CH712558A2 - Carrier disk of a soil tillage machine and method for removing dirt and dust from a tillage machine. - Google Patents

Abstract

The invention relates to a carrier disc of a soil tillage machine and a method for removing dirt and dust of a tillage machine. On the front of the carrier disc (1) processing elements are mounted, which produce a suction, which dirt and dust by a plurality of radially arranged openings (2) in the carrier disc (1) from the front to the back of the carrier disc (1) conveys.

Description

Description: [0001] The present invention relates to a carrier disk of a suction-type soil tillage machine according to the preamble of patent claim 1, and to a method for suctioning detached material according to the preamble of patent claim 12.

The constant development of the abrasive elements and in particular the use of diamond grinding has significantly improved the effectiveness of the grinding. A more efficient sanding but also that more material is detached from the bottom surface. The removal of dirt consisting of dust and detached material must therefore be improved accordingly, because their accumulation on the processing elements and on the carrier disk can have undesirable consequences. First, the effectiveness of a dirty processing element is severely impaired. For example, must have abrasive wheels for effective grinding depending on the task, grooves or a rough surface. In it, however, dust or residues of the removed floor covering are constantly fixed, as a result of which the sanding element sticks, becomes smooth, and as a result the abrasive effect decreases or, in extreme cases, no longer exists at all. Secondly, this accumulated dust and dirt adds to the heating of the tool, because on the one hand it stores the heat of friction, and on the other hand hinders the cooling air flow around the processing elements and around the carrier disk. During the grinding process, the temperature of the processing elements and the carrier disk can become severely high. Excessive heat of the material may cause damage to these elements, and the covering to be removed may heat depending on the material depending on the drive tool, which may result in damage to the tool or on the bottom surface or complete failure of the abrasive element.

There are some solutions that deal with the removal of the generated dirt and dust. EP 1 414 619 describes a grinding wheel in which openings have been arranged, through which dirt and dust can be conveyed. To increase the effectiveness of the openings, they must be as long and wide as possible. However, this can affect the stability and durability of the grinding wheel and, due to the size of the openings, the grinding performance is reduced because fewer machining elements can be attached. The dirt and dust in this solution, however, only partially removed because the transport through these openings is not active, but only by accidental turbulence. One option for improvement is to actively suck the dirt and dust through the openings. Usually, the tillage machine is equipped with a powerful industrial vacuum cleaner, with which all the dirt and dust can be absorbed. This not only has the advantage of minimizing the possible damage to the floor and machine, but also avoids contamination of the workplace and thereby reduces the burden on the operator. For these tasks, however, very powerful vacuum cleaners are required because both the finest dust and heavier soil particles are to be removed. The incorporation of such additional suction devices in a tillage machine makes their manufacture more complex and expensive, and the tillage machine becomes more cumbersome and has a higher weight.

In other solutions, an air flow is generated by the geometry of the carrier disc, which causes primarily that the grinding wheel is cooled. The air flow is generated here simply by the rotation of the carrier disk or its geometry. In JPS 57,156,171, US 6,312,325 and US 6,758,732 grinding wheels or carrier discs are described, which also have elevations in addition to the openings. During rotation of the carrier disc, these elevations generate air turbulence, so that cool air is conducted to the bottom surface and to the processing elements. Dirt and dust are blown away from the bottom surface by the cooling air flow. A major shortcoming of this method, however, is that they eliminate the dirt and dust from the work surface, but scatter it throughout the environment, so that this dirt and dust must be collected afterwards in an additional step. Of course, such contamination is undesirable. During a renovation work, which takes place in an inhabited house, the dust may possibly be additionally whirled up and possibly gets through cracks and small openings in rooms that are not affected by the renovation. In the worst case, this not only means additional work for the subsequent cleaning, but also a health impairment of the residents.

The present invention now has the task to improve a carrier disk of the type mentioned in such a way that the advantages of the known devices are retained, the dirt and dust but without the use of an additional powerful vacuum cleaner or other device effectively from the work surface is sucked off and collected. Another object of the invention is to create a strong suction by suitable geometry of the carrier disk so that the air flow through openings of the carrier disk is accelerated such that any dirt and dust from the lower side of the carrier disk to the upper side and beyond still further upwards.

This object is achieved by the carrier disk with the features of claim 1 and the method according to claim 12. Further features and embodiments will become apparent from the dependent claims and the advantages thereof are explained in the following description.

In the following, the carrier disc according to the invention will be described. The figures represent possible embodiments, which will be explained in the following description.

