KR20120139104A - Composite waste crusher - Google Patents

Abstract

PURPOSE: A composite waste crusher is provided to use the composite waste as fuel for cement manufacturing and paper manufacturing. CONSTITUTION: A composite waste crusher comprises a main blade tool(20), an auxiliary blade tool(30), a cutting blade tool(40) and a crushing container tool(50). The main blade tool is installed in a driving shaft(10) and includes a fixed body(21) and main wings(22). The auxiliary blade tool is located between the main wing tools, and is installed in the driving shaft. The auxiliary blade tool includes a fixed body(31) and a flap(32). The size of the flap is smaller than the size of the main wing.

Description

Composite waste crusher

The present invention relates to a composite waste shredder, in detail, the composite waste is fixed by adjusting the interval between the inlet portion and the blade portion is rotated to return the blade cutting the waste mixed with wood, waste synthetic resin, food waste, etc. The present invention relates to a composite waste crusher that can be used as a heating fuel in cement production and paper production.

Food waste generated in Korea accounts for 90% of the total amount emitted from homes, restaurants, and catering establishments. Only a small portion of such food waste is recycled into livestock feed and compost, and the rest is disposed of by landfilling. have.

In this way, the landfilled food waste not only causes environmental pollution due to leachate, but also causes bad odors as the garbage is decomposed, and pathogens grow, causing direct or indirect adverse effects on human health and hygiene. It caused serious problems of contamination.

In addition, there is a demand for the establishment of a landfill site due to increasing food waste, which is a major social issue due to difficulties such as cost and location. Food waste treatment apparatus for the treatment of such food waste has been disclosed in a number of forms.

On the other hand, a lot of tree roots are collected at construction sites such as roads, land development, and ports. Logs or branches are easy to process by recycling and shredding with wood shredders, but roots are not only difficult to use as logs but also have many difficulties in shredding.

So far, tree roots collected at construction sites have usually been treated with oil and burned away or buried in the ground. In the case of burning and treating tree roots, smoke is generated to increase the environmental pollution.In addition, when the tree roots are buried in the ground, the roots are decayed after a long time since they are reclaimed. If it was built, there was a problem that the ground is settled as the roots rot.

Therefore, there is a demand for the development of a device that can efficiently recycle industrially while preventing the pollution of the environment by efficiently processing a small number of tree roots collected at the construction site and the like.

The crusher of the present invention devised in view of the conventional problems as described above produces cement by producing a composite waste pulverized to a certain size by cutting the complex waste to a certain size by a high speed rotating blade means and a discharge mesh body to discharge only a certain size. And composite waste shredders that can be used as a heating fuel in paper production to reduce waste, that is, waste of fossil fuels, and to reduce product costs. have.

The present invention is a plurality of rotary blades are installed in the drive shaft rotating at a constant speed and a fixed blade is attached to the end of the rotary blade, discharged when the cutting cut by the blade is cut to a certain size discharged In a crusher having a plurality of through-hole shattering means having a perforated mesh shape is fixedly installed in the housing, the fixed body to be fixed to the drive shaft is installed in the fixed body close to the discharging network body having a main wing that rotates the main wing Wing means; An auxiliary wing means formed between the main wing means and the main wing means and having an auxiliary wing having a size smaller than that of the main wing in a fixed body fixed to the drive shaft; The blade body formed with a fixed hole fixed to the end of the main blade and the auxiliary blade blade means consisting of a tungsten material and the surface is roughly formed; At both ends of the discharge mesh body having a perforated mesh shape, a fixed plate bent horizontally is formed, and the fixing plate is formed with a position adjusting fixing hole for adjusting the position of both ends of the discharge mesh body, and the fixing plate is integrally formed in the inner direction of the discharge network body. It characterized by consisting of crushing cylinder means having a cutting guide groove for continuously cutting the cutting guide groove for cutting the waste sandwiched between the blade means and the cutting means while the blade means and the main rotary blades are continuously repeated. Achieved by a complex waste crusher.

The shape of the blade means is achieved by a composite waste crusher, characterized in that the M-shape.

The gap between the cutting guide groove and the outer side of the blade means is achieved by a composite waste crusher, characterized in that more than 2mm ~ 5mm and the side spacing is 1mm.

