BR102016029478A2 - pneumatic seed dispenser and pneumatic turbine - Google Patents

Abstract

The present invention relates to power supply systems applied to agricultural sowing implements, also known as planting machines (21), more specifically the present invention relates to power supply to pneumatic seed feeders (1) . the pneumatic seed dispenser (1) comprises a kinetic energy capture means (2), wherein the kinetic energy capture means (2) is associated with a chamber (3) with pressure difference.

Description

(54) Title: PNEUMATIC SEED FEEDER AND PNEUMATIC TURBINE (51) Int. Cl .: A01C 7/04 (73) Owner (s): JOSÉ ROBERTO DO AMARAL ASSY (72) In wind r (s): JOSÉ ROBERTO DO AMARAL ASSY; ALEXANDRE LEITE ROSA; DANIEL AUGUSTO DE SOUZA MELLO MONTEIRO; RODRIGO TADEU DE OLIVEIRA LADEIRA (74) Attorney (s): VIEIRA DE MELLO ADVOGADOS (57) Abstract: The present invention relates to energy supply systems applied to agricultural implements for planting crops, also known as planting machines (21 ), more specifically the present invention relates to the supply of energy for pneumatic seed metering (1). The pneumatic seed doser (1) comprises a means of capturing kinetic energy (2), in which the means of capturing kinetic energy (2) is associated with a chamber (3) with a pressure difference.

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Field of the Invention [001] The present invention relates to energy supply systems applied to agricultural implements for sowing crops, also known as planter machines, more specifically the present invention relates to the supply of energy to pneumatic seed feeders .

Background to the Invention [002] Planters are widespread in the current agribusiness scenario and play key roles in ensuring efficient large-scale production. One of the known types of planters is the pneumatic planter, also known as a vacuum planter.

[003] Figure 1 illustrates an example of a pneumatic planter of the state of the art coupled to a tractor 14, in which a central pneumatic pump 22 designed to generate a pressure difference, generally negative, which is distributed by pipes that compose, can be observed. the pneumatic lines 18 until reaching the pneumatic seed metering 1 in the planting lines 23.

[004] Modern planters are generally pulled by tractors and have a mechanical coupling structure to support traction and connection means for transmitting the energy produced in the tractor to the planter's devices, such as pumps, actuators, dosers and sensors.

[005] Some of the devices, such as pumps, actuators and dosers, may alternatively use the mechanical energy transmitted by hydraulic, pneumatic or axle lines. On the other hand, some devices, such as sensors, are powered only by electric energy and for that purpose use power cables 19 that extend from the tractor 14 to each of the planting lines 23.

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2/15 [006] In general, planters have a chassis that includes a tractor hitch structure and a crosspiece that supports planting lines, each with a respective seed storage tank or with a central tank of seed storage shared between all rows. Each planter can have dozens of planting lines, which makes the structures reach 27 meters in width.

[007] As is known by the technicians in the subject, due to the size of the planters generally used, it is necessary to use long power cables running through all the structures between the tractor and each planting line. Thus, the cabling in these agricultural implements, in addition to demanding costs and specific processes for manufacturing and implementation, have significant costs inherent to the materials used for the means of fixation along the implements, as well as the material of the cabling itself. Figure 2 illustrates a side view of a prior art planting line, in which examples of wiring arrangements and pneumatic lines commonly used in the prior art can be seen.

[008] Furthermore, cabling is generally one of the first elements to demand maintenance due to the wear and tear resulting from common use in the agricultural environment, since the cabling is exposed to hostile conditions typical of the crop, such as vibrations, bad weather, mechanical stresses, exposure to abrasive and corrosive materials.

[009] The maintenance of cabling demands specific labor, which generates additional costs, even more when taking into account the dimensions and the high quantity of the planting lines generally practiced.

[0010] In view of the aforementioned disadvantages in the use of cabling, among others known, the state of the art presents other ways of supplying electrical energy to the devices generating energy in the actual

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3/15 device or very close to it, for example, capturing solar, mechanical and / or pneumatic energy, among others, and converting it into electrical energy.

