Patent Grant
11446676
The present invention relates to a shredder device for shredding material, in particular recyclable materials, waste wood and date storage devices, the shredder device comprising a machine frame, at least one shredder rotor rotatably supported on the machine frame, and at least one feed device for conveying the material to be shredded to the at least one shredder rotor. The invention further relates to processes for operating such a shredder device.
Shredder devices are already known from the prior art. It is frequently provided that the at least one feed device is configured to be movable between a first end position and a second end position. Thereby, an inductive sensor is arranged on both end positions, and the inductive sensor detects whether the feed device is located in one of the two end positions. If the feed device shall be moved into a certain position deviating from the end positions, then this is only possible by a switching interval, that is to say by an adjustable time in which the pusher is moved into a position which presumably corresponds to the desired position. The fact whether the feed device actually reaches the desired position cannot be controlled. That is a disadvantage, for example when the feed device is to be moved into a certain position for maintenance purposes. Also, the removal performance of the material cannot be detected. And eventually, malfunctions occurring between the two end positions can neither be detected by the control technology nor resolved. The malfunctions, for example, include a reduced throughput rate which can occur in connection with some materials to be shredded, or in the event of an inadequate cutting function of the cutting system, which is denoted colloquially as a so-called “free-cutting”, that is to say cutting without substantial resistance. This free-cutting leads to an undesired heating of the shredder rotor, and/or the material to be shredded partially begins to melt, burn or char. There is a risk of fire for the end user. A further malfunction is that the feed device gets jammed.
It is to be noted that there are also shredding devices in which the at least one feed device is not movable between two end positions, but rather in a circle. The invention also relates to these shredding devices.
It is an object of the present invention to propose a shredder device which is improved over the prior art, which resolves at least partially, preferably entirely, the aforementioned problems, and which permits a complete controlling functionality of at least the movement of the at least one feed device. Further, an improved process for operating such a shredder device shall be proposed.
Regarding the shredder device, at least one measuring device for continuously detecting a position of the at least one feed device, a control and/or regulating device for controlling and/or regulating the movement of the at least one feed device, and a signal transmitting device are provided, and measuring signals generated by the at least one measuring device can be supplied to the control and/or regulating device by the signal transmitting device.
The term measuring device for continuously detecting a position of the at least one feed device is to be understood as a measuring device which is configured so as to continuously measure, thus on a multiplicity of subsequent locations, the position of the at least one feed device, in contrast to the prior art in which a measurement of the position of the at least one feed device is only possible on single locations.
By a continuous detection, it is possible that the position of the at least one feed device, in each position, can be clearly and reproducibly detected in terms of control and regulation. In addition, a detection of the at least one feed device at two end positions, as in the prior art, may, of course, also be provided, in particular in the case when the at least one feed device is configured to be movable between a first end position and a second end position, and the at least one measuring device is configured so as to continuously detect a position of the at least one feed device between the two end positions, as is provided in accordance with a preferred embodiment of the invention.
According to a preferred embodiment, at least one hydraulic piston-cylinder-device is provided for moving the at least one feed device. The at least one hydraulic piston-cylinder-device includes at least one inlet and at least one outlet for a hydraulic fluid, and the at least one measuring device for continuously detecting a position of the at least one feed device is configured to measure a volume flow of the hydraulic fluid in the inlet and/or in the outlet.
As an alternative or in addition, the at least one feed device may also be operated electrically or pneumatically.
Alternatively, the at least one measuring device for continuously detecting a position of the at least one feed device can be configured as a path measuring device. Preferably, the path measuring device includes a cable potentiometer.
The at least one measuring device for continuously detecting a position of the at least one feed device can be configured to measure a rotation angle of the at least one feed device. Preferably, the at least one measuring device includes a rotary encoder, and/or the at least one feed device is rotationally supported on the machine frame and the measuring device is configured to measure a rotation angle of the at least one feed device.
The measurement of a rotation angle does not necessarily mean that the at least one feed device is rotationally supported on the machine frame. For example, it is also possible that the at least one feed device is configured as a linear pusher configured to be driven by a chain, the chain being in engagement with a gear, and the rotation angle of the gear can be measured.
