KR102683582B1 - Food waste disposal system - Google Patents

Abstract

The present invention relates to a food waste processor for separating and processing solids and moisture from food waste, and specifically, a stirring liquefaction device that liquefies input food into sludge form while stirring it with a microbial immersion carrier; A dehydration separation device that separates and dehydrates solids and desorbed liquid through gravity sedimentation and pressurization while vertically transporting the liquefied food waste flowing from the stirring liquefaction device; A drying device that dries the solids flowing from the dehydration and separation device by stirring and heating; and a water purification device that stores and precipitates the desorbed liquid flowing from the dehydration separation device and discharges the purified water into an overflow pipe.

Description

Discharge formula fermentation drying weight loss food waste disposal system {Food waste disposal system}

The present invention relates to a food waste processor for separating and processing solids and moisture from food waste.

In Republic of Korea Patent No. 1911524 (October 24, 2018), a 'food waste disposal system' is invented, and the invention includes 'a sorter for sorting out various foreign substances from discarded food waste; A shredder that crushes selected food waste; A first dehydrator that dehydrates the pulverized food waste to a moisture content of 75% and separates it into solids and desorbed liquid; A desorbed liquid storage tank in which the desorbed liquid containing moisture, oil, residue, salt, and odor is transferred through a transfer pipe while being separated by the first dehydrator; An oil-water separator that transfers the desorbed liquid from the desorbed liquid storage tank to separate the oil content by centrifugal separation; a second dehydrator that introduces the desorbed liquid from which the oil has been removed and separates the solid residue and the desorbed liquid containing moisture, salt, and odor through dehydration; The solids discharged from the first dehydrator and the residue discharged from the second dehydrator are transported through a rotary drying chamber that rotates while passing horizontally through the dryer firebox, thereby removing odor, steam, and dry gas along with semi-dry solids with a moisture content of 30 to 40%. a dryer that discharges; An oxygen-free carbonizer that allows the semi-dry solids discharged from the dryer to pass horizontally through the carbonizer firebox and be transferred through a rotating rotary carbonization chamber so that dry distillation gas is discharged together with the carbide; And a power generation turbine disposed on a line connecting the dryer and the anaerobic carbonizer, converting the desorbed liquid into dry saturated steam and using it for power generation through the power generation turbine, while drying by the dryer, and The entire amount of steam, odor, and carbonized gas generated during carbonization by the oxygen-free carbonizer is collected and passed through the carbonized gas pipe installed in the carbonizer firebox of the oxygen-free carbonizer, and the generated combustion heat and dry carbonized gas in a gaseous state are converted into gaseous gas. It consists of ‘using it as a heat source’.

This invention allows the solid content of discarded food waste to be converted into fuel while the remaining desorbed liquid is converted into steam to generate electricity.

The present invention is to liquefy food waste in the form of sludge by stirring it with a microbial carrier, separate the liquefied food waste into solid content and desorbed liquid, dry the separated solid content, and treat the desorbed liquid with water before discharging it into sewage.

The present invention is intended to separate and dehydrate solids using a gravity sedimentation and pressure type dehydration device.

The present invention is intended to treat a portion of the treated water by circulating it as mixed water or washing water in the process of treating the desorbed liquid and recirculating the sediment.

The present invention includes a stirring liquefaction device that liquefies input food into sludge form while stirring it with a microbial immersion carrier; A dehydration separation device that separates and dehydrates solids and desorbed liquid through gravity sedimentation and pressurization while vertically transporting the liquefied food waste flowing from the stirring liquefaction device; A drying device that dries the solids flowing in from the dehydration and separation device by stirring and heating; and a water purification device that stores and precipitates the desorbed liquid flowing from the dehydration separation device and discharges the purified water into an overflow pipe.

When food waste is input through the input port, the stirring liquefaction device measures the input amount by comparing the weight before input and the weight after input, supplies mixed water according to the measured input amount of food waste, and maintains a constant constant through the outlet with a perforated network. It is formed to discharge solids of smaller size together with the liquid.

