KR101683864B1 - Disposer of food waste - Google Patents

Abstract

The present invention discloses a food garbage disposal facility. The garbage disposal system includes a garbage fermentation tank into which food waste is introduced and fermented, a rotary shaft rotatably installed in the garbage fermentation tank, a rotary shaft coupled to the rotary shaft so as to be separated from the inner bottom surface of the waste fermentation tank, And a stirring unit which stirs the food waste fermented in the food waste to keep the level of the food waste constant.

Description

DISPOSER OF FOOD WASTE [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a food garbage disposal apparatus, and more particularly, to a food garbage disposal apparatus capable of gradually transferring food garbage to be fermented in the inside as the fermentation time elapses, The present invention relates to a garbage disposal facility.

In general, food waste left in homes and restaurants is discharged daily. Such food garbage contains a large amount of water, which causes spoilage in a short time, causing odor and causing bacteria to multiply rapidly.

Especially, the amount of food garbage is so large as to occupy more than 30% of the household garbage, and the treatment is very difficult. In general, food waste is buried in landfill or incinerated. However, as the landfill is limited and secondary environmental pollution problems arise due to landfill and incineration, studies for treating food waste are proceeding in various forms.

Until recently, although much effort has been made to treat food waste more hygienically, there is no specific method other than collection of most food waste using a separate collection box.

Recently, food waste has been fermented and recycled as compost. However, there is a lot of odor in the process of fermentation and composting of food waste, a large amount of secondary pollutants such as waste water, There is a problem that it is very difficult to treat secondary pollutants.

Therefore, there is a need to improve this.

Korean Patent Registration No. 10-0890206 (filed on Mar. 17, 2009, entitled " Food waste disposal apparatus and food waste disposal method using the same) Korean Registered Patent No. 10-1184149 (Registered on September 12, 2012, entitled " Method for manufacturing compost using litter and food waste)

The present invention has been made in view of the above-mentioned need, and it is an object of the present invention to provide a sliding roll type heat insulating shutter which can prevent the wear and scratch of the outer surface, .

According to an aspect of the present invention, there is provided a garbage disposal apparatus comprising: a garbage fermentation tank into which food waste is charged and fermented; A rotating shaft rotatably installed in the waste fermentation tank; And a stirring unit coupled to the rotating shaft so as to be spaced apart from the inner bottom surface of the waste fermentation tank and stirring the food waste fermented in the waste fermenter while rotating together with the rotating shaft to keep the level of the food waste constant. do.

The waste fermentation tank is characterized by having two or more fermentation spaces.

Further, the stirring unit is characterized in that the stirring unit is provided so as to be spaced apart from the rotating shaft so as to be respectively located in the plurality of fermentation spaces.

The stirring unit may further include: an axis coupling unit coupled to the rotation shaft; And a stirring member that is coupled to the shaft coupling unit at equal intervals so as to be horizontal with the rotation shaft.

The plurality of stirring members may have different lengths and may be formed in a circular shape so as to reduce frictional force with the food waste.

The shaft coupling portion may include: a rim member coupled to the rotation shaft; A support rod member vertically coupled to the rim member; And a ring member joined to the supporting rod member and to which the stirring member is joined.

The shaft coupling portion may include: a rim fixing member for selectively fixing the rim member to the rotation shaft so as to adjust a coupling position of the rim member on the rotation shaft; And a support bar fastening member for detachably attaching the rim member to the support rod member.

The rim fixing member may include: a fastening hole formed in the rim member; And a bolt member fastened through the fastening hole and closely attached to the rotation shaft.

The rim fixing member may further include a flow preventing groove formed on an outer surface of the rotating shaft so as to prevent the flow of the rim member by inserting the bolt member.

Further, the support bar fastening member may include: a female screw portion formed on the rim member; And a male screw portion formed on the support bar member to be coupled to the female screw portion.

As described above, the food garbage disposal facility of the present invention differs from the prior art in that the food garbage to be fermented therein is gradually transported as the fermentation time elapses and the surface of the food garbage to be transported is horizontally The fermentation effect of the food waste can be improved.

1 is a perspective view illustrating a garbage disposal apparatus according to an embodiment of the present invention.
2 is a plan view of Fig.
3 is a side view of Fig.
FIG. 4 is a perspective view illustrating a dust particle remover according to an embodiment of the present invention. FIG.
5 is a side view of Fig.
6 is a cross-sectional view of Fig.
7 is a perspective view illustrating a foreign matter separator according to an embodiment of the present invention.
8 is a perspective view illustrating a cutting unit according to an embodiment of the present invention.
9 is a cross-sectional view illustrating a trash mature tank according to an embodiment of the present invention.
10 is a perspective view illustrating a waste fermenter and a stirrer according to an embodiment of the present invention.
11 is an assembled cross-sectional view of Fig.
12 is an exploded perspective view illustrating a waste fermenter according to an embodiment of the present invention.
13 is a perspective view illustrating an agitator according to an embodiment of the present invention.
14 is a perspective view showing a stirring unit according to an embodiment of the present invention.
FIG. 15 is a perspective view illustrating a rim fixing member and a support bar fastening member according to an embodiment of the present invention.
Fig. 16 is an assembled sectional view of Fig. 15. Fig.
17 is a perspective view illustrating a waste fermentation tank and a fermentation air circulation apparatus according to an embodiment of the present invention.
18 is a perspective view illustrating a fermented air circulating apparatus according to an embodiment of the present invention.
19 is a plan sectional view of Fig.
20 is an exploded perspective view illustrating a heat exchange and dehumidifier according to an embodiment of the present invention.
FIG. 21 is an assembled cross-sectional view of FIG. 20 showing a heat exchange and dehumidifier according to an embodiment of the present invention.
22 is an exploded perspective view showing a dry air cooler according to an embodiment of the present invention.
23 is an end view of FIG. 22 showing a dry air cooler according to an embodiment of the present invention.
24 is an air flow chart for explaining an air flow of a food waste disposal facility according to an embodiment of the present invention.

