RU2475010C2 - Device for presowing treatment of large seeds - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: device comprises a belt conveyor, a source of ultraviolet (UV) radiation, the hoppers of supply and receiving seeds, and a sensor for detecting the irradiation dose of seeds. The belt conveyor shaft is connected to the electric drive. The source of UV irradiation is enclosed in a casing and is mounted above the conveyor belt. Above the first belt conveyor the belt of the second belt conveyor is mounted with the possibility of its interaction with the irradiated seeds and with the possibility of adjusting the height of its location and tension. The second conveyor belt is made of ultraviolet-transmitting material. At the lower part of the hopper of supply a dispenser and a sensor of seeds presence is mounted, connected to the input of the unit of control and management. The dispenser through the electric drive is connected to the output of the time relay, the other two outputs of which give a signal to electric drives of the first and second belt conveyors. The other inputs of the unit of control and management are connected to the outputs of sensors for detecting the irradiation dose of seeds and the output of the operating modes selector. The output of the unit of control and management is connected to the input of the time relay, and to the inputs of start-control devices the signal is given from the time relay output and the output of the unit of control and management. And the output of the start-control devices is connected to a source of (UV) radiation.

EFFECT: use of the invention enables to enhance the uniformity of the seeds irradiation.

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Description

The invention relates to the field of agriculture, in particular to crop production, and may find application in the preparation of large seeds for sowing.

A device for treating cotton seeds is known (RF patent No. 2265304 A01C 1/00). A device for treating cotton seeds, comprising treating the seeds with a high-frequency alternating electromagnetic field. Seeds are blown through a gas-electric plasma, which is ionized air, heated to 200-250 ° C in an alternating high-frequency electromagnetic field for 0.5-1.0 s. The inductor is connected to a high-frequency source of electrical energy. The inductor is mounted on a quartz tube to create a high-frequency alternating electromagnetic field that forms a gas-electric plasma inside the tube through which the seeds are blown.

The disadvantages of this device are:

1. It is impossible to control the feed rate of cotton seeds, hence the uneven processing of seeds, which can lead to reinfestation of seeds.

2. When processing at an elevated temperature, the seed germ may die or be injured, which in turn leads to reduced germination and productivity.

A device is known for pre-sowing seed treatment with optical radiation (RF patent No. 2278492 A01C 1/00). A device for pre-sowing seed treatment with optical radiation, comprising a cylindrical body, an optical radiation source connected through a power supply to a power source. The optical radiation source consists of an even number of lamps, at least six LE-30 lamps, the maximum radiation of which falls on the wavelength range of 340-347 nm, evenly distributed on the inner side of the cylindrical body, with some lamps connected through the chokes of the power supply, respectively to the first, second and third phases of the network, and other lamps are connected respectively to the same phases of the network through the chokes of the power supply and additional capacitors, while lamps with different connections to the network are installed in turn vaniem relative to one another to form a circular rotating field optical radiation. The device is mounted on a seed dresser by means of a transition element.

The disadvantages of this device are:

1. This device irradiates seeds in suspension, and for cotton seeds, for example, it is impossible to irradiate in suspension, since they cling, and a lump is obtained, it is impossible to obtain uniform exposure for cotton seeds.

2. Used erythema lamps, which are not so effective against bacteria, viruses, diseases, etc.

The closest technical solution is a device for presowing treatment of seeds (RF Application for invention No. 99117472/13, А01С 1/00), containing a conveyor belt, the shaft of which is connected to the electric drive, an ultraviolet radiation source enclosed in a casing and mounted above the conveyor belt, a vibrator , grain feeding and receiving silos. It is equipped with a photosensor for determining the dose of radiation to the seeds, which is located above the conveyor belt under the source of ultraviolet radiation and is electrically connected through the signal conversion unit to the electric drive of the conveyor belt. The vibrator is rigidly fixed to the shaft of the conveyor belt and is made in the form of an asterisk with bent ends interacting with the grain feed hopper and the conveyor belt. The seed hopper is made in the form of telescopic cylinders with matching slots for rashing seeds.

The disadvantage of this device is:

1. Uneven supply of seeds from the hopper and their various layer on the conveyor is possible and, as a consequence, their irregular irradiation.

The objective of the invention is to increase the uniformity of seed irradiation.

