RU2663595C1 - Chamber grain drier - Google Patents

Abstract

FIELD: agriculture; machine building.SUBSTANCE: chamber grain drier consists of a grain bin, distribution boxes, drying chambers with parallel vertical air-permeable and blind end walls, drying agent chamber located between the drying chambers, in the end walls of which there are supplying injection windows, and under the drying chambers there are receiving boxes with unloading dosing devices. On the vertical air-permeable walls of the drying chambers, from their inner sides, horizontal and vertical rows with spacings between them two-sided trays are installed, deviated from the horizontal downward by an angle of 42 to 48 degrees and directed toward the opposite walls. Angle between the sides of the trays is 45–48 degrees. At the same time, at least one wall of each drying chamber is configured with a planar parallel horizontal displacement.EFFECT: invention provides improvement in the technological characteristics of drying process of materials with distinct physical and mechanical properties and particle shapes, as well as improvement of drying quality.1 cl, 5 dwg

Description

The proposed chamber dryer relates to devices for drying bulk materials, for example, seeds of cereals, legumes, Pancake week, industrial, decorative and other crops, as well as some industrial materials or their compositions.

Known devices and technical solutions that serve the same purposes. These, for example, include: “Column of a shaft grain dryer” according to patent No. 306644, class. F26B 17/12 of 06/11/1971. Bull. No. 19; “Ventilated hopper for grain materials” according to A.S. SU No. 1193403, class F26B 9/06 of 11/23/1985. Bull. No. 43; “Grain dryer and grain dryer inverter” according to patent RU No. 2143090 C1, class 6 F26B 17/12 from 12.20.1999; "Grain dryer" according to patent RU No. 2458301 C1, class 6 F26B 17/12 of 08/10/2012. Bull. Number 22.

Said devices have disadvantages. So, in the "Column" according to patent No. 306644, where vertical perforated breathable partitions with rotary shutters are installed, the relative speeds of the vertical movement of grain in layers located on opposite sides of the partitions are provided. In this case, the process of heat and moisture exchange may be disrupted, that is, the heat carrier passing through the first layers of grain will be cooled and saturated with moisture, and in the following layers, for example, at the column inlet, where the grain temperature is lower than the temperature of the heat carrier, moisture will condense on the surface of grains having lower temperature.

The disadvantages of the analogue according to AC No. 1193403 “Ventilated hopper for grain materials” are a large number of structural elements and assemblies.

So, for example, for loading grain into each drying element and its unloading, separate loading and unloading devices are provided. Gas-tight plates, with which drying elements are connected together, complicate the design, reduce the temperature of the drying agent and the efficiency of the process. In addition, the intensity of the inversion of grain flows in the drying elements of this hopper depends on the diameter and number of steps of the helical surface and is a constant value. This narrows the range of use of the “Ventilated Hopper for Grain Materials” when drying materials of different physical and mechanical properties.

When using the device according to the patent No. 2143090, in the case of drying seeds with high fluidity, the manifestation of a destabilization of sedimentation rates to unacceptable limits is inevitable until the grain layers adjacent to the walls of the drying chambers stop completely. This is also facilitated by the fact that the height of the column and the pressure of the material to be dried, which is in the gap S, are much higher than at the walls of the drying chamber, especially in the area located below the inverter. A further disadvantage of said inverter is that free spaces form under inclined guides and gable covers. Through these spaces, the coolant can go outside the drying chambers. To prevent this phenomenon, the walls of the drying chambers in the zone of the inverters are made deaf, which complicates the design, increases the material consumption and dimensions of the device.

The analogue according to patent RU No. 2458301 C1 “Zernosushilka”, according to the applicant, is the closest to the claimed “Zernosushilka chamber” and can be taken as a prototype. The disadvantages of this dryer are the complexity of manufacturing, installation and maintenance of inverter elements made in the form of segments of screw surfaces, as well as the inability to control the distance between the inner and outer walls of the drying chambers. This disadvantage is inherent in other analogues and devices.

The purpose of the claimed device is to simplify the design, expand the possible range of applications for drying materials with distinctive physical and mechanical properties and particle shapes, as well as improve the quality of drying and the efficiency of the proposed "chamber dryer".

This goal is achieved by the fact that on the vertical breathable walls of the drying chambers, on their inner sides in horizontal and vertical rows, with gaps between them, two-sided trays are installed, which are deviated from the horizons by an angle γ ranging from 42 to 48 degrees down and directed to the side opposite walls, and the angle between the faces of the trays is 45-48 degrees.

