This application claims priority to Spanish Utility Model Application No. U201830333 filed Mar. 12, 2018, the disclosure of which is hereby incorporated by reference in its entirety.
The present invention relates to a mobile shredder with a prior slow shredding that improves the safety of the shredding process of metal materials, so as to prevent problems associated with the presence of flammable or explosive products among the metal materials being shredded. The mobile shredder object of the invention can be applied to the metal industry, specifically to the industry of metal recycling.
A shredder is a machine that processes metal material (scrap) with the objective of reducing the size thereof and increasing the density thereof. This way a material is obtained that is suitable for a series of applications in the industrial field, mainly focused on the recycling of the same.
The use of scrap metal has become an integral part of the steel industry, improving the economic viability of the sector and reducing the environmental impact. In comparison with mineral extraction, the use of recycled ferrous metals significantly reduces CO2 emissions, energy use and water consumption, as well as air pollution. At the same time, steel recycling makes more efficient use of the Earth's natural resources.
Metal recycling is an industry that is symbolically like a pyramid, with many small companies at the base which supply scrap metal to large multinational companies at the top of the pyramid. Steel recycling is done in some or all of the following steps:
Steel is ideal for recycling because it does not lose any of the inherent physical properties thereof during the recycling process, which can be repeated as many times as desired. Steel is a material that is 100% recyclable and therefore recycled steel can be used for the same applications as the steel produced from virgin material.
Practically 40% of the world's steel production comes from scraps. Recycling one tonne of steel allows 1,100 kilograms of iron ore, 630 kilograms of carbon and 55 kilograms of limestone all to be saved. CO2 emissions are reduced by 58% with the use of ferrous scrap metal.
A shredder in a very basic form includes:
Currently, one of the main problems with shredders are the explosions that can occur when introducing flammable materials into the same (for example fuel tanks with traces of fuel, gas canisters, etc.), given that the shredding process is done with hammers rotating at a high peripheral speed, which strike the material against an anvil and therefore generate a large amount of sparks and heat in the process. It is when this process comes across an element or recipient that contains a trace of a flammable material that explosions of a greater or lesser degree are produced, said explosions constituting a risk for machine operators as well as for people or buildings near the same.
One way of preventing explosions is by previously shredding the material, by means of a machine designed for such purposes.
Machinery designed to perform a previous shredding has two or three rollers, such that the material placed in a hopper moves to the first roller by gravity (which rotates around 2-3 rpm) where a pushrod facilitates the contact of the material with the first roller, which traps the material and moves it towards a second roller which is faster than the first roller (8-11 rpm). The rollers rotate in opposite directions and have teeth that are interspersed with respect to the width thereof.
Thus, the material in the prior shredding is torn by the teeth of the rollers and once it is processed, it is sent to the area for the exit of the material.
Given that this process is done at a slow speed, it does not cause explosions and, furthermore, prepares the material for the subsequent shredding thereof, eliminating the situations in which explosions may occur.
These machines are designed to work separately, and as such the power designed for each one of them must be suitable to carry out a specific production. When these machines work in line, meaning first the prior shredding and then the shredding, the percentage of time in which the two machines will be working at full load is reduced to a minimum. This is due to the fact that regulating the feeding of the shredder is done based on the load of the motor which actuates the same, and when this motor is at a pre-established load, the feeding is reduced and even stops, depending on the parameters of design and control, and as such the slow shredding will not need to work at full load. This is the result of overdimensioned motors in design when the two machines work in line.
With the aim of achieving the objectives and avoiding the drawbacks that were mentioned in the preceding sections, the invention proposes a mobile metal shredder that offers improved safety conditions in the operation thereof with respect to mobile metal shredders known in the state of the art.
The mobile metal shredder object of the invention comprises a feeding device in which the slow shredding process is included, configured to receive material to be shredded, a shredding mill to shred the material received through the feeding device by means of a plurality of hammers associated with a rotor, a removal device configured to remove the shredded material and an actuating device configured to provide energy to the feeding device, the shredding mill and the removal device.