The problem is solved due to the fact that the device for pre-sowing treatment of large seeds, containing belt conveyors, the shafts of which are connected to the electric drive, an ultraviolet radiation source enclosed in a casing and mounted above the conveyor belt, seed feeding and receiving bins, a seed dose detection sensor, which is located above the conveyor belt under the source of ultraviolet radiation, and the electric drive of the conveyor belt, above the first conveyor belt, a second about the conveyor with the possibility of its interaction with the irradiated seeds and with the possibility of regulating the height of its location and tension, made of a material that transmits ultraviolet light, and is installed at the bottom of the feed hopper as a dispenser, which is connected through the electric drive to the output of the time relay, two other outputs of which they supply a signal to the electric drives of the first and second belt conveyors, as well as a seed sensor connected to the input of the control and control unit, and its other inputs are connected to the outputs of the sensors EFINITIONS irradiation dose seed yield and the setpoint operating mode, wherein the inputs of ballasts signal is output from the output time switch and the control unit, and an output coupled to the ballasts ultraviolet radiation source.

New significant features:

1. Above the first belt conveyor is a belt of the second conveyor with the possibility of its interaction with the irradiated seeds.

2. The belt of the second conveyor is made with the possibility of regulating the height of its location and tension.

3. The belt of the second conveyor is made of a material that transmits ultraviolet light.

4. A dispenser is installed in the lower part of the input hopper, which is connected via an electric drive to the output of the time relay, the other two outputs of the latter supply a signal to the electric drives of the first and second belt conveyors.

5. At the bottom of the input hopper there is a sensor for the presence of seeds, which is connected to the input of the control and management unit.

6. Other inputs of the control and management unit are connected to the output of the sensors for determining the dose of radiation to the seeds and to the output of the setpoint mode of operation.

7. The output of the control and management unit is connected to the input of the time relay.

8. The inputs from the output of the time relay and the output of the monitoring and control unit are fed to the inputs of ballasts.

9. The output of ballasts is connected to a source of ultraviolet radiation.

These new essential features, together with the known ones, are necessary and sufficient to achieve a technical result in all cases to which the requested amount of legal protection applies.

The technical result consists in uniform seed irradiation, achieved due to the fact that the dispenser evenly feeds the seeds to the first belt conveyor, while the second belt conveyor can operate in reverse mode, and its speed and adjustable clearance between the belt conveyors ΔS can also be adjusted. The seeds pass between two conveyor belts and due to their different speeds the seeds will rotate in a horizontal plane, therefore, uniform irradiation of the seeds and their uniform distribution along the length of the first conveyor belt is achieved. For uniform seed delivery, for example, to eliminate clumping of seed shells, a dispenser is used. To turn on the device only when there is seed in the feed hopper, a seed detector is used. To drive the two conveyors, a signal from a time relay is used. The control and management unit for its communications sets the operation mode of the device.

Figure 1 schematically shows a device for presowing treatment of large seeds.

A device for pre-sowing treatment of large seeds, containing the first belt conveyor 1, which is connected to the electric drive 2, an ultraviolet radiation source 3, enclosed in a casing 4 and mounted above the belt of the second conveyor 5, a feed hopper 6 and a seed receiving hopper 7, a seed dose detection sensor 8, which is located, for example, above the belt of the first belt conveyor 1, under the ultraviolet radiation source 3 and through the control and control unit 9 is electrically connected to the electric drive 2 of the first belt about the conveyor 1, above the first belt conveyor 1, a belt of the second belt conveyor 5 is installed with the possibility of its interaction with the irradiated seeds and with the possibility of adjusting both its tension and changing the height of its installation made of ultraviolet transmitting material. At the bottom of the feed hopper 6, both a metering device 10 and a seed availability sensor 11 are installed. The metering device 10 is connected through the electric drive 12 to the output of the time relay 13. The other two outputs of the time relay 13 signal the electric drives 2, 14 of the first 1 and second 5 belt conveyors respectively. The output of the sensor for the presence of seeds 11 is connected to the input of the control and management unit 9, and its other two inputs are connected to the outputs of the sensors for determining the dose of seeds 8 and with the output of the operating mode adjuster 15, while a signal from the output of the time relay 13 is supplied to the inputs of the ballast equipment 16 and the output of the control and control unit 9, and the output of the ballasts 16 is connected to a source of ultraviolet radiation 3. The second belt conveyor 5 is made, for example, in the form of a triangle, at the corners of which are located the lead 17, the followers e 18 shafts and a stretch 19, made, for example, from a spring. The first belt conveyor 1 is driven by an electric drive 2 through the leading 20 and driven 21 shafts. Processed large seeds may be cotton, corn, beans, etc.

