Feeder housing for feeding granular or powdery material, feeding system, agricultural implements inc

专利摘要:
This document shows a feed housing (12) for feeding granular or powdered material. The feed housing comprises a feed space (123) with a material inlet (121) and a material outlet (122), and a wall portion (124, 124 ') extending between the material inlet and the material outlet. The wall portion (124, 124 ') is substantially in the form of a cylindrical sector. The wall portion (124, 124 ') has a scraper portion (1241, 1241') which extends substantially parallel to a center axis of the cylinder sector. Publication image: Fig. 2
公开号:SE1551290A1
申请号:SE1551290
申请日:2015-10-08
公开日:2017-04-09
发明作者:Gilstring Gert
申请人:Väderstad Holding Ab；
IPC主号:

专利说明:

| / IATARHUS FOR IVIATNING granular OR PULVERFORIVIIGTMATERIAL, IVIATARSYSTEIVI, agricultural equipment O | / IFATTANDESADANT IVIATARSYSTEIVI AND METHOD FOR IVIATNING AVGRANULÄRT OR PULVERFORIVIIGT | / IATERIAL Technical Field This document relates to a feeder housing for feeding granular ellerpulverformigt material which finds application particularly in agricultural implements.
The document also refers to a system for feeding granular or powdered material comprising such a feeding house and an agricultural implement comprising such a system.
The document also relates to a method for feeding granular or powdered material in an agricultural implement.
Background It is known from, for example, WO2013180619A1, that in an agricultural implement, granular or powdered material is fed from a material container via a feeder to a duct for receiving the material in an air stream, which feeds the material on to, for example, a plurality of saw beetles. The lathe comprises a feed housing, in which a feed rotor is rotatably arranged.
The air flow is typically provided by a fan or pump, which creates an overpressure in the duct that conducts the air flow.
To reduce energy consumption, it is desirable to ensure that the overpressure is maintained throughout the duct. One challenge is to insert the material into the channel without losing the overpressure.
One way to achieve this is by providing the material container with a tight-fitting lid, so that the overpressure is maintained all the way up in the material container.
Another way of achieving this is to use an injector, whereby a vacuum suction to the duct is provided according to the venturi principle. 2 Another way is to provide a feeder which acts as a single air lock and thus prevents the overpressure in the duct from leaking to the top material container, so that normal pressure can be allowed in the material container.
Normal pressure in the material container is advantageous in that it is difficult to achieve a large material container, with an equally large lid, which closes sufficiently tightly.
One problem is that both the environment in which agricultural implements are used and the material that is fed, often give rise to large amounts of dust and dirt, which makes it difficult to achieve good seals.
Another problem is that the material to be fed can interfere with the interfering feeder rotor, so that the rotor blades are prevented from closing tightly inside the feeder housing. Based on the premise that it is desirable to provide a feeder which functions as an air lock, there is a need for an improved feeder, and in particular of a feeder which reduces air leakage in a reverse direction from feeder outlet to feeder inlet.
SummaryA purpose is thus to achieve an improved feeder. A particular object is to provide a feeder which causes less pressure loss than known feeders.
The invention is defined by the independent claims. Embodiments appear from the dependent claims, from the following description and from the drawings.
According to a first aspect, a feed housing is provided for feeding degranular or powdered material. The latar housing comprises a feeding space with a material inlet and a material outlet, and a wall portion extending between the material inlet and the material outlet. The wall portion is substantially in the shape of a cylinder sector. The wall portion has a scraper portion which extends substantially parallel to a center axis of the cylinder sector. l / joint "substantially parallel" is meant here +/- 10 °, preferably +/- 5 °, +/- 1 ° or completely parallel. By providing a scraper part, material stuck between the rotor blade and the wall can be detached, whereby sealing abutment of the distal part of the rotor blade and the wall can be restored.
Experiments have shown that leakage flow from material outlet to material inlet can be reduced by in the order of 30-50 ° />.
The scraper part may comprise at least one recess recessed in the wall portion, which extends along substantially the entire axial length of the cylinder sector.
A latch has the advantage that material can be removed in a way that is too rotor blade-friendly.
The scraper part may comprise at least one raised axis, which extends along substantially the entire axial length of the cylinder sector.
An ace has the advantage that a sealing abutment is maintained in the event that material is stuck between the wall and the rotor blade passing the ace.
The scraper portion may extend over a center angle of the cylinder sector which is less than 10 °, preferably less than 5 degrees, less than 1 ° or less than 0.5 °. "Center angle" means an angle about the center axis of the cylinder sector.
The scraper part may be located at an upper part of the wall portion in the vertical direction, preferably within a center angle of the cylinder sector corresponding to the highest 45 °, the highest 30 ° or the highest 15 °.
Because the scraper part is located near the inlet opening and preferably at such a position that the space between the rotor blades is still being filled, the possibility is given for the material which is scraped to be taken up by the space between the rotor blades.
According to a second aspect, a feed system for feeding degranular or powdered material into an agricultural implement is provided. The feed system comprises a feed housing as described above, and a feed rotor, which is driven rotatably in the feed space while outer portions of the rotor blade of the feed rotor are in contact with the wall portion. The contact between the rotor blades and the feed housing is preferably airtight, which can be achieved by biasing the rotor blades against the feed housing.
The rotor blades may be formed of an elastic material, preferably a rubber-elastic material, such as rubber, TPE or polyurethane.
The rotor blades can be biased against the wall portion, so that leakage of air between the material inlet and the material outlet is prevented. In the feed system the scraper part may be arranged so that the scraper part is located downstream, seen in a material flow direction envertically highest point at which said rotor blade is in contact with the wall portion, and within a center angle of the cylinder sector from the highest point corresponding to less than 30 ° or preferably less than 20 ° 10 °.
According to a third aspect, an agricultural tool for feeding degranular or powdered material is provided. The agricultural implement comprises a single container for the material, an air flow generating device, and a duct connected to the air flow generating device. The agricultural implement further comprises a feeding system as described above, arranged feeding of the material from the container to the air duct.
According to a fourth aspect, there is provided a method of feeding granular material or powdered material into an agricultural implement. The method comprises receiving the material in a material inlet located at an upper portion of a feeder housing, between the material inlet and the material outlet extending cylindrical sector-shaped wall portion, feeding a predetermined amount of material per unit time, and discharging the material into a material outlet located at a lower portion of the feed housing. Furthermore, the method comprises loosening material which is stuck between the rotor blade and the wall portion by means of a radial level variation in the wall portion.
