KR102533025B1 - Apparatus for reducing moisture in solids of the food waste - Google Patents

Abstract

The present invention relates to an apparatus for reducing moisture in solids of food waste to reduce the amount of waste discharge as much as possible. According to the present invention, the apparatus comprises: a transfer screw having a screw blade formed in a spiral shape on the outer peripheral surface and rotated by an operation of a motor to transfer solids forward when the solids from which moisture has been removed through dehydration are introduced from the rear upper part; a screw cover surrounding the outside of the screw blade and gradually reducing the outer diameter forward from the tip of an inlet through which solids flow, so that a transfer pressure of solids transferred by the transfer screw gradually increases; a cutter formed to have a small diameter between the screw blades over a predetermined length on the front outer peripheral surface of the transfer screw, which is provided at a position to reduce the outer diameter of the screw cover, to cut the transferred solid into small pieces; a hot air supply path having a main passage formed in the axial direction at the center of the transfer screw and a plurality of branch passages formed radially from the main passage to the outer peripheral surface of the transfer screw and heating and drying the solids pressurized and cut through the transfer screw by hot air supplied by a hot air blower; and a solid recovery box allowing one end to be connected to the front end part of the screw cover to accommodate a predetermined amount of solids pressurized and cut through the transfer screw, allowing the hot air supplied by the hot air blower to flow into the inside to dry the solids, and being entered and drawn out from one side to allow the solids to be discharged to the outside.

Description

Apparatus for reducing moisture in solids of the food waste}

The present invention relates to an apparatus for reducing the moisture of solids in food waste, and more particularly, allows solids from which moisture is separated by dehydration to be pressurized through a conveying screw having a gradually narrower diameter while being dried by hot air during pressurization, and is cut by the cutter so that the solids can be discharged in a dispersible manner, and the solids discharged are recovered so that they can be discharged to the outside, but the recovered solids are heated again to minimize the amount of discharge and weight. Reduction of solids moisture in food waste It's about the device.

In general, as natural disasters caused by environmental pollution occur frequently, and the resulting damage continues to appear one after another, interest in reducing environmental pollution is increasing. In addition to strengthening regulations to reduce pollution, efforts are being made to prepare appropriate treatment methods.

As a method of treating solids while minimizing environmental pollution, representatively, incineration or drying followed by RDF treatment for fuel conversion may be cited.

However, since solids contain a lot of moisture, simple incineration requires too much fuel, so a dehydration process must be accompanied, and the dehydration efficiency greatly affects the reduction of solids treatment costs.

To this end, in the past, a compression dehydrator by pressurizing the piston in the cylinder, that is, a plurality of cylinders made of nets were arranged in a pistol-type body at regular intervals and integrated, and then, while rotating, solids were supplied from the solids pump to the cylinders. When it is received and transported, the piston is pushed by the rotational motion of the eccentric body so that the solids in the cylinder are squeezed and dehydrated, and then a series of processes that are automatically discharged in the following section are performed continuously to dehydrate the solids. There was a dehydrator.

This dehydrator has the advantage of high dehydration efficiency because dehydration is performed by compression of the piston, but each cylinder is installed in a single body in a piston type and rotates to supply, dewater, and discharge solids. There is a problem in that it was not possible to have sufficient time for dehydration, and the smooth operation of the functions of each section cannot be expected due to unreasonable linkage between each function due to the narrow installation space of the device for the function operation of each section.

In addition, the belt press method, which is mainly used for dewatering solids, has a limit in that the moisture content of solids after dehydration does not exceed about 70%, compared to widely known and used methods. In addition to the high cost of treatment equipment, it is structurally very complex, and in particular, continuous treatment is difficult, so there is a disadvantage in that the amount of solids is limited.

In the solids moisture reduction device of Registered Patent No. 1443819 (2014.09.17.), the supply, dehydration, and separation and discharge process of wet solids by the body part, pressurization part, cake discharge part and transfer screw are excellent in linkage between functions in stages. It enables smooth operation and at the same time enables continuous processing to increase the amount of dewatering of solids.

That is, the solids inserted into the main body are pressurized by the pressurizing part, and the water is discharged through the filter net and the drain hole, and the water-removed solids are compressed by the transfer screw and discharged downward through the cake discharge part along with dehydration. .

However, in the prior art water reduction device, dehydration is performed by simply squeezing solids, but dehydration by simply squeezing is limited, and the discharged water is too polluted to be discharged through the sewer as it is, which deteriorates sewage quality. In addition, there is a problem in that a separate drying device must be provided.

(Document 1) Registered Patent No. 1443819 (2014.09.17.)

