CN212167858U - Needle tube type artificial rainfall simulation device - Google Patents

Abstract

The utility model provides a needle tubing formula artificial simulation rainfall device, including water supply system, rainfall system, autonomous system, control system, observation system, drainage system and support. The water supply system comprises a water collecting tank, a water inlet pipe of the water collecting tank, a limiting water pipe, a water outlet pipe and a filter; the rainfall system comprises a rainfall system water inlet pipe, a rain box, a shunt cylinder, a shunt pipe and a needle head; the automatic control system comprises two groups of liquid pressurizers and a timing controller; the control system comprises two flowmeters, two control knobs and a flowmeter water inlet pipe; the observation system comprises an organic glass disc with a hole and an electric turntable; the drainage system comprises a water collecting cylinder and a drainage pipe. The device can automatically control the duration of rainfall, the rainfall period and the rainfall frequency, can also accurately simulate the rainfall under the conditions of different rainfall intensities, rainfall capacity, raindrop size, rainfall duration and the like, and has the advantages of automatic control, high accuracy, simple principle and the like.

Description

Needle tube type artificial rainfall simulation device

Technical Field

The utility model belongs to the technical field of the artificial rainfall simulation, concretely relates to needle tubing formula artificial rainfall simulation device.

Background

The artificial rainfall device is used for simulating rainfall, is an ideal test method, is not limited by time and space, reproduces natural rainfall, saves a large amount of manpower and material resources, can repeat the test in a short period, and shortens the test period. Meanwhile, the artificial rainfall device can effectively control rainfall according to the requirement of the test, and the influence of various characteristics (such as rainfall, rainfall intensity, raindrop size and distribution uniformity, rainfall kinetic energy and the like) of the rainfall on the soil property can be researched from multiple aspects.

From the 90 s in the 20 th century, many domestic scholars have developed and introduced artificial rainfall simulation devices and applied to experimental research in the aspects of soil erosion and the like. The current artificial rainfall simulation device is mainly divided into 4 types, namely a nozzle type, a pipe network type, a suspension line type and a needle type, according to the raindrop generation mode, and the characteristics of various types of rainfall devices are different. The nozzle formula is as follows: the water is sprayed out from the spray holes or the nozzles, and is dispersed into water drops with different sizes in the air to fall to the ground, and the formed raindrops have uneven diameters; a pipe network type: small holes are drilled on some parallel thin tubes, and water is sprayed out of the holes to form raindrops, so that the flexibility is poor and the control is inconvenient; a suspension wire type: the water drops leave at the suspension wire terminal with the initial speed of zero and land on the ground, and the raindrops hardly reach the landing terminal speed of natural rainfall; a needle head type: the characteristic is similar to the catenary type, where water droplets fall to the ground through the end of the needle.

Therefore, it is necessary to design an artificial rainfall device which has simple principle, high accuracy, convenient control and is suitable for indoor rainfall test research.

SUMMERY OF THE UTILITY MODEL

Characteristics and not enough to present rainfall device combine the characteristic of natural rainfall, the utility model provides a can automatic control and be suitable for the needle tubing formula artificial rainfall device that the laboratory used, the device can automatic control rainfall duration, rainfall cycle, rainfall number of times, also can the accurate rainfall of simulating under the condition such as different rainfall intensity, rainfall, raindrop size, rainfall duration, but have advantages such as automatic control, the accuracy is high, the principle is simple.

The utility model discloses a solve the technical scheme that the problem that exists adopts as follows:

the utility model provides a needle tubing formula artificial simulation rainfall device which characterized in that: comprises a water supply system, a rainfall system, an automatic control system, a control system, an observation system, a drainage system and a bracket. The water supply system comprises a water collecting tank, a water collecting tank water inlet pipe communicated with the upper surface of a water collecting tank cavity, a limiting water pipe communicated with the limiting height of the side wall of the water collecting tank, a water outlet pipe connected with a water outlet at the bottom of the water collecting tank, a filter A connected to the water collecting tank water inlet pipe and a filter B connected to the water outlet pipe; the rainfall system comprises a rainfall system water inlet pipe and a shunt cylinder connected with the tail end of the rainfall system water inlet pipe, the bottom of the shunt cylinder is connected with a plurality of shunt pipes, the shunt pipes are communicated with the inside of the rain box, and a plurality of needles are arranged at the bottom of the rain box; the automatic control system comprises two groups of liquid pressurizers and a timing controller, one group is arranged on the water inlet pipe of the water collecting tank to realize automatic water supply and interruption of the water collecting tank and play a role of saving water, and the other group is arranged between the water outlet pipe and the water inlet pipe of the flow meter to realize automatic control of the duration of rainfall, the rainfall period and the rainfall times; the control system comprises two flowmeters, two control knobs arranged on the two flowmeters and a flowmeter water inlet pipe; the observation system comprises an organic glass disc with holes and an electric turntable, wherein the observation system comprises an organic glass disc with holes and an electric turntable; the drainage system comprises a water collecting barrel and a drainage pipe which are positioned below the rain box.

The water supply system adopts laboratory running water to supply water, and water pressure is about 0.06MPa, the diameter of header tank is 600mm, highly is 900mm, and header tank height 600mm department is equipped with spacing water pipe to keep water level control at 600mm height.

The rain box is formed by processing organic glass, is cylindrical, has the size of phi 700mm multiplied by 15mm, is provided with a shunt cylinder on the upper surface, is connected with 8 shunt tubes, the other end of the shunt tube is connected to a needle head arrangement area of the rain box, 268 injection needle head sockets are distributed on the lower surface of the rain box, are arranged in a plum blossom shape and have the space of 40mm, the needle head sockets are formed by cutting and installing 2.5ml medical syringe cylinders, and the needle heads adopt industrial glue clamping needle heads; the rain box is arranged on the upper surface of the supporting bracket.

The height of a liquid pressurizer A connected with the water collecting tank in the two groups of liquid pressurizers is lower than the highest point of the water collecting tank, and the height of a liquid pressurizer B connected with the flow meter in the two groups of liquid pressurizers is lower than the height of the water collecting tank by 600 mm.

The highest point of the water inlet pipe of the flowmeter is higher than the 600mm high point of the water collecting tank, and the flowmeters with the measuring ranges of 0-25 mL/min, 25-250 mL/min and 0.25-2L/min are selected according to the rainfall range simulated by the device design to be alternately matched for use.

The organic glass disc is divided into an upper layer and a lower layer, and small holes which are 2mm in diameter, 10mm in distance and arranged in a plum blossom shape are distributed on the upper surface of the disc.

The electric turntable is a BL-130 electric turntable, the rotating speed is 3 min/rotation, the organic glass disc is driven to rotate slowly, and the uniformity of rain on the disc is improved.

The two liquid pressurizers are ORS25-10 type liquid pressurizers, the rated voltage is 220V-50 Hz, the output power is 200W, the lift is 10m, the maximum flow is 90L/min, and the pipe diameter is 20mm (4 minutes).

The two timing controllers adopt KG316T type microcomputer single-phase time control switches, rated voltage is 220V-50 Hz, output power is less than or equal to 3500W, a program can support ten groups of switches every day, and on-off can be set at different time intervals every day, and the setting is performed once and for a long time.

The support includes that the support A is placed to the header tank and support C is placed to the rain box, and support A bottom is for strengthening support bracket B. The upper surface of the support C is hollow, the influence on the rainwater spraying of the needle head at the bottom of the rain box is avoided, and the bottom of the water collecting tank arranged on the support A is higher than the horizontal height of the rain box.

The utility model has the advantages of as follows:

the device can accurately simulate rainfall under the conditions of different rainfall intensities, rainfall capacity, raindrop sizes, rainfall duration and the like indoors; the duration, the rainfall period and the rainfall times of the rainfall can be automatically controlled; manual management is not needed in the rainfall simulation process, so that a large amount of manual management time can be saved; the water can be stopped on time, so that the effects of saving water resources and avoiding waste are achieved; the intelligent control system has the advantages of automatic control, intellectualization, high accuracy, simple principle, easiness in installation and use, energy conservation, environmental protection and the like.

