KR910009583B1 - Apparatus for fermenting excrementitous matter live stock of excrementitous - Google Patents

Abstract

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Description

Condensation Fermentation Device

1 is a longitudinal cross-sectional view of the condensation fermentation apparatus according to the present invention.

2 is a cross-sectional view taken along the line II-II of FIG.

3 is a cross-sectional view taken along the line III-III of FIG.

4 is a plan view of FIG.

5 and 6 are a partial plan view and a side view schematically showing a drive device of the axle stirring and air supply device.

7 is a schematic front view of a screw for stirring and air supply according to the present invention.

8 and 9 are a side view and a plan view of the condensation fermentation apparatus according to an embodiment of the present invention.

FIG. 10 is a schematic plan view showing a heated air passage for use in the condensation fermentation apparatus shown in FIG.

11 is a schematic representation of the agitation and air supply device used in the FIG. 9 apparatus.

12 is a cross-sectional view of the condensation fermentation device according to another embodiment of the present invention.

* Explanation of symbols for the main parts of the drawings

2,61,70: condensation fermentation warehouse or tank 4,64: condensation agitation and air supply

11: outer bottom wall 12: insulation layer

13: interior floor 14: ventilation floor

15,16: wire mesh 17: side wall

20,62: heating air supply passage 23: hot air fan

25: blower 30: air supply pipe

50: screw 51: screw shaft

53: air passage

The present invention relates to a condensate fermentation apparatus, and more particularly, to a condensation fermentation apparatus capable of shortening the fermentation period of the condensate by heating the condensate to a certain temperature and then supplying sufficient air continuously while stirring.

In general, in large poultry farms and livestock farms, there is a problem of treatment as large quantities of livestock such as poultry, pig meal or cow flour are released, and there have been efforts to use it as a compost and fertilizer as a treatment method. However, the composting of such constituents is not possible to ferment due to the climate conditions of Korea in the state of 70 to 80% moisture, and some of them are dried using solar heat. However, this is a social problem such as pollution of drinking water source into the river due to bad smell and rain. In addition, very dried things are not worth fertilizer.

Even in the case of ordinary farmers, if they want to stock or ferment these stocks to prevent or reduce the use of chemical fertilizers to use pollution-free farming methods at the village level, the fermentation period is quite long, so the storage and storage of the Not only were there problems but they were also uneconomical and inefficient in compost production.

In addition, even if the fermentation in the natural state is fermented by the low-temperature microorganisms, the fermentation is not only slow but also becomes a breeding ground of bacteria by low-temperature fermentation. It is also unsanitary to provide habitats for pests such as flies and mosquitoes. However, bacteria tend not only to fertility but also to sterilization at temperatures above 70 to 80 ° C. Therefore, fermentation of livestock powder is better to ferment at a higher temperature than natural state. That is, the fermentation is carried out by the thermophilic microorganism at a high temperature, and the fermentation rate is fast and bacteria are killed by the high temperature. Therefore, by using the compost produced by fermentation of constituents at high temperature, it is possible to prevent acidification of the soil and to produce a pollution-free food, and also to prevent environmental pollution. However, in the past, there was a big problem in providing a suitable high temperature condensation fermentation device.

Accordingly, an object of the present invention is to provide a condensate fermentation apparatus capable of speeding up the treatment of condensate and preventing pollution by condensate by significantly shortening the fermentation time of the condensate to solve the above problems and the like.

In addition, an object of the present invention is to produce a compost that can produce a pollution-free food, while at the same time can be composted at low cost to produce compost by a low-pollution farming method, to facilitate the smooth production and supply of compost. It is to provide a condensation fermentation device that can be.

These and other advantages of the present invention will be readily understood by those skilled in the art by describing the preferred embodiments of the present invention in conjunction with the accompanying drawings.

Hereinafter, with reference to the accompanying drawings of the present invention will be described in detail.