Accordingly, the present invention is to solve the above problems, and the present invention is a solids moisture reduction device for food waste that allows the solids to be dried very quickly by hot air and heat during dehydration, thereby enabling the recovery of solids in a minimum amount. Its main purpose is to provide

In addition, another object of the present invention is to provide an apparatus for reducing solids moisture in food waste, which can prevent deterioration of sewage quality by preventing discharge of solids through sewage.

Particularly, another object of the present invention is to provide an eco-friendly device for reducing the amount of solids in food waste, which minimizes the amount of garbage by reducing the weight of dried solids as much as possible and at the same time discharging them in a small amount.

In order to achieve the above object, the device for reducing moisture in solids of food waste according to the present invention has screw blades formed in a spiral shape on the outer circumferential surface, and rotates by driving a motor when solids from which moisture is removed through dehydration are introduced from the upper part of the rear side. A conveying screw that allows the solids to be conveyed forward while doing so; A screw cover that gradually increases the conveying pressure of the solids conveyed by the conveying screw by gradually reducing the outer diameter toward the front from the front end of the inlet through which the solids are introduced while covering the outside of the screw blades; A cutter formed on the outer circumferential surface of the front side of the transfer screw provided at a position where the outer diameter of the screw cover is reduced to have a smaller diameter between the screw wings over a predetermined length to cut the solid material to be pressurized into small pieces; A main passage formed in the axial direction from the center of the transfer screw and a plurality of branch passages are formed radially from the main passage toward the outer circumferential surface of the transfer screw, and the hot air supplied by the hot air blower presses through the transfer screw and A hot air supply path for drying by applying heat to the solid material to be cut; One end is connected to the front end of the screw cover so that a certain amount of the solids that are pressurized and cut through the transfer screw are accommodated, and the hot air supplied by the hot air blower is introduced into the inside to dry the solids, and take them out from one side It is a configuration provided with a solids collection box that allows the mouth to be discharged to the outside.

In the hot air supply path, a hot air supply convex is fixedly connected to a rear end surface of the screw cover covering the rear end of the transfer screw, and the hot air supply block passes through the screw cover from the rear end of the transfer screw to the outside. It is provided in a ring shape surrounding the outer circumferential surface of the boss formed to protrude, and the rear end of the main passage of the hot air supply path formed in the transfer screw is connected to a ring-shaped hot air receiving groove formed on the outer circumferential surface of the boss. The hot air accommodating groove communicates with the hot air supply groove of the hot air supply block provided outside thereof, so that the hot air supplied from the hot air blower passes through one side of the hot air supply block to the hot air accommodating groove connected to the main passage together with the hot air supply groove. to supply

One side of the hot air supply block is fixedly connected to the screw cover, and the boss penetrating the center of the hot air supply block has an end rotatably connected to a motor so that the boss is formed on the boss even when rotated by the motor The hot air accommodating groove maintains mutual communication with the hot air supply groove formed in the hot air supply block.

The solids collection box includes a discharge pipe having one end connected to the front end of the screw cover so that the pressurized, cut and dried solids can be transported and dropped downward, a collection case connected to the lower end of the discharge pipe, and the recovery box. It is made as a case that is opened upward to accommodate a certain amount of solids falling through the discharge pipe while the lower end is elastically supported inside the box case so that the upper end is in close contact with the upper surface of the collection case.

A portion of the hot air generated from the hot air blower is supplied to the upper surface of the solids collection box to which the discharge pipe is connected, so that the solids contained in the box together with the solids falling downward from the discharge pipe are heated and dried.

As in the above configuration, the apparatus for reducing moisture in solids of food waste according to the present invention allows the solids of the food waste, from which moisture is removed, to be compressed by the conveying screw so that the conveyed solids are more finely pulverized, and at the same time, the hot air supply path The solids to be pulverized by the hot air supplied through the pipe are first dried, and the solids discharged from the transfer screw are dried by the hot air again in the solids collection box, thereby minimizing the amount and weight of the solids and reducing the amount of garbage discharged as much as possible. do.

In addition, the present invention makes it possible to provide an eco-friendly device that can further reduce pollution while reducing the amount of food waste passing through the sewer.

1 is a structural diagram illustrating an apparatus for reducing solid moisture in food waste according to the present invention;
Figure 2 is an enlarged view of the main part of the food waste solids moisture reduction device according to the present invention
3 is a cross-sectional view illustrating an enlarged example of a hot air supply path of the apparatus for reducing solids moisture in food waste according to the present invention;
4 is a cross-sectional view illustrating an enlarged connection structure between a boss of a transfer screw and a hot air supply block of a hot air supply path in the apparatus for reducing solid moisture in food waste according to the present invention.
5 is a cross-sectional view illustrating an enlarged example of a solids collection box in the solids moisture reduction device for food waste according to the present invention

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily carry out the present invention.

