DE2836525A1 - KNIFE ARRANGEMENT IN MOTOR-DRIVEN SICKLE LAWN MOWER - Google Patents

Abstract

The mower is provided with a grass-ejection orifice in the housing (2). Above the cutter bar (10) provided with air-deflecting elements (36), a disc-shaped structure (17) is arranged on the rotary shaft (6). This structure (17) is designed, on its upper side facing the housing bottom (2), as a pure surface of revolution. The cutter bar (10) has a combined cutting and ventilating part (22) which, as a result of its profiling, acts as an axial-blower stage. The cutter bar is twisted. Its angle of incidence decreases from the inside outwards, preferably from 20-25 DEG to 8-15 DEG on the circumference. The tangential run of the bar profiles is continuous. The cutter bar (10) is transferred radially from the inside outwards out of the horizontal into a lower horizontal position by means of a bend (20), at least part of which has a cutting edge (21). The passage between the cutter bar (10) and housing (2) is smaller, preferably substantially smaller than that between the structure (17) and the housing (2). The pure surface of revolution of the structure (17) is smooth, for example polished. This mower, for the same cutting capacity, works with less noise. <IMAGE>

Description

Blade arrangement in motor-driven sickle lawn mower

The present invention relates to a motorized knife assembly powered sickle lawn mower with grass discharge opening in the housing, in which over the one with at least one cutter bar provided with air acceleration elements a disk-shaped or shell-shaped structure is arranged on the rotating shaft.

In terms of the noise protection that is often sought today, the Lawn mower manufacturers in compliance with cutting performance, cutting quality and the throwing power not only the noise generated by the lawnmower drive, which takes place by means of an explosion or an electric motor, but rather reduce this in particular by designing the knife assembly accordingly. Such attempts have been made frequently. There is no lack of more recent patent literature, in which such endeavors are revealed.

DE-OS 2 635 807 explains that at the usual speeds the cutting knife of around 3,600 rpm. the knife noise is very strong and already can exceed the engine noise after slight noise reduction of the engine. These statements are to be agreed with. The noise level of the cutting knife arrangement could well be by lower speed, and therefore lower air delivery, so reduo adorns that the desired noise values, e.g. in the order of magnitude of 65 dbA, are effortless can be achieved. However, such a measure has the disadvantage that the cutting quality and in particular the conveying or ejection capacity, i.e. the Throwing the cut grass into a grass catcher that will sink the lawnmower as such becomes unusable It is therefore the noise attenuation at usual sickle lawn mowers in this direction set limits, which are very narrow are and therefore force the specialists to deal with the "noise reduction" issue the aforementioned fixed boundary conditions for a good cut and good grass ejection to solve.

There are also knife assemblies are known in which on a substantially horizontal plate is attached to the rotating knife shaft and the knife edges on knife arms at a distance below and radially outside of the substantially circular periphery of the plate. It will a larger number of air acceleration elements on the knife arms and / or the plate as a whole evenly distributed over the circumference of the knife assembly.

(DE-OS 2 635 807) This version represents a practical option the noise reduction. But it leaves other options open, such as that according to DE-OS 2 652 232.

In the latter construction, the cutting mechanism mainly consists of one or more cutting bars and a washer attached to its upper part is provided with vertically arranged wings. These sit offset over the or the cutter bar, with a suction gap behind each wing, seen in the direction of rotation is provided.

The present invention is based on the object on the basis of Flow tests the shaping of the knife assembly in motor-driven To examine sickle lawn mowers and to design them so optimally that they have so far The achieved cutting performance and ejection quality are maintained and the noise level nonetheless can be lowered into the range of 65 dbA.

A knife assembly that provides a significant noise reduction in the aforementioned Ensures sense is characterized by the content of the identifying part of claim 1.

The subject matter of the invention is then based on, for example a drawing explained in a purely schematic representation.

They show: FIG. 1 a detail from a meridional section through the lower part of a sickle lawn mower, with dash-dotted lines as variants Parts, Fig. 2 shows a section of a cutter bar in plan view, to scale Embodiment 1: 1, FIG. 3 shows a side view of the section according to FIG. 2, FIG. 4 shows the detail in a perspective view (not to scale), FIGS. 5 and 6 two meridional sections of the cutting part according to the section lines V - V and VI-VI of Fig. 2, in a scale representation 1: 1.

To aerodynamics in connection with the noise generation rotating Knives in sickle lawnmowers should note the following: The noise generation is particular caused by pressure fluctuations in the air. This "aerodynamic" noise continues composed of two components, namely the noise of rotating air masses and the noise generated by vortex formation.

The noise from the rotating part is due to the impulses which are released into the air by the rotary generator, i.e. by the rotating knife assembly This noise component basically has the same fundamental frequency, like the rotational frequency of the knives. The vortex component is fluid-related and very likely dependent on the local pressure equalization Flow fields, in particular through pressure compensation vortices behind the cutter bar and at their ends. This is what is known as broadband noise, i.e. noise with a broad frequency band.