As a longitudinal cross-sectional view of the condensation fermentation apparatus according to the present invention in FIG. 1, the condensation fermentation apparatus is composed of a condensation fermentation warehouse or tank 2 and a condensation stirring and air supply device 4. The bottom of the condensation fermentation warehouse or tank 2 has an outer bottom wall 11 made of cement or the like from below, and a heat insulating material made of a heat insulating material installed inside the bottom wall 11 to prevent heat from being released to the outside. It consists of the layer 12, the inner bottom 13 which formed the heating air passage 20 mentioned later, the ventilation bottom 14 provided with the air supply pipe 30, and the wire mesh 15. As shown in FIG. The side of the condensation fermentation warehouse or tank 2 consists of an existing side wall 17. In the upper part of the heating air passage 20 provided in the inner bottom 13, the wire net 16 is provided so that the gravel which forms the ventilation floor 14 which is the upper layer does not fall down. The gravel of the ventilation floor 14 may be sized so as to be introduced into the fermentation storage warehouse or the tank 2 in a state in which air or heated air is evenly distributed as described below to supply appropriate air to the shaft. The upper wire mesh 15 is for smooth removal of the fermented shaft.

FIG. 2 is a sectional view taken along the line II-II of FIG. 1, showing the configuration of the above-described heating air passage 20. As shown in FIG. A hot air blower 23 such as a burner is provided at the inlet 22 of the heated air passage 20, and a blower 25 is provided at the outlet 24. The heated air heated in the hot air blower 23 enters the blower 25 after passing through the heated air passage 20 in a path as shown by an arrow. At this time, a part of the heating air exits through the wire mesh 16 provided on the heating air passage 20 as shown in FIG. 1, the ventilation floor 14 on which the gravel is stacked, and the wire mesh 15. A three port two-way valve (not shown) is provided between the outlet 24 and the blower 25, in which case heated air flows into the blower 25, and in other cases, air enters the blower. This will be described later.

3 is a cross-sectional view taken along the line III-III of FIG. 1, and as described above, heated air or air sucked by the blower 25 is forcibly introduced into the air supply pipe 30, and the air supply pipe 30 is shown in FIG. Through the holes 27 formed on the surface, the gravel-vented ventilation floor 14 is introduced into the diesel fuel, storage of fermentation warehouse or tank 2 to supply the appropriate air to the powder.

The heated air flowing from the hot air blower 23 into the shaft fermentation warehouse or tank 2 not only raises the temperature of the bottom and the interior of the shaft fermentation warehouse or tank 2 but also raises the temperature to the temperature required for fermentation of the shaft powder. . Therefore, it is possible to shorten the fermentation time of the livestock by reaching the fermentation temperature earlier than the livestock stored in the open air or general livestock storage warehouse. In addition, the heating air is continuously supplied through the heating air passage 20 and the air supply pipe 30 to supply sufficient oxygen for fermentation, thereby shortening the fermentation time. In general, when the shaft portion rises to a certain temperature, for example, 60 to 70 ° C., it is no longer required to be heated by the fermentation heat of the shaft portion. Thus, in this case, as already mentioned, the air blower 23 is turned off and the two-way valve (not shown) is operated to introduce air through the blower 25 to continuously maintain air (or oxygen) through the air supply pipe 30. To supply.