It is, of course, also possible to combine the three preferred possibilities for the configuration of the measuring device in any desired way in a shredder device, for example in order to increase the accuracy in detection of a position of the at least one feed device, or in order to provide a precaution in case that a measuring device fails.
With regard to the signal transmitting device provided according to the invention, it is further to be noted that the signal transmitting device can be based on each form of a physical data transmission, therefore also wirelessly for example.
The type and form of the at least one feed device is not crucial. It can be a feed device which is arranged in an arcuate configuration as well as a feed device arranged in a linear form.
The process according to the invention for operating a shredder device according to the invention includes the following process steps:
In accordance with the three possibilities, mentioned in connection with the shredder device, for configuring the at least one measuring device, the following preferred embodiments can be provided, either individually or in combination with one another:
The at least one feed device is moved by at least one hydraulic piston-cylinder-device, the at least one hydraulic piston-cylinder-device being supplied via the at least one inlet and the at least one outlet with a hydraulic fluid, and the at least one measuring device measures a volume flow of the hydraulic fluid in the inlet and/or outlet.
The at least one measuring device measures a path covered by the at least one feed device, preferably relative to at least one end position.
The at least one measuring device measures a rotation angle. Preferably, the at least one measuring device is moved between two end positions, thereby performs a rotational movement and the at least one measuring device measures a rotation angle of the at least one feed device.
The detection of the position of the at least one feed device between the two end positions is the basis for a series of advantageous operating modes of the shredder device. For example, it is possible for the at least one feed device to be moved into an exactly predetermined position for maintenance purposes. In particular, this can be relevant when a maintenance flap is provided, and the at least one feed device has to adopt a given position relative to that maintenance flap, so that the maintenance flap can be opened at all or a given maintenance task can be performed.
Preferably, a speed of the at least one feed device can be detected by the control and/or regulating device based on the measurement signals generated by the at least one measuring device.
The speed of the at least one feed device, in turn, can further be used to determine a removal performance of the material.
It is also possible that the detected speed is compared to a reference speed. Preferably, for the case that the at least one feed device is moved by at least one hydraulic-cylinder-device, a deflection of a control slider is adapted upon a deviation of the detected speed from the reference speed.
In this connection, it is appropriate that a proportional valve for controlling the at least one feed device can be used for the machine hydraulics. By means of a proportional valve, there is the possibility to continuously control the speed of the at least one feed device between 0% and 100%. By measuring the actually occurring speed of the at least one feed device in relation to the speed theoretically predetermined by the valve, thus the reference speed, the same can be regulated. Therefore, when the theoretical speed is not reached, the control slider deflection can be altered until the theoretical speed conforms with the detected speed. By this regulation, the control slider is only deflected only as far as it is necessary for the material to be shredded. As a result, the absorbed power in the unit can be reduced and the oil warming can be decreased which, in turn, contributes to a decrease of the consumed power. With the current state of art, this is only possible with an increased effort. Here, the deflection of the control slider is performed with 100% of the maximum flow volume delivered by the hydraulic pump. Upon a deviation of the theoretical speed from the actual speed of the feed device, the excess volume of oil is returned to the tank again via a bypass and is introduced afresh into the cycle.
It has also been proven to be desirable that the speed is compared to at least one predefined threshold value. Preferably, the control or regulating device
For example, the predefined threshold value can be determined from the configuration of the cutting system, that is to say from the number of rows of blades, the maximum possible cut thickness and the prevailing rotational speed. From the mentioned parameters, it follows how much material can be removed per revolution or per time interval, respectively.
Through the measures mentioned above, the control and/or regulating device can actively counteract inefficiency of the cutting system and, in the event of a “free-cutting”, an additional warming of the at least one shredder rotor can be prevented and the at least one feed device can be relieved.
As at the same time, if there is no change in the position of the at least one feed device or, respectively, the advance speed, the power consumption of drive motors, which are preferably provided, also decreases, it is appropriate for that parameter to be additionally used in order to detect a “free-cutting” situation.
The mentioned cleaning procedure can be advantageously performed in detail as described in the following: The cutting system is firstly deactivated, that is to say its power is cut off, and it comes to a halt. After stoppage, the rotational direction of the at least one shredder rotor is reversed, the at least one feed device moves in a rearward position, again fetches material and conveys the material actively in a direction of the at least one shredder rotor.