The grass-cutting knife in its most general design has to fulfill three functions. It has to lift the grass and make it clear the cut edges of the Cutter bar in optimal, i.e. on; posed position, present for the cut. It must also cut this grass and after cutting it from the area remove or eject the knife assembly. The lifting of the grass and its Ejections after the cut are made by the flowing air while cutting is an essentially mechanical problem. So it exists the task, as the noise generation also depends on the air flow, lifting and Ejecting fluidically to be carried out in such a way that at the same time minimal noise To do this, it is undoubtedly necessary to use the rotating part of the knife assembly to investigate generated air movement and to determine by which measure a appropriate pressure distribution of the moving air can be generated so that it with minimal noise the required lifting of the grass, its cutting and its Can ensure ejection after the cut.

In one implementation, these findings basically lead to one Airfoil-like profile of the ventilation part of the following the cutting part Knife bar. There is a static negative pressure on the underside and on the Top of this part generates a static overpressure. Due to the Strömuno creates an air force that lifts the grass. After cutting it will this is carried along by the air flowing out of the area of the knife arrangement.

ner shown in Fig. 1 section from a meridional section through a lawnmower lower part 1 shows a housing 2 with a base and a collar 3. In the Housing 2, a guide ring 5 is also shown in phantom. This guide ring 5 can serve as an inner guide channel delimitation to allow air and cuttings accordingly respectively. The ring 5 is not an absolute requirement. It is also a rotating shaft 6, which is driven by an electric or internal combustion engine (not shown) evident. A fastening screw 7dtent provided at its free end axial retention of a wedged hub part 9 on which a cutter bar 10 - es can also be two or more such bars - by means of a clamping ring 11 is clamped. A spring ring or washer forms the end 13. A sleeve 15 is slipped over the hub part 9, which by means of screws 16 on Hub part 9 is attached. A faceplate 17 is attached to the top of the sleeve 15, e.g. welded on. The cutter bar 10 has an inner arm 19 on the outside Transitions via a crank 20 into a cutting part 22, the front edge of which acts as a knife edge 21 is formed. The knife edge 21 is the lowest area of the knife bar 10. As can be seen from FIG. 1, it is slightly higher than the lower end edge of the collar 3. The part 23 following the cutting part 22 is used for production the desired air flow.

The outside diameter of the face plate 17 and the cutter bar 10 can be almost the same. They correspond to the diameter of the collar 3. The passage between the periphery of the cutter bar 10 and the inner surface of the collar 3 normally larger than the one between the periphery of the faceplate 17 (or the shell 53) and the collar 3, as will be explained later.

In FIGS. 2 to 6, the dimensioned on the basis of tests and designed cutter bars 25 can be seen. For centering and fastening on the Rotary shaft 6 it is provided with a central bore 26, which is in the so-called. Inner arm 27 is located. A first crank 29 pointing into the interior of the housing leads to an upper one Guide surface 31, which has a second crank 32, which is directed downwards is, merges into a cutting and ventilation part 34 and 36, respectively. That one has one Cutting edge 35 lying in front plane 40. The upper guide surface 31 is bounded by a front upper edge 37 and a rear upper edge 38. The rear Upper edge 38 is approximately twice as long as the front edge 37. The cutting edge Ventilation part 34, 36 is trough-shaped.

Fig. 4 and the two profiles according to FIGS. 5 and 6 show that this combined part 34, 36 has kinked profile lines 41 and 42. But it is normal in mass production, these profiles 43 and 44 as lines with constant tangents, i.e. without kinks, e.g. by pressing. Lay the profile endpoints 45, connected to one another, a rear terminating edge 46 of the ventilation part 36 fixed. As can be seen from the scale figures 2, 3, 5 and 6 of a test execution, is the outflow area of the ventilation part 36 as a triangular surface 48 with on the Periphery of the cutter bar 25 located tip 49 is formed. It is in the present Case roughly an isosceles triangle.

For versions equipped with a housing 2 with a guide ring 5 are, instead of the face plate 17 occurs a cup-shaped or tulip-shaped Formation 53, as shown in phantom in FIG. 1. It can be flatter or deeper. This version has the same surface area like the faceplate 17, i. e.

without any special air moving tabs, vanes o. The like. Both the face plate 17 and the shell 53 have a normal machining fineness on the surface, i.e. surfaces such as those produced during pressing processes, as will be explained below.

As mentioned, the rotating cutter bar 10 acts on its own Profiling in the outer part, which according to FIGS. 2 to 6 at the front as a cutting part 34 and at the back as ventilation part 36 is designated, like the stage of an axial fan, which conveys the air in the axial direction, whereby after a deflection on the ground of the housing 2 ejected the air together with the clippings through the opening in the collar will. In particular, there are the following phenomena, of a fluidic nature, which the present invention or the considerations take into account: 1. The Air set in rotation by the cutter bar 10, which flows in axially and radially-tangentially flows out, creates a boundary layer with high at the bottom of the housing 2 Velocity gradients. Therefore, there are relatively high pressure differences in this area, which leads to the formation of eddies for a few seconds and consequently to noise generation. It represents this Furthermore, due to the resulting frictional losses, a loss of efficiency which should be expressed in the lower ejection speed. Through the basic measure, with the help of a rotating disk or bowl-shaped, arranged above the cutter bar Formed what minimal air movement has conveying parts (surface roughness instead of blades, bends and the like), noise-producing boundary layers could be prevented. The other side of the The structure should be as smooth as possible, e.g. polished, in order to minimize the fan effect to generate and thus the space between the disc or the shell-shaped structure, and the bottom of the housing 2 as far as possible undisturbed with regard to radial speed allow. Due to the tests carried out, the noise increases due to such measures without the ejection speed differentiating the critical minimum value.

