CN207392295U - A kind of artificial landscape water circulation system - Google Patents

Abstract

The utility model discloses a rockery water circulation system, which aims to solve the problem that water cannot be automatically added to the pool at the bottom of the mountain. The technical solution is as follows: it includes a rockery body and a pool at the bottom of the mountain, a water inlet pipe is provided on one side of the pool at the bottom of the mountain, the water inlet pipe is provided with a solenoid valve, a detection device for detecting high water level and low water level to send a detection signal is provided in the pool at the bottom of the mountain, and the detection device is electrically connected to the solenoid valve to control the opening and closing of the solenoid valve. The rockery water circulation system of the utility model has the advantages of automatically adding water to the pool at the bottom of the mountain and reducing manpower consumption.

Description

A kind of artificial landscape water circulation system

technical field

The utility model relates to an artificial mountain, more specifically, it relates to an artificial mountain water circulation system.

Background technique

Rockery has strong landscaping functions, such as forming the main landscape or terrain skeleton of the garden, dividing and organizing the garden space, arranging courtyards, revetments, slope protection, soil retaining, and setting up natural flower beds. It can also be combined with garden buildings, garden roads, sites and garden plants to form a changing landscape, so as to reduce the artificial atmosphere, add natural interest, and make the garden buildings blend into the landscape environment.

At present, the retrieved Chinese patent with the notification number CN203920222U discloses a waterfall circulating water system for rockery. There is a platform, the rear part of the platform is provided with a water pool on the top of the mountain, and there is a water pool at the bottom of the rockery outside the backside of the rockery below the water pool on the top of the mountain. Water pipe, the top of the suction pipe is connected to the water pump, the bottom of the suction pipe is connected to the water pool at the bottom of the mountain, and a waterfall waterway is provided on the rockery between the water pool on the top of the mountain and the water pool at the bottom of the mountain.

In the above scheme, the water in the pool at the bottom of the mountain is pumped to the pool at the top of the mountain through pumps and pipes, and then flows down from the waterfall channel, which adds to the scenery of the rockery and makes the rockery more ornamental. Under the evaporation, the water stored in the pool at the bottom of the mountain is reduced or dried up, so that the water cannot be pumped to the pool at the top of the mountain to complete the water cycle. Usually, when there is no water in the pool at the bottom of the mountain, the water at the water inlet of the pool at the bottom of the mountain will be manually opened The valve adds water to the pool at the bottom of the mountain, so there is a problem of labor consumption.

Utility model content

Aiming at the deficiencies of the existing technology, the purpose of this utility model is to provide a fake landscape water circulation system, which has the advantages of automatically adding water to the pool at the bottom of the mountain and reducing manpower consumption.

The above-mentioned technical purpose of the utility model is achieved through the following technical solutions: a rockery water circulation system, including a rockery mountain body and a water pool at the bottom of the mountain, one side of the water pool at the bottom of the mountain is provided with a water inlet pipe, and the water inlet pipe is provided with a solenoid valve , The water pool at the bottom of the mountain is equipped with a detection device for detecting high water level and low water level to send a detection signal, and the detection device is electrically connected with the solenoid valve to control the opening and closing of the solenoid valve.

By adopting the above technical scheme, through the detection device for detecting the water level installed in the water pool at the bottom of the mountain, when the water level in the water pool at the bottom of the mountain is low, the detection device sends a detection signal, so that the solenoid valve is energized and opened, and the water inlet pipe automatically feeds the water level of the water pool at the bottom of the mountain. Water is added until the water in the water pool at the bottom of the mountain reaches a high water level, and the solenoid valve is closed, which has the advantages of automatically adding water to the water pool at the bottom of the mountain and reducing manpower consumption.

The utility model is further set as: the detection device includes a floating ball assembly and a switch circuit for controlling the opening and closing of the solenoid valve, the floating ball assembly includes a floating ball, a moving rod vertically connected to the floating ball, and a moving rod arranged on the moving rod. A trigger block and a trigger switch that conflicts with the trigger block, the trigger switch includes a high water level trigger switch and a low water level trigger switch, the trigger block is located between the high water level trigger switch and the low water level trigger switch; the trigger switch and The switch circuit is electrically connected.