[0011] These means of generating local energy, generally take advantage of the energy available in the environment, whether it comes from the sun, the displacement of air or fluids or even the movement of the object in which it is applied or part of it. In this way, these means of generating local energy known to the prior art take advantage of the energy that was available, that is, they take advantage of the energy that was not being used and, therefore, being dissipated in the environment.

[0012] Particularly, in relation to the use of systems that take advantage of the energy coming from the displacement of air and / or fluids, here called as "kinetic energy" of the fluid, the state of the art presents numerous documents for the most varied areas and applications, the use of turbines is quite consolidated, mainly in systems where the displacement of fluids is done by pipes.

[0013] Cooling and / or ventilation systems are known, in which the circulation of fluids is generally oversized, that is, the mechanical energy given by the displacement of the refrigerant fluid ends up not being fully used in the system and is lost.

[0014] The state of the art presents solutions that use turbines to take advantage of the energy that would be lost in these cooling and / or ventilation systems as revealed, for example, in WO 2015/200134, US 2015/0001849 and US 2012/0286514. All of these examples are intended for application in immobile and / or building systems, in which there is excess kinetic energy to the original application and which would be dissipated.

[0015] With regard to pneumatic turbines, there are more and more applications in the field of transport, mainly applied in the areas of aviation, railway and automotive.

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4/15 [0016] The document US 2015/0239571 deals with an emergency power supply system for planes designed to generate energy for the plane during the flight, this system uses an air intake duct with a turbine. In this case, the kinetic energy is used from the air that passes through the plane during the flight and is used to obtain electrical energy in emergency cases of electrical failure.

[0017] The document US 2008/0178586 discloses the generation of energy from an air turbine generator, used in pneumatic brake systems of railroad cars and locomotives, which features a controller to control the volume of air directed to the turbine. according to the energy demand of the railway system.

[0018] US patent 6,054,838 discloses a method and system for charging electrical energy storage devices applied to automobiles using compressed fluid storage media and an air turbine generator. The pneumatic electricity generation system is used to charge the electrical energy storage device when it reaches predetermined low levels.

[0019] Portable turbines of general use are known in the state of the art, which provide convenience in the generation of energy in any system that has pressurized fluids, such as the US patent 4,731,545. In this patent, portable turbines are indicated for preferential uses in hydraulic systems such as irrigation and fire hoses.

[0020] US patent 9,146,141, which deals with a method and system for monitoring pneumatic systems and also with an energy capture unit configured to capture energy from the pneumatic system being monitored and generate energy, is also known from the state of the art. power to power the monitoring device.

[0021] In agriculture, even in the most recent developments, the generation of electric energy is done in the tractor. This can be seen in the patent

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US 7,135,785, which deals with an electric generator in tractors and exemplifies how the power source is usually far from the implements attached to the tractor, making the use of cabling indispensable.

[0022] Thus, although the state of the art encompasses means of energizing devices without the use of long wiring, none of these means, even in combination, is applicable in pneumatic planters, in particular for seed metering.

[0023] Thus, in order to circumvent the aforementioned inconveniences, a system that provides electrical energy for peripheral devices in planters without the use of cabling becomes interesting.

Objectives of the Invention [0024] Thus, to solve the problems exemplified above and other problems existing in the state of the art, the present invention has as one of its objectives to provide a planter system without the use of cables passing through the entire implement to feed peripheral devices.

[0025] Another of the objectives of the present invention is to provide a planter equipped with energy generating sources arranged in each of the planting lines, particularly close or in the doser.

[0026] Still, it is one of the objectives of the present invention to provide efficient means of capturing energy from a pneumatic line.

[0027] It is also an objective of the present invention to provide an energy generating system that is simple to apply and maintain.

[0028] Another objective of the present invention is to provide an energy generating system with control in the supply of energy.

[0029] It is also an objective of the present invention to provide a pneumatic energy generating system with inlet flow control.

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6/15 [0030] Another objective of the present invention is to provide a pneumatic turbine system with flow compensation in relation to the pneumatic system.

[0031] The present invention, through its own characteristics, can also solve other problems of the state of the art not brought here as an example, since the systems applied to planters discussed here and their problems are exemplary and not exhaustive.

