CN212271080U - Novel water supply conversion system - Google Patents

Abstract

A novel water supply system relates to the technical field of fracturing. Comprises a header and a plurality of water storage tanks. The water storage tanks are all selectively communicated with the manifold so that the manifold can selectively deliver water into the water storage tanks and selectively recycle the water in the water storage tanks. The water storage tanks are all provided with level gauges, and the headers have connecting pipes for selectively communicating with the fracturing device. The water supply device can obviously reduce manual water transfer amount and external water demand, obviously reduce labor intensity and cost input, simultaneously can uniformly recycle return water, and is more environment-friendly under the condition of reducing subsequent treatment cost.

Description

Novel water supply conversion system

Technical Field

The utility model relates to a fracturing technical field particularly, relates to a novel change water supply system.

Background

The fracturing operation has the characteristics of large available water amount, large water transfer amount and long operation period, and the conventional water transfer only depends on manual water transfer, so the labor intensity is high, the operation risk is high and the cost is high. On the other hand, a large amount of gas field water is generated after fracturing, and the gas field water contains a large amount of fracturing additives, so that the workload is very large for subsequent treatment.

In view of this, the present application is specifically made.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a novel change water supply system, it can obviously reduce artifical water yield and outside water demand of changeing, makes intensity of labour and cost input all obtain obvious reduction, can also unify recovery reuse to gas field water simultaneously, and green is more again under the condition that has reduced subsequent treatment cost.

The embodiment of the utility model is realized like this:

a novel water diversion and supply system, comprising: a manifold and a plurality of water storage tanks. The water storage tanks are all selectively communicated with the manifold so that the manifold can selectively deliver water into the water storage tanks and selectively recycle the water in the water storage tanks. The water storage tanks are all provided with level gauges, and the headers have connecting pipes for selectively communicating with the fracturing device.

Furthermore, the novel water supply system also comprises a communicating pipe for selectively communicating the water storage tanks in sequence so as to supply water to the water storage tanks for mutual water delivery.

Further, novel change water supply system still includes a plurality of water storage groups, and every water storage group all includes a plurality of water storage tanks. Each water storage group is selectively communicated with the collecting pipe, and the water storage tanks of the same water storage group are sequentially and selectively communicated through a communication pipe.

Furthermore, each water storage group comprises a plurality of water storage units, each water storage unit comprises a plurality of water storage tanks, the number of the water storage tanks of each water storage unit of the same water storage group is the same, and the water storage tanks of the same water storage unit are sequentially and selectively communicated through a communicating pipe. The water storage units of the same water storage group are sequentially and selectively communicated through a water quantity balancing pipe.

Furthermore, at least one water storage unit in each water storage group is selectively communicated with the collecting pipe through the water inlet pipe, and the water inlet pipe is selectively communicated with all the water storage tanks of the water storage units.

Furthermore, at least one water storage unit in each water storage group is selectively communicated with the collecting pipe through a water outlet pipe, and the water outlet pipe is selectively communicated with all the water storage tanks of the water storage units.

Furthermore, the water storage unit positioned at the starting end in each water storage group is selectively communicated with the collecting pipe through the water inlet pipe, and the water inlet pipe is selectively communicated with all the water storage tanks of the water storage unit. The water storage units positioned at the tail ends of the water storage groups are selectively communicated with the collecting pipe through the water outlet pipe, and the water outlet pipe is selectively communicated with all the water storage tanks of the water storage units.

Furthermore, the novel water supply system also comprises a water storage tank, and the manifold is selectively communicated with the water storage tank.

Furthermore, the novel water supply system also comprises a water diversion tank, and the water storage pool and the manifold are selectively communicated with the water diversion tank.

Furthermore, a plurality of water pipes are arranged between the water diversion tank and the collecting pipe, each water pipe selectively communicates the collecting pipe with the water diversion tank, and each water pipe is provided with an infusion pump.