Hereinafter, a preferred embodiment of the present invention will be described with reference to the accompanying drawings. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

2 is a plan view of FIG. 1, FIG. 3 is a side view of FIG. 1, and FIG. 4 is a cross-sectional view of a food garbage disposal apparatus according to an embodiment of the present invention. FIG. 2 is a perspective view showing a waste foreign material remover. FIG.

FIG. 5 is a side view of FIG. 4, FIG. 6 is a sectional view of FIG. 4, FIG. 7 is a perspective view illustrating a foreign matter separator according to an embodiment of the present invention, Fig.

As shown in FIGS. 1 to 8, the food garbage disposal apparatus according to the present embodiment is configured such that the garbage from which the foreign substance is removed from the refuse removing unit 100 is transferred to the refuse-aging fermenter 200, and aged and fermented. In order to improve the fermentation effect of the food waste, the food waste disposed in the fermentation fermenter 200 is aged in the waste aging tank 210 and then put into the refuse fermentation tank 220 for fermentation do.

In order to further improve the fermentation effect of the food waste according to the present embodiment, non-perishable foreign substances such as vinyl are removed from the waste foreign material removing unit 100 and then introduced into the waste aging tank 210.

The trash foreign material remover 100 includes a main body 110 into which food waste is introduced, a foreign matter separator 120 rotatably installed in the main body 110, a tilt regulator 130). The food waste disposal system includes a first conveyor 140 for transferring the trash removed from the foreign material, a second conveyor 150 for transferring foreign substances discharged from the foreign material separator 120, a first conveyor 140, And a garbage storage tank 160 in which food waste transported by the storage tank 160 is stored.

In addition, the food waste treatment facility removes moisture by a dehydrator (not shown) before the food waste is introduced into the main body 110, and the food waste introduced into the waste storage tank 160 is discharged through the screw conveying system 210 to be processed.

The main body 110 is hinged to the mounting structure, and the tilt is adjusted by the tilt adjusting part 130. The main body 110 is provided with a hopper 111 at one end so as to easily insert the food waste into the foreign matter separating part 120 and a foreign matter discharged from the foreign matter separating part 120 to the second conveyor 150 The discharge guide member 113 is provided at the other end. At this time, one end of the hopper 111 is inserted into the foreign material separator 120. This is to prevent the food waste introduced into the foreign material separating unit 120 from being released to the outside of the foreign material separating unit 120 through the hopper 111.

The main body 110 further includes a waste conveying unit 115 for conveying the food waste discharged from the foreign material separating unit 120 to the first conveyor 140. The main body 110 has a feed installation part 110a formed at the lower part thereof to prevent the waste feed part 115 from being exposed to the outside.

The main body 110 is formed with a waste transfer part 115 by a conveyor and a discharge hole part for discharging food waste to the first conveyor 140 at the end of the transfer installation part 110a. The food waste discharged to the waste discharge hole portion is discharged to the first conveyor 140.

The foreign matter separating unit 120 includes a rotating drum 121 rotatably coupled to the inside of the main body 110, a cutting unit 123 for cutting the food waste introduced into the rotating drum 121, (Not shown). The foreign matter separating unit 120 cuts the food waste while transferring the food waste to be supplied to the rotary drum 121 through the rotation of the rotary drum 121 installed to be inclined by the main body 110. That is, the foreign material separating unit 120 separates the food waste to be cut into the rotary drum 121 and discharges the food waste to be cut to the outside of the rotary drum 121, And is discharged to the portion 113.

The rotary drum 121 is formed with a plurality of garbage discharge holes 121a so as to separate garbage to be finely cut by the cutting portion 123 into the waste transfer portion 115. The rotary drum 121 is provided with shaft engagement members 121b rotatably coupled to the main body 110 through rotation shafts on the inner surfaces of both ends. In addition, the rotary drum 121 is inserted and coupled with the shaft coupling member 121a so that the lower end of the hopper 111 is positioned inside.

In addition, the rotary drum 121 discharges the food waste, which is cut to a specific size or less by rotation, to the waste conveying unit 115 through the waste discharge hole 121a.

The cutting portion 123 is detachably inserted into the rotary drum 121 and cuts food garbage that is rotated and dropped by the rotary drum 121. The cutting portion 123 includes a cutting blade 123a for cutting food waste, a detachable plate 123b joined to the inner surface of the rotary drum 121 by being joined to the cutting blade 123a, 123b for fixing the rotary drum 121 to the rotary drum 121.

The cutting edge 123a has a triangular shape so as to effectively cut the food waste. The cutting blade 123a is joined to the desorption plate 123b through welding. The detachable plate 123b is formed with an engaging hole so that the detachable member 123c passes therethrough.

The detachable member 123c is composed of a bolt passing through the rotating drum 121 and the detachable plate 123b and a nut fastened to the bolt.

The tilt adjusting unit 130 is coupled with the main body 110 to adjust the inclination of the main body 110 so as to adjust the feeding speed of the food waste supplied to the rotating drum 121. The tilt adjusting unit 130 includes a support member 131 coupled to the main body 110, a bolt member 133 coupled to the support member 131, And a base member 135 supported by the base member 135. At this time, the base member 135 is formed with a rotating wave 135a so as to rotate the bolt member 133 by fastening the tool.

The support member 131 is formed with a space portion therein so that the bolt member 133 can be smoothly lifted and lowered when the bolt member 133 is lifted and rotated.

The lower end of the bolt member 133 is joined to the base member 135 and the upper end of the bolt member 133 is fastened to the support member 131 and is lifted and lowered by the support member 131 while rotating together with the rotation of the base member 135.

The tilt adjusting unit 130 according to the present embodiment may be provided with a plurality of tilt adjusting units 130 spaced apart from the main body 110 so as to stably support the main body 110.

The first conveyor 140 is supplied with food waste from which foreign substances have been removed from the main body 110 and the second conveyor 150 and transfers the food waste to the waste storage tank 160.

The second conveyor 150 is supplied with foreign matter discharged from the rotary drum 121. The foreign matter supplied to the second conveyor 150 is completely separated by the operator, and only the remaining food waste is discharged to the first conveyor 140. For this, the second conveyor 150 is positioned above the first conveyor 140, and the length of the second conveyor 150 is shorter than the length of the first conveyor 140.

