SE1350150A1 - Agricultural implements and procedure for feeding air in an agricultural implement - Google Patents

Abstract

An agricultural tool (1) comprises a fan (4) arranged to create an air flow to a feeding device (5a, 5b) for dosing and/or feeding granular or powdery material, the fan (4) comprising a fan housing (40) housed in fan wheel (42), and wherein the fan housing has an inlet (41) upstream of the fan wheel (42) and an outlet (43) downstream of the fan wheel (42). The sizes and geometries of the fan wheel (42) and the fan housing (40) as well as the drive speed of the fan are selected so that the fan housing (40), downstream of the fan wheel (42) and upstream of the outlet have a part (P) where during operation there is a pressure in the range 0, 3-15 kPa and where a ratio between flow (q) and cross-sectional area (A) is in the range 3-10 m/s. Publication image: Fig. 1

Description

15 20 25 30 Summary An object is thus to provide an agricultural implement which has an improved feeding device for air flow-based feeding of granular or powdered material. Particular objects include providing a feeding device which has improved efficiency.

The invention is defined by the appended independent claims.

Embodiments appear from the dependent claims, from the following description and from the drawings.

According to a first aspect, there is provided an agricultural implement comprising a fan arranged to provide an air flow to a feeding device for dosing and / or feeding granular or powdered material. The fan comprises a fan wheel housed in a fan housing. The fan housing has an inlet upstream of the impeller and an outlet downstream of the impeller. The sizes and geometries of the fan wheel and fan housing and the drive speed of the fan are selected so that the fan housing, downstream of the fan wheel and upstream of the outlet has a portion where there is a pressure in operation in the range 0.3-15 kPa and where a ratio between flow q in the range 3-10 m / s.

The invention is based on the insight that an agricultural implement operated according to the above will admittedly have impaired efficiency in the fan itself, but if the air is to be distributed from the fan to different consumers, it has been found that distribution at high pressure and low flow rate gives an energy gain. conventional flow rate, and that this energy gain well outweighs the deterioration in efficiency of the fan itself, compared to a traditional worm fan.

In accordance with what is accepted in the theory of flow, a "cross-sectional area" is perpendicular to a direction of flow.

The agricultural implement may comprise at least two feeding devices for air flow-based dosing and / or feeding of granular or powdered material. In addition, the fan housing may have at least two outlets, each of which is arranged to provide said air flow to one of said feeding devices, and said portion is located upstream of both outlets. 10 15 20 25 30 3 The pressure can be in the range 0.542 kPa. In different embodiments, the pressure can be in the range 0.313 kPa, 3-7 kPa or 8-15 kPa.

The ratio can in different designs be 3-7 m / s, 4-6 m / s or about 5 mls. In further embodiments, the ratio may be 8-10 mls.

A cross-sectional area of a duct for directing the air from the outlet to the feeding device may be smaller than the cross-sectional area of the portion.

The fan may be of the centrifugal type and a direction of flow at the outlet may be substantially radial relative to the axis of rotation of the fan wheel.

Alternatively, the fan may be of the centrifugal type and a flow direction at the outlet may be substantially axial relative to the axis of rotation of the fan wheel.

The fan wheel may have, seen in the direction of rotation of the fan wheel, backwardly inclined or backwardly curved vanes.

The outlet can be connected to a distributor having a distributor inlet and at least two distributor outlets, wherein the distributor inlet can have a cross-sectional area which is at least equal to the cross-sectional area of the portion.

According to a second aspect, there is provided a method of feeding air into an agricultural implement comprising a feeding device for air flow based dosing and / or feeding of granular or powdered material.

The method comprises providing an air flow by means of a fan comprising a fan wheel housed in a fan housing. The method further comprises driving the fan wheel so that the fan housing, downstream of the fan wheel and upstream of the outlet has a portion where there is a pressure in the range 0.3-1 5 kPa and where a ratio between flow and cross-sectional area is in the range 3-10 m / s.

The method may further comprise at said pressure dividing the air flow into at least two separate air flows, each of which is led to a respective feeding device for air flow-based dosing and / or feeding of granular or powdered material.

According to one embodiment, the distribution can take place in the fan housing.