The embodiment of the utility model provides a beneficial effect is:

the embodiment of the utility model provides a novel change water supply system can be retrieved gas field water to the manifold through the connecting pipe after fracturing finishes when putting into use, retrieves gas field water to the water storage tank through the inlet tube by the manifold again. And under the monitoring of the liquid level meter, controlling the gas field water to fill the water storage tanks and keeping the water amount in each water storage tank balanced. And when the next fracturing work is carried out, the water in the water storage tank is recycled to the manifold through the water outlet pipe and is conveyed to the fracturing site through the connecting pipe for fracturing water.

Novel change water supply system and realized retrieving, storing and reuse to the gas field water that the fracturing in-process produced, this innocent treatment cost of having practiced thrift gas field water greatly also avoids gas field water to pollute the surrounding environment, also has made the replenishment for subsequent fracturing water simultaneously, has reduced follow-up required extra water yield, and not only green has also reduced follow-up degree of difficulty and the work load of transporting new water source.

Generally, the embodiment of the utility model provides a novel water supply system that changes can obviously reduce artifical water yield and outside water demand volume of changing, makes intensity of labour and cost input all obtain obvious reduction, can also unify recycle to gas field water simultaneously, and green again under the condition that has reduced subsequent treatment cost.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention, and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

Fig. 1 is a schematic view of a novel water supply system provided by an embodiment of the present invention.

Icon: a new water supply system 1000; a manifold 100; a connection pipe 110; a water inlet pipe 120; a water outlet pipe 130; a water storage tank 200; a communication pipe 210; a water storage group 300; a water storage unit 400; a water quantity balancing pipe 410; a water storage tank 500; a water diversion tank 600; a water delivery pipe 610.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. The components of embodiments of the present invention, as generally described and illustrated in the figures herein, may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present invention, presented in the accompanying drawings, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Examples

Referring to fig. 1, the present embodiment provides a novel water supply system 1000. The novel water supply system 1000 includes: a manifold 100 and a plurality of water storage tanks 200.

Each of the water storage tanks 200 is in selective communication with the manifold 100 to enable the manifold 100 to selectively deliver water to the water storage tanks 200 and to selectively recycle water from the water storage tanks 200 to the manifold 100. The water storage tanks 200 are all provided with a liquid level meter (not shown in the figure) for monitoring the liquid level condition in each water storage tank 200 in real time. The header 100 has a connecting tube 110 for selective communication with a fracturing device,

it should be noted that, in the embodiment of the present invention, "selectively connected" means that "connection" or "disconnection" can be selected according to actual needs, so as to implement different connection modes under different situations. The valve can be realized by a pipeline provided with a valve, or by a pipeline provided with a valve and a delivery pump at the same time; the pipes can be in one-way conduction or in two-way conduction. And is not limited thereto.

In the present embodiment, an inlet pipe 120 and an outlet pipe 130 are provided, and the inlet pipe 120 is used to selectively communicate the manifold 100 with the water storage tank 200 and to transfer the water in the manifold 100 to the water storage tank 200. The outlet pipe 130 is used to selectively communicate the manifold 100 with the storage tank 200 and to transfer water in the storage tank 200 into the manifold 100.

When the gas field water is put into use for the first time, the gas field water can be recovered to the manifold 100 through the connecting pipe 110 after fracturing is finished, and then the gas field water is recovered to the water storage tank 200 through the manifold 100 and the water inlet pipe 120. Under the monitoring of the liquid level meter, the gas field water is controlled to fill the water storage tanks 200 and the water amount in each water storage tank 200 is kept balanced. When the next fracturing operation is performed, the water in the water storage tank 200 is recycled to the manifold 100 through the water outlet pipe 130 and is delivered to the fracturing site through the connecting pipe 110 for the fracturing water.

Novel water supply system 1000 that changes has realized the recovery, storage and the reuse to the gas field water that the fracturing in-process produced, this innocent treatment cost of having practiced thrift gas field water greatly also avoids gas field water to pollute the surrounding environment, has also made the replenishment for subsequent fracturing water simultaneously, has reduced follow-up required extra water yield, and not only green has also reduced follow-up degree of difficulty and the work load of transporting new water source.

