KR102102879B1 - Waste recycling apparatus using air house with frame anchor - Google Patents

Abstract

The present invention relates to a synthetic resin waste recycling device using an air house with a frame fixing anchor, capable of firmly fixing a plurality of frames to the ground, the frame being installed in a tunnel form to form a frame of an air house. The device comprises: a frame (1) which is installed on the bare ground and is spaced apart at regular intervals to form a tunnel; a house member (2) which is fixed while covering the frames (1) and maintains its shape by the air filled in the inside; an anchor member (10) which is installed at an end part of the frame (1), has a cylindrical shape with a coupling hole (11) therein into which the frame (1) is inserted to be fixed on the ground, and is provided with an extension part (12) bent to protrude in the outer direction at a lower end part thereof; a frame fixing member (20) which has a tube shape to cover an upper part of the anchor member (10) and has a frame insertion hole (21) with a guide hole to which the frame (1) is inserted protruding at an upper end thereof and a plurality of fixing protrusions (22) protruding along the circumference of a lower outer circumferential surface; a synthetic resin disposal unit (70) which is provided in an indoor space formed by the house member (2) to dispose of the synthetic resin waste (a); and a wastewater purification tank (80) which collects and purifies leachate from the synthetic resin waste (a) of the synthetic resin waste disposal unit (70).

Description

Waste recycling apparatus using air house with frame anchor

The present invention relates to a synthetic resin waste recycling device using an air house having a frame fixing anchor, specifically, a frame fixing anchor capable of firmly fixing a plurality of frames installed in a tunnel form to form a frame of the air house. It has a synthetic resin waste recycling device using the air house.

In general, the air howl is the sun while blocking the gas or fine dust from the outside while the plastic filled with air forms the dome or tunnel form to the upper part of the frame installed on the ground to grow vegetables or to grow tropical plants. It has a greenhouse effect through which light is transmitted.

In order to install and use the above air house, the frame forming the frame must first be firmly installed on the ground. Conventionally, a fixed anchor connected to the end of the frame has been provided for the installation of the frame forming the frame.

For example, as in the literature below, a conventional air house is installed on the top of the ground to block external gas or fine dust.

In a conventional air house installation process, a process of inserting a frame into the ground and fixing it is common.

However, when an external factor such as wind pressure or snow pressure is applied to the air house, the frame installed on the ground is easily separated from the ground.

Republic of Korea Registered Patent Registration No. 10-1455166 (2014.10.21.)

The present invention has been devised to solve the above-mentioned problems, and the object of the present invention relates to a device for recycling synthetic resin waste using an air house having a frame anchor, and is specifically installed in a tunnel form to form a skeleton of an air house. An object of the present invention is to provide a synthetic resin waste recycling device using an air house having a frame anchor that can firmly fix a plurality of frames to the ground.

Characteristic configuration of the synthetic resin waste recycling apparatus using an air house having a frame anchor according to the present invention for achieving the purpose, is installed spaced at regular intervals on the road, forming a tunnel form, and fixed while surrounding the frame The house member that maintains its shape by the air filled in the inside, and the coupling hole into which the frame is inserted to be fixed to the ground by being installed at the end of the frame form a cylindrical shape, and at the bottom, bend to protrude outward An anchor member provided with an extended part to be formed, and a frame insert having a guide hole through which a frame is inserted is projected at an upper end in a tube shape surrounding the upper part of the anchor member, and a frame fixing member protruding along a circumference of the lower outer circumference Wow, provided in the indoor space formed by the house member It may be composed of a synthetic resin waste processing unit for processing synthetic resin waste, and a waste water purification tank for collecting and purifying the leachate leached from the synthetic resin waste processing unit.

Preferably, the anchor member is formed with a plurality of fastening holes to which the fastening bolt is coupled to the upper surface, the frame fixing member is formed with a plurality of through holes corresponding to the fastening hole on the upper surface, the fastening to secure the frame to be coupled around the outer peripheral surface of the frame insert A plurality of fixing holes to which the bolt is selectively coupled may be formed and configured.

Preferably, the fixing protrusion is formed of a flexible material, and when coupled between the anchor member and the frame fixing member, it may be configured to be bent to branch along the extension portion and fixed to the ground.

Preferably, the frame fixing member is provided so that a pair of connecting projections are opposed along the longitudinal circumference, and the connecting projection is further provided with a tubular connection pipe detachably, and the connecting projections are formed with a plurality of connecting holes, The pipe is formed with a connection hole corresponding to the coupling hole, and can be firmly coupled to each other through a coupling hole and a fastening bolt passing through the connection hole.

Preferably, the connecting pipe is installed to connect a frame fixing member installed on a plurality of predetermined parts of the ground, the connecting pipe is formed to be bent in the longitudinal direction, and fixed ends are provided with fastening pins connected to both ends. A reinforcement member fixed to the ground to surround the upper portion of the pipe may be further installed and configured.

Preferably, a plurality of installation grooves are further formed in the longitudinal direction of the frame fixing member, and a fixing ring may be further coupled to the installation groove.

Preferably, according to the present invention, a transfer device for automatically transporting synthetic resin waste is installed inside the house member, and synthetic resin waste utilization means capable of burning and generating synthetic resin waste transported by the transport device can be installed. have.

