CN105158440A - Indoor frozen soil water migration rule simulating system and characteristic parameter measuring method - Google Patents

Abstract

The invention discloses an indoor frozen soil water migration rule simulating system. The indoor frozen soil water migration rule simulating system comprises a simulating system box, a frozen soil water migration law characteristic parameter measuring system, a test data acquiring and controlling device, a chilling and heating all-in-one machine, a snowfall simulating system, a geologic model system and a solar radiant heat simulating system; the snowfall simulating system comprises a snowfall groove, a fixing support and a plurality of snowfall point simulating mechanisms; the geologic model system comprises a base, a geologic model groove, a longitude and latitude grating plate and a ceramic plate; the solar radiant heat simulating system comprises an electric heating tube, an electric heating tube front-back moving mechanism and an electric heating tube left-right moving mechanism; and the frozen soil water migration law characteristic parameter measuring system comprises a soil temperature and moisture content measuring system, a snowfall runoff volume measuring system and a snowfall diffluent volume measuring system. The invention also discloses a method for measuring characteristic parameters of an indoor frozen soil water migration rule. The indoor frozen soil water migration rule simulating system is convenient to operate, provides a way for studying the frozen soil water migration rule under the condition of snowfall, and is high in practicability.

Description

Indoor frozen soil Moisture Transfer Rule simulation system and characteristic parameter assay method

Technical field

The invention belongs to Geotechnical Engineering field, be specifically related to a kind of indoor frozen soil Moisture Transfer Rule simulation system and characteristic parameter assay method.

Background technology

The duration being in frozen state according to the soil body is different, and frozen soil can be divided into seasonal frozen ground and ever frost.Frozen soil is extensively distributed in epidermic one cryogenically plastid, and permafrost region has abundant soil, forest and mining deposits, its existence and develop living environment to the mankind, activity in production and sustainable development and have material impact.

Water translocation in current frozen soil (comprising frozen soil and positive frozen soil), be regarded as the active key problem of freezing soil, be put into one of the principles of science of the subjects such as civil engineering work, agricultural and geology respectively, and as the important subject of in soil science, environmental science, architecture and geography, be subject to the attention of many countries in the world.

Freezing of soil, causes moisture to move to Zheng Dong district and attempts this region of form filling with ice.In the low compressibility soil body, these ice bodies are arranged in the lensing paralleled with isotherm usually.In the high-compressibility soil body, usually form netted in staggered ice vein at three dimensions.Due to the reduction of soil body surface temperature, energy equilibrium in the soil body before not freezing is broken, except the migration causing moisture, also the redistribution of temperature in soil is caused, and produce the concentration gradient of salinity in soil, salinity also redistributes simultaneously, thus the solid-liquid vapour assembled state causing space brand-new.

As can be seen here, the research of frozen soil Moisture Transfer Rule is most important.At present, people have carried out a large amount of subject studies had about rainfall infiltration, and are scarcely out of swaddling-clothes for the research of the frozen soil Moisture Transfer Rule occurred after snowfall.Because the frozen soil Moisture Transfer Rule occurred after rainfall infiltration and snowfall exists bigger difference, be in particular in the following aspects: the temperature of 1. infiltrating is different, the frozen soil water translocation occurred after snowfall occurs at low ambient temperatures, and rainfall infiltration then carries out at normal temperature; 2. infiltrate influence factor difference, the frozen soil water translocation principal element occurred after snowfall is temperature, and rainfall infiltration is not then; The mechanism of 3. infiltrating is different, the frozen soil water translocation occurred after snowfall to infiltrate mechanism more complicated, research difficulty is larger, and rainfall infiltration is compared comparatively simple.Also there is no the system can carrying out the simulation of frozen soil Moisture Transfer Rule easily in indoor in prior art, the mensuration of frozen soil Moisture Transfer Rule characteristic parameter can not be carried out well in indoor.

Summary of the invention

Technical matters to be solved by this invention is for above-mentioned deficiency of the prior art, provide a kind of compact conformation, novel in design rationally, realize convenient, use easy to operate, provide feasible indoor frozen soil Moisture Transfer Rule simulation system for frozen soil Moisture Transfer Rule under research snowfall condition further.

For solving the problems of the technologies described above, the technical solution used in the present invention is: a kind of indoor frozen soil Moisture Transfer Rule simulation system, it is characterized in that: comprise simulation system casing, frozen soil Moisture Transfer Rule characteristic parameter measuring system and Test Data Collecting and controller, and be arranged on the cold-hot integrated machine of simulation system box house, Simulation of Snowfall system, geologic model system and solar radiant heat simulation system;

Described Simulation of Snowfall system comprises the snowfall groove embedding and be arranged on simulation system casing top, be arranged on the fixed support in snowfall groove and embed the multiple snowfall point simulation mechanisms be arranged on fixed support, each described snowfall point simulation mechanism includes the ice storage cylinder of all uncovered setting in top and bottom and is arranged on the open seal cover at ice storage cylinder top, the bottom of described ice storage cylinder is provided with cross-shaped strut, the center of described cross-shaped strut is provided with snowfall motor, the output shaft of described snowfall motor is fixedly connected with rotary cutting skates, the inner bottom surface of described open seal cover is connected with the anti-bull stick of ice cube, the anti-bull stick of described ice cube is set with the pressure spring for being pressed on by ice cube on rotary cutting skates, the shape of the anti-bull stick xsect of described ice cube is rectangle, described ice cube has to penetrate for ice cube anti-bull stick and with the close-fitting cylinder hole of the anti-bull stick of ice cube, the bottom of described snowfall groove is provided with the vibratory screening apparatus cutting the snowflake fallen for vibrating landing rotary cutting skates, the top of any one the ice storage cylinder in multiple ice storage cylinder is provided with ultrasonic distance-measuring sensor,

Described geologic model system is comprised base and is supported the geologic model groove be arranged on base by multiple lifting jack, the bottom of described geologic model groove is provided with the longitude and latitude flase floor for forming water space at geologic model groove inner bottom part, described longitude and latitude flase floor is provided with multiple water outlet hole, the top of described longitude and latitude flase floor is provided with pottery clay plates, the surrounding of described pottery clay plates is along all bonding with geologic model groove inwall, and the top of described pottery clay plates is for placing test soil sample;

Described solar radiant heat simulation system comprises for the electrothermal tube of simulated solar illumination, seesaw for the electrothermal tube driving electrothermal tube to seesaw in simulation system casing mechanism and for driving the electrothermal tube side-to-side movement mechanism of electrothermal tube side-to-side movement in simulation system casing, described electrothermal tube is arranged between described geologic model system and described Simulation of Snowfall system, and the side of described electrothermal tube is provided with for carrying out the electrothermal tube temperature sensor detected in real time to the heating-up temperature of electrothermal tube;

Described frozen soil Moisture Transfer Rule characteristic parameter measuring system comprises the soil moisture and measurement of water ratio system, snowfall run-off measuring system and snowfall go out milliosmolarity measuring system, the described soil moisture and measurement of water ratio system comprise point multilayer and are embedded in the multiple soil temperature-moisture sensors tested in soil sample, the quantity of every layer of described soil temperature-moisture sensor is multiple, in each layer, multiple described soil temperature-moisture sensor is that square net is evenly laid, and in multilayer, the multiple described soil temperature-moisture sensor of adjacent two layers is all laid up and down relatively by equidistant from distance; Described snowfall run-off measuring system comprises snowfall run-off and measures measuring cup and be arranged on multiple snowfall run-off measured holes of geologic model groove side, and the snowfall run-off measurement be connected on described snowfall run-off measured hole is in charge of and be in charge of to be connected and to access the snowfall run-off that snowfall run-off measures in measuring cup with the measurement of snowfall run-off and measure house steward; Described snowfall goes out milliosmolarity measuring system and comprises snowfall and go out milliosmolarity and measure measuring cup and the multiple snowfalls be arranged in geologic model groove bottom and go out milliosmolarity measured hole, and be connected to the described snowfall snowfall gone out on milliosmolarity measured hole and go out milliosmolarity measurement and be in charge of and go out milliosmolarity measurement with snowfall and be in charge of and be connected and access snowfall to go out the milliosmolarity snowfall of measuring in measuring cup and go out milliosmolarity and measure house steward, described snowfall goes out milliosmolarity and measures on house steward and be provided with for carrying out the flow sensor detected in real time to the flow melting water oozing out test soil sample;

Described Test Data Collecting and controller comprise microcontroller and connect with microcontroller and serial communication circuit for being connected with computing machine, the output terminal of described microcontroller is connected to liquid crystal display and for driving the first motor driver of snowfall motor, described ultrasonic distance-measuring sensor, flow sensor, electrothermal tube temperature sensor are all connected with the input end of microcontroller with multiple soil temperature-moisture sensor.

