KR101049235B1 - Apparatus for waste recycling - Google Patents

Abstract

PURPOSE: An apparatus for recycling wastes is provided to improve the recycling efficiency of irons materials by collecting the iron materials after small sized wastes are separated using a cylindrical mesh net. CONSTITUTION: A first hopper(10), a vibration generating unit, a first magnet sorting part(30), a first collecting container(40), and a second hopper(50) are prepared. The first hopper introduces wastes. The vibration generating unit is in connection with a spring(22). The first magnet sorting part sorts iron materials contained in the wastes. The first collecting container collects the sorted iron materials. The second hopper introduces small sized wastes.

Description

Apparatus for waste recycling

The present invention relates to a device for waste recycling that allows to separate and recycle the iron contained in the waste, more specifically, to improve the efficiency by separating the iron contained in the waste through two processes, the flat body portion Vibration generating means and high-tension springs formed on the surface prevents waste from being caught in the mesh network when separating small particles of waste, thereby improving work efficiency and operator convenience. It is possible to easily select only the iron included to improve the recycling efficiency of the steel, as well as the length of the first and second magnet conveyor belt of the first and second magnet sorting portion is formed larger than the width of the conveyor belt, 2 The length of the magnet is shorter than the length of the first and second magnet conveyor belt and formed longer than the width of the conveyor belt to The present invention relates to an apparatus for waste recycling to improve removal rates.

In general, industrial waste treatment methods include incineration and landfill methods, and incineration methods incur a lot of pollutants such as dioxins, causing serious problems to natural and residential environments around incinerators. It is not easy to secure and there is also a problem that damages the environment, such as soil pollution.

Therefore, it is best to minimize the industrial waste by efficiently using resources at each industrial site and to recycle the industrial waste that is inevitably generated at the industrial site or at home. We have devised a recycling system that forms various industrial wastes generated at industrial sites into a recycled molded body that can be recycled by a fully automatic system (Registration Utility Model No. 20-0409103).

The following is a list of some examples of the recycling method of steel waste, in which various research and efforts are being made along with the industrial waste.

In Korean Patent Publication No. 10-0162016, the collected dry dust and wet sludge are mixed in a mixer, and the moisture content is dried in a drying burner, and the cooling and size are selected in a rotary cooler, crushed in a hammer crusher, and reselected in a vibrating screen. In addition, iron, molasses, and lime are mixed in a mixer through a series of processes such as silo, iron storage, scale hopper, and compression molding into briquettes in a briquetting device to select and reshape the size on a vibrating screen to produce briquettes. A converter coolant (briquette) manufacturing apparatus using steel waste is disclosed.

In Korean Patent Publication No. 10-0645082, the slag crushed in a pulverizer is crushed and blended, and after constant compression molding in a molding machine, the molded product is reduced by input of a reducing agent in a high temperature reduction furnace of more than 1200 degrees Celsius, and then used as a product of recycled products after air cooling. Disclosed is an industrial waste recycling method and a molding apparatus for use in which industrial waste is processed so as to be manufactured and recycled.

Korean Patent Laid-Open Publication No. 10-2000-0037285 contains more than 60% of iron in steelmaking slag, and grains of 8mm or more in size are directly used as scrap iron for converters or electric furnaces with scrap, and 60% or more of iron. And fine particles having a particle size of 8mm or less are collected and re-crushed by a rod mill to remove impurities as much as possible, and only magnetic fragments and vibrating screens containing more than 86.5% of iron and having a particle size of 6.5mm or less The molasses and quicklime are mixed with a binder composed of 80 ± 6.5: 20 ± 6.5 to make briquettes through a briquette maker. Is published again on the method of producing briquettes of fine ore in steelmaking slag.

The existing facilities have a problem in that the production line of the recycled molded body is made of a complicated process and process, not only to reduce productivity, but also to reduce the efficiency of the recycled molded product so that the actual use rate is very low.

