CN217113113U - Wireless control system for water diversion and mountaineering - Google Patents

Abstract

The utility model relates to a liquid level monitoring system specifically is a diversion wireless control system that ascends a mountain. Comprises a first-stage pump station, a second-stage pump station and a third-stage pump station which are sequentially arranged from the mountain foot to the mountain top, when the liquid level of the second radar monitors that the water level in the second water tank is too low, the secondary signal emitter sends a signal to the secondary signal receiver and transmits the signal to the secondary PLC controller, the secondary PLC controller controls the second booster pump to pump water from the primary water tank, when the liquid level of the secondary radar monitors that the water level in the second water tank reaches the designated height, the secondary signal transmitter sends a signal to the secondary signal receiver and transmits the signal to the secondary PLC controller, the secondary PLC controller controls the second booster pump to stop pumping water, and the same principle is adopted between the primary water tank and the water source of the mountain foot, the utility model automatically controls the start and stop of the two booster pumps through wireless signals, and a control cable is saved, the method can effectively reduce the faults of the buried lines, ensure stable water consumption of the mountain tops and reduce the labor intensity of personnel.

Description

Wireless control system for water diversion and mountaineering

Technical Field

The utility model relates to a liquid level monitoring system specifically is a diversion wireless control system that ascends a mountain.

Background

At present, the raw material limestone for cement production is mainly taken from mines, and the mining surface needs to be covered or vegetation needs to be restored in time after the mining operation is completed. Water is used as an essential link for greening, stable and efficient water supply provides guarantee for mine greening, and the method plays an active role in realizing green mines. But the water source under the mountain foot is far away from the mountain top, so can't guarantee when needs water the water tank water level on mountain top keeps suitable position, temporarily draws water the required time overlength through the water pump, often depends on artifical inspection water level again extravagant manpower, so need an automatic system of leading the mountain on water, can promote green mine construction work comprehensively, further optimize the ecological environment of mine enterprise.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the above problem to a diversion mountain-climbing wireless control system that can keep the water level automatically is provided.

The utility model provides a problem, the technical scheme who adopts is:

a wireless control system for drawing water and ascending a mountain comprises a first-stage pump station, a second-stage pump station and a third-stage pump station which are sequentially arranged from a mountain foot to a mountain top;

a primary control cabinet is arranged in the primary pump station, a primary signal receiver and a primary PLC controller are arranged in the primary control cabinet, and the primary signal receiver is electrically connected with the primary PLC controller;

a secondary control cabinet and a first water tank are arranged in the secondary pump station, a secondary signal receiver and a secondary PLC controller are arranged in the secondary control cabinet, the secondary signal receiver is electrically connected with the secondary PLC controller, a primary radar liquid level meter is arranged at the top of the first water tank, and a primary signal transmitter is connected to the primary radar liquid level meter;

a second water tank and a third booster pump are arranged in the third-stage pump station, the second water tank is connected with a water inlet of the third booster pump, a second-stage radar liquid level meter is arranged at the top of the second water tank, and a second-stage signal transmitter is connected to the second-stage radar liquid level meter;

be provided with first booster pump between the water source of first water tank and mountain foot, first booster pump is connected with one-level PLC controller electricity, and one-level signal transmitter sends the water level signal of one-level radar level gauge for one-level signal receiver, is provided with the second booster pump between first water tank and the second water tank, and the second booster pump is connected with second grade PLC controller electricity, and second grade signal transmitter sends the water level signal of second grade radar level gauge for second grade signal receiver.

Adopt above-mentioned technical scheme the utility model discloses, compare with prior art, its outstanding characteristics are:

when the secondary radar liquid level meter monitors that the water level in the second water tank is too low, the secondary signal transmitter sends a signal to the secondary signal receiver and transmits the signal to the secondary PLC controller, the secondary PLC controller controls the second booster pump to pump water from the primary water tank, when the secondary radar liquid level meter monitors that the water level in the second water tank reaches a specified height, the secondary signal transmitter sends a signal to the secondary signal receiver and transmits the signal to the secondary PLC controller, the secondary PLC controller controls the second booster pump to stop pumping water, and the third booster pump is controlled to pump water from the secondary water tank when the water source between the primary water tank and the mountain foot is in the same manner as the above, and the mountain top uses water. A control cable is omitted, faults of the buried line can be effectively reduced, and stable water consumption on the mountain top is guaranteed.

Preferably, the present invention further provides:

and a third-level control cabinet is also arranged in the third-level pump station, a third-level signal receiver and a third-level PLC controller are arranged in the third-level control cabinet, the third-level signal receiver and the third-level PLC controller are electrically connected, and the third-level PLC controller and the third booster pump are electrically connected.

Drawings

Fig. 1 is a schematic structural view of a wireless control system for guiding water to ascend a mountain according to an embodiment of the present invention;

labeled as: the system comprises a first-stage pump station 1, a second-stage pump station 2, a third-stage pump station 3, a first booster pump 4, a second booster pump 5, a third booster pump 6, a first-stage control cabinet 11, a second-stage control cabinet 21, a first water tank 22, a first-stage radar liquid level meter 221, a third-stage control cabinet 31, a second water tank 32 and a second-stage radar liquid level meter 321.