The driving unit 125 is fixed to the main body 110 by a speed reducer connected to the rotating drum 121 through a rotating shaft and a constant speed motor is installed in the speed reducer to rotate the rotating drum 121 in normal and reverse directions.

The food garbage disposal apparatus according to the present embodiment configured as described above is constructed such that the food waste put into the rotary drum 121 through the hopper 111 of the main body 110 is fed to the rotary drum 121 And is cut by the cutting blade 123a.

At this time, the food waste that is cut smaller than the waste discharge hole 121a is separated into the waste conveyance part 115 through the waste discharge hole 121a, and foreign materials such as vinyl and bone are not cut by the cutting blade 123a, And is continuously delivered from the inside of the drum 121 and discharged to the second conveyor 150 through the discharge guide unit 113. [

The foreign matter, such as vinyl, is completely removed from the foreign matter discharged to the second conveyor 150 and transferred to the first conveyor 140 by the operator.

In particular, the tilt of the main body 110 is adjusted by the tilt adjusting unit 130 according to the type and amount of the food waste put into the rotating drum 121. That is, if the inclination of the main body 110 is large, the feeding speed of the food waste increases and the amount of the food waste to be processed can be increased. If the inclination of the main body 110 is small, the feeding speed of the food waste is slowed, Is reduced.

The food waste separated from the waste foreign material remover 100 and transferred to the waste storage tank 160 is transferred to the waste aging fermenter 200 through a screw conveying method and aged and fermented. This will be described in detail with reference to FIG. 9 to FIG.

10 is a perspective view illustrating a waste fermenter and a stirrer according to an embodiment of the present invention, and FIG. 11 is a sectional view And FIG. 12 is an exploded perspective view illustrating a waste fermenter according to an embodiment of the present invention.

As shown in FIGS. 1, 9 to 12, the fermentation fermenter 200 according to the present embodiment ages and ages and ferments food waste supplied from the refuse storage tank 160. The waste fermentation fermenter 200 ages the food waste to be fed into the compost, and composts the fermentation process at various stages. The waste fermentation fermenter 200 includes a waste aging tank 210 for aging food waste, a waste fermentation tank 220 for supplying food waste from the waste aging tank 210 and fermenting the supplied food waste, .

The waste aging fermenter 200 is provided with a stirrer 230 for stirring the food waste in the waste aging tank 210 and the waste fermentation tank 220 so that aging and fermentation of the food waste to be aged and fermented can proceed smoothly Respectively.

In the waste fermentation fermenter 200, two or more waste fermentation tanks 220 are connected in parallel to a single waste aging tank 210, and the food waste aged in the waste aging tank 210 is supplied to the waste fermentation tank 220 And simultaneously fed and fermented. At this time, the waste fermentation tank 220 is installed in two or more stages in order to more effectively ferment food waste.

In the waste aging tank 210, food waste stored in the waste storage tank 160 is injected through a screw system, and food waste put into the agitation tank 230 is agitated while being stirred by an agitator 230. The waste aging tank 210 includes an aging tank 211 into which food waste is introduced and a tank dividing section 213 that divides the internal space of the aging tank 211. [

At this time, the waste aging tank 210 is filled with fermenting microorganisms for the good aging of food waste.

The agitator 230 is rotatably installed in the aging tank 211 and the food waste injected into the agitating tank 210 is divided into three spaces by the tank partition 213. This is to ensure that the surface of the food garbage to be aged while being stirred by the stirrer 230 is maintained smoothly. Therefore, the food waste is supplied to all the waste fermentation tanks 220 connected in parallel to the waste aging tank 210 at a predetermined amount, so that the fermentation of the food waste uniformly proceeds in all the waste fermentation tanks 220.

The aging tank 211 has an inlet 211a through which food garbage is introduced into the rear surface and a plurality of discharge ports 211b through which the aged food garbage is discharged. The discharge port 211b of the aging tank 211 is connected to the waste fermentation tank 220 through the connecting member 240.

In addition, the aging tank 211 is provided with an internal air outlet 211c for discharging the humid air of high temperature and humidity generated during the aging of the food waste to the external fermentation air circulation apparatus 300. The aging tank 211 is formed with a dehumidifying air inlet 211d through which the air dehumidified by the fermentation air circulating device 300 flows. At this time, in the aging tank 211, an inner air outlet 211c and a dehumidifying air inlet 211d are formed on both sides of the upper end so that the inner air can be dehumidified while being smoothly circulated by the fermented air circulating device 200. [ Particularly, the aging tank 211 is provided with a plurality of inner air outlet 211c and a dehumidifying air inlet 211d, and a plurality of inner air outlet 211c and dehumidifying air inlet 211d are communicated with the cover 211e by a communication case 211e. do. The communication case 211e is connected to the fermentation air circulation device 300 through a pipe.

In addition, the aging tank 211 is divided into three spaces by the tank dividing section 213, and the charged food wastes are aged for about 10 to 13 days, and then put into the waste fermentation tank 220. In addition, the aging tank 211 is sealed by the tank lid 215, and the tank lid 215 is provided with an aging tank check door 215a for confirming the inside thereof.

The tank dividing section 213 has a plate shape, and two of the tank dividing sections 213 are disposed apart from the aging tank 211 to divide the aging tank 211 into three spaces. The outer surface of the tank dividing section 213 is welded to the aging tank 211 by welding and an opening 213a for moving food waste is formed at the center.

The garbage ripening tank 210 according to this embodiment is configured such that the food garbage which is aged inside is horizontally maintained by the stirrer 230 and the tank dividing unit 213 and is discharged to the discharge port 211b 211b to the waste fermentation tank 220. For this, the height of the discharge port 211b is located at a position higher than the charging port 221 of the waste refinement tank 220 in the trash maturing tank 210.

The waste fermentation tank 220 is connected to the discharge port 213a of the aging tank 211 through the connecting member 240, and the aged food waste is charged and fermented.

