IT201600069428A1 - PLANT FOR PNEUMATIC DISTRIBUTION OF PRODUCTS. - Google Patents

Description

“PLANT FOR PNEUMATIC DISTRIBUTION OF PRODUCTS”.

TEXT OF THE DESCRIPTION

The present patent application for industrial invention relates to a system for the pneumatic distribution of products provided with an obstruction detection system. The products distributed by the breadcrumbs can be granular, powdery or solid or gaseous substances.

Although specific reference will be made later to granular products, the invention also extends to powdery products or solid or gaseous substances.

Agricultural machines are known for spreading seeds having a granular shape on a ground, in order to facilitate and speed up the sowing operations.

The agricultural machine includes a tank intended to contain the seeds and a main tube connected to the tank. The main tube is intended to be crossed by the seeds coming out of the tank.

The agricultural machinery comprises a multiplicity of secondary pipes which branch off from the main pipe. The secondary tubes communicate with the main tube to allow seeds to pass from the main tube to the secondary tube. The secondary pipes have an outlet for the release of seeds from the agricultural machine.

The secondary pipes have a smaller diameter than the main pipe. In addition, each secondary pipe has a different length and inclination with respect to the main pipe than the other secondary pipes.

The agricultural machine comprises handling means which move the seeds from the tank to the main tube and from the main tube to the secondary tubes. The handling means are pneumatic and are designed to generate an air flow that pushes the granular seeds from the tank towards the outlet of the secondary pipes. The seeds, coming out of the secondary tube, fall on the ground.

This agricultural machine, although it allows to distribute the granular seeds on a ground in a simple and fast way, has a drawback due to the fact that the granular seeds could partially or totally occlude a secondary tube.

The obstruction of the secondary tube is caused by the granular nature of the seeds, which tend to cluster in the tube

secondary, occluding the secondary tube.

This obstruction can also occur due to a decrease in flow caused by an external cause, such as a narrowing of the secondary pipe outlet. This does not cause an increase in pressure in the secondary pipe as the flow of air and the granules destined for the secondary pipe tend to be distributed in the other free pipes. At this point a degenerative process is triggered, destined to worsen up to the complete obstruction of the secondary tube.

In case of obstruction of a secondary tube, the granules will tend to distribute in the free secondary tubes. Due to the increase of seeds in the free secondary tubes, even the free secondary tubes will tend to become clogged, causing a total blockage of seed delivery over time.

It should be noted that often the occlusion of the secondary pipes is noticed only when it occurs that no seeds come out of the secondary pipes or when the agricultural machine is stopped and a manual check of the secondary pipes is carried out.

It is clear that the longer it takes to notice the occlusion of the secondary tubes, the higher the costs due to the failure to distribute the seeds on the ground.

In fact, if the seeds have not been sown, it will be necessary to manually free the occluded secondary tubes and proceed again with the distribution of the seeds on the ground.

It should also be noted that the handling equipment may be subject to breakage or malfunctions. Even in this case, the breakage or malfunction will be noticed only by verifying that the seeds are not distributed on the ground or by stopping the agricultural machine and manually checking the operation of the handling equipment.

The object of the present invention is to overcome the drawbacks of the known art by providing a system for the distribution of a product which is reliable and capable of signaling any occlusions of the secondary pipes.

A further object of the present invention is to provide a system for the distribution of a product which is simple and economical.

The system for the pneumatic distribution of the product, according to the invention, includes a tank, intended to contain the product, and a main pipe, connected to the tank. The main pipe is intended to be passed through by the product.

The system includes at least two secondary pipes, connected to the main pipe. The secondary pipe is intended to allow the product to escape from the system.

The system includes pneumatic handling means, designed to generate an air flow that moves the product from the tank to the main pipe and from the main pipe to the secondary pipe.

The peculiarity of the system according to the invention consists in the fact that it includes at least one flow meter, placed inside the secondary pipe in order to measure the air flow that passes through the secondary pipe.

The advantages of the system according to the invention are evident, in which, thanks to the provision of the flow meter, arranged inside the secondary pipe, it is possible to detect the presence of a flow of air in the secondary pipe and, consequently, the passage of the product to the outside.