In order to smoothly supply the air, the present invention provides a shaft agitation and air supply device 4 as shown in FIGS. 1 and 4 to 6. FIG. 4 is a plan view of the shaft stirring device, and FIGS. 5 and 6 are partial plan and side views schematically showing the drive device, and the shaft stirring and air supply device 4 is provided with a rail 18 provided on the side wall 17. It is configured to reciprocate from the upper sidewall 17 to the left and right (based on FIG. 1) by the pulley 42 traveling on the above. The shaft stirring and air supply device 4 includes a main frame 41, a reversible drive motor 45 and 46 attached thereto, a rotation shaft 43 rotatably installed on the main frame 41, and the rotation shaft. It consists of a screw 50 which is rotated by 43. As shown in FIG. 6, a pulley 42 is provided below the main frame 41, and the pulley 42 is connected to the rotation shaft 47. The rotation shaft 47 is provided with a pulley 48 to be driven by the pulley 46 and the belt 44 of the drive motor 45. Therefore, when the drive motor 45 is driven, the rotation shaft 47 is driven to rotate through the pulley 46, the belt 44 and the pulley 48 to rotate the pulley 42. As the pulley 42 rotates, it travels on the rail 18 on the side wall 17, so that the axial stirring and air supply device 4 can reciprocate back and forth on the side wall 17. In addition, the screw 50 is installed at equal intervals perpendicular to the frame plane (see FIG. 1), and the driven gear 52b is mounted on the upper end of the screw shaft 51 of the screw 50, respectively. The screw shaft 51 is rotatably mounted to the frame 41 by means such as a thrust bearing suitable for it. As shown in FIG. 5, the rotating shaft 43 rotatably installed on the upper portion of the frame 41 has a driving gear 52a interlocked with the driven gear 52b mounted on the screw shaft 51. The number and intervals of the mounting. Moreover, the pulley 57 of the drive motor 56 and the pulley 59 driven by the belt 58 are attached to the rotating shaft 43. As shown in FIG. Therefore, when the drive motor 56 is driven, the driving force is attached to the pulley 59 which is driven by the pulley 57 and the belt 58. Therefore, when the drive motor 56 is driven, the driving force is transmitted to the rotation shaft 43 through the pulley 57, the belt 58, and the pulley 59 so that the rotation shaft 43 rotates, and this rotation force is each pair It is transmitted to the screw 50 through the gears 52a and 52b of the screw 50 to rotate.

As shown on the right side of Figs. 5 and 6, the axis of the drive gear 52a and the axis of the driven gear 52b are configured to cross each other. Accordingly, the drive gear and the driven gear may use spiral gears or hyperboloidal gears, or may be used as worm and worm gears. This staggered configuration is for injecting air into the air passages 53 formed in the longitudinal direction on the screw shaft 51 through the air holes 53a from the pressurized air source, which will not be described later.

The configuration of this screw 50 is shown in detail in FIG. 7 is a front view of the screw 50, the screw 50 is a screw shaft 51 in the form of a pipe formed with an air passage 53 formed along the longitudinal axis thereof, and a screw thread 54 formed on the screw shaft 51. It is composed. The air passage 53 of the screw shaft 51 communicates with a pressurized air source (not shown) through an air hole 53a formed at the upper end of the screw shaft 51. The thread 54 serves to agitate the shaft portion as the screw 50 rotates by the operation as described above, and a plurality of air holes 53b are formed in the screw shaft 51 portion between the threads 54. The air introduced from the air hole 53a through the air passage 53 is supplied to the shaft portion through the air hole 53b. The air hole 53b may be formed not only in the screw shaft 51 but also in the thread 54.

The operation of the present invention configured as described above will be described with reference to the drawings. First, a proper amount of shaft powder is put into the shaft fermentation warehouse or tank 2, and the two-way valve (not shown) is operated to operate the heated air passage 20 and the blower ( 25) to communicate. Thereafter, by operating the hot air fan 23 to supply the heating air to the heating air passage 20, a part of the heating air is introduced into the tank 2 through the wire mesh 16 on the heating air passage 20, The remaining heating air is supplied to the air supply pipe 30 through the outlet 24 and the blower 25 and introduced into the tank 2. At this time, since the gravel is covered on the air supply pipe 30 and the air discharged through the air hole 27 is dispersed by the gravel, uniform air supply is possible. The supplied heated air raises the temperature inside the tank 2. When the temperature inside the tank 2 or the temperature of the condensate reaches a temperature suitable for fermentation and the fermentation is made to a certain level, the temperature of the condensate is maintained by the heat of fermentation even if no heating air is supplied. At this time, the operation of the hot air blower 23 is stopped, and the two-way valve (not shown) is operated to allow the blower 25 to communicate with the atmosphere. Thus, the blower 25 introduces the atmosphere into the air supply pipe 30. The blower 25 is operated until the fermentation of the shaft powder is completed to supply sufficient air for fermentation.