The dehydration separation device has an inlet formed on one side of the lower part to vertically transport food waste, the upper surface is penetrated, and is formed at a certain height to allow moisture to gravity settle from the transported food waste, and the gravity-settled moisture is discharged to the outside. An inner cylinder with as many holes formed on the side as possible; an outer cylinder that covers the inner cylinder and has a drain hole formed on one lower side to receive moisture flowing to the outside through the perforation and discharge it to the water purification device; a housing installed on an upper side of the inner cylinder to store a certain amount of discharged food waste, and having an outlet on one side to discharge the stored food waste to the drying device; A shaft is installed to vertically penetrate the inner cylinder and the housing, a screw for transporting food waste is formed on the outer surface corresponding to the inner cylinder, and a wing for pushing food waste to the outlet is formed on the outer surface corresponding to the housing. formed shaft; an elastic valve installed between the inner cylinder and the housing and configured to discharge food waste transported by the shaft while pressing it at a constant pressure; and a washing nozzle installed on a side of the outer cylinder and configured to spray washing water toward the inner cylinder.

A first three-way valve for supplying the liquid discharged from the dehydration separation device to the water purification device and supplying some of the supplied desorption liquid to the washing water of the dehydration separation device or to the mixed water of the stirring liquefaction device. It is configured to include a supply device equipped with two three-way valves and a third three-way valve for mixing and recirculating the fine solids settled at the bottom of the water purification device with the liquid discharged from the dehydration separation device.

The dehydration and separation device is configured to include an auxiliary purified water tank that stores and precipitates the discharged liquid, supplies the stored lower layer water to the water purification device, and discharges the upper layer water through an overflow pipe of the water purification device.

According to the present invention, by reducing the solid content in treated water discharged into sewage, clogging or contamination of sewers is prevented, and the moisture content in the separated solids is reduced, thereby making food waste disposal more environmentally friendly and convenient.

According to the present invention, the water content in the solid content can be more easily reduced by separating and dehydrating the solid content using a gravity sedimentation and pressurized dehydration device.

According to the present invention, in the process of treating the desorbed liquid in a water treatment unit, some of the treated water is circulated as mixed water or washing water and the sediment is recirculated and treated, thereby reducing the amount of water used and improving the efficiency of water treatment.

1 is an explanatory diagram showing the overall configuration and structure of the present invention.
2 to 4 are schematic diagrams showing the dehydration and separation device of the present invention.

A preferred embodiment of the present invention will be examined in detail based on the attached drawings.

As shown in FIG. 1, the discharge type fermentation drying weight loss food waste processor of the present invention includes a stirring liquefaction device 100 that liquefies the input food into sludge form while stirring it with a microbial immersion carrier; A dehydration separation device (200) that vertically transports the liquefied food waste flowing in from the stirring liquefaction device and separates and dehydrates the solid content and the desorbed liquid through gravity sedimentation and pressurization; A drying device 300 that dries the solids flowing from the dehydration separation device by stirring and heating; and a water purification device 400 that stores and precipitates the desorbed liquid flowing from the dehydration separation device and discharges the purified water to the overflow pipe 410.

As shown in FIG. 1, the stirring liquefaction device 100 is configured to liquefy the input food in the form of sludge while stirring it with the microbial immersion carrier. That is, the stirring liquefaction device 100 is an embodiment in which, as shown in the drawing, a stirring wing is installed at the center of a stirring tank for stirring food waste, and an outlet 110 that can be opened and closed is provided at the bottom of the stirring tank. It is formed, and a pipe for supplying mixed water is connected to the upper part of the stirring tank. Therefore, a certain amount of microbial immersion carrier that decomposes food waste is stored inside the stirring liquefaction device 100, and when food waste is input, mixed water is supplied in proportion to the amount of food waste input, and then the stirring blade rotates, thereby dissolving the food waste. It is liquefied by stirring with the carrier and mixing water.

As an example of an embodiment, the stirring liquefaction device 100 measures the input amount by comparing the weight before input and the weight after input when food waste is input through the inlet, and supplies mixed water according to the measured input amount of food waste, while providing a perforated network. It is formed to discharge solids of a certain size or less along with the liquid through this formed discharge port. In particular, by allowing only solids of a certain size or less to be discharged through the outlet 110 in which the perforated network is formed, it is possible to reduce the proportion of solids in the liquefied food waste that is subsequently processed. At this time, the solid content can be reduced to less than 20%, for example, as required by the Ministry of Environment. Meanwhile, the stirred liquefaction device 100 is configured to include a weight sensor for comparing and measuring the input amount.

As shown in FIG. 1, the dehydration and separation device 200 is formed to separate and dehydrate the solid content and the desorbed liquid through gravity sedimentation and pressurization while vertically transporting the liquefied food waste flowing in from the stirring liquefaction device 100. In other words, in the process of vertically transporting liquefied food waste, the solid content is transferred upward and compressed, and the desorbed liquid naturally flows down and separates.