By adopting the above technical scheme, the floating ball remains on the water surface under the buoyancy of the water. When the water level in the pool at the bottom of the mountain moves down, the floating ball moves down synchronously until it reaches the low water level. The trigger block is in contact with the low water level trigger switch, so that the low water level trigger switch is closed, and the switch circuit responds to the low water level trigger switch to control the solenoid valve to open the water; On the high water level trigger switch, the switch circuit responds to the high water level trigger switch to control the solenoid valve to close, and completes the process of automatically adding water to the pool at the bottom of the mountain.

The utility model is further set as: the switch circuit includes the first relay KM1, the second relay KM2, the normally open contact switch KM1-1 of the first relay, the second normally open contact switch KM1-2 of the first relay and The first normally closed contact switch KM2-1 of the second relay, the low water level trigger switch is connected in series with the first relay KM1, the first normally open contact switch KM1-1 of the first relay and the first normally open contact switch KM1-1 of the second relay A normally closed contact switch KM2-1 is connected in series with the low water level trigger switch; the high water level trigger switch is connected in series with the second relay KM2, and the second normally open contact switch KM1-2 of the first relay is connected with the solenoid valve in series.

By adopting the above technical scheme, when the low water level trigger switch is closed, the first relay KM1 is energized, and then the first normally open contact switch KM1-1 of the first relay is closed to realize the circuit self-locking of the first relay KM1, At the same time, the second normally open contact switch KM1-2 of the first relay is closed, so that the solenoid valve is energized and opened, and the water inlet pipe adds water to the pool at the bottom of the mountain; when the high water level trigger switch is closed, the second relay KM2 is energized, and then the first The first normally closed contact switch KM2-1 of the second relay is opened to disconnect the self-locking circuit of the first relay KM1, so that the second normally open contact switch KM1-2 of the first relay is disconnected, and the solenoid valve is powered off Close the inlet hose.

The utility model is further configured as: the second normally open contact switch KM1-2 of the first relay is connected with a working indicator light P in series.

By adopting the above technical scheme, when the working indicator light P emits light, it can be clearly known that the water inlet pipe is adding water to the pool at the bottom of the mountain.

The utility model is further configured as follows: one side of the pool at the bottom of the mountain is connected with an installation cavity, and the floating ball assembly is located in the installation cavity.

By adopting the above-mentioned technical scheme, the installation cavity connected to the pool at the bottom of the mountain, the water level in the installation cavity is consistent with the water level of the pool at the bottom of the mountain, and the floating ball assembly is arranged in the installation cavity to reduce the impact of fish in the pool at the bottom of the mountain on the floating ball. interference.

The utility model is further configured as follows: the installation cavity is provided with an installation plate, the moving rod is inserted through the installation plate, the high water level trigger switch is arranged on the top of the installation cavity, and the low water level trigger switch is arranged on the installation plate.

By adopting the above technical solution, the installation plate provided in the installation cavity can reduce the water vapor in the installation cavity from contacting the trigger switch through the installation plate barrier, causing a short circuit.

The utility model is further configured as follows: the connection between the water pool at the bottom of the mountain and the installation cavity is provided with a grid-like baffle plate.

By adopting the above-mentioned technical scheme, the grid-shaped baffle plate provided at the connection between the pool at the bottom of the mountain and the installation cavity can prevent fish from entering the installation cavity and avoid affecting the work of the floating ball.

The utility model is further configured as: the floating ball is provided with a counterweight.

By adopting the above technical proposal, the counterweight disposed in the floating ball improves the response degree of the floating ball following the water level moving up and down on the premise of ensuring the buoyancy of the floating ball.

In summary, the utility model has the following beneficial effects: through the detection device for detecting the water level in the water pool at the bottom of the mountain, when the water level in the water pool at the bottom of the mountain is low, the detection device sends a detection signal, so that the solenoid valve is energized and opened, The water inlet pipe automatically adds water to the pool at the bottom of the mountain until the water in the pool at the bottom of the mountain reaches a high water level, and the solenoid valve is closed, which has the advantage of automatically adding water to the pool at the bottom of the mountain and reducing manpower consumption.

