RU224473U1 - PNEUMATIC SEEDING UNIT - Google Patents

Abstract

The utility model relates to agricultural engineering, in particular to machines for sowing seeds of agricultural crops. The objective of this useful model is to improve the quality of seed dosing by a pneumatic sowing apparatus by reducing the number of “zero” and group seed feeds, simplifying the operation of the pneumatic sowing apparatus, as well as unifying the shaped gaskets used in its design. This task is achieved due to the fact that in a pneumatic sowing apparatus, including a housing, a seed chamber, a vacuum chamber with elastic elements placed in it, a drive shaft, an agitator, a sowing disk with suction holes and additional holes, the diameter of which is less than or equal to the diameter of the suction holes , as well as a gasket with a shaped cutout, the outer edge of which is concentric to the axis of rotation of the sowing disk, the diameters of the suction holes of the sowing disk are 1.4... 1.8 times smaller than the diameters of the suction holes traditionally used when sowing seeds of the corresponding row crops. The radial size of the shaped cutout of the gasket in the area adjacent to the seed chamber is equal to twice the sum of the diameters of the suction and additional holes of the sowing disk, designed for sowing the largest seeds planned for dispensing with a pneumatic sowing device, and in the seed transportation zone the radial size of the shaped cutout in the gasket is equal to double the diameter of the suction holes of such a seeding disc. In this case, the radius of the circle where the centers of the suction holes are located is greater than the radius of the inner edge of the figured cutout of the gasket in the seed transportation zone by an amount equal to the diameter of the suction holes, and the radius of the circle where the centers of the additional holes are located is less than the radius of the location of the same face of the figured cutout of the gasket by an amount greater than the diameter, but less one and a half diameters of additional holes.

Description

The utility model relates to agricultural engineering, in particular to machines for sowing seeds of agricultural crops.

A known pneumatic sowing apparatus includes a housing, a drive shaft, an agitator, a sowing disk with suction and additional holes, a seed chamber, an ejector of “extra” seeds, a gasket with a figured cutout and a lid containing a vacuum chamber with an extension from the beginning of the vacuum chamber to a line passing through the beginning of the ejector of excess seeds. In this case, the diameter of the circle of the centers of the additional holes is less than the diameter of the centers of the suction holes by an amount not exceeding the length of the seeds being sown, and the additional holes are shifted in phase relative to the suction holes [Utility model patent RU 113629 Pneumatic sowing apparatus. Published: 02/27/2012. Bull. No. 6 - analogue].

The disadvantage of this useful model is that the presence of additional holes in the seeding disk with a reduced volume of the vacuum chamber contributes to the occurrence of vacuum differences in the suction holes, which in turn provokes the appearance of gaps. In addition to the disadvantages of such a sowing apparatus, one can include the presence of a “extra” seed ejector, which is adjusted visually and at angular speed modes of the sowing disk that do not correspond to the operating ones, which subsequently affects the performance of the “extra” seed ejector, and, consequently, the entire pneumatic sowing machine. the apparatus is poorly predictable and unstable.

The closest technical solution to the proposed utility model is a pneumatic sowing device, including a housing, a seed and vacuum chamber, a drive shaft, a turner, an ejector of “excess” seeds, a gasket with a figured cutout and a sowing disk with suction and additional holes. In this case, the diameter of the centers of the additional holes is less than the diameter of the centers of the suction holes by an amount, the value of which is in the range from one to three lengths of the sown seeds. At the same time, the outer edge of the shaped cutout of the gasket is concentric to the axis of rotation of the sowing disk, and the radius of its location is greater than the radius of the circle of the centers of the suction holes by the diameter of the suction holes. In the area adjacent to the seed chamber, the radial size of the shaped cutout is greater than the difference between the radius of the circle where the centers of the suction holes are located and the radius of the circle where the centers of the additional holes are located by an amount equal to the sum of the diameters of the suction and additional holes, and from the zone where the ejector of “extra” seeds begins to operate and up to the point where the seeds are discharged into the furrow, the radial size of the shaped cutout in the gasket is equal to the double diameter of the suction holes; in addition, elastic elements are installed in the vacuum chamber, and chamfers are made on the edges of the shaped slot of the gasket, on the side facing the vacuum chamber [Patent for useful model RU 188276 Pneumatic sowing device. Published: 04/04/2019. Bull. No. 10 - prototype].

The disadvantages of this pneumatic sowing device include the presence of an ejector for “extra” seeds, which reduces the stability of dosing of seed, as well as the need for paired “sowing disk-spacer” sets for sowing each fraction of seeds of the corresponding crop.