Waste recycling apparatus of the present invention for solving the above problems and the first hopper for injecting waste; Receiving the waste introduced into the first hopper through a conveyor belt, a planar body hopper including a mesh network made of a first mesh inside, a high-tensile spring formed on the outside of the planar hopper and the plane hopper It is configured to oscillate 15 to 20 times per second to generate small particles to remove small wastes, and to operate with an amplitude of 15 to 30 mm, when there is waste having the same size as the first mesh of the mesh network formed in the planar hopper. A flat body portion formed of vibration generating means configured to not be caught by the first mesh of the mesh network by interlocking with a high tension spring; A first magnet sorting unit for receiving the waste passing through the planar body through a conveyor belt and installed on the conveyor belt to sort only the steel contained in the waste; A first holder for accommodating iron selected through the first magnet sorting unit; A second hopper for injecting waste having small particles removed from the planar body portion; Receiving the waste introduced through the second hopper through a conveyor belt, to form a first cylindrical mesh network made of a second mesh inward, the second formed on the outside of the first cylindrical mesh network, including a third mesh Cylindrical mesh network is composed of a cylindrical mesh network, for sorting the waste small particles while rotating when the waste input; A second magnet sorting unit configured to receive the waste passing through the cylindrical mesh network through a conveyor belt and to be installed on an upper side of the conveyor belt to sort only iron contained in the waste; And a second holder for accommodating the steel sorted through the second magnet sorting part, wherein the first and second magnet sorting parts operate on the first and second magnet conveyor belts operating in a direction perpendicular to the direction in which the conveyor belt moves. And first and second magnets of a ferromagnetic material are formed inside the first and second magnet conveyor belts, and a plurality of first and second bars are configured outside the first and second magnet conveyor belts. The length of the first and second magnet conveyor belts of the two-magnet sorting unit is longer than the width of the conveyor belt, and the length of the first and second magnets is longer than the width of the conveyor belt and shorter than the length of the first and second magnet conveyor belts. The first mesh formed in the mesh network of the planar body part is formed larger than the second mesh formed in the first cylindrical mesh network of the cylindrical mesh network, and the second mesh is formed larger than the third mesh of the second cylindrical mesh network. And that is characterized.

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The device for recycling waste of the present invention can be recycled by improving the efficiency of iron separation by separating the iron contained in the waste in two processes.

In addition, the vibration generated by the vibration generating means included in the planar body portion is formed in a frequency band of high frequency and small amplitude to add a resilient force through a high tension spring while vibrating the planar hopper, a large number of vibrations in a short time with a small amplitude By generating a, the first mesh of the mesh network formed in the planar body part is operated so that waste does not get caught, and the work efficiency and the operator's convenience can be achieved.

In addition, since the waste particles filtered through the planar body part are separated through the cylindrical mesh network twice, the small particles waste is collected and the steel is collected, thereby improving the recycling efficiency of the steel.

In addition, by forming the first and second bars on the first and second magnet conveyor belt of the first and second magnet selection unit, the steel selected by the first and second magnets can be easily stored in the first and second holders. .

In addition, the length of the first and second magnet conveyor belt of the first and second magnet sorting portion is formed larger than the width of the conveyor belt, the length of the first and second magnet is shorter than the length of the first and second magnet conveyor belt, It is a useful invention that can form longer than the width to improve the collection rate of iron.

1 is a block diagram illustrating an apparatus for waste recycling according to the present invention.
2 is a plan view of a portion A of FIG.
Figure 3 is a side view showing the first and second magnet sorting unit according to the present invention.
Figure 4 is an exploded perspective view of the cylindrical mesh exploded according to the present invention.

Hereinafter, the configuration of the present invention with reference to the accompanying drawings in more detail.

First, the first hopper 10 is configured as shown in FIG.

Since the first hopper 10 is a general configuration used in various fields such as waste or food waste in other devices, detailed description thereof will be omitted.

In addition, in the present invention, a conveyor belt (B) for transporting waste in each step is configured.

This conveyor belt (B) is not shown in the drawings, but it is natural that it is driven through a separate motor.

Next, the planar body part 20 is formed to separate wastes with small particles from the wastes received through the conveyor belt B through the wastes introduced through the first hopper 10.