Above-mentioned indoor frozen soil Moisture Transfer Rule simulation system, it is characterized in that: described rotary cutting skates comprise discoidal cut skates body and be evenly arranged on that the many rows cut on skates body outwards disperse from the center of cutting skates body cut ice hole, cut described in each in ice hole and be provided with diamond knife edge.

Above-mentioned indoor frozen soil Moisture Transfer Rule simulation system, is characterized in that: the distance of the bottom of the bottom distance ice storage cylinder of described rotary cutting skates is 2cm ~ 5cm.

Above-mentioned indoor frozen soil Moisture Transfer Rule simulation system, it is characterized in that: the described electrothermal tube mechanism that seesaws comprises electrothermal tube and to seesaw dolly and the door type framework that is arranged on along the fore-and-aft direction of simulation system casing in simulation system casing, described electrothermal tube is suspended on electrothermal tube and seesaws the bottom of dolly, the top of described door type framework is provided with and seesaws guide rail for the seesaw electrothermal tube of carriage walking of electrothermal tube, the side, top of described door type framework is provided with electrothermal tube and seesaws motor, the top opposite side of described door type framework is provided with the first electrothermal tube and seesaws belt wheel, described electrothermal tube seesaw motor output shaft on be connected with the second electrothermal tube and seesaw belt wheel, seesaw belt wheel and described second electrothermal tube of described first electrothermal tube seesaws and belt wheel is connected with electrothermal tube and seesaws belt, described electrothermal tube bottom and the electrothermal tube of the dolly belt that seesaws that seesaws is fixedly connected with, the described electrothermal tube side-to-side movement mechanism left and right directions comprised along simulation system casing is arranged on two electrothermal tube side-to-side movement guide rails of simulation system bottom half, one side bottom of described door type framework is provided with electrothermal tube left and right active movement guide wheel along a wherein electrothermal tube side-to-side movement guide rail movement and the first electrothermal tube side-to-side movement sprocket wheel of being coaxially connected with electrothermal tube left and right active movement guide wheel, the electrothermal tube left and right driven motions guide wheel along another electrothermal tube side-to-side movement guide rail movement is provided with bottom the opposite side of described door type framework, the both sides of the electrothermal tube side-to-side movement guide rail matched with electrothermal tube left and right active movement guide wheel are respectively arranged with electrothermal tube side-to-side movement motor and the second electrothermal tube side-to-side movement sprocket wheel, the output shaft of described electrothermal tube side-to-side movement motor is connected with the 3rd electrothermal tube side-to-side movement sprocket wheel, described first electrothermal tube side-to-side movement sprocket wheel, second electrothermal tube side-to-side movement sprocket wheel and described 3rd electrothermal tube side-to-side movement sprocket wheel are connected with electrothermal tube side-to-side movement chain, the input end of described microcontroller is connected to electrothermal tube side-to-side movement button and electrothermal tube and seesaws button, the output terminal of described microcontroller is connected to for driving the second motor driver of electrothermal tube side-to-side movement motor, for driving electrothermal tube to seesaw the 3rd motor driver of motor and the relay for controlling electrothermal tube power on/off, the coils connected in series of described relay is in the current supply circuit of electrothermal tube.

Above-mentioned indoor frozen soil Moisture Transfer Rule simulation system, it is characterized in that: the seesaw rear and front end of guide rail of described electrothermal tube is respectively arranged with limit switch after electrothermal tube front limit switch and electrothermal tube, the two ends, left and right of the electrothermal tube side-to-side movement guide rail matched with electrothermal tube left and right driven motions guide wheel are respectively arranged with electrothermal tube left limit switch and electrothermal tube right limit switch, and after described electrothermal tube front limit switch, electrothermal tube, limit switch, electrothermal tube left limit switch are all connected with the input end of microcontroller with electrothermal tube right limit switch.

Above-mentioned indoor frozen soil Moisture Transfer Rule simulation system, it is characterized in that: in each layer, multiple described soil temperature-moisture sensor is that the square net of 1m × 1m is evenly laid, and in multilayer, the multiple described soil temperature-moisture sensor of adjacent two layers is all laid up and down relatively by the equidistant from distance of 0.5m.

Present invention also offers that a kind of method step is simple, complete function, the indoor frozen soil Moisture Transfer Rule characteristic parameter assay method that practical, result of use is good, it is characterized in that the method comprises the following steps:

Step one, build geologic model: operate multiple lifting jack, after making geologic model groove be in horizontal positioned, test soil sample layering is filled into the top of pottery clay plates in geologic model groove, and carry out soil sample and ram and fill; Then, then operate multiple lifting jack, the gradient of adjustment geologic model groove is the test gradient;

Step 2, assembling snowfall point simulation mechanism: ice cube is put into ice storage cylinder, anti-for ice cube bull stick is inserted in cylinder hole, and open seal cover is connected to ice storage cylinder top; Described ice cube is cylindrical ice cube;

Step 3, optimum configurations: input total snowfall Q on computers _zwith electrothermal tube heating-up temperature T ₃, computing machine is according to formula calculate the falling head limit value h of single ice cube ₀, and by the falling head limit value h of serial communication circuit by single ice cube ₀with electrothermal tube heating-up temperature T ₃be transferred to microcontroller; Wherein, S is the cross-sectional area of single ice cube, and n is the quantity of ice cube;

Step 4, measure test soil sample freeze before initial aqueous rate: multiple soil temperature-moisture sensor carries out one-time detection to the temperature and humidity of test soil sample respectively and the temperature signal of the multiple test point places detected test soil samples and moisture signal is transferred to microcontroller, the temperature signal of the multiple test point places test soil samples that microcontroller is received again and moisture signal by serial communication circuit real-time Transmission to computing machine, computing machine receives and records temperature signal and the moisture signal of multiple test point place test soil sample, and by each test point place test soil sample moisture signal be recorded as each test point place test soil sample freeze before initial aqueous rate θ _o,

Step 5, simulation frozen soil environment and measure test soil sample freeze before valley water percentage: regulate the temperature of cold-hot integrated machine to be frozen soil environment temperature T ₄, the temperature in simulation system casing declines gradually and reaches frozen soil environment temperature T ₄process in, multiple soil temperature-moisture sensor carries out periodically detecting to the temperature and humidity of test soil sample respectively and the temperature signal of the multiple test point place test soil samples detected and moisture signal is transferred to microcontroller, the temperature signal of the multiple test point places test soil samples that microcontroller is received again and moisture signal by serial communication circuit real-time Transmission to computing machine, computing machine receives and records temperature signal and the moisture signal of each sampling instant multiple test point place test soil sample, and the humidity of each multiple sampling instant in test point place is arranged from big to small, and each test point place is arranged in last humidity value be recorded as this test point place test soil sample freeze before valley water percentage θ _v,

Step 6, carry out Simulation of Snowfall and measure test soil sample freeze after stable aqueous rate: regulate the temperature of cold-hot integrated machine to be snowfall temperature T ₁after, operation computing machine, start snowfall pattern, computing machine sends the signal of snowfall pattern startup to microcontroller by serial communication circuit, microcontroller drives snowfall electric machine rotation by the first motor driver, snowfall driven by motor rotary cutting skates rotate, cutting ice cube produces snowfall, in snowfall, ultrasonic distance-measuring sensor detects the falling head of ice storage cylinder ice cube described in one of them and in real time by the falling head real-time Transmission of ice cube that detects to microcontroller, the falling head of the ice cube that microcontroller is received and the falling head limit value h of single ice cube ₀compare, when the falling head of ice cube reaches the falling head limit value h of single ice cube ₀time, microcontroller drives snowfall motor stalls by the first motor driver, and total snowfall now reaches Q _z, simultaneously, in snowfall, multiple soil temperature-moisture sensor carries out periodically detecting to the temperature and humidity of test soil sample respectively and the temperature signal of the multiple test point place test soil samples detected and moisture signal is transferred to microcontroller, the temperature signal of the multiple test point places test soil samples that microcontroller is received again and moisture signal by serial communication circuit real-time Transmission to computing machine, computing machine receives and records temperature signal and the moisture signal of each sampling instant multiple test point place test soil sample, and the humidity of each multiple sampling instant in test point place is arranged according to time order and function order, when the humidity differences of adjacent two sampling instants is less than or equal to 1%, illustrate that the humidity of this test point place test soil sample is stable, the humidity value of a rear sampling instant in adjacent two sampling instants is recorded as this test point place test soil sample freeze after stable aqueous rate θ _f,