The coating layer of the blade means is achieved by a composite waste crusher, characterized in that formed by attaching a ball or piece.

The shape of the cutting guide groove is achieved by a composite waste crusher, characterized in that any one selected from square or trapezoid.

The present invention is such that the composite waste is crushed to a certain size and adjusted to a certain size by adjusting the interval between the inlet portion for entering the blade for cutting waste mixed with wood, waste synthetic resin, food waste, etc. The pulverized composite waste can be used as a heating fuel in cement production and paper production, thereby reducing fuel consumption, and suppressing the use of fuel, thereby suppressing an increase in product cost.

1 is an installation state showing the installation state of the inventors of the composite waste crusher.
Figure 2 is an exploded perspective view showing the structure of the composite waste crusher to which the technique of the present invention is applied.
Figure 3 is a plan view showing the structure of a composite waste crusher to which the technique of the present invention is applied.
Figure 4 is a longitudinal sectional view showing the structure of a composite waste crusher to which the technique of the present invention is applied.
Figure 5 is a perspective view showing the structure of the blade means which is the main part of the present invention.
6 is an enlarged view of a portion A in Fig.
7 is a cross-sectional view showing an operating state of the present invention.
8 is a perspective view showing another structure of the crushing cylinder means that is the main part of the present invention.

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

1 is an installation state diagram showing the installation state of the composite waste shredder of the present invention, the installation structure of the composite waste shredder 1 of the present invention is a composite waste by the hopper 700 installed to be rotatable by the cylinder means (800) When this is supplied, wastes are crushed by the complex waste crusher 1 installed at the bottom.

Waste shredded by the complex waste shredder 1 is transported by a transport means 400 installed at the bottom, and the complex waste shredder 1 of the present invention is shown in FIG. It is described as being installed in the movable form that the drive wheel 300 is driven by the) but this is not intended to be limited to the movable type, it is also installed and used in the fixed type omitting the driving of the drive wheel 300 by the engine drive 500 Can be.

2 is an exploded perspective view showing the structure of a composite waste shredder to which the technique of the present invention is applied. According to this, the composite waste shredder 1 of the present invention has the main wing means 20 and the auxiliary wings built on the drive shaft 10. By means 30, the blade means 40 fixed to the end of the main wing means 20 and the auxiliary wing means 30, and shredding cylinder means 50 for discharging the composite waste shredded to a predetermined size It is composed.

The main wing means 20 is a main wing that is installed and rotated close to the end close to the discharge network body 51 in the fixed body 21 is fixed to the drive shaft as shown in Figures 3 to 4 attached drawings It has a structure having a 22, the structure of the auxiliary wing means 30 is installed between the main wing means 20 and the main wing means 20 and the fixed body 31 is fixed to the drive shaft (10) A secondary wing 32 having a size smaller than the size of the main wing 22 is formed.

Meanwhile, the blade means 40 is attached to the blade body 42 having a fixing hole 41 fixed to the end of the main blade 22 and the auxiliary blade 32, as shown in FIGS. 5 and 6. The coating layer 43 is formed to have a tungsten material and to have a rough surface.

The cross-sectional shape of the blade means 40 is formed in an M shape, the coating layer 43 of the blade means 40 is a structure formed by attaching a ball or a piece of tungsten material.

The reason is to roughly form the surface of the blade means 40 so that waste such as wood, waste synthetic resin, food waste and the like can be easily cut. For example, when the surface of the blade means 40 is smooth, the cutting due to the impact due to the rotational force, that is, only the role of the blade, but when the surface of the blade means 40 is roughly formed because it is easier to cut because it has a harquin shape. .

The crushing cylinder means 50 forms a fixed plate 52 bent horizontally at both ends of the discharge net body 51 having a perforated network shape, the fixed plate 52 is a position of both ends of the discharge net body 51 Position adjustment fixing hole (53) is formed to adjust the fixed plate (52) integrally with the blade means (40) while protecting the blade means (40) and the main blade (22) inwardly of the discharge net body (51) The cutting guide groove 54 for cutting the waste sandwiched between and the projection 55 for forming the cutting guide groove 54 is composed of a structure having a cutting crushing portion 56 is provided repeatedly.