Preferably, the transfer device is provided with a storage tank that temporarily stores synthetic resin waste that has been transferred to the interior of the house member, and on one side of the storage tank is installed a first conveyor that can transport synthetic resin waste stored in the storage tank. , On one side of the first conveyor, a separating means for separating foreign substances from the synthetic resin waste is installed, and on one side of the separating means, a second conveyor for transferring the selected synthetic resin waste is installed, and on one side of the second conveyor, from the synthetic resin waste. A dewatering means for separating moisture is installed, and a third conveyor for transferring dehydrated synthetic resin waste is installed at one side of the dewatering means, and a crushing means for crushing dehydrated synthetic resin waste is installed at one side of the third conveyor. Crushed synthetic resin on one side of the crushing means A fourth conveyer for transporting objects is installed, and a drying means for drying synthetic resin waste is installed on one side of the fourth conveyor, and on one side of the drying means, the dried synthetic resin waste is transferred to the synthetic resin waste utilization means. 5 Conveyors can be installed.

Preferably, the synthetic resin waste utilization means includes a combustion unit in which the dried synthetic resin waste is burned, a circulation unit for circulating water to the combustion unit so that water is heated by heat generated in the combustion unit to generate steam, and is heated while being circulated in the circulation unit. A turbine rotated by steam generated from water, a generator generating electric energy using rotation of the turbine, a heat exchange unit heat exchanged by steam rotating the turbine, and water liquefied from steam by the heat exchange unit It may include a supply unit to supply as a wealth.

Preferably, the circulation unit is installed in a state surrounding the combustion unit, the circulation pipe through which water to be flowed is heated, a steam drum in which steam generated from water flowing through the state connected to the circulation pipe is collected, and a turbine to steam in the state connected to the steam drum It may include a steam supply pipe supplied to the.

The present invention as described above can obtain the following effects.

First, the frame forming the frame of the air house can be easily fixed to the ground without a complicated configuration.

In addition, it is possible to increase the coupling force between the ground and the frame through the configuration of the frame fixing member to which the frame is coupled without having a separate configuration capable of fixing the fixing anchor to the ground unnecessarily.

In addition, the size and size of each component are unnecessarily increased in order to increase the bonding force between the frame and the ground, and it is possible to reduce the overall production cost for the production of fixed anchors by preventing a complicated configuration.

In addition, even if any one component constituting the fixed anchor is damaged, the original function of the fixed anchor can be maintained, and the damaged area can be easily replaced and stable use can be achieved.

In addition, a synthetic resin waste purification device is installed inside the air house where a certain space is secured to purify and discharge the leachate generated from the synthetic resin waste, and the synthetic resin waste can be dried and fermented for recycling.

In addition, it is possible to reduce the synthetic resin waste to a raw material that is a renewable energy by selectively extruding and thermally decomposing synthetic waste in a state in which external contaminated gas or air is blocked.

In addition, there is an advantage that can be used for power generation and heating by using the heat generated in the process of burning synthetic resin waste.

1 is a perspective view showing a synthetic resin waste recycling apparatus using an air house having a frame anchor of the present invention.
Figure 2 is a side view showing the appearance of the present invention.
Figure 3 is a schematic diagram of a synthetic resin waste recycling apparatus using an air house having a fixed anchor of the present inventors.
Figure 4 is a cross-sectional view of a synthetic resin waste recycling apparatus using an air house having a fixed anchor of the present inventors.
Figure 5 is a cross-sectional view showing a combined state of the synthetic resin waste recycling apparatus using an air house having a frame anchor anchor inventors.
Figure 6 is a cross-sectional view showing a state of use of the synthetic resin waste recycling apparatus using an air house having a fixed anchor of the present inventors.
7 is a cross-sectional view showing a connection pipe of a synthetic resin waste recycling apparatus using an air house having a fixed anchor of the present inventors.
8 is a cross-sectional view of the use state of FIG. 7.
Figure 9 is a cross-sectional view showing another embodiment of a synthetic resin waste recycling apparatus using an air house having a fixed anchor of the present inventors.
10 is a state diagram showing a state in which the air house frame is installed on the ground through a fixed anchor according to the present invention.
Figure 11 is a schematic diagram showing the fastening process of the connection pipe according to the present invention.
12 is a state diagram showing a state in which the air house frame is installed on the ground through a connection pipe according to the present invention.
13 is a view showing a synthetic resin waste treatment unit to which the air house of the present invention is applied.
Figure 14 is a view showing the perforated tube of the blind rock.
15 is a view showing a wastewater purification tank installed on one side of the treatment unit.
16 is a view showing an air house and a synthetic resin waste treatment device installed on the ground.
17 is a view showing a state in which a synthetic resin waste transport device and a waste utilization means are installed inside the air house.

The terms or words used in the specification and claims are not to be construed as being limited to a conventional or lexical meaning, but the inventors may properly define the concept of terms in order to best describe their own invention in the best way. It can be interpreted as meaning and concept in accordance with the technical idea of the present invention based on the principle of 'can be.'

