AT515237A1 - Control and drive of a multi-stage heat exchanger for wastewater with buffer storage - Google Patents

Abstract

The invention relates to the control and the drive for a heat exchanger for wastewater with buffer storage with several superimposed wastewater containers (1 to 3). The connecting tube (6) is connected via a cable with a counterweight (8), the counterweight (8) is attracted by a permanent magnet (7), which can be electrically deactivated. If the waste water tank is filled, the connecting hose (6) is heavier than the counterweight (8), whereby the connecting hose (6) is held only by the permanent magnet (7) in the filling position. The float switch (9) is mounted in the first waste water tank stage (1), which deactivates the permanent holding magnet (7) of the lowest waste water tank stage (3) upon reaching the desired level and thus emptied. By emptying the connecting hose (6) lighter than the counterweight (8) and thereby brought back to its original position. With the aid of the controller (10), the middle and finally the uppermost wastewater tank stage are then emptied.

Description

Control and drive of a multi-stage heat exchanger for wastewater with buffer storage

The invention relates to the control and the drive for a heat exchanger for wastewater with buffer storage with a plurality of superposed drainage tanks or sewage tank stages.

The waste heat exchanger with buffer storage has been published with the patent number EP 2531799. Patent application AT508015 describes a wastewater heat exchanger controlled by gravity and electrically controlled or magnetic holding mechanisms.

The drive of the lifting devices of multi-stage heat exchangers for buffered waste water is carried out according to the state of the art by means of motors and the associated sensors.

Programmable logic controllers are often used in practice because they are very easy to use.

The buffered waste heat exchanger is a product suitable for serial production. In order to enable a large area of use for the recovery of thermal energy from wastewater, the economic production is of great importance.

The gravity drive and the control of several superimposed waste containers are made possible by keeping the counterweight in the filling position by an electrically controlled holding magnet.

In the control shown here, delayed-action relays, a float switch and permanent holding magnets are used, which can be electrically deactivated.

The embodiment according to the invention in FIG. 1 shows a heat exchanger for buffered waste water with three drainpipes placed one above the other in front view. (Without front covers)

The wastewater passes through the wastewater inlet 4 into the wastewater tank stage 1. Upon reaching the desired level, the permanent magnet 7 of the wastewater tank stage 3 is deactivated for a short time.

The filled with sewage connection hose 6 is heavier than the counterweight 8, whereby this tilts down and the wastewater is discharged into the wastewater drain 5. By emptying the connecting hose 6 is again lighter than the counterweight 8 and thereby brought back to its original position and again held by the permanent magnet 7.

With the aid of the controller 10, the wastewater is then discharged from the wastewater tank stage 2 into the wastewater tank stage 3, and thereafter the waste water from the wastewater container stage 1 is discharged into the underlying waste water tank stage 2.

The thermal energy of the wastewater is recovered with heat exchangers.

Figure 2 shows the circuit diagram for three superimposed wastewater containers, which are connected in series.

The float switch S1 activates the delayed-action relays R1, R2 and R3.1 and the permanent magnet M3. The magnet M3 is now deactivated, which causes the waste water filled connection hose to tip down and drain the wastewater in the wastewater tank stage 3 into the wastewater drain.

The magnet M3 is reactivated after a short time by the relay R3.1. The stage 3 connector hose is raised after being discharged by the counterweight and held by the magnet M3.

Subsequently, the delayed-action relay R2 deactivates the permanent magnet M2, whereby the wastewater can drain into the underlying drainage tank. The magnet M2 is reactivated after a short time by the relay R2.1.

Lastly, the on-delay relay R1 deactivates the permanent magnet M1, thereby diverting the first-stage effluent to the stage 2 sewage tank. The falling level in the waste water tank stage 1 switches off the float switch S1 and all relays.

FIG. 3 shows the functional time diagram of S1, M1, M2 and M3 list of reference numbers: 1. Wastewater container stage 1, 2. Wastewater container stage 2, 3. Wastewater container stage 3, 4. Wastewater inlet, 5. Waste water outlet, 6. Connection hose, 7 Permanent magnet, 8th counterweight, 9th float switch, 10th control

Claims (5)

1. Control and drive of a multi-stage heat exchanger for wastewater with buffer storage, by means of electrically controlled or magnetic holding mechanisms, characterized in that the connecting hose (6) via a cable with a counterweight (8) is connected. 2. Control and drive of a multi-stage wastewater heat exchanger with buffer storage according to claim 1, characterized in that the connection hose (6) in its full state is heavier than the counterweight (8). Control and drive of a multi-stage wastewater heat exchanger with buffer storage according to claims 1 and 2, characterized in that the connection hose (6) is lighter when empty than the counterweight (8). 4. Control and drive of a multi-stage heat exchanger for wastewater with buffer storage of claim 1 to 3, characterized in that only zugverzögerte relays are used. 5. Control and drive of a multi-stage heat exchanger for wastewater with buffer storage of claim 1 to 4, characterized in that only one float switch (9) is used.