The interval between the cutting guide groove 54 and the outside of the blade means 40 is 2mm ~ 5mm and the side spacing is preferably 1mm, the shape of the cutting guide groove 54 is shown in Figure 2 As shown in FIG. 8, any one selected from a trapezoidal shape may be used.

Meanwhile, as shown in FIG. 7, the end spacing of the cutting guide groove 54 and the blade means 40 on the side drawn into the crushing cylinder means 50 when viewed in the rotation direction is as wide as L1 as shown in the drawing. , The distance between the end of the blade means 40 discharged from the crushing cylinder means 50 and the cutting guide groove 54 is preferably used as narrow as L3 as shown in the figure.

The reason is that when viewed from the rotation direction, the cutting guide groove 54 on the side leading into the shredding barrel means 50 and the edge of the blade means 40 are shredded once in the wide area L1 and the shredded waste is shredded barrel means 50 ) And the blade means 40 is crushed once again at the interval of L2, the gap between the end of the blade means 40 and the cutting guide groove 54 is installed in the narrow gap, that is, discharged from the crushing cylinder means 50 Since the waste is crushed at a part, the waste is crushed by three impacts in one rotation of the drive shaft 10, thereby improving the efficiency of crushing the waste.

Of course, the crushing occurs by the rotation of the auxiliary wing means 30, which is a crushing due to the impact of the direct rotation of the drive shaft 10 because the collision between the other components.

The thickness of the fixing plate 52 in which the cutting guide groove 54 is formed should be formed thicker than the thickness of the discharge net body 51 to prevent deformation and breakage of the fixing plate 52 during waste crushing.

Referring to the operational description of the present invention having the structure as described above, as shown in the accompanying drawings, Figures 3 and 4 first perforated network of the blade means 40 is introduced into the crushing cylinder means 50 when viewed in the rotation direction Loosen the fixing bolts installed on the fixing plate 52 of one side integrally provided at both ends of the discharge mesh body 51 having a shape to adjust the position of the fixing plate 52 in the position adjustment fixing hole 53.

After adjusting the position of the fixing plate 52 to adjust the end gap of the cutting guide groove 54 and the blade means 40 of the side leading into the crushing cylinder means 50 as shown in the drawing L1 and then fixed plate 52 on the opposite side Position, that is, the gap between the end of the blade means 40 and the cutting guide groove 54 from which the blade means 40 is discharged from the crushing means 50 is narrowly adjusted as L3 shown in the drawing.

As seen from the rotation direction, the gap between the cutting guide groove 54 on the side into which the blade means 40 is led into the crushing cylinder means 50 and the outside of the blade means 40, that is, L1 is 2 mm to 5 mm and the side spacing is Adjusting to 1mm, the distance between the cutting guide groove 54 and the outside of the blade means 40 on the side from which the blade means 40 is drawn out from the crushing cylinder means 40 when viewed in the rotation direction | Is adjusted to 1mm.

As described above, when the gap between the cutting guide groove 54 and the blade means 40 is completed, supplying power to rotate the drive shaft 10 causes the drive shaft 10 to rotate at a high speed of 1,800 RPM / min and the drive shaft ( The main rotary blade 22 and the auxiliary rotary blade 32 which is arranged in 10) is rotated.

When the main rotary blade 22 and the auxiliary rotary blade 32 is rotated, the composite waste supplied through the hopper 700 shown in Figure 1 attached to the blade means 40 installed on the main rotary blade 22 and Wastes located between the cutting crushing portions 56 in which the cutting guide grooves 54 are formed are crushed.

When the wastes are crushed to a predetermined size, the wastes are passed through a plurality of perforations (through holes) formed in the discharge net body 51 having a perforated network shape to form the shredding cylinder means 50, and transferred to the lower conveying means 400.

However, when the size is larger than the perforations, it is not discharged, so that crushing occurs by the auxiliary wing means 30, and the crushed waste is crushed by the crushing means 50 and the blade means 40 again, and by centrifugal force. Waste that is not discharged is crushed at a portion discharged from the crushing cylinder means 50, which is provided with a narrow gap between the end of the blade means 40 and the cutting guide groove 54, so that the waste is impacted three times when the drive shaft 10 is rotated. The crushing is caused by and the efficiency of crushing the waste is improved.

