SE469255B - Sowing machine for forest regeneration, having a rotary ground-preparing member - Google Patents

Abstract

Sowing/ground-preparing machine for forest regeneration, which plants seed in conjunction with ground-working on a hauled quantity of earth. A tool 1 comprises an earth- working member 2 provided with cutting elements 6, a splash-screening device 22 and a seed dispenser 12-16. When the working member 2 rotates, the cutting elements 6, by means of a sidelong throw-up of earth, make a ring 24 of thrown-up earth, against which ring the seed dispenser 12-16 plants small portions of seed. <IMAGE>

Description

15 20 25 30 35 469 255 j z planting is a faster and safer way to get new forest than sowing or natural rejuvenation, but recently these facts have begun to be re-evaluated in favor of sowing. The plants are divided into two main types, barrot plants and taproot plants. A barrot plant has, as the name suggests, only roots while those of the cover root plant are covered with some material, usually peat.

However, planting also has certain disadvantages when compared to sowing or natural regeneration.

Anders Lindström at the Swedish University of Agricultural Sciences' Department of Forest Production in Garpenberg has conducted an extensive study, "Stability in young pine root crops", which was published in April 1990. The content of the study is that naturally rejuvenated plants have the best conditions to clear upsetting moments. Among the planted objects, there are stands where one can have concerns about future stability problems. Of the inventory plant types, the naturally rejuvenated plants also have the straightest growth habit and also show the lowest frequency of strong to very strong stem base curves.

The planted stands have a poor root system due to "root spin", ie the roots are forced to grow in a narrow pot which in 1973-1988 consisted of paper which did not rot. The paper sleeve is not produced now, but there are many indications that roots that are forced to grow in a narrow pot still tend to rotate with a poor root system as a result.

Admittedly, by growing the plants for a very short time in a nursery and in relatively large containers provided with root guide strips or by growing the plants in small containers for a longer period of time, the root control principle being based on pruning the roots at the side and bottom by air or by mechanical means. seedlings with a large root area distributed on few roots and a relatively small proportion of spinning roots.

However, as mentioned above, it has been found that the type of plant which has the greatest preconditions for coping with overturning 10 15 20 25 30 35 s 469 255 moments is the naturally rejuvenated plants, which in addition to a large root area, lack of root deformations and an even root distribution has the root area distributed on few coarse roots.

Another reason for low-quality stands is the high costs associated with conventional planting, which means that as a rule a sufficiently large number of plants per hectare is not planted. Experts today recommend planting about 2,500 seedlings per hectare when planting final felled fellings. Of these, a large number die or are deformed due to poor planting, incorrect planting, freezing, game damage, beetle damage or other damage. Since the goal for regrowth work should be to have a high production of valuable timber, ie timber that is not too fast-growing or has too many twigs, you should plant much denser, perhaps as dense as 5000-10000 plants / hectare.

The total cost of forest rejuvenation, including soil preparation with an excavator, plow or harrow, acquisition of seedlings, planting, transport, etc. will be quite high, approximately SEK 7,000 to 8,000 / hectare. Both Sweden's forest owners and other experts also agree that many of the plantings carried out in recent decades have failed. Production has too much focused on quantity instead of quality, ie we grow pulpwood instead of quality hours.

The problems that can arise in connection with rejuvenation according to conventional methods are thus many. Soil preparation leaves deep traces, which often lead to leaching of the soil's nutrients. The high costs contribute to a small number of plants per hectare, which results in sparse stands which in turn means that the growing forest will contain low-quality timber. When planting with taproot plants, growth is often low due to malformed roots and stability problems often arise when the trees reach the age of 15-20. The object underlying the invention is therefore to provide a device with which forest rejuvenation can be carried out mechanically, at low cost and without leaving any deep tracks in the terrain, while at the same time creating good growth conditions for a large number of well-developed plants per hectare. Based on the above, this task can only be solved with a combined soil conditioner and seed drill.

The object is solved according to the invention by the features stated in the characterizing part of claim 1. Preferred embodiments and further developments appear from the subclaims.

