阅读说明：本技术 具有可控制拉入机构的粉碎装置 (Crushing device with controllable drawing-in mechanism ) 是由 皮特·希弗 马里奥·弗利茨 于 2018-07-26 设计创作，主要内容包括：根据本发明的粉碎装置(100)包括用于供给待粉碎材料的供给开口(10)、用于粉碎供给到装置的材料的粉碎轴(20),以及设置于供给开口(10)和粉碎轴(20)之间并由切割室壁(40a,40b)界定的切割室(30)。根据本发明的粉碎装置的特征在于切割室壁(40a)是能枢转的。本发明还涉及一种对应方法。(The comminution device (100) according to the invention comprises a feed opening (10) for feeding material to be comminuted, a comminution shaft (20) for comminuting the material fed to the device, and a cutting chamber (30) which is arranged between the feed opening (10) and the comminution shaft (20) and is delimited by cutting chamber walls (40a, 40 b). The comminution device according to the invention is characterized in that the cutting chamber wall (40a) is pivotable. The invention also relates to a corresponding method.)

1. A comminution device comprising:

a feed opening for feeding material to be comminuted into the cutting chamber; and

at least one crushing shaft for crushing the supplied material,

wherein the cutting chamber is arranged between the feed opening and the comminution shaft and is delimited by cutting chamber walls,

the method is characterized in that:

at least one cutting chamber wall is pivotable, in particular in order to control the pulling-in action of the supplied material to the comminution shaft on the basis of its own weight.

2. Comminution device as claimed in claim 1, wherein the at least one cutting chamber wall can be pivoted during operation of the comminution device, in particular it can be pivoted in an automatically controlled manner, or wherein the at least one cutting chamber wall can be pivoted outside the operation of the comminution device, in particular can be pivoted manually.

3. Comminution device as claimed in claim 1 or 2, wherein the cutting chamber wall is pivotable about a pivot axis parallel or substantially parallel to the axis of rotation of the comminution shaft, in particular wherein the pivot axis is provided at a lower end of the cutting chamber wall.

4. The crushing apparatus as claimed in any one of claims 1 to 3, further comprising:

a pressing device for pressing the material to be crushed against the crushing shaft.

5. A comminution device as claimed in claim 4 in which the pressure application device is pivotable with the cutting chamber wall.

6. A comminution device as claimed in claim 4 or 5, wherein the pressure application device is rotatable about a rotation axis, in particular wherein in combination with claim 3 the rotation axis is arranged parallel or substantially parallel to the pivot axis but offset therefrom.

7. A comminution device as claimed in claim 6 in which the cutting chamber wall comprises a cylindrical portion and the axis of rotation of the pressure applicator is disposed on the axis of the cylinder.

8. A comminution device as in any preceding claim further comprising:

a control device for adjusting the pivot angle of the cutting chamber wall.

9. A comminution device as in claim 8, wherein the control device

During operation of the crushing device, the pivot angle is controlled depending on the load applied to the crushing shaft and/or the torque applied to the crushing shaft and/or the current supplied to an electric motor driving the crushing shaft and/or the hydraulic pressure supplied to a hydraulic motor driving the crushing shaft and/or the operating state of an internal combustion engine driving the crushing shaft, in particular wherein the pivot angle is adjusted such that the pull-in action is reduced when the load and/or the torque and/or the current and/or the hydraulic pressure is increased.

10. Method for operating a comminution device which comprises a feed opening, a comminution shaft and a cutting chamber which is arranged between the feed opening and the comminution shaft and is delimited by cutting chamber walls, and wherein the method comprises:

feeding material to be crushed into the feed opening; and

the supplied material is pulverized by the pulverizing shaft,

the method is characterized in that:

pivoting at least one cutting chamber wall to control the pull-in action of the supplied material to the comminution shaft based on its own weight.

11. The method of claim 10, wherein the pivoting step comprises:

pivoting, in particular automatically controlled pivoting, the at least one cutting chamber wall during operation of the comminution device; or

Pivoting the at least one cutting chamber wall, in particular manually, outside the operation of the comminution device.

12. The method of claim 10 or 11, comprising the steps of:

pressing the material to be pulverized against the pulverizing shaft.

13. The method according to one of claims 10-12, comprising the steps of:

the pivot angle is adjusted during operation of the comminution apparatus in dependence on the load applied to the comminution shaft and/or the torque applied to the comminution shaft and/or the current supplied to an electric motor driving the comminution shaft and/or the hydraulic pressure supplied to a hydraulic motor driving the comminution shaft and/or the operating state of an internal combustion engine driving the comminution shaft.