Step 7, carry out solar radiation thermal simulation: regulate the temperature of cold-hot integrated machine to be that temperature T is infiltrated in snowfall ₂after, operation computing machine, start snowfall and infiltrate pattern, computing machine by serial communication circuit send snowfall infiltrate pattern start signal to microcontroller, the current supply circuit of electrothermal tube connected by microprocessor controls relay, and electrothermal tube starts heating, in electrothermal tube heating process, electrothermal tube temperature sensor detects the heating-up temperature of electrothermal tube and in real time by the signal real-time Transmission that detects to microcontroller, the heating-up temperature detected value that microcontroller is received and electrothermal tube heating-up temperature T ₃compare, when heating-up temperature detected value reaches electrothermal tube heating-up temperature T ₃time, microprocessor controls relay disconnects the current supply circuit of electrothermal tube, and electrothermal tube stops heating, when heating-up temperature detected value is lower than electrothermal tube heating-up temperature T ₃time, the current supply circuit of electrothermal tube connected by microprocessor controls relay, and electrothermal tube starts heating, thus makes the heating-up temperature of electrothermal tube remain T ₃; In electrothermal tube heating process, press electrothermal tube side-to-side movement button or electrothermal tube and seesaw after button, the side-to-side movement or seesaw in simulation system casing of microprocessor controls electrothermal tube, carries out solar radiation thermal simulation;

Step 8, carry out snowfall infiltrate observe and measure test soil sample melt after stable aqueous rate and the peak value water percentage of test soil sample when melting: the electrothermal tube heating in step 7 makes in the snowfall ablation procedure in step 6, and the water that melts in non-infiltration test soil sample flows out and is in charge of through measurements of too much root snowfall run-off and flows in snowfall run-off measurement measuring cup with snowfall run-off measurement house steward in multiple described snowfall run-off measured hole, the water that melts oozed out in test soil sample goes out in milliosmolarity measured hole to flow out from multiple described snowfall and goes out milliosmolarity measurements through too much root snowfall to be in charge of to go out milliosmolarity with snowfall and measure house steward and flow into snowfall and go out in milliosmolarity measurement measuring cup, simultaneously, multiple soil temperature-moisture sensor carries out periodically detecting to the temperature and humidity of test soil sample respectively and the temperature signal of the multiple test point place test soil samples detected and moisture signal is transferred to microcontroller, the temperature signal of the multiple test point places test soil samples that microcontroller is received again and moisture signal by serial communication circuit real-time Transmission to computing machine, computing machine receives and records temperature signal and the moisture signal of each sampling instant multiple test point place test soil sample, and the humidity of each multiple sampling instant in test point place is arranged according to time order and function order, when the humidity differences of adjacent two sampling instants is less than or equal to 1%, illustrate that the humidity of this test point place test soil sample is stable, the humidity value of a rear sampling instant in adjacent two sampling instants is recorded as this test point place test soil sample melt after stable aqueous rate θ _e, and computing machine also arranges from big to small to the humidity of each multiple sampling instant in test point place, and each test point place is arranged in the most front humidity value and is recorded as peak value water percentage θ when this test point place test soil sample melts _p, simultaneously, flow sensor carries out periodically detecting and the signal detected being exported to microcontroller to the discharge that melts of oozing out test soil sample, the discharge that melts of test soil sample that what microcontroller was received ooze out is transferred to computing machine by serial communication circuit, and computing machine calls flow curve drafting module and draws out the curve melting discharge t change in time oozing out test soil sample, check the display curve melting discharge t change in time oozing out test soil sample on computers, when ooze out test soil sample melt discharge in time t change curve tends in straight line time, illustrate that snowfall is infiltrated stable, now, check that snowfall run-off measures the amount melting water in measuring cup in non-infiltration test soil sample, and be snowfall run-off Q by this read-record _j, check that snowfall goes out milliosmolarity and measures in measuring cup the amount melting water of oozing out in test soil sample, and be that snowfall goes out milliosmolarity Q by this read-record _c,

Step 9: frozen soil Moisture Transfer Rule snowfall Infiltration characteristics parameter calculates, and detailed process is:

Step 701, according to formula Q _r=Q _z-Q _j, calculate snowfall infiltration capacity Q _r;

Step 702, according to formula Δ S=Q _r-Q _ccalculate water deficit amount Δ S;

Step 703, according to formula calculate snowfall infiltration rate V _r;

Step 704, according to formula calculate snowfall to go out to ooze rate V _c;

Step 705, according to formula calculate snowfall infiltrated water α;

In step 703 and step 704, t is the time.

Above-mentioned method, it is characterized in that: in step 7, press electrothermal tube side-to-side movement button or electrothermal tube to seesaw button, make electrothermal tube side-to-side movement or seesaw in simulation system casing, the detailed process of carrying out solar radiation thermal simulation is: when pressing electrothermal tube side-to-side movement button, microcontroller drives electrothermal tube side-to-side movement electric machine rotation by the second motor driver, 3rd electrothermal tube side-to-side movement sprocket rotation described in electrothermal tube side-to-side movement driven by motor, described 3rd electrothermal tube side-to-side movement sprocket wheel is by electrothermal tube side-to-side movement chain-driving first electrothermal tube side-to-side movement sprocket rotation, first electrothermal tube side-to-side movement sprocket wheel drives active movement guide wheel in electrothermal tube left and right to rotate, active movement guide wheel in electrothermal tube left and right drives edge, a side wherein electrothermal tube side-to-side movement guide rail movement of door type framework, simultaneously, electrothermal tube left and right driven motions guide wheel drives the opposite side of door type framework driven along another electrothermal tube side-to-side movement guide rail, door type frame strip electro kinetic potential pipe seesaws dolly side-to-side movement in simulation system casing, the electrothermal tube dolly that seesaws drives electrothermal tube side-to-side movement in simulation system casing, when press electrothermal tube seesaw button time, microcontroller drives electrothermal tube to seesaw electric machine rotation by the 3rd motor driver, electrothermal tube seesaw the second electrothermal tube described in driven by motor seesaw belt wheel rotate, the described second electrothermal tube belt wheel that seesaws drives the described electrothermal tube belt that seesaws to rotate around described second electrothermal tube belt wheel and the first electrothermal tube belt wheel that seesaws that seesaws, the described electrothermal tube belt drive electrothermal tube dolly that seesaws that seesaws seesaws in simulation system casing, electrothermal tube seesaw dolly drive electrothermal tube seesaw in simulation system casing.

Above-mentioned method, is characterized in that: electrothermal tube heating-up temperature T in step 3 ₃value be 20 DEG C ~ 80 DEG C, frozen soil environment temperature T in step 5 ₄value be-20 DEG C ~ 30 DEG C, snowfall temperature T in step 6 ₁value be-25 DEG C ~ 0 DEG C, in step 7, temperature T is infiltrated in snowfall ₂value be-20 DEG C ~ 20 DEG C.

The present invention compared with prior art has the following advantages:

1, the compact conformation of the present invention's indoor frozen soil Moisture Transfer Rule simulation system, rationally novel in design, and it is convenient to realize.

2, adopt the present invention carry out indoor frozen soil Moisture Transfer Rule characteristic parameter measure use easy to operate, method step is simple.