According to another embodiment, the distribution can take place in a distributor connected to the fan housing, so that the ratio upstream of a distributor outlet does not increase compared with the ratio present in the portion of the fan housing. Brief Description of the Drawings Fig. 1 is a schematic view of an agricultural implement 1, which is pulled by a towing vehicle 2.

Figs. 2a-2c are schematic views of a fan 4 according to a first embodiment.

Figs. 3a-3c are schematic views of a fan 4 according to a second embodiment.

Figures 4a-4c are schematic views of a fan 4 according to a third embodiment.

Figs. 5a-5c are schematic views of a fan 4 according to a fourth embodiment.

Fig. 6 is a schematic sketch of a distributor 9.

Description of embodiments Fig. 1 shows an agricultural implement 1, which may be, for example, a seed drill, a fertilizer spreader, a pesticide spreader or a combined agricultural implement, which comprises two or more such functions.

The agricultural implement 1 may be designed to be towed or supported by a towing vehicle 2, such as a tractor, which may supply the agricultural implement 1 with power via a power transmission 7. Such power transmission may be in the form of mechanical force (such as a shaft coupling), hydraulic power, pneumatic force and / or electric power.

The agricultural implement has a fan 4, which is connected to a pair of feeding devices 5a, 5b for feeding granular or powdered material via respective channels 6a, 6b. The granular or powdered material may be seed, fertilizer or pesticide.

The fan 4 may be of the centrifugal type and have a fan wheel 42, which is designed to take in air through an inlet 41 at the center of the fan wheel, so that an inlet direction is substantially axial relative to the fan wheel 42. The fan wheel 42 may have, set the direction of rotation of the fan wheel, rearward bent or backwardly inclined vanes 421. An outlet direction from the fan housing 40 may be substantially radial relative to the fan wheel 42. Alternatively, the outlet direction may be substantially axial relative to the fan wheel 42.

The fan 4 can be driven by means of force supplied from the towing vehicle 2, as described above. The fan wheel 42 can, in a conventional manner, be designed to rotate at a given speed at a given power supply. Alternatively, the fan can be driven via a variable transmission or via a motor whose speed is controllable.

A control unit 8 can be arranged to provide control signals to the fan 4. Such control signals can for instance regulate the speed of the fan, a transmission associated with the fan and / or valves / dampers (not shown) at the outlet of the fan. The control unit 8 can be arranged to communicate with the towing vehicle 2, a control unit arranged in the towing vehicle (not shown) or a user interface (not shown) arranged in the towing vehicle.

As can be seen from the various figures, the options for designing the fan 4 are great: based on a given need for pressure and flow, and taking into account expected energy losses, the person skilled in the art can choose the fan wheel and motor with sufficient capacity.

Those skilled in the art further know that in stationary flow, the product of density, cross-sectional area and flow rate is constant. Thus, those skilled in the art can select the cross-sectional area of a portion P in the fan housing downstream of the fan wheel 42 and upstream of the outlet 43 to provide a certain flow rate.

According to the invention, a pressure in the portion should be 0.3-15 kPa and a flow velocity should be 3-10 m / s. In an operating case where the air flow is to be distributed to two or three consumers, the ratio q / A can be allowed to be around 8-10 m / s, which gives good efficiency in the fan.

If the material to be dosed or fed is heavy, for example in the "nursing" of seeds (such as corn, soybeans, etc.), or if the feeding is to take place over a longer distance, a higher pressure can be chosen, such as 8-15 kPa, preferably 10-14 kPa, 11-13 kPa or about 12 kPa.

If the air flow is instead to be used for overpressure-based singulation of, for example, seed, a medium-high pressure can be used, such as 2-7 kPa, preferably 3-6 kPa, 3-5 kPa or 3-4 kPa. 10 15 20 25 30 6 If the air flow is instead to be used for transport of light material, for example seed (such as grain), a low pressure can be used, such as 0.3-2 kPa, preferably 0.3-1 kPa, 0.4- 0.6 kPa or about 0.5 kPa. In an operating case where the air flow is to be distributed to three or more consumers, the ratio q / A can be selected to about 2-7 m / s, whereby pressure is selected based on application as described above.

When designing the fan housing, the ratio q / A is chosen as a compromise between, on the one hand, the technical function, where a lower value of the ratio q / A is advantageous from a technical point of view by obtaining lower energy loss, while a higher value of the ratio q / A is advantageous from a design or space point of view, since a smaller fan housing can then be created.