In addition, the configuration shown in the embodiments and drawings described in this specification is only a preferred embodiment of the present invention, and does not represent all of the technical spirit of the present invention, and can replace them at the time of this application. It should be understood that there may be various equivalents and variations.

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

The present invention, as shown in Figures 1 to 4 is installed spaced at regular intervals on the road to form a tunnel (1) and the frame (1) while being fixed in a state surrounding the frame by the air filled therein The house member (2) maintaining the shape, the air supply means (3) for supplying air so that the shape of the house member (2) is maintained, and the frame (1) installed at the end of the frame (1) for fixing to the ground ) Is inserted into the coupling hole 11 is formed in the shape of a cylinder formed on the inside, the lower end of the anchor member 10 and the anchor member 10 is provided with an extension 12 is bent to protrude in the outer direction, The frame fixing member 20 having a tube shape enclosing the upper portion and having a guide hole through which the frame 1 is inserted is protruded, and a plurality of fixing protrusions 22 are protruded along the circumference of the lower outer circumference. Wow, mold by house member (2) It includes a synthetic resin waste treatment unit 70 disposed in the interior space to process the synthetic resin waste (a), and a waste water purification tank 80 for collecting and purifying the leachate leached from the synthetic resin waste (a) of the synthetic resin waste processing unit 70. .

The frame 1 is configured to be installed in a plurality on the ground G, as shown in FIGS. 10 and 12 shown to form the frame of the air house.

The house member 2 is formed to be convex upward while being located on the upper portion of the lower vinyl 2a and the lower vinyl 2a, which is convex to the upper portion, and is fixed and integrated around the lower vinyl 2a. It is formed in communication between the upper vinyl (2b), the lower vinyl (2a) and the upper vinyl (2b) to guide the air supplied from the air supply means (3) between the lower vinyl (2a) and the upper vinyl (2b) It includes an inlet 2c.

The lower vinyl 2a and the upper vinyl 2b are made of transparent or translucent, so that sunlight can be transmitted therethrough. That is, the air temperature of the indoor space formed by the road surface covered by the house member 2 and the house member 2 may be increased.

When air is injected through the inlet 2c, the house member 2 expands to form a dome or tunnel.

The house member 2 is formed with a double entrance 2d, so that the double entrance 2d is sequentially opened and closed, so that internal air can be prevented from leaking to the outside.

The air supply means 3 may be composed of a fan or a pump that supplies air through the inlet 2c of the house member 2. Since the air supply means 3 periodically or intermittently supplies air, air lost in the house member 2 may be replenished.

In addition, the air supply means 3 is further configured to supply air to the indoor space formed by the house member 2. That is, since the air is supplied to the indoor space of the house member 2 by the air supply means 3, sagging of the house member 2 can be prevented.

The anchor member 10 is formed by forming a coupling hole 11 in its longitudinal direction so that the end of the frame 1 can be inserted, and is formed in a cylindrical shape as in FIGS. 3 to 6.

In addition, the anchor member 10, as shown in Figure 3, is configured by forming an extension 12 that is bent from the top to the bottom in the outer direction.

The extension 12 is formed at the lower end of the anchor member 10, and as shown in FIG. 6, the anchor member 10 inserted into the ground G is exposed to the ground or is easily separated from the ground G Prevent it.

The frame fixing member 20 is formed in a tube shape surrounding the upper portion of the anchor member 10, and is detachably coupled to the upper side of the anchor member 10, as shown in FIGS. 5 and 6, and the upper frame ( 10) A frame insertion hole 21 in which a guide hole into which a guide hole is inserted is formed is protruded.

6, the end of the frame 1 inserted into the guide hole of the frame insertion hole 21 is inserted into the coupling hole 11 of the extension portion 12 coupled with the frame fixing member 20 and the ground It is to be positioned inside the anchor member 10 fixed to.

In addition, the frame fixing member 20 is configured by protruding a plurality of fixing protrusions 22 along the circumference of the lower outer circumferential surface.

3 and 6, the fixing protrusion 22 is formed to protrude to the bottom of the frame fixing member 20, the frame fixing member 20 to the upper portion of the anchor member 10, the anchor, The fixing protrusions 22 are brought into close contact with each other along the upper surface of the extension portion 12 of the member 10, and are configured to achieve a coupling as in FIG. 6.

This configuration, that is, when the frame fixing member 20 is coupled to the upper surface of the anchor member 10, a plurality of fixing protrusions 22 provided at the lower end of the frame fixing member 20, the upper surface of the extension 12 By spreading along and being driven into the ground G, the anchor member 10 and the frame fixing member 20 are firmly coupled, and the anchor member 10 and the frame fixing member 20 are ground (G) ) Is easily prevented from being separated.

At this time, the fixing protrusion 22 is preferably formed of a flexible material, and is preferably formed of a metal material, a plastic material, or the like, which can be bent by external pressure.

In addition, a plurality of fastening holes 13 are formed on the upper surface of the anchor member 10, and a plurality of through holes 23 corresponding to the fastening holes 13 are formed on the upper surface of the frame fixing member 20. .

