of water or food waste collected from a general household as compost. More specifically, a cylindrical housing in which wet waste flows in from the outside and a heating heater is attached to the surface is installed upright, while inside the housing, the mixing blade and waste for mixing the waste laterally are longitudinally mixed and carbonized. It is equipped with screw vanes for inducing discharge upon completion of processing, and it installs working shaft which is forward and reverse rotated through driving motor to heat, stir and dry carbonize the incoming wet waste. The installation area is greatly reduced so that the occupied area on the ground is greatly reduced, making it easier to select the installation site. By agitating the high waste vertically and horizontally, the carbonization process is improved quickly and uniformly, and the working effect is improved. Also, through the operating shaft, the external air is forced into the bottom of the housing to supply air to the agitated wet waste. It can be agglomerated into or stuck in the housing to prevent incomplete or delayed treatment, and to give up the wet waste at the bottom of the housing to give it an even stirring effect. By collecting and dropping the dust contained in the exhaust gas at the outlet to be mixed and discharged into the carbonized waste, most of the dust generated during the carbonization of the waste is collected first to prevent air pollution. Cooling air is mixed into the exhaust gas to the outside In addition to reducing the temperature of the exhaust gas, it causes condensation due to the temperature difference between the exhaust gas and the cooling air, thereby greatly reducing the gas moisture content and adsorbing fine dust to prevent air pollution.

Recently, the Ministry of Environment has installed village sewerage facilities in small villages scattered in the upper water supply area as part of the preservation policy of clear water, but the investment cost is excessive compared to the pollution level. The cause is much more serious, but there are insufficient active countermeasures.

Livestock manure is less quantitatively than living sewage in terms of emissions, but is very high in terms of pollution loads, and livestock farms are mainly located in rural areas, upstream of water supplies, recently contaminating water, living, agricultural water and even groundwater. to be.

Conventional treatment methods for livestock manure were mixed with sawdust, dried, and then sprayed on agricultural land. However, these methods involve various problems such as the purchase of sawdust and treatment after mixing with manure. Is not used well, and the reason for this is that sawdust, chaff, or lime are added to solidify the livestock manure, so the cost of maturation of livestock manure increases, increasing the economic burden on livestock farmers. Because.

Recently, the government has invested enormous funds to install livestock waste treatment facilities, but it is not operating properly due to the overloading measures and other inappropriate management.

In particular, as a method for maturing livestock manure in livestock manure, fermentation by adding chaff or sawdust is generally used. In this way, when the solid material of livestock manure is matured, the scale of livestock manure treatment facility is very large. There is a disadvantage that the construction cost is very high.

Therefore, the livestock waste treatment facility has a problem that the livestock manure treatment facility must be very small in size to provide a device with low maintenance cost, construction cost, and treatment cost by miniaturizing the livestock manure processing facility in accordance with the reality of Korea.

In addition, recently, a boiler drying apparatus was developed to dry livestock manure with high pressure steam as a heat source to dry the livestock manure, and it has been spread to farms, but the installation area is excessive because it requires a boiler facility. In addition, the mechanical equipment is complicated and frequently occurs, and when the drying operation is completed through the boiler drying apparatus, the worker has to artificially discharge the fixed shaft powder each time, which has a disadvantage in that the work is cumbersome and the workability is lowered.

In view of the above problems, I have proposed a livestock manure treatment device as Patent Registration No. 10-0651040 (see Fig. 7).

The pre-registration structure has a plurality of manure conveying pipes 1 arranged up and down as shown in FIG. ), Which has the following problems in structure.

◎ The manure conveying pipe (1) is arranged horizontally, so the occupied area on the ground becomes large, and there are many obstacles in the selection of the installation place, and the conveying screw (3) is a structure that carries and agitates the waste only in one direction. There is a problem that the agitation effect is reduced and the size and degree of carbonization of the final carbide is not uniform,

◎ In addition, in the present invention, the outside air is mixed from the bottom of the housing to induce the generation of countless bubbles in the stirred waste, thereby improving the decomposition, drying and thermal conductivity of the waste, and raising the waste upward through the air inlet pressure. There is no air supply structure to give the effect of improving the agitation effect. Therefore, when the wet waste is agitated, it becomes stuck in the housing during the agglomeration and heating process of the waste, causing the overload of the device and the heat transfer between the waste. Due to the non-uniformity of the carbonization treatment was incomplete or delayed,

◎ In addition, in the invention, a recycling means for preheating or transferring waste to which a high temperature of the discharge gas is introduced in the manure conveying pipe 1 is applied to a heater to increase thermal efficiency. There was a problem that the high temperature gas containing a lot of water vapor is released as it is to increase the ambient air temperature, and the fine dust contained in the exhaust gas is released into the atmosphere without filtration, which causes air pollution.