The device according to the invention is thus essentially characterized by a cultivating tool in the form of a "seed cutter" comprising a soil cultivating means with cutting means arranged to cut through the surface layer of the soil shallower or deeper depending on the nature of the soil. The material that is cut loose from the soil's humus layer and underlying soil layer is milled up and mixed to create a nutritious germination soil and best conditions for seeds to germinate and develop a biologically strong root system. In order to facilitate the accumulation of the material and contribute to it being above ground level, a soil cultivating device surrounding the mudguard device is used which helps to collect the vomited material in a ring, pyramid or the like in connection with the highest parts of the pit. Finally, means are provided for cooperating with the processing tool in such a way that small portions of seed are selectively applicable to the vomited material and preferably to its highest parts. In order to prevent fragments of the vomited ring of soil from falling back into the pit again during milling, when working with a convexly curved member, it is suitable to equip the member with two or more soil blades.

Significant advantages are achieved with the seed drill according to the invention compared to conventional soil preparation and planting. The tool can easily be mounted on a conventional harvester used in forestry, since its weight is only barely 10 15 20 25 30 35 s 469 255, half the weight of the harvester head. This is particularly advantageous from a cost point of view, since a special machine does not need to be procured as a carrier of the unit. The harvesters used for felling timber and pulpwood are usually idle during the spring and early summer, when the most suitable time for milling and sowing falls. Existing hydraulic resp. pneumatic and electrical equipment can be used to drive and operate the cutter and seed dispenser. This also means that the same control valves as in harvesting work are used to control the operation and maneuvering of a harvester unit, are useful for controlling operation and maneuvering the seed cutter. The power requirement is moderate (approx. 70 horsepower), so the cutter does not require a large, heavy base machine. It can therefore be used in both large and small-scale forestry, can mill between stumps and stones and leaves only insignificant traces in the terrain. In rugged terrain, it is possible to make suitable route choices, whereby terrain sections that are difficult or impossible to climb can still be reached with the seed cutter, due to its flexibility and long range. It can also be used to advantage in seed tree stands and leaf screens. According to a preferred embodiment, the cutter is intended for thick humus layers and black soils, where it is completely uncompetitive because a conventional soil conditioner is too heavy to run there without getting stuck. The only alternative, apart from manual soil preparation on these types of soil, is an excavator, with severe soil damage and environmental problems as a result. The cost of soil preparation and sowing with the seed cutter only amounts to about half of the cost of conventional soil preparation and planting, or about SEK 4,000-5,000 per hectare. Forest regeneration with the help of the tool described is thus preferable to conventional methods both in terms of cost and in terms of environmental impact, usability on different soil types, in terms of quality and also in view of the effective result of rejuvenation work performed. Experiments have shown that the germination of seeds sown with this tool is very high, in some cases as high as 90%.

The invention will be described in more detail below by means of exemplary embodiments with reference to the accompanying drawing, in which the same reference numerals in the various figures indicate corresponding parts.

Fig. 1 shows a schematic vertical view of a machining tool (seed cutter) according to the invention.

Figs. 2A-2E schematically show alternative embodiments of the tillage means included in the tool according to Fig. 1.

Fig. 3 shows a schematic vertical view of a cultivating member at the top provided with radially projecting earth vanes.

The seed drill is designed as a tool 1 comprising a soil cultivating means 2 with cutting device 6 and a seed dispenser comprising a seed box 12 with lines 14 for transporting seeds from the seed box to one or more blow-out points 16.

The tool 1 is suitably suspended by a holder 17 on the outrigger arm of a harvester (not shown), agricultural tractor, excavator forwarder, etc. and has a drive motor 18 attached to the holder on the shaft of which the member 2 is mounted and driven by the motor 18.