Figs. 2a-2c show a first embodiment of a fan, which can be operated so that the above pressures and speeds are obtained. The fan 4 can be connected directly to a consumer, possibly via a channel 6a, 6b which has a smaller cross-sectional area than the portion P in the fan housing.

The fan 4 in Figs. 2a-2c has an inlet 41, which is surrounded by conical walls so that a cross-sectional area tapered towards the fan wheel 42 is provided. The fan wheel 42 may have vanes 421 whose, seen in the radial direction, central portion has an increased axial width. For example, the vanes may have a portion with increasing axial width.

The fan housing 40 may have an adjacent side wall 401 outlet of the fan wheel, the distance of which to the periphery of the fan wheel 42 is substantially constant in a circumferential direction. The distance between the periphery of the fan wheel and the side wall 401 can be selected so that a free area between the periphery of the fan wheel and the side wall 401 is less than half of a cross-sectional area A at the portion P.

As can be seen from Figs. 2a-2c, the outlet from the fan housing is directed substantially axially relative to the fan wheel. The fan housing can thus be made substantially rotationally symmetrical.

Figs. 3a-3c show a second embodiment of a fan 4, which can be operated so that the above pressures and speeds are obtained. This embodiment is similar to the embodiment in Figs. 2a-2c, but the fan housing has an integrated distributor in that the fan housing has a plurality of outlets 43. In addition, the fan housing has an outlet of the fan wheel adjacent the side wall 401, the distance of which to the periphery of the fan wheel 42 is 10 substantially constant in the circumferential direction, but increasing in the axial direction of the fan.

Figs. 4a-4c show a fan, the outlet direction of which is substantially radial relative to the fan wheel 42 and whose fan housing has a thickness, set axial direction, which is substantially constant. The fan in Figs. 4a-4c has a lower portion which is open downwards and forms an outlet 43, which can be connected to a distributor 9 (see Fig. 6), which can be integrated with a part of the agricultural implement as the support fan. Such a part of an agricultural implement can be a beam which is designed to also function as an air duct or a seed box with a built-in distributor.

The side wall 401 here has a substantially parabolic shape, the maximum of the parabola being the point closest to the periphery of the fan wheel 42. Seen in a plane perpendicular to the axis of rotation (Fig. 4b), the fan housing is symmetrical about the central plane CP. The inlet wall 402 and the engine wall (the wall to which the engine is fixed) may be substantially flat.

Figs. 5a-5c show a fan whose outlet direction is substantially radial relative to the fan wheel 42 and whose fan housing 40 has two outlets 43, each of which can be connected to a respective distributor 9 (see Fig. 6). The outlets 43 are directed substantially opposite each other. As shown in Fig. 5c, the fan housing has a thickness, seen in the axial direction, which is substantially constant. The inlet wall 402 and the engine wall (the wall to which the engine is fixed) may be substantially flat.

Characteristic of the embodiments shown above is that the side surface 401 of the fan housing follows the periphery of the fan wheel 42 in the sense that, seen in a plane perpendicular to the axis of rotation and seen along a radius from the axis of rotation and outwards, the inclination of a tangent to the side wall 401 the same sign over less than about 270 ° of a fan revolution, preferably less than about 225 ° of a fan revolution or less than about 180 ° of a fan revolution. The same sign refers to the slope that each key would have seen in an orthogonal coordinate system.

The fans 2 in Figs. 2a-2c or Figs. 4a-4c can be connected to a distributor 9, which has an inlet 91 to which the outlet 43 of the fan housing 40 is connectable and a plurality, for example two, three, four, five or six, outlet 93, to which the respective feeding device is connectable. It will be appreciated that the connection between the fan housing 40 and the distributor 9 should be such that the cross-sectional area A does not decrease, since the flow rate then increases, which leads to energy loss during the distribution.

A cross-sectional area at the inlet 91 of the distributor should thus be as large as a cross-sectional area at the outlet of the fan housing and preferably in the same way as the portion P in the fan housing, have a pressure of 0.3-15 kPa and a flow velocity of 3-10 m / s. Furthermore, this pressure of 0.3-15 kPa and a flow velocity of 3-10 m / s can be present in a space in the distributor, downstream of the distributor inlet and upstream of the outlets 93.