The scope of the present invention should not be construed as being limited by the embodiments described in the text.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the description of the embodiments, the same reference numerals are assigned to the same components, and descriptions of the same reference numerals are omitted in some cases.

1 is a structural diagram illustrating a device for reducing solid moisture in food waste according to the present invention, and FIG. 2 is an enlarged view illustrating a cutter of the device for reducing solid moisture in food waste according to the present invention.

As illustrated, the apparatus for reducing the moisture content of food waste according to the present invention largely consists of a transfer screw 10, a screw cover 20, a cutter 30, a hot air supply path 40, and a solids collection box 50. am.

The transfer screw 10 of the present invention allows the screw blades 11 to be formed at a constant pitch in the axial direction along the outer circumferential surface, and allows solids to be removed from the water by the previous equipment to flow in from the upper rear side.

In addition, the drive shaft of the motor 12 is connected to the rear end so that the transfer screw 10 rotates by driving the motor.

The screw blades 11 formed on the outer circumferential surface of the transfer screw 10 are formed in a spiral shape so that the solids supplied from the upper portion of the rear are moved forward.

The outer circumferential surface of the transfer screw 10 forming the screw wings 11 on the outer circumferential surface is covered by the screw cover 20.

That is, the screw cover 20 covers the outside of the transfer screw 10 and is formed with an inner diameter close to the outer diameter of the screw wing 11. It is formed in a shape in which the inner diameter is gradually reduced from the front end to the front.

In other words, the outer circumferential surface on which the inlet 21 is formed is formed horizontally, and the inner diameter gradually decreases from the front end of the inlet 21 forward, or the inner diameter gradually decreases from the rear end toward the front. .

Therefore, the solids supplied between the screw blades 11 by the rotation of the transfer screw 10 move in a helical shape and gradually pressurize the solids along the screw cover 20 having a reduced diameter.

It is more preferable that the screw cover 20 is made of a metal material that is resistant to corrosion while preventing deformation during pressure transfer of solids and does not cause scratches even in continuous friction with solids.

The cutter 30 is formed with a smaller outer diameter than the screw wing 11 on the outer circumferential surface of the transfer screw 10 at the front end of the screw wing 11 covered by the screw cover 20.

The cutter 30 is formed to protrude integrally on the outer circumferential surface of the front side of the transfer screw 10, and is formed between the pitches of the screw wings 11 formed on the outer circumferential surface of the transfer screw 10, but the screw blades It is to be formed with a smaller outer diameter than the outer diameter of (11) so that the solid material compressed between the screw blades 11 and transported forward is more finely cut.

Even though the solids cut by the cutter 30 are compressed, the bonding force between the solids is weakened to facilitate dispersion.

The hot air supply path 40 is formed on the outer circumferential surface of the transfer screw 10 together with the cutter 30.

As shown in FIG. 3, the hot air supply path 40 forms a main passage 41 with a predetermined diameter along the center of the diameter of the transfer screw 10, and radially extends from the main passage 41 to the outer circumferential surface of the transfer screw 10. The branch passage 42 is formed, but the outer circumference side end of the transfer screw 10 of the branch passage 42 is formed in a shape in which hot air is sprayed toward the outside, while the end is formed toward the front of the outside. desirable.

The hot air generated by the hot air blower 43 is supplied to the hot air supply path 40 formed in the transfer screw 10, and the heat supplied in this way removes moisture from the solids moving along the outer circumferential surface of the transfer screw 10. By removing it, it is easy to cut and disperse the solids in front of the transfer screw 10.

The hot air blower 43 for supplying heat to the hot air supply path 40 sucks in air from the outside at the bottom of the transfer screw 10, and heats the sucked air inside to a certain temperature or higher so that the blower 430 The hot air supply block 44 is fixedly connected to the rear end surface of the screw cover 20 covering the rear end of the transfer screw 10, as shown in FIG. 4. While doing so, the hot air supply block 44 is provided in a ring shape surrounding the outer circumferential surface of the boss 13 formed to protrude outward through the screw cover 20 from the rear end of the transfer screw 10, and the transfer screw The rear end of the main passage 41 of the hot air supply passage 40 formed in (10) is connected to the ring-shaped hot air receiving groove 410 formed on the outer circumferential surface of the boss 13, and the hot air receiving groove 410 is The hot air supplied from the hot air machine 43 is supplied to the hot air supply groove 440 through one side of the hot air supply block 44 by communicating with the hot air supply groove 440 of the hot air supply block 44 provided outside. make it possible

At this time, one side of the hot air supply block 44 is fixedly connected to the screw cover 20, and the end of the boss 13 passing through the center of the hot air supply block 44 is rotated by the motor 12, so that the boss 13 ) is rotated, the hot air receiving groove 410 formed in the boss 13 is most preferably sealed so that it can be stably connected to the hot air supply groove 440 formed in the hot air supply block 44.

