DE3941133A1 - Device for recovering energy in reverse osmosis systems - uses throttle valve in retentate line replace by pump coupled to feed pump with smaller delivery rate - Google Patents

Abstract

Device for recovering energy in reverse-osmosis installations comprises first pump (1a) in the raw water inlet pipe, which is mechanically connected to a second pump (1b), which is in the retentate pipeline (i.e. the return pipe for water which has not passed through the osmosis membrane), and has a delivery rate which is less than that of the first pump (1a). The delivery rate of the second pump is 60-90 percent of that of the first pump. The two pumps (1a,1b) may be in the same housing and may be multiple gear pumps whose driven wheels engage with driving wheels on a single drive shaft. USE/ADVANTAGE - Used in reverse osmosis systems in e.g. desalination of sea-water. The customary throttle valve used in the retentate line is replaced by the second pump, so energy normally dissipated in the throttle valve is in part recovered and the overall energy consumption of the installation is therefore reduced.

Description

The invention relates to a device for Recovery of energy in reverse osmosis systems, some with raw water, retentate and permeate lines provided reverse osmosis module and one in the Have raw water supply arranged first pump.

Reverse osmosis systems are known in which the Raw water by means of a pump in the reverse osmosis module is pumped. At the exit of the reverse osmosis module in the Rententatleitung is a throttle device, for. B. in Shape of a valve arranged so that on the Raw water side of the reverse osmosis module an overpressure arises for the filtration of a certain amount Raw water by the arranged in the reverse osmosis module Membrane leads. Such reverse osmosis systems have the Disadvantage that hydraulic energy in the Retentate line remaining under pressure Raw water is not used.

The object of the invention is therefore a device for the recovery of energy in reverse osmosis systems to provide the hydraulic Energy of the raw water for driving the before the Reverse osmosis module at least arranged pump to partially exploit.

This task comes with the characteristic feature solved by claim 1.

In that the arranged in the retentate line Throttle device replaced by a second pump is mechanically coupled to the first pump is pushing it into the retentate line under pressure incoming raw water this second pump  due to the mechanical coupling to the drive of the first pump. Since part of the in the Reverse osmosis module pumped raw water through the If the membrane enters the permeate line, the Delivery rate of the second pump may be less than the delivery rate of the first pump.

This direct mechanical coupling of two pumps has the advantage that, for example, a generator for Recovery of electrical energy to the second Pump can be connected, is unnecessary.

Because of the energetic coupling according to the invention two in the raw water and the retentate line arranged pumps is a simple Energy recovery achieved with reverse osmosis.

The delivery rate of the second pump is preferably 60 to 90% of the delivery rate of the first pump.

In a preferred embodiment, both are Pumps installed in a common housing and designed as a multiple gear pump. The two grasp the driven pump wheels of the gear pumps on a common driving pump wheel after the mechanical coupling of the two pumps simple way is achieved.

Another advantage is that only one only drive required for two or more pumps is. In contrast to two separate pumps reduced thus the number of components. This works is particularly advantageous if it in addition to the low weight of the pumps and one small space requirement arrives.  

By arranging two or more driven Pump wheels on a single driving pump wheel a compact unit that achieves the function of takes over at least two pumps.

According to a preferred embodiment, this is driving pump wheel as a one-piece multiple gear, especially double gear. The usually provided in a gear pump Middle part of the housing, such as from the EP 01 47 567 is known in this Embodiment by a first stator plate, a second stator plate and an intermediate one Center plate formed, with the double gear through the two stator plates and the middle plate extends. They are in the two stator plates driven pump wheels arranged with the corresponding gear sections of the double gear are engaged.

The two are advantageously driven Pump wheels on one fixed in the middle plate common shaft rotatably mounted. As part of the Invention is also provided that the two driven pump wheels on a common shaft are fixed in the middle plate or in the Base plate and is stored in the cover plate.

So that two completely separate from each other Pumping spaces are created, are the two Sprocket sections of the double sprocket spatially arranged separately from each other. For this purpose between the two gear sections disk-shaped section may be provided, the is rotatably and sealingly mounted in the middle plate.  

To different funding rates in the two Adjusting pump parts can vary the width of the driven impellers may be different, whereby the gear sections of the driving pump wheel to the Width of the driven pump wheels are adjusted. By arranging several different widths driven pump wheels becomes a pump unit created the one without changing the speed predetermined number of different funding rates offers.

The funding rates can also vary as a result that the diameter and the Tooth pitch of the driven pump wheels and the thus engaged gear sections of the Multiple gear are formed differently.

Exemplary embodiments are as follows explained in more detail with reference to the drawings. It shows

Fig. 1 shows the schematic representation of the device according to the invention

Fig. 2 shows a longitudinal section through a double gear pump according to a first embodiment

Fig. 3 is a section along the line AA of the gear pump shown in Fig. 2

Fig. 4 shows a section along the line AA according to a second embodiment.

In FIG. 1, a reverse osmosis module 33 is shown, which is fed via a raw water line 30 to the raw water. In this raw water line 30 , a first pump 1 a is arranged, which pumps the raw water at high pressure into the reverse osmosis module. Due to the overpressure, part of the raw water passes through the membrane 34 and flows out via the permeate line 32 . The remaining raw water leaves the reverse osmosis module 33 via the retentate line 31 and reaches a second pump 1 b, which is mechanically coupled to the first pump 1 a. The pump 1 b has a lower delivery rate than the pump 1 a. Characterized in that the raw water flows under pressure into the retentate line 31 , the pump 1 b is driven, which contributes to driving the first pump 1 a due to the mechanical coupling.

For pumps 1 a and 1 b, for example, rotary vane or rotary lobe pumps can be used.