The waste fermentation tank 220 according to the present embodiment is connected to the waste aging tank 210 in parallel, and two or more of the waste trash fermentation tanks 220 are installed in multiple stages so that food waste can be gradually fermented. The trash fermentation tanks 220 arranged in multiple stages are connected to each other through the connection member 240 and the food waste fermented in one of the trash fermentation tanks 220 is transferred to the adjacent one of the trash fermentation tanks 220 And fermented. As described above, the plurality of waste fermentation tanks 220 arranged in multiple stages are reduced in size in a stepwise manner in order to accommodate the food waste having a gradually decreasing volume due to the fermentation process step by step.

The fermentation air circulation device 300 for dehumidifying the humid air of high temperature and high humidity, which occurs in the process of fermenting food waste, is installed in each of the refuse collection tanks 220. At this time, the inner temperature of the waste fermentation tank 220 is maintained at 50 to 60 degrees by the fermentation air circulation device 300 so that the fermentation of the food waste fermented therein is progressed smoothly and the fermentation time is shortened .

The waste fermentation tank 220 includes a fermentation tank 221 into which food waste is charged and fermented, a tank partition wall 223 partitioning the interior of the fermentation tank 221, And a detachable mounting portion 227 for detachably attaching the stirrer 230. The tank supporting portion 225 is provided with a detachable mounting portion 227,

The fermentation tank 221 is formed at both ends with a charging port 221a and a discharging port 221b through which food waste is charged and discharged. The fermentation tank 221 is partitioned into three spaces by the tank partition wall portion 223 and the discharge port 211a is connected to the discharge port 211b of the waste aging tank 210 through the connecting member 240 ).

In addition, the inlet 221a and the outlet 221b are located on the horizontal line so that the food waste to be fermented in the fermentation tank 221 is conveyed to the neighboring other waste fermentation vessels 220 in a horizontal state. That is, the fermentation tank 221 is filled with the food waste to be fermented up to the height of the discharge port 221b, and then discharged to the discharge port 221b. In this embodiment, the inlet 221a and the outlet 221b of the fermentation tank 221 are positioned on the horizontal line, but the inlet 221a may be formed at a position higher than the outlet 221b .

In addition, the fermentation tank 221 according to the present embodiment is hermetically sealed by the tank cover 221c, and the fermentation tank check door is provided in the tank cover 221c so that the inside thereof can be confirmed.

The surface of the food waste which is stirred in the fermentation tank 221 by the stirrer 230 is kept constant and the food waste to be fermented is discharged from the inlet 221a of the fermentation tank 221 to the outlet 221b.

To this end, two or more tank partition wall portions 223 are joined to the fermentation tank 221 at regular intervals, and a penetration portion 223a for moving food waste is formed at an upper end portion. For example, two tank partition wall portions 223 are provided so as to be spaced apart from the fermentation tank 221 to separate the fermentation space of the fermentation tank 221 into the first fermentation space 220a, the second fermentation space 220b, And is divided into a fermentation space 220c. The food waste charged into the first fermentation space 220a of the fermentation tank 221 through the inlet 221a is filled up to the penetration portion 223a and fermented, And transferred to the fermentation space 220b to be continuously fermented. That is, the garbage fermentation tank 220 divided by the tank partition wall portion 223 is fermented while the food waste is gradually moved from the first fermentation space 220a to the third fermentation space 220c.

For example, the food waste put into one of the waste fermentation tanks 220 is moved at low speed along the first fermentation space 220a, the second fermentation space 220b, and the third fermentation space 220c, It is fermented for 15 days and then discharged. At this time, the food waste put into the waste fermentation tank 220 must be appropriately filled in accordance with the discharge capacity of the food waste discharged from the fermentation process.

Meanwhile, the fermentation tank 221 is stably installed on the ground or the structure by the tank supporter 225, and the installation height is variously adjusted. Whereby two or more fermentation tanks 221 can be easily installed in multiple stages.

The tank support member 225 includes a tank seating member 225a coupled to the lower surface of the fermentation tank 221 and a support plate member 225b coupled to the tank seating member 225a and attached to the ground . At this time, the support plate member 225b is fixed to the ground via bolts and nuts.

The tank seating member 225a is formed with a seating groove having the same shape as the outer surface of the tank supporting portion 225 so as to stably engage the fermentation tank 221 and is joined to the supporting plate member 225b. The tank seating member 225a is joined to the fermentation tank 211 and the support plate member 225b by a welding method.

The support plate member 225b is cut to an appropriate length according to the installation height of the fermentation tank 221 and used. Thus, the height of the fermentation tank 221 can be variously adjusted by cutting the support plate member 225b.

The tank support member 225 according to the present embodiment may be formed integrally with the tank seat member 225a and the support plate member 225b, respectively.

In addition, the waste fermentation tank 220 according to the present embodiment includes a fermentation tank 221 and a detachable attachment portion 227 on the tank partition wall portion 223 so as to easily attach and detach the stirrer 230 for stirring the food waste Respectively. Accordingly, the stirrer 230 can be easily installed in the waste fermentation tank 220, and the maintenance of the stirrer 230 can be facilitated.

The attaching / detaching attachment portion 227 is configured such that the stirrer 230 has an installation elongated hole 227a formed in the fermentation tank 221 and the tank partition wall portion 223, Preventing plate 227b. The detachable attachment portion 227 is inserted or removed by the installation slot 227a and the upper end of the installation slot 227a is covered through the engagement of the detachment prevention plate 227b. At this time, the separation preventing plate 227b is detached from the fermentation tank 221 and the tank partition wall portion 223 by bolts and nuts.

The agitator 230 is installed in the waste aging tank 210 and the waste fermentation tank 220, respectively, and agitates the food waste to be aged or fermented. Such an agitator 230 according to the present embodiment will be described with reference to Figs. 10, 11, and 13 to 16. Fig.

FIG. 13 is a perspective view illustrating an agitator according to an embodiment of the present invention, FIG. 14 is a perspective view illustrating a stirring unit according to an embodiment of the present invention, FIG. And FIG. 16 is an assembled cross-sectional view of FIG. 15. FIG.

As shown in FIGS. 10, 11, and 13 to 16, the stirrer 230 includes a rotation shaft 240 rotatably installed in a waste aging tank 210 and a waste fermentation tank 220, An agitation unit 250 for agitating the food waste, and a driving unit 125 for driving the rotation shaft 240. The rotary shaft 240 of the stirrer 230 is rotatably coupled to the installation hole of the waste aging tank 210 and the installation hole 227a of the waste fermentation tank 220 through a bearing.

