CN212715123U - Energy-saving water taking process system - Google Patents

Abstract

The utility model discloses an energy-saving water intaking process system, which comprises a tailing pond area, a mine pit area and a high water level pond, wherein the tailing pond area is provided with three water intaking points, each water intaking point is provided with a movable water intaking pipe, each movable water intaking pipe comprises a first water conveying pipe, the number of the first water conveying pipes is three, a first water pump is installed on a pipeline of the first water conveying pipe, the upper end of the first water conveying pipe is communicated with an intermediate pump pond, a second water conveying pipe is communicated between the mine pit area and the intermediate pump pond, the number of the second water conveying pipes is one, the height difference from the intermediate pump pond to the high water level pond is 200m, the energy consumption is higher, therefore, a movable water intaking system is adopted for supplying water, the total installed capacity is 1930KW, the installed capacity of the water intaking system is reduced by 2300KW compared with the original water supplying system, the construction cost of the movable process system is low, the effect is fast, and the water intaking, the electric energy consumption of water supply is reduced.

Description

Energy-saving water taking process system

Technical Field

The utility model relates to an energy-conserving water intaking process systems.

Background

The high-level water pool is supplemented with water by two systems. The first set of systems: and a two-stage pump station is adopted to supply a high-level water pool. The backwater pump station is conveyed to a pressurizing pump station by a single-stage pump with the flow rate of 1200m3/h and the lift of 110m, wherein the single-stage pump is 500 KW; three 710KW pressurizing pump stations are used, the flow rate is 500m3/h, the lift is 342m, and the multi-stage pumps are conveyed to a high-level water pool to enter a production system for water. The second set of systems: a primary pump station is adopted to directly supply a high-level water pool. Two 800KW 8-grade pumps with the flow rate of 500m3/h (total flow rate of 1000m3/h) and the lift of 380-460 m are operated to directly convey water to a high-level water pool to enter a production system for water, so that the water supply energy consumption is high. The two systems need to be started simultaneously to meet the requirement of production water, the total installed capacity is 4230KW, and the production water cost is high. Along with the annual rise of the water level of a tailing pond area, in order to reduce the water supply cost, a movable water taking pump station is arranged at the tail part of a tailing pond and close to a mine, an intermediate pump station is arranged above the water taking pump station, water collected in a mining pit of the mine and pumped by the movable water taking pump station enter a water storage pond of the intermediate pump station, and the two pumps are used for pumping the water to a high-level water pond.

The production water is mainly conveyed to the high-level water tank by the backwater pump station and the booster pump station and enters the production system, and the water pumping needs higher energy consumption because the water taking point reaches 460 meters of the height difference of the high-level water tank.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides an energy-conserving water intaking process systems.

For solving above technical problem, the technical scheme of the utility model for adopt an energy-conserving water intaking processing system, including tailing reservoir area, mine pit district and high water level pond, tailing reservoir area is provided with three water intaking point, the water intaking point is provided with portable water intaking, portable water intaking includes first raceway, first raceway quantity is three, install first water pump on the pipeline of first raceway, first raceway upper end intercommunication has middle pump pond, the intercommunication has the second raceway between mine pit district and the middle pump pond, second raceway quantity is one, install the second water pump on the pipeline of second raceway, the intercommunication has the third raceway between middle pump pond and the high water level pond, third raceway quantity is two, install the third water pump on the pipeline of third raceway.

As an improvement, the first water conveying pipe is a DN350 water pipe.

As an improvement, the second water conveying pipe is a DN200 water pipe.

As an improvement, the third water conveying pipe is a DN400 water pipe.

As an improvement, the difference in height between middle pump pond to the high water level pond is 200m, portable water intaking elevation is 1710m, middle pump pond elevation is 1735 m.

The utility model discloses an useful part lies in: the height difference between the intermediate pump pool and the high water level pool with the structure is 200m, the energy consumption is high, the water supply of the mobile water taking system is adopted, the total installed capacity is 1930KW, 2300KW is reduced compared with the installed capacity of the original water supply system, the building cost of the mobile water taking process system is low, the effect is fast, the water entering the production system through the high water level pool is avoided, and the electric energy consumption of water supply is reduced.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

The labels in the figure are: 1 tailing reservoir area, 2 first water pumps, 3 first water delivery pipes, 4 mining pit areas, 5 second water pumps, 6 second water delivery pipes, 7 middle pump pools, 8 third water pumps, 9 third water delivery pipes, 10 high water level pools and 11 water taking points.

