WO2008147237A1 - Machine for harvesting high-grass helophytes and a method for the use thereof - Google Patents

Abstract

The group of inventions relates to agriculture, in particular to the cultivation of perennial high-grass air-aquatic plants (helophytes), to which relates, in particular bur reed (phragmites australis), club-rush (scirpus lacustris) and narrow-leaved cattail (sparganium erectum). Said invention makes it possible to preserve a helophyte root system, thereby ensuring the stable helophyte crops from year to year and to substantially reduce the negative influence of the machine on the local ecosystem. The inventive machine for harvesting high-grass helophytes comprises a tractor (1), to which an intermediate truck (2) is attached, and a transport truck (6) attached to said intermediate truck. The width of the intermediate truck (2) is greater than the width of the tractor (1). N binding reapers (3) are placed in line on the intermediate truck (2) in such a way that cutting elements thereof (5) are oriented in the direction of the machine travel and are located substantially outside the wheeltrack of the tractor (1). The tractor (1), the intermediate (2) and transport (6) trucks are designed in such a way that a mean specific pressure thereof on the ground is equal to or less than 0.22 kg/cm2. The inventive method for harvesting high-grass helophytes consists in cutting plants, in forming sheaves and in transferring the sheaves to the transport truck (6). When the transport truck (6) is full of the sheaves, the machine is stopped and the full transport truck is substituted for an empty transport truck. Said method uses the above-disclosed machine.

Description

 A machine for harvesting tall grass helophytes and a method for its application.

The claimed group of inventions relates to agriculture, namely to the cultivation of perennial tall grassy air-water plants (helophytes).

In accordance with the terminology of hydrobotany, airborne plants, or helophytes, are called rooted plants, the vegetative body of which is located both in water and above its surface (Papchenkov V.G., Scherbakov AB, Lapirov A.G. Basic hydrobotanical concepts and related terms: Project. Ryazan: Service, 2003. [1]). Plants of this group occupy coastal shallow waters with a depth of 1 ÷ 2 m. Depending on the height of the shoots, they are divided into tall grasses and low grasses. Perennial tall grassy water-air plants include, in particular, common reed (phragmites australis), lake reeds (sirpus lacustris) and narrow-leaved cattail (srgapium erstum). These plants are used for weaving various products and as a packaging, insulation and building material - reeds. Bulrush is suitable for covering roofs, making hedges, rough grades of paper; goes to bedding for livestock and for fuel (T. V. Egorova. Reed, reed. Great Soviet Encyclopedia - 3rd ed., M., 1977 [2]). Artificial plantings of tall grass helophytes are also used as biofilters in mine and wastewater treatment systems (A. Direnko, EM Kotsar, “Use of higher aquatic plants in the practice of wastewater and surface runoff treatment”, COK magazine, Ukraine, 04/2006 , 04/12/2006, http://www.cok.com.ua/content/view/374/ [3]).

Harvesting tall grass helophytes is carried out for about a hundred days a year: from November to March. This period is dictated by the biological characteristics of these plants. By the beginning of the harvest, the plants ripen and in most of them the leaf falls. The maturity of plants is determined primarily by the light yellow color of its stem, as well as by the absence of a spongy core in tubular stems.

Since ancient times, methods for manual harvesting of reeds and reeds have been known (see, for example, “Roof from Reeds and Clay”, newspaper “Summer Resident”, issue 10.11.2000, published by Fedorov Corporation, Samara, Russia [4]). In them for mowing use a sickle with an extended handle, a short braid or a wide knife. After mowing, a sheaf of plants is formed, tied and laid on ice or a raft, and then transported to the place of further processing. In particular, this method is still used by residents of the village of Vauvert (Vauvert) in the south of France. The disadvantage of this method is manual mowing and linking of sheaves, leading to high complexity and very low productivity of the method. In addition, when implementing the method, the worker is forced to work in the cold winter time in the open, often being in the water. Improving the productivity of mowing plants occurs when implementing the known method of collecting reeds, in which for mowing use a motorized mower MAX 630WS manufactured by BCS S.p.A., Italy. The specified mower contains a power unit located on the frame. The frame is equipped with two wheels, control knobs and a front cutting machine. The wheels and the cutting apparatus are connected by transmissions to the power unit. After mowing the plants with the specified machine, a sheaf is formed, bundled and laid on the ground, and then transported to the place of further processing. Despite the increase in productivity, this method is essentially manual, and it has the disadvantages of the previously mentioned method.