The stirrer 230 is easily installed in the aging tank 211 and the fermentation tank 221 partitioned into a plurality of spaces by the tank dividing section 213 and the tank partition wall section 223, The stirring unit 250 is installed so as to be spaced apart from the rotating shaft 240. [ Thus, the agitator 230 can keep the level of the garbage being aged and fermented in the garbage fermentation tank 220 constant.

In the stirrer 230 according to the present embodiment, the rotating shaft 240 can rotate three to five times per minute.

The agitation unit 250 is spaced apart from the inner bottom surface of the fermentation tank 221 and the aging tank 211 and the fermentation tank 221 The food waste to be treated is stirred to keep the level of the food waste constant.

The stirring unit 250 includes a shaft coupling part 251 coupled to the rotation shaft 240 and a stirring member 253 coupled to the shaft coupling part 251 at equal intervals to be horizontal with the rotation shaft 240 . At this time, the stirring members 253 are arranged at regular intervals along the circumferential direction of the rotating shaft 240.

The shaft coupling portion 251 includes a rim member 251a coupled to the rotary shaft 240, a support rod member 251b vertically coupled to the rim member, and a support rod member 251b for contacting the stirring member 253. [ And a ring member 251c coupled to the ring member 251c. The shaft coupling portion 251 is configured such that the rim member 251a and the rotary shaft 240 are detached by the rim fixing member 255 so as to facilitate installation and maintenance work on the rotary shaft 240, 251a and the support bar member 251b are detached by the support bar fastening member 257. [

The rim fixing member 255 has a fastening hole 255a formed in the rim member 251a so as to easily adjust the engaging position of the rim member 251a in the rotary shaft 240 as well as to facilitate the fastening, And a bolt member 255b fastened to the fastening hole 255a and brought into close contact with the rotating shaft 240. The rim fixing member 255 is provided with a plurality of flow prevention grooves 252a spaced apart from the outer surface of the rotary shaft 240 so that the flow of the rim member 251a coupled to the rotary shaft 240 by the bolt member 255b is completely prevented, (255c).

The position of the rim member 251a coupled to the rotating shaft 240 through the rim fixing member 255 can be easily adjusted according to the length of the stirring member 253, It is possible to prevent the first electrode 251a from flowing.

The support shaft fastening member 257 includes a female screw portion 257a formed on the rim member 251a and a male screw portion 257b formed on the support rod member 251b to be engaged with the female screw portion 257a. By using such a support bar fastening member 257, the support bar member 251b can be easily installed on the rim member 251a.

Meanwhile, as the food waste is fermented, the humid air of high temperature and humidity generated in the fermentation tank 220 according to the present embodiment is forcibly sucked into the fermentation air circulation device 300, processed, and then introduced again. Therefore, since the internal air generated by the fermentation of the food waste is forcibly sucked into the fermentation air circulation device 300, the waste fermentation tank 220 according to the present embodiment is prevented from being discharged to the outside, Can be minimized. As a result, the occurrence of odor can be remarkably reduced.

In addition, since the dry air heated by the fermentation air circulating device 300 flows into the waste fermentation tank 220, the fermentation temperature and humidity of the interior of the waste fermentation tank 220 can be kept constant, thereby further improving the fermentation effect of the food waste.

The fermentation air circulating apparatus 300 according to the present embodiment sucks air by sucking air from the discharge port 221b side of the waste fermentation tank 220 to dehumidify it and then supplies the dehumidified air to the charging port 221a side of the waste fermentation tank 220. This will be described in detail with reference to FIG. 17 to FIG.

18 is a perspective view illustrating a fermented air circulating apparatus according to an embodiment of the present invention. FIG. 19 is a cross-sectional view of a fermented air circulating apparatus according to an embodiment of the present invention. Fig.

FIG. 20 is an exploded perspective view illustrating a heat exchange and dehumidifier according to an embodiment of the present invention, FIG. 21 is an assembled cross-sectional view of FIG. 20 showing a heat exchange and dehumidifier according to an embodiment of the present invention, FIG. 23 is an assembled cross-sectional view of FIG. 22 showing a dry air cooler according to an embodiment of the present invention, and FIG. 24 is a cross-sectional view illustrating a dry air cooler according to an embodiment of the present invention. And an air flow chart for explaining the air flow of the waste disposal facility.

17 to 24, the fermentation air circulation apparatus 300 according to the present embodiment includes a heat exchange and dehumidifier 300a for absorbing humid air, which is the internal air of the waste fermentation tank 220, to remove moisture, And a drying air cooler 300b for cooling the dry air discharged from the heat exchange and dehumidifier 300a and supplying the cooled air to the heat exchange and dehumidifier 300a.

The fermented air circulating device 300 exchanges the humid air generated in the waste fermentation tank 220 and the cooling air cooled in the dry air cooler 300b with the heat exchanger dehumidifier 300a to generate humid air . The fermentation air circulating apparatus 300 heats the cooling air cooled in the drying air cooler 300b through the heat exchange dehumidifier 300a through heat exchange with humid air and supplies the heated cooling air to the waste fermentation tank 220. [ Therefore, the inside air of the waste fermentation tank 220 maintains proper temperature and humidity.

The heat exchange and dehumidifier 300a heats the humid air of the waste fermentation tank 220 and the cooling air of the dry air cooler 300b to dehumidify the humid air and simultaneously heats the cooling air.

For this, the heat exchange and dehumidifier 300a according to the present embodiment includes a housing 310 in which humid air and cooling air circulate through respective flow paths, moist air introduced into the housing 310, and cooling air And a heat exchanging part 320 for exchanging heat with the heat exchanging part 320. At this time, the heat exchange and dehumidifier 300a is constructed such that the heat exchanger 320 is disposed inside the housing 310 and humid air sucked into the housing 310 is transferred between the housing 310 and the heat exchanger 320, Is transferred to the inside of the heat exchanging part (320).