Description of the Invention [0032] The objectives of the aforementioned invention, among others, are achieved through a pneumatic seed doser that comprises a means of capturing kinetic energy from the fluid, in which the means of capturing kinetic energy is associated with a chamber with a pressure difference to capture the mechanical energy of flow.

[0033] According to additional or alternative embodiments of the pneumatic seed feeder of the present invention, the following characteristics, and their possible variants, can also be understood, isolated or in combination:

- the means of capturing kinetic energy is associated with an electric energy generator;

- the means of capturing kinetic energy is a turbine;

- the electric power generator is one of an electromagnetic generator and a piezoelectric transducer;

- the electromagnetic generator is a dynamo;

- the collection means can be associated with the dispenser through the entry of the pneumatic line or disposed inside the dispenser;

- the collection means is fixed to the doser by means of a mechanical quick coupling;

- the quick coupling is equipped with electrical connections;

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- the seed dispenser comprises a sensor powered by the energy generated in the energy collection medium;

- the sensor is placed on the surface of the dosing disc in position before the seeds are released;

- the sensor is placed in position after the seeds are released;

- the position after release is selected from a position just below the disk until the seed conductor leaves;

- the sensor is one of an optical sensor, capacitive sensor, inductive sensor and ultrasonic sensor;

- the seed dispenser comprises an actuator powered by the energy generated in the energy collection medium

- the actuator is one of the organizer's calibrator, pressure controller, cleaner, seed input controller and input applicator;

[0034] In addition, the invention deals with a pneumatic turbine comprising an inlet duct, an outlet duct, a capture chamber and a kinetic energy pickup associated with an electric power generator, in which the pneumatic turbine comprises a window air inlet in the inlet duct and a means of control.

[0035] According to additional or alternative embodiments of the pneumatic turbine of the present invention, the following characteristics, and their possible variants, can also be understood, isolated or in combination:

- the control medium is an electronic control circuit configured to regulate the electrical output energy;

- the control means is an electronic control circuit configured to control the rotation of the turbine by means of an electric charge association;

- the control means is an electronic control circuit configured to control the rotation of the turbine by means of an electromechanical valve system to maintain the flow of air through the turbine;

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- the control medium is a self-regulating valve;

- the air inlet window is equipped with a means of regulating flow between a sliding cover and a rotating clamp.

Brief Description of the Drawings [0036] The objectives, advantages and technical and functional improvements of the present invention will be better understood from the following description made in relation to particular realizations, which refer to the attached figures, in which:

figure 1 shows a top view of a tractor coupled to a prior art planter;

figure 2 shows a side view of a prior art planting line;

figure 3 shows a perspective view of an embodiment of the invention; figure 4 shows a top view of a tractor coupled to a planter according to an embodiment of the invention;

figure 5 shows an exploded view of an embodiment of the invention; figure 6 shows a side view of a first embodiment of the invention; figure 7 shows an exploded view of a second embodiment of the invention;

figure 8 illustrates an association scheme of an embodiment of the invention;

figure 9 shows an exploded view of a turbine according to an embodiment of the invention;

figure 10 shows a side sectional view of a turbine according to an embodiment of the invention;

figure 11 illustrates an association circuit diagram according to an embodiment of the invention;

figure 12 shows a quick coupling according to an embodiment of the invention;

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9/15 figure 13 shows a sensor in a first arrangement in the doser according to an embodiment of the invention;

figure 14 shows a sensor in a second arrangement in the dispenser according to an embodiment of the invention; and figure 15 illustrates a doser with an actuator according to an embodiment of the invention.

Description of Embodiments of the Invention [0037] The invention is now described with respect to its particular embodiments, with reference to the accompanying figures. In the figures and description below, equal or corresponding parts are marked with equal reference numbers.

[0038] The figures are schematic and their dimensions and proportions are exemplary, since they aim only to describe the invention in order to facilitate understanding and do not impose any limitations beyond those defined by the attached claims.

[0039] It must be recognized that the different teachings of the achievements discussed below can be used separately or in any suitable combination to produce the same desired results.

[0040] The object of the present invention is applied in pneumatic planters 21, in particular in the supply of electric power to pneumatic seed metering 1 disposed in each of the planting lines 23 of planters 21, the supply being without the use of cabling 19 .

