KR101028570B1 - Process apparatus of organic waste - Google Patents

Abstract

PURPOSE: An organic waste processing apparatus is provided to reduce bad smell and impurities from organic waste including food waste, and to minimize the discharging amount of sludge. CONSTITUTION: An organic waste processing apparatus comprises the following: a sludge collection tank(100) divided into a stirring region(110), a precipitation region(120), and a storage region(130) for forming purified sludge fluid by crushing and purifying an object to be stirred; and a compressing dehydrator(200) receiving the purified sludge fluid from the storage region, and compressing the fluid for separating water to discharge. The sludge collection tank includes a stirrer(111), a driver(113), and a screen(115).

Description

Process Apparatus Of Organic Waste

The present invention relates to an organic waste treatment apparatus, and more particularly, to clean organic waste such as food waste to remove odors and impurities, and to purify the waste and then pressurize to discharge solid sludge, thereby efficiently treating organic waste. In addition, the present invention relates to an organic waste disposal apparatus capable of minimizing sludge discharge and maintaining a pleasant environment from organic waste at all times.

In general, as an organic waste treatment method such as food waste, an incineration treatment method that burns away from an incinerator and a method of reducing the volume of food waste by removing moisture contained in the organic waste are used.

In relation to the treatment technology of organic waste as described above, Korean Patent Registration No. 10-0365896 discloses that a cylindrical dewatering screen having a plurality of dewatering holes formed on its periphery is installed and installed at a lower end of the dewatering screen. An introduction port through which the pulverized food waste pulverized is introduced is formed, and a conveying screw is rotatably disposed in the dewatering screen by a driving means, and the crushed food waste introduced into the dehydrating screen is introduced into the dehydrating screen. A food waste processing apparatus configured to dehydrate while being conveyed upward by forward rotation and discharged from an outlet provided at an upper end of a dewatering screen, wherein a conveying speed detecting means for detecting a conveying speed of the ground food waste by the conveying screw is provided; The conveying speed detected by the conveying speed detecting means is not sufficient. When the lower than the prescribed value, there is a description of a food waste treatment apparatus ", characterized in that configured to again rotate the conveying screw constant post bar after the conveying screw by rotating a predetermined rotation.

However, the conventional food waste treatment apparatus is not equipped with a sludge purification treatment system is completely equipped with a bad odor occurs in the discharged sludge, there is no separate device that can reduce the emissions during the treatment of sludge In order to reduce the discharge of the sludge, there was a problem in that the function as a food waste treatment device was not sufficient, so that it was not effective.

In addition, the water contained in the sludge is separated from the sludge to be purified through the filter to be discharged, the sludge is dehydrated after the discharge of the sludge during the discharge process is not completely made, so that some remain on the filter This is because the filter is clogged by the continuous work and the purification function is greatly reduced, so the replacement of the filter is inevitable. Therefore, the filter needs to be continuously managed such as cleaning or changing the filter in the middle of the work. It is an urgent need to develop an organic waste treatment apparatus that can process organic waste more efficiently because it is costly and provides a cause of deterioration of the work efficiency.

The present invention is to solve the above problems, the organic waste and the solid and the sludge and water separated from each other from the purified sludge liquid and the means for washing and crushing by washing with agitation while water is filtered out after each By discharging means, the odor and impurities of organic wastes are removed, the organic wastes can be treated efficiently, and the surrounding environment can be kept comfortably from the organic wastes, and together with the sludge particle size and water content It is an object of the present invention to provide an organic waste treatment apparatus capable of minimizing sludge emissions by reducing volume.

In addition, the present invention can be used permanently without replacing the filter to filter the water by installing the means for completely discharging the solid sludge after separating and filtering the water in the purified sludge liquid from the organic waste, the convenience of maintenance In addition to minimizing maintenance costs, the filter is prevented from being clogged by foreign substances to improve the filtration efficiency by the filter, and the work can be continuously performed to provide an organic waste treatment device that can maximize the efficiency of the work. It is to.

The organic waste treatment apparatus proposed by the present invention comprises: a sludge collecting tank partitioned into a stirring zone, a precipitation zone, and a storage zone to form a fine particle size purified sludge liquid by pulverizing and purifying the stirring object; And a pressurized dewatering device connected to the sludge collection tank to supply the sludge solution contained in the storage area and pressurized sludge solution to separate water from the sludge and then discharge the sludge solution.

The sludge collection tank is provided with a rotating shaft rotatably installed in the stirring zone, the stirring means comprising a stirring blade formed along the outer circumference of the rotating shaft to stir the stirring object; And driving means fixed to the outside of the sludge collection tank and connected to one end of the rotating shaft to apply rotational force to the stirring means.

The stirring object to be added to the stirring zone of the sludge collection tank includes organic waste, microorganisms, water and auxiliary stirring material, and the auxiliary stirring material is added at a ratio of 1: 1 based on the organic waste.

The sludge collection tank includes a screen which is provided between the stirring zone and the precipitation zone and is provided to be supplied to the precipitation zone because only the stirring object that is agitated in the stirring zone and ground to a predetermined size is passed.

And a solid-liquid feeder which sucks sludge liquid from the storage area of the sludge collection tank and supplies it to an upper end of the pressurized dewatering device, wherein the solid-liquid feeder is fixed to an outer upper end of the storage area and to a suction port of the pump. A solid-liquid suction pipe connected to the inlet and formed at the lower end of the storage area to suck sludge liquid, and a solid-liquid supply pipe connected to one end of the pump outlet and connected to an upper end of the pressurized dehydration device. Is done.