The heat exchange and dehumidifier 300a includes an air forced circulation unit 330 for forcedly sucking the air from the waste fermentation tank 220 and circulating the fermented air circulation apparatus 300, And an oxygen generator 340 for supplying oxygen to the circulating air.

The housing 310 includes a humid air inlet 311, a dry air outlet 313, a cooling air inlet 315 and a heated air outlet 317. The housing 310 further includes a drain valve 319 for storing condensed water generated in the heat exchanging unit 320 by heat exchange between humid air and cooling air, and discharging the stored condensed water to the outside. At this time, the housing 310 is formed to be inclined toward the drain valve 319 when the stored condensed water is smoothly guided to the drain valve 319 side.

The humid air inlet 311 is humidified by forced air sucked in the waste fermentation tank 220 through the air forced circulation unit 330. At this time, the forced air circulation unit 330 is connected to the humid air inlet 311 and the waste fermentation tank 220 by piping. The forced air circulation unit 330 forcibly blows the humid air in the waste fermentation tank 220 to the housing 310 through the humid air inlet 311.

The humid air forcedly inhaled into the housing 310 through the humid air inlet 311 is maintained in a high temperature and high humidity condition due to heat and moisture generated when the food garbage is fermented.

The dry air outlet 313 is connected to the dry air cooler 300b through a pipe so that the dry air dehumidified through the heat exchanger 320 is transferred to the dry air cooler 300b.

The cooling air inlet 315 is connected to the dry air cooler 300b through a pipe to allow the cooling air cooled in the dry air cooler 300b to flow into the interior of the housing 310. [

The heated air outlet 317 is connected to the waste fermentation tank 220 through a pipe so that heated air heated while passing through the heat exchange unit 320 is supplied to the waste fermentation tank 220.

The housing 310 according to this embodiment exchanges the humid air introduced through the humid air inlet 311 with the cooling air conveyed to the heat exchanger 320 while being transferred to the inside of the housing 310. As a result, moisture contained in moist air condenses. The hot dry air discharged through the dry air outlet 313 is air-cooled in the dry air cooler 300b and flows into the cooling air inlet 315 of the housing 310.

The humid air of the hot and humid refuse tank 220 is sucked into the housing 310 and transferred to the heat exchanger 320 to exchange heat with the cooling air to remove moisture. That is, the humid air discharged from the waste fermentation tank 220 is dehumidified and the cooling air transferred to the inside of the heat exchange unit 320 is heated and supplied to the waste fermentation tank 220. Thus, the internal temperature of the waste fermentation tank 220 is kept constant.

The heat exchanging part 320 is provided inside the housing 310 to transfer humid air and cooling air through the respective flow paths. The heat exchanging unit 320 exchanges heat between the humid air introduced into the housing 310 through the humid air inlet 311 and the dry air introduced into the housing 310 through the cooling air inlet 315, At the same time, the drying air is heated.

To this end, the heat exchange unit 320 according to the present embodiment includes a heat exchange member 321 for exchanging heat between the humid air and the cooling air, and a heat exchange expansion unit 323 for improving the heat exchange efficiency of the humid air and the cooling air .

The heat exchange member 321 is installed inside the housing 310 through the heat exchange expansion unit 323 and also performs heat exchange between the humid air and the cooling air to heat the humid air flowing into the housing 310 do. The heat exchange member 321 has a heat exchange pipe 321a in which both ends thereof are welded to the heat exchange expansion portion 323 and an air induction plate 321b for dividing the inner space of the housing 310, ).

The heat exchange pipe 321a is vertically and horizontally arranged in the interior of the housing 310 so as to be uniformly transferred to all the heat exchange pipes 321a while the flow of the cooling air flowing into the heat exchange expansion unit 323 is reduced. As a result, the heat exchange efficiency between the humid air and the cooling air by the heat exchange pipe 321a is remarkably improved.

In addition, the air induction plate 321b is coupled to the heat exchange expansion part 323 so that the humid air introduced into the housing 310 is positioned between the heat exchange pipes 321a so as to be longer than the outside of the heat exchange pipe 321a The inner space of the housing 310 is divided. Accordingly, the humid air introduced into the housing 310 through the air forced circulation unit 330 is discharged into the dry air outlet 313 while being transferred in the zigzag form from the housing 310. This further improves the heat exchange efficiency between the humid air and the cooling air by the heat exchange pipe 321a.

The heat exchange expanding section 323 is formed at both ends of the housing 310 so that the humid air is transferred to the outside of the heat exchange pipe 321a and the cooling air is transferred into the heat exchange pipe 321a. The heat exchange expanding section 323 is connected to the cooling air inlet 315 so that one of the heat exchange expanding sections 323 is connected to the waste fermentation tank 220 and the drying air circulator 300b, And the portion 323 is communicated with the heated air outlet 317.

To this end, the heat exchange expansion unit 323 according to the present embodiment includes a partition member 323a that is joined to both ends of the heat exchange pipe 321a and divides an internal space of the housing 310, And a cooling air split / supply unit 323b formed at one end side of the heat exchange pipe 321a so as to be smoothly transferred to the heat exchange pipe 321a. The heat exchange expansion unit 323 further includes a heated air merging unit 323c formed on the other end side of the heat exchange pipe 321a so that heated air heated by the heat exchange pipe 321a is merged.

The partition member 323a is joined to inner surfaces of both ends of the housing 310 to divide the inside of the housing 310 so that humid air and cooling air are transferred to the respective compartmented spaces inside the housing 310. [

The cooling air split supply portion 323b is communicated with the cooling air inlet 315 and is separated by the partition member 323a so that the cooling air is smoothly supplied simultaneously through the plurality of cooling air transfer paths formed by the heat exchange pipe 321a .

The heat exchange expansion unit 323 according to the present embodiment further includes a cooling air split supply unit 323b and a heating air supply unit 323b for supplying more oxygen to the waste fermentation tank 220 through the heated air supplied to the waste fermentation tank 220, And the oxygen generating unit 340 is provided in the merging unit 323c.

Meanwhile, a blower may be used as the forced air circulation unit 330 according to the present embodiment.