The planar body 20 is waste, in which the planar hopper 21 having the mesh net 21a formed of the first mesh m1 thereon is moved by the conveyor belt B as shown in FIGS. 1 and 2. It is configured to receive and separate small wastes.

In addition, a plurality of high tension springs 22 are provided at both sides of the planar hopper 21, and vibration generating means 23 is configured at one side of the planar hopper 21 to vibrate the planar hopper 21. It is configured to.

The vibration generating means 23 is configured in such a manner that the frequency is high frequency and the amplitude is small so that waste does not get caught in the first mesh m1 of the mesh net 21a formed in the planar hopper 21.

At this time, the first mesh (m1) is preferably configured in a grid pattern size of 13 to 17 mm .

In particular, when the planar body portion 20 separates waste of small size particles through the high tension spring 22 and the vibration generating means 23, it forms an inclination angle of 10 to 12 degrees to move the waste to the next process. It is good to configure the form.

Next, the first magnet sorting unit 30 is configured to separate the iron contained in the waste by receiving the waste separated the waste of small particles through the flat body portion 20 through the conveyor belt (B). .

The first magnet sorting unit 30 is installed at a predetermined interval on the upper side of the conveyor belt (B) as shown in FIG. 3, and may be driven in a direction perpendicular to the direction in which the conveyor belt (B) is driven. A magnet conveyor belt 31 is configured, and a plurality of first bars 32 are formed at an outer side of the first magnet conveyor belt 31, and a first magnet M1 made of a ferromagnetic material is formed at an inside thereof.

Here, the first magnet conveyor belt length (L1) is formed to be longer than the lower conveyor belt width (w), the first magnet length (L3) is formed longer than the conveyor belt width (w), the first magnet It is preferable to form shorter than the conveyor belt (L1).

In addition, it is natural that the driving of the first magnet conveyor belt 31 is made in a separate motor (not shown).

Next, a first holder 50 for storing the iron selected through the first magnet sorting unit 30 is configured.

Next, the second hopper 50 is configured to separate the iron out of the waste of small size particles separated from the planar body 20.

Next, the cylindrical mesh 60 is configured to receive the waste introduced through the second hopper 50 through the conveyor belt (B) to separate the small particles of the waste.

That is, the cylindrical mesh 60 forms a first cylindrical mesh net 61 on the inside and a second cylindrical mesh net 62 on the outside of the first cylindrical mesh net 61.

Here, as shown in FIG. 4, the second mesh m2 constituting the first cylindrical mesh net 61 is formed to have a smaller size than the first mesh m1 formed in the mesh net 21a of the planar body 20. However, to form larger than the third mesh (m3) of the second cylindrical mesh network 62.

Preferably the first cylindrical Of mesh network (51)  2nd Mesh (m2)  9 to 13 mm , Second cylindrical Of mesh network (52)  The third Mesh (m3)  3 to 5 mm It is good to form.

In particular, the cylindrical mesh net 60 may be arranged to form an inclination angle of 7 to 9 ° so that the waste passed through the cylindrical mesh net 60 may be configured to move to the next process.

In addition, the cylindrical mesh network 60 is preferably configured to separate the waste of small particles from the waste injected while the first, second cylindrical mesh network 61, 62 is rotated through a conventional motor (not shown in the figure). Do.

Next, the second magnet sorting unit 70 is configured to receive the waste passed through the cylindrical mesh 60 through the conveyor belt B so as to sort out the iron contained in the waste once again.

The second magnet sorting unit 70 has the same configuration as the first magnet sorting unit 30.

That is, as shown in FIG. 3, the second magnet sorting unit 70 is installed at a predetermined interval on the upper side of the conveyor belt B, and may be driven in a direction perpendicular to the direction in which the conveyor belt B is driven. A second magnet conveyor belt 71 is configured, and a plurality of second bars 72 are formed at the outside of the second magnet conveyor belt 71, and a second magnet M2 is formed at the inside of the ferromagnetic material. have.