In general, the novel water supply system 1000 that changes can obviously reduce the manual work and change water yield and outside water demand, makes intensity of labour and cost input all obtain obvious reduction, can also unify recycle to gas field water simultaneously, and is green again under the condition that has reduced subsequent treatment cost.

Further, the novel water supply system 1000 further includes a communication pipe 210 for selectively communicating the water storage tanks 200 in sequence, so as to allow the water storage tanks 200 to communicate with each other. The water storage tanks 200 can be selectively communicated with each other using the communication pipe 210, so that water balance is achieved among the water storage tanks 200, which facilitates management of water storage work, regulation and distribution of water amount, and maintenance of balance of internal pressures of the water storage tanks 200 and pipes.

Specifically, in the present embodiment, the novel water transfer and supply system 1000 further includes a plurality of water storage units 300, each water storage unit 300 includes a plurality of water storage units 400, and each water storage unit 400 includes a plurality of water storage tanks 200. The number of the water storage tanks 200 of each water storage unit 400 of the same water storage group 300 is the same, and the water storage tanks 200 of the same water storage unit 400 are selectively communicated with each other in sequence through the communication pipe 210. The water storage units 400 of the same water storage group 300 are selectively communicated with each other in sequence through the water balance pipe 410.

Through the design, each water storage group 300 is mutually independent, so that the water storage work and management can be conveniently and respectively carried out, the stability of the whole system is greatly improved, and even if some water storage groups 300 break down, the normal functions of other water storage groups 300 are not influenced, and the whole system can still normally operate. Each water storage unit 300 is composed of a plurality of water storage units 400, and the water yield between the water storage tanks 200 in each water storage unit 400 can be effectively balanced, so that the whole water storage part is divided into a plurality of adjusting units, each adjusting unit can realize independent water balance adjustment, when a small amount of water in the header 100 needs to be supplemented or absorbed, only one water storage unit 400 can be used for corresponding work without using the whole water storage unit 300, the operation amount is reduced, and the influence on the whole system is reduced as much as possible.

In addition, the water balance pipe 410 is used for realizing large-range water balance between each water storage unit 400, the whole system has local water quantity adjusting capacity, and meanwhile, the whole water quantity balancing capacity is also realized, the flexibility of whole water quantity adjustment and water quantity management is greatly improved, water can be flexibly selected from which water storage tanks 200 to take water according to single water consumption (different fracturing operation and fracturing requirements, and the difference of the water consumption can be large) instead of taking water from all the water storage tanks 200 at each time, the operation is convenient, and the subsequent operation quantity of replenishing water into the water storage tanks 200 again is reduced.

Further, in the present embodiment, the water inlet pipe 120 is selectively communicated with the water storage unit 400 located at the starting end of each water storage group 300, and the water inlet pipe 120 is selectively communicated with all the water storage tanks 200 of the water storage unit 400. The water outlet pipe 130 is selectively communicated with the water storage unit 400 at the tail end of each water storage unit 300, and the water outlet pipe 130 is selectively communicated with all the water storage tanks 200 of the water storage unit 400.

Through the design, each water storage group 300 can be more independent, and the integrity and the harmony inside each water storage group 300 are improved. Because the gas field water is continuously generated in the fracturing process, the gas field water can be recovered while delivering water to the fracturing site (at the moment, the manifold 100 can be divided into two mutually independent parts, one part is used for delivering water to the fracturing site, and the other part is used for receiving the gas field water), namely, the novel water transfer and supply system 1000 can be simultaneously used for the fracturing work of two fracturing sites.

In this embodiment, the novel water supply system 1000 further includes a water storage tank 500 and a water tank 600, the manifold 100 is selectively communicated with the water storage tank 500, and both the water storage tank 500 and the manifold 100 are selectively communicated with the water tank 600. A plurality of water pipes 610 are arranged between the catchment tank 600 and the collecting pipe 100, each water pipe 610 selectively communicates the collecting pipe 100 and the catchment tank 600, and each water pipe 610 is provided with an infusion pump.