Another distinctive feature of the proposed grain dryer is that at least one wall of each drying chamber, preferably the outer one, is made with the possibility of plane-parallel horizontal movement. This achieves a change in the width of the drying chambers and the dried material passing through the drying chambers, for example, when replacing the seeds of various crops such as wheat, rapeseed, barley, peas, millet, corn, mustard, etc.

For the same purpose, in the proposed grain dryer, the gas distribution chamber of the drying agent (coolant) is divided into two parts that are approximately equal in volume using a blank vertical partition, and a removable, longitudinal, vertical partition is located in the loading hopper. This allows you to apply in different drying chambers of the coolant (drying agent) and the dried material with various parameters, for example, pressure, temperature, humidity or flow. This solution makes it possible to simultaneously dry the seeds of two different crops, or, for example, drying and cooling, sequentially directing the seeds from one drying chamber to another.

The device is shown in the attached drawings.

- расстояние между верхними ребрами двух соседних лотков в одном горизонтальном ряду, ƒ - просвет, или перекрытие, пространства между верхними ребрами лотков, расположенных на противоположных стенках сушильных камер, S - межлотковое пространство, K - ширина сушильной камеры. На фиг. 3 показано расположение и форма мест соединения лотков со стенкой сушильной камеры, где m - расстояние между нижними ребрами соседних лотков в одном горизонтальном ряду, n - расстояние между нижними ребрами лотков по вертикали, приведен вариант, когда m=2n. Пунктирными линиями обозначены места соединения лотков с противоположной стенкой сушильной камеры. На фиг. 4 показан вариант размещения лотков со смещением каждого нижнего ряда относительно верхнего на величину расстояния между лотками по горизонтали. При этом

и h могут быть равными или, что предпочтительнее,

на 2-3%. На фиг. 5 представлены чертеж развертки лотка - многоугольник CDOEF (обозначен сплошными линиями), и проекция лотка на плоскость, проходящую через его боковые ребра - многоугольник C¹D¹OE¹F¹ (обозначен пунктирными линиями). Размеры сторон и углов развертки и лотка подбираются в соответствии с размерами сушильных камер, которые определяются исходя из заданной или расчетной производительности по массе высушиваемого материала в единицу времени и по величине снижения его влажности за один цикл сушки. Длина развертки лотка, как и самого лотка, определяется исходя из ширины сушильной камеры K в ее среднем значении, а именно: при S=0, L=0,75K. Размеры сторон OD, ОЕ, OG и величины N и β образуются в процессе изготовления лотка. Ширина развертки лотка Н° должна быть в два-три раза меньше ее длины L. Схема размещения лотков в сушильных камерах и их количество определяются исходя из заданной, плановой производительности, режимов сушки, свойств высушиваемого материала, параметров агента сушки и ряда других показателей.In FIG. 1 schematically shows a transverse vertical section of a chamber dryer. In FIG. 2 shows a section of the drying chamber, a top view showing the main technological parameters, where h is the width of the tray, that is, the distance between the upper ribs of one tray,

- the distance between the upper ribs of two adjacent trays in the same horizontal row, ƒ - the gap or overlap, the space between the upper ribs of the trays located on opposite walls of the drying chambers, S - the inter-tray space, K - the width of the drying chamber. In FIG. Figure 3 shows the location and shape of the junctions of the trays with the wall of the drying chamber, where m is the distance between the lower ribs of adjacent trays in the same horizontal row, n is the vertical distance between the lower ribs of the trays, and an option is given when m = 2n. Dotted lines indicate the junction of the trays with the opposite wall of the drying chamber. In FIG. Figure 4 shows the placement of trays with the offset of each lower row relative to the top by the horizontal distance between the trays. Wherein

and h may be equal to or, more preferably,

2-3%. In FIG. Figure 5 shows a drawing of the development of the tray — the CDOEF polygon (indicated by solid lines), and the projection of the tray onto a plane passing through its side edges — the polygon C ¹ D ¹ OE ¹ F ¹ (indicated by dashed lines). The dimensions of the sides and the angles of the sweep and the tray are selected in accordance with the dimensions of the drying chambers, which are determined based on the set or calculated productivity by the mass of the dried material per unit time and by the value of its moisture reduction per drying cycle. The scan length of the tray, as well as the tray itself, is determined based on the width of the drying chamber K in its average value, namely: at S = 0, L = 0.75K. The dimensions of the sides OD, OE, OG and the values of N and β are formed during the manufacture of the tray. The width of the sweep of the tray Н ° should be two to three times less than its length L. The layout of the trays in the drying chambers and their number are determined based on the set, planned productivity, drying modes, properties of the dried material, parameters of the drying agent and a number of other indicators.