The present invention has been made to solve and solve the problems caused by the existing device as described above,

The object of the present invention is to install the longitudinal direction of the device in the longitudinal direction so that the occupied area on the ground is greatly reduced, it is easy to select the installation site, the agitation of the waste is made vertically and horizontally, the carbonization treatment is quick and uniform operation It is to provide a wet waste carbonization device, characterized in that the effect is improved.

Another object of the present invention is to force the inflow of external air through the working shaft to the bottom of the housing to provide air to the agitated wet waste, whereby the wet waste is agglomerated or stuck in the housing, resulting in incomplete treatment. It is to provide a wet waste carbonization apparatus, characterized in that to prevent the delay and to give the effect of lifting up the wet waste at the bottom of the housing to give a uniform stirring effect.

Another object of the present invention is to collect the dust contained in the exhaust gas of the gas outlet to be naturally collected and discharged in the carbonized waste to collect most of the dust generated during the carbonization of waste to prevent the prevention of air pollution At the same time, the cooling air is mixed with the high temperature exhaust gas, thereby causing the condensation caused by the temperature difference between the exhaust gas and the cooling air, as well as reducing the temperature of the gas discharged to the outside, thereby greatly increasing the moisture content in the gas. It is to provide a wet waste carbonization apparatus characterized by reducing and adsorbing fine dust to prevent air pollution.

In order to achieve the above object, the present invention vertically installs a cylindrical housing in which wet waste is introduced from the outside and a heating heater is attached to a surface thereof, but a mixing wing and waste for mixing the waste transversely inside the housing. It is equipped with screw blades for mixing in the direction and at the same time to induce discharge upon completion of carbonization treatment, and installs the working shaft which is rotated forward and reverse through the drive motor to heat, stir and dry carbonize the incoming wet waste. It is.

In addition, the present invention has an air inlet hole and an air supply hole interconnected to the upper and lower edges of the operating shaft, but has an isolation chamber in which the air inlet hole is located inside the upper side of the housing so that compressed air is forced into the compression chamber so that the compressed air flows into the isolation chamber. Air is injected into the bottom of the housing through the air inlet hole and the air supply hole of the operating shaft.

In addition, the present invention has a dust discharge pipe connected to the gas discharge port and the carbonization waste discharge pipe upper and lower, respectively, and is installed in the subsequent portion of the dust discharge pipe to supply an air cooling nozzle for mixing the external cooling air to the hot discharge gas It characterized in that it comprises a gas treatment means for collecting and draining the condensed water generated during air cooling of the gas.

The present invention as described above is installed so that the longitudinal direction of the device vertically, the occupied area on the ground is greatly reduced to facilitate the selection of the installation site, as well as the agitation of the waste vertically and horizontally, so that the carbonization treatment is quick, Uniformity has the effect of improving the working effect.

In addition, since the outside air is forced into the bottom of the housing through the operating shaft, air can be increased between the wet wastes by providing air to the agitated wet wastes. There is an effect that can be prevented from being incomplete or delayed to be fixed in the carbonization treatment, and also has the effect of giving up the wet waste of the bottom of the housing up to give a uniform stirring effect.

In addition, by collecting the dust contained in the exhaust gas of the gas outlet to be naturally collected and discharged into the carbonized waste, it is possible to prevent most of the air pollution by collecting most of the dust generated during the carbonization of the waste first. By mixing the cooling air into the high temperature exhaust gas, it causes not only the temperature reduction of the gas discharged to the outside but also condensation due to the temperature difference between the exhaust gas and the cooling air, which greatly reduces the water content in the gas and adsorbs fine dust. It is effective to prevent air pollution.