3, the present invention is specially for indoor frozen soil Moisture Transfer Rule characteristic parameter method for measuring under the test apparatus of frozen soil Moisture Transfer Rule simulation indoor under snowfall condition and snowfall condition, different gradient can be studied, different snowfall intensity, frozen soil Moisture Transfer Rule and characteristic parameter under snowfall condition in different soil property under different temperatures (test soil sample freeze before initial aqueous rate, valley water percentage before soil freezing, stable aqueous rate after soil freezing, stable aqueous rate after soil melts, peak value water percentage when soil melts, snowfall run-off, snowfall goes out milliosmolarity, snowfall infiltration capacity, water deficit amount, snowfall infiltration rate, snowfall goes out to ooze rate and snowfall infiltrated water) Changing Pattern, complete function, for frozen soil Moisture Transfer Rule under studying snowfall condition further provides approach.

4, Simulation of Snowfall system of the present invention can control snowfall, by controlling the rotating speed of snowfall motor, can also control snowfall speed.

5, geologic model system of the present invention, by regulating the height of multiple lifting jack, can realize the Work condition analogue of different gradient, better with the consistance of actual tests operating mode.

6, of the present invention practical, result of use is good, is convenient to promote the use of.

In sum, the present invention uses easy to operate, complete function, and for frozen soil Moisture Transfer Rule under studying snowfall condition further provides approach, practical, result of use is good, is convenient to promote the use of.

Below by drawings and Examples, technical scheme of the present invention is described in further detail.

Accompanying drawing explanation

Fig. 1 is the structural representation (not shown solar radiant heat simulation system) of the present invention's indoor frozen soil Moisture Transfer Rule simulation system.

Fig. 2 is cold-hot integrated machine of the present invention, Simulation of Snowfall system and the geologic model system installation position schematic diagram in simulation system casing.

Fig. 3 is the front view that the present invention is provided with the snowfall point simulation mechanism of ultrasonic distance-measuring sensor.

Fig. 4 is the upward view of Fig. 3.

Fig. 5 is the structural representation of geologic model system of the present invention.

Fig. 6 is the structural representation of solar radiant heat simulation system of the present invention.

Fig. 7 is the schematic block circuit diagram of Test Data Collecting of the present invention and controller.

Fig. 8 is the method flow block diagram of the present invention's indoor frozen soil Moisture Transfer Rule characteristic parameter assay method.

Description of reference numerals:

1-simulation system casing; 2-1-fixed support; 2-2-vibratory screening apparatus;

2-3-snowfall groove; 3-snowfall point simulation mechanism; 3-1-open seal cover;

3-2-pressure spring; 3-3-ice storage cylinder; 3-4-rotary cutting skates;

3-41-cut skates body; 3-42-cut ice hole; 3-43-diamond knife edge;

3-5-snowfall motor; 3-6-cross-shaped strut; 3-7-ice cube;

The anti-bull stick of 3-8-ice cube; 3-9-cylinder hole; 3-10-ultrasonic distance-measuring sensor;

4-geologic model groove; 4-1-test soil sample; 4-2-longitude and latitude flase floor;

4-3-pottery clay plates; 5-lifting jack; 6-base;

7-cold-hot integrated machine; 8-computing machine; 9-flow sensor;

10-1-snowfall run-off measurement is in charge of; 10-2-snowfall run-off measures house steward;

10-3-snowfall goes out milliosmolarity measurement and is in charge of; 10-4-snowfall goes out milliosmolarity and measures house steward;

11-snowfall run-off measures measuring cup; 12-snowfall goes out milliosmolarity and measures measuring cup;

13-controller; 13-1-microcontroller;

13-2-serial communication circuit; 13-3-electrothermal tube side-to-side movement button;

13-4-electrothermal tube seesaws button; 13-5-liquid crystal display;

13-6-the first motor driver; 13-7-the second motor driver;

13-8-the 3rd motor driver; 13-9-relay;

14-electrothermal tube; 15-electrothermal tube seesaws dolly;

16-door type framework; 17-electrothermal tube seesaws guide rail;

18-electrothermal tube side-to-side movement guide rail; 19-electrothermal tube side-to-side movement motor;

20-electrothermal tube side-to-side movement chain; 21-the second electrothermal tube side-to-side movement sprocket wheel;

22-electrothermal tube seesaws motor; 23-electrothermal tube seesaws belt;

24-the first electrothermal tube seesaws belt wheel; 25-the first electrothermal tube side-to-side movement sprocket wheel;

26-electrothermal tube left and right active movement guide wheel; 27-electrothermal tube right limit switch;

28-electrothermal tube left limit switch; 29-electrothermal tube temperature sensor;

Limit switch after 30-electrothermal tube; 31-electrothermal tube front limit switch;

32-electrothermal tube left and right driven motions guide wheel; 33-soil temperature-moisture sensor.

Embodiment

As depicted in figs. 1 and 2, indoor frozen soil Moisture Transfer Rule simulation system of the present invention, comprise simulation system casing 1, frozen soil Moisture Transfer Rule characteristic parameter measuring system and Test Data Collecting and controller 13, and be arranged on the cold-hot integrated machine 7 of simulation system casing 1 inside, Simulation of Snowfall system, geologic model system and solar radiant heat simulation system;

As depicted in figs. 1 and 2, described Simulation of Snowfall system comprises the snowfall groove 2-3 embedding and be arranged on simulation system casing 1 top, be arranged on the fixed support 2-1 in snowfall groove 2-3 and embed the multiple snowfall point simulation mechanisms 3 be arranged on fixed support 2-1, as shown in Figure 3 and Figure 4, each described snowfall point simulation mechanism 3 includes the ice storage cylinder 3-3 of all uncovered setting in top and bottom and is arranged on the open seal cover 3-1 at ice storage cylinder 3-3 top, the bottom of described ice storage cylinder 3-3 is provided with cross-shaped strut 3-6, the center of described cross-shaped strut 3-6 is provided with snowfall motor 3-5, the output shaft of described snowfall motor 3-5 is fixedly connected with rotary cutting skates 3-4, rotary cutting skates 3-4 is for supporting and cutting the ice cube 3-7 be placed in ice storage cylinder 3-3, the inner bottom surface of described open seal cover 3-1 is connected with the anti-bull stick 3-8 of ice cube, the anti-bull stick 3-8 of ice cube is used for preventing ice cube 3-7 from rotating with rotary cutting skates 3-4, the anti-bull stick 3-8 of described ice cube is set with the pressure spring 3-2 for being pressed on by ice cube 3-7 on rotary cutting skates 3-4, the shape of described ice cube anti-bull stick 3-8 xsect is rectangle, described ice cube 3-7 has to penetrate for ice cube anti-bull stick 3-8 and with the close-fitting cylinder hole 3-9 of ice cube anti-bull stick 3-8, the bottom of described snowfall groove 2-3 is provided with the vibratory screening apparatus 2-2 cutting the snowflake fallen for vibrating landing rotary cutting skates 3-4, the top of any one the ice storage cylinder in multiple ice storage cylinder 3-3 is provided with ultrasonic distance-measuring sensor 3-10,

As shown in Figure 1, Figure 2 with shown in Fig. 5, described geologic model system is comprised base 6 and is supported the geologic model groove 4 be arranged on base 6 by multiple lifting jack 5, the bottom of described geologic model groove 4 is provided with the longitude and latitude flase floor 4-2 for forming water space at geologic model groove 4 inner bottom part, described longitude and latitude flase floor 4-2 is provided with multiple water outlet hole, the top of described longitude and latitude flase floor 4-2 is provided with pottery clay plates 4-3, the surrounding of described pottery clay plates 4-3 is along all bonding with geologic model groove 4 inwall, and the top of described pottery clay plates 4-3 is for placing test soil sample 4-1; During concrete enforcement, the quantity of described lifting jack 5 is three.During use, by regulating the height of multiple lifting jack 5, the Work condition analogue of different gradient can be realized.

