DE19818691C1 - Control of concentration and yield in reverse osmosis plant - Google Patents

Abstract

Water level in the buffer (30) is controlled between upper and lower levels, alternately admitting and blocking inlet flow. The concentrate flow change-over interval is synchronized with the interval of level control. Preferred Features: In each control interval, raw water volume (Qw) admitted and concentrate volume leaving (Qa) are measured. To control yield, the desired concentrate efflux Qa(n) for the current period n is determined, based on the desired yield value esoll and the measured raw water influx Qw(n-1) in the previous filling phase. Flow of concentrate leaving is reduced in the current interval, once the determined concentrate volume has left. Desired concentrate efflux is given by Qa(n) = Qw(n-1) x (1-esoll). Concentrate efflux is blocked once the efflux achieves this value in the current interval. The difference between desired and measured values is calculated at the end of each interval. The calculated value is reduced by this difference in the following interval. The yield e in corresponding period n, is given by e = 1-Qa/Qw. To maintain minimal concentrate separation at greatly reduced permeate efflux, excess concentrate is extracted using the valve (68), once the interval exceeds a given limit above that of the preceding value.

Description

The invention relates to a control method a reverse osmosis system.

The principle of operation of reverse osmosis systems is known Lich in that the water to be treated in a filter mo dul under high pressure on the surface of a semipermeable Membrane is passed along, with part of the raw water, the pure water (permeate), passes through the membrane and on the other side of the membrane collected and the consumption points is fed. The one that does not pass through the membrane with retained substances enriched part of the raw water, the waste water (concentrate) flows at the end of the flow stretch the primary space out of the membrane module.

It is desirable to achieve the highest possible yield. This refers to the relationship between that at Ver Permeate volume taken from the user connection and that of the Plant supplied raw water volume. The achievable yield however, there are limits to the fact that with increasing Yield the concentration of poorly soluble substances on the Primary side of the membrane can become so high that it is too off precipitation occurs and the membrane module becomes unusable.

For these reasons, the correct setting and over come the yield is of particular importance. This applies in increased degree with strongly fluctuating permeate demand and that correspondingly variable utilization of the plant.

It is common for the perm need the excess permeate generated to  Raw water input, likewise a more or less large portion of the concentrate. This reduces the Raw water consumption, and the tendency of sinking te by the reduced permeate consumption can be compensated become. To keep the yield constant with fluctuating However, a control system is necessary for permeate consumption, that is the division of the concentrate into the raw water side returned portion and the portion discharged into the drain Proportion sets automatically.

The invention was based, the yield of a task Reverse osmosis system with little technical effort regulate.

An exemplary embodiment is described below with the aid of the Fig which shows the diagram of a reverse osmosis system, explained.

The core of the reverse osmosis system is the actual reverse osmosis unit, consisting of the membrane module 10 and the high pressure pump 20 . The interior of the membrane module is divided by the semipermeable membrane 12 into a primary space 10 a and a secondary space 10 b. The pump 20 is fed from a buffer vessel 30 and conveys water via the line 14 into the primary space of the membrane module. The permeate passing through the membrane into the secondary space flows out via line 16 . The concentrate is discharged at the end of the primary room via line 17 , the throttle 18 inserted into this line being used to adjust the pressure in the primary space of the membrane module.

The raw water passes from the inlet line 32 via the valve 34 , the flow meter 36 and the line 38 into the buffer vessel 30 . The buffer vessel is equipped with level sensors 41 , 42 . They serve a two-point fill level control in the buffer vessel. When the level drops to a minimum level, which is recognized by the sensor 41 , the raw water inflow is released via the control unit 40 and the valve 34 . When the maximum level is reached and sensor 42 responds , the raw water flow is blocked again. Each period of this control process consists of a filling and an emptying phase of the buffer vessel.

Permeate emerging from the membrane module via line 16 flows via outlet line 50 to the consumption points. Excess permeate can flow back into the buffer vessel via line 51 , pressure-maintaining valve 52 and line 53 . The pressure control valve 52 , the z. B. is designed as a spring loaded check valve, can serve to set the pressure in the outlet line 50 .

A portion of the concentrate that exits via restrictor 18 flows back through line 60 , valve 62 and line 64 back into the buffer tank, another portion flows through line 66 , valve 68 and flow meter 70 into the drain.

When valve 68 is open, most or all of the concentrate flows into the drain. When the valve 68 is closed, most or all of the concentrate is returned to the buffer vessel. The simplest case is that a switch is made between the complete discharge of the concentrate into the drain and the complete return of the concentrate into the buffer vessel. This is the case when the opening pressure of the valve 62 , which is shown in the diagram as a spring-loaded check valve, is higher than the pressure drop at the opened valve 68 , and when a shunt throttle 68 a connected in parallel with the valve 68 is not present or is completely closed .

By periodically switching the valve 68 , the concentrate discharge can be set to an average value over time, which depends on the opening duration of the valve 68 in relation to the period. The yield can also be adjusted by changing this ratio.

According to the invention, the period of the switchover of the concentrate flow is synchronized with the period of the level control of the buffer vessel. As a result, it is sufficient that the concentration fluctuations in the buffer vessel 30 , which inevitably result from the discontinuity of the returned concentrate flow, assume a regular, as flat a course as possible. In particular, it can be avoided in this way that, as a result of a temporarily unfavorable constellation, namely the return of the full concentrate flow at low fill level and blocked raw water inflow, the concentration reaches such high values that damage to the membrane module is to be feared.

The synchronization of both processes has the further important gene advantage that despite the variability of the level in the buffer vessel and the discontinuity of the raw water supply and Concentrate return or concentrate discharge for everyone Period, a quantity balance can be drawn up from which a valid statement about the yield can be derived.

