RU54579U1 - PNEUMOTRIC INSTALLATION FOR TRANSPORTATION OF BULK CARGOES - Google Patents

Abstract

The proposed utility model relates to the field of material loading, namely, to continuous transporting machines and can be used in continuous production lines for the vertical lifting of bulk cargoes.

The technical task of the proposed utility model is to reduce the trauma of crops during vertical lifting by a screw conveyor, as well as to increase the productivity of a vertical screw conveyor.

The pneumatic screw installation for transporting bulk cargo consists of a loading hopper (2) rigidly fixed to the frame (1), to the bottom of which a screw (3) is attached. The screw (3) is arranged vertically. The screw shaft runs along the entire length of the installation and is mounted on the upper wall of the duct (6). The housing (4) is bolted to the bottom of the feed hopper (2). A drive system (7) is attached to the bed (1) and is connected to the screw shaft (3) by means of a belt drive. The opposite side of the housing (4) from the loading hopper (2) is equipped with a threaded part to which the threaded part of the pneumatic chamber (5) is attached, the tightness of the connection is ensured by a compression nut (8), with a seal (9). The pneumatic chamber (5) is equipped with a ramp plane (10), the angle of inclination of which coincides with the angle of inclination of the discharge pipe (11), into which the gateway unloader (12) is integrated with an offset axis to the upper wall of the pipeline (11). The part of the pneumatic chamber (5) opposite from the housing (4) is provided with a threaded connection to which the threaded part of the air duct (6) leading to the fan (13) connected via a shaft to the drive system (14) is connected. In the upper wall

of the duct (6), the screw shaft (3) is mounted with a bearing connection, and at the fan inlet (13), a damper (15) is fixed, which is fixed by a bolt connection.

The design of a pneumatic screw installation for transporting bulk materials allows to increase the productivity of the conveyor and reduce the trauma of the transported material.

Description

The proposed utility model relates to the field of material loading, namely, to continuous transporting machines and can be used in continuous production lines for the vertical lifting of bulk cargoes.

Known screw feeder for pressure pneumatic conveying installation (US Pat. RF No. 156 728 C1 IPC: B 65 G 53/48), comprising a housing with a loading chamber, a screw with a shaft located in the housing and connected to the drive, a mixing chamber connected with housing. In the loading chamber, a rotary tray designed to supply bulk material in the direction of rotation of the screw, a latch and a visor.

The disadvantage of this feeder is that this design does not prevent injury to the material when it is moved by a screw and has low productivity during vertical transportation.

The closest to the design of the proposed utility model is a pneumatic screw feeder comprising a housing with a loading neck, a drive screw, a mixing chamber connected to a compressed air supply source and a transport pipeline (see author certificate No. 779211, class B 65 G 53 / 48, publ. 15.11.80. Bull. 42)

However, the design of the feeder does not allow to prevent injury to the material when loading agricultural products, such as crops, and to increase productivity with vertical feed of the material.

The technical task of the proposed utility model is to reduce the trauma of crops during vertical lifting by a screw conveyor, as well as to increase the productivity of a vertical screw conveyor.

The objective is achieved in a pneumatic screw installation for transporting bulk cargo containing a housing with a loading hopper, a screw installed in the housing with a shaft connected to the drive, an air supply source and an unloading pipe, where according to the invention, the screw has a vertical arrangement, the shaft of which extends along the length of the entire installation and the housing is hermetically connected to a cylindrical pneumatic chamber, which is hermetically connected to an air duct connected to an air supply source having a damper regulating the air flow ha, and the pneumatic chamber is rotatably fixed around the axis of the screw and provided with a sloping plane, the inclination angle of which coincides with the angle of inclination of the discharge pipe, in addition, a sluice unloader is built into the discharge pipe, the wheel axis of which is offset from the center of the pipeline to its upper wall.

The difference from the prototype in the proposed design of a pneumatic screw installation for transporting bulk goods is that the material is transported in a vertical plane. The installation contains a pneumatic chamber in the form of a cylinder; air duct damper; fan with drive system; pipeline; gateway unloader. The screw housing and the pneumatic chamber are connected by means of a threaded part, with a compression nut and a seal for tightness, and the pneumatic chamber has the ability to rotate around the axis of the screw and change the direction of unloading due to the threaded connection to the duct. In a cylindrical pneumatic chamber there is a pitched plane with an angle of inclination coinciding with the angle of inclination of the pipeline. A sluice unloader is built into the pipeline, in which the axis of the impeller is offset from the center to the level of the upper wall of the pipeline. In this case, the screw shaft passes along

the entire length of the installation and is mounted in a bearing in the upper wall of the duct connecting the air chamber and the fan. This allows, unlike the prototype, to combine the processes of transportation by screw and air flow over the entire length of the installation.

Thus, the productivity of the conveyor is increased due to transportation by air flow and screw, which reduces the friction of the transported material on the body and screw; the damageability of the material is reduced, since the cargo particles do not catch between the screw and the casing.

Comparative analysis with the prototype allowed us to conclude that the claimed technical solution has novelty, since, unlike the prototype, the screw housing is equipped with a pneumatic chamber, hermetically coupled with them through threaded parts and a compression nut with a seal, and the pneumatic chamber has the ability to rotate around the axis of the screw, and the shaft the screw passes through the pneumatic chamber and is fixed in the bearing mounted on the upper wall of the pipeline from the side opposite to the screw. To deliver the cargo, the pneumatic chamber is equipped with a sloping plane coinciding with the angle of inclination of the pipeline, with a gateway unloader built into it, the axis of which is shifted to the level of the upper pipe wall.