In the drawing: [0008]

Fig. 1a back of the carrier disk

Fig. 1b front side of the carrier disk

Fig. 1c side view of the carrier disk

Fig. 2a air flow around the carrier disk, without wings

Fig. 2b trajectory of the dirt and dust around the carrier disk, without wings Fig. 3a opening with a wing

Fig. 3b high and low pressure zones around the carrier disk with a wing Fig. 3c air flow around the carrier disk with a wing

3d trajectory of dirt and dust around the vehicle disk with a wing, side view

Fig. 3e trajectory of the dirt and dust around the carrier disc with a wing, supervision

Fig. 4a High and low pressure zones around the carrier disc with two wings Fig. 4b air flow around the carrier disc with two wings

Fig. 4c trajectory of the dirt and dust around the carrier disc with two wings

Fig. 5a trajectory of the dirt and dust around the carrier disc with inwardly oriented wings

Fig. 5b trajectory of the dirt and dust around the carrier disk with outwardly oriented wings

Fig. 6 Two-wing opening The present invention consists of a circular carrier disc 1 to a tillage machine, which is driven by a motor about a central axis of rotation 5 (Fig. 1a, 1b and 1c). On the front side of the support disk processing elements 4 are attached (Fig. 1b and 1c), which are either firmly attached to the support plate 1 or can be easily replaced. In addition to the processing elements 4, the carrier disk 1 has radial openings 2. These openings 2 serve to remove dirt, consisting of dust and removed soil material, which is generated by the processing elements and / or removed.

During the rotation of the carrier disk 1, the air flows on the front and rear sides of the carrier disk 1 substantially parallel to the carrier disk 1 (FIG. 2a). The dirt and dust 6, which is generated on the front side of the carrier disk, is therefore only picked up to a small extent by the openings to the rear side (FIG. 2b).

On the back of the support disk 1 so a wing 3 is fixed at each opening 2, to generate an increasing air flow through these openings 2 (Fig. 1a and 3a). This creates a suction which accelerates the flow of air from the front side of the carrier disk 1 to the rear side and carries along the dirt and dust 6. An essential feature of the wings 3 is that they are removable so that they can be e.g. be easily and quickly replaced if damaged.

In addition, the wings 3 can also be changed depending on the nature of the work. For example, certain soil surfaces are processed at higher grinding speeds. This then exposes the wings 3 stronger air currents, to which they must be adapted to ensure optimum performance. Also, the carrier disk 1 is exposed to different temperatures depending on the rotational speed and nature of the soil. At low temperatures the wings 3 could e.g. made of plastics that are lighter and cheaper than metal, whereas metals are more likely to be used at high temperatures, otherwise the plastic could melt. If different wings 3 with different shapes and made of different materials are available, the user can apply exactly the right wing 3 to the carrier plate 1 for each application, in order to obtain the optimum suction for the removal of the dirt and dust 6 as a function of the speed of rotation of the carrier disc guarantee.

When choosing the shape of the wing 3 is essential to note that the desired strong air flow is generated as efficiently as possible. It makes sense, but also the air resistance is minimized, so that a greater power is not required to rotate the carrier disk. A simple way to reduce the air resistance is to round off the upstanding corners of the wing. This has the additional advantage that the wings are also less likely to catch or impact with other parts of the tillage machine.

The wings 3 have two different areas: The first region 3a is parallel to the support plate 1 and serves to attach the wings 3. The second region 3b is bent back or is at an angle a back of the support plate 1 from (Fig 3a). During the rotation of the carrier disk 1, a high-pressure zone 7a ', which conveys the air from the rear side upwards, is formed on the upper side of the blade 3. On the bottom, a low-pressure zone 7b is created, which absorbs the air from the front side through the opening 2 (FIGS. 3b and 3c). Thanks to this suction, the dirt and dust 6 are removed from the processing elements 4 and the work surface immediately after being produced, and conveyed to the rear side of the carrier disk 1 (Figs. 3d and 3e). This avoids the accumulation of dirt and dust on the carrier disc and its settling in the processing elements. The carrier disc and the processing elements remain clean, effective and cooler, because with the strong air flow generated in addition to the material and the heated air is removed.

In one embodiment, each opening 2 not only one, but two wings 3, 3 'on. The first wing 3 is mounted in the direction of rotation in front of the opening 2, the second 3 'thereafter, and both are back from the support plate 1 from. As previously described, the first wing 3 sucks up the dirt and dust 6 from the front to the back of the carrier disc 1 by forming behind it a low pressure zone 7b during rotation. Thus, the dirt and dust 6 is indeed sucked through the opening 2, then it is scattered and accumulated on the back of the support disk 1 (Figures 3d and 3e). By adding a second blade 3 'behind the opening 2, during rotation of the support disk 1, a high-pressure zone 7a is formed on its front side, so that the incoming air is further accelerated, and the dirt and dust is carried away from the support disk 1 (FIG. 4b and 4c). From this combination of the suction on the front of the carrier disk 1 and the acceleration of the air flow on the back of a very strong and quasi-laminar air flow is generated from bottom to top. Thus, the dirt and dust 6 is not only absorbed by the bottom surface and conveyed to the other side of the carrier disk 1, but also further led up (Fig. 4c), to a dust container, which can not be mounted directly above the opening 2 because otherwise it is in the way of the rotating wings 3. Without this additional acceleration and amplification of the air flow, it is clear that the dirt and dust 6 does not reach the dust container in the situation of FIG. 3d. In the situation of Fig. 4c, however, all dirt and dust 6 reaches directly to the mouth of the dust container, so that only a small, low-power vacuum cleaner is necessary to transport the dirt and dust in the dust container and collect there.

