SU1102726A1 - Bucket elevator - Google Patents

Abstract

1. BUCKET ELEVATOR containing drive and tension drums, placed respectively in the head and boot with loading window, vertically closed traction body with buckets, the ascending and descending branches of which are placed in pipes with windows, and the bypass device tilted under angle of repose and connecting pipes to each other through windows, characterized in that, in order to increase reliability, the bypass device is inclined towards the downward branch of the traction body, and the pipes in the zones of connection with them usknogo fixture made advanced. the minimum distance from the lower edge of the window of the pipe of the descending branch of the trap to the upper edge of the boot window of the shoe is determined by the ratio & n% NIN Zn-volume flow of cargo; where Sg is the actual cross-sectional area of the bucket; n is the number of buckets crossing the level of the load in the shoe per unit of time. 2. Elevator according to claim 1, characterized in that the bypass device is made in the form of a nozzle. 3. An elevator according to claim 1, characterized in that the nozzle is provided with a V-shaped dissector made of vertically installed partitions forming an acute angle directed apex toward the pipe of the ascending branch of the traction organ. 4. Elevator according to claim 1, characterized in that the buckets on the pulley are fixed with a step fil-V / Q, where 1 is the volume of the bucket; V is the velocity of motion of the traction axis.

Description

The invention relates to industrial transport, namely to bucket conveyor frames.

A bucket conveyor is known, which contains a drive and tension drum, a traction body with buckets, placed in tubular boxes connected with a head and a shoe, and a device for controlling the loading of an elevator, made in the form of a valve in the shoe 1.

However, due to the change in the properties of the bulk material (moisture, debris, etc.) and the conditions for its entry into the boot opening (e.g., speed), even when the valve is in the same position, the flow of bulk material through the gap between the valve and bottom edge of the loading opening.

Therefore, such a structure does not protect the conveyor from the dam, the occurrence of which is possible from pouring out excess bulk material from the buckets when they leave the shoe.

Also known is a bucket elevator containing drive and tension drums, placed respectively in the head and boot with a loading window, a vertically closed draft body with upward and downward buckets which are placed in tubes with windows, and a bypass device inclined at an angle repose and pipe between each other through windows 2.

In this elevator, due to the bypass device, the blockage in the branch pipe of the descending branch of the traction body is eliminated by a load that has spilled past the discharge opening in the head. However, in the case of complete elimination of this head in the head by any means in this elevator, debris is not excluded in other places, for example, in the pipe of the ascending branch of the traction body.

The purpose of the invention is to increase reliability.

The goal is achieved by the fact that in the bucket elevator containing drive and tension drums, placed respectively in the head and the shoe with the loading window, there is a vertically closed traction body with buckets, the ascending and descending branches of which are placed in pipes with windows, and the bypass device tilted at an angle of repose and connecting the pipes to each other through windows, the bypass device is inclined towards the downward branch of the traction organ, with the minimum distance from the lower edge of the window pipes of the downward branch of the traction organ to the upper edge of the loading window are determined by the ratio: n. - QH

mtn

where Q is the volume flow of the cargo;

Sg is the actual cross-sectional area of the bucket; m - the number of buckets crossing the level of the fuse in the shoe per unit

of time.

The bypass device is made in the form of a pipe.

The nozzle is provided with a V-shaped cutter, made of vertically mounted partitions, forming an acute angle directed by the apex toward the pipe of the ascending branch of the traction organ. In addition, the buckets on the body are fixed in increments

 . i iv / a

where 1 is the volume of the bucket;

V is the speed of movement of the traction organ.

FIG. 1 shows a bucket elevator, general view; in fig. 2 - node I on

FIG. one; in fig. 3 shows section A-A in FIG. 2

Bucket Elevator contains a drive

I and tension 2 drums, placed respectively in head 3 with discharge port 4 and shoe 5 with loading window 6, vertically closed traction body 7 with buckets 8, rising 9 and descending 10 branches of which are passed through pipes 11 and 12 s windows 13 and 14, and the bypass device in the form of a nozzle 15, 00 tilted in the direction of the descending branch of the traction organ at an angle of repose and connecting pipes 11 and 12 to each other through windows 13 and 14. At the same time, the pipes

II and 12 in the zones of connection with the nozzle 15 are expanded, and the minimum distance from the lower edge of the window of the pipe 12 of the downward branch of the traction member 7 to the upper edge of the loading window 6 of the shoe 5 is determined by the ratio

LT 6d

Hfnin

0o, - „

where Qi is the volume consumption of the goods;

Sg is the actual cross-sectional area of the bucket; J1 is the number of buckets crossing the load level in the shoe per unit 5 time.

The nozzle 15 is made with a V-shaped cutter Secatelle 16, consisting of vertically mounted partitions 17, which together form an acute angle directed by the top towards the pipe 11 of the upward branch of the 9th tail body 7. The buckets 8 on the dead end body 7 are fixed in increments

Qjf

N, 5GG

where i is the bucket volume;

. V is the speed of movement of the traction organ.

The load, for example grain, enters the shoe 5 through the loading window 6, is captured by the buckets 8 of the traction body 7, is transported to the head 3 and when the traction body 7 bends around the drum 1 is unloaded through the discharge opening 4. When an excess amount of grain and the growth of its column in the pipe 11 to the broadened section, it flows through the pipe 15 into the broadened section of the pipe 12 of the downward branch 10 from which it again enters the buckets 8. The divider 16 ensures that the excess amount of grain goes to the area of the broadened section stka not overlapping the traction body 7 from the nozzle 15. The abutment Selection window layer pipe 12 and the bucket installation step 8 is performed so as to ensure the smooth functioning of the device.

To capture excess grain with buckets 8 of the descending branch 10, the junction of the nozzle 15 to the pipe 12 must be higher than the grain level in the shoe 5 from the side of the pipe 12 by such an amount that moving empty buckets of the 8 downward branch are able to capture all the incoming grain before the buckets meet. 8 with its main flow entering through the loading window 6 in the shoe 5.

The proposed implementation of the elevator increases the reliability of its work.

sixteen

td n

Claims (4)

1. A BUCKET ELEVATOR containing a drive and a tension drum located respectively in the head and shoe with a loading window, a vertically closed traction body with buckets, the ascending and descending branches of which are placed in pipes with windows, and a bypass device, inclined at an angle of repose and communicating pipes to each other through windows, characterized in that, in order to increase reliability, the overflow device is inclined towards the descending branch of the traction body, and the pipes in the zones of connection to them bypass o devices are made expanded, while the minimum distance from the lower edge of the window of the pipe of the descending branch of the traction body to the upper edge of the boot window of the shoe is determined by the ratio where (2 _{n is the} volumetric flow rate of the load; Sg is the actual bucket cross-sectional area; p - the number of buckets crossing the load level in the shoe per unit time. 2. Elevator in π. 1, characterized in that the bypass device is made in the form of a pipe. 3. Elevator in π. 1, characterized in that q the pipe is equipped with a V-shaped dissection body 18 made of vertically mounted L · partition walls forming an acute IV angle directed by the apex toward the pipe IA of the ascending branch of the traction member. 4. Elevator in π. 1, characterized in that g that the buckets on the traction body are fixed “with a step fil-V / Q ,, where ί is the volume of the bucket; V is the speed of movement of the traction body.