The dry air cooler 300b according to this embodiment removes moisture through heat exchange between the humid air and the cooling air to cool the dry air discharged to the dry air outlet 313 of the housing 310. [ At this time, the dry air discharged to the dry air discharge port 313 of the housing 310 is cooled by air cooling in the dry air cooler 300b, and then supplied to the heat exchanging unit 320 to serve as a coolant for dehumidifying the humid air .

The dry air cooler 300b includes a case 350 connected to the dry air outlet 313 of the housing 310 through a pipe, And an air cooling unit 360 for cooling the air.

The case 350 has a dry air inlet 351 connected to the dry air outlet 313 at one end and a cooling air outlet 353 connected to the cooling air inlet 315 of the housing 310 at the other end. . In addition, the dry air introduced into the case 350 is air-cooled by the air cooling unit 360.

The air cooling unit 360 includes a cooling heat exchange member 361 for transferring dry air and a heat exchange medium supply member 363 for air cooling the dry air conveyed to the cooling heat exchange member 361. The air cooling unit 360 cools the dry air conveyed to the cooling heat exchange member 361 by using a heat exchange medium sucked into the case 350 by the heat exchange medium supply member 363.

The cooling heat exchange member 361 has a cooling pipe 361a through which dry air is conveyed to the inside and a pipe fixing plate 361b for fixing the cooling pipe 361a inside the case 350. [ At this time, the cooling pipe 361a of the cooling heat exchange member 361 is provided with a plurality of pipes vertically and horizontally continuously on the pipe fixing plate 361b to improve the heat exchange effect with the heat exchange medium.

The pipe fixing plate 361b is joined to the inner surfaces of both ends of the case 350 so that the dry air partitioning space 355 and the cooling air merging space 357 are formed at one end and the other end of the case 350, respectively.

The dry air partition space 355 formed by the pipe fixing plate 361b simultaneously conveys the dry air introduced into the case 350 through the dry air inflow port 351 to all the cooling pipes 361a. As a result, the heat exchanging area and time between the dry air conveying the inside of the cooling pipe 361a and the heat exchange medium conveyed to the outside of the cooling pipe 361a are increased and the dry air is more effectively cooled.

In addition, the cooling air merging space portion 357 formed by the pipe fixing plate 361b communicates with the cooling air outlet 353 of the case 350, so that the cooling air discharged from the cooling pipe 361a stays.

That is to say, the pipe fixing plate 361b is disposed inside the case 350 so that the dry air introduced into the case 350 and the heat exchange medium can be transferred to the cooling heat exchange member 361 and the heat exchange medium supply member 363, respectively It divides.

The heat exchange medium supply member 363 includes a blowing fan 363a for sucking outside air as a heat exchanging medium into the case 350 and a heat exchange medium sucked by the blowing fan 363a to be in contact with the cooling pipe 361a And an airflow passage 363b formed in the case 350. [

A plurality of blowing fans 363a are provided so as to be spaced apart from the case 350. Specifically, three blowing fans 363a are provided on the upper surface of the case 350 at regular intervals.

The dry air cooler 300b according to the present embodiment includes a dry air division space 355 and a cooling air merging space 357 so that a larger amount of oxygen can be contained in the cooling air supplied to the heat exchange and dehumidifier 300a. And an oxygen generating part 340 is provided in the interior of the fuel cell.

In addition, the fermentation air circulation apparatus 300 according to the present embodiment further includes a temperature sensor (not shown) for sensing the internal temperature of the waste fermentation tank 220. When the internal temperature of the waste fermentation tank 220 is lower than the set temperature through the control of the control unit (not shown), the fermentation air circulation apparatus 300 reduces the supply of heated air to raise the internal temperature of the waste fermentation tank 220 , And if the internal temperature of the refuse collection tank 220 exceeds the set temperature, the supply of the heated air is increased to lower the internal temperature of the refuse collection tank 220.

In this embodiment, three waste fermentation tanks 220 are provided. However, the number of waste fermentation tanks 220 may be two or four or more depending on the needs of the user. The fermentation, disintegration and drying treatment are successively carried out to treat the food waste. The fermentation, decomposition and drying process of the waste fermentation tank 220 can be variously adjusted according to the needs of the user.

For example, when there are three waste fermentation tanks 220, food waste is fermented in the first waste fermentation tank 220, food waste is decomposed in the second waste fermentation tank 220, The food waste is dried.

When the waste fermentation tank 220 is six, the food waste is fermented in the first and second waste fermentation tanks 220, the food waste is decomposed in the third and fourth trash fermentation tanks 220, The sixth garbage fermenter 220 can dry the food garbage.

At this time, the volume of the garbage fermentation tank 220, which is installed in a plurality of ways, is reduced as the volume of the garbage is fermented, decomposed, and dried.

The operation of the food garbage disposal apparatus according to an embodiment of the present invention will now be described.

The food waste put into the rotary drum 121 through the hopper 111 of the main body 110 is cut by the cutting blade 123a while being transferred from the rotary drum 121 through the rotation of the rotary drum 121 . At this time, the food waste that is cut smaller than the waste discharge hole 121a is released to the waste transfer section 115 through the waste discharge hole 121a.

The food waste dropped to the waste transfer unit 115 is transferred to the first conveyor 140 and then transferred to the waste storage unit 160 through the first conveyor 140 and stored.

Particularly, since the slope of the main body 110 is adjusted according to the type and amount of the food waste put into the rotary drum 121, the foreign matter processing speed of the food waste can be variously adjusted. For example, if the amount of food waste introduced into the rotary drum 121 is large, the inclination of the main body 110 may be increased to increase the amount of food waste to be treated by increasing the feeding speed of the food waste, The amount of food waste to be treated can be reduced by lowering the inclination of the main body 110 and reducing the feeding speed of the food waste.

Thereafter, the food wastes which are removed from the foreign materials and put into the waste aging tank 210 are aged for 10 to 13 days while being stirred by the agitation unit 250 after the microorganisms for fermentation are introduced. At this time, the agitation unit 250 stirs aged food waste while rotating 3 to 5 times per minute.

The food waste aged in the waste aging tank 210 is filled up to the discharge port 211b and is dropped into the waste fermentation tank 220 through the discharge port 211b and put into the waste fermentation tank 220 for fermentation for 10 to 15 days.