An important feature of the invention is therefore that no powerful vacuum cleaner is necessary to produce a suction which is strong enough that all the dirt and dust from the bottom surface is conveyed through openings of the carrier disk and to the dust container. In the present device, the carrier disc is not an obstacle to the suction, but it causes its own buoyancy, which brings the dirt and dust alone already up to the dust container. The necessary vacuum cleaner can thus be much less strong, which causes significant space, weight, space and cost savings when using a tillage machine.

The wings 3 may have different shapes so that they can be adapted to any application. The wings 3 may have angles y of -90 ° to 90 ° with the radial direction (FIGS. 5a and 5b). In the configuration of FIG. 5a, the rotation of the carrier disk 1 and the wing 3 causes a swirl of air which carries the dirt and dust 6 to the center of the carrier disk 1. Thus, the dirt and dust 6 could e.g. collected, or removed by a central drainage. In the configuration of Fig. 5b, however, the dirt and dust 6 are carried outside by the centrifugal effect. Thus, the disc could have a raised border which catches the dirt and dust 6, e.g. can be collected in a marginal collection basin.

In addition, the wings 3, 3 'with different angles a from 5 ° to 90 ° from the carrier plate 1 protrude (Fig. 3a). In particular, in the embodiment with two wings 3, 3 ', it is often advantageous if the two wings 3, 3' do not have the same angle to the carrier plate 1 (FIG. 6). The role of the first wing 3 is namely to produce a laminar air flow as possible for what a small angle a is ideal. In contrast, the role of the second wing 3 ', the incoming air flow as much as possible to accelerate upward, which is achieved with a larger angle ß.

In further embodiments, the wings could also be bent, as they are so streamlined and produce an even more effective air flow. It is also possible to attach multiple wings to each hole, left, right, in front, behind, or around it, always to provide the best possible airflow for any application. For example, several such small wings could have a curved shape, which is much cheaper and easier to manufacture than the curved shape of a larger wing.

The wings 3 can be fastened to the support disc 1 with screws, or by other suitable attachment methods, such as. Magnets or radial grooves in which they are pushed and clamped. It is important that the wings are fixed to the carrier disc so that they do not come loose during the rotation and on the other hand that the connection can be released by simple means to replace the wings.

Also, the openings 2 in the carrier disk can have different shapes to ensure optimal removal of dirt and dust 6 depending on the application. In principle, the greater the openings 2 are, as long as they do not affect the stability and strength of the carrier disk 1, the easier it is to suck off the entire dirt and dust 6. In particular, trapezoidal openings 2 (FIGS. 1a and 1b) are advantageous because the disk section in which the openings 2 are located is therefore utilized to the maximum. May be

Claims (14)

a e.g. Curved elongated shape or other special shapes of the openings better suited to achieve a powerful suction effect with sufficient acceleration. claims 1. carrier plate 1 of a tillage machine with attached on the front processing elements 4, which has a plurality of radially arranged openings 2, characterized in that on the back of the carrier plate 1 at each opening 2 at least one removable wing 3 is attached. 2. Carrier disk 1 according to claim 1, characterized in that the wings 3 are mounted projecting from the back of the carrier disk 1. 3. carrier plate 1 according to claim 1, characterized in that the wings 3 are mounted in the direction of rotation in each case in front of the opening 2. 4. carrier plate 1 according to claim 1, characterized in that each opening 2 with at least two wings 3, 3 'is provided, wherein a wing 3 in the direction of rotation in front of and a wing 3' in the direction of rotation behind the opening is mounted. 5. carrier plate 1 according to claim 1, characterized in that the wings 3 have an angle of -90 ° to 90 ° with the radial direction. 6. carrier plate 1 according to claim 1, characterized in that the wings 3 protrude at an angle of 5 ° to 90 ° from the carrier plate 1. 7. carrier plate 1 according to claim 1, characterized in that the wings 3 are bent. 8. carrier plate 1 according to claim 4, characterized in that the at least two wings 3, 3 'have different angles to the radial direction and / or the carrier plate 1. 9. carrier plate 1 according to claim 1, characterized in that the wings 3 consist of an antistatic material. 10. carrier plate 1 according to claim 1, characterized in that the wings are fastened 3 with screws or with magnets on the support plate 1. 11. Carrier disk 1 according to claim 1, characterized in that the carrier disk has 1 grooves, in which the wings 3 are inserted. 12. A method for removing dirt and dust 6 a tillage machine, which has a carrier disk 1 according to claim 1, characterized in that in the region of the carrier disk 1 by the geometry of the carrier disk 1, a suction is formed, which the dirt 6 through openings 2 of the Carried front to the back of the carrier plate 1. 13. The method according to claim 12, characterized in that the mitbeförderte dirt 6 is conveyed by the mounted on the back of the carrier disk 1 wings 3 of the carrier disk 1 further upwards. 14. The method according to claim 12, characterized in that the working surface of the dirt 6 is completely freed.