Drawings

FIG. 1 is a schematic structural view of the test apparatus;

FIG. 2 is a schematic view of a stent structure;

FIG. 3 is a top plan view of rack C18-3;

FIG. 4 is a bottom view of the rain box;

wherein: 1-1 parts of a water collecting tank water inlet pipe, 1-2 parts of a water inlet pipe of a flow meter, 1-3 parts of a water inlet pipe of a rainfall system, 2-1 parts of a filter A, 2-2 parts of a filter B, 3-1 parts of a liquid pressurizer A, 3-2 parts of a liquid pressurizer B, 4-1 parts of a timing controller A, 4-2 parts of a timing controller B, 5 parts of a water collecting tank, 6 parts of a limiting water pipe, 7 parts of a water outlet pipe, 8 parts of a control knob, 9 parts of a flow meter, 10 parts of a flow distributing cylinder, 11 parts of a flow distributing cylinder, 12 parts of a rain box, 13 parts of a needle, 14 parts of an organic glass disc, 15 parts of an electric rotating disc, 16 parts of a water collecting cylinder, 17 parts of a water outlet pipe, 18-1 parts.

Detailed Description

The technical solution of the present invention will be further described in detail by the following embodiments with reference to the accompanying drawings, and the structure of the present invention is shown in fig. 1. The utility model discloses the structure includes water supply system, rainfall system, autonomous system, control system, observation system, drainage system and support. The water supply system comprises a water collecting tank 5, a water inlet pipe 1-1 of the water collecting tank, a limiting water pipe 6, a filter A2-1 connected with the water inlet pipe 1-1 of the water collecting tank and a filter B2-2 connected with a water outlet pipe 7, and has the main functions of collecting water flow of the water inlet pipe 1-1 of the water collecting tank, limiting the water level in the water collecting tank 5 to be at a fixed height through the limiting water pipe 6, and enabling the water pressure of the water flow flowing through the water outlet pipe 7 to be constant; the rainfall system comprises water inlet pipes 1-3, a rain box 12, a shunt cylinder 10, shunt pipes 11 and needles 13, and is a raindrop generating part which is used for uniformly shunting water flow of the water inlet pipes 1-3 to the needles 11 to generate raindrops; the automatic control system comprises a liquid pressurizer A3-1 and a timing controller A4-1 which are connected with a filter A2-1, a liquid pressurizer B3-2 and a timing controller B4-2 which are connected with a filter B2-2, wherein the liquid pressurizer A3-1 and the timing controller A4-1 realize automatic water supply and water cut-off of the water collecting tank to play a role in saving water, and the timing controller B2-2 realize automatic control of the duration of rainfall, the rainfall period and the rainfall times; the control system comprises two flowmeters 9 and two control knobs 8, and is used for controlling water pressure and adjusting rainfall intensity; the observation system comprises a perforated organic glass disc 14 and an electric rotating disc 15, which is a rain-receiving part and also a platform for collecting raindrops and carrying out device experiment application; the drainage system comprises a water collecting cylinder 16 and a drainage pipe 17, and is used for collecting and draining rainwater and is also used as a collecting part for test flushing matters such as soil erosion; the auxiliary equipment is a three-dimensional detachable support and is used for fixing and adjusting the levelness and the height of the device.