Through the above design, the water storage tank 500 is used for collecting other sewage, rainwater or river water at ordinary times, and also can be used for temporarily collecting gas field water, and after fracturing work is completed, the gas field water is stored to the water storage tank 200 again. In addition, the water stored in the priming tank 600 can be used for emptying the infusion pump, so that the infusion pump can normally work as soon as possible, and manual emptying is avoided.

It should be noted that, in this embodiment, the water inlet pipe 120 is a pipe with a valve, the water outlet pipe 130 is a pipe with a valve and a delivery pump, the connection pipe 110 is a pipe with a valve, the connection pipe 210 is a pipe with a valve, the water balance pipe 410 is a pipe with a valve, and the water delivery pipe 610 is a pipe with a valve and a delivery pump. And the valve in this embodiment is long-range program control valve, and novel water supply system 1000 that changes is unified by PLC control system control, and valve and each pump all are connected with control center communication to realize overall control.

To sum up, novel water supply system 1000 that changes can obviously reduce artifical water yield and outside water demand that changes, makes intensity of labour and cost input all obtain obvious reduction, can also unify recycle to gas field water simultaneously, and green again under the condition that has reduced subsequent treatment cost.

Novel water supply system 1000 changes passes through level gauge control tank 500, tank 200 liquid level, changes water according to the automation that the liquid level height realized between tank 500 and the tank 200, accomplishes and has realized intellectuality and automation, for the user has practiced thrift a large amount of manpower and materials costs, has reduced valve maloperation and accident rate. The system has strong functions and stable performance, and can be remotely monitored.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. A novel water supply system that changes, its characterized in that includes: a manifold and a plurality of water storage tanks; the water storage tanks are all selectively communicated with the manifold so that the manifold can selectively convey water into the water storage tanks and selectively recycle the water in the water storage tanks; the water storage tank all is provided with the level gauge, the manifold has and is used for the connecting pipe with fracturing unit selective intercommunication.

2. The novel water transfer and supply system according to claim 1, further comprising a communication pipe for selectively communicating the water storage tanks in sequence, so as to allow the water storage tanks to mutually convey water.

3. The novel water transfer system of claim 2, further comprising a plurality of water storage groups, each water storage group comprising a plurality of the water storage tanks; each water storage group is selectively communicated with the header respectively, and the water storage tanks of the same water storage group are sequentially and selectively communicated through the communicating pipe.

4. The novel water transfer and supply system as claimed in claim 3, wherein each water storage group comprises a plurality of water storage units, each water storage unit comprises a plurality of water storage tanks, the number of the water storage tanks of each water storage unit of the same water storage group is the same, and the water storage tanks of the same water storage unit are sequentially and selectively communicated through the communication pipe; the water storage units of the same water storage group are sequentially and selectively communicated through a water quantity balancing pipe.

5. The water supply system according to claim 4, wherein at least one of the water storage units in each of the water storage groups is selectively communicated with the manifold via a water inlet pipe, and the water inlet pipe is selectively communicated with all of the water storage tanks of the water storage units.

6. The water supply system according to claim 4, wherein at least one of the water storage units in each water storage group is selectively communicated with the manifold through a water outlet pipe, and the water outlet pipe is selectively communicated with all the water storage tanks of the water storage units.

7. The novel water transfer and supply system as claimed in claim 4, wherein the water storage unit at the initial end of each water storage group is selectively communicated with the header through a water inlet pipe, and the water inlet pipe is selectively communicated with all the water storage tanks of the water storage unit; the water storage units positioned at the tail ends of the water storage groups are selectively communicated with the header through water outlet pipes, and the water outlet pipes are selectively communicated with all the water storage tanks of the water storage units.

8. A novel water transfer system as claimed in claim 1 further comprising a reservoir, said manifold being in selective communication with said reservoir.

9. The water supply system according to claim 8, further comprising a diversion tank, wherein the water storage tank and the manifold are in selective communication with the diversion tank.

10. A novel water transfer and supply system according to claim 9, wherein a plurality of water pipes are arranged between the water diversion tank and the manifold, each water pipe selectively communicates the manifold with the water diversion tank, and each water pipe is provided with an infusion pump.

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