Among the methods and machines for the mechanized collection of tall grass helophytes by A. with. USSR Ns SU36189 for invention (IPC 6 B62D55 / 065, A01D44 / 00, 1934 [5]) a caterpillar motor vehicle for harvesting reeds is known, adapted for movement by water and land and carrying a harvesting machine driven by a transmission of the wagon . The wagon is equipped with an additional pair of tracks, the lower branch of which is located at some height above the lower branch of the tracks of the main pair. From the description of the same invention [5] a method for collecting reeds is known, comprising the following steps. First, the caterpillar motor vehicle, adapted for movement on water and on land, is moved with the sweeper placed on it to the place of work. Then cut the reeds with a harvesting machine. In this case, the sweeper is driven from the transmission of the wagon. In this case, the wagon is equipped with an additional pair of tracks, the lower branch of which is located at a certain height above the lower branch of the caterpillar tracks of the main pair. A harvesting machine forms sheaves from cut reeds and throws them onto the deck. Sheaves are removed from the deck in a container. After filling the container, the wagon is moved to the place of intermediate storage, where sheaves are unloaded from the container. The disadvantage of this vehicle is the placement of a sweeper on it. When using the cart in the above manner, this leads to the need to interrupt the process of mowing reeds for transporting harvested sheaves to the place of intermediate storage, in particular to the shore. This leads to a decrease in the efficiency of using the cart for mowing reeds. Moreover, this efficiency is lower, the farther the place of intermediate storage from the mowing site. This also leads to significant overhead energy for the multiple transportation of side cargo - harvesting machine - between the mowing place and the place of intermediate storage. Another disadvantage of this wagon is the location of the sweeper on the wagon in combination with the location of the lower branches of the tracks at different heights. This leads to a significant specific pressure on the ground when using the cart in the coastal zone or flooded areas, that is, in those places where the coupling of the cart with the ground occurs only the lower branches of the main pair of tracks. A significant load on the root system of perennial reeds, in turn, leads to mechanical damage, which reduces its yield in subsequent years due to the death of some plants whose roots were damaged. In addition, the mass death of reeds leads to a violation of the biological balance of the area, which negatively affects the life of other participants in the ecosystem of this area.

Known industrial headers for mechanized harvesting of plants, for example:

- ZhSK-2,1 hemp-binder, produced by Simferopolsselmash Plant OJSC (http://www.selmash.strace.net), Ukraine, current technical condition: TU 23-2.900-82 [6];

- hemp harvester ZhK-1, 9 manufactured by ZAO 3avod Bezhetskelmash (http://www.bezh.tver.ru [7]), Bezhetsk, Tver Region, Russia.

It is also known to use the above reapers aggregated with tractors of class 0.9-1, 4 tf for collecting helophytes. For example, using a well-known machine made up of hemp-sheaves ZhCK-2,1 attached to an MTZ-80 tractor, mow plants, form sheaves, tie and tie them onto the field (“Dynamics of vegetation of the lower Volga delta.” Zhivoglyad A. F. // Materials of the scientific session dedicated to the 50th anniversary of the Astrakhan State Reserve. Astrakhan, 1968. [8]. "The effect of cattle grazing on the productivity of reeds." Kenig GF // Resources of reed raw materials and the biological basis of its reproduction. Proceedings of the scientific and technical conference. Fear, 1970 [9]). Then the sheaves are picked up and transported to the warehouse. The disadvantage of this machine is the design of the chassis of the header-sheaf and the availability of the MTZ-80 tractor. As a result, the machine is of great importance for the average specific pressure on the ground. When using it, most of the roots of a perennial plant are mechanically damaged, which significantly reduces the yield of helophytes in the following years and upsets the equilibrium of the local ecosystem. The disadvantage of the method of collecting helophytes using the specified reaper-shears is the placement of sheaves on the field after tying. Since the collection of helophytes usually occurs in flooded areas, such sheaves get wet, which leads to an increase in energy costs for transporting wet sheaves to the warehouse and drying them. In addition, the placement of sheaves on the field leads to the presence of an additional operation of the selection of sheaves, complicating the method. The specified method was widely used when harvesting reeds in the Astrakhan region in the lower reaches of the Volga river delta. This reed was to serve as the raw material of the local pulp mill. However, after the start of harvesting of cane in this way, its reproduction decreased sharply and the plant had to switch to another type of raw material - wood [8].