The solid-liquid supply pipe includes a control valve for controlling the amount of sludge supplied to the compression-type dewatering device by controlling whether the sludge is supplied to the compression-type dehydration device in the storage area of the sludge collection tank or by adjusting the opening degree. .

The pressurized dewatering device may include a pressurizing part for pressurizing the sludge solution supplied from the sludge collection tank, a filtration part fixedly installed at a lower end of the pressurizing part and formed to purify water separated from the sludge by the pressurizing action of the pressurizing part; And, it comprises a discharge portion installed in the lower portion of the pressing portion to discharge the purified water separated through the filtration.

The press part is provided with an inlet through which the sludge solution is supplied to the upper end, and a pressurized space is formed to receive the pressurized sludge solution and pressurizes therein, and a lower sludge outlet port is formed to discharge the solid sludge from which water is removed. It includes a case and a sludge press fixed to the upper surface of the body case and pressurized sludge liquid supplied to the pressurized space.

The sludge presser is installed on the upper surface of the body case and the rod is lifted up and down, and the compression cylinder is applied to the compression cylinder, and fixed to the rod end of the compression cylinder is located in the pressurized space of the body case is transmitted from the compression cylinder It comprises a pressing head for pressing the sludge liquid while the slide moves by the power.

The pressing head portion includes a packing formed on an upper end of the outer circumference so as to prevent water from leaking upward when the sludge solution is pressurized.

The filtration unit comprises a filtration filter in which a plurality of holes are formed to pass only water while filtering sludge when the sludge solution is pressurized by the pressing unit, a nonwoven fabric stacked on the filtration filter, and a lower surface of the filtration filter. Packing is laminated on the periphery, and is laminated around the upper surface of the nonwoven fabric comprises a cover for fixing the filter and the nonwoven fabric and packing.

As the nonwoven fabric, it is preferable to use a polyethylene nonwoven fabric having high density.

The discharge part includes a hopper case having a water discharge port formed at a lower end thereof and an inclined surface toward the water discharge port so that the purified water passed through the filtration unit can be smoothly moved to the water discharge port.

In addition, the organic waste treatment apparatus of the present invention may further comprise a sludge sweep device for discharging to the outside to remove the solid sludge which is separated from the pressing portion and left in the upper portion of the filtering portion at the lower end of the pressing portion. It is possible.

The sludge sweep device is located at the lower end of the pressing portion and the upper and lower sides are formed to allow the inflow of sludge liquid or to move the water and the side of the sweep portion is formed so as to move the solid sludge dehydrated by the pressing portion; And a sweep cylinder which is connected to one side of the sweep part and moves the rod back and forth to discharge the solid sludge while the sweep part is bound and separated from the crimping part.

The blade plate is formed in a semi-circular shape in the inner lower front of the sweep portion, the upper end includes a blade plate formed to form an inclined surface inclined toward the inner side as the upper end is in contact with the side wall, the blade plate is inclined angle relative to the side wall that the upper end is in contact with It is formed at 20 ~ 45 °.

The sweep unit may further include a blade pad member extending from the lower end of the blade plate and formed of a material having excellent elastic force to discharge the compressed sludge remaining on the filtration unit.

According to the organic waste treatment apparatus according to the present invention, the composition of the sludge collection tank for cleaning and pulverizing and cleaning the sludge of the organic waste while stirring organic waste such as food waste with water, microorganisms and auxiliary stirring materials and purified sludge liquid As it constitutes a pressurized dehydration device that discharges solid sludge and water from each other, the water is filtered and discharged, the odor of organic waste is removed as well as impurities, and the process of treating such organic waste is efficiently performed so that the environment is always maintained. The effect can be kept comfortable.

In addition, the organic waste treatment apparatus according to the present invention stirs the organic waste by means of agitation, but microorganisms are added to fermentation and decomposition of the organic waste and at the same time the auxiliary stirrer is added to the trituration of the organic waste by friction crushing dehydration apparatus As the water removal and compression force are applied through the sludge compactor, the sludge particle size and water content can be reduced while the volume is reduced, thereby minimizing sludge emissions.

In addition, the organic waste treatment apparatus according to the present invention is permanently without replacement by installing a sludge sweep device for separating and filtering the water in the sludge liquid purifying the organic waste, and completely discharge the solid sludge without remaining amount on the filtration unit. The use of a filtration unit facilitates facility maintenance, minimizes facility maintenance costs, prevents filtration from being blocked by foreign substances, improves filtration efficiency, and enables continuous operation to maximize work efficiency. It works.

1 is a front sectional view showing an embodiment according to the present invention.
Figure 2 is a plan sectional view showing one embodiment according to the present invention.
Figure 3 is a side view showing an embodiment according to the present invention.
Figure 4 is a cross-sectional view showing an embodiment according to the present invention.
Figure 5 is an enlarged cross-sectional view showing a filter in one embodiment according to the present invention.
6 (a) and 6 (b) are a side cross-sectional view and a plan view, respectively, illustrating a sweep portion of the present invention.
Figure 7 is a side cross-sectional view showing another embodiment of the sweep portion in the present invention.
8 is an enlarged view showing a state of use of the sludge collection tank in the present invention.
Figure 9 is an enlarged view showing a state of use of the crimping portion in the present invention.
10 is an enlarged view showing a state of use of the sludge sweep apparatus in the present invention.