1 is an exemplary view showing the overall configuration of an embodiment of the present invention.
2 is a cross-sectional view of main parts of the present invention.
Figure 3 is an enlarged cross-sectional view of the main part of the present invention showing a process of discharging the waste carbonized.
Figure 4 is an enlarged cross-sectional view of the main portion of the present invention showing the process of entering the outside air into the working shaft.
Figure 5 is an enlarged cross-sectional view of the main portion of the present invention showing the process of blowing external air to the bottom of the operating shaft.
Figure 6 is an enlarged cross-sectional view of the main portion of the present invention showing a process of mixing the cooling air in the exhaust gas.
7 is an exemplary view showing the structure of the line registration invention.

As shown in Figure 1 the wet waste treatment apparatus of the present invention

A cylindrical housing 10 installed upright on the mounting table 11 and equipped with a plurality of heaters 12 for heating, drying and carbonizing the wet waste put into some outer periphery;

And a hopper 20 installed to be connected to the inside of one upper edge portion of the housing 10 and having an input amount control valve 21 and a supply amount control valve 22 at the inlet side and the outlet side, respectively.

An air supply compartment 30 configured through a set of sealing diaphragms 31 isolated from each other on an upper side of the housing 10,

A plurality of stirring vanes 41 and the stirring vanes, which are supported by the electric motor of the driving motor M in the inside of the housing 10 to enable forward and reverse rotation, protrude to a part of the outer circumferential surface of the middle part, and the stirring vanes ( The operating shaft 40 of the hollow state which is provided with the screw blade 42 which is comprised to the lower end below 41, and the electric gear 43 which protrudes out of the mounting table 11, and is connected to the drive motor M, respectively. )and,

A lower outer side of the operating shaft 40 in a state of being connected to the air inlet hole 51 and the air inlet hole 51 which is drilled on the upper outer periphery of the operating shaft 40 and located in the air supply compartment 30. An air supply hole 52 is formed in the periphery and connected to the air supply compartment 30 through the air supply pipe 54 and includes an air supply 53 for supplying compressed air into the air supply compartment 30. Waste air supply means 50 is configured to,

A discharge guide tube 62 protrudingly installed in a state connected to a carbide discharge port 61 punctured at the lower edge of the housing 10, and having a carbide discharge pipe 63 connected to a bottom thereof, and the discharge guide tube 62. Carbide discharge is provided fixed to the end of the cylinder including a cylinder (64) having an opening and closing (65) for selectively opening and closing the carbide discharge port 61 while sliding in the discharge guide tube 62 through the opening and closing rod (66) Means 60,

An upper end is connected to the gas discharge pipe 71 is configured to communicate with the inner upper side of the housing 10 and the lower end is a dust discharge pipe 70 is configured to be connected to the carbide discharge pipe (63),

Condensate water collecting pipe 81 is installed in the longitudinal direction at the end of the gas discharge pipe 71 and connected to the lower end of the condensate water collecting pipe 81, the water level sensor 83 and the drain valve 84 A water supply nozzle (82) having a water supply nozzle (85) fixedly installed so as to be located inside the condensate water collecting pipe (81) in a state connected to the air supply (53) through a supply pipe (86). Gas processing means 80, including, and

Waste moisture measuring sensor 90 for measuring the moisture content of the waste is fixed and installed in the inner place of the housing 10,

The exhaust gas moisture measuring sensor 100 and fixed to the inside of the gas discharge pipe 71 for measuring the moisture content of the exhaust gas, and

It is fixed to the inside of the hopper 20 is to include a waste input amount sensor 110 for detecting the waste input amount in the hopper 20, respectively.

Referring to the operation of the present invention configured as described above in detail as follows.

First, the present invention is installed so that waste stored in a wet waste storage tank (not shown), such as livestock manure or food waste, can be supplied to the hopper 20 through a supply pipe (not shown) in which an automatic transport structure is installed. .

When the device is operated in the above state, the supply amount control valve 22 of the outlet side of the hopper 20 is closed and the input amount control valve 21 of the inlet side is opened, and the supply pipe (not shown) of the hopper 20 is opened. When the waste is supplied to the inside and the waste is introduced until the waste input detection sensor 110 is detected, the input quantity control valve 21 of the inlet side is automatically closed by the detection signal of the waste input detection sensor 110, The feed into the hopper is stopped and at the same time the supply amount control valve 22 on the outlet side is opened, and the waste in the hopper 20 is supplied into the housing 10.

Here, the amount of waste one-time supply of the hopper 20 may be sufficient so that the whole stirring blade 41 may come into contact with the waste and be stirred when introduced into the housing 10.