As shown in Figure 6, described solar radiant heat simulation system comprises for the electrothermal tube 14 of simulated solar illumination, seesaw for the electrothermal tube driving electrothermal tube 14 to seesaw in simulation system casing 1 mechanism and for driving the electrothermal tube side-to-side movement mechanism of electrothermal tube 14 side-to-side movement in simulation system casing 1, described electrothermal tube 14 is arranged between described geologic model system and described Simulation of Snowfall system, and the side of described electrothermal tube 14 is provided with for carrying out the electrothermal tube temperature sensor 29 detected in real time to the heating-up temperature of electrothermal tube 14;

As shown in Figure 1, described frozen soil Moisture Transfer Rule characteristic parameter measuring system comprises the soil moisture and measurement of water ratio system, snowfall run-off measuring system and snowfall go out milliosmolarity measuring system, the described soil moisture and measurement of water ratio system comprise point multilayer and are embedded in the multiple soil temperature-moisture sensors 33 tested in soil sample 4-1, the quantity of every layer of described soil temperature-moisture sensor 33 is multiple, in each layer, multiple described soil temperature-moisture sensor 33 is evenly laid in square net, in multilayer, the multiple described soil temperature-moisture sensor 33 of adjacent two layers is all laid up and down relatively by equidistant from distance, described snowfall run-off measuring system comprises multiple snowfall run-off measured holes that snowfall run-off is measured measuring cup 11 and is arranged on geologic model groove 4 side, and the snowfall run-off measurement be connected on described snowfall run-off measured hole is in charge of 10-1 and is in charge of 10-1 with the measurement of snowfall run-off and is connected and accesses the snowfall run-off that snowfall run-off measures in measuring cup 11 and measure house steward 10-2, described snowfall goes out milliosmolarity measuring system and comprises snowfall and go out milliosmolarity and measure measuring cup 12 and the multiple snowfalls be arranged on geologic model groove 4 bottom surface go out milliosmolarity measured hole, and be connected to the described snowfall snowfall gone out on milliosmolarity measured hole and go out milliosmolarity measurement and be in charge of 10-3 and go out milliosmolarity measurement with snowfall and be in charge of 10-3 and be connected and access snowfall to go out the milliosmolarity snowfall of measuring in measuring cup 12 and go out milliosmolarity and measure house steward 10-4, described snowfall goes out milliosmolarity and measures on house steward 10-4 and be provided with for carrying out the flow sensor 9 detected in real time to the flow melting water oozing out test soil sample 4-1,

As shown in Figure 1 and Figure 7, described Test Data Collecting and controller 13 comprise microcontroller 13-1 and connect with microcontroller 13-1 and serial communication circuit 13-2 for being connected with computing machine 8, the output terminal of described microcontroller 13-1 is connected to liquid crystal display 13-5 and for driving the first motor driver 13-6 of snowfall motor 3-5, described ultrasonic distance-measuring sensor 3-10, flow sensor 9, electrothermal tube temperature sensor 29 are all connected with the input end of microcontroller 13-1 with multiple soil temperature-moisture sensor 33.

As shown in Figure 4, in the present embodiment, described rotary cutting skates 3-4 comprise discoidal cut skates body 3-41 and be evenly arranged on that the many rows cut on skates body 3-41 outwards disperse from the center of cutting skates body 3-41 cut ice hole 3-42, cut described in each in the 3-42 of ice hole and be provided with diamond knife edge 3-43.

In the present embodiment, the distance of the bottom of the bottom distance ice storage cylinder 3-3 of described rotary cutting skates 3-4 is 2cm ~ 5cm.The sidewall being positioned at the ice storage cylinder 3-3 of the bottom, bottom of rotary cutting skates 3-4 like this may be used for gear snow, can ensure to cut in snow process snowflake centrifugal phenomenon does not occur.

As shown in Figure 6, in the present embodiment, the described electrothermal tube mechanism that seesaws comprises electrothermal tube and to seesaw dolly 15 and the door type framework 16 that is arranged on along the fore-and-aft direction of simulation system casing 1 in simulation system casing 1, described electrothermal tube 14 is suspended on electrothermal tube and seesaws the bottom of dolly 15, the top of described door type framework 16 is provided with and seesaws guide rail 17 for seesaw electrothermal tube that dolly 15 walks of electrothermal tube, the side, top of described door type framework 16 is provided with electrothermal tube and seesaws motor 22, the top opposite side of described door type framework 16 is provided with the first electrothermal tube and seesaws belt wheel 24, described electrothermal tube seesaw motor 22 output shaft on be connected with the second electrothermal tube and seesaw belt wheel, seesaw belt wheel 24 and described second electrothermal tube of described first electrothermal tube seesaws and belt wheel is connected with electrothermal tube and seesaws belt 23, described electrothermal tube bottom and the electrothermal tube of dolly 15 belt 23 that seesaws that seesaws is fixedly connected with, the described electrothermal tube side-to-side movement mechanism left and right directions comprised along simulation system casing 1 is arranged on two electrothermal tube side-to-side movement guide rails 18 bottom simulation system casing 1, one side bottom of described door type framework 16 is provided with the electrothermal tube left and right active movement guide wheel 26 and the first electrothermal tube side-to-side movement sprocket wheel 25 that be connected coaxial with electrothermal tube left and right active movement guide wheel 26 that move along wherein electrothermal tube side-to-side movement guide rail 18, the electrothermal tube left and right driven motions guide wheel 32 moved along another electrothermal tube side-to-side movement guide rail 18 is provided with bottom the opposite side of described door type framework 16, the both sides of the electrothermal tube side-to-side movement guide rail 18 matched with electrothermal tube left and right active movement guide wheel 26 are respectively arranged with electrothermal tube side-to-side movement motor 19 and the second electrothermal tube side-to-side movement sprocket wheel 21, the output shaft of described electrothermal tube side-to-side movement motor 19 is connected with the 3rd electrothermal tube side-to-side movement sprocket wheel, described first electrothermal tube side-to-side movement sprocket wheel 25, second electrothermal tube side-to-side movement sprocket wheel 21 and described 3rd electrothermal tube side-to-side movement sprocket wheel are connected with electrothermal tube side-to-side movement chain 20, the input end of described microcontroller 13-1 is connected to electrothermal tube side-to-side movement button 13-3 and electrothermal tube and seesaws button 13-4, the output terminal of described microcontroller 13-1 is connected to for driving the second motor driver 13-7 of electrothermal tube side-to-side movement motor 19, for driving electrothermal tube to seesaw the 3rd motor driver 13-8 of the motor 22 and relay 13-9 for controlling electrothermal tube 14 power on/off, the coils connected in series of described relay 13-9 is in the current supply circuit of electrothermal tube 14.

As shown in Figure 6, in the present embodiment, the seesaw rear and front end of guide rail 17 of described electrothermal tube is respectively arranged with limit switch 30 after electrothermal tube front limit switch 31 and electrothermal tube, the two ends, left and right of the electrothermal tube side-to-side movement guide rail 18 matched with electrothermal tube left and right driven motions guide wheel 25 are respectively arranged with electrothermal tube left limit switch 28 and electrothermal tube right limit switch 27, and after described electrothermal tube front limit switch 31, electrothermal tube, limit switch 30, electrothermal tube left limit switch 28 are all connected with the input end of microcontroller 13-1 with electrothermal tube right limit switch 27.In the process of electrothermal tube 14 side-to-side movement in simulation system casing 1, the left end extreme position that electrothermal tube left limit switch 28 pairs of door type frameworks 16 move to electrothermal tube side-to-side movement guide rail 18 detects and the signal detected is exported to microcontroller 13-1 in real time, the extreme right position that electrothermal tube right limit switch 27 pairs of door type frameworks 16 move to electrothermal tube side-to-side movement guide rail 18 detects and the signal detected is exported to microcontroller 13-1 in real time, when electrothermal tube left limit switch 28 or electrothermal tube right limit switch 27 detect signal, when namely exporting as high level, microcontroller 13-1 controls electrothermal tube side-to-side movement motor 13-3 and stops operating, avoid the outside that door type framework 16 moves to electrothermal tube side-to-side movement guide rail 18, cause the system failure.In the process that electrothermal tube 14 seesaws in simulation system casing 1, electrothermal tube front limit switch 31 pairs of door type frameworks 16 move to the seesaw front end extreme position of guide rail 17 of electrothermal tube and detect and the signal detected is exported to microcontroller 13-1 in real time, after electrothermal tube, limit switch 30 pairs of door type frameworks 16 move to the seesaw rear end extreme position of guide rail 17 of electrothermal tube and detect and the signal detected is exported to microcontroller 13-1 in real time, when after electrothermal tube front limit switch 31 or electrothermal tube, limit switch 30 detects signal, when namely exporting as high level, microcontroller 13-1 controls the electrothermal tube motor 13-4 that seesaws and stops operating, avoid the electrothermal tube dolly 15 that seesaws to move to electrothermal tube and to seesaw the outside of guide rail 17, cause the system failure.