Detailed Description

In order to make those skilled in the art better understand the technical solution of the present invention, the present invention will be further described in detail with reference to the specific embodiments.

As shown in figure 1, the utility model comprises an energy-saving water taking process system, which comprises a tailing reservoir area 1, a mine pit area 4 and a high water level pool 10, wherein the tailing reservoir area 1 is provided with three water taking points 11, the water taking points 11 are provided with movable water taking, the movable water taking is also called movable water taking, the movable water taking is arranged by taking water in rivers or water areas with large fluctuation range of water level, the floating boat water taking and cable car water taking are mainly adopted, and the floating suction type and derrick type are also adopted individually, so that the system has the characteristics of small investment, quick construction, easy construction, large adaptability and flexibility, capability of frequently obtaining surface water with small sand content and the like, the utility model adopts the floating boat water taking, the movable water taking part is built with the movable water taking process system, the movable water taking part comprises a first water delivery pipe 3, the number of the first water delivery pipes 3 is three, and a first water pump 2 is arranged on the pipeline of the first water delivery pipe 3, the power of the first water pump 2 is 160KW, the upper end of the first water delivery pipe 3 is communicated with an intermediate pump pool 7, the first water pump is generally directly discharged to a tailing pond area 1 due to the fact that a large amount of accumulated water exists in a mining pit area 4, the water saving amount in dry seasons and high-water seasons is 100-300 m3/h, in order to combine water pumping of the mining pit area 4 and water taking of the tailing pond area 1, an intermediate pump station is built between the tailing pond area 1 and a mine, the intermediate pump pool 7 is arranged on the intermediate pump station, a second water delivery pipe 6 is communicated between the mining pit area 4 and the intermediate pump pool 7, the number of the second water delivery pipes 6 is one, the second water pump 5 is installed on a pipeline of the second water delivery pipe 6, the power of the second water pump 5 is 110KW, a third water delivery pipe 9 is communicated between the intermediate pump pool 7 and the intermediate pump pool 10, the number of the third water delivery pipes 9 is two, and a third water pump 8 is installed on a pipeline of the third water, the third water pump 8 is a 800KW single-pole double-suction horizontal centrifugal pump.

The model of the first water delivery pipe 3 is DN350 water pipe.

The model number of the second water conveying pipe 6 is DN200 water pipe.

The model of the third water conveying pipe 9 is DN400 water pipe.

The difference in height between middle pump pond 7 and high water level pond 10 is 200m, portable water intaking elevation is 1710m, middle pump pond 7 elevation is 1735 m.

The above is only a preferred embodiment of the present invention, and it should be noted that the above preferred embodiment should not be considered as limiting the present invention, and the protection scope of the present invention should be subject to the scope defined by the claims. It will be apparent to those skilled in the art that various modifications and enhancements can be made without departing from the spirit and scope of the invention, and such modifications and enhancements are intended to be within the scope of the invention.

Claims (5)

1. The utility model provides an energy-conserving water intaking process systems, includes tailing storehouse district (1), mine pit area (4) and high water level pond (10), its characterized in that: the tailing pond area (1) is provided with three water taking points (11), the water taking points (11) are provided with movable water taking, the movable water intaking device comprises three first water conveying pipes (3), a first water pump (2) is arranged on the pipeline of the first water delivery pipe (3), the upper end of the first water delivery pipe (3) is communicated with a middle pump pool (7), a second water delivery pipe (6) is communicated between the mine mining area (4) and the middle pump pool (7), the number of the second water delivery pipes (6) is one, a second water pump (5) is arranged on the pipeline of the second water delivery pipes (6), a third water delivery pipe (9) is communicated between the middle pump pool (7) and the high water level pool (10), the number of the third water conveying pipes (9) is two, and a third water pump (8) is installed on a pipeline of the third water conveying pipes (9).

2. An energy-saving water getting process system according to claim 1, characterized in that: the model of the first water conveying pipe (3) is DN350 water pipe.

3. An energy-saving water getting process system according to claim 1, characterized in that: the model of the second water conveying pipe (6) is DN200 water pipe.

4. An energy-saving water getting process system according to claim 1, characterized in that: the model of the third water conveying pipe (9) is DN400 water pipe.

5. An energy-saving water getting process system according to claim 1, characterized in that: the difference in height between middle pump pond (7) to high water level pond (10) is 200m, portable water intaking elevation is 1710m, middle pump pond (7) elevation is 1735 m.

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