The main elements of the proposed grain dryer are: loading hopper 1 with two chambers A and B, separated by a removable partition 2, grain feed boxes 3 and two drying chambers 4 with air-conducting internal and external walls and blind end walls (Fig. 1). Between the drying chambers 4 there is a chamber of the drying agent 5, divided by a blank partition 6 into two parts of approximately equal volume. In the end walls of each of the parts of the chamber of the drying agent, supply windows 7 are made through which the drying agent, for example, heated air, is supplied. The outer walls of the drying chambers are connected to the dryer body through screw mechanisms 8, with the help of which plane-parallel movement of the walls is carried out. Under each drying chamber, discharge-metering shutters 9 are installed, through which the material to be dried enters the receiving troughs 10 and 12, then it can be sent to the accumulator 11 or for other purposes. On the walls of the drying chambers, from their inner sides, dihedral trays 13 and 14 are installed obliquely downward at an angle γ, identical to each other both on the outer sides and on the inside.

The operation of the grain dryer is as follows. Grain or other bulk material from compartments A and B of the loading hopper 1 is fed through the boxes 3 to the drying chambers 4 and, when filled, the drying agent is fed into the chambers 5. Then, the drying agent penetrates through the air-permeable walls of the drying chambers 4, passes through through the grain layer, while there is a process of moisture-heat exchange between the grain and the drying agent. When opening the discharge-metering shutters 9, the material to be dried falls down and, meeting with the two-sided trays 13 and 14, is inverted mutually from the inner walls to the outer ones, and vice versa. In this case, the temperature and humidity values of the drying agent and the material to be dried are equalized. The process of heat-moisture exchange occurs smoothly in all areas of the movement of the dried material from the grain feed boxes to the discharge-metering closures, this positively affects the efficiency of the drying process and the quality of the dried material, which is especially important when drying seed grain.

Given that the seeds of various crops have different properties, for example, shape, size, fluidity or angle of repose, and others, the proposed grain dryer provides for the possibility of changing the width of the drying chambers. To do this, the outer walls of the drying chambers are connected to the dryer body, for example, through screw mechanisms 8, which allows you to change the distance between their inner and outer walls. This makes it possible to rapidly switch from drying, for example, wheat, barley to drying rapeseed, millet, mustard or the like.

In addition, in the proposed dryer, the loading hopper is divided into two compartments A and B using a removable partition 2, and the coolant chamber is also divided into two blank walls 6. This solution makes it possible to dry various seeds or to dry and cool them, directing the flow of seeds coming from the discharge-metering valves 9 to the gutters 10 and 12, and then to the accumulator 11 - stream A ₁ from the hopper A and stream B ₁ from the hopper B and further from the drive, for example, to the storage. If necessary, if multiple drying and cooling are required, then for this purpose it is necessary to direct the flow from hopper B through one drying chamber, and from the chute 12 to direct flow B ₂ to hopper A and then through the drying chamber, in which cooling should be carried out by blowing the stream seed with chilled air or another agent, feed it into the gutter 10, and then send it as directed.

The proposed "Chamber grain dryer", in the opinion of the applicant and the authors, will provide a positive effect, has novelty elements and can be industrially applicable, that is, it satisfies all the requirements of the invention.

Claims (2)

1. Chamber grain dryer, including a grain hopper, distribution boxes, drying chambers with parallel vertical breathable and blank end walls, a drying agent chamber located between the drying chambers, in the end walls of which there are supply discharge windows, and receiving chambers with discharge chambers are installed under the drying chambers metering devices, characterized in that on the vertical breathable walls of the drying chambers from their inner sides are horizontal and vertical diagonal trays are installed in rows, with gaps between them, inclined from the horizontal downward at an angle of 42 to 48 degrees and directed towards opposite walls, and the angle between the faces of the trays is 45-48 degrees, with at least one wall of each drying chamber made with the possibility of plane-parallel horizontal movement. 2. A chamber grain dryer according to claim 1, characterized in that the drying agent chamber is divided into two parts approximately equal in volume using a blank vertical partition, and a removable vertical vertical partition is located in the loading hopper.

Images