Brief Description of the Drawings Fig. 1 is a schematic view of a feed system 1 for feeding granular or powdered material. Fig. 2 shows a feed housing according to a first embodiment, seen in section.
Fig. 3 shows a feed housing according to a second embodiment, seen in section.
Fig. 4 shows a feed housing according to a third embodiment, seen in section.
Detailed description Fig. 1 shows a feeding system 1, which can be supported by an agricultural implement 0, and is used there to distribute granular or powdered material to land over which the agricultural implement travels. Non-limiting examples of such materials may be seeds, fertilizers and / or pesticides. It will be appreciated that different types of material may be fed into the same system, and that an agricultural implement may be provided with parallel systems, where for example one may feed seed and another may feed fertilizer or pesticide.
The system 1 comprises a material container 10, which may have a cover 11 in the form of a lid or a tarpaulin. The system further comprises a feed housing 12, which houses a feed rotor 13, which is rotatable in the feed housing 12. The latar rotor 13 can be driven by a drive unit, such as an electric or hydraulic motor (not shown). The latar rotor 13 can be driven directly by the motor or indirectly, for example via a transmission, which may comprise gears, belts or friction wheels. The lath housing 12 has an inlet 121 at its upper portion and an outlet 122 at its lower portion. The inlet 121 connects to a lower portion of the material container 10, so that material contained therein can be fed to the feed housing 12 at least in part by means of gravity. Any additional feeding can be accomplished using a stirrer, auger or fluidized bed. The feed housing 12 houses a feed space 123, which may have a generally cylindrical shape. The larynx space 123 has a cylindrical boundary surface 124, the radius of which is approximately equal to or slightly less than a radius of the feed rotor 13. The radially outer portion of the wing blade 131 of the latar rotor may thus abut the cylindrical boundary surface 124. The abutment may be the wing blades 131 are biased against the cylindrical boundary surface 124. Thus, due to the friction between the wing blades and the cylindrical boundary surface 124, the wing blades may bend slightly while the feed rotor 13 rotates in the feed space 123. one may have a bushing for a shaft about which the feed rotor 13 is rotatable. This shaft may be a drive shaft, which, as described above, may be connected to the drive unit.
In the case of an axially opposite portion of the feed rotor 13, an axial limiting surface may comprise a bushing and / or bearing for the shaft.
According to a first alternative embodiment, the feed rotor 13 may have a free end of the feeder housing, i.e. no support in the radial direction at the axially opposite portion relative to the drive shaft.
According to a second alternative embodiment, a shaft feed-through displacement shaft can be provided at one axial end of the feed rotor 13, while at its other axial end a support is provided in the form of an integral part of the axial limiting surface. The axial outer space 123 may have an axial length equal to, or slightly less than, an axial length of the feed rotor 13. The axially outer portions of the lateral wing blades 131 of the latar rotor may thus abut at least one axial boundary surface.
The bearing may be such that the vane blades 131 are biased toward the axial boundary surface 124. Thus, due to the friction between the vane blades and the axial boundary surface, the vane blades may bend slightly below that the feed rotor 13 rotates in the feed space 123. which connects to a duct, so that the feed rotor 13 fed material is introduced into the duct 14 via a duct inlet 141. A pump or fan 15 may be connected to the duct to provide an air flow in the duct 14. At the duct inlet 141 the material can be introduced into the duct, so that a material-mixed air flow is achieved.
The channel 14 can lead the material directly to one or more discharge parts, for example saw beetles 16a, 16b, 16c or fertilizer beetles.
According to an alternative, a distributor 17 can be arranged for distributing the material-mixed air stream to the saw blades 16a, 16b, 16c. Such distributors are known from, for example, WO2015112086A1. As a further alternative, or complement, one or more singularizing devices 18a, 18b, 18c may be provided to ensure a smoother material flow to the saddles 16a, 16b, 16c. Such singulating devices are known from, for example, WO2015069179A1. The latar rotor 13 may comprise a rotor core 132 and a plurality of rotor blades 131. The rotor core 132 may be made of a relatively rigid material, seasonal or polymer. In the latter case, the rotor core can be formed of a construction plastic with relatively high rigidity.
The rotor core 132 may be integrated with a motor shaft, i.e. permanently connected to the motor shaft or formed integrally with the motor shaft. Alternatively, the rotor core 132 may be a separate part which is connected to a motor shaft in such a way that torque from the motor is transferable to the feed rotor 13.
The rotor blades 131 may be formed of polymeric material with bearing stiffness than the material of which the rotor core is formed.
For example, the rotor blades may be formed of an elastic material, such as a rubber-elastic material, for example polyurethane, rubber, thermoplastic elastomer or the like. Elastic materials with hardness Shore A in the order of 30-90, preferably 50-70, have proved suitable.
Preferably, the rotor blades 131 may also be formed of a material which is softer than the material of which the boundary walls 124 of the feed space are formed.
The rotor blades 131 may be formed in a piece of material which may surround and enclose the core 132. Fig. 2 shows a first embodiment of a feed housing, where one of the walls defining the feed space 123, more specifically a cylinder sector mold wall 124, is provided with a groove recessed in the wall. 1241. The latch 1241 may extend over substantially the axial length of the feed space 123.
The rafter can have a depth corresponding to 0.1-20 ° /> of the radius of curvature of the wall, preferably 0, 5-15 ° />, 1-15 ° / -. ~, 5-15 ° / -. ~, 7-13 ° /> or about 10 ° / °.
The rafter may have a width, seen along the tangential direction of the wall 124, which may be about 1 ° -30 °, 5 ° -25 °, 10 ° -20 ° or about 15 °. The rafter can have straight or curved walls.
For example, the rafter may have a pair of straight walls, which at the bottom of the rafter form an angle with each other.
Alternatively, the rafter may have a substantially cylindrical sector-shaped cross-section.
Fig. 3 shows a second embodiment of a feed housing, where one of the walls defining the feed space 123, more particularly a cylinder sector shaped wall 124 ", is provided with an axis 1241 'projecting from the wall. The shaft can have a height corresponding to 0.1 -20 ° /> of the wall's 124 "bending radius, preferably 0, 5-15 ° />, 1-15 ° / -. ~, 5-15 ° / -. ~, 7- 13 ° /> or about 10 ° / °. The shaft may have a width, seen along the tangential direction of the wall 124, which may be about 1 ° -30 °, 5 ° -25 °, 10 ° -20 ° or about 15 °. The donkey can have straight or curved walls.
For example, the ace may have a pair of straight walls, which at the top of the ace form an angle with each other.
Alternatively, the shaft may have a substantially cylindrical sector-shaped cross-section. In an alternative embodiment, two, three or more aces may be present. Preferably, such aces are substantially parallel to each other.
As a further alternative, one or more grooves 1241 may be combined with one or more aces 1241 ”. Fig. 4 shows an embodiment which is in accordance with that shown in Fig. 2, except that here instead there are two grooves 1241 a, 1241 b, which are 9 located next to each other and run parallel to each other, within an angular position of less than 10 °, preferably less than 5 ° or less than 3 ° around the center of the wall 124.