The fastening holes 13 and the through-holes 23 are mutually sturdy through the fastening bolts P firmly coupling the anchor member 10 and the frame fixing member 20, as shown in FIGS. 5 and 6 shown. To be combined, the user adjusts the coupling of the fastening bolt P fastened to the fastening hole 13 and the through-hole 23, so that the anchor member 10 and the frame fixing member 20 are engaged, and the space between them is combined. It can be adjusted.

In addition, the outer circumferential surface of the frame insert 21 is pressed to the side of the frame 1 coupled inward with a fastening bolt P to make it possible to securely join the frame insert 21 and the frame 1. It is formed by forming a plurality of fixing holes (21a) to which the fastening bolt (P) is coupled.

As shown in FIG. 3, the fixing hole 21a may be configured by a user in advance around the outer circumferential surface of the frame insertion hole 21, but as shown in FIG. 6, the anchor member 10 and the frame fixing member 20 are After being fixedly installed on the ground, a fixing hole 21a may be formed in the frame inserting port 21 so that the frame 1 coupled to the frame inserting port 21 can be firmly supported.

In addition, as shown in FIGS. 3 to 10 and 12, the frame fixing member 20 is configured to be provided with a pair of connecting projections 24 facing along the longitudinal circumference, and the connecting projections 24 include The tubular connection pipe 40 is further installed to be detachable.

In addition, a plurality of coupling holes 24a are formed in the connecting projection 24, and a coupling hole 40a corresponding to the coupling hole 24a is formed in the coupling pipe 40 to form a coupling hole 24a and a coupling hole 40a. ) Through the fastening bolt (P) passing through is firmly coupled to each other.

This configuration, as shown in FIGS. 7, 8, 10, and 12, when a plurality of frame fixing members 20 are installed in a plurality of previously set portions of the ground G, the connecting pipe 40 When constructing the frame of the air house by interconnecting the frame fixing members 20, which are installed through the configuration of, the combination of the anchor member 10 and the frame fixing member 20 is made more firmly and through this, the installation is easy. The constructed air house frame can be firmly installed on the ground (G).

In addition, the connecting pipe 40 is formed to be bent in the longitudinal center, and fixed ends 50a are provided at both ends with fastening pins 60 to be fixed to the ground to surround the upper portion of the connecting pipe 40. The reinforcement member 50 is further installed and configured.

8, 11, and 12, the reinforcing member 50 is provided with a plurality of frame fixing members 20 at a plurality of predetermined portions of the ground G, and through the connecting pipe 40 When configured to be interconnected, it is installed to surround the upper portion of the connection pipe 40 and then is firmly installed on the ground through the configuration of the fixing pin 60 provided.

This is, even when connecting the plurality of frame fixing members 20 by connecting the connection pipe 40, the connection of the connection pipe 40 and the frame fixing member 20 is made more firmly to firmly fix the installed air house frame. Is to do.

To explain this configuration in more detail, the reinforcing member 50 is installed to surround the upper portion of the connecting pipe 40, as shown in (b), (c) in the expanded state as shown in Figure 11 (a). , (d), it is configured by inserting a fixing pin 60 which is inserted into the ground G into the fixing hole 50a of the reinforcing member 50.

Through this, as shown in Figure 12, a plurality of anchor members 10, the frame (1) installed on the ground (G) through the frame fixing member 20, the connection between the lower end of the frame (1) The pipe 40 is formed to be firmly installed on the upper portion of the ground G on which the installation is made.

At this time, in the present invention, the reinforcing member 50 is illustrated and illustrated in a cylindrical shape with fixing holes 50a formed at both ends, but the connection pipe 40 connecting the frame fixing member 20 is firmly installed. If it is a sustainable configuration, the shape and configuration of the reinforcing member 50 can be applied in various ways.

Meanwhile, as illustrated in FIG. 9, in another embodiment of the present invention, a plurality of installation grooves 20a are further formed in the longitudinal direction of the frame fixing member 20, and a fixing ring ( 30) is further combined.

As shown in Figure 9, the fixing ring 30 is coupled to the installation groove 20a to form pressure in the direction of the anchor member 10 from the outside of the frame fixing member 20, thereby fixing the anchor member 10 and the frame. It is possible to further increase the bonding force of the member 20, and it is desirable to form a metal material of a solid material or a synthetic resin material having elasticity.

As described above, the present invention can conveniently and quickly install the frame (1) installed to install the air house on the ground (G), and after the installation of the frame (1) is easily separated from the ground (G) Can be prevented.

13 to 17, the inner area of the house member 2 may be usually in the range of 330 m 2 to 3,000 m 2.

Further, inside the house member 2, a plurality of catalyst injection nozzles 4a for mixing are injected into the synthetic resin waste (a) crushed and crushed by the synthetic resin waste treatment unit 70 and placed therein, thereby ducting the duct 4 It is installed, it is preferable that the duct 4 is installed on the ceiling of the house member (2).

As shown in FIG. 13, the synthetic resin waste treatment unit 70 is formed in the house member 2 and is disposed in an indoor space where external air inflow and internal air loss are blocked to process the synthetic resin waste (a).