The disadvantage of the intermediate placement of sheaves on the field was eliminated in Ne RU2220531 known for the invention (IPC 7 A01 D37 / 00, A01 D41 / 08, A01 D45 / 00, 2004 [10]) a combine for harvesting sorghum and a sorghum. The specified harvester is a header-sheaf binder consisting of a frame with a divider fixed to it, a sectional conveyor, a grass separator, a cutting apparatus, a knitting apparatus, a needle conveyor, and a running gear. Behind the header-sheaves, sheaf conveyor and tractor trolley are attached. Mentioned A method for harvesting sorghum broom involves the use of the aforementioned combine. In this case, the plants are mowed with a cutting apparatus, grabbed by a sectional conveyor and transported to a knitting apparatus, where sheaves are formed and tied with twine. With a needle conveyor, sheaves are dumped onto the sheaf conveyor, and they are moved to a tractor trolley.

The disadvantage of this harvester is the design of the chassis, sheaf conveyor and tractor cart. As a result, the combine has a large specific pressure on the ground. When used to collect perennial helophytes in a known manner, most of the roots of plants are mechanically damaged, which significantly reduces the yield of helophytes in the following years and upsets the balance of the local ecosystem.

Known according to the patent of the Russian Federation Ns RU2220531 [10], the harvesting method and the combine are, by the combination of essential features, the closest technical solutions to the claimed group of inventions. The technical problem to be solved by the claimed group of inventions is to provide the possibility of non-destructive exploitation of the habitats of perennial tall grass helophytes.

The technical result provided by the inventive machine for harvesting tall grass helophytes is to ensure the safety of the root system of helophytes, which is directly manifested when using the inventive machine. This ensures stable yields of helophytes from year to year. This also leads to a significant reduction in the negative impact of the use of the machine on the ecosystem of the area.

The technical result provided by the claimed method of harvesting tall grass helophytes is the preservation of the root system of helophytes, which is manifested in the implementation of the method. On the one hand, this ensures stable crops from year to year. On the other hand, this leads to a significant reduction in the negative impact of the method on the ecosystem of the area in which the method is applied. The essence of the machine for collecting tall helophytes is that it contains a tractor, to which an intermediate trolley is attached, to which a transport trolley is attached. In this case, the width of the intermediate carriage is greater than the width of the tractor. On an intermediate trolley, N headers and sheaves are arranged in a row N, so that their cutting elements are directed forward in the direction of the car’s movement, they were mainly outside the tractor’s track. In this case, the tractor, intermediate and transport trolleys are configured to provide an average specific pressure on the ground of not more than 0.22 kg / sq. Cm. The tractor is mainly made in the form of a caterpillar tractor, and its coupling device for engaging the intermediate truck is placed horizontally in the center of its rear.

It is advisable to carry out an uniaxial intermediate carriage with three wheels: left, right and middle, with two wheels placed on the sides of the carriage, and one - the middle - between them. In this case, the drawbar and the coupling device for engaging the transport trolley are placed between two of the same adjacent wheels of the intermediate trolley.

It is advisable to place on the intermediate trolley two header-sheaf-binder (N = 2). It is possible to drive the header-sheaves from one power unit located on an intermediate trolley.

The wheels of the undercarriage of the intermediate and transport trolleys are preferably in the form of wheels of ultra-low pressure.