In the mobile metal shredder object of the invention the feeding device comprises a hopper and a shredder, the shredder comprising a first toothed roller and a second toothed roller that rotates in the opposite direction to that of the first toothed roller and at a greater speed.
The actuating device of the mobile metal shredder object of the invention comprises a single motor, which provides power to the feeding device, the shredding mill and the removal device.
The mobile metal shredder object of the invention comprises a control system which comprises a plurality of hydraulic pumps and a hydraulic clutch with variable flow, the plurality of hydraulic pumps and the hydraulic clutch with variable flow being joined to the motor.
In the mobile metal shredder object of the invention, the plurality of hydraulic pumps controls the movement of the toothed rollers and the hydraulic clutch with variable flow controls the movement of the rotor.
The control system of the mobile metal shredder object of the invention is configured to modify the rotational speed of the first toothed roller and of the second toothed roller based on the motor load associated with the shredding mill.
In the shredder object of the invention the feeding device, the shredding mill, the removal device and the actuating device are mounted on a frame.
In the mobile shredder with improved safety features object of the invention, teeth of the first toothed roller are interspersed between teeth of the second toothed roller.
The mobile shredder with improved safety features object of the invention comprises a series of pulleys and belts joined to the motor by means of the hydraulic clutch with variable flow, said series of pulleys and belts being joined to the rotor of the shredding mill.
The mobile shredder with improved safety features object of the invention comprises a series of measuring systems for controlling a workload of the motor.
The measuring systems for controlling a workload of the motor of the mobile shredder with improved safety features object of the invention are:
The mobile shredder with improved safety features object of the invention comprises a series of systems for regulating the operation of the shredder.
The systems for regulating the operation of the shredder are:
For the purpose of helping to make this specification more readily understandable, a set of drawings constituting an integral part of the same has been included below, wherein by way of illustration and not limitation represent the following:
The various numerical references found in the figures correspond to the following elements:
Considering the numbering used in the figures, the mobile metal shredder object of the disclosure comprises a feeding device (1) that receives the material to be shredded and moves it towards a shredding mill (2) where the shredding of the material received through the feeding device (1) is carried out, and then to a removal device (3) for removing the material that has now been shredded by the shredding mill.
Furthermore, the mobile metal shredder object of the disclosure comprises an actuating device (4) that comprises a single motor (5) which provides the necessary power for all of the components of the shredder to function properly, in other words, the motor (5) provides energy to the feeding device (1), to the shredding mill (2) and to the removal device (3).
The shredding mill (2) in the preferred embodiment of the disclosure comprises a plurality of hammers (6) associated with a rotor (7) inside the shredding chamber (8) such that the impact against the metal material causes the shredding of the metal material.
The feeding device (1) of the mobile metal shredder object of the disclosure incorporates a hopper (12) in which the material to be shredded is placed, and a shredder (9), which performs a first shredding of the metal material at a low speed, so that when the metal material reaches the shredding mill (2), where hammers (6) associated with the rotor (7) rotate at a very high speed and produce sparks and heat inside the shredding chamber (8), possible traces of flammable materials present in the material to be shredded are prevented from producing explosions, which are dangerous for the operation of the shredder.
In the preferred embodiment of the disclosure of the mobile metal shredder, the shredder (9) comprises a first toothed roller (10) and a second toothed roller (11) that rotates in the opposite direction to that of the first toothed roller (10). The first toothed roller (10) in the preferred embodiment of the disclosure rotates at a slow speed (approximately 2-3 r/min) while the second toothed roller (11) rotates at a greater speed than the speed of the first toothed roller (10), at approximately 8-11 r/min).
The toothed rollers (10, 11) have teeth interspersed throughout the width of the same, such that the material to be shredded is trapped by the teeth of the two toothed rollers (10, 11) and once it is shredded, it is then moved to the shredding mill (2).
The feeding of the shredding mill (2) is regulated by regulating the rotational speed of the toothed rollers (10, 11) of the shredder (9), since the shredding mill is fed (2) from the production of the shredder (9).