14. The method of claim 13, wherein the pivot angle is adjusted such that the pull-in action is reduced as the load and/or the torque and/or the current and/or the hydraulic pressure increases.

Technical Field

The invention relates to a comminution device comprising a feed opening for feeding material to be comminuted, a comminution shaft for comminuting the feed material and a cutting chamber arranged between the feed opening and the comminution shaft and delimited by cutting chamber walls.

Background

Commercial waste, industrial waste, household waste, etc., such as (hard) plastics, textiles, composites, rubber or waste wood (e.g. pallets and particle boards) need to be comminuted before final disposal or especially return to circulation. Single-shaft or multi-shaft mills, which are fed, for example, by wheel loaders, forklifts or conveyor belts through hoppers for material feeding, are known for crushing these waste materials.

A typical shredder comprises a rotor unit in the cutting chamber, which comprises one or more shredding shafts provided with tearing hooks or knives. The tool is fastened, for example, by screwing onto a tool carrier, which can be welded into the pocket or screwed onto it, which is milled into the comminution shaft. The comminution of the feed material takes place between a knife rotating with the comminution shaft and a stationary, i.e. non-rotating counter knife (stationary knife, scraper comb). The rotor unit is driven by an electric machine (e.g., an internal combustion/electric motor).

The general pulverizer may further include a second pressing part that pushes or presses the feeding material in a direction of rotating the rotor. After comminution between the rotating knives and the counter knives, the material can be discharged through a screening device (if present) that determines the comminution factor depending on the size of the screen and can be further transported by using a conveyor belt, a transport screw, a chain conveyor or an extraction system or the like. The still oversized material is returned to the cutting chamber by the above-mentioned rotation.

For efficient comminution performance, it is very important to permanently feed the material to the cutting zone.

There are generally two different approaches here:

flat cutting chamber wall

Some shredding devices have at least one flat cutting chamber wall, which delimits the cutting chamber on one side, together with a pressing system or a second pressing system that presses the material towards the rotor or the counter knife. This may be, for example, a propeller or screw conveyor. Flat means that the walls of the cutting chamber close to the comminution axis are at a small angle (e.g. within +/-20 °) to the horizontal.

The advantage here is that by reducing the pressure of the second pressure application portion, even material that is difficult to crush can be crushed without the machine stopping due to overload. However, a disadvantage is that the throughput capacity of the machine is greatly reduced during retraction of the second pressure application portion. On the other hand, an easily comminuted material requires a great force and energy from the second pressure application portion in order to achieve a higher throughput rate.

Steep cutting chamber wall

Other comminution devices are acted upon by steep or even vertical cutting chamber walls, so that the material slides automatically into the cutting zone due to its own weight, resulting in a better pulling-in action. In addition, a second pressing portion may be installed. Steep means that the cutting chamber wall near the comminution axis is at a relatively large angle (e.g. more than 45 °) to the horizontal. If the cutting chamber wall is curved upwards, it will be at a greater angle to the horizontal at the upper end of the cutting chamber wall.

Without the second pressing, the throughput rate of the material averaged over a determined period of time may be designated as a pull-in mechanism or action.

Here a more constant throughput capacity/throughput rate is advantageous, since the material slides permanently to the cutting area. The disadvantage is that it is not possible to pulverize difficult-to-pulverize materials (e.g. solids and/or coarse material) or only by means of greater force or energy consumption of the rotor or for permanently low quantities of feed material.

Disclosure of Invention

The object of the invention is to at least reduce defects in the case of steep cutting chamber walls with a material drawing action.

The comminution device according to the invention is suitable for the above-described waste material in connection with the prior art.

This object is achieved by a comminution device according to patent claim 1.

The comminution device according to the invention comprises a feed opening for feeding material to be comminuted, a comminution shaft for comminuting the fed material, and a cutting chamber which is arranged between the feed opening and the comminution shaft and is delimited by a cutting chamber wall. The comminution device according to the invention is characterized in that the cutting chamber wall is pivotable.

The crushing device according to the invention has the advantage that by pivoting the cutting chamber wall, the pulling-in action of the fed material to the crushing shaft based on its own weight can be controlled.

The waste crushing apparatus according to the present invention can be further improved as follows.

During operation of the crusher, at least one cutting chamber wall can be pivoted, in particular it can be pivoted in an automatically controlled manner. In addition, or alternatively, the at least one cutting chamber wall can be pivoted, in particular manually pivotable, outside the operation of the comminution device.

A further refinement consists in that the cutting chamber wall can be pivoted about a pivot axis which is parallel or substantially parallel to the axis of rotation of the comminution shaft, wherein in particular the pivot axis can be arranged at the lower end of the cutting chamber wall. The angle between the direction (or direction vector) substantially parallel to the axis of rotation, meaning the crushing axis, and the direction (or direction vector) of the pivot axis is 10 ° or less, preferably 5 ° or less, more preferably 2 ° or less. Thus, the angle between the axes also defines an oblique axis with the angle between the directional vectors. In this way, the walls of the cutting chamber located close to the comminution shaft and/or the comminution shaft can be fed uniformly along the shaft or the comminution shaft.

According to another refinement, the comminution apparatus can also comprise a pressure device for pressing the material to be comminuted against the comminution shaft. The pressing means causes the material to be crushed which is temporarily pressed against the crushing shaft to have a higher pressure to improve the throughput.

Another improvement consists in that the pressure applicator is pivotable together with the cutting chamber wall. This has the advantage that the relative position of the pressure applicator with respect to the cutting chamber wall is maintained (kept constant) when the cutting chamber wall is pivoted.

According to a further refinement, the pressure-exerting device can be rotatable about a rotational axis, in particular the rotational axis can be arranged parallel or substantially parallel to the pivot axis but offset therefrom. Substantially parallel means that the angle between the direction (or direction vector) of the axis of rotation and the direction (or direction vector) of the pivot axis is 10 ° or less, preferably 5 ° or less, more preferably 2 ° or less.

The cutting chamber wall may include a cylindrical portion therein, and the rotating shaft of the pressing device may be disposed on a central axis of the cylinder. In this way, the pressure applicator can be located at a constant distance from the cutting chamber wall when the pressure applicator is rotated relative to the cutting chamber wall.

According to a further refinement, the comminution device can also comprise a control device for adjusting the pivoting angle of the cutting chamber wall. This enables the pivoting angle to be automatically adapted to the material to be comminuted when the comminution unit is in operation.

It may also be modified such that the control means adjusts the pivot angle during operation of the crushing means in dependence on the load applied to the crushing shaft and/or the torque applied to the crushing shaft and/or the current supplied to the electric motor driving the crushing shaft and/or the hydraulic pressure supplied to the hydraulic motor driving the crushing shaft and/or the operating state (e.g. the rotational speed) of the internal combustion engine driving the crushing shaft, in particular wherein the pivot angle is adjusted such that the pull-in action is reduced when the load and/or the torque and/or the current and/or the hydraulic pressure is increased.

The aforementioned object is also achieved by a method for operating a comminution device according to patent claim 9.

The comminution device comprises a feed opening, a comminution shaft and a cutting chamber arranged between the feed opening and the comminution shaft and delimited by cutting chamber walls. The method comprises the following steps: feeding material to be comminuted into the feed opening and comminuting the fed material with the comminution shaft, wherein the method is characterized in that the cutting chamber wall is pivoted to control the pulling action of the fed material into the comminution shaft on the basis of its own weight.

According to a further refinement, the pivoting of the at least one cutting chamber wall can take place during operation of the comminution apparatus, in particular by automatically controlling the pivoting; alternatively, the pivoting of the at least one cutting chamber wall can be carried out outside the operation of the comminution device, in particular by manual pivoting.

The method according to the invention can also be modified to have a step of pressing the material to be comminuted against the comminution shaft.

In a further refinement, the following steps can also be provided: the pivot angle is adjusted during operation of the crushing device in dependence on the load applied to the crushing shaft and/or the torque applied to the crushing shaft and/or the current supplied to the electric motor driving the crushing shaft and/or the hydraulic pressure supplied to the hydraulic motor driving the crushing shaft and/or the operating state of the internal combustion engine driving the crushing shaft.

The pivot angle can be adjusted such that the pull-in action is reduced when the load and/or torque and/or current and/or hydraulic pressure increases.

Further features and exemplary embodiments and advantages of the present invention will be explained in detail below with reference to the accompanying drawings. It goes without saying that the present embodiment does not limit the overall scope of the invention. It goes without saying that some or all of the features described below can also be combined in other ways.

Drawings

Figure 1 shows a comminution device according to a first embodiment of the invention;

fig. 2 shows a crushing apparatus according to a second embodiment of the invention.

Detailed Description

Figure 1 depicts a comminution device according to a first embodiment of the invention.

The first embodiment depicted in fig. 1 shows a comminution apparatus 100 with a supply opening 10 for supplying material to be comminuted, a comminution shaft 20 for comminuting the supplied material, and a cutting chamber 30 which is arranged between the supply opening 10 and the comminution shaft 20 and is delimited by cutting chamber walls (only cutting chamber walls 40a and 40b are shown, the two end walls not being shown). According to the invention, the cutting chamber wall 40a can be pivoted during operation of the comminution apparatus 100. The cutting chamber wall 40a is here exemplary designed as a wall which is only partially planar. However, in this first embodiment, differently shaped cutting chamber walls (such as cylindrical according to the second embodiment described below) may also be used.

In this embodiment, the cutting chamber wall 40a is pivotable about a pivot axis 41. The pivot shaft 41 is parallel to the rotation shaft 25 of the pulverizing shaft 20. The crushing shaft 20 comprises rotor cutters 21. In addition to the crushing shaft 20 (several crushing shafts 20 may also be provided), a fixed counter knife 80 is also located in the cutting chamber 30. By rotating the crushing shaft 20 around the rotation shaft 25, the material is crushed between the rotor blade 21 and the opposed blade 80. Optional screen 60 may be used to determine below what size of comminuted material may exit cutting chamber 30. The screen 60 represents the lower limit of the cutting chamber 30.

Fig. 1 shows a first position I in which the cutting chamber walls 40a are arranged at a steep angle, and a second position II in which the cutting chamber walls 40a are arranged at a flat angle. The pulling-in action of the material in the first position I is greater due to its own weight than in the second position II. In this way, the throughput of the comminution apparatus is controllable. Furthermore, adaptation to the material to be comminuted can be achieved. Specifically, in the case where the power supply to the motor (not shown) of the pulverizing shaft 20 is temporarily increased, a flatter angle may be set due to the temporary supply of the coarse material, so as to reduce further supply of the material.

A control device 50 may be provided for adjusting the pivoting angle of the cutting chamber wall 40 a. The control device 50 may adjust the pivot angle during operation of the pulverizing device 100 according to the load applied to the pulverizing shaft 20 and/or the torque applied to the pulverizing shaft 20 and/or the current supplied to the motor driving the pulverizing shaft 20. The pivot angle is adjusted such that the pull-in action is reduced as the load and/or torque and/or current increases, so that the angle of the cutting chamber wall 40a becomes smaller/flatter with respect to the horizontal.

Figure 2 depicts a comminution device according to a second embodiment of the invention.

The crushing apparatus 200 of the second embodiment of the present invention depicted in fig. 2 further includes, unlike the crushing apparatus 100 according to the first embodiment of the present invention, a pressing device 90 for pressing the material to be crushed toward the crushing shaft 20. Wherein the cutting chamber wall 40a is at least partially cylindrical. The pressing device 90 can rotate about the rotating shaft 91. The rotation axis 91 also represents the axis of symmetry of the cylindrical portion of the cutting chamber wall 40 a. The rear cutting chamber wall is made up of two axially adjacent sections 40c and 40d (which are e.g. perpendicular to the axis of rotation 91), wherein the section 40d is connected to the cutting chamber wall 40a and pivots together with the cutting chamber wall 40 a.

Fig. 2A shows a cross-sectional view of the comminution apparatus with the pressure applicator 90 shown in a raised position. In fig. 2B, the pressing device 90 is in the lowered position and presses the material to be crushed against the crushing shaft 20.

Fig. 2C and 2D show the corresponding positions of the pressure applicator 90, but the unit of cutting chamber wall 40a and pressure applicator 90 is pivoted about pivot axis 41, so that cutting chamber wall 40a is steeper and so that a greater pull-in action is produced.

Fig. 2E and 2F show perspective views of fig. 2C and 2B, respectively. However, since these are also cross-sectional views, the front cutting chamber wall is not shown (consisting of two parts like the rear cutting chamber walls 40c, 40 d).

In summary, the cutting chamber wall 40a is not rigid, but pivotable, so that the pull-in action can vary during operation. The control unit 50 detects how much pull-in action is optimal for the existing material. On the one hand, this makes the comminution device 100 more elastic, since it is suitable for a wide variety of materials. On the other hand, many materials can be pulverized more consistently, resulting in increased throughput.

The illustrated embodiments are exemplary only, and the full scope of the invention is defined by the claims.