权利要求:
Claims (11)
[1]
A lath housing (12) for feeding granular or powdered material, comprising: a feed space (123) with a material inlet (121) and a material outlet (122), and a wall portion (124, 124 ") extending between the material inlet and the material outlet, wherein the wall portion (124, 124 ') is substantially in the form of a single cylinder sector, characterized in that the wall portion (124, 124 ") has a scraper portion (1241, 1241", 1241 a, 1241 b) which extends substantially parallel to a center axis of the cylinder sector. .
[2]
A lath housing according to claim 1, wherein the scraper part comprises at least one recessed groove (1241, 1241a, 1241b) in the wall portion (124), which extends along substantially the axial length of the entire cylinder sector.
[3]
A lathe housing according to claim 1 or 2, wherein the scraper part comprises at least one raised axis (1241 "), which extends along substantially the axial length of the entire cylinder sector.
[4]
A lath housing according to any one of the preceding claims, wherein the scraper portion (1241, 1241 ', 1241a, 1241b) extends over a center angle of the cylinder sector which is less than 10 °, preferably less than 5 degrees, less than 1 ° or less than 0 °. .5 °.
[5]
A lath housing according to any one of the preceding claims, wherein the scraper part (1241, 1241 ', 1241a, 1241 b) is located at a vertically upper part of the wall portion, preferably within a center angle of the cylinder section corresponding to the highest 45 °, the the highest 30 ° or the highest 15 °.
[6]
A loading system (1) for feeding granular or powdered material into an agricultural implement, comprising: a feed housing (12) according to any one of the preceding claims, and a feed rotor (13), which is driven rotatably in the feed space below the outer portions of the rotor blade (131) of the feed rotor is in contact with the wall portion.
[7]
A lathe system according to claim 6, wherein the rotor blades (131) are formed of an elastic material, preferably a rubber-elastic material, such as rubber, TPE or polyurethane.
[8]
A charger system according to claim 6 or 7, wherein the rotor blades are biased against the wall portion so that leakage of air between the material inlet (121) and the material outlet (122) is prevented.
[9]
A charging system according to any one of claims 6-8, wherein the scraper part is located downstream, seen in a material flow direction a vertically highest point at which said rotor blade (131) is in contact with the wall portion (124, 124 "), and within a center angle of the cylinder sector from the highest point corresponding to less than 30 °, preferably less than 20 ° or less than 10 °.
[10]
Agricultural implement (0) for feeding granular or powdered material, comprising: a container (10) for the material, an air flow generating device (15), and a channel (14) connected to the air flow generating device, characterized by a feed system (1) according to any of claims 6-8, provided for feeding the material from the container (10) to the air duct (14). 12
[11]
A method of feeding granular material or powdered material into an agricultural implement (0), comprising: receiving the material in a material inlet (121) located at an upper portion of a feed housing (12), which by means of a feed rotor (13), which rotor blades, which lie opposite a wall portion (124, 124 ") extending between the material inlet and a material outlet, feed a predetermined amount of material per unit time, and to discharge the material in the material outlet (122) located at a lower portion of the feed housing, characterized in that by means of a radial level variation (1241, 1241 ”, 1241a, 1241b) in the wall portion loosen material stuck between the rotor blade and the wall portion.