On the other hand, when the apparatus is operated, the heater 12 is driven to heat the housing 10, and the driving motor M rotates in the reverse direction while rotating the operating shaft 40 to rotate the waste introduced through the stirring blade 41 in the horizontal direction. It is crushed and stirred, and the screw blade 42 which rotates in reverse allows the waste of the bottom of the housing 10 to be lifted up to allow stirring in the longitudinal direction.

Meanwhile, when the waste is agitated by the operating shaft 40 in the housing, the outside air is introduced into the bottom of the housing 10 through the waste air supply means 50.

When the operating shaft 40 is rotated as shown in FIG. 4, the air supply 53 is driven to supply compressed air to the air supply compartment 30 through the air supply pipe 54, and flow into the air supply compartment 30. Air is introduced into the operating shaft 40 through the air inlet 51 of the operating shaft 40 located therein, and then the air supply hole 52 configured at the bottom of the operating shaft 40 as shown in FIG. 5. When forced air is injected into the housing 10 through the compressed air, the agitation process is performed through the effect of finely decomposing tissue because air is penetrated into the waste to increase bubble generation. This prevents waste from agglomerating or sticking in the housing 10 to prevent incomplete or delayed carbonization, and gives the effect of lifting up the wet waste at the bottom of the housing to give a uniform stirring effect.It is over.

As such, the waste that is stirred vertically and horizontally is dried and carbonized inside the housing 10 heated to a predetermined temperature by the heater 12, and the water content of the waste carbonized through the waste moisture measuring sensor 90 is carbonized. When the driving motor M is rotated forward when the set value is reached, the cylinder 64 is opened and closed as shown in FIG. 3 while moving the waste downward in the discharge direction, that is, under the housing 10 having the carbide discharge port 61. 66 is immersed so that the opening and closing port 65 opens the carbide discharge port 61 and the carbide discharge pipe 63 to collect and discharge the carbide to the outside.

On the other hand, when the carbide is completely discharged in the housing 10, the cylinder 64 is advanced, and the driving motor M is rotated forward with the opening and closing hole 65 again blocking the carbide discharge port 61, thereby initializing the operating shaft 40. As shown in FIG. 2, the feed control valve 22 of the hopper 20 is closed and the feed control valve 21 is opened to receive the next waste into the hopper 20 as described above. Will be repeated.

On the other hand, the gas including dust and water vapor generated during the carbonization of the waste is introduced into the gas discharge pipe 71 while rising to the upper portion of the housing 10, and most of the dust in the inflowed and moved gas is primarily discharged by its own weight. 71 is connected to the dust discharge pipe 70 is connected to the carbide discharge pipe (63) to be discharged together with the carbide discharged through the dust discharge pipe (70) by the exhaust gas moisture measurement sensor (100) The air supply amount to the air supply nozzle 85 to be described later is added or subtracted according to the measured value.

The hot gas passing through the dust discharge pipe 70 is supplied to the condensate water collecting pipe 81, and the air supply nozzle 86 is supplied with air from the air supply 53 through the air supply pipe 86 as shown in FIG. 6. Condensation is formed by the mutual temperature difference while joining the air injected from

When the amount of water vapor contained in the gas is large, the amount of entrained air at a relatively low temperature in the air supply nozzle 86 is proportionally increased so that a large amount of water vapor is condensed through cooling to be collected into the water tank 82 to be discharged into the atmosphere. The amount of water vapor in the tank can be minimized.

At this time, since the fine dust contained in the water vapor is collected in the state of being adsorbed by the water droplets in the condensation process, it is possible to reduce the fine dust emissions to the atmosphere.

As such, the water vapor in the exhaust gas is collected and removed through condensation. When the condensation water collected in the water tank 82 is gradually increased and detected by the water level sensor 83, the drain valve 84 is opened and discharged to the outside.

In the above, one embodiment of the present invention has been described, but modifications and variations within the scope without departing from the technical spirit of the present invention by those skilled in the art belong to the scope of the present invention Of course.