The present invention comprises a sludge collection tank divided into a stirring zone, a precipitation zone, and a storage zone so as to grind and purify the stirring object to form a purified sludge liquid having a fine particle size; Organic sludge treatment apparatus comprising a pressurized dewatering device which is connected to the sludge collection tank and is supplied with sludge solution contained in the storage area and pressurized sludge solution separates water from the sludge and then discharges the sludge solution. It features.

In addition, the sludge collecting tank is provided with a rotating shaft rotatably installed in the stirring zone, and formed along the outer circumference of the rotating shaft, the stirring means comprising a stirring blade for stirring the stirring object; The organic waste treatment apparatus comprising a; is fixed to the outside of the sludge collection tank and connected to one end of the rotating shaft to apply a rotational force to the stirring means.

In addition, the stirring object to be added to the stirring zone of the sludge collection tank includes organic waste, microorganisms, water and auxiliary stirring material, and the auxiliary stirring material is organic waste treatment in a ratio of 1: 1 based on the organic waste. The device is characterized by a technical configuration.

In addition, the sludge collection tank is disposed between the stirring zone and the precipitation zone, and the organic waste treatment comprising a screen formed to be able to supply to the precipitation zone because it is passed through the stirring object that is stirred in the stirring zone and crushed to a certain standard. The device is characterized by a technical configuration.

In addition, the organic waste treatment apparatus comprising a solid-liquid feeder for sucking the sludge liquid from the storage area of the sludge collection tank and supplying it to the upper end of the pressurized dewatering device is a feature of the technical configuration.

In addition, the solid-liquid feeder is a pump fixed to the outer top of the storage zone, the solid-liquid suction pipe connected to the suction port of the pump and the inlet is located at the lower end in the storage zone to be able to suck the sludge liquid, and the pump One side is connected to the discharge port of the organic waste treatment apparatus comprising a solid-liquid supply pipe connected to the upper end of the crimping dewatering device is characterized by the technical configuration.

In addition, the solid-liquid supply pipe includes a control valve for controlling the amount of sludge supplied to the pressure-type dewatering device by controlling whether the sludge liquid is supplied to the pressure-type dewatering device in the storage area of the sludge collection tank or by adjusting the opening degree. The organic waste treatment apparatus which comprises the above is characterized by a technical configuration.

In addition, the pressurized dewatering device is a filtration unit for pressurizing the sludge liquid supplied from the sludge collection tank, and is fixed to the lower end of the squeezing unit filtration is formed to purify the water separated from the sludge by the pressing action of the pressing unit It characterized in that the organic waste treatment apparatus comprising a portion, and the discharge portion installed in the lower portion of the pressing unit to discharge the purified water separated through the filtration unit.

In addition, the press portion is provided with an inlet through which the sludge solution is supplied to one side of the pressing portion, and a pressurized space is formed to receive the pressurized sludge solution therein and a pressurized space is formed thereon, and a sludge discharge port is formed to discharge the solid sludge from which water is removed. It is characterized in that the organic waste treatment apparatus comprising a body case and a sludge compactor for pressurizing the sludge liquid supplied to the pressurized space and fixed to the upper surface of the body case.

In addition, the sludge presser is installed on the upper surface of the body case and the rod is moved up and down, the compression cylinder and the compression cylinder is fixed to the rod end of the compression cylinder is installed in the pressurized space of the body case is located from the compression cylinder An organic waste treatment apparatus comprising a pressurized head portion for pressurizing the sludge liquid while being slide-moved by the transmitted power is a feature of the technical construction.

In addition, the pressing head portion is characterized in that the organic waste treatment device comprising a packing formed on the upper end of the outer periphery to prevent water from leaking upward when the sludge liquid is pressurized.

The filtration unit may include a filtration filter in which a plurality of holes are formed to pass only water while filtering sludge when the sludge liquid is pressurized by the pressing unit, a nonwoven fabric stacked on the filtration filter, and the filtration filter. The organic waste treatment apparatus comprising a packing laminated around the lower surface of the upper surface of the nonwoven fabric, and a cover which is laminated around the upper surface of the nonwoven fabric to fix the filtration filter, the nonwoven fabric and the packing.

In addition, the nonwoven fabric is characterized by an organic waste treatment apparatus which is a polyethylene nonwoven fabric of high density.

In addition, the discharge portion is an organic waste treatment device comprising a hopper case is formed at the bottom and the inclined surface toward the water discharge port so that the purified water passed through the filter portion can be smoothly moved to the water discharge port at the bottom. It is characterized by the technical configuration.

In addition, the organic waste treatment device further comprises a sludge sweep device for discharging to the outside to remove the solid sludge remaining in the upper portion of the filter portion is separated from the pressing portion on the lower end of the pressing portion as a technical feature do.

In addition, the sludge sweep device is located at the lower end of the crimping portion and the upper and lower surfaces are opened to receive the sludge liquid or to move the water and the side wall is formed to move the solid sludge dehydrated by the pressing portion And a sweep cylinder which is connected to one side of the sweep section and moves the rod back and forth so as to discharge the solid sludge while the sweep section is bound and separated from the crimp section. .