For greater clarity, the description of the plant according to the invention continues with reference to the attached drawing tables, having only illustrative and non-limiting value, where:

Fig. 1 is a schematic representation of a plant according to the invention;

Fig. 2 is an axonometric view of a system flow meter according to the invention;

Fig. 3 is an axonometric view of the flow meter of Fig. 2, seen from a different angle;

Fig. 4 is a schematic representation of the electronic system for processing the signals coming from the flow meters of Fig. 1.

With reference to Fig. 1, a plant according to the invention is described, indicated as a whole with the reference number 100.

The plant (100) for the pneumatic distribution of granules includes a tank (1) intended to contain the product. Advantageously, the product is a granular type product, such as for example seeds.

The system (100) also includes a main pipe (2) connected to the tank (1). The main pipe (2) is intended to be crossed by the moving product.

The plant (100) includes a multiplicity of secondary pipes (3). Each secondary pipe (3) includes a first end section (30), connected to the main pipe (2), and a second end section (31) communicating with the outside. In particular, the first end section (30) includes an inlet mouth, communicating with the central tube (2), to allow the passage of the product from the main tube (2) to the secondary tube (3). The second end section (31) includes an outlet mouth, to allow the product to escape from the system (100).

The plant (100) comprises handling means (4) adapted to generate an air flow (F) which moves the product from the tank (1) to the main pipe (2) and from the main pipe (2) to the secondary pipe ( 3). The handling means (4) are of the pneumatic type, ie they generate an air flow (F) that crosses the tank (1), the main pipe (2) and the secondary pipe (3), transporting the product.

Optionally, the system (100) includes presence detection means (6), arranged in the main pipe (2) to detect the presence of the product in the main pipe (2). The presence detection means (6) can comprise an optical sensor and / or a piezoelectric sensor

The system (100) includes a flow meter (5), placed inside each secondary pipe (3) in order to check the amount of air flow (F) that passes through the secondary pipe (3).

As shown in Fig. 2, the flow meter (5) includes a thermistor (50) capable of being hit by the air flow (F), which causes a lowering of the temperature of the thermistor (50). The thermistor (50) is a resistor whose resistance value varies with its temperature.

Advantageously, the thermistor (50) is of the Negative Temperature Coefficient (NTC) type.

With reference to Fig. 4, the flow meter (5) is electrically connected to a data processing unit (58) which can collect information from one or more control units (51) and / or from one or more flow meters. flow (5).

The control unit (51) comprising a voltage generator (G) designed to generate a constant electrical voltage (V *). The voltage generator (G) is connected in input to the thermistor (50) to supply the thermistor (50) with a constant voltage (V *).

The control unit (51) also includes a

current meter (C), connected at the output to the thermistor (50) to detect a current value (I) passing through the thermistor (50). The current flowing through the thermistor (50) heats the thermistor (50) by the Joule effect. The thermistor (50) heats up until a stable temperature value is reached in steady state. The stable temperature value is reached when the heat dissipated by the thermistor (50) is equal to the heat produced by the Joule effect of the current flowing through the thermistor (50). A stable temperature value of the thermistor (50) corresponds to a stable resistance value of the thermistor (50). When the thermistor (50) is hit by a flow of air having a temperature (-20 <T <40 ° C) compatible with the ambient temperature, and in any case lower than the temperature reached by the thermistor due to the Joule effect, the temperature of the thermistor is lowered and consequently, the resistance value of the thermistor (50) also varies.

The control unit (51) comprises a microcontroller (M) connected to the voltage generator (G) and to the current meter (C) to calculate the resistance value of the thermistor (50) starting from the current value (I) measured by the current meter (C) and by the constant voltage value (V *) supplied by the constant voltage generator (G). In fact, the resistance value of the thermistor (50) is equal to the ratio between the constant voltage value (V *) generated by the constant voltage generator (G) and the current value (I) detected by the current meter (C) .

For each calculated resistance value, a thermistor temperature value (50) corresponds. The microcontroller (M) is configured so as to calculate a numerical value proportional to the temperature of the thermistor (50) starting from the resistance value of the thermistor (50).