The originality of the invention lies in the fact that the pneumatic chamber is connected hermetically by means of a threaded connection with the housing of the screw conveyor, while the pneumatic chamber has the ability to rotate around the axis of the screw. This achieves the combination of transportation processes with a screw and air flow and unloading in the right direction. Thanks to what productivity increases and injury by the screw decreases. Originality also consists in the fact that the cylindrical pneumatic chamber has an inclined plane inside with an angle equal to the angle of inclination of the pipeline, and the axis of the lock wheel is offset

from the center, to the upper wall of the pipeline; the screw shaft extends along the entire length of the installation and is fixed in the bearing on the wall of the duct connected by means of a thread with a pneumatic chamber from the side opposite to the screw.

The proposed design has greater productivity due to the combination of the lifting process by the screw and the air flow, and less damage due to the air flow eliminating jamming of the particles of the transported material between the screw and the housing during vertical lifting of the material.

Technical solutions are illustrated by technical drawings. In Fig. Depicts a General view of a pneumatic screw installation.

Pneumatic screw installation for transporting bulk cargo (Fig.) Consists of a loading hopper (2) rigidly fixed to the frame (1), to the bottom of which a screw (3) is attached with a bearing connection. The screw (3) is arranged vertically. The screw shaft passes along the entire length of the installation, namely, through the body (4), the pneumatic chamber (5) and is mounted on the upper wall of the duct (6). The housing (4) is bolted to the bottom of the feed hopper (2). A bolted connection to the bed (1) is attached to the drive system (7) connected to the screw shaft (3) by means of a belt drive. The opposite side of the housing (4) from the loading hopper (2) is equipped with a threaded part to which the threaded part of the pneumatic chamber (5) is attached, the tightness of the connection is ensured by a compression nut (8), with a seal (9). The pneumatic chamber (5) is equipped with a ramp plane (10), the angle of inclination of which coincides with the angle of inclination of the discharge pipe (11), into which the gateway unloader (12) is integrated with an offset axis to the upper wall of the pipeline (11). The part of the pneumatic chamber opposite from the housing (4) is provided with a threaded connection to which the threaded part of the air duct (6) leading to the fan (13) connected via a shaft to the drive system (14) is connected. In the upper wall of the duct

(6) the screw shaft (3) is fixed by a bearing connection, and at the fan inlet (13) a damper (15) is fixed, which is fixed by a bolt connection.

Pneumatic screw installation works as follows. Before starting work, the shutter (15) is fixed with fixing screws, which regulates the air flow depending on the type of cargo being transported. The drive system (7) by means of a belt drive drives the screw shaft (3) into rotation with a given angular velocity. At the same time, the second drive system (14) sets the rotation of the fan (13). The material under the influence of the air flow and the screw (3) begins to move along the body (4) from the loading hopper (2) into the pneumatic chamber (5), which can rotate around its axis due to the threaded connection with the body and the pipeline. Upon reaching the pneumatic chamber (5), the flow rate decreases and the material crumbles onto the ramp plane (10). Further along the ramp plane (10), the material moves to the discharge pipe (11) with a sluice unloader (12), which, thanks to the displacement of the axis to the upper wall of the pipe (11), rotates during the accumulation of the material to be lifted and unloads the installation in any direction (Fig.).

During the operation of the screw (3), without air flow, the material tends to crumble back into the gap between the screw (3) and the casing (4), because of this, the transported material is injured. Due to the lifting force of the air, the cargo does not crumble into the gap, but rises up.

The advantages of the proposed pneumatic rotary installation are as follows.

1. The design allows you to change the angular velocity of the auger and air flow, configure the installation for a specific load in accordance with its physical and mechanical properties.

2. The load rises to a predetermined height by combining the transportation processes with an air stream and a screw, i.e. the conveyor uses a new principle for moving cargo.

3. The pneumatic chamber has the ability, due to the threaded connection with the housing and the pipeline, to rotate around its axis, which allows, in conjunction with the ramp plane inside the pneumatic chamber, to unload in any direction.

All this allows you to achieve the following technological results.

1. The conveyor productivity is increased by adjusting the feeder to the load and combining the processes of conveyor with a screw and air flow.

2. Reduces the damageability of the material due to the air flow eliminating the spillage of particles between the screw and the housing.

Claims (1)

A pneumatic screw installation for transporting bulk cargo, comprising a housing with a loading hopper, a screw installed in the housing with a shaft connected to the drive, an air supply source and an unloading pipe, characterized in that the screw has a vertical arrangement, the shaft of which extends along the length of the entire installation, and the housing is hermetically connected to a cylindrical pneumatic chamber, which is hermetically connected to an air duct connected to a source for supplying air, having a damper regulating the air flow, and the pneumatic chamber fixed with the possibility of rotation around the axis of the auger and provided with a sloping plane, the angle of inclination of which coincides with the angle of inclination of the discharge pipe, in addition, a sluice unloader is built into the discharge pipe, the wheel axis of which is offset from the center of the pipe to its upper wall.