Simultaneously with the above operation, the shaft agitation and air supply device 4 are operated. When each of the drive motors 45 and 46 is driven, the pulley 42 and the screw 50 rotate so that the shaft agitation and air supply device reciprocates back and forth in the tank 2 and at the same time flows into the shaft. Sufficient air flows in while being gently stirred by the rotating operation of the respective screws 50. In general, the agitation of the shaft powder and the operation of the air supply device 4 do not need to be continuously maintained, and when it is operated once or twice a day, the shaft powder is sufficiently stirred and at the same time, sufficient air for fermentation can be supplied.

When using the livestock fermentation apparatus of the present invention, it takes only about one week for the livestock to ferment. Therefore, if the stock is stored in a warehouse or a tank, fermentation is impossible due to temperature conditions, and becomes a habitat for odors and various bacteria. According to the technology of the present invention, since the fermentation can be performed within a short time, the storage warehouse of the livestock powder can be reduced by that much, and once the fermented food stock is fertilized, it is not a problem for pollution even if it is stored outdoors. In addition, the composting can be quickly and easily supplied to the compost for the farmhouse. This is very economical because it can be supplied and supplied compost smoothly when operating in a pollution-free farm. In addition, since a large amount of livestock can be disposed of in a short time, it can be installed and operated in villages or small scale farmers, which can be very economical in preparing livestock and treat compost and contribute to preventing pollution.

An embodiment of the present invention will be described with reference to FIGS. 8, 9, 10 and 11, FIG. 8 is a side view of the condensation fermentation apparatus according to an embodiment of the present invention, and FIG. 9 is a plan view of FIG. Fig. 8 is a plan view of the heating air passage used in the condensation fermentation apparatus shown in Figs. 8 and 9, and Fig. 11 is a schematic view of the stirring and air supply apparatus used in the condensation fermentation apparatus shown in Figs. , The condensed fermentation apparatus according to the embodiment of the present invention is different in that the condensed fermentation warehouse or tank 61 is cylindrical unlike the condensed fermentation warehouse or tank 2 described above. Accordingly, the heated air passage 62 is also formed in a circle. The center column 63 is provided in the center of the storage powder fermentation warehouse or the tank 61. Accordingly, the shaft agitation and air supply device 64 has one end rotatably installed on the central column 63 via the shaft 65, and the other end on the rail 68 of the side wall by the pulley 67. It is slidably installed. The configuration and operation of each drive motor, the rotating shaft and the screw are the same as described above, and thus will not be described in detail. However, when the drive motor for driving the pulley 67 is operated, the pulley 67 travels along the rail 68 and thus causes the shaft agitation and air supply device 64 to rotate about the center column 63. do.

Further, as well shown in FIGS. 8 and 11, each screw 65a, 65b, ... 65n of the axle stirring and air supply device 64 according to the present embodiment is a screw 50 as described above. ), They have different diameters and spacing. That is, the thread diameter of the screw decreases toward the central axis. In addition, the spacing between the screws is also reduced (d ₁ > d ₂ > d ₃ ... d _n ). The reason for forming a smaller diameter and spacing toward the central axis as described above is that a circle farther from the shaft is larger than the inner screw. Along with the point of traveling on the track, the thrust of the screw having a larger diameter is generated by the rotation of the large diameter screw, which causes the shaft agitation and the force that the air supply device 64 attempts to rotate to generate. This is to assist the shaft stirring and the rotational force of the air supply device (64).

Condensation fermentation device according to an embodiment of the present invention can be more effectively designed in the pressurized air passage and the air supply pipe than the hexahedral condensation fermentation device can be more smoothly the temperature rise of the shaft and the air supply. In addition, in the case of designing the condensation fermentation tank having the same cross-sectional area, the size of the condensation agitation and the air supply device 64 can be reduced, so that the economic effect of reducing the number of screws and the like required can be obtained.

12 shows a stock fermentation warehouse or tank 70 according to another embodiment of the present invention. This is different in that the large iron mesh 71 and the small iron mesh 72 are provided in the shaft fermentation warehouse or tank 2 or 61 of FIG. The wire meshes 71, 72 are for supplying air to the shaft through the interior of the side wall 17. In addition, an appropriate size and number of discharge ports 73 are provided below the side wall 17. The discharge port 73, together with the wire meshes 71 and 72, is intended to allow the water contained in the shaft to be collected along the inside of the side wall 17 at the bottom and discharged through the discharge port 73.