Performing an absolute measurement of the air flow, or obtaining a value that has its own unit of measurement, implies a complex detection system which, in addition to taking into account the air temperature, must be subjected to calibration and therefore respect the linearity parameters. , repeatability and stability on measurements. This would be expensive and useless to understand if an output has a different flow from the others.

In fact, to understand if if an output has a different flow from the others, it is sufficient to compare the values obtained by the thermistors to understand if the balance of the flows has changed and therefore to be able to intercept the output that has a different value from the others.

In this way, a change in temperature, flow in the main pipeline or any other quantity that is common to all flow meters, will not be able to alter the balance of the system.

As shown in Fig. 2, the thermistor (50) of the flow meter (5) includes terminals (52) to connect the thermistor (50) to the control unit (51) via connection supports (57a, 57b). The terminals (52) have a length between 1 mm and 100 mm and having a thickness between 0.01 mm and 1 mm.

The connection supports (57a, 57b) create a mechanical constraint and an electrical connection of the terminals (52) to the control unit (51).

In order to obtain a large excursion of the resistance value detected in the absence of air flow (F) and detected in the presence of air flow (F), it is necessary that the temperature value excursion of the thermistor (50) be large. . In order for the temperature range of the thermistor (50) to be high, the thermistor (50) must be small in size, in order to minimize thermal inertia. At the same time, a small thermistor (50) could burn out if passed through by a high electric current. Consequently, to thermally insulate the thermistor (50), the terminals (52) of the thermistor are long and thin.

The flow meter (5) comprises the connection supports (57a and 57b), electrically connected to the thermistor (50) and to the microcontroller (51) to allow the passage of electrical signals from the thermistor (50) to the microcontroller (51).

Multiple thermistors can be connected to a single control unit or to the same processing unit in order to simplify installation and to optimize costs.

As shown in Figs. 2 and 3, the flow meter (5) comprises support means (53) connected to the thermistor (50) and the secondary tube (3) to support the thermistor (50) and connect the thermistor (50) to the secondary tube (3 ).

The support means (53) comprise a base (54) arranged in a hole made on a side wall of the secondary pipe (3). Advantageously, the base (54) has a discoidal shape with a shape and size compatible with the shape, size and thickness of the secondary pipe.

The support means (53) comprise foils (55) connected to the base (54). The plates (55) are arranged in the shape of a comb, inclined with respect to the base. Each lamina (55) comprises a first end (55a) fixed to the base (54) and a second end (55b) free and raised with respect to the base (54). The thermistor (50) is arranged below the foils (55).

The first end (55a) of the foils (55) faces the air flow (F) and, consequently, towards the direction of origin of the product. In this way, the foils (5) act as protection for the thermistor (50), in case the product is granular. In fact, thanks to the second raised end of the foils (55), the granules are deflected away from the thermistor (50). The foils (55) therefore repair the thermistor (50) from the granules, preventing the granules from damaging the thermistor (50). At the same time, the plates (55) allow the passage of the air flow (F) towards the thermistor (50).

The foils (55) are flexible and have such a flexibility that they can oscillate due to the stresses produced by the granules impacting against the foils (55). This flexibility of the foils prevents any fragments, powders, filaments from getting stuck between the foils and consequently hindering the passage of air towards the thermistor (50).

The support means (53) comprise a first wing (56a) and a second wing (56b). The first wing (56a) and the second wing (56b) protrude from the base (54) and have a curvilinear shape. The first wing (56a) faces the second wing (56b) and mirrors the second wing (56b), so as to form a tapered channel. The laminae (55) are arranged in the channel formed by the wings (56a, 56b).

The wings (56a, 56b) allow to divert granules having large dimensions and to convey the flow of air (F) towards the thermistor (50). The wings (56a, 56b) have a curved shape to prevent the granules from getting stuck between the wings.

Thanks to the provision of the flow meter (5), it is possible to check the presence of air flow (F) in the secondary pipe (3). Furthermore, the flow meter (5) has no moving parts that can be damaged due to dust present in the secondary pipe (5).