[0041] The pneumatic seed dispenser 1 of the present invention is provided with a pneumatic line inlet 5 and a seed conductor 15 to guide the dosed seeds inside the dispenser 6 to the ground. Figure 3 illustrates an embodiment of the invention in which the means for capturing kinetic energy 2 is coupled externally to the doser 1 via the pneumatic line inlet 5.

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10/15 [0042] Figure 4 illustrates an embodiment of the invention in which planter 21 is coupled to a tractor 14. In this figure, it is possible to observe the structure of planter 21 comprising a chassis 16, a crosspiece 17, also known as rod, and the planting lines 23. Also shown in figure 4 is a pneumatic pump 22 and pneumatic lines 18 connecting pump 22 to the planting lines 23.

[0043] The air flow in the pipes of the pneumatic lines 18 is controllable and can be adjusted in the central pneumatic pump 22 according to the need of the operator. In the present invention, the air flow is regulated to supercharge the pneumatic lines 18 so that this supercharge is sufficient for the kinetic energy capture means 2 to generate the energy necessary to feed the doser devices 1 without affecting the performance of the doser in the dosage of seeds.

[0044] Thus, the generation of electric energy is done close to the devices to be fed without affecting the dosage efficiency of the doser 1 and, thus, providing the energization of devices distant from the tractor 14 without the use of cabling 19.

[0045] Figure 5 shows an exploded view of a pneumatic doser 1 according to an embodiment of the invention. This figure shows a vacuum chamber 3, which makes up the internal part of the doser 1, and a dosing disc 20.

[0046] In one embodiment of the invention, the means of capturing kinetic energy 2 is, on one end, associated externally to the metering unit 1 through the pneumatic line inlet 5 and, on the opposite end, to the pneumatic pump 22 through the pneumatic lines 18, as illustrated in figure 6.

[0047] Another embodiment of the invention is illustrated in figure 7, in which the means of capturing kinetic energy 2 is internally associated with the doser 1, more specifically the means of capturing kinetic energy 2 is disposed in the vacuum chamber 3 over the opening flow rate 35.

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11/15 [0048] Figure 8 shows an association diagram between the pneumatic doser 1, the energy collection medium 2, the sensors 9, the actuators 10 and the pneumatic pump 22. In general, air enters through the doser 1, passes through the energy capture medium 2, where electrical energy is generated and supplied to sensors 9 and actuators 10, and, finally, the air exits through the pneumatic pump 22.

[0049] Particularly, in an embodiment of the present invention, the energy generated in the energy capture medium 2 is used to feed a seed passage sensor 9 disposed inside the doser 6 on the dosing disk 20. Alternatively or in combination the energy generated can be used to power one or more actuators 10 inside the dispenser 6, which can be, among others, an organizer calibrator, a pressure controller, a cleaner, a seed input controller or an input applicator .

[0050] In one embodiment of the invention, the means of capturing kinetic energy 2 is a pneumatic turbine 4. The present invention presents particular embodiments related to pneumatic turbine 4, in which in one embodiment the turbine 4 is formed by a housing 32 , a kinetic energy pickup 28 and an electric energy generator 13.

[0051] More specifically, as shown in an exploded view in figure 9, the pneumatic turbine 4 has an energy collector 28, in this embodiment represented by a rotor 11 with substantially circular blades 12. The energy pickup 28 is arranged in a capture chamber 25 inside the housing 32 and associated with an electric energy generator 13.

[0052] The electrical power generator 13 of the present invention provides for the use of electromagnetic generators, piezoelectric transducers or other equivalent devices capable of converting the kinetic energy of the fluid into electrical energy. In a preferred embodiment of the invention, a dynamo is used.

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12/15 [0053] Still in figure 9, it is possible to observe an embodiment of the turbine housing 32, in which an inlet duct 26, an outlet duct 27 and the kinetic energy capture chamber 25 are illustrated.