It is permissible to additionally install a sheaf conveyor on the intermediate trolley, driven by the same unit from which the header-sheaves are driven.

The essence of the method of harvesting tall grass helophytes is that when implementing the method, a machine containing a shear-binder and a transport trolley is used, and the method includes cutting said helophytes, forming sheaves from them and transporting sheaves to a transport trolley. Moreover, the said machine further comprises a tractor and an intermediate trolley attached to it, on which at least one header-sheave is placed. The transport trolley is attached to the intermediate trolley. In this case, the tractor, intermediate and transport trolleys are configured to provide an average specific pressure on the ground of not more than 0.22 kg / sq. Cm. After filling the transport trolley with sheaves, the machine is stopped and the filled transport trolley is replaced with an empty transport trolley.

The filled trolley is transported from the harvesting place by transport, preferably made providing an average specific pressure on soil no more than 0.22 kg / sq. cm. It is advisable to use an intermediate trolley wider than the width of the tractor, and place the header-sheaves on the intermediate trolley so that their cutting elements are directed forward in the direction of travel of the machine and are located mainly outside the track of the tractor.

The invention is illustrated by the following graphic materials.

Figure 1 shows a diagram of a machine for cleaning helophytes, a top view, Figure 2 is a diagram of the same machine, side view, in FIG. 3 - an example of the performance of the header-sheaves.

The machine for collecting tall grass helophytes (Fig. 1, 2) contains a tractor (1), to which an intermediate trolley (2) is attached. On the intermediate trolley (2), N row shearers (3) are placed in a row. The minimum value of N is one. Each shear-binder (3) contains a divider (4), a sectional conveyor (not shown), a cutting apparatus (not shown) with cutting elements (5), a knitting apparatus (not shown). The width of the intermediate carriage (2) is greater than the width of the tractor (1). Header-sheaves (3) are placed on the intermediate carriage (2) so that their cutting elements (5) are directed forward in the direction of movement of the machine and are outside relative to the track of the tractor (1). In this case, it is advisable to place the header-sheaves (3) on one side of the tractor rut: to the right or left. The attachment of the header-sheaf binder (3) to the intermediate trolley (2) is made with the possibility of adjusting their height position. Header-sheaves (3), in addition, are made with the possibility of adjusting the height of the position of the cutting elements (5) of the cutting apparatus. A transport trolley (6) is attached to the intermediate trolley (2), designed to accommodate helophytes cut and tied into sheaves. For coupling the tractor (1) and the intermediate carriage (2), the tractor contains a towing device (7) connected to the drawbar (8) of the intermediate carriage (2). For coupling the bogies (2, 6), the intermediate bogie (2) contains a towing device (9) connected to the drawbar (10) of the transport bogie (6):

The chassis of the tractor (1), intermediate (2) and transport (6) bogies are made providing an average specific pressure on the ground of not more than 0.22 kg / sq. Cm.

Examples of the machine for collecting perennial tall grass helophytes.

Example 1

The tractor is made in the form of a caterpillar all-terrain vehicle TM 120 of the base model manufactured by OJSC Kurganmashzavod, Russia. (http://www.kmz.ru/ [11]) The operating weight of the all-terrain vehicle is 9800 kg, the width of the track (11) is 800 mm, the average specific ground pressure is 0.22 kgf / sq. cm. The coupling device (7) of the tractor (1) for engaging the intermediate carriage is placed horizontally in the center of its rear. Example 2. The intermediate carriage (2) is uniaxial, with three wheels: left (12), right (13) and middle (14). Two wheels (12, 13) are placed on the sides of the intermediate trolley (2), and one - the middle (14) - between them. This embodiment of the intermediate carriage (2) makes it possible to simplify the design of its chassis due to the absence of a rotary device compared to a four-wheeled biaxial carriage, for example, a 2-PTC-4-887B trailer ("Agricultural machines and the fundamentals of operating a tractor fleet." Chetyrkin B . H. et al. - 2nd ed. - M .: Agropromizdat, 1989 [12, p. 263, Fig. 128 (6)]). In addition, the uniaxial implementation of the intermediate truck (2) provides better maneuverability of the claimed machine. The drawbar (8) of the intermediate carriage (2) is placed in front of the carriage between its two adjacent wheels (in figure 1, between the left (12) and middle (14) wheels). The track of these wheels, between which the drawbar (8) is placed, can be made slightly smaller than the track of the tractor (1). This is done so that during straight-line movement of the machine, the wheels of the intermediate carriage (2) do not move in the same place as the tractor (1) passed, made, for example, as described in example 1. In this case, the intermediate carriage (2) does not move “NEXT-NEXT” behind the tractor (1). This provides an additional reduction in the mechanical effect on the root system of helophytes when using the inventive machine. The coupling device (9) for engaging the transport carriage (6) is located on the intermediate carriage (2) at the rear, between the same wheels between which the drawbar (8) is placed. This ensures the exclusion of bending loads on the intermediate carriage (2) from the side of the transport carriage (6) while the machine is moving.