The objective of this useful model is to improve the quality of seed dosing by a pneumatic sowing apparatus by reducing the number of “zero” and group seed feeds, simplifying the operation of the pneumatic sowing apparatus, as well as unifying the shaped gaskets used in its design.

This task is achieved due to the fact that in a pneumatic sowing apparatus, including a housing, a seed chamber, a vacuum chamber with elastic elements placed in it, a drive shaft, an agitator, a sowing disk with suction holes and additional holes, the diameter of which is less than or equal to the diameter of the suction holes , as well as a gasket with a shaped cutout, the outer edge of which is concentric to the axis of rotation of the sowing disk, the diameters of the suction holes of the sowing disk are 1.4...1.8 times smaller than the diameters of the suction holes traditionally used when sowing seeds of the corresponding row crops. The radial size of the shaped cutout of the gasket in the area adjacent to the seed chamber is equal to twice the sum of the diameters of the suction and additional holes of the sowing disk, designed for sowing the largest seeds planned for dispensing with a pneumatic sowing device, and in the seed transportation zone the radial size of the shaped cutout in the gasket is equal to double the diameter of the suction holes of such a seeding disc. In this case, the radius of the circle where the centers of the suction holes are located is greater than the radius of the inner edge of the figured cutout of the gasket in the seed transportation zone by an amount equal to the diameter of the suction holes, and the radius of the circle where the centers of the additional holes are located is less than the radius of the location of the same face of the figured cutout of the gasket by an amount greater than the diameter, but less one and a half diameters of additional holes.

The proposed utility model is illustrated with illustrations. In fig. 1 shows a diagram of a pneumatic sowing apparatus; Fig. 2 - section A-A in Fig. 1, in fig. Figure 3 shows a diagram of the relative position of the sowing disk and spacer; Fig. 4 - diagram of the relative position of the gasket and elastic elements of the vacuum chamber.

The pneumatic sowing apparatus (Fig. 1 and 2) includes a housing 1, a seed chamber 2 and a vacuum chamber 3, between which a agitator 5 and a seeding disk 6 with suction holes 7 and additional holes 8 are fixed on the drive shaft 4 (Fig. 3), diameter d _d which is less than or equal to the diameter d _p of the suction holes 7, and additional holes 8 can be located relative to the suction holes 7 both radially and with an angular displacement. The diameter d _p of the suction holes 7 of the sowing disk 6 is 1.4...1.8 times smaller than the diameter of the suction holes traditionally used when sowing seeds of the corresponding row crops. Between the sowing disk 6 (Fig. 2 and 3) and the vacuum chamber 3 there is a gasket 9 with a shaped cutout, which is made in such a way that its outer edge is concentric with the axis of rotation of the sowing disk 6 (Fig. 4). In this case, the radial size t ₁ of the shaped cutout of the gasket 9 in the area adjacent to the seed chamber 2 is equal to twice the sum of the diameters of the suction 7 and additional holes 8 of the sowing disk 6 (Fig. 3), intended for sowing the largest seeds planned for dosing with pneumatic sowing apparatus (h=2d _{p max} +2d _{d max} ). In the seed transportation zone (behind the zone of the seed chamber 2 in the direction of rotation of the sowing disk, up to the place where the seeds are discharged into the furrow), the radial size h of the shaped cutout in the gasket 9 is equal to the double diameter of the suction holes 7 of such sowing disk 6 (t ₂ =2d _{p max} ) (Fig. 1, 3 and 4). The geometric parameters of the sowing disk 6 and spacer 9 are selected in such a way that the radius R _p of the circle of the location of the centers of the suction holes 7 is greater than the radius R _in the inner edge of the figured cutout of the spacer 9 behind the area of the seed chamber 2 to the place where the seeds are discharged into the furrow by an amount equal to the diameter d _p suction holes 7, and the radius R _d of the circumference of the location of the centers of the additional holes 8 is less than the radius of the location of the same face of the figured cutout of the gasket 9 by an amount greater than the diameter, but less than one and a half diameters of the additional holes b/d (Fig. 3). Additionally, elastic elements 10 are installed in the vacuum chamber 3 (Figs. 2 and 4), resting with their free end against the gasket 9, and chamfers are made on the edges of the shaped slot of the gasket 9, on the side facing the vacuum chamber 3. In this case, the design of the elastic elements 10 provides minimal local resistance to the movement of air flows.

The pneumatic seeding device works as follows.