类似技术:

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同族专利:

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US20180310470A1|2018-11-01|

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WO2017061941A1|2017-04-13|

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EP3358930B1|2019-09-25|

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CA3001280A1|2017-04-13|

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法律状态:

优先权:

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申请号 | 申请日 | 专利标题

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SE1551290A|SE541232C2|2015-10-08|2015-10-08|Feeder housing for feeding granular or powdery material, feeding system, agricultural implements including such feeding system and method for feeding granular or powdery material|SE1551290A| SE541232C2|2015-10-08|2015-10-08|Feeder housing for feeding granular or powdery material, feeding system, agricultural implements including such feeding system and method for feeding granular or powdery material|

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CA3001280A| CA3001280A1|2015-10-08|2016-10-06|Meter housing for feeding granular or powdered material, meter system, agricultural implement comprising such meter system and method for feeding granular or powdered material|

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EP16794081.6A| EP3358930B1|2015-10-08|2016-10-06|Meter housing for feeding granular or powdered material, meter system, agricultural implement comprising such meter system and method for feeding granular or powdered material|

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PCT/SE2016/050960| WO2017061941A1|2015-10-08|2016-10-06|Meter housing for feeding granular or powdered material, meter system, agricultural implement comprising such meter system and method for feeding granular or powdered material|

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US15/766,482| US10561058B2|2015-10-08|2016-10-06|Meter housing for feeding granular or powdered material, meter system, agricultural implement comprising such meter system and method for feeding granular or powdered material|