The synthetic resin waste treatment unit 70 includes a blind rock 71 under the synthetic resin waste (a). In the blind rocker 71, a capillary yarn 72 for filtering leachate from synthetic resin waste (a) is installed, and a capillary network 73 through which only the leachate passes while supporting the capillary yarn is installed under the capillary yarn 72 , Mat 74 is installed in the lower portion of the capillary network 73 to pass the leachate while filtering the fine synthetic resin waste (a), and the capillary force passing only the leachate while supporting the mat 74 in the lower portion of the mat 74 (75) is installed, the lower portion of the capillary force (75) is installed a perforated pipe (76) for collecting the leachate that has passed through the capillary force (75) and transporting it to the wastewater purification tank, and an impermeable membrane (at the bottom of the perforated pipe (76)) 77) is installed so that the leachate does not penetrate underground, and one end of the perforated pipe 76 passes through the impermeable membrane 77 and is connected to the wastewater purification tank 80.

The blind rocker 71 is very useful for purifying contaminants generated from contaminated synthetic resins. In particular, the synthetic resin wastes (a) can be recycled by removing contaminated components during the process in which the synthetic wastes (a) are crushed and crushed and transported. You can.

The synthetic resin waste treatment unit 70 in which the blind rocker 71 is installed will continuously agitate the synthetic resin waste (a) placed using the stirrer 78.

At this time, it is preferable that a moisturizing agent is further added to the synthetic resin waste (a) to be stirred, and as a moisturizing agent, any one of rice husk, sawdust, and beetroot or a mixture thereof may be used.

It is preferable to use steel sand for the capillary yarn 72, a non-woven fabric for the mat 74, and a cape gravel or fine stone for the capillary force 75.

The impermeable membrane 77 has the advantage that it is strong in water resistance and easy to move when the concrete is poured into the concrete so that the leachate is not lost while the structure is strengthened, and a waterproofing material is applied to the concrete or a material made of synthetic resin is used.

As shown in FIG. 14, a plurality of perforated pipes 76 are installed to be connected to the water collecting well 5 to be spaced apart at regular intervals, so that the collected leachate is collected in the water collecting well 5.

At the rear of the shredded and pulverized synthetic resin waste treatment unit 70, a water collecting well 5 is installed, and the leachate collected through the blind rocker 71 is collected in the water collecting well 5, and the collected leachate is collected (5). ) Is transferred to the wastewater purification tank 80 by the submersible pump 51 provided inside.

15, the wastewater purification tank 80 collects and purifies the leachate leached from the synthetic resin waste (a) of the synthetic resin waste treatment unit 70.

The wastewater purification tank 80 is provided with a sedimentation separation tank 81 for leaching the introduced wastewater, and a batch treatment tank 82 for repeatedly aeration and sedimentation of the leachate is provided at one side of the sedimentation separation tank 81. , One side of the batch treatment tank 82 is provided with a final settling tank 83 in which the leachate treated in the batch treatment tank 82 is precipitated and sludge generated is collected.

In the batch processing tank 82, a diffuser 85 for supplying air by a blower 84 is installed, and in the final sedimentation tank 83, a pump 86 for returning sludge and nitric acid bacteria to the sedimentation separation tank 81 again ) Is installed, and the conveying pipe 87 is connected to the pump 86.

As another embodiment of the present invention, as shown in Figure 16, the synthetic resin waste treatment unit 70 can be installed and used on the ground when it is difficult to install underground inside the house member 2, the wastewater purification tank 80 Can be installed outside the house member 2 on the ground. The synthetic resin waste treatment unit 70 may be used by installing a retaining wall 89 using concrete or synthetic resin material to prevent loss of leachate.

Another embodiment of the present invention, as shown in Figure 17, the interior of the house member 2 is provided with a transfer device 90 for automatically transporting the synthetic resin waste (a), the transfer device 90 The synthetic resin waste utilization means 100 capable of generating and heating the synthetic resin waste (a) transferred by the combustion is installed.

The transfer device 90 is provided with a storage tank 91 in which synthetic resin waste (a), which has been transferred to the interior of the house member 2 by a vehicle, is temporarily stored, and on one side of the storage tank 91, a storage tank ( 91) is provided with a first conveyor (9a) capable of transporting the synthetic resin waste (a), and one side of the first conveyor (9a) has a sorting means (92) for sorting foreign matter from the synthetic resin waste (a) Installed.

One side of the sorting means 92 is provided with a second conveyor (9b) for transferring the selected synthetic resin waste (a), and on one side of the second conveyor (9b) is dehydration means for separating the moisture from the synthetic resin waste (a) (93) is installed, one side of the dehydration means (93) is provided with a third conveyor (9c) for transporting the dehydrated synthetic resin waste (a), and the dehydrated synthetic resin waste on one side of the third conveyor (9c) A crushing means 94 capable of crushing and crushing (a) is provided. The crushing means 94 may be composed of a screw device.

On one side of the shredding means 94, a fourth conveyor 9d for transferring the shredded synthetic resin waste (a) is installed, and on one side of the fourth conveyor 9d, drying means for drying the synthetic resin waste (a). (95) is installed, and one side of the drying means (95) is provided with a fifth conveyor (9e) for transporting the dried synthetic resin waste (a) to the synthetic resin waste utilization means (100).