In this context it is also important that the distance between the surfaces of the structure and the bottom of the housing is large enough to accommodate the speed gradient to keep small in the boundary layers. This distance should be more than the width of the annular gap of the structure housing, e.g. at least twice, preferably at least triple.

2. The flow around the free edge has proven to be a further noise generator, i.e. the peripheral area of the cutter bar 10 and 25, respectively. Due the profile shape of the cutting and ventilation part 34, 36 is created on the upper side thereof a zone of increased static pressure and a corresponding zone on the underside lower static pressure. The greater the pressure difference in the mentioned peripheral area is, the stronger the equalizing flow and the greater the flow through it Compensation generated vortex movement and thus the generation of noise. It's another one Concern for noise reduction, the pressure difference (overpressure - underpressure) in the Keeping the rotating shafts much larger near the area than in the peripheral area. Since the internal speed is smaller than according to the smaller turning radius the speed at the ends of the cutter bar must be used to generate a greater one Pressure difference (buoyancy) the profile inside a larger Angle of attack exhibit than outside. The profile must have a greater set there, like this with reference to FIGS. 5 and 6 can be seen.

3. The width of the annular gap between the inner jacket of the collar 3 and the periphery of the knife bar proved lo. The decisive factor for this is the ratio of the two diameters, while the absolute Gap width, if it has a certain minimum size, meaning second (diameter ratio e.g.

21.6: 21, i.e. split ring width 6 mm. This shipyard can also be larger, e.g. 10 mm).

4. The annular gap between the inner surface of the collar 3 and the periphery of the disc or the shell-shaped structure must be aerodynamic judged to be as low as possible. For manufacturing reasons, because of occurring Vibrations and because of the possibility of the occurrence of the speed of sound in the annular gap, however, this must have a certain minimum width.

5. It is basically also possible instead of an axial fan stage to combine a radial fan stage with the cutter bar. The shape of the radial blades and the cover plate are to be provided in the sense of the present explanations, whereby according to point 1 the runner is to be provided with a cover plate to prevent the mentioned To reduce boundary layer in the bottom of the housing.

While the redirection for the outermost profiles of the knife bar are in the order of magnitude of 8 to 15, preferably around 100, these increase on the inside to around 20 to 250, preferably around 230.

Claims (13)

Claims ts knife arrangement in motor-driven sickle lawn mower with grass discharge opening in the housing, in which above the with at least one with Cutter bars provided with air acceleration elements are disc-shaped or bowl-shaped Structure is arranged on the rotating shaft, characterized in that this structure at least on its upper side, facing the case back, as a pure surface of rotation is trained. 2. Knife arrangement in motor-driven sickle lawn mower with Grass discharge opening in the housing, in which above the with at least one with air acceleration elements provided cutter bar a disk or bowl-shaped structure on the rotating shaft is arranged, characterized in that the cutter bar is a combined Has cutting ventilation part, which as a result of its profiling as an axial blower stage works. 3. knife arrangement according to claim 2, characterized in that the profile is twisted and the angle of attack decreases from the inside to the outside, preferably from 20 - 250 to 0 8 - 15 on the circumference. 4. knife arrangement according to claim 2, characterized in that the profiles show a continuous tangent course. 5. Knife arrangement according to Claims 1 and 2. 6. knife assembly according to claim 1, characterized in that the Forms as a flat disc or from the inside radially outwards in the shape of a bowl or tulip is designed to rise. 7. knife arrangement according to claim 1 or claim 2, characterized in that that the cutter bar radially from the inside to the outside from the horizontal by at least a bend is transferred to a lower, horizontal position, from which the latter at least a part has a cutting edge. 8. knife arrangement according to claim 1 or claim 2, characterized in that that a first bend lifts the upper edge of the cutter bar and another The bend lowers the bar below the radially innermost bar horizontal surface. 9. knife arrangement according to claim 1 or claim 2, characterized in that that the front upper edge of the cutter bar, which follows the first bend, is shorter, e.g. about half as long as or as the rear upper edge. 10. Knife arrangement according to claim 1 or claim 2, characterized in that that the passage between the cutter bar and housing is smaller, preferably substantially is smaller than that between the structure and the housing. 11. Knife arrangement according to claim 1 or claim 2, characterized in that that the pure surface of rotation of the structure is smooth, e.g. polished. 12. Knife arrangement according to claim 1, characterized in that the cutter bar and the structure, the side boundaries of the radial conveying blades form. 13. Knife arrangement according to claim 1, characterized in that the distance of the structure from the bottom inner surface of the housing for the purpose of reduction the speed gradient in the boundary layers is a multiple of the annular gap width between the structure and the collar is, for example, at least twice, preferably at least three times.