CN212293070U - Small-size sea water desalination device based on GO membrane - Google Patents

Abstract

The utility model provides a small-sized seawater desalination device based on GO membrane, which comprises a filter vat, a first booster pump, a throttle valve, a filter, a second booster pump and a GO membrane component which are connected in sequence; the GO membrane module is connected with a drainage device and a purified water outlet device. The utility model discloses a small-size sea water desalination device based on GO membrane to the actual demand of island and fishing boat, coupling GO membrane technique, the technique of receiving strain combines leading filter to reach sea water desalination's preliminary treatment effect, and the light small-size booster pump of cooperation use improves the system water efficiency of GO membrane to solve the problem that the small-size sea water desalination equipment running cost of island is high.

Description

Small-size sea water desalination device based on GO membrane

Technical Field

The utility model relates to a sea water desalination device field especially relates to a small-size sea water desalination device based on GO membrane.

Background

Water is a source of life, is a life pulse for social and economic development and is a fixed foundation for human development. The water on earth, although in huge quantities, can be directly utilized by human production and life, but is few.

The cost of seawater desalination is composed of energy consumption cost, equipment consumption, personnel cost, medicament cost and the like, wherein the energy consumption cost accounts for the highest proportion of the total cost, and most islands have no heat source, so the production cost is further increased by adopting a thermal method for seawater desalination. At present, a reverse osmosis membrane process is mainly adopted for sea water desalination in islands, and energy is supplied as electric energy. Most islands have no power plants, and the electric energy is transmitted by the continent; even if a power plant is built on the island, the power supply is not very sufficient. A part of limited electric energy is used for sea water desalination, and although the problem of lack of fresh water is relieved, the shortage of electricity for residents on the island is bound to be caused. Therefore, the single barrier of the energy mode for seawater desalination must be broken, and the hydropower requirements of residents on the island can be met at the same time. At present, the automation degree of the seawater desalination equipment is not high, and the maintenance of the equipment needs the field operation of professional personnel. Compared with the offshore region on the continent, the island is inconvenient to transport, and once equipment fails, the response time of personnel for repairing is long, so that the production and the life on the island are seriously influenced.

Disclosure of Invention

Not enough to above-mentioned prior art, the utility model provides a small-size sea water desalination device based on GO membrane to the actual demand of island and fishing boat, coupling GO membrane technique, the nanofiltration technique combines leading filter to reach sea water desalination's preliminary treatment effect, and the light small-size booster pump of cooperation use improves the system water efficiency of GO membrane to solve the problem that the small-size sea water desalination equipment running cost of island is high.

In order to realize the aim, the utility model provides a small-sized seawater desalination device based on GO membrane, which comprises a filter vat, a first booster pump, a throttle valve, a filter, a second booster pump and a GO membrane component which are connected in sequence; the GO membrane module is connected with a drainage device and a purified water outlet device.

Preferably, the GO membrane module comprises a housing, a GO membrane layer, a first conduit and a second conduit; the shell forms a filtering space; the first pipeline and the second pipeline are connected with the shell and partially penetrate through the filtering space; the first pipeline and the second pipeline are communicated in the filtering space; the GO membrane layer is arranged between the first pipeline and the second pipeline in the filtering space; the first pipeline is arranged in the middle of the shell, and the second pipeline is arranged on one side of the first pipeline; the first end of the first pipeline is connected with the second booster pump, and the second end of the second pipeline is connected with the water drainage device; the first end of the second pipeline is sealed, and the second end of the second pipeline is connected with the purified water outlet device.

Preferably, the purified water outlet device comprises a fresh water outlet pipe, a water storage tank, a fresh water straight pipe and a first faucet which are connected in sequence; the fresh water straight pipe is provided with a valve.

Preferably, the drain device comprises a drain pipe and a second faucet which are connected, and the drain pipe is connected with the second end of the second pipeline.

Preferably, still include a shell, the filter vat is connected the shell, first booster pump, the choke valve, the filter, the second booster pump and the GO membrane module set up in the shell.

Preferably, the housing forms a water storage tank support, and the water storage tank is fixed on the water storage tank support through a fixing frame.

Preferably, the water outlet of the filter vat is connected with the water inlet of the first booster pump through a first pipeline assembly; the first pipeline assembly comprises a plurality of seamless steel pipes and at least one straight joint, and the seamless steel pipes are connected through the straight joint; and the seamless steel pipe is connected with the water outlet of the filter barrel through a joint flange and a plurality of bolts.

Preferably, the water outlet of the first booster pump is connected with the water inlet of the filter through a second pipeline assembly; the throttle valve is mounted on the second conduit assembly.

The utility model discloses owing to adopted above technical scheme, make it have following beneficial effect:

the adoption of the preposed filter can achieve the effect of pretreatment of seawater desalination and can prolong the service life of the GO membrane component; the first booster pump and the second booster pump are respectively used for improving the water production rate of the filter and the GO membrane component; through the cooperation of filter, first booster pump, second booster pump and GO membrane module, can solve the small-size sea water desalination equipment of island problem with high operating cost.

Meanwhile, the integrated design with the shell enables the water making device to be more compact, occupies smaller area and is convenient to carry; in addition, aiming at poor traffic conditions and inconvenient transportation of islands, the seawater desalination equipment is subjected to modularized and integrated design, and the transportation process can be decomposed into a plurality of operation units, so that the seawater desalination equipment is favorable for rapid configuration according to the island conditions.