[0054] The inlet duct 26 of the present invention has an opening at the free end and an air inlet window 30 disposed on the duct wall. The window 30 being provided with a flow regulation means 29, in the embodiments illustrated in figures 9 and 10, for example, the flow regulation means 29 is a sliding cover that moves over the window 30 to decrease the flow until complete closure and outward to increase flow.

[0055] An alternative to the flow regulation means 29 is a clamp (not shown) involving the turbine inlet duct 26 in a rotating manner, this clamp being provided with an opening of a shape coincident with the shape of the inlet window. air 30.

[0056] The air intake window 30 has the function of compensating for the air intake that should flow from the doser 1 to the pneumatic lines 18, but that ends up not flowing due to clogging, inadequate adjustments, flow differences that naturally result from according to the shape of the seeds of different cultures, among others. In this way, the air inlet window 30 ensures sufficient air flow to keep the pneumatic turbine 4 in full operation.

[0057] In another embodiment of the invention, the pneumatic turbine 4 comprises a control means 33. Figure 11 illustrates an association scheme of the control means 33, in which the control means 33 is associated, on the one hand, with the generator 13 and, on the other hand, to sensors 9 and / or actuators 10.

[0058] The control medium 33 is provided in a preferred mechanical configuration and in three electronic configurations, not limiting, of the invention, and the configurations can be applied separately or in any combination without impairing the functioning of the system.

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13/15 [0059] In the mechanical configuration, the control medium 33 is a self-regulating valve 31. In this configuration the control medium 33 is impacted by pressure variations in the fluid in order to adjust the flow to a constant value according to predefined specifications .

[0060] In the first electronic configuration, the control means 33 is an electronic circuit that works with a voltage regulator, in which it receives the energy generated in the generator 13, which generally presents oscillations, and regulates it to provide stabilized energy and according to the demand of the device to be powered.

[0061] In the second electronic configuration, the control means 33 functions as a rotational speed controller for the rotor 11 of the turbine 4. In this configuration the control means 33 is an electronic circuit that detects the rotation speed of the turbine 4 and adds electrical charges to maintain rotation at a predetermined speed.

[0062] In the third electronic configuration, the control means 33 also functions as a rotational speed controller for rotor 11 of the turbine 4. In this configuration, the control means 33 is an electronic circuit that controls the rotation speed of the turbine 4 by means of an electromechanical valve system that maintains the flow that passes through the duct at a predetermined level and thereby keeps the turbine rotation 4 constant.

[0063] Another embodiment of the invention is related to the way in which the kinetic energy capture medium is associated with the pneumatic seed doser and / or the doser peripherals, being given by mechanical quick coupling 7. Figure 12 illustrates the provisions of the quick coupling 7 according to a preferred embodiment of the invention, in which mechanical coupling means with electrical connections 8 are shown.

[0064] The invention also provides for the use of the energy generated in the system to feed sensors 9 through and / or inspection, particularly for sensors arranged in order to detect whether the dosage of the

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14/15 seeds are being effectively conducted. Sensors 9 are preferably, but not limited to, optical sensors, capacitive sensors, inductive sensors or ultrasonic sensors.

[0065] In one embodiment, as illustrated in figure 13, sensor 9 is disposed on the surface of the dosing disc 20 in a position that allows the detection of seeds in the holes of the disc 20 moments before the release of these seeds.

[0066] In another embodiment, as shown in figure 14, the sensor is disposed under disk 20, so that sensor 9 can detect the passage of seeds moments after its release from disk 20.

[0067] Still, the present invention provides for the use of the energy generated in the energy capture and generation system to feed actuators 10 both arranged in the seed dispenser 1 and in the energy capture and generation system itself.

[0068] Some preferential, non-limiting applications for actuators 10 are, in the case of the doser, to act as the organizer calibrator, pressure controller, seed input controller, cleaner and input applicator. Figure 15 illustrates an exemplary arrangement of an actuator associated with the organizer 34 to act as an organizer calibrator. In the case of actuators applied to the energy capture and generation system, actuator 10 can act for flow regulation and turbine rotation control 4.

[0069] Thus, based on its unique characteristics, it is easily noticed that the present invention achieves the proposed objectives and overcomes the drawbacks of the state of the art.