The synthetic resin waste utilization means 100 is a combustion unit 110 in which the dried synthetic resin waste (a) is burned, and water is heated by heat generated from the combustion unit 110 so that water is heated to generate steam, so that the combustion unit 110 Circulation unit 120 for circulating to, a turbine 130 rotated by steam generated from water heated while being circulated in the circulation unit 120, and a generator that generates electric energy using rotation of the turbine 130 140, a heat exchange unit 150 for heat exchange by the steam rotated turbine 130, and a supply unit 160 for supplying water liquefied in the steam by the heat exchange unit 150 to the circulation unit 120 Includes.

In the combustion unit 110, the inlet through which the synthetic resin waste (a) supplied by the fifth conveyor 9e flows is formed in communication with the combustion space, and an air pump for supplying external air to the combustion space is connected, High heat may be generated as the synthetic resin waste (a) flowing into the combustion space through the inlet is burned. That is, since the synthetic resin waste (a) is supplied as a raw material of the combustion unit 110, there is an advantage in that the synthetic resin waste can be treated, and there is also an advantage of not having to separately supply fuel. Then, the ash generated as the synthetic resin waste (a) is burned can be discharged through the lower portion of the combustion unit 110 to be treated.

The circulation unit 120 is installed in a state surrounding the combustion unit 110, and the circulation pipe 121 in which the water flowing therethrough is heated, and the steam generated from the water flowing through the water connected to the circulation pipe 121 is collected. It includes a drum 122 and a steam supply pipe 123 that supplies steam to the turbine 130 while being connected to the steam drum 122.

The circulation pipe 121 surrounds the combustion unit 110 so that water flowing through the high temperature of the combustion unit 110 is rapidly heated to generate steam.

The steam drum 122 is located at the upper portion of the combustion unit 110 so that the steam collected by the high temperature of the combustion unit 110 can be amplified at high pressure.

Steam may be supplied to the turbine 130 through the steam supply pipe 123.

The turbine 130 may be rotated at high speed by hot steam.

The generator 140 may generate electric energy by the rotational force of the turbine 130 rotating at high speed.

The electric energy generated by the generator 140 may be supplied to the outside through a transmission line network.

The heat exchanger 150 is thermally bridged using steam used in the turbine 130 and heat obtained according to heat exchange can be used for district heating.

The supply unit 160 may be configured as a pump that supplies liquefied water from the heat exchange unit 150 to the circulation unit 120.

Therefore, there is an advantage that can be treated by burning the synthetic resin waste (a), there is an advantage that can be utilized as a recycled raw material for power generation and district heating by the combustion of the synthetic resin waste (a).

Hereinafter, the use of the present invention is as follows.

First, as shown in FIGS. 13 to 16, when the synthetic resin waste (a) is transferred to the synthetic resin waste treatment unit 70 and placed therein, the parent thread of the blind rocker 2 provided in the synthetic resin waste treatment unit 70 ( 72), the mat 74 and the leachate generated from the synthetic resin waste (a) by the capillary force 75 are collected in the lower portion of the synthetic resin waste treatment unit 70.

At this time, the leachate collected by the plurality of perforated pipes 76 installed at the lower portion of the synthetic resin waste treatment unit 70 is collected by the collecting well 5 provided on one side of the synthetic resin waste treatment unit 70, and this collecting well 5 The collected leachate is transferred to the wastewater purification tank 80 by the submersible pump 51.

A catalyst for combusting is introduced to treat the synthetic resin waste (a) processed in the blind rocker 71.

The leachate transferred to the wastewater purification tank 80 first enters the sedimentation separation tank 81 and precipitates sludge mixed with the leachate, and this leachate is again installed in one side of the sedimentation separation tank 81 (82) ), The leachate is repeatedly aerated and precipitated by the diffuser (85) installed at the bottom, and the leachate that has passed through the batch treatment tank (82) is introduced into the final settling tank (83) and the absorption bar formed thereunder ( 88), the excess sludge is collected. At this time, the collected sludge and nitric acid bacteria are returned to the sedimentation separation tank 81 by the pump 86.

The purified water can be recycled by discharging clean water purified by the wastewater purification tank 80 to a general river or supplying the planted soil.

The synthetic resin waste (a) through which the leachate escapes is mixed with a catalyst for mixing, which is sprayed from the catalyst injection nozzle (4a) for mixing, installed on the upper part of the house member (2), moisturizing agents such as rice husk, sawdust, and flanks, and then added to the stirrer (78). The mixture is dried while stirring, and the dried synthetic resin waste (a) is recycled.

In addition, the use of the present invention according to another embodiment is as follows.

First, as shown in FIG. 17, the synthetic resin waste (a) is transferred by the transfer device 90 installed inside the house member 2, and the transferred synthetic resin waste (a) is synthetic resin waste utilization means 100 Is stacked on.

The transfer process of the transfer device 90 is performed as follows. First, the synthetic resin waste (a) transported to the storage tank 91 installed at one side of the entrance 2d of the house member 2 is temporarily stored, and the stored synthetic resin waste (a) is next by the first conveyor 9a. It is transferred to the process.