In addition, the organic waste treatment apparatus is formed in a semi-circular shape in the lower front of the inside of the sweep portion, the upper end is in contact with the side wall and formed to form an inclined surface inclined inwardly downward as a feature of the technical configuration.

In addition, the blade plate is characterized in that the organic waste treatment device of the inclination angle of 20 ~ 45 ° inclined relative to the side wall contacting the upper end of the technical configuration.

In addition, the sweep portion is an organic waste treatment apparatus further comprises a blade pad member is formed of a material having excellent elasticity so as to extend to the lower end of the blade plate and discharge the compressed sludge remaining on the filter portion It is characterized by the configuration.

Next, a preferred embodiment of the organic waste treating apparatus according to the present invention will be described in detail with reference to the drawings.

First, one embodiment of the organic waste treatment apparatus according to the present invention, as shown in Figures 1 to 7, comprises a sludge collection tank 100, and a compression type dewatering device (200).

As shown in Figure 1 to Figure 3, the sludge collection tank 100, the stirring object is put into the sequential movement through the grinding and purification step by step, three zones, that is, the stirring zone 110, sedimentation inside It is formed by partitioning the zone 120, storage zone 130.

The sludge collection tank 100 may be formed in an open state at the top, or may be formed in a closed state at the top. In other words, by forming the upper surface of the sludge collection tank 100 in an open state, it is possible to form a structure capable of opening and closing the upper surface from a separate ceiling cover by injecting a stirring object, the upper surface is formed in a closed state It is also possible to form the structure to inject the stirring object from the inlet (not shown in the figure).

As shown in FIGS. 1 and 2, in the stirring zone 110 of the sludge collection tank 100, a stirring means 111 is installed to pulverize and purify the fine particles into fine grains.

The stirring means 111 rotates in the stirring zone 110 and serves to stir the stirring object. That is, the stirring means 111 is a rotating shaft 111a is installed in the stirring zone 110 so as to be rotatable, and is formed along the outer circumference of the rotating shaft 111a to stir while contacting the stirring object (111b) It consists of.

The stirring blades 111b are formed in plural along the outer periphery of the rotating shaft 111a and are installed at equal intervals. Specifically, the stirring blades 111b are longitudinally centered around the rotating shaft 111a for each of the stirring blades 111b. Along the different angles. For example, since the stirring blades 111b installed along the longitudinal direction of the rotating shaft 111a are installed at a position further rotated by an angle of 90 °, as shown in FIG.

In addition, the stirring blades (111b) are formed in a plurality of at equal intervals along the longitudinal direction of the rotary shaft (111a), but the stirring blades (b) are formed by installing a plurality of the stirring blades (111b) at various angles on the same vertical line ( It is also possible to enhance the agitation force by 111b).

The stirring blade 111b is extended so that one side is positioned as close to the inner surface as possible in the stirring zone 110 of the sludge collection tank 100. That is, the stirring blade 111b is fixedly installed on one side of the rotating shaft 111a and the opposite end extends to a position close to the inner surface of the stirring zone 110 so as to stir evenly while applying frictional force to the stirring object. Is formed.

At the end of the stirring blade 111b, a paddle-shaped wing is formed as a cross-sectional structure having a predetermined area so as to generate a sheet resistance force during rotation.

One wing portion forming the paddle shape in the stirring blade 111b may be provided at one end only, and the plurality of wing portions may be formed in a number that can be installed corresponding to the length of the stirring blade 111b. Possible, it is also possible to configure so that the blade wing of the paddle-shaped integrally formed so that the stirring blades (111b) can produce a sheet resistance as a whole by an extended length.

The sludge sump tank 100 is fixed to the outside and comprises a drive means 113 for transmitting power to the stirring means (111).

The driving means 113 is connected to one end of the rotating shaft 111a so that the stirring means 111 can rotate. That is, the driving means 113 is connected to one side of the rotary shaft 111a which has a predetermined portion protruding out of the sludge collection tank 100 to transmit a rotational force, and the driving means 113 and the rotary shaft 111a. Each sprocket is installed, and the sprocket has a structure in which a power transmission means such as a chain is connected to the sprocket.

The agitation object introduced into the agitation zone 110 of the sludge collection tank 100 and stirred by the agitation means 111 includes organic waste (eg, food waste, etc.), microorganisms, water, and auxiliary stirring materials. do.

The microorganism introduced into the stirring zone 110 of the sludge collection tank 100 as one of the stirring objects removes the odor of the organic waste during the stirring process with the organic waste and reduces the overall amount of organic waste by fermenting and decomposing the organic waste. To perform. In addition, the water introduced into the stirring zone 110 of the sludge collection tank 100 creates an optimal environment in which microorganisms can ferment and decompose organic waste.

In order to supply water to the stirring zone 110 of the sludge collection tank 100, it is also possible to supply and supply with other stirring objects, and watering means for spraying water into the stirring zone 110 (not shown in the drawing). Can be installed and configured.

The sprinkling means can generally be applied by applying a variety of sprinkling structure, such as a spray nozzle or a hole sprinkled with a sprinkler, a detailed description thereof will be omitted.

When the watering means is installed in the stirring zone 110 as described above, the stirring object, ie, organic waste, which is stuck to the inside of the stirring zone 110 by the pressure of water by strong watering, is stirred again after the stirring zone ( It is possible to flow to the bottom of 110).