The intermediate carriage (2) is equipped with an operator's cab (not shown), containing a place for the operator and governing-shears-header controls. When the machine is in operation, the operator adjusts the frequency of operation and the height above the ground of the cutting elements (5) of the cutting apparatus.

Example 3. On the intermediate trolley (2) there are two header-sheaf-binder (3)

(N = 2). Each shear-binder header (3) is made in the form of an industrially manufactured mounted shear-binder header (Fig. 3), which is included in the set of the BCS 270 industrially manufactured mini-tractor manufactured by BCS S.p.A., Milan, Italy. All header-sheaves (3) are driven by a single power unit (15) mounted on an intermediate trolley (2). The transmission of torque from the power unit (15) to the shearers-sheaves (3) is carried out using a hydraulic actuator. Example 4. The transport trolley (6) is made biaxial and contains a frame (16), a platform (17) and a running gear. The chassis contains two axles (18), four low pressure wheels (19), a rigid suspension (not shown), a front wheel swivel mechanism (not shown) with a drawbar (10). The platform (17) is made essentially rectangular in shape, has dimensions 3200x3000 mm. In the center of the platform (17), a recess (20) is made over the entire width, which makes it possible to rationally use the space between the wheels (19) of the transport trolley (6) to place sheaves of harvested helophytes. The said recess (2) is also intended to hold the sheaves on the bogie (b): to prevent them from slipping when the speed of the machine changes. Example 5

The wheels of the undercarriage of the intermediate (2) and transport (6) bogies are made in the form of wheels of ultra-low pressure 0.3-0.5 atmospheres, 1300 mm in diameter and 600 mm wide manufactured by TREKOL NPF LLC, Lyubertsy, Moscow Region, Russia (http://www.trecol.ru [13]). The design of the wheels is described in the description of the invention to patent N ° RU2089403 (IPC 6 B60B21 / 10, 1997 [14]) Curb weight of the intermediate trolley (2) (with equipment and three operators), containing two header-sheave-knobs (3) and three wheels ( 12, 13, 14), is 2,400 kg. Moreover, the load on one wheel does not exceed 850 kg (due to the uneven distribution of load between the wheels). Measured the adhesion area of the loaded wheel with a flat ground surface is 4,600 sq. cm. In this case, the specific pressure on the soil does not exceed 850 kg / 4,600 sq. Cm = 0.18 kg / sq. Cm. The mass of a fully loaded four-wheeled transport trolley (b) is 4,300 kg (empty trolley (6) 1,500 kg, 4 workers 300 kg, plants weigh up to 2,500 kg). Moreover, the load on one wheel (19) does not exceed 1,075 kg. The measured adhesion area of a loaded wheel with a flat ground surface is 5,300 sq.cm. In this case, the specific pressure on the soil does not exceed 1,075 kg / 5,300 sq. Cm = 0.20 kg / sq. Cm. Example 6. On the intermediate trolley, a sheaf conveyor belt is additionally installed. The specified conveyor is designed to move the sheaves from the header-sheaf-binders to the transport trolley. To unload the sheaves onto the sheaf conveyor from the sheaf-binder, the latter is equipped with a needle conveyor. The sheaf conveyor is driven from the same unit from which the shearers-sheaves are driven.