The synthetic resin waste (a) transferred by the first conveyor (9a) is supplied to the sorting means (92) to remove foreign substances and the like, and the synthetic resin waste (a) from which the foreign substances are removed is processed by the second conveyor (9b). Is transferred to.

The synthetic resin waste (a) transferred by the second conveyor (9b) is dehydrated by the dehydration means (93), and the synthetic resin waste (a) from which the moisture is dehydrated is transferred to the next process by the third conveyor (9c). do.

The synthetic resin waste (a) transferred by the third conveyor (9c) is crushed and crushed into regular particles by the crushing means (94), and the crushed and crushed synthetic resin waste (a) is next by the fourth conveyor (9d). It is transferred to the process.

The synthetic resin waste (a) transferred by the fourth conveyor (9d) is dried with an extra moisture by the drying means (95), and the dried synthetic resin waste (a) is the synthetic resin waste utilization means by the fifth conveyor (9e). (100).

The synthetic resin waste utilization means 100 combusts the synthetic resin waste (a) that is crushed and transported in a dried state.

Then, the synthetic resin waste (a) boils water using the heat generated during combustion and generates electricity using steam generated in the process of boiling water to generate electrical energy, and heats the steam used for power generation to heat it. .

Although the preferred embodiments of the present invention have been described in detail above, a person having ordinary knowledge in the technical field to which the present invention pertains, various modifications or design changes to the present invention without departing from the scope of the claims If it does, it is considered as the scope of the present invention.

Although the present invention has been illustrated and described in connection with specific embodiments, it is understood in the art that the present invention may be variously modified and modified within the limits not departing from the spirit or scope of the present invention provided by the following claims. It will be obvious to those of ordinary skill.

a: Synthetic resin waste 1: Frame
2: House member 2a: Lower vinyl
2b: upper vinyl 2c: inlet
2d: Entrance 3: Air supply
4: Duct 4a: Catalyst injection nozzle for mixing
10: anchor member
11: Joiner 12: Extension
13: fastening hole 20: frame fixing member
20a: Installation groove 21: Frame insert
21a: Fixed hole 22: Fixed projection
23: through hole 24: connecting projection
24a: coupling hole 30: retaining ring
40: connecting pipe 40a: connecting hole
50: reinforcement member 50a: fixing hole
60: fixing pin G: ground
P: Fastening bolt N: Nut
70: synthetic resin waste treatment unit
71: Maengamgeo 72: Mogwansa
73: capillary network 74: mat
75: capillary force 76: perforated tube
77: impermeable membrane 78: agitator
80: wastewater purification tank 81: sedimentation separation tank
82: batch processing tank 83: final settling tank
84: blower 85: diffuser
86: pump 87: return pipe
90: transfer device 91: storage tank
92: screening means 93: dehydration means
94: crushing means 95: drying means
9a: 1st conveyor 9b: 2nd conveyor
9c: 3rd conveyor 9d: 4th conveyor
9e: 5th conveyor
100: synthetic resin waste utilization means
110: combustion unit 120: circulation unit
121: circulation pipe 122: steam drum
123: steam supply pipe 130: turbine
140: generator 150: heat exchanger
160: supply unit

Claims (12)