In the present embodiment, in each layer, the square net of multiple described soil temperature-moisture sensors 33 in 1m × 1m is evenly laid, and in multilayer, the multiple described soil temperature-moisture sensor 33 of adjacent two layers is all laid up and down relatively by the equidistant from distance of 0.5m.

As shown in Figure 8, indoor frozen soil Moisture Transfer Rule characteristic parameter assay method of the present invention, comprises the following steps:

Step one, build geologic model: operate multiple lifting jack 5, after making geologic model groove 4 be in horizontal positioned, test soil sample 4-1 layering is filled into the top of pottery clay plates 4-3 in geologic model groove 4, and carry out soil sample and ram and fill; Then, then operate multiple lifting jack 5, the gradient of adjustment geologic model groove 4 is the test gradient;

Step 2, assembling snowfall point simulation mechanism: ice cube 3-7 is put into ice storage cylinder 3-3, anti-for ice cube bull stick 3-8 is inserted in cylinder hole 3-9, and open seal cover 3-1 is connected to ice storage cylinder 3-3 top; Described ice cube 3-7 is cylindrical ice cube;

Step 3, optimum configurations: on computing machine 8, input total snowfall Q _zwith electrothermal tube heating-up temperature T ₃, computing machine 8 is according to formula calculate the falling head limit value h of single ice cube 3-7 ₀, and by serial communication circuit 13-2 by the falling head limit value h of single ice cube 3-7 ₀with electrothermal tube heating-up temperature T ₃be transferred to microcontroller 13-1; Wherein, S is the cross-sectional area of single ice cube 3-7, and unit is cm ²; N is the quantity of ice cube 3-7; Total snowfall Q _zunit be cm ³, the falling head limit value h of single ice cube 3-7 ₀unit be cm;

Step 4, measure test soil sample freeze before initial aqueous rate: multiple soil temperature-moisture sensor 33 carries out one-time detection to the temperature and humidity of test soil sample 4-1 respectively and the temperature signal of the multiple test point places detected test soil sample 4-1 and moisture signal is transferred to microcontroller 13-1, the temperature signal of the multiple test point places test soil sample 4-1 that microcontroller 13-1 is received again and moisture signal by serial communication circuit 13-2 real-time Transmission to computing machine 8, computing machine 8 receives and records temperature signal and the moisture signal of multiple test point place test soil sample 4-1, and by each test point place test soil sample 4-1 moisture signal be recorded as each test point place test soil sample freeze before initial aqueous rate θ _o,

Step 5, simulation frozen soil environment and measure test soil sample freeze before valley water percentage: regulate the temperature of cold-hot integrated machine 7 to be frozen soil environment temperature T ₄, the temperature in simulation system casing 1 declines gradually and reaches frozen soil environment temperature T ₄process in, multiple soil temperature-moisture sensor 33 carries out periodically detecting to the temperature and humidity of test soil sample 4-1 respectively and the temperature signal of the multiple test point place test soil sample 4-1 detected and moisture signal is transferred to microcontroller 13-1, the temperature signal of the multiple test point places test soil sample 4-1 that microcontroller 13-1 is received again and moisture signal by serial communication circuit 13-2 real-time Transmission to computing machine 8, computing machine 8 receives and records temperature signal and the moisture signal of each sampling instant multiple test point place test soil sample 4-1, and the humidity of each multiple sampling instant in test point place is arranged from big to small, and each test point place is arranged in last humidity value be recorded as this test point place test soil sample freeze before valley water percentage θ _v,

Step 6, carry out Simulation of Snowfall and measure test soil sample freeze after stable aqueous rate: regulate the temperature of cold-hot integrated machine 7 to be snowfall temperature T ₁after, operation computing machine 8, start snowfall pattern, computing machine 8 sends the signal of snowfall pattern startup to microcontroller 13-1 by serial communication circuit 13-2, microcontroller 13-1 drives snowfall motor 3-5 to rotate by the first motor driver 13-6, snowfall motor 3-5 driven rotary is cut skates 3-4 and is rotated, cutting ice cube 3-7 produces snowfall, in snowfall, ultrasonic distance-measuring sensor 3-10 detects the falling head of ice storage cylinder 3-3 ice cube 3-7 described in one of them and in real time by the falling head real-time Transmission of ice cube 3-7 that detects to microcontroller 13-1, the falling head of the ice cube 3-7 that microcontroller 13-1 is received and the falling head limit value h of single ice cube 3-7 ₀compare, when the falling head of ice cube 3-7 reaches the falling head limit value h of single ice cube 3-7 ₀time, microcontroller 13-1 drives snowfall motor 3-5 to stop operating by the first motor driver 13-6, and total snowfall now reaches Q _z, simultaneously, in snowfall, multiple soil temperature-moisture sensor 33 carries out periodically detecting to the temperature and humidity of test soil sample 4-1 respectively and the temperature signal of the multiple test point place test soil samples detected and moisture signal is transferred to microcontroller 13-1, the temperature signal of the multiple test point places test soil sample 4-1 that microcontroller 13-1 is received again and moisture signal by serial communication circuit 13-2 real-time Transmission to computing machine 8, computing machine 8 receives and records temperature signal and the moisture signal of each sampling instant multiple test point place test soil sample 4-1, and the humidity of each multiple sampling instant in test point place is arranged according to time order and function order, when the humidity differences of adjacent two sampling instants is less than or equal to 1%, illustrate that the humidity of this test point place test soil sample 4-1 is stable, the humidity value of a rear sampling instant in adjacent two sampling instants is recorded as this test point place test soil sample freeze after stable aqueous rate θ _f, during concrete enforcement, by regulating the rotating speed of snowfall motor 3-5, the control to snowfall speed can also be realized.

Step 7, carry out solar radiation thermal simulation: regulate the temperature of cold-hot integrated machine 7 to be that temperature T is infiltrated in snowfall ₂after, operation computing machine 8, start snowfall and infiltrate pattern, computing machine 8 by serial communication circuit 13-2 send snowfall infiltrate pattern start signal to microcontroller 13-1, microcontroller 13-1 pilot relay 13-9 connects the current supply circuit of electrothermal tube 14, electrothermal tube 14 starts heating, in electrothermal tube 14 heating process, the heating-up temperature of electrothermal tube temperature sensor 29 pairs of electrothermal tubes 14 detects and in real time by the signal real-time Transmission that detects to microcontroller 13-1, the heating-up temperature detected value that microcontroller 13-1 is received and electrothermal tube heating-up temperature T ₃compare, when heating-up temperature detected value reaches electrothermal tube heating-up temperature T ₃time, microcontroller 13-1 pilot relay 13-9 disconnects the current supply circuit of electrothermal tube 14, and electrothermal tube 14 stops heating, when heating-up temperature detected value is lower than electrothermal tube heating-up temperature T ₃time, microcontroller 13-1 pilot relay 13-9 connects the current supply circuit of electrothermal tube 14, and electrothermal tube 14 starts heating, thus makes the heating-up temperature of electrothermal tube 14 remain T ₃; In electrothermal tube 14 heating process, press electrothermal tube side-to-side movement button 13-3 or electrothermal tube and seesaw after button 13-4, microcontroller 13-1 controls electrothermal tube 14 side-to-side movement or seesaw in simulation system casing 1, carries out solar radiation thermal simulation;