The garbage fermentation tank 220 is fermented while being stirred by the stirrer 230. When the food waste charged into the first fermentation space 220a is filled up to the penetration portion 213a of the tank partition wall portion 223, the waste fermentation tank 220 passes through the penetration portion 213a and flows into the second fermentation space 220b ) And fermented. The food waste to be filled while being fermented in the second fermentation space 220b is moved to the third fermentation space 220c through the penetration portion 213a of the tank partition wall portion 223.

As the fermentation time has elapsed from the first fermentation space 220a to the third fermentation space 220c through the second fermentation space 220b, the food waste introduced into the refuse-fermentation tank 220 is gradually transferred to the fermentation process do.

 The food waste fermented in any one of the waste fermentation tanks 220 is moved to another neighboring waste fermentation tank 220 and continuously fermented.

In addition, the stirrer 230 is gradually moved in the waste fermentation tank 220 to stir the food waste to be fermented so that the fermentation can proceed smoothly, and at the same time, the surface height of the food waste is kept constant. Therefore, the fermentation effect of the food waste fermented in the refuse-fermenting tank 220 can be further improved.

The humid air of high temperature and high humidity generated due to the fermentation of food waste in the refuse collection tank 220 flows into the housing 310 of the heat exchange and dehumidifier 300a by the air forced circulation unit 330, And then discharged to the dry air discharge port 313. [0050] At this time, the humid air stays in the housing 310 for a longer time by the air induction plate 321b, so that the heat exchange by the heat exchange pipe 321a is further improved.

The high temperature dry air from which the moisture is removed from the heat exchanging unit 320 is supplied to the dry air cooler 300b through the dry air outlet 313 and is cooled and then supplied to the heat exchange and dehumidifier 300a for condensation of humid air It is used as a refrigerant.

The hot dry air flowing into the dry air cooler 300b is transferred through the cooling pipe 361a of the cooling heat exchange member 361 and is heat exchanged with the low temperature air flowing into the case 350 by the blowing fan 363a And cooled.

The cooling air cooled in the drying air cooler 300b is supplied to the heat exchange and dehumidifier 300a and is transferred through the inside of the heat exchange pipe 321a to heat-exchange the high temperature and high humidity humid air transferred to the housing 310. As a result, the moisture contained in the moist air condenses and is collected inside the housing 310. The condensed water collected in the housing 310 is selectively discharged through the opening and closing of the drain valve 319.

Thereafter, the heating air, which is heat-exchanged with the humid air while transferring the inside of the heat exchange pipe 321a, is put back into the waste fermentation tank 220 through the heated air outlet 317. [ Accordingly, the internal temperature and humidity of the waste fermentation tank 220 can be appropriately maintained. That is, since the internal temperature of the waste fermentation tank 220 is maintained at 54 to 56 degrees, the fermentation effect of the food waste can be improved, and the food waste can be gradually dried.

Further, since a large amount of oxygen is supplied by the oxygen generating unit 340 while the air in the waste fermentation tank 220 circulates through the heat exchange dehumidifier 300a and the dry air cooler 300b, the fermentation effect of the food waste is further improved .

In addition, since the air generated in the fermentation process of the food waste is introduced into the waste fermentation tank 220 through the heat exchange dehumidifier 300a and the dry air cooler 300b, the odor generated in the fermentation process of the food waste is diffused to the outside Can be minimized. That is, the generation of odor can be remarkably reduced.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand.

Accordingly, the true scope of protection of the present invention should be defined by the claims.

100: Trash foreign matter remover 110: Body
120: Foreign matter separator 130: Tilt regulator
140: first conveyor 160: waste storage tank
200: Waste fermentation fermenter 210: Waste aging tank
211: aging tank 213: tank division
211c: inner air outlet 211d: dehumidifying air inlet
220: waste refining tank 221: fermentation tank
220a: first fermentation space 220b: second fermentation space
220c: a third fermentation space 223: a tank support
227: Desorption installation part 227a: Installation installation
227b: separation preventing plate 230: stirrer
240: rotation shaft 250: stirring unit
251: shaft coupling portion 251a: rim member
251b: support rod member 251c: ring member
253: stirring member 255: rim fixing member
255a: fastening hole 255b: bolt member
255c: a flow preventing groove portion 257:
257a: Female thread portion 257b: Male thread portion

Claims (9)

A garbage fermentation tank into which food waste is charged and fermented; A rotating shaft rotatably installed in the waste fermentation tank; And a stirring unit coupled to the rotating shaft so as to be spaced apart from the inner bottom surface of the waste fermentation tank and stirring the food waste fermented in the waste fermenter while rotating together with the rotating shaft to keep the level of the food waste constant, The stirring unit may include: an axial coupling portion coupled to the rotation shaft; And an agitating member which is equally spaced from the shaft engaging portion so as to be parallel to the rotation axis,
Wherein the shaft coupling portion includes: a rim member coupled to the rotation shaft; A support rod member vertically coupled to the rim member; A ring member joined to the support rod member and to which the stirring member is joined; A rim fixing member for selectively fixing the rim member to the rotation shaft so as to adjust a coupling position of the rim member on the rotation shaft; And a support bar fastening member for detaching the rim member from the support rod member,
The rim fixing member
A fastening hole formed in the rim member;
A bolt member fastened through the fastening hole and closely attached to the rotary shaft; And
A flow preventing groove portion formed on an outer surface of the rotating shaft to prevent the flow of the rim member by inserting the bolt member;
Wherein the food garbage disposal apparatus comprises: The method according to claim 1,
The waste fermentation tank has two or more fermentation spaces,
Wherein the stirring unit is provided so that the stirring unit is spaced apart from the rotating shaft so as to be respectively positioned in the plurality of fermentation spaces. delete The method according to claim 1,
Wherein the plurality of stirring members have different lengths and are formed in a circular shape so as to reduce a frictional force with the food wastes. delete delete delete delete 2. The apparatus according to claim 1, wherein the support-
A female screw portion formed on the rim member; And
A male screw portion formed on the support bar member to be coupled to the female screw portion;
Wherein the food garbage disposal apparatus comprises:

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