Seeds from the hopper enter the seed chamber 2, where, under the influence of vacuum created in the vacuum chamber 3, they are captured by the suction holes 7 and additional holes 8 of the sowing disk 6. At the same time, the seed is reduced by 1.4...1.8 times compared to the traditional one. the diameter d _p of the suction holes 7 makes it possible to reduce the likelihood of the formation of group supply of seeds to a level that allows excluding the ejector of “extra” seeds from the design of the pneumatic sowing apparatus. At the same time, due to the effect of pneumatic tedding created by the paired action of the suction holes 7 and additional holes 8 on the seed material, the capture and removal of single seeds by the suction holes 7 is facilitated, and the probability of gap formation is reduced to an agrotechnically acceptable level. Additional activation of the process of capturing seeds is facilitated by the influence of the agitator 5 on them. When the sowing disk 6 rotates, due to the specified shape of the figured cutout in the spacer 9, the seeds removed from the seed chamber 2 by additional holes 8 fall back because they come out of the expansion zone of the cutout in the spacer 9, communicating with the vacuum chamber 3. In this case, the relationship between the radial dimensions t ₁ and t ₂ of the cutout in the gasket 9 with the parameters of the sowing disk 6, designed for sowing the largest seeds (t ₁ = 2d _{p max} +2 _{d max} and t ₂ = 2d _{p max} ), allows you to use one gasket 9 complete with various sowing discs 6 and, at the same time, ensure guaranteed communication with the vacuum chamber of the suction holes 7 and, in the area adjacent to the seed chamber 2, additional holes 8 of the sowing disc 6 when dosing seeds more small crops. At the same time, the specified ratio of the parameters of the cutout in the gasket 9 and the parameters of the location of the suction holes 7 and additional holes 8 make it possible, on the one hand, to ensure the rigidity of the gasket and the maximum proximity of a number of additional holes 8 to a row of suction holes 7, which increases the efficiency of seed capture, on the other - prevents air from being sucked through additional holes 8 in the area behind the seed chamber and reduces the likelihood of retaining “extra” seeds. It should be noted that the design feature of the proposed pneumatic sowing apparatus is the absence of an ejector for “extra” seeds, and this, in turn, allows, when choosing the parameters of the sowing disk, to focus not on the radius of the circle of location of the suction holes 7, but on the parameters of the cutout in the gasket 9, which and made it possible to constantly use it when replacing the sowing disk 6. Moreover, the absence of an ejector for “extra” seeds will simplify the operation of the seeder as a whole, by eliminating the procedure for adjusting its position in sections, and increase the stability of the operation of the pneumatic sowing apparatus. With further rotation of the sowing disk 6, the seeds remaining at the suction holes 7 are transported to the discharge zone, where the vacuum is cut off and they, under the influence of gravity, fall into the furrow prepared by the opener.

When the pneumatic sowing device is operating, the action of the elastic elements 10 ensures that the gasket 9 is tightly pressed to the sowing disk 6 in the area of capturing and transporting seeds, thereby preventing unproductive “losses” of vacuum. The significant volume of the vacuum chamber 3 helps to equalize fluctuations in the vacuum value both in the vacuum chamber 3 itself and in the plane of the suction holes 7 and additional holes 8 of the seeding disk 6. At the same time, the presence of chamfers on the edges of the cutout of the gasket 9 reduces local resistance in the corresponding areas, making it easier movement of air currents. Taken together, the proposed improvements make it possible to increase the efficiency of the pneumatic system and reduce the load on the vacuum source.

Claims (1)

A pneumatic sowing device, including a housing, a seed chamber, a vacuum chamber with elastic elements placed in it, a drive shaft, an agitator, a sowing disk with suction holes and additional holes, the diameter of which is less than or equal to the diameter of the suction holes, as well as a gasket with a figured cutout, the outer edge of which is concentric to the axis of rotation of the sowing disk, characterized in that the diameter of the suction holes of the sowing disk is 1.6 times smaller than the diameter of the suction holes traditionally used when sowing seeds of the corresponding row crops, the radial size of the shaped cutout of the gasket in the area adjacent to the seed chamber, is equal to twice the sum of the diameters of the suction and additional holes of the sowing disk, intended for sowing the largest seeds planned for dispensing with a pneumatic sowing device, and in the seed transportation zone, the radial size of the figured cutout in the gasket is equal to the double diameter of the suction holes of such a sowing disk, while the radius of the circle of location the centers of the suction holes are greater than the radius of the inner edge of the shaped cutout of the gasket in the seed transportation zone by an amount equal to the diameter of the suction holes, and the radius of the circle of the centers of the additional holes is less than the radius of the location of the same face of the shaped cutout of the gasket by an amount equal to 1.25 times the diameter of the additional holes.