The implementation of the structural elements of the claimed invention is not limited to the above examples. So, the actuation of the reaper-sheaves (3) can be performed from the tractor power take-off device (1). The intermediate carriage (2) can be made biaxial or triaxial.

In the inventive machine for harvesting tall grass helophytes, the claimed technical result: ensuring the safety of the root system of helophytes, is achieved due to the fact that the machine contains a tractor to which an intermediate carriage is attached, to which a transport carriage is attached. In this case, the width of the intermediate carriage is greater than the width of the tractor. On the intermediate trolley N row-shears are placed in a row N, so that their cutting elements are directed forward in the direction of travel of the machine and are mainly outside the tractor rut. In this case, the tractor, intermediate and transport trolleys are configured to provide an average specific pressure on the ground of not more than 0.22 kg / sq. Cm. Pilot tests of the claimed machine in the territory of the Krasnodar Territory (Russia) showed the achievement of the claimed technical result. The decrease in comparison with analogues of the average specific pressure on the soil of the claimed machine in combination with other features that allow industrial preparation of helophytes, showed the practical absence of deformation of the root system of helophytes, the harvest of which was collected. This suggests the possibility of obtaining stable helophyte yields from year to year. This in turn leads to a significant reduction in the negative impact of the use of the claimed machine on the ecosystem of the area in comparison with analogues. The method of collecting tall helophytes is as follows. They set up a machine for collecting tall grass helophytes, put it into operation and move it around the growing area of mature helophytes.

In this case, a machine is used (Fig. 1, 2), comprising a tractor (1) connected in series, an intermediate carriage (2) and a transport carriage (6). The tractor (1) is coupled to the intermediate carriage (2). The intermediate trolley (2) is coupled with the transport trolley (6). On the intermediate trolley (2), N row shearers (3) are placed in a row. Each shear-binder (3) contains a divider (4), a sectional conveyor (not shown), a cutting apparatus (not shown) with cutting elements (5), a knitting apparatus (not shown). The width of the intermediate carriage (2) is greater than the width of the tractor (1). Header-sheaves (3) are placed on the intermediate trolley (2) so that their cutting elements (5) are directed forward in the direction of movement of the machine and are outside the track of the tractor (1). The chassis of the tractor (1), intermediate (2) and transport (6) bogies are made with the possibility of providing an average specific pressure on the ground of not more than 0.22 kg / sq. Cm.

In the course of tuning the machine, the height of the cutting elements (5) of the cutting apparatus is set above the ground, and the frequency of operation of the cutting elements (5) is also established. When the machine is moving, the plants falling into the divider (4) are cut using a cutting apparatus. Depending on the terrain, the density of gelofit thickets, the speed of the machine, the height of the cutting elements (5) and the frequency of operation of the cutting elements (5) are adjusted. When a continuous stream of cut helophytes enters the sectional conveyor, bundles are formed that are transported to the knitting apparatus. In the knitting apparatus, these bundles are tied, for example, with Tex 2200 polypropylene twine according to GOST 17308-88. Sheaves obtained in this way are transported from the knitting apparatus to the transport trolley (6). After filling the transport trolley (6) with sheaves, the machine is stopped and the filled transport trolley is replaced with an empty transport trolley. At the same time, the filled transport trolley is unhooked and another, empty transport trolley is attached. The filled trolley is transported to a warehouse, or a temporary storage place, or a place for further processing, where this trolley is unloaded. In this case, transportation of the filled truck to the warehouse is carried out by transport, the chassis of which is made with the possibility of providing an average specific pressure on the ground of not more than 0.22 kg / sq. Cm. This is done, for example, using a device similar to the tractor unit (1) of the machine used in the claimed method. Transportation of the filled truck can also be carried out by a light all-terrain vehicle or a tractor on ultra-low pressure wheels (patent Ns RU2084366, IPC 6 B62D57 / 00, B62D61 / 00, 1997 [15]).