Due to the reversal of the rotational direction and the pressing process of the at least one feed device, the material adhering on the shredder rotor is moved into an undefined new position by the counter-rotation of the at least one shredder rotor. The duration of the rotor cleaning is dependent on the material and can be preferably adjusted by the control and/or regulating device. After the rotor cleaning has been finished, the cutting system is again stopped and after starting in the normal direction of rotation, the shredding process starts from the beginning. The automatic detection of inefficiency and the automatic initiation of the corrective measures are only made possible by the detection of the position or, respectively, advance detection action according to the invention.
It is appropriate for the cleaning procedure to be activated when the threshold value is reached x-times, and the number is preferably adjustable.
A further preferred operating mode is that the control and/or regulating device is configured to vary a position of an end position of the at least one feed device.
This means that, due to the detection of a position of the at least one feed device, there is the possibility to electronically limit a maximum possible stroke movement of the at least one feed device. If the at least one feed device, for example, provides a maximum possible stroke movement of approximately 1100 mm from the foremost to the rearmost end position, and material is shredded in the shredder device which does not require a stroke movement of 1100 mm, then the stroke movement can be reduced, for example to 50%, by electronic limitation. Thereby, the substantial control parameters remain unaffected. Due to the electronical limitation, the throughput rate can be increased, because the dead time for the unnecessary stroke movement is eliminated and the cycle time can be reduced. This makes it possible for the customer to react in a material-specific manner, without mechanical adjustment operations need to be performed at the shredder device, for example a time-consuming adjustment of sensors. That provides an increased throughput rate in relation to the lifetime of the shredder device.
A further preferred operating mode is that the control and/or regulating device determines a change of a path covered by the at least one feed device based on the measuring signals generated by the at least one measuring device. Preferably, a change of the path is compared to at least one predetermined threshold value, and, in the case the at least one threshold value is reached, the direction of movement of the at least one feed device is reversed.
In that way, for example, a jamming of the at least one feed device with material can be automatically detected at an early stage. If the at least one feed device is in its active operation, then a change in position is detected by the control and/or regulating device. If the value falls below a defined threshold value, and the motor current drops below a given threshold value, a free-cutting situation is present. An inward travel movement of the at least one feed device is automatically performed. If this also does not lead to a change in position or travel distance of the at least one feed device, then that is a clear indication that the at least one feed device is jammed. This automatic detection of a jam is not possible in the state of the art.
And eventually, it has been proven to be advantageous that the control and/or regulating device transmits a malfunction, detected by the control and/or regulating device based on the measuring signals generated by the at least one measuring device, to at least one indicator device. Preferably, the at least one indicator device includes a display screen. In this way, the malfunction can immediately be recognized by an end user.
In specific terms, it is appropriate, for example, that a transmittal to the at least one indicator device is to be effected when, after a cleaning procedure which has been activated several times for the at least one shredder rotor, no improvement in the advance of speed, or, respectively, the removal performance is found.
Further details and advantages of the invention will be explained in the following description of figures with reference to the drawings, in which:
Material to be shredded is fed to the shredder device 1 by a material delivery chamber 20. In addition, a feed device 4 is rotationally supported about a rotational axis 22 on the sidewalls of the shredder device 1. The feed device 4 conveys the material to be shredded further to a shredder rotor 3 (cannot be seen in
As can be seen from the sectional view according to
Instead of such a pivotable feed device 4, a linearly displaceable feed device may also be employed.
The pusher 24 or, respectively, the feed device 4 moves along a wall portion 21, namely between a first end position 5 and a second end position 6. The first end position 5 is arranged adjacent to a shredder rotor 3 and the second end position 6 is spaced therefrom. Thereby, the pusher 24 or, respectively, the feed device 4 can assume any position between these two end positions 5 and 6. The positions through which the device passes in that case are indicated by a dash-dotted line 35. In order to move the pusher 24 or, respectively, the feed device 4 from the first position 5 into the second end position 6, the pusher 24 rotates about the pivot point 34 in an anticlockwise direction, in the view shown in
The feed device 4 is driven by two hydraulic piston-cylinder-devices 15, each having a cylinder 29 and a piston movable therein, the piston having a piston rod 30. In the illustrated case, the cylinder 29 is arranged on the machine frame 2. The piston rod 30 is hingedly connected to the lever arm 23 via an intermediate lever 25. Of course, a reversed configuration may also be used, in which the piston rod 30 is arranged on the machine frame 2 and the cylinder 29 acts on the intermediate lever 25.