Here, the second magnet conveyor belt length (L2) is formed to be longer than the conveyor belt width (w) of the lower side, the second magnet length (L4) is formed longer than the conveyor belt width (w), the second magnet It is preferable to form shorter than the conveyor belt (L2).

In addition, it is obvious that the driving of the second magnet conveyor belt 71 is performed by a separate motor (not shown).

In addition, a second holder 80 for accommodating the iron screened through the second magnet sorting unit 70 is configured.

Looking at the effect of the device for waste recycling of the present invention made of a configuration as described above are as follows.

The present invention is for the operation of separating the iron contained in the waste as described above, the first hopper 10, the planar body portion 20 and the first magnet sorting unit 30 through the iron screening once , The operation of sorting the iron contained in the small waste particles selected by the planar body 20 once again using the second hopper 50, the cylindrical mesh 60 and the second magnet sorting unit 70. It can act to separate the iron through.

In particular, the planar body part 20 in the present invention is a mesh network formed in the planar body hopper 21 by vibration generating means 23 for generating a vibration force in the planar body hopper 21 for storing waste. The first mesh m1 of 21a acts so that waste does not get caught.

That is, the size of the first mesh (m1) of the mesh network 21a is composed of 13 to 17mm, if the waste is the same size as the first mesh (m1) is sandwiched in the first mesh (m1). This is not only a phenomenon that the work rate is lowered due to the phenomenon occurs, the inconvenience that must be removed by the worker one by one.

At this time, the vibration generating means 23 vibrates 15 to 20 times per second, the amplitude of 15 to 30 mm As a result, vibrations are generated in the form of high frequency and small amplitude.

Then, the planar hopper 21 is vibrated in a state where low amplitude is formed many times in a short time to separate wastes having a small particle size, and at the same time, the vibration is not generated smoothly, but the mesh is cut by a momentary force. The first mesh m1 of the net 21a serves to prevent waste.

In particular, high tension springs 22 are formed at both sides of the planar hopper 21 of the planar body 20 according to the present invention, and vibration is generated in the planar hopper 21 through the vibration generating means 23. When the waste is separated, the amplitude is made smaller and the inertia of the instantaneous positional change of the planar hopper 21 acts to prevent the waste from being caught in the first mesh m1 of the mesh network 21a.

Of course, same as above Flat body portion 20  When the waste is separated, it is natural that small particles such as soil are separated.

Meanwhile, in the present invention, the first and second magnet sorting units 30 and 70 may include ferromagnetic first and second magnets M1 and M2 to prevent magnetization of the nonferrous metal component by the metal component during the sorting of iron in the waste. ) Is used.

In particular, first and second bars 32 and 72 are formed on the first and second magnet conveyor belts 31 and 71 of the first and second magnet sorting units 30 and 70 to form first and second magnets M1 and M2. Iron by the magnetic force of the) to prevent the phenomenon to remain in the first and second magnet conveyor belts (31, 71) to act to move smoothly to the first and second holders (40, 80).

In detail, the first and second magnet conveyor belts 31 and 71 rotate continuously, and at the same time, the first and second magnet sorting units 30 and 70 continuously discharge waste through the conveyor belt B. Movement is made.

In this state, steel is attached to the surfaces of the first and second magnet conveyor belts 31 and 71 by the first and second magnets M1 and M2. In this case, the first and second magnet conveyor belts 31, 71. The steel attached to the surface is moved by the first and second magnet conveyor belts 31 and 71 so that the steel is moved by the magnetic force of the first and second magnets M1 and M2. The phenomenon that the iron is going to move in the direction opposite to the driving direction of the 31, 71 occurs, the first, second bars 32, 72 in the present invention is made of the first and second magnets (M1, M2) While forcibly blocking the phenomenon of movement is to act to smoothly move the steel to the first and second holders (40, 80).

Further, in the present invention, the first and second magnet conveyor belt lengths L1 and L3 of the first and second magnet sorting units 30 and 70 are formed longer than the width w of the lower conveyor belt, thereby forming the conveyor belt ( It is configured to facilitate the screening of steel from the waste that passes through B).