Step 8, carry out snowfall infiltrate observe and measure test soil sample melt after stable aqueous rate and the peak value water percentage of test soil sample when melting: electrothermal tube 14 heating in step 7 makes in the snowfall ablation procedure in step 6, and the water that melts in non-infiltration test soil sample 4-1 flows out and is in charge of 10-1 through measurements of too much root snowfall run-off and snowfall run-off is measured in house steward 10-2 inflow snowfall run-off measurement measuring cup 11 in multiple described snowfall run-off measured hole, the water that melts oozed out in test soil sample 4-1 goes out in milliosmolarity measured hole to flow out from multiple described snowfall and goes out milliosmolarity measurements through too much root snowfall to be in charge of 10-3 and snowfall and to go out milliosmolarity and measure house steward 10-4 and flow into snowfall and go out in milliosmolarity measurement measuring cup 12, simultaneously, multiple soil temperature-moisture sensor 33 carries out periodically detecting to the temperature and humidity of test soil sample 4-1 respectively and the temperature signal of the multiple test point place test soil samples detected and moisture signal is transferred to microcontroller 13-1, the temperature signal of the multiple test point places test soil sample 4-1 that microcontroller 13-1 is received again and moisture signal by serial communication circuit 13-2 real-time Transmission to computing machine 8, computing machine 8 receives and records temperature signal and the moisture signal of each sampling instant multiple test point place test soil sample 4-1, and the humidity of each multiple sampling instant in test point place is arranged according to time order and function order, when the humidity differences of adjacent two sampling instants is less than or equal to 1%, illustrate that the humidity of this test point place test soil sample 4-1 is stable, the humidity value of a rear sampling instant in adjacent two sampling instants is recorded as this test point place test soil sample melt after stable aqueous rate θ _e, and computing machine 8 also arranges from big to small to the humidity of each multiple sampling instant in test point place, and each test point place is arranged in the most front humidity value and is recorded as peak value water percentage θ when this test point place test soil sample melts _p, simultaneously, flow sensor 9 carries out periodically detecting and the signal detected being exported to microcontroller 13-1 to the discharge that melts of oozing out test soil sample 4-1, the discharge that melts of what microcontroller 13-1 was received ooze out test soil sample 4-1 is transferred to computing machine 8 by serial communication circuit 13-2, and computing machine 8 calls flow curve drafting module and draws out the curve melting discharge t change in time oozing out test soil sample 4-1, check the curve melting discharge t change in time oozing out test soil sample 4-1 be presented on computing machine 8, when ooze out test soil sample 4-1 melt discharge in time t change curve tends in straight line time, illustrate that snowfall is infiltrated stable, now, check that snowfall run-off measures the amount melting water in measuring cup 11 in non-infiltration test soil sample 4-1, and be snowfall run-off Q by this read-record _j, check that snowfall goes out milliosmolarity and measures in measuring cup 12 amount melting water of oozing out in test soil sample 4-1, and be that snowfall goes out milliosmolarity Q by this read-record _c, wherein, snowfall run-off Q _junit be cm ³, snowfall goes out milliosmolarity Q _cunit be cm ³,

During concrete enforcement, the sense cycle that in step 5, step 6 and step 8, multiple soil temperature-moisture sensor 33 carries out periodically detecting to the temperature and humidity of test soil sample 4-1 is respectively 1s ~ 10s; In step 8 flow sensor 9 to ooze out test soil sample 4-1 to melt the sense cycle that discharge carries out periodically detecting be 1s ~ 10s.

Step 9: frozen soil Moisture Transfer Rule snowfall Infiltration characteristics parameter calculates, and detailed process is:

Step 901, according to formula Q _r=Q _z-Q _j, calculate snowfall infiltration capacity Q _r; Snowfall infiltration capacity Q _runit be cm ³;

Step 902, according to formula Δ S=Q _r-Q _ccalculate water deficit amount Δ S; The unit of water deficit amount Δ S is cm ³;

Step 903, according to formula calculate snowfall infiltration rate V _r; Snowfall infiltration rate V _runit be cm ³/ s;

Step 904, according to formula calculate snowfall to go out to ooze rate V _c; Snowfall goes out to ooze rate V _cunit be cm ³/ s;

Step 905, according to formula calculate snowfall infiltrated water α;

In step 903 and step 904, t is the time, and unit is s.

In the present embodiment, in step 7, press electrothermal tube side-to-side movement button 13-3 or electrothermal tube to seesaw button 13-4, make electrothermal tube 14 side-to-side movement or seesaw in simulation system casing 1, the detailed process of carrying out solar radiation thermal simulation is: when pressing electrothermal tube side-to-side movement button 13-3, microcontroller 13-1 drives electrothermal tube side-to-side movement motor 13-3 to rotate by the second motor driver 13-7, electrothermal tube side-to-side movement motor 13-3 drives described 3rd electrothermal tube side-to-side movement sprocket rotation, described 3rd electrothermal tube side-to-side movement sprocket wheel drives the first electrothermal tube side-to-side movement sprocket wheel 25 to rotate by electrothermal tube side-to-side movement chain 20, first electrothermal tube side-to-side movement sprocket wheel 25 drives electrothermal tube left and right active movement guide wheel 26 to rotate, electrothermal tube left and right active movement guide wheel 26 drives the side of door type framework 16 to move along a wherein electrothermal tube side-to-side movement guide rail 18, simultaneously, electrothermal tube left and right driven motions guide wheel 25 drives the opposite side of door type framework 16 driven along another electrothermal tube side-to-side movement guide rail 18, door type framework 16 drives electrothermal tube to seesaw dolly 15 side-to-side movement in simulation system casing 1, the electrothermal tube dolly 15 that seesaws drives electrothermal tube 14 side-to-side movement in simulation system casing 1, when press electrothermal tube seesaw button 13-4 time, microcontroller 13-1 drives the electrothermal tube motor 13-4 that seesaws to rotate by the 3rd motor driver 13-8, electrothermal tube seesaw motor 22 drive described second electrothermal tube seesaw belt wheel rotate, the described second electrothermal tube belt wheel that seesaws drives the described electrothermal tube belt 23 that seesaws to rotate around described second electrothermal tube belt wheel and the first electrothermal tube belt wheel 24 that seesaws that seesaws, the described electrothermal tube belt 23 that seesaws drives the electrothermal tube dolly 15 that seesaws to seesaw in simulation system casing 1, the electrothermal tube dolly 15 that seesaws drives electrothermal tube 14 to seesaw in simulation system casing 1.

In the present embodiment, electrothermal tube heating-up temperature T in step 3 ₃value be 20 DEG C ~ 80 DEG C, frozen soil environment temperature T in step 5 ₄value be-20 DEG C ~ 30 DEG C, snowfall temperature T in step 6 ₁value be-25 DEG C ~ 0 DEG C, in step 7, temperature T is infiltrated in snowfall ₂value be-20 DEG C ~ 20 DEG C.

In sum, the present invention can study different gradient, different snowfall intensity, frozen soil Moisture Transfer Rule and characteristic parameter under snowfall condition in different soil property under different temperatures (test soil sample freeze before initial aqueous rate, valley water percentage before soil freezing, stable aqueous rate after soil freezing, stable aqueous rate after soil melts, peak value water percentage when soil melts, snowfall run-off, snowfall goes out milliosmolarity, snowfall infiltration capacity, water deficit amount, snowfall infiltration rate, snowfall goes out to ooze rate and snowfall infiltrated water) Changing Pattern, for frozen soil Moisture Transfer Rule under studying snowfall condition further provides approach.

The above; it is only preferred embodiment of the present invention; not the present invention is imposed any restrictions, every above embodiment is done according to the technology of the present invention essence any simple modification, change and equivalent structure change, all still belong in the protection domain of technical solution of the present invention.

Claims (9)

1. an indoor frozen soil Moisture Transfer Rule simulation system, it is characterized in that: comprise simulation system casing (1), frozen soil Moisture Transfer Rule characteristic parameter measuring system and Test Data Collecting and controller (13), and be arranged on the inner cold-hot integrated machine (7) of simulation system casing (1), Simulation of Snowfall system, geologic model system and solar radiant heat simulation system;

Described Simulation of Snowfall system comprises the snowfall groove (2-3) that embedding is arranged on simulation system casing (1) top, be arranged on fixed support (2-1) in snowfall groove (2-3) and embedding and be arranged on multiple snowfall points simulation mechanism (3) on fixed support (2-1), each described snowfall point simulation mechanism (3) includes the ice storage cylinder (3-3) of all uncovered setting in top and bottom and is arranged on the open seal cover (3-1) at ice storage cylinder (3-3) top, the bottom of described ice storage cylinder (3-3) is provided with cross-shaped strut (3-6), the center of described cross-shaped strut (3-6) is provided with snowfall motor (3-5), the output shaft of described snowfall motor (3-5) is fixedly connected with rotary cutting skates (3-4), the inner bottom surface of described open seal cover (3-1) is connected with the anti-bull stick of ice cube (3-8), the anti-bull stick of described ice cube (3-8) is set with the pressure spring (3-2) for being pressed on by ice cube (3-7) on rotary cutting skates (3-4), the shape of the anti-bull stick of described ice cube (3-8) xsect is rectangle, described ice cube (3-7) has for the anti-bull stick of ice cube (3-8) penetrate and with the anti-bull stick of ice cube (3-8) close-fitting cylinder hole (3-9), the bottom of described snowfall groove (2-3) is provided with the vibratory screening apparatus (2-2) cutting the snowflake fallen for vibrating landing rotary cutting skates (3-4), the top of any one the ice storage cylinder in multiple ice storage cylinder (3-3) is provided with ultrasonic distance-measuring sensor (3-10),

