RU2620095C1 - Device for grain drying - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: device for grain drying comprises the casing covered with a layer of a heat-insulating material, the loading hopper, the unloading window, the conveying working body mounted within the casing, the heating elements, the fan and the air duct connected to the inner casing cavity. The casing is made rectangular in cross section. Plates are installed inside and along the casing, vertically and parallel to one another. The conveying working body is made in the form of shafts mounted on the plates with the possibility to rotate in one direction. The shafts are arranged in parallel to one another and at an equal distance therebetween in one plane from the loading hopper to the unloading window. Flow guides, the upper surface of which is inclined in the grain movement direction, are mounted between the shafts on their upper side on the plates. The gap between the shafts and the flow guides is made smaller than the minimum grain size. The air duct is installed on the upper side of the casing. The heating elements are installed in the air duct.

EFFECT: improving the quality of grain drying due to the quick and uniform heating of the grain.

2 dwg

Description

The invention relates to agricultural machinery, in particular to a device for drying grain.

A device for drying grain [Device for drying grain. - Patent RU No. 2323580. - Publ. 05/10/2008, Bull. No. 13], comprising a cylindrical casing, a loading hopper, an unloading window, a transporting working element coaxially mounted rotatably inside the casing, heating elements and a cooling device. The outer surface of the casing is covered with a layer of heat-insulating material. The transporting working body is made in the form of a screw with perforated turns, the diameter of the perforation does not exceed the minimum grain size. The casing is made integral, and its components are divided among themselves by rings made of heat-insulating material. Heating elements are placed on the outer surface of the casing under a layer of heat-insulating material between the loading hopper and the discharge window with the possibility of individually controlling the heating temperature of each of the sections of the casing. Each component of the casing is equipped with an individual heating element, and the end surface of the casing from the side of the loading hopper is perforated. The cooling device consists of a fan and an air duct connected to the internal cavity of the casing behind the discharge window.

The known device has the disadvantage of low quality grain drying.

Achievable technical result - improving the quality of drying of grain.

The technical result is achieved by the fact that the casing is of rectangular cross-section. Inside and along the casing, plates are mounted vertically and parallel to each other. The transporting working body is made in the form of shafts that are mounted on the plates with the possibility of rotation in one direction. The shafts are installed parallel to each other and at an equal distance between each other in the same plane from the loading hopper to the discharge window. Between the shafts, flow guides are installed on the plates on their upper side, the upper surface of which is tilted in the direction of grain movement. The gap between the shafts and the flow guides is smaller than the minimum grain size. The duct is installed on the upper side of the casing. Heating elements are installed in the duct.

In FIG. 1 shows a general view of the device, FIG. 2 is a section along AA in FIG. one.

The device for drying grain consists of a casing 1, covered with a layer of heat-insulating material 2, a loading hopper 3, an unloading window 4, installed inside the casing 1 of the transporting working member 5, heating elements 6, a fan 7 and an air duct 8 connected to the inner cavity of the casing 1. Casing 1 is made of rectangular cross section. Plates 9 are installed vertically and parallel to each other inside and along the casing 1. The transporting working member 5 is made in the form of shafts mounted on the plates 9 with the possibility of rotation in one direction. The shafts are mounted parallel to each other and at an equal distance from each other in the same plane from the loading hopper 3 to the discharge window 4. Between the shafts on their upper side, flow guides 10 are installed on the plates 9, the upper surface of which is inclined in the direction of grain movement. The gap between the shafts and the flow guides 10 is made smaller than the minimum grain size. Air duct 8 is installed on the upper side of the casing 1. Heating elements 6 are installed in the duct 8.

The device operates as follows. Turn on the heating elements 6 and the drive (not shown in Fig.) Transporting the working body 5. After reaching the required temperature of the air pumped by the fan 7 through the duct 8 into the inner cavity of the casing 1, the grain is fed into the feed hopper 3, where it comes to rotating in one the direction of the shafts that are mounted on the plates 9 parallel to each other and at an equal distance from each other in the same plane from the loading hopper 3 to the unloading window 4. Due to the friction forces, the rotating shafts of the transporting worker about the body 5 grab the grain and move it to the flow guides 10, which are mounted on the plates 9 between the shafts from their upper side, the upper surface of the flow guides 10 inclined in the direction of grain movement, and the gap between the shafts and the flow guides is made smaller than the minimum size grain. Due to this, the grain does not fall down between the shafts, but moves along the upper inclined surface to the next rotating shaft of the transporting working body 5.

When the grain moves by the rotating shafts of the transporting working body 5 to the discharge window 4, the heated air heats both the shafts 8, the flow guides 10, and the grain, which, in contact with the heated shafts of the transporting working body 5, the flow guides 10, and also blown by the heated air flow, Heats up and loses excess moisture. In addition, when the grain is on the rotating shafts of the transporting working body 5, it constantly turns around its axis, ensuring the uniformity of its heating. Excess moisture in the form of steam is removed from the device partially through the discharge window 4, and partially through the loading hopper 3. Dry grain is removed from the device through the discharge window 4.

The execution of the casing of rectangular cross-section, the installation of plates inside and along the casing vertically and parallel to each other, the implementation of the conveying working body in the form of shafts mounted on the plates with the possibility of rotation in one direction, the installation of shafts parallel to each other and at an equal distance from each other in the same plane from loading hopper to the discharge window, placement between the shafts on their upper side on the plates of the flow guides, the upper surface of which is inclined in the direction of movement of the grain, and beyond the gap between the shafts and the flow guides is made smaller than the minimum grain size, installing an air duct on the upper side of the casing, placing heating elements in the air duct - all this ensures quick and uniform heating of grain, increasing the quality of its drying.

Claims (1)

A device for drying grain containing a casing covered with a layer of heat-insulating material, a loading hopper, an unloading window, a transporting working element installed inside the casing, heating elements, a fan and an air duct connected to the internal cavity of the casing, characterized in that the casing is made of rectangular cross-section, inside and plates are installed vertically and parallel to each other along the casing, the transporting working body is made in the form of shafts mounted on the plates with the possibility of rotation in one direction the phenomenon, moreover, the shafts are mounted parallel to each other and at an equal distance from each other in the same plane from the loading hopper to the discharge window, flow guides are installed on the plates between the shafts on their upper side, the upper surface of which is inclined in the direction of grain movement, and the gap between the shafts and the flow guides are made smaller than the minimum grain size, the duct is installed on the upper side of the casing, and the heating elements are installed in the duct.

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