The flow meter 36 in the raw water pipe and the flow meter 70 in the drain pipe serve this purpose. Preferably, these are pulse-generating flow meters, e.g. B. vane meter with optoelectronic or magnetic scanning, which emit a certain number of electrical pulses for each volume, so that by simply counting down the pulses emitted in a period, the volume flowed through can be concluded.

Since the same fill level is present in the buffer vessel 30 at the beginning and at the end of a period of the fill level control, the permeate volume withdrawn in the period results as the difference between the raw water volume Qw supplied and the concentrate volume Qa removed and thus the yield e = 1 for the past period - Qa / Qw. This value can be calculated from the pulse numbers by appropriate devices of the control device 40 and output on a display device.

To create a volume balance, the second flow meter could also be inserted into the permeate consumer line 50 instead of into the concentrate drain line, but this appears to be less advantageous. In general, the aim is to obtain water that is as germ-free as possible. Additional components in the permeate line, which cannot be flowed through completely free of dead space, so that they offer the possibility for the settlement of microorganisms, should be avoided.

The invention also provides for control of the yield. Through the control, the yield concentrate deposition is to be adjusted so that at a predetermined desired yield of e _to the concentrate deposition and the raw water supply in the ratio Qa / Qw = 1 - e _should be. For this purpose, according to the invention, the concentrate quantity Qa (n) to be eliminated for the current period (n) is determined on the basis of the raw water volume Qw (n − 1) of the previous filling phase, and the concentrate separation in the current period is ended by closing valve 68 as soon as this target Concentrate volume Qa (n) = Qw (n - 1) × (1 - e _soll ) has flowed out. The signals from the flow meters 36 and 70 serve as measured quantities for the inflowing and outflowing volumes, as in the determination of the actual yield.

It may be expedient to connect the shunt 68 to the valve 68 in parallel in order to maintain a minimum concentrate separation in order to protect the membrane modules even in times when no permeate is removed and therefore no raw water would flow in because the permeate is completely recycled. Because of the shunt choke 68 a by closing the valve 68 no complete blocking of the concentrate drain is effected. As a result, an additional amount of concentrate flows out after switching. An error in the yield control caused by this can be compensated for in that when determining the target concentrate volume Qa (n), upon reaching which the switchover is triggered, a computational correction in the form Qa (n) = Qw (n - 1) × (1 - e _soll ) - Qa0 is provided, where Qa0 represents an empirically determined correction variable, which mainly depends on the setting of the shunt inductor and the period. Such a correction is also suitable to compensate for a switching delay caused by the mechanical-hydraulic holding of the valve 68 .

In another embodiment, an automatic correction is in provided that at the end of each period the difference between the measured outflowing concentrate volume and determined the target value of the flowing concentrate volume  and the setpoint of the flowing concentrate volume for the next period is reduced by this difference. It it is determined whether there is a Deviation between the actual concentrate discharge and the concentrate required to achieve the target yield flow has taken place and this deviation if necessary when specifying the concentrate discharge for the next one Period taken into account with the correct sign.

If no permeate is withdrawn from the outlet line, the period of the level and extraction control is extended as desired. In order to maintain a certain minimum concentrate separation in order to protect the filter module, it is provided in a further embodiment that when Errei surfaces a predetermined maximum permissible time interval over the last concentrate separation, the valve 68 is opened and thereby an additional concentrate volume is separated. After this additional concentrate volume, which is measured by the flow meter 70 , has drained away, the valve is closed again. As a result, approximately the same effect is achieved as by the shunt choke 68 a, so that this can be omitted.

Claims (7)

1. A method for controlling a reverse osmosis system with supply of the raw water in a buffer vessel ( 30 ) which is connected upstream of the actual reverse osmosis unit consisting of a high-pressure pump ( 20 ) and filter module ( 10 ), recycling excess permeate and recycling of concentrates occurred in the buffer vessel , wherein the non-recirculated portion of the concentrate flow, which is directed to the drain, is periodically switched between a high and a low value, fluctuating around a temporal mean value, characterized in that the fill level in the buffer vessel is controlled by a two-point fill level control with alternating release / blocking of the Raw water inflow varies between a lower and an upper level and the period of the switchover of the concentrate flow is synchronized with the period of this level control. 2. The method according to claim 1, characterized in that in every period of the level control that the buffer vessel supplied raw water volume Qw and the flowing concentra tread volume Qa can be determined. 3. The method according to claim 2, characterized in that for the purpose of regulating the yield of the target value of the concen- trate discharge Qa (n) for the current period n on the basis of the predetermined yield target value e _soll and the inflow of raw water volume Qw measured in the previous filling phase (n-1) is determined and the concentrate outflow is switched to the lower value in the current period when the concentrate volume determined by the target value has flowed out. 4. The method according to claim 3, characterized in that the 3 target value of the flowing concentrate volume Qa (n) for the current period according to the relationship Qa (n) = Qw (n - 1) × (1 - e _Soll ) determined and the concentrate outflow is blocked in the current period as soon as the measured flowing concentrate volume has reached this value. 5. The method according to claim 3 or 4, characterized in that at the end of each period the difference between the measured outflowing concentrate volume and the setpoint of the outflowing concentrate volume is determined and the 3 Setpoint of the flowing concentrate volume for the next one Period is reduced by this difference. 6. The method according to any one of the preceding claims, characterized characterized in that the valid for the respective period n Actual value of the yield e according to the relationship e = 1 - Qa / Qw is determined. 7. The method according to claim 4, characterized in that in order to maintain a minimum concentrate separation with a greatly reduced permeate removal, a certain additional concentrate volume is derived via the valve 68 as soon as the time interval compared to the previous concentrate separation exceeds a predetermined limit.