Detailed Description

The invention will be further described with reference to the following examples, which are intended only for better understanding of the invention and therefore do not limit the scope of the invention.

Referring to fig. 1, a water diversion and mountain climbing wireless control system comprises a first-stage pump station 1, a second-stage pump station 2 and a third-stage pump station 3 which are sequentially arranged from a mountain foot to a mountain top, wherein the first-stage pump station 1 is arranged at the mountain foot, the second-stage pump station 2 is arranged at the mountain waist, the third-stage pump station 3 is arranged at the mountain top, and a water source is arranged below the mountain foot;

a primary control cabinet 11 is arranged in the primary pump station 1, a primary signal receiver and a primary PLC controller are arranged in the primary control cabinet 11, and the primary signal receiver is electrically connected with the primary PLC controller;

the secondary pump station 2 is provided with a secondary control cabinet 21 and a first water tank 22, the secondary control cabinet 21 is provided with a secondary signal receiver and a secondary PLC controller, the secondary signal receiver is electrically connected with the secondary PLC controller, the top of the first water tank 22 is provided with a primary radar liquid level meter 221, and the primary radar liquid level meter 221 is connected with a primary signal transmitter;

a second water tank 32 and a third booster pump 6 are arranged in the third-stage pump station 3, a water inlet of the second water tank 32 is connected with a water inlet of the third booster pump 6, a second-stage radar liquid level meter 321 is arranged at the top of the second water tank 32, and a second-stage signal transmitter is connected to the second-stage radar liquid level meter 321;

a first booster pump 4 is arranged between the first water tank 1 and a water source of a mountain foot, the first booster pump 4 is electrically connected with a first-stage PLC (programmable logic controller), a first-stage signal transmitter sends a water level signal of a first-stage radar liquid level meter 221 to a first-stage signal receiver, a second booster pump 5 is arranged between the first water tank 22 and a second water tank 32, the second booster pump 5 is electrically connected with a second-stage PLC, and the second-stage signal transmitter sends a water level signal of a second-stage radar liquid level meter 321 to a second-stage signal receiver;

still be provided with tertiary control cabinet 31 in tertiary pump station 3, be provided with tertiary signal receiver and tertiary PLC controller in the tertiary control cabinet 31, electricity is connected between tertiary signal receiver, tertiary PLC controller and the third booster pump 6, through long-range signal to tertiary signal receiver, then through the work of tertiary PLC controller control third booster pump 6, has realized automatic control.

When the secondary radar liquid level meter monitors that the water level in the second water tank is too low, the secondary signal transmitter sends a signal to the secondary signal receiver and transmits the signal to the secondary PLC controller, the secondary PLC controller controls the second booster pump to pump water from the primary water tank, when the secondary radar liquid level meter monitors that the water level in the second water tank reaches a specified height, the secondary signal transmitter sends a signal to the secondary signal receiver and transmits the signal to the secondary PLC controller, the secondary PLC controller controls the second booster pump to stop pumping water, and the third booster pump is controlled to pump water from the secondary water tank when the water source between the primary water tank and the mountain foot is in the same manner as the above, and the mountain top uses water. A control cable is omitted, faults of the buried line can be effectively reduced, and stable water consumption on the mountain top is guaranteed.

The above description is only a preferred and practical embodiment of the present invention, and is not intended to limit the scope of the present invention, which is intended to be encompassed by the present invention, unless otherwise indicated by the appended claims.

Claims (1)

1. The utility model provides a wireless control system for guiding water to ascend a mountain, includes one-level pump station, second grade pump station and tertiary pump station that arrange in proper order from the foot of a mountain to the mountain top, its characterized in that:

a primary control cabinet is arranged in the primary pump station, a primary signal receiver and a primary PLC controller are arranged in the primary control cabinet, and the primary signal receiver is electrically connected with the primary PLC controller;

a secondary control cabinet and a first water tank are arranged in the secondary pump station, a secondary signal receiver and a secondary PLC controller are arranged in the secondary control cabinet, the secondary signal receiver is electrically connected with the secondary PLC controller, a primary radar liquid level meter is arranged at the top of the first water tank, and a primary signal transmitter is connected to the primary radar liquid level meter;

a second water tank and a third booster pump are arranged in the third-stage pump station, the second water tank is connected with a water inlet of the third booster pump, a second-stage radar liquid level meter is arranged at the top of the second water tank, and a second-stage signal transmitter is connected to the second-stage radar liquid level meter;

be provided with first booster pump between the water source of first water tank and mountain foot, first booster pump is connected with one-level PLC controller electricity, and one-level signal transmitter sends the water level signal of one-level radar level gauge for one-level signal receiver, is provided with the second booster pump between first water tank and the second water tank, and the second booster pump is connected with second grade PLC controller electricity, and second grade signal transmitter sends the water level signal of second grade radar level gauge for second grade signal receiver.

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