Description of drawings

Fig. 1 is the overall structure schematic diagram of the present embodiment;

Fig. 2 is a schematic diagram of the internal structure after the installation cavity is cut in this embodiment;

Fig. 3 is a circuit diagram of the switch circuit in this embodiment.

In the figure: 1. Rockery mountain body; 2. Water pool at the bottom of the mountain; 21. Installation cavity; 22. Grid-shaped baffle; 23. Installation plate; Waterfall channel; 7. Inlet pipe; 8. Solenoid valve; 9. Float assembly; 91. Float; 911. Counterweight; 92. Moving rod; 93. Trigger block; 94. High water level trigger switch; 95. Low Water level trigger switch; 10. Switch circuit.

Detailed ways

Below in conjunction with accompanying drawing and embodiment, the utility model is described in detail.

A kind of rockery water circulation system, as shown in Figure 1, comprises rockery mountain body 1, and the bottom of rockery mountain body 1 is provided with mountain bottom water pool 2, and rockery mountain body 1 top is provided with mountain top water pool 3, and is placed in the mountain bottom water pool 2 and is provided with pump 4, pumps The water pump 4 is connected with a water pump 5 extending to the water pool 3 on the top of the mountain, and the rockery body 1 is provided with a waterfall channel 6 connected to the water pool 3 on the top of the mountain. A water inlet pipe 7 is installed on one side wall of the water pool 2 at the bottom of the mountain, and the water inlet pipe 7 is connected with an external water pipe for water supply.

As shown in Figure 2 and Figure 3, a solenoid valve 8 is provided at the water inlet pipe 7, and a detection device for detecting high water level and low water level to send a detection signal is provided in the pool 2 at the bottom of the mountain, and the detection device is electrically connected with the solenoid valve 8 to Control solenoid valve 8 open and close. The detection device includes a floating ball assembly 9 and a switch circuit 10 for controlling the opening and closing of the solenoid valve 8. The floating ball assembly 9 includes a floating ball 91, a moving rod 92 vertically connected to the floating ball 91, and a trigger block 93 arranged on the moving rod 92. And the trigger switch that conflicts with the trigger block 93, the trigger switch includes a high water level trigger switch 94 and a low water level trigger switch 95, the trigger block 93 is located between the high water level trigger switch 94 and the low water level trigger switch 95; the trigger switch and the switch circuit 10 are electrically connected, and a counterweight 911 is arranged in the floating ball 91 .

There is an installation cavity 21 connected to the bottom of one side of the mountain bottom water pool 2, the float assembly 9 is installed in the installation cavity 21, the moving rod 92 is vertically inserted into the installation plate 23, the high water level trigger switch 94 is set on the top of the installation cavity 21, and the low water level trigger switch 95 is arranged on mounting plate 23, and high water level trigger switch 94 and low water level trigger switch 95 are normally open stroke switches. The connection between the water pool 2 at the bottom of the mountain and the installation chamber 21 is provided with a grid-like barrier 22 .

The floating ball 91 remains on the water surface under the buoyancy of the water. When the water level in the pool 2 at the bottom of the mountain moves down, the floating ball 91 moves down synchronously until reaching the low water level position. At this time, the trigger block on the moving rod 92 93 is in conflict with the low water level trigger switch 95, so that the low water level trigger switch 95 is closed, and the switch circuit 10 responds to the low water level trigger switch 95 to control the solenoid valve 8 to open the water intake; The trigger block 93 on the 92 is in conflict with the high water level trigger switch 94, and the switch circuit 10 responds to the high water level trigger switch 94 to control the electromagnetic valve 8 to close, and completes the process of automatically adding water to the water pool 2 at the bottom of the mountain.

The switch circuit 10 includes a first relay KM1, a second relay KM2, a normally open contact switch KM1-1 of the first relay, a second normally open contact switch KM1-2 of the first relay and a first normally closed contact switch of the second relay. Contact switch KM2-1, the low water level trigger switch 95 is connected in series with the first relay KM1, the first normally open contact switch KM1-1 of the first relay and the first normally closed contact switch KM2 of the second relay -1 is connected in series with the low water level trigger switch 95 in parallel; the high water level trigger switch 94 is connected in series with the second relay KM2, the second normally open contact switch KM1-2 of the first relay is connected in series with the solenoid valve 8, and the first The second normally open contact switch KM1-2 of the relay has a working indicator light P connected in series.