As an example of the dehydration and separation device 200, as shown in FIGS. 2 to 4, an inlet 211 is formed on one side of the lower part to vertically transport food waste, the upper surface is penetrated, and the food waste is transported. An inner cylinder (210) formed at a certain height to allow moisture to settle by gravity and having a plurality of holes formed on the side to discharge the gravity-settling moisture to the outside, covers the inner cylinder, and receives moisture flowing to the outside through the holes. An external cylinder 220 with a drain 221 formed on one lower side to be discharged to the water purification device, installed on the upper side of the inner cylinder to store a certain amount of food waste to be discharged, and one side to discharge the stored food waste to the drying device. A housing 230 formed with an outlet 231, a shaft installed vertically penetrating the inner cylinder and the housing, and a screw 241 for transporting food waste is formed on an outer surface corresponding to the inner cylinder, and the housing and A shaft 240 having wings 242 formed on the corresponding outer surface for pushing food waste to the discharge port, installed between the inner cylinder and the housing, and discharging the food waste 250 transported by the shaft by pressing it at a constant pressure. It is configured to include a formed elastic valve 250 and a washing nozzle 260 installed on the side of the outer cylinder and configured to spray washing water toward the inner cylinder. Therefore, the liquefied food waste is transferred from the lower part of the inner cylinder 210 to the upper part by driving the shaft 240, and in this process, the solid content is transferred to the upper part of the shaft 240 and is compressed by the elastic valve 250. , the desorbed liquid is discharged to the external cylinder through a hole in the inner cylinder 210, and in the process of the solids being compressed by the elastic valve 250, the desorbed liquid contained therein is further separated and dehydrated.

As shown in FIG. 3, the cleaning nozzle 260 of the dehydration separator 200 is formed to spray at a position horizontally moved to one side from the center of the inner cylinder 210, while spraying at the top and bottom of the outer cylinder 220. It is installed.

Meanwhile, as shown in FIG. 2, the dehydration separation device 200 is installed axially via a stainless steel ball 270 while spaced apart from the shaft 240 and the lower end of the inner cylinder 210 at a certain interval, and the shaft ( A first groove 243 is formed at the bottom of the inner cylinder 240 to accommodate the upper part of the stainless steel ball 270, and a second groove 212 is formed at the lower end of the inner cylinder 210 to accommodate the lower part of the stainless steel ball 600. This is formed. At this time, the first groove 243 or the second groove 212 is formed so that the stainless steel ball 270 can move within a certain range, thereby enabling the shaft 240 to flow. Accordingly, the lower end of the shaft 240 flows within a certain radius from the lower end of the inner cylinder 210, thereby enabling fine movement of the axis when the shaft 240 rotates.

As shown in FIG. 1, the drying device 300 is formed to dry the solid content flowing in from the dehydration and separation device 200 by stirring and heating. As an example of the drying device 300, as shown in the drawing, a stirring wing is installed at the center of a stirring tank for stirring solid content, and a heating wire is installed in the stirring tank or a stirring wing is installed while supplying hot air into the stirring tank. It rotates to remove and dry the moisture contained in the added solids. At this time, the moisture evaporating from the drying device 300 is circulated to the cooling device, condensed, and then discharged through the overflow pipe 410 of the water purification device 400, which will be described later. According to this drying device 300, for example, it is possible to reduce the moisture content from the dehydrated solid content to 40%.

As shown in FIG. 1, the water purification device 400 is configured to store and precipitate the desorbed liquid flowing from the dehydration and separation device 200 while discharging the purified water into the overflow pipe 410. As an example, the water purification device 400 is divided into a storage space for reducing the flow rate of the desorbed liquid inside a tank of a certain size as shown in the drawing, and a settling space for settling sludge (fine solids) from the desorbed liquid, and the storage space The desorbed liquid flows in through the lower part of the sedimentation space, and the purified water is discharged through the overflow pipe 410 formed in the upper part of the sedimentation space. In the storage space, a partition wall to form a storage space is formed in the vertical direction, and the bottom of the sedimentation space An outlet is formed to discharge the settled sludge.