Common to the above fans is that they have a sufficiently large space along a relatively large part of the periphery of the fan wheel 42 for the influence of the flat wheel on the flow speed at the outlet 43 to be eliminated or at least substantially reduced. This is in contrast to, for example, worm fans, where the fan housing is designed so that over between 1/2 and% of the circumference of the flywheel, the distance between the periphery of the flywheel and the adjacent fan housing wall increases continuously.

The fans shown herein have fan housings where a radial distance between side wall 401 and fan periphery, set a section perpendicular to the axis of rotation of the fan, is constant over at least 45 °, preferably at least 90 °, at least 315 ° or substantially 360 °.

Claims (13)

10 15 20 25 30 9 PATENT REQUIREMENTS An agricultural implement (1) comprising: a fan (4) arranged to provide an air flow to a feeding device (5a, 5b) for dosing and / or feeding granular or powdered material, the fan (4) comprising a fan housing (40) housed the fan wheel (42), and wherein the fan housing has an inlet (41) upstream of the fan wheel (42) and an outlet (43) downstream of the fan wheel (42), characterized in that the sizes and geometries of the fan wheel (42) and the fan housing (40) and drive speed for the fan is selected so that the fan housing (40), downstream of the fan housing (42) and upstream of the outlet have a portion (P) where during operation there is a pressure in the range 0.345 kPa and where a ratio between flow (q) and cross-sectional area (A) is in the range 3-10 m / s. Agricultural implement according to claim 1, wherein the agricultural implement comprises at least two feeding devices (5a, 5b) for air flow-based dosing and / or feeding of granular or powdered material, wherein the fan housing (40) has at least two outlets (43), each of which is arranged providing said air flow to one of said feeding devices (5a, 5b), and said portion (P) being upstream of both outlets (43). Agricultural implement according to one of the preceding claims, wherein the pressure is in the range 0.5-12 kPa. Agricultural implement according to one of the preceding claims, wherein the ratio is 3-7 m / s, 4-6 m / s or approx. 5 m / s. 10 15 20 25 30 10 Agricultural implement according to any one of the preceding claims, wherein a cross-sectional area of a duct for directing the air from the outlet to the feeding device is smaller than the cross-sectional area in the portion (P). Agricultural implement according to any one of the preceding claims, wherein the fan (4) is of the centrifugal type and wherein a direction of flow at the outlet is substantially radial relative to the axis of rotation (C) of the fan wheel. Agricultural implement according to any one of the preceding claims, wherein the fan (4) is of the centrifugal type and wherein a flow direction at the outlet is substantially axial relative to the axis of rotation (C) of the fan wheel. Agricultural implement according to one of the preceding claims, wherein the fan wheel (42) has, seen in the direction of rotation of the fan wheel, backwardly inclined or backwardly bent blades (421). An agricultural implement according to any one of the preceding claims, wherein the outlet (43) is connected to a distributor (9) having a distributor inlet (91) and at least two distributor outlets (93), and wherein the distributor inlet (91) has a cross-sectional area of at least equal size as the cross-sectional area of the lot (P). A method of feeding air in an agricultural implement comprising a measuring device for air flow-based dosing and / or feeding granular or powdered material, comprising: providing an air flow (q) by means of a fan (4) comprising a fan wheel (42) which housed in a fan housing (40), characterized by driving the fan wheel (42) so that the fan housing (40), downstream of the fan wheel (42) and upstream of the outlet has a portion (P) where there is a pressure in the range 0.3-15 kPa and where a ratio between flow (q) and cross-sectional area (A) is in the range 3-10 m / s. 10 15 ll A method according to claim 10, further comprising dividing the air flow at said pressure into at least two separate air flows (q1, q2, q3), each of which is led to a respective supply device (5a, 5b) for air flow-based dosing and / or feeding of granular or powdered material. A method according to claim 11, wherein the distribution takes place in the fan housing (40). A method according to claim 11, wherein the distribution takes place in a distributor (9) connected to the fan housing, so that the ratio (q / A) upstream of a distributor outlet (93) does not increase compared with the ratio present in the portion (P) in the flat housing (40). ).