But there is also the possibility to use two coupled gear pumps 1 a and 1 b.

Such a double gear pump 1 is shown as a preferred embodiment in FIG. 2. The pump 1 has a base plate 2 , a cover plate 6 and a middle housing part 25 , which is arranged between the base plate 2 and cover plate 6 . In the illustration shown here, the middle housing part consists of a first stator plate 3 and a second stator plate 5 and a middle plate 4 arranged between them.

In each stator plate 3 and 5 there is a pump chamber in which the pump wheels 14 , 17 and 18 are arranged.

The pump wheel 14 is the driving pump wheel, which in the embodiment shown here is designed as a double gear wheel with two gear wheel sections 15 and 16 . The gear section 15 is arranged in the pump chamber of the second pump part 1 b, while the gear section 16 is arranged in the pump chamber of the first pumps 1 a. Between the two gear sections 15 and 16 of the driving pump wheel 14 , a disc-shaped section 26 is formed, which is rotatably and sealed in the middle plate 4 , so that the two pump chambers in the pump parts 1 a and 1 b are separated from one another and a mixture of the in liquids pumped between the two pump parts is excluded.

The driving pump wheel 14 is rotatably mounted on a fixed shaft 12 which is fastened in the cover plate 6 . For this purpose, a corresponding recess is provided in the cover plate 6 . The driving pump wheel 14 is led out through the base plate 2 to the outside as a hollow shaft 27 . A magnet 11 is arranged on the hollow shaft 27 and forms part of a magnetic coupling (not shown in more detail) for transmitting the drive forces for the gear pump 1 . The magnet 11 is located in an interior 10 which is formed by a hood 9 which is fastened to the base plate 2 .

FIG. 3 shows a section along line AA of the illustration shown in FIG. 2. The stator plate 5 is provided with an inlet channel 19 and an outlet channel 20 , which are arranged opposite one another. The stator plate 3 is provided in the same way with inlet and outlet channels.

The embodiment shown in FIG. 2 shows a pump in which the delivery rates of the two pump parts 1 a and 1 b are of different sizes. The gear section 16 and the driven pump wheel 18 are accordingly wider than the gear section 15 and the driven pump wheel 17 .

Different delivery rates can also be achieved in that the diameter of the driven pump wheels 17 and 18 and the corresponding gear sections 15 and 16 of the driving pump wheel 14 are selected to be different sizes. This is shown in a representation corresponding to FIG. 3 in FIG. 4.

But there is also the possibility, if the double gear pump is used for other purposes, to choose the width or the diameter of the driven pump wheels and the corresponding gear sections of the driving pump wheel. The gear pump 1 can also be expanded as desired by extending the driving pump wheel by further gear wheel sections and by providing further driven pump wheels which are arranged in corresponding further stator plates.

Reference symbol list:

1 gear pump
1 a first pump
1 b second pump
2 base plate
3 first stator plate
4 middle plate
5 second stator plate
6 cover plate
9 hood
10 interior
11 magnet
12 first wave
13 , 13 a, 13 b second wave
14 driving impeller
15 first gear section
16 second gear section
17 first driven impeller
18 second driven impeller
19 inlet duct
20 outlet duct
25 middle part of housing
26 disc-shaped section
27 hollow shaft
30 raw water pipe
31 Retentate management
32 permeate line
33 reverse osmosis module
34 membrane

Claims (9)

1. Device for recovering energy in reverse osmosis systems, which have a reverse osmosis module provided with raw water, retentate and permeate line and a first pump arranged in the raw water supply line, characterized in that with the first pump ( 1 a) mechanically a second pump ( 1 b) is coupled, which is arranged in the retentate line ( 31 ) and has a lower delivery rate than the first pump ( 1 a). 2. Device according to claim 1, characterized in that the delivery rate of the second pump ( 1 b) is 60 to 90% of the delivery rate of the first pump. 3. Apparatus according to claim 1 or 2, characterized in that the first pump ( 1 a) and the second pump ( 1 b) are arranged in a common housing and are designed as a multi-gear pump, the driven pump wheels ( 17, 18 ) on a common Grip the driving impeller ( 14 ). 4. The device according to claim 3, characterized in that the driving pump wheel ( 14 ) is made as a one-piece multiple gear with the gear sections ( 15, 16 ). 5. Apparatus according to claim 3 or 4, characterized in that the housing has a drive-side base plate ( 2 ), a bearing-side cover plate ( 6 ) and in between at least a first stator plate ( 3 ), a second stator plate ( 5 ) and an intermediate plate ( 4 ), the multiple gearwheel extending through the stator plates ( 3, 5 ) and the central plate ( 4 ) and with the first driven pump wheel ( 17 ) rotatably mounted in the first stator plate ( 3 ) and with the one in the second stator plate ( 5 ) rotatably mounted second driven pump wheel ( 18 ) is engaged. 6. Device according to one of claims 3 to 5, characterized in that the two driven pump wheels ( 17, 18 ) are rotatably mounted on a common shaft ( 13 ) fixed in the central plate ( 4 ). 7. Device according to one of claims 3 to 5, characterized in that the two driven pump wheels ( 17, 18 ) on a common shaft ( 13 ) are fixed in the middle plate ( 4 ) or in the base plate ( 2 ) and in the cover plate ( 6 ) is rotatably mounted. 8. Device according to one of claims 3 to 7, characterized in that the width of the driven pump wheels ( 17, 18 ) is different and that the gear sections ( 15, 16 ) of the driving pump wheel ( 14 ) are adapted thereto. 9. Device according to one of claims 3 to 8, characterized in that the diameter and the tooth pitch of the driven pump wheels ( 17, 18 ) is different and that the gear sections ( 15, 16 ) of the driving pump wheel ( 14 ) are adapted thereto.