The proposed device for pre-treatment of large seeds works as follows.

When filling the seeds into the feed hopper 6, the seed availability sensor 11 sends a command to the control and control unit 9, which generates a command to turn on the ballast 16 and the time relay 13. According to the commands of the control and control block 9 and the time relay 13, the ballast 16 controls the power not shown) to the ultraviolet radiation source 3. Using the time relay 13, the time for the delay in turning on the metering drive 12 and the second 14 drive and the first 2 belt conveyors 1 and 5. The delay time depends on the type and power of the ultraviolet radiation source 3. After the exposure time of the ultraviolet radiation source 3, a command is issued to turn on the electric drives 14 and 2 of the conveyor belts 1 and 5, respectively, and the electric drive of the dispenser 12. The electric drive of the dispenser 12 through a belt drive (on 1 is not shown) drives the dispenser 10, which starts the seed supply to the first belt conveyor 1. The belt conveyors 1 and 5 are driven. Seeds are captured on both sides (top and bottom) by conveyor belts 1 and 5 and begin to move at a speed at which the required dose of radiation is provided using an ultraviolet radiation source 3. Seeds come from feed hopper 6, move into the inter-conveyor space and then enter the hopper seed acceptance 7. Due to the adjustable speed of the conveyor belts 1 and 5, the seeds between them rotate and evenly irradiated, receiving the necessary dose of radiation. The exposure time, in turn, is determined by the speed of the conveyor belts 1 and 5 and the size of the seeds.

Using the mode dial 15, depending on the type (size) of seeds, treatment modes are set, i.e. the seed feed rate is controlled by the metering device 10 and the conveyor belt speeds 1 and 5. If the second belt conveyor 5 is stretched under the influence of an ultraviolet radiation source 3, mechanical stress, or for some reason, the seed treatment will be violated. Due to the stretching 19, the second belt conveyor 5 will constantly be in working condition. When the feed hopper 6 is released from seeds, the signal from the seed availability sensor 11 is fed to the control and control unit 9, which in turn sends a command to the time relay 13, which turns off the power to the metering unit 12. This will turn off the metering unit 10. Electric drives 2 and 14 the first and second belt conveyors 1, 5 will work with a time delay set by the time relay 13 and which is sufficient to release the belt conveyors 1 and 5 from the treated seeds. After the exposure time, the time relay 13 disconnects the power from the electric drives 2 and 14 of the first and second belt conveyors 1 and 5 and ballasts 16, which feeds the source of ultraviolet radiation 3. Depending on the processing conditions of the seeds, the ultraviolet radiation source 3 can be equipped with various lamps ( e.g. DRT, LE, DB). The proposed device is equipped with a power source that allows you to work from the AC network and from a DC source in the field. The operation of the device for presowing treatment of large seeds with optical radiation ends.

Claims (1)

A device for pre-sowing treatment of large seeds, containing a conveyor belt, the shaft of which is connected to the electric drive, an ultraviolet radiation source enclosed in a casing and mounted above the conveyor belt, seed feeding and receiving hoppers, a seed dose detection sensor located above the conveyor belt under the ultraviolet source radiation, and the electric conveyor belt, characterized in that above the first belt conveyor is installed a belt of the second belt conveyor with the possibility of its interaction with the irradiated seeds and with the possibility of regulating the height of its location and tension, made of a material that transmits ultraviolet light, and a dispenser is installed in the lower part of the feed hopper, which is connected through an electric drive to the output of a time relay, the other two outputs of which send a signal to the electric drives the first and second belt conveyors, and a seed availability sensor connected to the input of the monitoring and control unit, the other inputs of which are connected to the outputs of the radiation dose determination sensors seeds and with the output of the operating mode setter, while the output of the control and control unit is connected to the input of the time relay, and the inputs from the output of the time relay and the output of the control and control unit are supplied to the inputs of the control gear, while the output of the control gear is connected to an ultraviolet radiation source .

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