RU80161U1 - Sedimentation tank - Google Patents

Abstract

The device relates to the field of industrial wastewater treatment, namely to discharge devices of sludge tanks, and can be used in various industries where the deposition method is used to de-slam industrial wastewater. The main objective of the utility model is to increase the reliability of the device by reducing the abrasive effect of sludge on the interface between the parts of the discharge chamber and the pump. To achieve this goal, a sump containing a sludge outlet assembly made in the form of a sludge collector and an unloading chamber, at the bottom connected to a transport pipeline and equipped with a drive drum made with longitudinal grooves along a generatrix installed in the unloading chamber with a gap to its walls parallel to the transport in this case, holes are made in the longitudinal grooves of the drive drum, in which pistons are connected to each other by a rod, and the rod itself is located with a gap to drive drum. 2 ill.

Description

The device relates to the field of industrial wastewater treatment, namely to discharge devices of sludge tanks, and can be used in various industries where the deposition method is used to de-slam industrial wastewater.

A device for cleaning water and surface wastewater (A.S. No. 1333365. Class B01D 21/24), including a precipitation chamber connected to the discharge hopper and discharge tank through the shut-off bodies. The discharge tank is made in the form of a tubular tee connected to a pressure pipe with a transporting medium and to a transport pipe.

The disadvantages of the known device include low reliability due to increased wear of the mating parts of the locking elements from the effects of an abrasive medium and the possibility of a large fraction of sludge falling under the mating parts. In this case, due to a violation of the tightness in the precipitation chamber, the process of decontamination of wastewater is terminated.

The closest technical solution for the totality of features and the achieved result is a device for water and surface wastewater treatment (A.S. parts connected to the transport pipeline and provided with a drive drum made with longitudinal grooves.

The main objective of the utility model is to increase the reliability of the device by reducing the abrasive effect of sludge on the interface between the parts of the discharge chamber and the pump.

To achieve this goal, a sump containing a node output sludge, made in the form of sludge collector and discharge chamber, in

the lower part connected to the transport pipeline and provided with a drive drum made with longitudinal grooves along a generatrix installed in the discharge chamber with a gap to its walls parallel to the transport pipe, while in the longitudinal grooves of the drive drum holes are made in which pistons are connected to each other rod, and the rod itself is located with a gap to the drive drum.

In relation to the prototype, the proposed device has the following distinctive features: in the longitudinal grooves of the drive drum, holes are made in which pistons are connected to each other by a rod, and the rod itself is located with a gap to the drive drum.

Pistons connected to each other by a rod allow pushing out sediment that fills the longitudinal grooves, thereby preventing it from clogging. The gap between the rod and the drive drum reduces the abrasive effect of the sludge on the mating parts.

The device is illustrated by drawings, where in Fig.1 shows a General view; figure 2, view A in figure 1.

The sump includes a sludge outlet assembly made in the form of a sludge collector 1, an unloading chamber 2, a pressure pipe 3 connected to a pump 4 and a transport pipe 5, a pipeline for supplying clarified water 6 with a chute 7; a drive drum 9 installed in the unloading chamber 2 on the axle shafts 8, with longitudinal grooves 10, located with a gap 11 to the walls of the unloading chamber; pistons 12, mounted on the rod 13 with a gap 14 with respect to the drive drum 9, mounted in the holes of the longitudinal grooves 10.

The sump works as follows:

Industrial wastewater is treated by sedimentation in a radial sump. The sludge deposited at the bottom of the sump is collected in sludge collector 1. When the sludge is in the sludge collector

reaches level II, then the sensor (not shown) turns on the pump 4 and the drive (not shown) of the drum 9. The sediment that fills the longitudinal grooves 10 of the drum 9 is moved to the lower part of the discharge chamber 2, pushed out of the grooves 10 into the transport pipe 5 by pistons 12, which are fixed on the stem 13, and is washed away by the oncoming flow of clarified water. Through the transport pipeline 5, the sludge is delivered to the place of further processing. The gap 14 between the rod and the drive drum allows you to reduce the abrasive effect of the sludge on the mating parts.

At the same time, under pressure necessary for hydrotransporting the sludge, water washes the drum 9 through the gap 11, reducing the abrasive effect of the sludge, and enters through the discharge chamber 2 into the sludge collector 1. The amount of upward water flow in the discharge chamber is limited by the size of the gap 11, which is determined from the condition of stable sliding sludge, for which it is necessary that the velocity of the upward flow of water in the discharge chamber is below the critical speed at which a fluidized state of sediment sludge is formed. When the precipitate reaches level II-II, a sensor (not shown) turns off the drive of the drum 9 and after the estimated time turns off the pump to flush the transport pipeline 5.

The technical result of the claimed device is to increase the reliability of the device by reducing the abrasive effect of sludge on the interface between the parts of the discharge chamber and the pump.

Claims (1)

A sump containing a sludge outlet assembly made in the form of a sludge collector and an unloading chamber, at the bottom connected to a transport pipeline and provided with a drive drum made with longitudinal grooves along a generatrix installed in the unloading chamber with a gap to its walls parallel to the transport pipeline, characterized in that holes are made in the longitudinal grooves of the drive drum, in which pistons are located, connected to each other by a rod, and the rod itself is located with a gap to the drive drum.