In particular, the first and second magnet lengths L2 and L4 coupled to the first and second magnet conveyor belts 31 and 71 of the first and second magnet sorting units 30 and 70 may have a conveyor belt width w. Form longer than, but shorter than the length of the first and second magnet conveyor belt (L1, L3) to be able to sort the steel throughout the waste passing through the conveyor belt (B) to improve the efficiency of the sorting operation will be.

Although the above-described embodiments are described for the most preferred embodiment of the present invention, the present invention is not limited thereto and specifies that the present invention may be modified in various forms without departing from the technical spirit of the present invention.

10: first hopper
B: Conveyor Belt w: Conveyor Belt Width
20: flat body part
21. Planar hopper 21a: Mesh network m1: First mesh 22: High tension spring
23: vibration generating means
30: first magnet sorting unit
31 first magnet conveyor belt 32 first bar M1 first magnet
L1: first magnet conveyor belt length L3: first magnet length
40: first holder
50: second hopper
60: cylindrical mesh
61: first cylindrical mesh network m2: second mesh 62: second cylindrical mesh network
m3: third mesh
70 second magnet sorting unit
71: second magnet conveyor belt 72: second bar M2: second magnet
L2: 2nd magnet conveyor belt L4: 2nd magnet length
80: second holder
100: waste recycling apparatus

Claims (5)

A first hopper 10 for introducing wastes;
A planar hopper 21 which receives the waste introduced into the first hopper 10 through a conveyor belt B and includes a mesh net 21a formed of a first mesh m1 therein, and the plane High tension spring 22 formed outside the sieve hopper 21 and the flat body hopper 21 vibrate 15 to 20 times per second to remove small particles of waste, and operate at an amplitude of 15 to 30 mm. When there is waste of the same size as the size of the first mesh (m1) of the mesh network 21a formed in the planar hopper 21, the first mesh of the mesh network (21a) in conjunction with the high tension spring (22) A flat body portion 20 made of vibration generating means 23 configured not to be caught by the mesh m1;
A first magnet sorting unit (30) for receiving the waste passing through the planar body part (20) through a conveyor belt (B), and installed on an upper side of the conveyor belt (B) to sort only the steel contained in the waste;
A first holder (40) for storing steel selected through the first magnet sorting unit (30);
A second hopper (50) for introducing waste having small particles removed from the planar body portion 20;
The waste injected through the second hopper 50 is supplied through the conveyor belt (B), and forms a first cylindrical mesh net 61 made of a second mesh m2 inward, and the first cylindrical mesh net ( 61) a cylindrical mesh network 60 formed on the outside and comprising a second cylindrical mesh network 62 including a third mesh m3, for sorting waste having small particles while rotating during waste input;
A second magnet sorting unit (70) for receiving wastes passed through the cylindrical mesh network (60) through a conveyor belt (B), and installed on the conveyor belt (B) to sort only steel contained in the waste;
And a second holder 80 for accommodating iron selected through the second magnet sorting unit 70;
The first and second magnet sorting units 30 and 70 include first and second magnet conveyor belts 31 and 71 that operate in a direction perpendicular to the direction in which the conveyor belt B moves. Ferromagnetic first and second magnets M1 and M2 are formed inside the two magnet conveyor belts 31 and 71, and a plurality of first and second bars are located outside the first and second magnet conveyor belts 31 and 71. 32 and 72, the first and second magnet conveyor belt length (L1, L3) of the first and second magnet sorting portion 30, 70 is formed longer than the width (w) of the conveyor belt, The lengths L2 and L4 of the first and second magnets are longer than the width w of the conveyor belt, and are shorter than the lengths L1 and L3 of the first and second magnet conveyor belts.
The first mesh m1 formed in the mesh net 21a of the planar body part 20 is formed to be larger than the second mesh m2 formed in the first cylindrical mesh net 61 of the cylindrical mesh net 60. And the second mesh (m2) is formed larger than the third mesh (m3) of the second cylindrical mesh network (62).
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