10: housing 11: mounting base
12: heater 20: hopper
21: Input flow control valve 22: Supply flow control valve
30: Air supply compartment 31: Sealing diaphragm
40: working shaft 41: stirring blade
42: screw wing 43: electric gear
50: waste supply means 51: air inlet
52: air supply hole 53: air supply
54: supply pipe 60: carbide discharge means
61: carbide outlet 62: discharge guide tube
63: carbide discharge pipe 64: cylinder
65: opening and closing 66: opening and closing rod
70: dust discharge pipe 71: gas discharge pipe
80: gas treatment means 81: condensate water collection pipe
82: water tank 83: water level sensor
84: drain valve 85: air supply nozzle
86: supply pipe 90: waste moisture measurement sensor
100: exhaust gas moisture measurement sensor

Claims (4)

A cylindrical housing 10 installed upright on the mounting table 11 and equipped with a plurality of heaters 12 for heating, drying and carbonizing the wet waste put into some outer periphery;
And a hopper 20 installed to be connected to the inside of one upper edge portion of the housing 10 and having an input amount control valve 21 and a supply amount control valve 22 at the inlet side and the outlet side, respectively.
An air supply compartment 30 configured through a set of sealing diaphragms 31 isolated from each other on an upper side of the housing 10,
A plurality of stirring vanes 41 and the stirring vanes, which are supported by the electric motor of the driving motor M in the inside of the housing 10 to enable forward and reverse rotation, protrude to a part of the outer circumferential surface of the middle part, and the stirring vanes ( 41, a hollow working shaft 40 having a screw blade 42 configured to the lower end of the lower side and an electric gear 43 protruding out of the mounting table 11 and connected to the drive motor M. and,
Waste air supply means for supplying compressed air into the air supply compartment 30 and transporting and spraying it to the bottom of the working shaft 40 to form bubbles in the waste during the process and to give a stirring effect using air pressure ( 50),
Carbide discharge means for selectively opening and closing the carbide discharge port 61 and the carbide discharge pipe (63) which is connected to the carbide discharge port 61 perforated at the lower edge of the housing (10) and discharged carbonized waste ( 60),
An upper end is connected to the gas discharge pipe 71 is configured to communicate with the inner upper side of the housing 10 and the lower end is a dust discharge pipe 70 is configured to be connected to the carbide discharge pipe (63),
It is connected to the end of the gas discharge pipe 71 and mixed with the cooling air of the outside in the high-temperature exhaust gas containing water vapor through the induction of condensation, adsorption of fine dust, gas temperature reduction, water vapor content of the exhaust gas Gas treatment means (80) for reducing,
Waste moisture measuring sensor 90 for measuring the moisture content of the waste is fixed and installed in the inner place of the housing 10,
The exhaust gas moisture measuring sensor 100 and fixed to the inside of the gas discharge pipe 71 for measuring the moisture content of the exhaust gas, and
It is fixed to the inside of the hopper 20 and the wet waste carbonization apparatus, characterized in that it comprises a waste input amount sensor 110 for detecting the waste input amount in the hopper 20, respectively. The method of claim 1, wherein the waste air supply means 50,
An air inlet hole 51 which is drilled on the upper outer periphery of the working shaft 40 and is located in the air supply compartment 30;
An air supply hole 52 drilled on the lower outer periphery of the operation shaft 40 in a state of being connected to the air inlet hole 51;
Wet waste carbonization device characterized in that it is connected to the air supply compartment through the air supply pipe (54) and comprises an air supply (53) for supplying compressed air into the air supply compartment (30), respectively. The method of claim 1, wherein the carbide discharge means 60,
A discharge guide pipe 62 protrudingly installed in a state connected to a carbide discharge port 61 drilled at a lower edge of the housing 10 and having a carbide discharge pipe 63 connected to a bottom thereof;
A cylinder fixedly installed at an end of the discharge guide tube 62 and having an opening and closing port 65 that slides in the discharge guide tube 62 and selectively opens and closes the carbide discharge port 61 through the opening and closing rod 66 ( Wet waste carbonization device, characterized in that it comprises a 64) each. The method of claim 2, wherein the gas treatment means 80,
A condensed water collecting pipe 81 connected to an end of the gas discharge pipe 71 in a longitudinal direction;
A water tank 82 connected to the lower end of the condensate water collecting pipe 81 and having a water level sensor 83 and a drain valve 84;
Wet type characterized in that it comprises a supply nozzle (85) which is fixed to be installed to be located above the inside of the condensate water collecting pipe 81 in a state connected to the air supply (53) through the air supply pipe (86) Waste carbonization.

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