When the low water level trigger switch 95 is closed, the first relay KM1 is energized, and then the first normally open contact switch KM1-1 of the first relay is closed, realizing the circuit self-locking of the first relay KM1, and simultaneously the first relay KM1 is closed. The second normally open contact switch KM1-2 is closed, so that the solenoid valve 8 is energized and opened, and the water inlet pipe 7 adds water to the pool 2 at the bottom of the mountain; when the high water level trigger switch 94 is closed, the second relay KM2 is energized, and then the second The first normally closed contact switch KM2-1 of the relay is opened, so that the self-locking circuit of the first relay KM1 is disconnected, so that the second normally open contact switch KM1-2 of the first relay is disconnected, and the solenoid valve 8 is powered off The water inlet pipe 7 is closed to automatically add water to the water pool 2 at the bottom of the mountain, reducing manual management.

The above descriptions are only preferred implementations of the present utility model, and the protection scope of the present utility model is not limited to the above-mentioned embodiments, and all technical solutions under the idea of the present utility model all belong to the protection scope of the present utility model. It should be pointed out that for those skilled in the art, some improvements and modifications without departing from the principle of the utility model should also be regarded as the protection scope of the utility model.

Claims (8)

1. a kind of artificial hillock water circulation system, including artificial hillock massif (1) and mountain bottom puddle (2), it is characterised in that：Mountain bottom puddle (2) one side is equipped with water inlet pipe (7), and the water inlet pipe (7) is equipped with solenoid valve (8), detection Gao Shui is equipped in mountain bottom puddle (2) To send the detection device of detection signal, the detection device is electrically connected to control electromagnetism with solenoid valve (8) for position and low water level Valve (8) opens and closes.

2. a kind of artificial hillock water circulation system according to claim 1, it is characterised in that：The detection device includes floating ball group The on-off circuit (10) that part (9) and control solenoid valve (8) open and close, the floating ball component (9) include floating ball (91), are connected to vertically The mobile bar (92) of floating ball (91), the triggering block (93) being arranged in mobile bar (92) and with triggering block (93) inconsistent triggering Trigger switch, the trigger switch include high water level trigger switch (94) and low water level trigger switch (95), the triggering block (93) between high water level trigger switch (94) and low water level trigger switch (95)；The trigger switch and on-off circuit (10) It is electrically connected.

3. a kind of artificial hillock water circulation system according to claim 2, it is characterised in that：The on-off circuit (10) includes the One relay (KM1), the second relay (KM2), the normally opened contact switch (KM1-1) of the first relay, the of the first relay First normally-closed contact of two normally opened contact switch (KM1-2) and the second relay switchs (KM2-1), and the low water level triggering is opened It closes (95) to connect with the first relay (KM1), the first normally opened contact switch (KM1-1) of first relay and the second relay It is in parallel with low water level trigger switch (95) after the first normally-closed contact switch (KM2-1) series connection of device；The high water level trigger switch (94) connect with the second relay (KM2), the second normally opened contact switch (KM1-2) and the solenoid valve (8) of first relay Series connection.

4. a kind of artificial hillock water circulation system according to claim 3, it is characterised in that：The second of first relay is often It opens contact switch (KM1-2) and is in series with work light (P).

5. a kind of artificial hillock water circulation system according to claim 2, it is characterised in that：The mountain bottom puddle (2) one side connects Installation cavity (21) is connected with, the floating ball component (9) is located in installation cavity (21).

6. a kind of artificial hillock water circulation system according to claim 5, it is characterised in that：Peace is equipped in the installation cavity (21) Loading board (23), the mobile bar (92) are interspersed in installing plate (23), and the high water level trigger switch (94) is arranged at installation cavity (21) top, the low water level trigger switch (95) are arranged at installing plate (23).

7. a kind of artificial hillock water circulation system according to claim 5, it is characterised in that：Mountain bottom puddle (2) and installation The connectivity part of chamber (21) is equipped with latticed baffles (22).

8. a kind of artificial hillock water circulation system according to claim 2, it is characterised in that：Counterweight is equipped in the floating ball (91) Block (911).