A shield 20 is attached to the motor 18 so that the holder 17 projects through an opening in the center part of the shield. Attached to its outer edge, which is suitably circular, a free-hanging, flexible screen 22, which hangs down so far that it touches a line drawn parallel to the upwardly facing base surface of the member 2. A suitable design of the screen 22 is achieved by utilizing a discarded tractor tire one side of which is cut away. The tire is moved from above over the tool so that the remaining tire side with its inside abuts against and is attached to the shield 20. The tire tread part forms the freely hanging part of the screen 22. The member 2 is according to a preferred embodiment designed with a external conical mantle surface 4, which constitutes a cone whose cone angle assumes values between 60 and 900, preferably 75 °. On the mantle surface 4 the cutting devices 6 are attached, preferably welded, which cutting devices form a helical flange 7 on the outside of the cone. The flange then runs from the base of the cone to its tip and follows the curvature of the mantle surface, whereby a preferred density between the flange turns is 6-8 turns per meter of mantle surface. The seed box 12 is mounted in the opening 10 15 20 25 30 35 7 469 255 in the shield 20, above the drive motor 18 and next to the holder 17.

The seed box is provided with four discharge lines 14 and has internally a slide valve device known per se, which is pneumatically operable to release a predetermined amount of seeds from the seed box 12 to resp. discharge line 14. The valve slide (not shown) consists of a thin, rectangular metal plate provided with four equally large openings so located that each cooperates with the corresponding discharge line 14, when the slide is mounted at the intended place in the seed box. The slide is spring-loaded towards a closed position and can be operated from this position to an open position where the openings coincide with the outlet of the seed box to the discharge lines 14. The valve slide is replaceable and by selecting a plate which has larger or smaller openings, it is possible to determine the size of the seed portions discharged from the seed box. The seed portions are then blown with compressed air through the lines 14 and leave these via the blow-out points 16. The blow-out points 16 are then designed as nozzles 16 and so located and aligned that the seed portions are blow-out against the vomited ring of soil.

The described embodiment is intended for deep processing of thick humus layers and black soil.

Fig. 2A shows such a conical soil cultivating means 2 for deep cultivation with the conical mantle surface 4, the helical cutting device 6 and a drive shaft 8.

For shallower tillage of mineral soils and the like, a tillage means according to Figs. 2B-2E is more suitable.

Fig. 2B shows a cylindrical tillage means 2 with a flat bottom 4 and bevelled cylindrical side edges. Towards the flat bottom and the chamfered side edges, cutting devices 6 with angled outer portions are welded according to the figure. It is sufficient to have two symmetrically arranged cutting devices for a basic machining, but in order to avoid blows and throws when in contact with stones and roots, it is suitable to arrange 8-10 cutting devices in pairs symmetrically evenly distributed over the machining 10 15 20 25 30 35 469 255 _ '8 bottom of the organ. Outside in the center of the bottom 4 a guide pin 5 is attached, which projects parallel to the drive shaft 8.

The center axis of the guide pin coincides with the axis of rotation of the member 2.

An embodiment intended for slightly deeper machining is shown in Fig. 2C. The outer surface 4 of the member 2 here has an externally spherically cupped shape with a welded helical running cutter 6.

A variant of this embodiment is shown in Fig. 2D. The member 2 here has a hollow underside with a concave mantle surface 4 on which a helically running cutting device 6 is attached. The cutting device here runs from the center of the concave mantle surface 4 towards its outer edge, with such an adapted pitch in dependence on the direction of rotation imparted by the member via the drive shaft 8, that processed material of the cutting device is transportable from the circumference of the member towards its center.

Fig. 2E shows a further embodiment of a tillage means 2 for shallow tillage. The outer surface 4 of the casing has a spherically cupped plate shape with welded cutting edges 6, welded radially outwards from the center of the plate. relation to the direction of rotation. In the center of the plate on the inside, a guide pin 5 is attached, which projects parallel to the drive shaft 8.

The center axis of the guide pin then coincides with the axis of rotation of the member 2.

Fig. 3 shows an arrangement of a conical processing member 2, wherein two earth vanes 10 with angled outer portions are arranged on the upwardly facing base surface of the cone, which consists of a flat, circular sheet metal plate 11. The vanes, and in particular their angled portions, force upon rotation the soil material cut loose by the cutter 6 and urged the soil material a further piece radially outwards. 10 15 20 25 30 35 9 469 255 The seed dispenser included in the tool consists in a preferred embodiment of a suitably designed seed box 12 and four discharge lines 14, each with its own blow-out nozzle 16.