All of the above-mentioned condensation fermentation warehouses or tanks 2, 61, and 70 may be provided with the discharge port 73, and condensation usually contains 50% or more of moisture, but these tanks mainly contain water of 70 to 70%. Very suitable for 80% of cases. Conventionally, there has been a significant difficulty in fermenting such moisture content fractions, but according to the present application this problem can be solved.

In addition, although the side wall 17 is provided in FIG. 12, the support column for removing a side wall and supporting a wire mesh and a rail can also be provided in a side wall position suitably. In this case, the air supply is smoother. However, in the winter it is preferable to install between the support pillars with a vinyl or heat insulating material for the warming effect. In addition, the wire mesh can increase its use effect by appropriately adjusting the size of the wire mesh in particular according to the moisture content of the shaft to be fermented.

Although the present invention has been described in detail above through each embodiment, it will be appreciated that the present invention is not limited thereto. The same effect may be achieved, for example, by using a different suitable drive transmission mechanism to transmit the driving force from the drive motor to the pulley and the screw.

Although not described in detail herein, an outlet door (66 in FIGS. 9 and 10) for discharging the shaft portion may be provided at an appropriate position. The transport mechanism required for the reciprocation or rotation of the shaft agitation and air supply may be replaced by other suitable mechanism. In addition, the roof may be provided in the shaft fermentation warehouse or tank top to prevent snow, rain, and the like.

Claims (8)

In a condensate fermentation apparatus in which a condensate is loaded into a condensate fermentation warehouse or a tank (2) to supply air to the condensate, and the condensation is agitated by a condensation stirring device capable of reciprocating on the condensate fermentation warehouse or a tank (2). , The bottom of the condensation fermentation warehouse or tank forms an insulation layer 12 on the outer bottom wall 11 and an inner bottom 13 and an air supply pipe 30 on which a heated air passage 20 or 62 is formed. A stacking structure consisting of a ventilation floor 14 and a wire mesh 15 installed therein, and the shaft agitation and air supply device 4 installed on the sidewall 17 of the shaft fermentation warehouse or tank, rotates a plurality of screws 50 on the shaft. Condensation fermentation device, characterized in that rotatably installed on the 43 at a predetermined interval. The method according to claim 1, wherein the hot air blower (23) is installed at the inlet (22) of the heated air passage (20 or 62), and the blower (25) is installed at the outlet (24) of the heated air passage (20 or 62). And at the same time the inlet of the blower (25) is selectively in communication with the outlet (24) or the atmosphere to selectively supply heating air or atmosphere to the air supply pipe (30). The condensation fermentation apparatus according to claim 1, wherein the condensation fermentation warehouse or the tank (61) has a cylindrical shape and a central column (63) is provided at the center. 4. Condensation fermentation apparatus according to claim 3, characterized in that the condensation stirring and air supply device (64) is rotatable along the side wall about an axis (65) located in the center column (63). The condensation fermentation apparatus according to any one of claims 1 to 4, wherein a wire mesh (71,72) is provided in the condensation fermentation warehouse or a tank, and a discharge port (73) is provided under the side wall. The condensation fermentation apparatus according to any one of claims 1 to 4, wherein a wire mesh (71, 72) is provided in place of the sidewall (17) of the condensation fermentation warehouse or tank. The screw 50 of Claim 1 or 4 rotatably provided in the axial-stirring stirring and air supply apparatus 4 or 64, The screw shaft 51 in which the air passage 53 was formed along the longitudinal axis, A screw thread (54) formed in the screw shaft (51) and a screw hole or an air hole (53b) in communication with the air passage (53) in the screw shaft therebetween, characterized in that the condensation fermentation device. 5. The shaft stirring and air supply device 64 is characterized in that the spacing and diameter therebetween gradually increase as the screws 65a, 65b, ... 65n move from the shaft 65 side to the side wall 17. Condensation fermentation device, characterized in that the.

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