[0070] Although the invention has been described specifically in relation to particular embodiments, it should be understood that variations and modifications will be apparent to those skilled in the art and can be made without departing from the scope of protection of the present invention. Consequently, the

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15/15 scope of protection is not limited to the described achievements, but is limited only by the attached claims, the scope of which must include all equivalents.

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Claims (20)

Claims 1. PNEUMATIC SEED FEEDER (1), characterized by the fact that it comprises: a means of capturing kinetic energy (2), wherein the means of capturing kinetic energy (2) is associated with a chamber (3) with a pressure difference. 2. PNEUMATIC SEED FEEDER, according to claim 1, characterized by the fact that the means of capturing kinetic energy (2) is associated with an electric energy generator (13). 3. PNEUMATIC SEED FEEDER, according to claim 2, characterized by the fact that the means of capturing kinetic energy (2) is a turbine (4). 4. PNEUMATIC SEED FEEDER, according to claim 2, characterized by the fact that the electric power generator (13) is one of an electromagnetic generator and piezoelectric transducer. 5. PNEUMATIC SEED FEEDER, according to any one of claims 1 to 4, characterized by the fact that the collection medium (2) is associated with the feeder (1) through the pneumatic line inlet (5). 6. PNEUMATIC SEED FEEDER, according to any one of claims 1 to 4, characterized by the fact that the collection medium (2) is arranged inside the feeder (6). 7. PNEUMATIC SEED FEEDER, according to any one of claims 1 to 6, characterized by the fact that the collection means (2) is fixed to the feeder (1) by means of mechanical quick coupling (7). 8. PNEUMATIC SEED FEEDER, according to claim 7, characterized by the fact that the quick coupler (7) has an electrical connection (8). 9. PNEUMATIC SEED FEEDER, according to any one of claims 1 to 8, characterized by the fact that the feeder Petition 870160075833, of 12/15/2016, p. 21/38 2/3 of seeds (1) comprises a sensor (9) fed by the energy generated in the energy collection medium (2). 10. PNEUMATIC SEED FEEDER, according to claim 9, characterized by the fact that the sensor (9) is disposed on the dosing disc (20) in position before the release of the seeds. 11. PNEUMATIC SEED FEEDER, according to claim 9, characterized by the fact that the sensor (9) is arranged in position after the release of the seeds. 12. PNEUMATIC SEED FEEDER, according to claim 9, characterized by the fact that the sensor (9) is one of an optical sensor, capacitive sensor, inductive sensor and ultrasonic sensor. 13. PNEUMATIC SEED FEEDER, according to any one of claims 1 to 10, characterized by the fact that the seed feeder (1) comprises an actuator (10) powered by the energy generated in the energy collection medium (2). 14. PNEUMATIC SEED FEEDER, according to claim 13, characterized by the fact that the actuator (10) is one of the organizer calibrator, pressure controller, cleaner, seed input controller and input applicator. 15. PNEUMATIC TURBINE (4), comprising an inlet duct (26), an outlet duct (27), a capture chamber (25) and a kinetic energy pickup (28) associated with an electric power generator, characterized by the fact that it comprises an air inlet window (30) arranged in the inlet duct (26) and a control means (33). 16. PNEUMATIC TURBINE (4), according to claim 15, characterized by the fact that the control means (33) is an electronic control circuit configured to regulate the electrical output energy. 17. PNEUMATIC TURBINE (4), according to claim 15, characterized by the fact that the control means (33) is an electronic circuit of Petition 870160075833, of 12/15/2016, p. 22/38 3/3 control configured to control the rotation of the turbine (4) by means of electric charge association. 18. PNEUMATIC TURBINE (4), according to claim 15, characterized by the fact that the control means (33) is an electronic control circuit configured to control the rotation of the turbine (4) by means of an electromechanical valve system for maintenance of air flow through the turbine (4). 19. PNEUMATIC TURBINE (4), according to claim 15, characterized by the fact that the control means (33) is a self-regulating valve (31). 20. PNEUMATIC TURBINE (4), according to claim 15, characterized by the fact that the air inlet window (30) is provided with a flow regulation means (29) between sliding cover and rotating clamp. Petition 870160075833, of 12/15/2016, p. 23/38 1/11