The helophyte harvest season for a particular locality is considered completed at the end of processing the entire planned locality. Harvesting is also stopped earlier if it is discovered that the period of bird nesting or the period of spawning of fish has come (tentatively from March 1). At the same time, it is required to stop harvesting helophytes to ensure the living conditions of migratory waterfowl. Examples of the method of collecting tall grass helophytes.

Example 1

All sheaves-sheaves (3) are driven by a single unit (15) mounted on an intermediate trolley (2). In this case, the machine is brought into action by starting the tractor engine (1) and starting the specified unit (15).

Example 2

All header-sheaves (3) are driven by a tractor power take-off device (1). The transmission of torque from the tractor (1) to the shearers and sheaves (3) is carried out using a hydraulic actuator. In this case, bringing the machine into action consists in starting the tractor engine (1).

Example 3

Transportation of sheaves from reapers-sheaves (3) is carried out manually. At the same time, several workers pass the sheaves to each other. The last worker in this chain stacks the sheaves on the transport trolley (6). Example 4

The transportation of sheaves from the header-sheaves (3) to the transport trolley (6) is carried out by the sheaf conveyor located on the intermediate trolley and driven by the same unit from which the shearers-sheaves (3) are driven. Moreover, each header-sheaf binder (3) contains a needle conveyor that ejects the sheaves from the knitting apparatus onto the sheaf conveyor.

In the inventive method of harvesting tall grass helophytes, the claimed technical result: preservation of the root system of helophytes, is achieved due to the fact that when implementing the method, a machine containing a tractor, an intermediate trolley attached to it, on which at least one header-sheaf binder is mounted, is used. A transport trolley is attached to the intermediate trolley. The tractor, the intermediate and transport trolleys are configured to provide an average specific pressure on the ground of not more than 0.22 kg / sq. Cm. The method includes cutting said helophytes, forming sheaves from them and transporting the sheaves to a transport trolley. After filling the transport carriage with sheaves, the aforementioned machine is stopped, and the filled transport carriage is replaced with an empty transport carriage. Testing of the proposed method in the territory of the Krasnodar Territory (Russia) showed the achievement of the claimed technical result. The decrease in comparison with analogues of the average specific pressure on the soil of the machine used in the implementation of the proposed method, in combination with other features that make it possible to industrialize helophytes, showed the practical absence of deformation of the root system of helophytes, the crop of which was being harvested. This suggests the possibility of obtaining stable helophyte yields from year to year. This in turn leads to a significant reduction in the negative impact of the application of the proposed method on the ecosystem of the area in comparison with the methods-analogues. In the inventive method, the machine is stopped for a short time - only to change the transport trolley. This ensures the efficient use of the machine for harvesting tall grass helophytes - this machine is not used for transporting harvested sheaves from the harvesting site. At the same time, the harvest of helophytes is almost continuous. The inventive harvesting machine of perennial tall grass helophytes is implemented on industrially produced devices, can be assembled at any industrial enterprise and will be widely used in agriculture.

INFORMATION SOURCES.

1. Papchenkov V. G., Shcherbakov A. B., Lapirov A. G. Basic hydrobotanical concepts and related terms: Project. Ryazan: Service, 2003.

2. T. V. Egorova. Reeds, reeds. Great Soviet Encyclopedia - 3rd ed., M., 1977

3. Direnko AA, Kotsar EM, The use of higher water plants in the practice of wastewater and surface runoff treatment, COK magazine, Ukraine, 04/2006, 04/12/2006, http://www.cok.com.ua/contefit / view / 374.

4. "Roof from reeds and clay", the newspaper "Summer resident", issue 10.11.2000, ed. "Fedorov Corporation", Samara, Russia.

5. USSR copyright certificate Na SU36189 for invention, IPC 6 B62D55 / 065, A01 D44 / 00, 1934.

6. "Hemp shear-binder ЖСК-2,1". Technical condition TU 23-2.900-82. 7. Internet Resource CJSC “3avod Bezhetstselmash” - manufacturer of hemp harvester ZhK-1, 9.