The auxiliary stirrer forms an angular shape of an outer shape, and is introduced into the stirring zone 110 to be rubbed with the organic waste while being stirred together with other stirring objects to serve to decompose the organic waste into fine particles.

The auxiliary stirring material is added to the stirring zone 110 in a ratio of 1: 1 based on the organic waste.

The sludge collection tank 100 includes a screen 115 installed between the stirring zone 110 and the precipitation zone 120. That is, the screen 115 forms a boundary by partitioning the stirring zone 110 and the precipitation zone 120, and the sludge liquid of the organic waste stirred in the stirring zone 110 is movable to the precipitation zone 120. It serves as a passage.

The screen 115 is formed in a lattice shape forming a mesh shape, and as a plurality of fine-sized holes are maintained in a tight gap as a whole, the stirring object is agitated in the stirring zone 110 to be pulverized to a predetermined standard. It is formed to be able to supply to the settling zone 120 by passing only the sludge liquid.

The screen 115 has a radius corresponding to the inner radius of the stirring zone 110 with respect to the rotating shaft 111a and is formed in an arc shape convex downward. That is, the screen 115 is installed to form a shape that does not interfere with the rotation of the stirring blade 111b according to the rotation operation of the stirring means 111.

The size of the hole drilled on the screen 115 is less than 1 mm. That is, only the sludge liquid pulverized into a fine particle size of 1 mm or less among the stirring objects stirred by the stirring means 111 in the stirring zone 110 is supplied through the screen 115 to the precipitation zone 120. Further, the sludge is formed to be supplied only after being pulverized to a particle size of the passage while continuously stirring in the stirring zone (110).

As shown in FIG. 1, the sedimentation zone 120 of the sludge collection tank 100 extends to the screen 115 at the lower portion of the stirring zone 110 and is stirred in the stirring zone 110. Sludge liquid passing through the screen 115 is formed to form a space to precipitate.

The sedimentation zone 120 is a structure in which the sludge solution supplied from the stirring zone 110 can be smoothly supplied toward the storage zone 130 while being collected and moved to one side, and a lower surface of the sedimentation zone 120 is provided. The one side is high and the other side is low, that is, the inclined surface is formed to be gradually downward toward the lower side (the direction in which the storage region 130 is formed).

In the sedimentation zone 120, the side wall of the sludge solution is settled in the direction of gathering is formed partition wall 125 for partitioning the space with the storage area 130, the lower end of the partition wall 125 is the precipitation zone 120 The supply path 126 is formed so that the sludge liquid of the c) may be moved toward the storage region 130.

In the sedimentation zone 120, the sludge liquid is moved along the inclined surface and then moved to the storage region 130 through the supply path 126, but the specific gravity located at the upper portion of the sludge liquid level by the partition wall 125 Small floats are blocked to block movement to the storage area 130.

The storage zone 130 of the sludge collection tank 100 is partitioned with the precipitation zone 120 and the partition wall 125 therebetween to be formed to extend to one side, and to store the sludge solution supplied from the precipitation zone 120. All four sides form a closed space.

The storage area 130 of the sludge collection tank 100 includes a solid-liquid feeder 140 that sucks the sludge solution from the storage area 130 and supplies it to the upper end of the compressed dewatering apparatus 200.

The solid-liquid feeder 140 is a pump 143 is fixed to the outer top of the storage area 130, as shown in Figure 1 and 3, and connected to the pump 143, the inlet is the storage zone ( The solid-liquid suction pipe 145 is located at the lower end of the 130 is formed to suck the sludge liquid, and the solid-liquid supply pipe connected to one side of the pump 143 and the other side is connected to the upper end of the crimp dewatering device 200 ( 141).

The solid-liquid suction pipe 145 is installed to suck the sludge liquid stored in the storage area 130 by the suction force generated through the pump 143, one end is connected to the suction port of the pump 143 and the opposite side Is extended to the inner bottom of the storage region 130 is formed to be immersed in the sludge liquid.

The solid-liquid supply pipe 141 is one end is connected to the discharge port of the pump 143 to supply the sludge liquid sucked through the solid-liquid suction pipe 145 to the compression dewatering device 200 and the opposite side is the compression dewatering device It is formed to be connected to the upper end of the (200).

The solid-liquid supply pipe 141 may be provided with a control valve 142 to control the movement of the sludge liquid toward the pressurized dewatering device 200 according to the operation of the solid-liquid feeder 140. That is, since the control valve 142 is adjusted to open or closed, it is installed to set the blocked sludge liquid or supply the sludge liquid to be supplied. In addition, the control valve 142 may be formed to control the amount of the sludge supplied to the pressure-type dewatering device 200 by adjusting the opening degree.

The control valve 142 preferably uses an electronic valve such as a solenoid valve so as to be automatically controlled in adjusting the opening and closing of the control valve 142.

As shown in FIG. 4, the pressurized dewatering device 200 is connected to the sludge collection tank 100 to supply the sludge solution accommodated in the storage area 130, and the sludge solution introduced into the sludge is pressurized to supply water from the sludge. After separating and discharging each, it consists of a crimping unit 210, a filtration unit 220, and the discharge unit 230.

The pressing unit 210 is a body case 211 for receiving the sludge solution supplied from the storage area 130 of the sludge collection tank 100, and a sludge presser for pressurizing the sludge solution contained in the body case 211 ( 215).