Of course, the crushing occurs due to the rotation of the auxiliary wing means 30, which is a collision between the other components and the crushing due to the impact of the direct rotation of the drive shaft also occurs.

When viewed from the rotation direction, the gap between the cutting guide groove 54 of the side into which the blade means is introduced into the crushing cylinder means 50 and the outer side (end) of the blade means 40 is 2mm to 5mm and the side spacing is adjusted to 1mm. When viewed from the rotation direction, the distance between the cutting guide groove 54 and the outside of the blade means 40 on the side where the blade means 40 is drawn out from the crushing cylinder means 50 is 1 mm and the side spacing is adjusted to 1 mm. However, the side drawn into the crushing cylinder means 50 forms a large gap between the cutting guide groove 54 and the blade means 40 so as to be easily introduced into the crushing cylinder means 50 and when viewed in the direction of rotation The reason for forming the gap between the cutting guide groove 54 on the side where the means 40 is drawn out to the crushing cylinder means 50 and the outer side (end) of the blade means 40 is smaller than the inlet side is that the crushed waste While preventing the escape from the outside (upper) It is to increase the efficiency of the chain.

Meanwhile, the cutting by the blade means 40 will be described in more detail. As shown in FIGS. 5 and 6, the cross-sectional shape of the blade means 40 has an M shape. The reason is that the fixed hole 41 is formed in the center of the blade body 42, so that the center portion is inserted to facilitate the coupling to each wing means 20, 30, and both sides protrude from the center of the fracture. This is to facilitate the.

In particular, the coating layer 43 provided on the outer circumferential surface of the blade body 42 is formed by attaching a ball or a piece of tungsten by welding or the like. The reason is that a ball or piece is made while increasing the contact area upon contact with waste. Since it is attached by welding to form a rough surface, the rough surface of the coating layer adds a shock and adds impact so that the waste is easily crushed.

1: compound waste crusher 10: drive shaft
20: main wing means 21: fixed body
22: main wing 30: auxiliary wing means
31: fixed body 32: auxiliary wing
40: blade means 41: fixed hole
42: blade body 43: coating layer
50: shredding cylinder means 51: discharge network body
52: fixed plate 53: position adjustment fixing hole
54: cutting guide groove 55: protrusion
300: driving wheel 400: transfer means
500: engine driving 700: hopper
800: cylinder means

Claims (5)

A plurality of rotary blades are installed on the drive shaft that rotates at a constant speed, and a blade is attached to the end of the rotary blade, and a plurality of discharge holes are discharged when the cutting cut by the blade is cut to a certain size. In the crusher which is provided with a crushing cylinder means of the perforated mesh shape provided in the housing,
A main blade means having a main blade which is fixed to the drive shaft and fixedly installed on the drive shaft, the main blade being rotated close to an end of the discharge network body;
An auxiliary wing means formed between the main wing means and the main wing means and having an auxiliary wing having a size smaller than that of the main wing in a fixed body fixed to the drive shaft;
The blade body formed with a fixed hole fixed to the end of the main blade and the auxiliary blade blade means consisting of a tungsten material and the surface is roughly formed;
It is fixed to the housing and forms a fixed plate bent horizontally at both ends of the discharge network body having a perforated network shape, the fixing plate is formed with a position adjustment fixing hole for adjusting the position of both ends of the discharge network body and discharged integrally to the fixed plate It is a crushing cylinder means having a cutting crushing portion which is provided with a cutting guide groove for cutting the waste sandwiched between the blade means and the cutting means and the projections to form a cutting guide groove continuously while protecting the blade means and the main rotor blade in the inner direction of the mesh body; Complex waste crusher, characterized in that made. The method of claim 1,
Cross-sectional shape of the blade means is a complex waste crusher, characterized in that the M-shape. The method of claim 1,
The composite waste crusher, characterized in that the thickness of the fixing plate formed with the cutting guide groove is formed thicker than the thickness of the discharge network body. The method of claim 1,
The coating layer of the blade means is a composite waste crusher, characterized in that formed by attaching a ball or a piece of tungsten material. The method of claim 1,
Complex waste shredder, characterized in that the cutting guide groove is any one selected from the shape of square or trapezoid.

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