The water supply system adopts tap water in a laboratory to supply water, and the water pressure is about 0.06 MPa. The diameter of the water collecting tank 5 is 600mm, and the height is 900 mm; a limiting water pipe 6 is arranged at the position of the water collecting tank with the height of 600mm so as to keep the water level controlled at the height of 600 mm; the water collecting tank 5 is placed in the bracket a 18-1. The rain box 12 is formed by processing organic glass, is cylindrical, has the size phi of 700mm multiplied by 15mm, is provided with a shunt tube 10 on the upper surface, the shunt tube 10 is connected with 8 shunt tubes 11, the other ends of the shunt tubes 11 are connected to a needle head arrangement area of the rain box 12, 268 injection needle head 13 sockets are distributed on the lower surface of the rain box 12, the distance is 40mm, the sockets are arranged in a plum blossom shape, the needle head 13 sockets are formed by cutting and installing a 2.5ml medical syringe needle cylinder, and the needle head 13 adopts an industrial glue clamping needle head; the rain box 12 is placed on the top upper surface of the rack C18-3. The liquid pressurizer a3-1 connected to the water collecting tank 5 is lower in height than the highest point of the water collecting tank 5. The highest point of the water inlet pipe 1-2 of the flowmeter is higher than the position of the water collecting tank 5 by 600 mm. The liquid pressurizer B3-2 connected with the flowmeter 9 is lower than the water collecting tank 5 by 600 mm. The rainfall capacity range selection range simulated according to the device design is as follows: 0-25 mL/min, 25-250 mL/min, 0.25-2L/min are alternatively matched. The organic glass rotary table 14 is divided into an upper layer and a lower layer, and small holes with the diameter of 2mm and the interval of 10mm and arranged in a plum blossom shape are distributed on the upper surface of the rotary table 14 and used for simulating the permeability of soil. The electric rotating disk 15 adopts a BL-130 electric rotating disk, the rotating speed is 3 min/rotation, the organic glass disk is driven to slowly rotate, and the uniformity of the disk subjected to rain is improved. The liquid pressurizer A3-1 and the liquid pressurizer B3-2 both adopt ORS25-10 type liquid pressurizers, the rated voltage is 220V-50 Hz, the output power is 200W, the lift is 10m, the maximum flow is 90L/min, and the pipe diameter is 20mm (4 minutes). The timing controller A4-1 and the timing controller B4-2 adopt KG316T microcomputer single-phase time control switches, the rated voltage is 220V-50 Hz, the output power is less than or equal to 3500W, and the program can support ten groups of switches per day. The support adopts a three-dimensional detachable stable triangular steel frame structure and is formed by assembling three parts, and the specific size is shown in figure 2.

The utility model discloses a theory of operation: connecting a water inlet pipe 1-1 to a tap water faucet, opening and controlling the faucet, forming a stable water head height by using tap water pressure, controlling the water head height to be more than a liquid pressurizer A3-1 connected with a water collecting tank 5 and below the highest position of the water collecting tank 5, setting a timing controller A4-1 of the liquid pressurizer A3-1 according to test requirements, automatically opening the liquid pressurizer A3-1 on time to enable water to flow into the water collecting tank, raising the water level in the water collecting tank until water flows out of a limiting water pipe, and keeping the water level height in the water collecting tank constant at 600mm at the moment. The fixed water head height in the water collecting tank generates fixed water pressure, so that the water level in a water inlet pipe 1-2 of the flowmeter is kept constant, the water level is higher than a liquid pressurizer B3-2 connected with the water collecting tank, water flow does not flow into the flowmeter 9, a timing controller B4-2 of a liquid pressurizer B3-2 is set according to test requirements, the liquid pressurizer B3-2 is automatically opened on time, the water flow is pressurized to flow into the flowmeter 9, the flow is controlled through the flowmeter 9, the water flow is divided into 8 branches after passing through the flow dividing cylinder 10 and uniformly flows into the rain box 12, rain drops are formed through an industrial glue clamping needle head 13, organic glass falls on a perforated disc 14 which rotates slowly, and the rainfall simulation process is carried out. The timing controller A4-1 and the timing controller B4-2 automatically control the on-off of the liquid pressurizer A3-1 and the liquid pressurizer B3-2 according to the set time, and the automatic operation of the rainfall simulation device is realized.

The utility model discloses a method of use specifically as follows:

installing a test device: installing the bracket according to the structural schematic diagram (figure 2) of the bracket; the water collecting tank 5 is placed in the bracket A18-1; connecting one end of a water inlet pipe 1-1 of the water collecting tank with a laboratory faucet, placing one end of the water inlet pipe in the water collecting tank 5 through a filter A2-1 and a liquid pressurizer A3-1, wherein the height of the liquid pressurizer A3-1 is lower than the highest position of the water collecting tank 5; one end of the limiting water pipe 6 is arranged at a fixed position of the water collecting tank 5 with the height of 600mm, and the other end is grounded; the water outlet pipe 7 of the water collecting tank is sequentially communicated with the water outlet pipe 7, a filter 2-2, a liquid pressurizer B3-2 and two flowmeters 9, the height of the liquid pressurizer B3-2 is lower than the fixed position of the water collecting tank 5 with the height of 600mm, and the highest position of the water inlet pipe 1-2 of the flowmeter is higher than the fixed position of the water collecting tank 5 with the height of 600 mm; placing a rain box 12 on the upper surface of the top of a support C18-3, connecting a flowmeter 9 with a rain box shunt cylinder 10 through a water inlet pipe 1-3, and connecting the shunt cylinder 10 with the rain box 12 through eight shunt pipes 11; a timing controller A4-1 and a timing controller B4-2 are respectively arranged on the liquid pressurizer A3-1 and the liquid pressurizer B3-2; selecting a needle 13 according to test requirements, and inserting the needle into a fixed injection needle socket; the observation system and the drainage system are arranged in the bracket C18-3, and the organic glass disc 14 and the electric rotating disc 15 are sequentially arranged in the water collecting cylinder 16 from top to bottom; the drain pipe 17 of the drainage system is connected with a floor drain.

The specific use method comprises the following steps: before the test is started, all valves are kept in a closed state, and the rainfall height is adjusted according to the test requirement; selecting an industrial glue clamping needle head meeting the requirements according to the test requirements; turning on a switch of the electric turntable 14 according to test requirements to enable the turntable 14 to work stably; opening and adjusting a tap switch at the tail end of the water inlet pipe 1-1, forming a stable water head height in the water inlet pipe 1-1 by using the water pressure of tap water, wherein the water head height is controlled to be more than a liquid pressurizer 3-1A connected with the water inlet pipe and below the highest point of a water collecting tank 5; setting a timing controller A4-1 on the liquid pressurizer A3-1 according to test requirements, automatically opening the liquid pressurizer 3-1 connected with the water inlet pipe 1-1 on time to enable water to flow into the water collecting tank 5, enabling the water level in the water collecting tank 5 to rise until water flows out of the limiting water pipe 6, and keeping the water level height in the water collecting tank 5 constant at 600mm, so that the water level in the water inlet pipe 1-2 of the flowmeter is kept constant, the water level height is higher than that of the liquid pressurizer 3-2, and the water does not flow into the flowmeter 9; then, a timing controller B4-2 on the liquid pressurizer B3-2 is set according to test requirements, the liquid pressurizer B3-2 is automatically turned on at regular time, water flows into the flowmeter 9, the flow is controlled by the control knob 8, the water flow is divided into eight branches after passing through the flow dividing cylinder 10 and uniformly flows into the rain box 12, raindrops are formed by the industrial glue clamping needle head 13 and drop on a sample placed on the organic glass disc 14, and the rainfall simulation process is carried out. The timing controller A4-1 and the timing controller B4-2 automatically control the on-off of the liquid pressurizer A3-1 and the liquid pressurizer B3-2 according to the set time respectively, and the automatic operation of the rainfall simulation device is realized.

The utility model discloses a method of contrast combines analysis software such as IPP, Origin, has carried out test and calibration test to the rainfall device. The results show that: when the rainfall height is 1.6m, the rainfall coverage area of the device is 196250mm²The rainfall intensity range is 0-15 mm/h, the raindrop particle size is 0-10 mm, and the rainfall uniformity is more than 90%. Compared with natural rainfall, the simulated rainfall generated by the device is more stable and reliable, and errors of related experimental research can be reduced.

The scope of the present invention is not limited to the above-described embodiments, and it is apparent that those skilled in the art can make various modifications and variations to the present invention without departing from the scope and spirit of the present invention. It is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

Claims (10)

1. The utility model provides a needle tubing formula artificial simulation rainfall device which characterized in that: the automatic rainfall monitoring device comprises a water supply system, a rainfall system, an automatic control system, a control system, an observation system, a drainage system and a support, wherein the water supply system comprises a water collecting tank, a water collecting tank water inlet pipe communicated with the upper surface of a cavity of the water collecting tank, a limiting water pipe communicated with the limiting height position of the side wall of the water collecting tank, a water outlet pipe connected with a water outlet at the bottom of the water collecting tank, a filter A connected to the water collecting tank water inlet pipe and a filter B connected to the water outlet; the rainfall system comprises a rainfall system water inlet pipe and a shunt cylinder connected with the tail end of the rainfall system water inlet pipe, the bottom of the shunt cylinder is connected with a plurality of shunt pipes, the shunt pipes are communicated with the inside of the rain box, and a plurality of needles are arranged at the bottom of the rain box; the automatic control system comprises two groups of liquid pressurizers and a timing controller, one group is arranged on the water inlet pipe of the water collecting tank to realize automatic water supply and interruption of the water collecting tank and play a role of saving water, and the other group is arranged between the water outlet pipe and the water inlet pipe of the flow meter to realize automatic control of the duration of rainfall, the rainfall period and the rainfall times; the control system comprises two flowmeters, two control knobs arranged on the two flowmeters and a flowmeter water inlet pipe; the observation system comprises an organic glass disc with holes and an electric turntable, wherein the observation system comprises an organic glass disc with holes and an electric turntable; the drainage system comprises a water collecting barrel and a drainage pipe which are positioned below the rain box.

2. The needle tube type artificial rainfall simulation device of claim 1, wherein: the water supply system adopts laboratory running water to supply water, and water pressure is about 0.06MPa, the diameter of header tank is 600mm, highly is 900mm, and header tank height 600mm department is equipped with spacing water pipe to keep water level control at 600mm height.

3. The needle tube type artificial rainfall simulation device of claim 1, wherein: the rain box is formed by processing organic glass, is cylindrical, has the size of phi 700mm multiplied by 15mm, is provided with a shunt cylinder on the upper surface, is connected with 8 shunt tubes, the other end of the shunt tube is connected to a needle head arrangement area of the rain box, 268 injection needle head sockets are distributed on the lower surface of the rain box, are arranged in a plum blossom shape and have the space of 40mm, the needle head sockets are formed by cutting and installing 2.5ml medical syringe cylinders, and the needle heads adopt industrial glue clamping needle heads; the rain box is arranged on the upper surface of the supporting bracket.

4. The needle tube type artificial rainfall simulation device of claim 1, wherein: the height of a liquid pressurizer A connected with the water collecting tank in the two groups of liquid pressurizers is lower than the highest point of the water collecting tank, and the height of a liquid pressurizer B connected with the flow meter in the two groups of liquid pressurizers is lower than the height of the water collecting tank by 600 mm.

5. The needle tube type artificial rainfall simulation device of claim 1, wherein: the highest point of the water inlet pipe of the flowmeter is higher than the 600mm high point of the water collecting tank, and the flowmeters with the measuring ranges of 0-25 mL/min, 25-250 mL/min and 0.25-2L/min are selected according to the rainfall range simulated by the device design to be alternately matched for use.

6. The needle tube type artificial rainfall simulation device of claim 1, wherein: the organic glass disc is divided into an upper layer and a lower layer, and small holes which are 2mm in diameter, 10mm in distance and arranged in a plum blossom shape are distributed on the upper surface of the disc.

7. The needle tube type artificial rainfall simulation device of claim 1, wherein: the electric turntable is a BL-130 electric turntable, the rotating speed is 3 min/rotation, the organic glass disc is driven to rotate slowly, and the uniformity of rain on the disc is improved.

8. The needle tube type artificial rainfall simulation device of claim 1, wherein: the two liquid pressurizers are ORS25-10 type liquid pressurizers, the rated voltage is 220V-50 Hz, the output power is 200W, the lift is 10m, the maximum flow is 90L/min, and the pipe diameter is 20 mm.

9. The needle tube type artificial rainfall simulation device of claim 1, wherein: the two timing controllers adopt KG316T type microcomputer single-phase time control switches, rated voltage is 220V-50 Hz, output power is less than or equal to 3500W, a program can support ten groups of switches every day, and on-off can be set at different time intervals every day, and the setting is performed once and for a long time.

10. The needle tube type artificial rainfall simulation device of claim 1, wherein: the support includes that the header tank places support A and rain box places support C, and support A bottom is for strengthening support bracket B, and support C upper surface cavity does not spray the rainwater to rain box bottom syringe needle and causes the influence, and the bottom of the header tank of putting on support A highly is higher than rain box level.

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