The body case 211 is formed of a structure capable of supplying sludge liquid to the inside and discharging solid sludge from which water is removed. Specifically, the solid-liquid supply pipe 141 is connected to one side of the sludge to supply sludge liquid. The inlet 212 is installed, the pressurizing space 214 is formed to receive the pressurized sludge liquid therein, and the sludge discharge port 213 is formed at the lower end to discharge the solid sludge from which water is removed. .

The sludge presser 215 is fixed to the upper surface of the body case 211 and pressurizes the sludge liquid supplied to the pressurizing space 214, and includes a pressing cylinder 217 and a pressing head portion 219. It is done by

The compression cylinder 217 is installed perpendicular to the upper surface of the body case 211 and serves to apply a compressive force to the sludge liquid introduced into the pressure space 214 while lifting the rod 218 up and down.

The pressing head portion 219 slides up and down by the power transmitted from the pressing cylinder 217 and presses the lower surface directly in contact with the sludge liquid to press the rod 218 of the pressing cylinder 217. It is fixedly installed and lifted by being located in the pressurized space 214 of the body case 211.

The pressing head portion 219 is preferably formed so that the lower surface in contact with the sludge liquid to form a flat plane so that a uniform force is applied to the sludge liquid during pressurization.

The pressing head part 219 is guided while a part of the side surface is in contact with the inner surface of the body case 211 during lifting, that is, the pressing head part 219 is in contact with the body case 211, that is, the pressing head At the upper end of the outer periphery of the part 219, the packing P1 may be configured to prevent water from leaking upward of the pressing head part 219 when the sludge solution is pressurized.

The filter unit 220 is fixed to the bottom of the body case 211 of the pressing unit 210 and purifies the water separated from the sludge by the pressure action of the sludge compactor 215 of the pressing unit 210. .

The filtration unit 220, as shown in Figure 5, when the sludge is pressurized by the pressing unit 210, the filtration filter 225 is formed with a plurality of holes to pass only the water while filtering the sludge, The nonwoven fabric 223 stacked above the filtration filter 225, the packing P2 stacked around the bottom surface of the filtration filter 225, and the filtration filter are stacked around the top surface of the nonwoven fabric 223. 225 and the cover 221 for fixing the nonwoven fabric 223 and the packing (P2).

The nonwoven fabric 223 has a thickness of 1 ~ 1.5mm, and uses a polyethylene nonwoven fabric of high density that can be used for wastewater treatment.

The discharge unit 230 is installed in the lower portion of the compression unit 210 to discharge the purified water through the filter unit 220, the discharge unit 230 has a water outlet 233 is formed at the bottom It includes a hopper case 231.

The hopper case 231 of the discharge part 230 is inclined toward the water discharge port 233 so that the purified water passed through the filtration unit 220 can be smoothly moved to the water discharge port 233. It forms a sloped surface downward to the water outlet (233).

In the present invention, after the water is separated from the pressing unit 210 through the filtration unit 220 and the discharge unit 230, the discharge to the outside to remove the solid sludge remaining on the upper portion of the filtration unit 220. It further comprises a sludge sweep device 240 to.

4 and 6, the sludge sweep device 240 is installed on the pressing portion 210, is installed on one side of the lower end of the body case 211, the sweep portion 241 and the sweep cylinder 246.

As shown in FIG. 6, the sweep part 241 is positioned at the lower end of the crimping part 210, and the upper and lower surfaces thereof are opened to receive sludge inflow or water separated by the crimping part 210. The side wall 242 is formed along the periphery so as to be movable toward 220 and to move the solid sludge dehydrated by the pressing unit 210.

A blade plate 243 formed in a semicircular shape is formed at an inner lower front side of the sweep part 241.

The upper end of the blade plate 243 is formed to form an inclined surface inclined toward the inner side (direction in which the solid sludge is located) in contact with the inner side wall 242 of the sweep portion 241 and downward.

The blade plate 243 forms an inclination angle of 20 ° to 45 ° with respect to the side wall 242 of the sweep part 241 which the upper end is in contact with. Preferably, the inclination angle of the blade plate 243 constitutes 30 °.

And, as shown in Figure 7, the sweep portion 241 is extended to the lower end of the blade plate 243, the blade pad is formed to discharge the compressed sludge remaining on the filter unit 220 It is also possible to comprise the member 250 further.

The blade pad member 250 is formed of a material having excellent elastic force (for example, rubber).

In addition, the blade pad member 250 may be formed in a brush shape so as to discharge while sweeping the compressed sludge remaining in the filtration unit 220.

When the blade pad member 250 is coupled to the blade plate 243 as described above, the blade plate 243 is useful for discharging the compressed sludge remaining on the filtration unit 220. It is possible to maximize.

The sweep cylinder 246 operates the rod 247 to discharge the solid sludge while moving the sweep unit 241 back and forth. Specifically, the sweep cylinder 246 is connected to one side of the sweep unit 241 and is connected to the sweep unit. 241 transfers the sweep part 241 to discharge solid sludge while binding and separating from the body case 211 of the crimping part 210.

It is installed at a lower distance under the sludge sweep device 240 and the conveying means such as a conveyor so that the solid sludge discharged after being transported from the sweep unit 241 can be smoothly transferred to one place (in the drawing). Not shown).

Next, the operational relationship of the organic waste treatment apparatus according to the preferred embodiment of the present invention will be described with reference to FIGS.