Drawings

Fig. 1 is a schematic diagram of a GO membrane-based small-sized seawater desalination plant according to an embodiment of the present invention;

fig. 2 is a front partial sectional view of a small-sized sea water desalination device based on a GO membrane according to an embodiment of the present invention;

fig. 3 is a side partial sectional view of a small-sized sea water desalination device based on GO membrane according to an embodiment of the present invention;

fig. 4 is a top partial cross-sectional view of a small-scale seawater desalination plant based on GO membrane according to an embodiment of the present invention;

fig. 5 is an elevation view of a GO membrane assembly of an embodiment of the invention;

fig. 6 is a side view of a GO membrane module of an embodiment of the invention.

Detailed Description

The following description of the preferred embodiments of the present invention will be given with reference to the accompanying drawings 1 to 6, and will make the functions and features of the present invention better understood.

Referring to fig. 1 to 4, a small seawater desalination device based on GO membrane according to an embodiment of the present invention includes a filter vat 1, a first booster pump 2, a throttle valve 3, a filter 4, a second booster pump 5, and a GO membrane module 6, which are connected in sequence; the GO membrane module 6 is connected with a drainage device 7 and a purified water outlet device 8.

Referring to fig. 1, 5 and 6, the GO membrane module 6 includes a housing 61, a GO membrane layer, a first pipe 62 and a second pipe 63; the housing 61 forms a filtering space; the first pipeline 62 and the second pipeline 63 are connected with the shell 61 and partially penetrate through the filtering space; the first pipe 62 and the second pipe 63 are communicated in the filtering space; a GO membrane layer is arranged between the first pipeline 62 and the second pipeline 63 in the filtering space; the first duct 62 is disposed at the middle of the case 61, and the second duct 63 is disposed at one side of the first duct 62; a first end of the first pipeline 62 is connected with the second booster pump 5, and a second end of the second pipeline 63 is connected with the drainage device 7; a first end of the second pipe 63 is sealed, and a second end of the second pipe 63 is connected with the purified water outlet device 8.

Referring to fig. 2 to 5, the purified water outlet device 8 includes a fresh water outlet pipe 81, a water storage tank 82, a fresh water straight pipe 83 and a first faucet 84 connected in sequence; the fresh water straight pipe 83 is provided with a valve 85.

The drain device 7 comprises a drain pipe 71 and a second tap 72 connected, the drain pipe 71 being connected to the second end of the second pipe 63.

Still include a shell 9, filter vat 1 connects shell 9, and first booster pump 2, choke valve 3, filter 4, second booster pump 5 and GO membrane module 6 set up in shell 9.

The housing 9 forms a water storage tank support 91, and the water storage tank 82 is fixed to the water storage tank support 91 through a fixing bracket 92.

The water outlet of the filter barrel 1 is connected with the water inlet of the first booster pump 2 through a first pipeline assembly; the first pipeline assembly comprises a plurality of seamless steel pipes 11 and at least one straight joint 12, and the seamless steel pipes 11 are connected through the straight joint 12; a seamless steel pipe 11 is connected to the water outlet of the filter vat 1 through a joint flange 13 and a plurality of bolts 14.

The water outlet of the first booster pump 2 is connected with the water inlet of the filter 4 through a second pipeline assembly 21; the throttle valve 3 is mounted on the second pipe assembly 21.

The present invention has been described in detail with reference to the embodiments shown in the drawings, and those skilled in the art can make various modifications to the present invention based on the above description. Therefore, certain details of the embodiments should not be construed as limitations of the invention, which are intended to be covered by the following claims.

Claims (8)

1. A small-sized seawater desalination device based on a GO membrane is characterized by comprising a filter vat, a first booster pump, a throttle valve, a filter, a second booster pump and a GO membrane component which are sequentially connected; the GO membrane module is connected with a drainage device and a purified water outlet device.

2. The GO membrane-based small seawater desalination plant of claim 1, wherein the GO membrane module comprises a housing, a GO membrane layer, a first conduit and a second conduit; the shell forms a filtering space; the first pipeline and the second pipeline are connected with the shell and partially penetrate through the filtering space; the first pipeline and the second pipeline are communicated in the filtering space; the GO membrane layer is arranged between the first pipeline and the second pipeline in the filtering space; the first pipeline is arranged in the middle of the shell, and the second pipeline is arranged on one side of the first pipeline; the first end of the first pipeline is connected with the second booster pump, and the second end of the second pipeline is connected with the water drainage device; the first end of the second pipeline is sealed, and the second end of the second pipeline is connected with the purified water outlet device.

3. The GO membrane-based miniature seawater desalination device of claim 2, wherein the water purification and discharge device comprises a fresh water outlet pipe, a water storage tank, a fresh water straight pipe and a first faucet which are connected in sequence; the fresh water straight pipe is provided with a valve.

4. The GO membrane-based compact seawater desalination plant of claim 2, wherein the drainage means comprises a drain pipe and a second faucet connected, the drain pipe being connected to a second end of the second pipeline.

5. The small sea water desalination device based on the GO membrane according to claim 3 or 4, further comprising a housing, wherein the filter vat is connected with the housing, and the first booster pump, the throttle valve, the filter, the second booster pump and the GO membrane module are arranged in the housing.

6. The GO membrane-based miniature seawater desalination device of claim 5, wherein the housing forms a water storage tank support, and the water storage tank is fixed on the water storage tank support through a fixing frame.

7. The small GO membrane-based seawater desalination plant of claim 5, wherein the water outlet of the filter tank is connected to the water inlet of the first booster pump through a first pipe assembly; the first pipeline assembly comprises a plurality of seamless steel pipes and at least one straight joint, and the seamless steel pipes are connected through the straight joint; and the seamless steel pipe is connected with the water outlet of the filter barrel through a joint flange and a plurality of bolts.

8. The GO membrane-based small seawater desalination plant of claim 5, wherein the water outlet of the first booster pump is connected to the water inlet of the filter through a second pipe assembly; the throttle valve is mounted on the second conduit assembly.

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