8. "Dynamics of vegetation of the lower Volga delta." Zhivoglyad A.F. //

Materials of the scientific session dedicated to the 50th anniversary of the Astrakhan State Reserve. Astrakhan, 1968. 9. The effect of cattle grazing on the reed productivity. Koenig G.F. // Resources of reed raw materials and the biological basis of its reproduction. Proceedings of the scientific and technical conference. Astrakhan, 1970

10. RF patent Ns RU2220531 for invention, IPC 7 A01 D37 / 00, A01D41 / 08,

A01 D45 / 00, 2004. 11. Internet resource http://www.kmz.ru/. Official website of OJSC

Kurganmashzavod, Russia.

12. "Agricultural machinery and the fundamentals of the operation of the machine and tractor fleet." Chetyrkin B. H. et al. - 2nd ed. - M .: Agropromizdat, 1989.

13. Internet resource http://www.trecol.ru. 14. RF patent N ° RU2089403 for the invention, IPC b B60B21 / 10, 1997.

15. RF patent Ns RU2084366 for the invention, IPC 6 B62D57 / 00, B62D61 / 00, 1997.

Claims

The invention is a machine for harvesting tall grass helophytes and the method of its application. 1. A machine for collecting tall grass helophytes, comprising a transport ^" trolley and a header-sheaf binder, characterized in that the machine further comprises a tractor to which an intermediate trolley is attached, on which N header-sheaf-balers are arranged in a row, the width of the intermediate trolley being greater than the width of the tractor, and shear-knotter headers are placed on the intermediate trolley so that their cutting elements are directed forward in the direction of movement of the machine and are mainly outside the tractor’s track, while the transport trolley is attached to intermediate truck, and the tractor, the intermediate and transport trolleys are configured to provide an average specific pressure on the ground of not more than 0.22 kg / sq. cm. 2. The machine according to p. 1, characterized in that the tractor is made in the form of a caterpillar tractor, and its coupling device for engaging the intermediate truck is placed horizontally in the center of its rear. 3. The machine according to claim 1 or 2, characterized in that the intermediate trolley is uniaxial, with three wheels: left, right and middle, with two wheels placed on the sides of the trolley, and one - the middle - between them, while the drawbar of the intermediate trolley placed in front of the trolley between its two adjacent wheels, while the coupling device for engaging the transport trolley is placed on the intermediate trolley at the rear, between the same wheels between which the drawbar is located. 4. The machine according to p. 1, characterized in that on the intermediate trolley there are two header-sheaf-binders (N = 2). 5. The machine according to p. 1 or 4, characterized in that the header-sheaves are driven from one power unit located on an intermediate trolley. 6. The machine according to claim 1, characterized in that the wheels of the undercarriage of the intermediate and transport trolleys are made in the form of ultra-low pressure wheels. 7. The machine according to claim 1, characterized in that the sheaf conveyor is additionally mounted on the intermediate trolley, driven from the same unit from which the header-shears are driven. 8. A method of harvesting tall grass helophytes, the implementation of which uses a machine containing a header-sheaf binder and a transport trolley, including cutting said helophytes, forming sheaves from them and transporting sheaves to a transport trolley, characterized in that the said machine further comprises a tractor and attached to him an intermediate trolley on which at least one header-sheave is placed, and a transport trolley is attached to an intermediate trolley, while the tractor, the intermediate and export carts are capable of providing an average specific ground pressure of not more than 0.22 kg / sq. cm, while after filling the transport cart with sheaves, the machine is stopped and the filled transport cart is replaced with an empty transport cart. 9. The method according to p. 8, characterized in that the filled trolley is transported from the place of cleaning by transport, configured to provide an average specific pressure on the ground of not more than 0.22 kg / sq. Cm. 10. The method according to p. 8, characterized in that the width of the intermediate carriage is greater than the width of the tractor, and the shear-shears are placed on the intermediate carriage so that their cutting elements are directed forward in the direction of travel of the machine and are located mainly outside the track of the tractor.