First, as shown in FIG. 8, the sludge collection tank 100 is agitated in a state in which microorganisms, water, and auxiliary agitator are added to the stirring zone 110 of the sludge collection tank 100, including organic waste, which is a stirring target. Initiate.

At this time, the stirring operation in the stirring zone 110 is a power is applied from the driving means 113 is operated so that the stirring means 111 is stirred sufficiently in the stirring zone 110 in the stirring zone 110, the stirring The rotational force of the driving means 113 is transmitted to the rotating shaft 111a of the means 111, and the rotation of the rotating shaft 111a is influenced by microorganisms and auxiliary stirring materials while generating sheet resistance from the stirring blades 111b. Therefore, organic waste is pulverized.

As such, the organic waste is crushed to form a sludge solution with water and passes through the screen 115 and then is supplied to the precipitation zone 120, the organic waste that is a stirring object that does not pass through the screen 115 is Grinding is further stirred in the stirring zone 110 until it can pass through the screen 115.

Subsequently, the sludge liquid dropped from the stirring zone 110 through the screen 115 to the precipitation zone 120 naturally flows along the inclined surface of the precipitation zone 120, and then supplies the partition wall 125. Into the storage area 130 through 126 and stores the sludge liquid of a certain level.

Subsequently, the sludge liquid stored in the storage region 130 is transferred through the solid-liquid feeder 140 and supplied to the compressed dewatering device 200, from the pump 143 of the solid-liquid feeder 140. Sludge liquid is sucked through the 145 and then the solid-liquid supply pipe 141 is supplied to the crimping unit 210 of the crimping and dehydrating apparatus 200, and the supply and opening of the sludge solution are controlled from the control valve 142. It is supplied by adjusting the conveying amount of sludge liquid.

Here, the pressurized dehydration apparatus 200 discharges the remaining solid sludge after separating and discharging water from the sludge liquid, as shown in Figure 9 and 10, in the storage area 130 of the sludge collection tank 100 The conveyed sludge liquid is first supplied to the crimping unit 210 to be accommodated.

In this case, as shown in FIG. 9, when the sludge solution is introduced through the inlet 212 and supplied to the pressurized space 214 in the body case 211, the pressing portion 210 of the sludge compactor 215 Compression force is applied from the compression cylinder 217 so that the compression head portion 219 is lowered and the compression head portion 219 is pressed strongly while contacting the sludge liquid through the filter unit 220. After purification, the water is discharged through the hopper case 231 of the discharge part 230 to the water discharge port 233.

Subsequently, the solid sludge from which the water is removed is discharged to the outside through the sludge sweep device 240 as shown in FIG. 10, and the solid sludge which is located in the state where the water is removed on the filtration unit 220 is consequently. The inside of the sweep portion 241 is located, and the sweep portion 241 is separated from the body case 211 while moving backward by the sweep cylinder 246 to discharge the solid sludge.

At this time, when the sweep part 241 is moved to the rear, the blade plate 243 moves while scratching the upper surface of the filter part 220 to the outside all the solid sludge remaining on the filter part 220. To be discharged.

That is, according to the organic waste treatment apparatus according to the present invention configured as described above, the sludge collection tank for cleaning, crushing and purifying the sludge of the organic waste while stirring the organic waste such as food waste with water, microorganisms and auxiliary stirring materials. The composition and the compressed sludge dewatering device which discharges the solid sludge and the water from the purified sludge solution, respectively, filter and discharge the water, thereby removing the odor of the organic waste as well as the impurities, and the process of treating such organic waste It is possible to be efficient and keep the surroundings comfortable at all times.

In addition, the present invention is to stir the organic waste by the stirring means, but the microorganisms are put into the fermentation and decomposition of the organic waste and at the same time the auxiliary stirrer is added to the friction crushing of the organic waste and the water removal through the sludge compactor of the compression type dehydration device And compressive force, it is possible to minimize the sludge emissions by reducing the volume and water content while reducing the sludge particle size.

In addition, according to the present invention, by separating and filtering water in a sludge liquid for which organic wastes have been purified, a sludge sweep device for completely discharging solid sludge without remaining amount on the filter part may be used to permanently use the filter part without replacement. It is possible to maximize the efficiency of the work by minimizing the cost of maintaining the facility, minimizing the maintenance cost of the facility, preventing the clogging of the filter by foreign substances, and improving the filtration efficiency.

In the above, a preferred embodiment of the organic waste treating apparatus according to the present invention has been described. However, the present invention is not limited thereto, and various modifications can be made within the scope of the claims and the detailed description of the invention. It belongs to the scope of the invention.

100: sludge collection tank 110: stirring zone 111: stirring means
111a: rotating shaft 111b: stirring blade 113: drive means
115: screen 120: precipitation zone 125: bulkhead
126: supply path 130: storage area 140: solid-liquid feeder
141: solid-liquid supply pipe 142: control valve 143: pump
145: solid-liquid suction pipe 200: pressurized dewatering device 210: crimping portion
211 body case 212 inlet 213 sludge outlet
214: pressurized space 215: sludge presser 217: pressurized cylinder
218,247 Rod 219 Crimping head 220 Filtering part
221 cover 223 nonwoven fabric 225 filter
230: outlet 231: hopper case 233: water outlet
240: sludge sweep device 241: sweep part 242: side wall
243: blade plate 246: sweep cylinder 250: blade pad member
P1, P2: Packing