Thanks to the provision of the support means (53) comprising the foils (55) and the wings (56a, 56b) it is possible to protect the thermistor (50) from the granules.

Furthermore, the flow meter (5) is inexpensive and can be small in size, so that it can be arranged non-invasively in the secondary pipe (3).

Claims (11)

CLAIMS 1) Plant (100) for the pneumatic distribution of a product comprising: - a tank (1) intended to contain the product to be distributed; - a main pipe (2) connected to said tank (1); said main tube (2) being intended to be crossed by the product; - at least two secondary pipes (3) connected to said main pipe (2); said secondary pipes (3) being intended to allow the product to escape from the system (100); and - handling means (4), of the pneumatic type, able to generate an air flow (F) which moves the product from the tank (1) to the main tube (2) and from the main tube (2) to the secondary tubes ( 3); characterized in that it further comprises - at least two flow meters (5) arranged inside the respective secondary pipes (3) in order to measure the air flow (F) that passes through the secondary pipes (3). 2) Plant (100) according to claim 1, wherein said flow meter (5) comprises a thermistor (50) arranged so as to be hit by the air flow (F) generated by the handling means (4), which causes a drop in the temperature of the thermistor (50); said thermistor (50) being shaped so as to vary its resistance value as its temperature varies. 3) Plant (100) according to claim 2, comprising at least one control unit (51) connected or integrated in a processing unit (58); said a control unit (51) comprising: - a constant voltage generator (G) connected to said thermistor (50) to supply said thermistor (50) with a constant voltage (V *); - a current meter (C) connected to said thermistor (50) for detecting a current value (I) flowing through the thermistor (50); And - a microcontroller (M) connected to said voltage generator (G) and to said current meter (C) to calculate the resistance value of the thermistor (50) starting from the current value (I) measured by the current meter (C) ) and the voltage value (V *) supplied by the voltage generator (G); said microcontroller (M) being configured so as to calculate a numerical value proportional to the temperature of the thermistor (50) starting from the resistance value of the thermistor (50); said processing unit (58) being configured so as to compare the measurements received from the control units (51) with each other and to evaluate whether one of said secondary pipes (3) is obstructed. 4) Plant (100) according to claim 3, wherein said thermistor (50) comprises terminals (52) for connecting said thermistor (50) to said control unit (51); said terminals (52) having a length between 1mm and 100mm and having a thickness between 0.01mm and 1mm so as to thermally insulate the thermistor (50). 5) Plant (100) according to any one of the preceding claims, wherein said flow meter (5) comprises support means (53) connected to said thermistor (50) and to said secondary tube (3) to support said thermistor (50) and connecting said thermistor (50) to the secondary pipe (3). 6) Plant (100) according to claim 5, wherein said support means (53) comprise: - a base (54) on which the thermistor (50) is arranged; and - laminae (55) connected to said base (54) and arranged in the shape of a comb, inclined with respect to the base; each lamina (55) comprising a first end (55a) fixed to the base (54) and a second end (55b) free and raised with respect to the base (54); said first end (55a) of the laminae (55) facing the air flow (F); said thermistor (50) being arranged below said laminae (55). 7) Plant (100) according to claim 6, in which said laminae (55) are flexible to avoid a grounding of granules in the case in which the product is granular. 8) Plant (100) according to claim 6 or 7, wherein said support means (53) comprise a first wing (56a) and a second wing (56b) which protrude from said base (54); said wings (56a, 56b) forming a tapered channel which receives said laminae (55). 9) Plant (100) according to claim 8, in which said wings (56) are curved to avoid grounding of the granules in the case in which the product is granular. 10) Plant (100) according to any one of the preceding claims, comprising presence detection means (6) arranged in the main tube (2) for detecting the presence of product in the main tube (2). 11) Use of at least two flow meters (5) arranged inside respective secondary pipes (3) of a plant (100) for the pneumatic distribution of product according to any one of the preceding claims, in which the flow meters (5 ) are used to measure the air flow (F) passing through the secondary tubes (3) in order to detect an obstruction of the secondary tubes.