The piston-cylinder-device 15 and the intermediate lever 25 are each arranged in a sidewall of the shredder device 1. The intermediate lever 25 is connected to the lever arm 23 in a torque-proof manner.
The material conveyed by the feed device 4 to the shredder rotor 3 is shredded by cutting devices arranged at a periphery of the shredder rotor 3 and stationary counterpart blades 26, more specifically until the material is at a given degree of shredding which is adjustable by a sieve device 27. Via the sieve device 27, the shredded material reaches to the outside and can be carried away, for example by conveyor belts.
The shredder rotor 3 is rotationally supported about a pivot point 36 on the machine frame 2. The directions of rotation are denoted with the reference number 17 and with a double-headed arrow.
As already stated in the opening part of this specification and as shown in
The position of the feed device 4 determined thereby serves as a starting point for the advantageous embodiments described hereinbefore of the process for operating the shredder device 1.
The control and/or regulating device 10 can be connected in a signal-conducting manner to an indicator device 19 in order to provide information to a user of the shredder device 1, for example about malfunctions which cannot be automatically resolved.
It is not necessary to arrange the measuring devices 28, 7, 8 and 9 indicated in the figures on the depicted locations of the feed device 4. Any appropriate location can be used here. It is also not mandatory that the measuring devices 28, 7, 8 and 9 are directly coupled to the at least one feed device 4. For example, an arrangement in a wall, along which the at least one feed device 4 moves, is also possible. A configuration in the form of a magneto-resistive sensor can be used here.
| Number | Date | Country | Kind |
|---|---|---|---|
| 17187514 | Aug 2017 | EP | regional |
| Number | Name | Date | Kind |
|---|---|---|---|
| 4061280 | Box | Dec 1977 | A |
| 4127236 | Lasar | Nov 1978 | A |
| 4394984 | Hight | Jul 1983 | A |
| 4423844 | Sours et al. | Jan 1984 | A |
| 4655403 | Sciortino | Apr 1987 | A |
| 5209413 | Dwyer | May 1993 | A |
| 5379955 | McGraw | Jan 1995 | A |
| 5417374 | Kranz | May 1995 | A |
| 5695134 | Williams | Dec 1997 | A |
| 5988544 | Williams, Jr. | Nov 1999 | A |
| 6016979 | Squires et al. | Jan 2000 | A |
| 6405949 | Maguire | Jun 2002 | B1 |
| 7905437 | Rota | Mar 2011 | B2 |
| 7926753 | Carver | Apr 2011 | B2 |
| 8733682 | Schiffer | May 2014 | B2 |
| 9221612 | Strautmann | Dec 2015 | B2 |
| 9795969 | Lindner | Oct 2017 | B2 |
| 9968939 | Berglitsch | May 2018 | B2 |
| 10695771 | Friz | Jun 2020 | B2 |
| 20070029418 | Jakobi | Feb 2007 | A1 |
| 20110240775 | Colombo | Oct 2011 | A1 |
| 20120018555 | Schiffer | Jan 2012 | A1 |
| 20150060585 | Fialho | Mar 2015 | A1 |
| 20150129697 | Berglitsch | May 2015 | A1 |
| 20150158030 | Lindner | Jun 2015 | A1 |
| 20160288133 | Friz | Oct 2016 | A1 |
| 20180214885 | Garin Rotondaro | Aug 2018 | A1 |
| 20190054474 | Pischon | Feb 2019 | A1 |
| 20200121823 | Aner, Sr. | Apr 2020 | A1 |
| Number | Date | Country |
|---|---|---|
| 20 2012 004 224 | Jul 2012 | DE |
| Entry |
|---|
| English translation for DE202012004224 May 16, 2012. |
| International Search Report dated Nov. 12, 2018 in International (PCT) Application No. PCT/EP2018/072422. |
| Number | Date | Country | |
|---|---|---|---|
| 20200179938 A1 | Jun 2020 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | PCT/EP2018/072422 | Aug 2018 | US |
| Child | 16794352 | US |