The mobile metal shredder object of the disclosure moves the rotor (7) of the shredding mill (2) with a series of pulleys and belts joined to the motor (5) with the interposition of a hydraulic clutch with variable flow (13), while the two toothed rollers (10, 11) of the shredder (9) are associated with a plurality of hydraulic pumps (14) that can make them rotate at a higher or lower speed.
The plurality of hydraulic pumps (14) and the hydraulic clutch with variable flow (13) that are joined to the motor (5) make up a control system (16) which ensures maximum efficiency of the single motor (5) of the mobile shredder object of the disclosure.
The operation of the control system (16) is simple, given that, assuming a state of equilibrium between the shredder (9) and the shredding mill (2), the hydraulic pumps (14) which move the toothed rollers (10, 11) of the shredder (9) operate a full capacity, feeding the shredding mill (2) with an amount of the product that the shredding mill (2) is capable of shredding. Now, at the moment when material that has come out of the shredder (9) accumulates in the shredding mill (2), the rotor (7) of the shredding mill (2) will require additional power from the motor (5), and this additional power comes from reducing the output of the hydraulic pumps (14) that move the toothed rollers (10, 11) of the shredder (9), and as such, an automatic regulation of the material that comes out of the shredder (9) and which has to be absorbed by the shredding mill (2) is carried out.
The mobile metal shredder object of the disclosure further has a plurality of measuring systems for controlling the workload of the motor (5) and of the hydraulic pumps (14) of the shredder (9).
The measuring systems that are incorporated in the shredder are:
Furthermore, mobile metal shredder object of the disclosure has a series of systems for regulating the operation of the shredder. These systems for regulating the operation of the shredder are:
By modifying the flow of the hydraulic pumps (14) which power the toothed rollers (10, 11), the speed of the toothed rollers (10, 11) themselves is modified and the power sent the shredder (9) is modified as well. The pressure of the hydraulic pumps (14) is limited to a maximum value.
The all or nothing supply system for the hydraulic circuit of the hydraulic clutch with variable flow (13) is used to prevent overloading of the motor (5) of the mobile metal shredder object of the disclosure.
With these systems for controlling and regulating the operation, it is known at all times what percentage of the motor (5) power is being sent to each part of the shredder itself, in other words to the shredder (9) or to the shredding mill (2).
This way, if it is detected that the motor (5) is operating above the pre-established values and it is in the part of the shredding mill (2), more power can be sent to the shredding mill (2), reducing the flow of the hydraulic pumps (14) of the shredder, thereby regulating the feeding (9) and vice versa.
All of the components of the mobile metal shredder object of the disclosure are incorporated on a frame (15), said frame (15) in turn resting on the ground by means of a drive system, which in the preferred embodiment of the disclosure are caterpillar tracks but could also be a plurality of wheels or any other means that make the shredder object of the disclosure mobile.
The present disclosure is not intended to be limited to the embodiments described herein. Those skilled in the art may develop other embodiments in light of the description made herein. As such, the scope of the disclosure is defined by the following claims.
Number | Date | Country | Kind |
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ES201830333U | Mar 2018 | ES | national |
Number | Name | Date | Kind |
---|---|---|---|
3335968 | Young | Aug 1967 | A |
5431350 | Purser | Jul 1995 | A |
6491245 | Rajewski | Dec 2002 | B1 |
20030230655 | Giberson | Dec 2003 | A1 |
20040112999 | Byram | Jun 2004 | A1 |
20130087644 | Ephraim | Apr 2013 | A1 |
20140203124 | Arrieta Gonzalez | Jul 2014 | A1 |
20190275531 | Manzanares Mercero | Sep 2019 | A1 |
Number | Date | Country |
---|---|---|
H08131864 | May 1996 | JP |
WO-2011015793 | Feb 2011 | WO |
2011092588 | Aug 2011 | WO |
Entry |
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Spencer, D. B., Temple, J. W., Forsythe, D. M., & Bond, B. E. Large-Scale Rotary Shear Shredder Performance Testing. Journal of Energy Resources Technology, Transactions of the ASME, 107(2), See p. 289 (Year: 1985). |
Number | Date | Country | |
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20190275529 A1 | Sep 2019 | US |