The nozzles are evenly distributed along the edge area of the shield.

The seed box has a pneumatic actuating device (not shown) which is operated with compressed air and enables seed portions of a predetermined size to be applied to the vomited ring of soil.

The tool is used as follows. It is mounted instead of the harvesting unit on the support arm of a harvester and the required hydraulic, compressed air and electrical connections are connected. The tillage means 2 is brought into continuous rotation by the hydraulic motor 18. By means of the support arm, the tool 1 is lowered towards a selected place for soil preparation and sowing. As the member 2 rotates, the cutting devices 6 cut through the humus layer of the soil and down into the underlying black soil, whereby humus and black soil are mixed with each other while simultaneously advancing to the ground surface. The material conveyed by the member to the ground surface is thrown by the member into an equally surrounding earth ring. The fender device 22 prevents the material from spreading too far from the member and helps to collect the material in an annular mound on the ground. The device 22 also constitutes a wind protection which contributes to the seed portions arriving at the intended location. When the driver judges that tillage and vomiting are sufficient, he triggers the seed discharge, whereby four seed portions of about 5 seeds each with compressed air are blown out towards the annular soil mound.

The four seed portions are then evenly distributed along the circumference of the soil ring and a preferred diameter of the soil ring, in order to obtain a suitable distance between the growing plants, is 1-1.5 m.

Due to the tool's relatively small dimensions, it can be placed between stumps and stones on a felling and leaves only traces in the form of small pits surrounded by a ground ring. The capacity is on average 400 such seed-prepared ear rings per hour. Within the scope of the present invention, of course, the tillage means 2 can be designed in a manner other than as shown in the embodiments, the cutting devices 6 can be straight or can assume a more or less curved shape in the plane of rotation. The helical flange 7 can also be provided with arbitrarily located recesses. 95

Claims (8)

10 15 20 25 30 11 469 255 Patent claims A rejuvenation seed drill comprising a cutting equipment equipped with a cutting device, designed as a rotationally symmetrical body rotatable about a substantially vertical center axis, and a seed dispenser comprising means which, in connection with soil cultivation, apply seeds to cultivated soil, characterized in that the machine (1 ) is operable to, by rotating the soil cultivating means (2) with the cutting device (6), partly cultivate the soil and partly by circumferential soil vomiting prepare an annular mound (24) of cultivated soil, that the seed dispenser comprises a seed box (12) with a sheath valve device known per se, which is pneumatically manoeuvrable and has discharge lines (14), each having its own blow-out nozzle (16), that small portions of seeds with a predetermined amount of seed by means of compressed air can be applied in predetermined positions on the required soil mound (24 ), and that the machine (1) has a shield (20), on the circular outer edge of which a freely hanging, the member (2) concentrates The surrounding screen (22) provides wind protection for the seed portions, and is designed to cooperate with the means (2) for delimiting the outer circumference of the mound (24). Seed drill according to claim 1, characterized in that the member (2) has a convex mantle surface (4). Seed drill according to claim 2, characterized in that the mantle surface (4) has a conical shape. Seed drill according to claim 2, characterized in that the mantle surface (4) consists of a spherically cupped surface. Seed drill according to claim 2, characterized in that the casing surface (4) has the shape of a flat bottom with chamfered, cylindrical side edges, that a guide pin (5) fastened in the center of the bottom (4) projects parallel to the drive shaft and that 10 15 _s- 4 469 255 f H The center axis of the guide pin coincides with the axis of rotation of the member (2). Seed drill according to one or more of Claims 1 to 5, characterized in that the cutting devices (6) are mounted on the member (2) joined to a helically extending flange (7). Seed drill according to one or more of Claims 1 to 6, characterized in that the helical flange (7) extends from the center portion of the member (2) to its circumference, the flange (7) following the curvature of the jacket surface (4). Seed drill according to one or more of Claims 1 to 5, characterized in that the cutting devices (6) are arranged on the member (2) in the form of radially and axially projecting projections, which connect to the shape of the jacket surface (4). .