IT201800004361A1 - Agricultural seeder - Google Patents

Description

Agricultural seeder

DESCRIPTION

The present invention relates to a seeder of the type comprising the characteristics mentioned in the preamble of claim 1.

A seeder including such characteristics is known for example from IT1421045. This document describes a pneumatic precision seeder in which the speed of the seed in the transport duct towards the seed bed is accelerated pneumatically by means of an ejector fed with pressurized air. In this way a pneumatic transport of the seed towards the seed bed is obtained which improves the regularity of the sowing distance even at high forward speeds.

Normally in these machines there is a centrifugal fan whose flow rate is used (in suction or delivery, depending on the type of seed separator used - positive or negative pressure) to feed the seeds one at a time to the transport duct towards the seedbed. Additionally, a high-head compressor is provided, for example of the lobe type, to generate a pressurized air stream with which to feed the ejectors.

Obviously, the presence on the machine of two distinct pressurization systems, in addition to negatively affecting the energy efficiency of the seeder, involves undesirable costs and, in the case of a lobe compressor, filtration problems of the treated air due to the intrinsic delicacy of these compressors.

The problem underlying the present invention is that of providing a seeder that is structurally and functionally conceived to overcome the technical drawbacks complained of with reference to the prior art mentioned above.

In particular, the main purpose of the invention is to exploit, for the pressurization of the ejectors, pressurized gas flows already available on the machine when the seeder is in use, normally associated with an internal combustion engine which presides over its movement. In this case, the ejectors can be powered using the exhaust gases of this endothermic engine as a pressurization system. The use of these gases can take place either directly, by connecting the ejectors to an exhaust gas derivation with which an at least partial deviation of the gas flow is obtained and which is applied to an exhaust gas manifold of the endothermic engine, and indirectly, using part of the residual energy of the exhaust gases to power an air compressor. In this second case, the use of a turbo-compressor system with a turbine connected to the exhaust gas manifold and a compressor driven by the turbine and connected to said at least one ejector is preferred.

Typically, the internal combustion engine is located on board an agricultural tractor which pulls or otherwise drives the seeder and constitutes its propeller. However, it is envisaged that the internal combustion engine is mounted on board an agricultural machine to which the seeder itself is associated, for example a combined machine for multiple tillage of the soil, including sowing. The characteristics and advantages of the invention will become clearer from the detailed description of a preferred and non-exclusive embodiment thereof illustrated, by way of non-limiting example, with reference to the accompanying drawings in which:

- Fig. 1 is a top plan view of an agricultural seeder associated with a tractor;

- Fig. 2 is a schematic view of the technical solution illustrated in fig. 1

- Figure 3 is a schematic view of an alternative solution to that of the previous figures.

In the figures, 1 generally indicates an agricultural tractor conventionally equipped with an internal combustion engine 2 with an exhaust gas collector 3. The engine 2 controls all the drives of the tractor 1 and constitutes its propeller.

The tractor 1 is connected to a pneumatically operated agricultural seeder 10, provided with a plurality of parallel and spaced sowing elements 11, each equipped with a seed selector and separator device 13 which delivers a seed into a seed delivery duct 14 16 at a time towards a seed bed 15 where this is distributed with a desired pitch P proportionate to the desired investment density of plants per unit of sowing surface. Downstream of the duct 14, a wheel 17 can optionally be provided which serves to hold the delivered seed to the ground and possibly locally compact the soil of the seed bed.

An ejector 18 is mounted along the duct 14 with the function of injecting into the duct 14 by means of suitable nozzles, for example of the type described in IT1421045, a flow of gas under pressure such as to generate an accelerated gaseous stream both upstream and downstream of the ejector 18, in order to accelerate the seed transported in the duct 14 with respect to the gravitational acceleration. In this way, a faster and more regular flow of the seed is obtained in the duct 14 and a consequent better constancy of the sowing pitch P even at relatively high forward speeds of the seeder. The gas flow necessary to favor this gaseous stream is fed to the ejectors 18 through respective pipes 20.

A centrifugal fan 19 or of another type is mounted on the machine on the seeder 10. It generates a positive delivery pressure and a negative suction pressure with which the selector device 13 is pneumatically fed. Depending on the pressure value fed to the selector device 13, yes it will have a pneumatic seeder with suction selector or with selector under pressure. The fan 19 is connected to each selector device by respective ducts 21.

In a first embodiment of the invention all the pipes 20 are in turn converged into an exhaust gas branch 22 which connects each ejector on one side and the exhaust gas manifold 3 of the internal combustion engine 2. In this in this way the pressure of the burnt gases discharged from the manifold 3 in the branch 22 is used as a system for pressurizing the ejectors.

The branch 22, which is preferably mounted on board the seeder 10, is conveniently valved by means of a pressure regulator 24 which serves to keep the pressure of the gaseous stream fed to the ejectors 18 within the foreseen limits and at the same time to avoid a counter-pressure at the discharge. excessive for the internal combustion engine 2.

A second embodiment of the invention is illustrated in Figure 3 in which details similar to those of the previous example are distinguished by the same numerical references.

In this case, instead of using the exhaust gases derived from the exhaust manifold 3 directly, the residual energy is used, transformed by a turbo-compressor 24 whose turbine 25 is connected to the exhaust manifold 3 and whose compressor 26 is driven in rotation by the turbine 25 and generates compressed air which is fed through a branch 26 to the ejectors 18.

It is contemplated that the turbo-compressor 24 may be the same that eventually equips the power supply system of the internal combustion engine of the tractor 1 from whose compressor an air flow necessary for the operation of the ejectors is tapped by means of a valveed bleed manifold 27.

Claims (7)

RI SELL CAZI ONI 1. Seed comprising at least one conduit for transporting the seed to a seed bed, at least one long ejector said conduit for accelerating the seed transported along the duct 5 at the expense of a gaseous stream , a pressurization system connected to said ejector for feeding said gaseous stream thereto, characterized by the fact that said pressurization system comprises an exhaust gas branch which can be applied to a collector 10 of exhaust gas from an internal combustion engine. 2. Sem inactive according to claim 1 wherein said derivation comprises a system for at least partial deviation of the flow of exhaust gas from the internal combustion engine to said at least one ejector. 15 3. Sem inactive according to claim 1 or 2 wherein said branch comprises a turbo-compressor system with turbine connected to the exhaust gas collector of said endothermic engine and compressor driven by said turbine and linked to said at least one ejector. 20 4. Sem inat r ic according to one or more of the preceding claims in which the said derivation is valveed by a pressure regulator. 5. Sem inat r ic according to claim 4 in which said pressure regulator is enslaved to a control to 25 limit the pressure of the gaseous stream fed to the ejectors and / or to limit the counter-pressure to the manifold discharger. 6. Sem inactive according to one or more of the preceding claims in which said turbo compressor belongs to the power supply system of said endothermic engine and a bleed manifold is provided on the compressor of said turbocharger for der a fraction of the compressed air flow from it. 7. The set of an agricultural t rat t r ice and a sem inat r ice 10 including the characteristics of one or more of the preceding claims in which said endothermic engine constitutes the propeller of the t rat t r ice .