Claims (19)

A sludge collecting tank partitioned into a stirring zone, a precipitation zone, and a storage zone so as to form a fine particle size purified sludge solution by pulverizing and purifying the stirring object;
It is connected to the sludge collection tank is supplied with the sludge solution accommodated in the storage area and the introduced sludge liquid is pressurized dewatering device for separating the water from the sludge by pressing and then discharged each;
The sludge collection tank is provided with a rotating shaft rotatably installed in the stirring zone, and formed along the outer circumference of the rotating shaft, the stirring means comprising a stirring blade for stirring the stirring object; Drive means fixed to the outside of the sludge collection tank and connected to one end of the rotary shaft to apply a rotational force to the stirring means; And a screen installed between the stirring zone and the precipitation zone and configured to be supplied to the precipitation zone because only the stirring object that is agitated in the stirring zone and ground to a predetermined standard passes through the stirring zone.
The pressurized dewatering device includes a pressurizing part for pressurizing the sludge solution supplied from the sludge collection tank; A filtering part fixedly installed at a lower end of the pressing part and configured to purify water separated from the sludge by the pressing action of the pressing part; And a discharge part installed at the lower portion of the compression part to discharge the purified water separated through the filtration part.
The pressurization part is provided with an inlet for supplying sludge liquid to one of the upper ends, and a pressurized space is formed to receive the sludge liquid therein and pressurize therein, and a sludge discharge port is formed to discharge the solid sludge from which water is removed at the lower end. And a sludge compactor for pressurizing the sludge solution which is fixedly installed on the upper surface of the body case and supplied to the pressurized space.
delete The method according to claim 1,
The agitation object introduced into the agitation zone of the sludge collection tank includes organic waste, microorganisms, water, and auxiliary stirring material,
The auxiliary agitating material is an organic waste treatment apparatus, characterized in that the input at a ratio of 1: 1 based on the organic waste.
delete The method according to claim 1,
And a solid-liquid feeder for sucking sludge from the storage area of the sludge collection tank and supplying the sludge solution to the upper end of the pressurized dewatering device.
The method according to claim 5,
The solid-liquid feeder, the pump is fixed to the outer top of the storage area, the solid-liquid suction pipe connected to the suction port of the pump and the inlet is located in the lower end of the storage area to be able to suck the sludge liquid, and the One side is connected to the discharge port and the other side is an organic waste treatment apparatus comprising a solid-liquid supply pipe connected to the upper end of the crimping dewatering device.
The method of claim 6,
The solid-liquid supply pipe includes a control valve for controlling the amount of sludge supplied to the compression-type dewatering device by controlling whether the sludge solution is supplied to the compression-type dehydration device from the storage area of the sludge collection tank or by adjusting the opening degree. Organic waste treatment apparatus, characterized in that made.
delete delete The method according to claim 1,
The sludge compactor is installed on the upper surface of the body case, the compression cylinder to apply a compressive force while the rod is moved up and down, and fixed to the rod end of the compression cylinder is located in the pressurized space of the body case and transmitted from the compression cylinder An apparatus for treating organic waste, characterized in that it comprises a crimping head portion for pressurizing the sludge liquid while being slid by a power.
The method according to claim 10,
The pressurized head portion comprises an organic waste treatment apparatus comprising a packing formed on an upper end of the outer periphery to prevent water from leaking upward when the sludge solution is pressurized.
The method according to claim 1,
The filtration unit may include a filtration filter in which a plurality of holes are formed so as to pass only water while filtering sludge when the sludge liquid is pressurized by the pressing unit, a nonwoven fabric stacked on the filtration filter, and the filtration filter. And a cover laminated around the lower surface and a cover laminated around the upper surface of the nonwoven fabric to fix the filtration filter, the nonwoven fabric and the packing.
The method of claim 12,
The nonwoven fabric is an organic waste treatment apparatus, characterized in that the polyethylene nonwoven fabric forming a high density.
The method according to claim 1,
The discharge portion, the organic waste characterized in that it comprises a hopper case is formed at the bottom and the inclined surface toward the water discharge port so that the purified water passed through the filtration unit can be smoothly moved to the water discharge port. Processing unit.
The method according to claim 1,
Organic waste treatment apparatus further comprises a sludge sweep device for discharging to the outside to remove the solid sludge remaining in the upper portion of the filter portion is separated from the pressing portion at the lower end of the pressing portion.
The method according to claim 15,
The sludge sweep device is located at the lower end of the pressing portion and the upper and lower surfaces are opened to receive the sludge liquid or to move the water and the side of the sweep portion is formed so as to move the solid sludge dehydrated by the pressing portion And a sweep cylinder which is connected to one side of the sweep part and moves the rod back and forth so as to discharge the solid sludge while the sweep part is bound and separated from the crimping part.
The method according to claim 16,
Organic waste treatment apparatus characterized in that it is formed in a semi-circular shape in the lower front of the inside of the sweep portion, the upper end is in contact with the side wall and formed to form an inclined surface inclined toward the lower side.
18. The method of claim 17,
The blade plate, the organic waste treatment apparatus, characterized in that the inclination angle is inclined 20 to 45 ° relative to the side wall contacting the upper end.
18. The method of claim 17,
The sweep part may further include a blade pad member extending from a lower end of the blade plate and formed of a material having excellent elasticity to discharge the compressed sludge remaining on the filter part. Device.

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