That is, while the boss 13 is rotatably connected with respect to the hot air supply block 44, the hot air receiving groove 410 formed toward the boss 13 and the hot air supply groove 440 of the hot air supply block 44 are mutually connected. The communication allows the hot air supplied to the hot air supply block 44 to be stably supplied through the hot air supply passage 40 .

The solids pressurized, cut, and dried in front of the transfer screw 10 are recovered to the solids collection box 50 through the discharge pipe 51 as shown in FIG. 5 .

One end of the discharge pipe 51 of the solids collection box 50 is connected to the front end of the screw cover 20 so that the pressurized, cut and dried solids can be transported by the pressurized force and fall downward, and the discharge pipe 51 The lower part of is connected to the upper end of the collection case 52, and the inside of the collection case 52 is provided with a housing 53 that opens upward.

The upper surface of the collection box case 52 to which the discharge pipe 51 of the solids collection box 50 is connected is supplied with a portion of the hot air generated from the hot air blower 43 so that the box together with the solids falling downward from the discharge pipe 51 Heat is applied to the solids filled in (53) to dry them again.

However, the lower part of the housing 53 is elastically supported inside the recovery case 52 so that the upper end communicates with the discharge pipe 51 and adheres to the upper surface of the recovery case 52 .

On the other hand, it is preferable that the collection case 52 is opened to one side and a handle is formed on the outer circumferential surface of one side of the case 53 so that the case 53 is detachably coupled to one side of the collection case 52. do.

In addition, the conveying screw 10 of the present invention allows the hot air to be supplied through the hot air blower 43 while the motor 12 starts to be automatically driven as the solids are introduced, and the collection case 52 of the discharge pipe 51 When the solids are not detected from the end connected to the motor 12, the driving of the motor 12 and the supply of hot air are stopped. It is most preferable that the solids accommodated in the housing 53 are completely dried and powdered by being maintained.

As in the above configuration, the action and effect of the device for reducing solid moisture in food waste according to the present invention will be described in more detail.

An object of the present invention is to pressurize solids discharged through a solid-liquid separation unit that separates sewage and solids from food waste, dry them with hot air, and at the same time cut the compressed solids so that they can be recovered to the outside.

To this end, the configuration including the transfer screw 10 provided to pressurize the solids and the screw cover 20 to cover the outside of the transfer screw 10 is the same as the previous one, but the screw cover 20 of the present invention is rear It is characterized in that the screw wing 11 of the transfer screw 10 provided therein is also formed with a diameter close to the diameter of the screw cover 20 while gradually reducing the outer diameter from the front.

However, in the present invention, the screw cover 20 provided to surround the transfer screw 10 from the outside prevents scratches or deformation even by continuous contact with the solid material while preventing the solid material pressurized from the inside from escaping to the outside at all. It is formed as a material that is resistant to corrosion while being prevented so that safe maintenance is possible.

The solids moving from the rear to the front by the transfer screw 10 have their inner diameters gradually reduced from the rear to the front in the same way as the transfer screw 10, so that the moving pressure gradually increases and the compression force between the solids in close contact with each other becomes stronger. do.

When the compression force between the solids becomes stronger, the volume is somewhat reduced by the remaining moisture, but as the adhesion between the solids becomes stronger, a problem may occur in which the load of the motor for pressurizing the solids increases.

Therefore, in the present invention, a plurality of cutters 30 having a smaller outer diameter than the screw wings 11 of the transfer screw 10 are provided on the front end of the front side transfer screw 10 of the screw cover 20 over a certain length along the outer circumferential surface. By causing the pressurized solids to be cut, the load by driving the motor 12 can be further reduced.

In addition, the water generated from the solids during pressure transfer along the transfer screw 10 requires a separate configuration for wastewater treatment. make it possible

When moisture is removed from the solids to be pumped, not only the compressive force between the solids is reduced, but also the volume can be further reduced and the weight can be further reduced.

To this end, the transfer screw 10 has a main passage 41 and a branch passage 42 formed radially from the main passage 41 so that the hot air generated through the hot air blower 43 moves the transfer screw 10 By supplying it to the solids being pumped through, the solids can be moved while drying.

The hot air generated from the hot air blower 43 for supplying hot air is integrally formed to protrude from the rear end surface of the transfer screw 10 through the hot air supply block 44 provided to the rear side of the transfer screw 10 by the blower 430. It is transmitted to the main passage 41 through one boss 13, and the boss 13 rotating together with the transfer screw 10 with respect to the hot air supply block 44 fixedly coupled to the screw cover 20 By ensuring that the sealing is always stably performed between the inner circumferential surfaces, the hot air supply groove 440 of the hot air supply block 44 and the hot air receiving groove 410 of the boss 13 are maintained in constant communication with the main passage 41 Stable supply of hot air through the branch passage 42 can be achieved.

If the solids during pressure transfer are cut while being dried, the mutual binding force between the solids is lowered, making it possible to pulverize the solids. Therefore, the load on the motor can be minimized during pressure transfer, so that the volume and weight of the solids can be further reduced along with safe maintenance of the motor 12. It is possible to reduce, and in particular, it is possible to omit a structure for separate wastewater collection and treatment.

The solids transferred to the solids collection box 50 through the transfer screw 10 are also collected in the housing 53, and the moisture is continuously removed from the solids as much as possible by the hot air supplied through the upper surface of the collection case 52. make it possible

Since the solids from which moisture has been removed are almost powdered in the housing 53, the solids can be easily discharged from the housing 53 taken out of the collection case 52, so hygienic management is possible and the convenience of easier operation is improved. There are advantages to offer.

As such, the present invention is not limited to the described embodiments, and it is obvious to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention. Therefore, it should be said that such modifications or variations fall within the scope of the claims of the present invention.

10: transfer screw
11: screw wing 12: motor
13 : Boss
20: screw cover
30: cutter
40: hot air supply path
41: main passage 410: hot air receiving groove
42: branch passage
43: hot air blower 430: blower
44: hot air supply block 440: hot air supply groove
50: solids collection box
51: discharge pipe 52: recovery box case
53: hull

Claims (5)

Screw blades are formed on the outer circumferential surface in a spiral shape, and when solids from which moisture is removed through dehydration are introduced from the rear upper part, a conveying screw that rotates by a motor drive and pressurizes the solids forward;
A screw cover that gradually increases the conveying pressure of the solids conveyed by the conveying screw by gradually reducing the outer diameter toward the front from the front end of the inlet through which the solids are introduced while covering the outside of the screw blades;
A cutter formed on the outer circumferential surface of the front side of the transfer screw provided at a position where the outer diameter of the screw cover is reduced to have a smaller diameter between the screw wings over a predetermined length to cut the solid material to be pressurized into small pieces;
A main passage formed in the axial direction from the center of the transfer screw and a plurality of branch passages are formed radially from the main passage toward the outer circumferential surface of the transfer screw, and the hot air supplied by the hot air blower presses through the transfer screw and A hot air supply path for applying heat to the solid material to be cut and drying it;
A discharge pipe, one end of which is connected to the front end of the screw cover, through which the pressurized, cut, and dried solids are transported and allowed to fall downward through the transfer screw; a collection case connected to the lower end of the discharge pipe; The lower part is elastically supported inside the box case so that the upper part is in close contact with the upper surface of the collection box case, and the solids falling through the discharge pipe are opened upward to receive a certain amount. A container to which the discharge pipe is connected On the upper surface of the hot air supplied by the hot air blower is introduced to simultaneously heat and dry the solids accommodated in the enclosure together with the solids falling downward from the discharge pipe, and to allow the solids to be drawn in and out from one side so that the solids are discharged to the outside solids recovery to enable;
equipped with,
In the hot air supply path, a hot air supply convex is fixedly connected to a rear end surface of the screw cover covering the rear end of the transfer screw, and the hot air supply block passes through the screw cover from the rear end of the transfer screw to the outside. It is provided in a ring shape surrounding the outer circumferential surface of the boss formed to protrude, and the rear end of the main passage of the hot air supply path formed in the transfer screw is connected to a ring-shaped hot air receiving groove formed on the outer circumferential surface of the boss. The hot air receiving groove communicates with the hot air supply groove of the hot air supply block provided outside thereof, so that when the end of the boss is connected to the motor and rotates, the hot air supplied from the hot air machine passes through one side of the hot air supply block. An apparatus for reducing solids moisture in food waste to be supplied to a hot air receiving groove connected to a main passage together with a supply groove. delete delete delete delete

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