A frame (1) that is installed spaced apart at regular intervals to form a tunnel, and
A house member (2) that maintains its shape by air filled therein while being fixed in a state surrounding the frames (1),
It is installed at the end of the frame (1), the coupling hole (11) into which the frame (1) is inserted for fixing to the ground forms a cylindrical shape formed inside, and an extension (12) is bent to protrude in the outer direction at the bottom. ) Is provided with an anchor member 10,
A frame insert 21 having a guide hole through which the frame 1 is inserted is projected at the top of the tube shape surrounding the upper part of the anchor member 10, and a plurality of fixing protrusions 22 are formed along the periphery of the lower outer circumferential surface. Frame fixing member 20,
A synthetic resin waste treatment unit 70 disposed in the indoor space formed by the house member 2 to process the synthetic resin waste (a);
It includes a waste water purification tank 80 for collecting and purifying the leachate leached from the synthetic resin waste (a) of the synthetic resin waste treatment unit 70,
The house member 2 is formed to be convex upward while being located on the upper portion of the lower vinyl 2a and the lower vinyl 2a, which is convex to the upper portion, and is fixed and integrated around the lower vinyl 2a. It is formed in communication between the upper vinyl (2b), the lower vinyl (2a) and the upper vinyl (2b) to guide the air supplied from the air supply means (3) between the lower vinyl (2a) and the upper vinyl (2b) It includes an inlet (2c),
When air is injected through the inlet 2c, the house member 2 expands to form a dome or tunnel,
The anchor member 10 is formed with a plurality of fastening holes 13 to which fastening bolts P are coupled to the upper surface,
The frame fixing member 20
A plurality of through holes 23 corresponding to the fastening holes 13 are formed on the upper surface,
A plurality of fixing holes (21a) to which the fastening bolt (P) for fixing the frame (1) to be coupled is selectively coupled is formed around the outer circumferential surface of the frame insert (21),
The fixing protrusion 22 is formed of a flexible material, and when coupled between the anchor member 10 and the frame fixing member 20, is bent to be branched along the extension portion 12 and fixed to the ground G,
The frame fixing member 20 is provided with a pair of connecting projections 24 facing each other along the longitudinal circumference,
The connection protrusion 24 is provided with a tubular connection pipe 40 detachably.
The connecting projection 24 is formed with a plurality of coupling holes (24a), the connection pipe 40 is formed with a coupling hole (40a) corresponding to the coupling hole (24a) and the coupling hole (24a) and the coupling hole (40a) Through the fastening bolt (P) penetrating each other is firmly coupled to each other,
The connecting pipe 40 is installed to connect the frame fixing member 20 which is installed in a plurality of parts already set on the ground,
The connection pipe 40 is formed to be bent in the longitudinal center, and at both ends there is a fixing hole 50a to which a fixing pin 60 is fastened, and a reinforcing member fixed to the ground to surround the upper portion of the connection pipe 40 50 is installed,
A plurality of installation grooves 20a are formed in the longitudinal direction of the frame fixing member 20,
A fixing ring 30 is coupled to the installation groove 20a to increase the bonding force between the anchor member 10 and the frame fixing member 20,
The synthetic resin waste treatment unit 70 includes a blind rock 71 under the synthetic resin waste (a),
Blind rock (71)
A capillary yarn (72) is installed to filter out the leachate from the synthetic resin waste (a),
A capillary network 73 through which only leachate passes is installed while supporting the capillary yarn at the bottom of the capillary yarn 72,
A mat 74 for passing the leachate while filtering the fine synthetic resin waste (a) is installed under the capillary network 73,
The lower portion of the mat 74 is provided with a capillary force 75 that passes only the leachate while supporting the mat 74,
A perforated pipe 76 for collecting the leachate that has passed through the capillary force 75 and transferring it to the wastewater purification tank is installed under the capillary force 75,
The impermeable membrane 77 is installed at the lower portion of the perforated pipe 76 so that the leachate does not penetrate underground, and one end of the perforated pipe 76 passes through the impermeable membrane 77 and is connected to the wastewater purification tank 80,
Wastewater purification tank (80)
A sedimentation separating tank 81 for leaching the inflowing wastewater is provided,
One side of the sedimentation separation tank 81 is provided with a batch processing tank 82 for repeatedly aeration and sedimentation of leachate,
One side of the batch treatment tank 82 is provided with a final settling tank 83 in which leachate treated in the batch treatment tank 82 is precipitated and sludge generated is collected.
The batch processing tank 82 is provided with a diffuser 85 for supplying air by a blower 84,
A pump 86 is installed in the final sedimentation tank 83 to return sludge and nitric acid bacteria to the sedimentation separation tank 81 again.
A conveying pipe 87 is connected to the pump 86,
A transfer device 90 for automatically transporting synthetic resin waste (a) is installed inside the house member (2),
Synthetic resin waste utilization means 100 capable of burning and generating and heating synthetic resin waste (a) transferred by the transfer device 90 is installed,
The transfer device 90
A storage tank 91 for temporarily storing the synthetic resin waste (a) transferred to the interior of the house member 2 is installed,
A first conveyor 9a capable of transferring the synthetic resin waste (a) stored in the storage tank 91 is installed at one side of the storage tank 91,
A screening means 92 for separating foreign substances from the synthetic resin waste (a) is installed on one side of the first conveyor (9a),
A second conveyor (9b) for transferring the selected synthetic resin waste (a) is installed on one side of the sorting means (92),
On one side of the second conveyor (9b) is provided with a dehydration means (93) for separating moisture from the synthetic resin waste (a),
On one side of the dewatering means 93, a third conveyor 9c for transferring the dehydrated synthetic resin waste (a) is installed,
A crushing means 94 capable of crushing dehydrated synthetic resin waste a is installed at one side of the third conveyor 9c,
On one side of the shredding means 94, a fourth conveyor 9d is installed to transport the shredded synthetic waste (a),
A drying means 95 for drying the synthetic resin waste (a) is installed at one side of the fourth conveyor 9d,
A fifth conveyor 9e is installed on one side of the drying means 95 to transfer the dried synthetic resin waste (a) to the synthetic resin waste utilization means 100,
Synthetic resin waste utilization means (100)
Combustion unit 110 in which the dried synthetic resin waste (a) is burned,
A circulation unit 120 for circulating water to the combustion unit 110 so that water is heated by heat generated by the combustion unit 110 to generate steam, and
Turbine 130 rotated by steam generated from water heated while being circulated in the circulation unit 120,
Generator 140 for generating electrical energy using the rotation of the turbine 130,
The heat exchange unit 150 heat-exchanged by the steam that rotates the turbine 130,
It includes a supply unit 160 for supplying water liquefied in the steam by the heat exchange unit 150 to the circulation unit 120,
The circulation unit 120
Circulating pipe 121 is installed in a state surrounding the combustion unit 110 is heated to flow through,
A steam drum (122) in which steam generated from water flowing through while connected to the circulation pipe (121) is collected,
Synthetic resin waste recycling apparatus using an air house having a frame anchor, characterized in that it comprises a steam supply pipe (123) for supplying steam to the turbine 130 while connected to the steam drum (122).
delete delete delete delete delete delete delete delete delete delete delete

Images