As an embodiment of the present invention, a first three-way valve ( 520) or a second three-way valve 510 for supplying mixed water to the stirring liquefaction device, while mixing the fine solids precipitated at the bottom of the water purification device with the liquid discharged from the dehydration and separation device for recirculation. A supply device 500 equipped with a third three-way valve 530 is configured. In other words, the supply device 500 forcibly supplies the desorbed liquid (including fine solids) to the water purification device 400, but switches or branches the flow of the supplied desorbed liquid to the stirring liquefaction device 100 or the dehydration separation device 200. First and second three-way valves 520 and 510 for circulation and a third three-way valve 530 for circulating fine solids (sludge) accumulated in the settling space of the water purification device 400 back to the storage space are provided. Therefore, since the desorbed liquid is used as mixing water in the stirring liquefaction device 100 or as washing water in the dehydration and separation device 200 by this feeding device 500, there is no need to use tap water, and recirculation of the settled sludge Through this, the efficiency of purification can be increased.

As an embodiment of the present invention, as shown in FIG. 1, the dehydration and separation device 200 stores and precipitates the discharged liquid, supplies the stored lower layer water to the water purification device 400, and supplies the upper layer water to the water purification device. It is configured to include an auxiliary purified water tank 280 that is discharged through the overflow pipe 410 of (400). At this time, the Bozer purified water tank 280 forms a control valve for opening and closing the discharge of upper layer water, thereby measuring the content of fine solids contained in the desorbed liquid and selectively discharging it.

According to this configuration, the solid content in the treated water discharged as sewage is reduced to prevent sewer clogging or contamination, and the moisture content in the separated solids is reduced, making food waste disposal more environmentally friendly and convenient.

In addition, the moisture content in the solid content can be more easily reduced by separating and dehydrating the solid content using a gravity sedimentation and pressurized dehydration device.

In addition, in the process of treating the desorbed liquid through a water treatment unit, some of the treated water is circulated as mixed water or washing water and the sediment is recirculated and treated, thereby reducing the amount of water used and improving the efficiency of water treatment.

100: Stirring liquefaction device
200: Dehydration separation device
300: Drying device
400: Purification device
500: Feeding device

Claims (5)

A stirring liquefaction device that liquefies the input food waste into sludge while stirring it with a microbial immersion carrier;
A dehydration separation device that separates and dehydrates solids and desorbed liquid through gravity sedimentation and pressurization while vertically transporting the liquefied food waste flowing in from the stirring liquefaction device;
A drying device that dries the solids flowing in from the dehydration and separation device by stirring and heating; and
A water purification device that stores and precipitates the desorbed liquid flowing from the dehydration separation device and discharges the purified water into an overflow pipe; It is composed including,
When food waste is input through the input port, the stirring liquefaction device measures the input amount by comparing the weight before input and the weight after input, supplies mixed water according to the measured input amount of food waste, and maintains a constant constant through the outlet with a perforated network. It is formed to discharge solids smaller than the size together with the liquid,
A first three-way valve for supplying the liquid discharged from the dehydration separation device to the water purification device and supplying some of the supplied desorption liquid to the washing water of the dehydration separation device or to the mixed water of the stirring liquefaction device. A supply device having two three-way valves and a third three-way valve for mixing and recirculating the fine solids settled at the bottom of the water purification device with the liquid discharged from the dehydration separation device. Discharge formula fermentation drying weight loss food waste processor. delete The method according to claim 1, wherein the dehydration separation device,
An inlet is formed on one side of the lower part to transport food waste vertically, the upper surface is penetrated, and is formed at a certain height to allow moisture to gravity settle from the transported food waste, and a plurality of holes are provided on the sides to allow gravity settling moisture to be discharged to the outside. An inner cylinder with perforations formed thereon;
an outer cylinder that covers the inner cylinder and has a drain hole formed on one lower side to receive moisture flowing to the outside through the perforation and discharge it to the water purification device;
a housing installed on an upper side of the inner cylinder to store a certain amount of discharged food waste, and having an outlet on one side to discharge the stored food waste to the drying device;
A shaft is installed to vertically penetrate the inner cylinder and the housing, a screw for transporting food waste is formed on the outer surface corresponding to the inner cylinder, and a wing for pushing food waste to the outlet is formed on the outer surface corresponding to the housing. formed shaft;
an elastic valve installed between the inner cylinder and the housing and configured to discharge food waste transported by the shaft while pressing it at a constant pressure; and
A discharge water type fermentation drying weight loss food waste disposer comprising a washing nozzle installed on a side of the external cylinder and configured to spray washing water toward the internal cylinder. delete The method according to claim 1, wherein the dehydration separation device stores and precipitates the discharged liquid, supplies the stored lower layer water to the water purification device, and discharges the upper layer water through an overflow pipe of the water purification device, including; A discharge-type fermentation drying weight loss food waste processor characterized in that it consists of: