EP1166879A1 - Device and method for comminuting bulky, household and industrial refuse and the like - Google Patents

Abstract

The invention relates to a device and a method for comminuting bulky, domestic and commercial waste and the like. The device has at least a first (10) and a second shaft (20), which are rotatably mounted about their horizontal longitudinal axes, and on which The circumference of the shafts with gaps (14, 24) arranged in the axial direction. In the method, the two parts of the crushing tools (14, 24) move in normal operation with different speeds and thereby mesh with each other, so that moments of force for crushing the bulky waste between at least one crushing tool (14) of the first axis (10) and a crushing tool ( 24) of the second axis (20) are generated. <IMAGE>

Description

The invention relates to a device for crushing bulky waste, household and Commercial waste and the like, with at least a first and a second wave, which in a machine frame rotatable about its substantially horizontal Longitudinal axes are supported and can be driven by at least one drive. there the waves define a gap between them. The device also has the circumference of the shafts with axially intervening for breaking crushing tools arranged in sufficiently wide spaces.

The invention further relates to a method for crushing bulky waste, household and industrial waste and the like by means of crushing tools by at least one Drive are driven. A first part of the tools is around a first one, in Main horizontal axis and a second part of the tools is around one second, essentially horizontal axis rotatable.

Devices and tools of this type are known. Are also known Shredding devices with sharp-edged, disc-like cutting tools known with sawtooth-shaped claws axially on two parallel shafts are offset from one another and are arranged so that they are mutually comb through the garbage while shearing. The disadvantage of these devices or The corresponding procedure is that the edges of the cutting tools are very wear out quickly. These therefore often have to be reground or even replaced become. In this respect, the process is very maintenance-intensive.

In all known devices and methods of this or the one described above The tools protrude radially over the circumference of the type Waves out. The tools are spaced axially on each of the tools Waves arranged. They comb through as the waves rotate a side comb that is essentially in a horizontal plane on the Gap opposite side of each of the shafts is arranged stationary. Both Shafts have the same circumference and rotate in normal operation during the Shredding synchronously, i.e. the tools have the same speed and move in the opposite direction, viewed from above.

Another known shredding device has on both shafts in Alternate circumferential direction several tools and intermediate Recesses on. The tools and recesses of one shaft are closed those of the others arranged offset in the circumferential direction, so that in the synchronous Rotation of both shafts a tool of the one shaft into a recess between two successive tools in the circumferential direction engages another wave.

A comminution device of the type described in the opening paragraph has one in the Gap between the two waves arranged middle comb. The middle ridge has a comb structure on both sides with alternating grooves and webs, which by is combed through the tools of the shafts bordering on both sides. The tools consist of double-sided in and against the direction of rotation Hooks the garbage during the synchronous rotation of both shafts in normal operation in the direction of the middle ridge. The garbage is combed through the Middle comb through the moments of force between the rotating tools and the fixed ridges of the middle ridge broken or torn and not cut. Accordingly, the grooves are in this shredding device the combs significantly wider than the width of the tools in the axial direction. The Tools are designed as crushing tools, i.e. they need just like that Middle ridge no sharp edges. The device is therefore not as prone to wear.

So-called problem substances, for example garbage with components that can be removed of the device described last can not be easily crushed, cause regularly the following problems: flexible problem substances, e.g. Rolls of carpet, are transported by the crushing tools towards the central ridge, there but not captured enough to be shredded. Such problematic substances are deposited on the webs. Other problematic substances are too massive, so that Forces of the device are not sufficient to shred it at once. On yet another problem arises when typically through a funnel Rubbish fed above the waves without using the crushing tools on the Waves come into contact in the funnel canting and slipping prevented further garbage.

Known procedural steps for eliminating such malfunctions provide to reverse the direction of rotation of the shafts if an overload or underload is detected. During the so-called reversing operation, the conveying direction is Breaking tools consequently vice versa, the shafts continue to rotate synchronously. The problematic materials and other waste are partly shredded, partly shredded transported out of the gap above the webs of the middle ridge and can also loosen tilted garbage. With subsequent reversal of the However, the problematic substances are often turned into their direction of rotation in normal operation old position back between the two waves. It may be Many such reversing processes are necessary to break the problematic materials feed in a different orientation and finally shred them.

Another problem area are, for example, springs that are about the Wind up hook-shaped breaking tools and / or the shaft and block it or at least their effective insert length, i.e. the clear height of the crushing tools over wave surface. Such springs can are not wiped off the combs in normal or reverse operation.

The invention is therefore based on the object of a comminution device and a shredding process for bulky waste, domestic and commercial waste and the like create that is less prone to failure with comparable effort.

The object is achieved by a device for comminuting Bulky waste, household and commercial waste and the like, with the characteristics of the beginning described type solved in the normal operation, the speed of the crushing tools the first wave higher than the speed of the crushing tools is second shaft and at least the first shaft has a direction of rotation that seen from above in the direction of the gap and their breaking tools are arranged and dimensioned on the first and the second shaft in such a way that due to the relative movement during the rotation of the shaft (s) at least one Breaking tool of the first shaft into a space between two breaking tools the second shaft and / or at least one breaking tool of the second Shaft into a space between two crushing tools of the first shaft intervenes.

In a method of the type described in the introduction, the object is achieved according to the invention solved by positioning the two axes so that both parts of the crushing tools in normal operation at different speeds, at least by rotating the first part of the crushing tools of seen above in the direction of the second axis, and intermeshing relative to each other move, creating moments of force to crush the garbage essentially between at least one breaking tool of the first axis and one Breaking tool of the second axis are generated.

In a preferred embodiment, the directions of rotation are in normal operation opposite waves, oriented towards each other when viewed from above.

The advantage of the invention is that the moments of force for comminution of the garbage between two movable at different speeds Breaking tools arise while in the known crushing devices one of the interacting elements, namely the central ridge, is stationary and only the breaking tool moves. The moments of power at the known devices are therefore always in and against the first approximation Direction of rotation at the point of penetration of the breaking tool through the central comb directed. In the device according to the invention or the corresponding The crushing tools, which are engaged in pairs in each case, can be used Positions vary at different speeds, which for one different pairs of crushing tools can be engaged and on the other hand the position of the crushing tools in pairs may be different at the time of the intervention. The directions of the moments of force are thus more diverse than the known devices, what malfunctions avoids the described type in many cases.

In the preferred embodiment, the different speeds of the breaking tools of both shafts in that the shafts are the same Scope and the crushing tools of the first shaft and the crushing tools of the second wave each have the same headroom, but the waves asynchronously are driven, i.e. the speed of the first shaft is higher than the speed the second wave is.

In an advantageous embodiment of the invention, the crushing tools have the first wave and the second wave each have an asymmetrical fin-shaped Hook profile, which in the case of the first shaft in its direction of rotation and in the case of second shaft opposite to the direction of rotation is curved during normal operation.

The shape of the crushing tools, which are tapered towards their outer end, enables automatic cleaning during the rotation of the shafts Wiping off problematic substances, for example around the breaking tools have wound up on two fixed combs, each on the gap horizontally opposite side of the shafts and parallel to them in the machine frame are arranged. The orientation of the crushing tools on the second Welle enables this during normal operation. The crushing tools of the first If necessary, the shaft can be cleaned in reverse operation.

The method preferably includes the direction of rotation and / or the speed to switch both shafts when an overload or an underload is detected. The is achieved according to the invention in that the shafts or their drives are each equipped with (torque) sensors that are dependent on the an analog or digital torque is required to shred the waste Generate load signal, along with at least one preselectable threshold for an overload and / or an underload by a controller to one Control signal for driving the shafts to control the direction of rotation and / or Speed is processed.

If an overload is determined in a first step, the direction of rotation is advantageous of the second part of the crushing tools while maintaining the lower Reverse speed and in a second step the direction of rotation of the first Reverse some of the crushing tools while maintaining the higher speed and increase the speed of the second part of the crushing tools.

By gradually reversing the direction of rotation and the meshing relative movement the breaking tools of both shafts - unlike the state of the Technology - the garbage is not only transported out of the gap, but partly reoriented and partly still crushed. Only in the second step of the Reversing mode is the direction of conveyance of both shafts from the center of the gap directed upwards. The garbage is due to the same speed of both shafts no longer in the gap but only in cooperation with the side combs crushed.

Fig. 1

eine Draufsicht auf einen Ausschnitt zweier Wellen einer Ausführungsform der erfindungsgemäßen Vorrichtung zum Zerkleinern von Sperrmüll, Haus- und Gewerbemüll und dgl.;

Fig. 2

eine Seitenansicht derselben Ausführungsform der erfindungsgemäßen Vorrichtung im Schnitt;

Fig. 3

eine Draufsicht auf einen Ausschnitt zweier Wellen einer zweiten Ausführungsform der erfindungsgemäßen Vorrichtung;

Fig. 4

eine Seitenansicht der zweiten Ausführungsform der erfindungsgemäßen Vorrichtung im Schnitt.

Further advantages of the invention are explained on the basis of a preferred exemplary embodiment in the following figures. Show it:

Fig. 1

a plan view of a section of two waves of an embodiment of the device according to the invention for crushing bulky, domestic and commercial waste and the like .;

Fig. 2

a side view of the same embodiment of the device according to the invention in section;

Fig. 3

a plan view of a section of two shafts of a second embodiment of the device according to the invention;

Fig. 4

a side view of the second embodiment of the device according to the invention in section.

The exemplary embodiment from FIG. 1 has a first shaft 10 and a second Shaft 20, which are arranged parallel to each other. The two waves have same perimeter and are spaced apart so that they are between them define a gap 11. The first shaft 10 has on its peripheral surface 12 a variety of crushing tools 14, both in the circumferential direction also spaced axially from the adjacent crushing tools are. All crushing tools 14 have the same width in the axial direction. As well are all distances between two axially adjacent crushing tools equal. This results in circumferential spaces 16, which are rotating in the axial direction with arrangements in the circumferential direction Alternate crushing tools 14. Similarly, is on the peripheral surface 22nd the second shaft 20 a plurality of crushing tools 24 arranged so that circumferential spaces 26 with an arrangement in Alternate circumferential direction of rotating tools 24. The crushing tools 24 of the second shaft 20 are offset in the axial direction from the crushing tools 14 of the first shaft 10 is arranged so that it with the spaces 16 correspond. The crushing tools 14 correspond in a corresponding manner with the gaps 26. The breaking tools 24 are on the second shaft wider in the axial direction than the breaking tools 14, but narrower than the gaps 16 between the crushing tools 14 on the first shaft, whereby in each case gaps 13 between the interlocking in the area of the gap 11 Breaking tools arise.

Both the breaking tools 14 and the breaking tools 24 have a clear Height above the respective circumferential surface 12 or 22 of the waves, which is slightly less is than the width of the gap 11 between the waves, so that also between the front ends of the crushing tools and the opposite Waves gaps 15 arises.

Furthermore, the crushing tools 14 as well as the crushing tools 24 are theirs nearest neighbors on the same shaft in axial and radial Direction staggered so that seen in the circumferential direction Form a V-shaped grouping.

2 shows the same embodiment of the invention Device with a machine frame 30 that on its top a funnel-shaped opening 32 for filling the garbage and on its underside has a section 34 with straight vertical side walls between which the arrangement of both shafts 10, 20 is. On both straight side walls of the housing is a side comb pointing in the direction of the waves 36, 38 arranged. The teeth of the side ridges protrude close to the peripheral surfaces 12, 22 of the shafts and are arranged in the axial direction so that they engage in the spaces 16, 26 between the crushing tools 14, 24 (not recognizable in this view).

The direction of rotation of the shafts is indicated by arrows 18 and 28 respectively. The arrow 18 indicates that the shaft 10 according to FIG. 2 is clockwise, ie from above seen in the direction of the gap 11 rotates. Shaft 20 rotates according to arrow 28 counterclockwise and viewed from above also in the direction of the gap 11. The length of the arrows also indicates that the shaft 10 is in the operating mode 2 rotates at a higher speed than shaft 20. Exemplary Speeds for the first shaft 10 is 40 revolutions per minute and accordingly 5 revolutions per minute for the second shaft 20.

The crushing tools 14 and 24 can be seen in this view in profile. she have a fin-shaped hook profile and are the same on both shafts Arranged way. The curvature of the breaking tools 14, 24 points in relation to the Direction of rotation in the case of the first shaft 10 in the same direction while the crushing tools 24 of the second shaft 20 are curved against their direction of rotation. In each case, an arrangement of circumferential breaking tools 14, 24 on each of the shafts consists of four of these crushing tools in angular increments of 90 °.

3 and 4 show an embodiment of the device according to the invention, which differs from the first exemplary embodiment in the number, arrangement and configuration of the breaking tools. In Fig. 3 it can be seen that the width of the crushing tools 14 ', 24' of both shafts in the axial direction is the same. The section (FIG. 4) shows that the first shaft 10
only has arrangements of two opposing crushing tools 14 'in the circumferential direction. The second shaft 20, however, is equipped with an annular arrangement 25 ', each of which contains 6 breaking tools 14' in angular steps of 60 °. The directions of rotation 18, 28, rotational speeds and orientations of the tools are the same as those of the first embodiment.

The operating mode indicated by the arrows 18, 28 according to FIGS. 2 and 4 is the normal operation of the device, that is, the operation for comminuting the Waste. Due to the direction of rotation of both shafts, garbage that is above the shafts is filled in the funnel of the housing 30 and with the crushing tools Waves come into contact, first transported in the direction of the gap 11. by virtue of the higher speed of the shaft 10, the breaking tools 14 move in the gap 11 with a relative speed on the breaking tools 24 of the Wave 20 to. The arrangement of the breaking tools 14, 14 'is combed through them How the arrangement of the crushing tools 24, 24 ', see. Fig. 1 and Fig. 3, and crushes the garbage transported into the area of the gap 11. The crushing tools 24, 24 'of the shaft 20 take over the function of the known fixed Middle crest, however, are due to their independent movement in contrast, much more flexible.

It can be seen that due to the different rotational speeds, which differ in the two exemplary embodiments Speeds of both shafts with the same shaft circumference results in the angular position of the Shaft 10 and thus the arrangement of the breaking tools 14, 14 'relative to the Angular position of the shaft 20 and the arrangement of the breaking tools 24, 24 ' constantly varies. This allows a large number of different moments of force caused by the relative movement of the crushing tools of both shafts whose direction spans a wide range from horizontal to vertical. The same effect is also achieved by arranging one for both waves different extent but have the same speed.

1 occurs due to the v-shaped grouping of adjacent tools always on each of the shafts in connection with the different speeds a different pair of opposing crushing tools 14, 14 'and 24, 24 'interact.

The curvature of the breaking tools 24, 24 'against the direction of rotation of the corresponding one Shaft 20 causes, if necessary, the crushing tools 28 coiled wire or accumulated garbage during normal operation and the side comb 38 can be stripped.

The first stage of the so-called Reversing operation in a reversal of the direction of rotation 28 of the shaft 20. The shafts still rotate asynchronously, i.e. the speed of the shaft 20 is maintained, while the shaft 10 continued at the same, higher speed and in the rotates in the same direction of rotation as before in normal operation. The result of this first stage is that the moments attacking the garbage to be shredded have different directions than normal operation. For example, kick on the column entry side on top of both shafts by the fast Rotation of the shaft 10 in the left region of the gap 11 downward forces and by the rotation of the shaft 20 in the right area of the gap 11 upwards directed forces. On the one hand, this creates a torque by that the waste is fed to the following crushing tool in a different orientation can be. On the other hand, the crushing tools of both shafts move in the The center of the gap continues against each other, causing a body to enter the gap can also be crushed in the first stage of reversing operation. The crushing tools 24, 24 'of the second shaft 20 move in this operating mode also towards the side comb in the direction of its curvature and can consequently break up the garbage at this point.

Rotate in the second stage of the reverse operation of the exemplary method both waves 10, 20 synchronously, i.e. at the same speed in opposite Direction seen from above out of the gap. In this mode of operation occurs no more relative movement of the crushing tools, the moments of force Cause shredding of the garbage. The garbage is only made in this position the gap center 11 transported out.

The crushing tools 14, 14 'on the shaft 10 rotate in the second stage of the Reverse operation in the opposite direction of their curvature and can thus any garbage or coiled wire deposited on the side comb 36 strip. Unlike the breaking tools 24, 24 ', these continue to move in Direction of their curvature towards the corresponding side comb and can break garbage there.

Claims (19)

Device for crushing bulky waste, domestic and commercial waste and the like, with at least a first and a second shaft (10, 20), which are rotatably mounted in a machine frame about their essentially horizontal longitudinal axes, which can be driven by at least one drive and which define a gap (11) between them, and with breaking tools (14, 24) arranged on the circumference of the shafts (10, 20) with intermediate spaces (16, 26) which are sufficiently wide for breaking in the axial direction,
characterized in that in normal operation the speed of the breaking tools (14) of the first shaft (10) is higher than the speed of the breaking tools (24) of the second shaft (20) and at least the first shaft (10) has a direction of rotation (18), which is viewed from above in the direction of the gap (11), and that the breaking tools on the first and the second shaft are arranged and dimensioned such that at least one breaking tool (14) due to the relative movement during the rotation of the shaft (s) first shaft (10) into an intermediate space (26) between two crushing tools (24) of the second shaft (20) and / or at least one crushing tool (24) of the second shaft (20) into an intermediate space (16) between two crushing tools (14) engages the first shaft (10). Device according to claim 1,
characterized in that in normal operation the directions of rotation (18, 28) of the two shafts (10, 20) are oriented in opposite directions, viewed from above. Device according to one of claims 1 or 2,
characterized in that the width of the crushing tools (14, 24) in the axial direction is substantially smaller than the width of the intermediate spaces (26, 16) in which they respectively engage. Device according to claim 3,
characterized in that the gap (11) between the shafts is parallel and the clear height of the crushing tools over the circumferential surfaces of the shafts is in each case substantially less than the width of the gap (11). Device according to claim 4,
characterized in that the width of the crushing tools (14) of the first shaft (10) and the width of the crushing tools (24) of the second shaft (20) are uniform in the axial direction. Device according to claim 5,
characterized in that the breaking tools (14) of the first shaft (10) are narrower than the breaking tools (24) of the second shaft (20) in the axial direction of the shafts. Device according to one of the preceding claims,
characterized in that the first and second shafts have the same diameter and the crushing tools (14) of the first shaft (10) and the crushing tools (24) of the second shaft (20) have the same clear height and the speed of rotation of the first shaft (10 ) is higher than the speed of the second shaft (20). Device at least according to claim 2,
characterized in that the crushing tools (24) of the second shaft (20) have an asymmetrical fin-shaped hook profile which is curved against the direction of rotation (28) of the second shaft (20) during normal operation. Device according to one of claims 1 to 8,
characterized in that the breaking tools (14) of the first shaft (10) have an asymmetrical fin-shaped hook profile which is curved in the direction of rotation (18) of the first shaft (10) during normal operation. Device according to one of the preceding claims,
characterized by two fixed combs, each of which is arranged on the side of the shafts (10, 20) horizontally opposite the gap (11) and parallel to them in the machine frame for cleaning the crushing tools (14, 24), the tines of which are each of a width, which essentially corresponds to the width of the intermediate spaces (16, 26), a distance in the axial direction which essentially corresponds to the width of the respective crushing tools, and a length which corresponds to the height of the crushing tools above the respective peripheral surfaces of the shafts. Device according to one of the preceding claims,
characterized in that the shafts or their drives are each equipped with (torque) sensors which generate an analog or digital load signal depending on the torque required to shred the waste. Device according to claim 11,
characterized by a controller which processes the load signal together with at least one preselectable threshold value for an overload and / or an underload to form a control signal for driving the shafts for controlling the direction of rotation and / or speed. Method for crushing bulky waste, domestic and commercial waste and the like by means of crushing tools which are driven by at least one drive, in which the first part of the crushing tools (14) about a first, essentially horizontal axis and the second part of the crushing tools (24 ) is rotatable about a second, essentially horizontal axis,
characterized in that both axes are set in relation to one another in such a way that both parts of the crushing tools move in a meshing manner relative to one another in normal operation, at least by rotating the first part of the crushing tools (14) as seen from above in the direction of the second axis, thereby creating moments of force for crushing the waste essentially between at least one crushing tool (14) of the first axis and one crushing tool (24) of the second axis. A method according to claim 13,
characterized in that in normal operation the directions of rotation (18, 28) of the first and second parts of the crushing tools (14, 24) are oriented in opposite directions, viewed from above. The method of claim 14
characterized in that in normal operation the speed of the first part of the breaking tools (14) is higher than the speed of the second part of the breaking tools (24). Method according to one of claims 13 to 15,
characterized by an individual, load-dependent control of the speed and direction of rotation of both parts of the crushing tools. A method according to claim 16,
characterized in that the direction of rotation and / or the speed of both parts of the crushing tools are switched when an overload or an underload is detected. The method at least according to claim 15,
characterized in that when an overload is detected, the direction of rotation of the second part of the crushing tools (24) is reversed in a first step while maintaining the lower speed and in a second step the direction of rotation of the first part of the crushing tools (14) is reversed while maintaining the higher speed and the speed of the second part of the breaking tools (24) is increased. The method at least according to claim 15,
characterized in that upon detection of an underload in one step the directions of rotation of both parts of the breaking tools (14, 24) are reversed and the speed of the second part of the breaking tools (24) is increased.

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