Described geologic model system comprises base (6) and supports by multiple lifting jack (5) the geologic model groove (4) be arranged on base (6), the bottom of described geologic model groove (4) is provided with the longitude and latitude flase floor (4-2) for forming water space at geologic model groove (4) inner bottom part, described longitude and latitude flase floor (4-2) is provided with multiple water outlet hole, the top of described longitude and latitude flase floor (4-2) is provided with pottery clay plates (4-3), the surrounding of described pottery clay plates (4-3) is along all bonding with geologic model groove (4) inwall, the top of described pottery clay plates (4-3) is for placing test soil sample (4-1),

Described solar radiant heat simulation system comprises the electrothermal tube (14) for simulated solar illumination, electrothermal tube for driving electrothermal tube (14) to seesaw in simulation system casing (1) seesaws mechanism and for driving the electrothermal tube side-to-side movement mechanism of electrothermal tube (14) side-to-side movement in simulation system casing (1), described electrothermal tube (14) is arranged between described geologic model system and described Simulation of Snowfall system, the side of described electrothermal tube (14) is provided with for carrying out the electrothermal tube temperature sensor (29) detected in real time to the heating-up temperature of electrothermal tube (14),

Described frozen soil Moisture Transfer Rule characteristic parameter measuring system comprises the soil moisture and measurement of water ratio system, snowfall run-off measuring system and snowfall go out milliosmolarity measuring system, the described soil moisture and measurement of water ratio system comprise point multilayer and are embedded in the multiple soil temperature-moisture sensors (33) tested in soil sample (4-1), the quantity of every layer of described soil temperature-moisture sensor (33) is multiple, in each layer, multiple described soil temperature-moisture sensor (33) is evenly laid in square net, in multilayer, the multiple described soil temperature-moisture sensor (33) of adjacent two layers is all laid up and down relatively by equidistant from distance, described snowfall run-off measuring system comprises snowfall run-off and measures measuring cup (11) and be arranged on multiple snowfall run-off measured holes of geologic model groove (4) side, and the snowfall run-off measurement be connected on described snowfall run-off measured hole is in charge of (10-1) and is in charge of (10-1) with the measurement of snowfall run-off and is connected and accesses the snowfall run-off snowfall run-off measured in measuring cup (11) and measure house steward (10-2), described snowfall go out milliosmolarity measuring system comprise snowfall go out milliosmolarity measure measuring cup (12) and the multiple snowfalls be arranged on geologic model groove (4) bottom surface go out milliosmolarity measured hole, and be connected to the described snowfall many snowfalls gone out on milliosmolarity measured hole and go out milliosmolarity measurement and be in charge of (10-3) and go out milliosmolarity measurement with snowfall and be in charge of (10-3) and be connected and access snowfall to go out the milliosmolarity snowfall of measuring in measuring cup (12) and go out milliosmolarity and measure house steward (10-4), described snowfall goes out in milliosmolarity measurement house steward (10-4) to be provided with for carrying out the flow sensor (9) detected in real time to the flow melting water oozing out test soil sample (4-1),

Described Test Data Collecting and controller (13) comprise microcontroller (13-1) and connect with microcontroller (13-1) and serial communication circuit (13-2) for being connected with computing machine (8), the output terminal of described microcontroller (13-1) is connected to liquid crystal display (13-5) and for driving first motor driver (13-6) of snowfall motor (3-5), described ultrasonic distance-measuring sensor (3-10), flow sensor (9), electrothermal tube temperature sensor (29) is all connected with the input end of microcontroller (13-1) with multiple soil temperature-moisture sensor (33).

2. according to indoor frozen soil Moisture Transfer Rule simulation system according to claim 1, it is characterized in that: described rotary cutting skates (3-4) comprise discoidal cut skates body (3-41) and be evenly arranged on that the many rows cut on skates body (3-41) outwards disperse from the center of cutting skates body (3-41) cut ice hole (3-42), cut described in each in ice hole (3-42) and be provided with diamond knife edge (3-43).

3. according to indoor frozen soil Moisture Transfer Rule simulation system according to claim 1, it is characterized in that: the distance of the bottom of bottom distance ice storage cylinder (3-3) of described rotary cutting skates (3-4) is 2cm ~ 5cm.

4. according to indoor frozen soil Moisture Transfer Rule simulation system according to claim 1, it is characterized in that: the described electrothermal tube mechanism that seesaws comprises electrothermal tube and to seesaw dolly (15) and the door type framework (16) that is arranged on along the fore-and-aft direction of simulation system casing (1) in simulation system casing (1), described electrothermal tube (14) is suspended on electrothermal tube and seesaws the bottom of dolly (15), the top of described door type framework (16) is provided with and seesaws guide rail (17) for seesaw electrothermal tube that dolly (15) walks of electrothermal tube, the side, top of described door type framework (16) is provided with electrothermal tube and seesaws motor (22), the top opposite side of described door type framework (16) is provided with the first electrothermal tube and seesaws belt wheel (24), described electrothermal tube seesaw motor (22) output shaft on be connected with the second electrothermal tube and seesaw belt wheel, seesaw belt wheel (24) and described second electrothermal tube of described first electrothermal tube seesaws and belt wheel is connected with electrothermal tube and seesaws belt (23), described electrothermal tube bottom and the electrothermal tube of dolly (15) belt (23) that seesaws that seesaws is fixedly connected with, the described electrothermal tube side-to-side movement mechanism left and right directions comprised along simulation system casing (1) is arranged on two electrothermal tube side-to-side movement guide rails (18) of simulation system casing (1) bottom, one side bottom of described door type framework (16) is provided with the electrothermal tube left and right active movement guide wheel (26) and the first electrothermal tube side-to-side movement sprocket wheel (25) that be connected coaxial with electrothermal tube left and right active movement guide wheel (26) that move along wherein electrothermal tube side-to-side movement guide rail (18), electrothermal tube left and right driven motions guide wheel (32) of moving along another electrothermal tube side-to-side movement guide rail (18) is provided with bottom the opposite side of described door type framework (16), the both sides of the electrothermal tube side-to-side movement guide rail (18) matched with electrothermal tube left and right active movement guide wheel (26) are respectively arranged with electrothermal tube side-to-side movement motor (19) and the second electrothermal tube side-to-side movement sprocket wheel (21), the output shaft of described electrothermal tube side-to-side movement motor (19) is connected with the 3rd electrothermal tube side-to-side movement sprocket wheel, described first electrothermal tube side-to-side movement sprocket wheel (25), second electrothermal tube side-to-side movement sprocket wheel (21) and described 3rd electrothermal tube side-to-side movement sprocket wheel are connected with electrothermal tube side-to-side movement chain (20), the input end of described microcontroller (13-1) is connected to electrothermal tube side-to-side movement button (13-3) and electrothermal tube and seesaws button (13-4), the output terminal of described microcontroller (13-1) is connected to the second motor driver (13-7) for driving electrothermal tube side-to-side movement motor (19), to seesaw the 3rd motor driver (13-8) of motor (22) and the relay (13-9) for controlling electrothermal tube (14) power on/off for driving electrothermal tube, the coils connected in series of described relay (13-9) is in the current supply circuit of electrothermal tube (14).

5. according to indoor frozen soil Moisture Transfer Rule simulation system according to claim 4, it is characterized in that: the seesaw rear and front end of guide rail (17) of described electrothermal tube is respectively arranged with limit switch (30) after electrothermal tube front limit switch (31) and electrothermal tube, the two ends, left and right of the electrothermal tube side-to-side movement guide rail (18) matched with electrothermal tube left and right driven motions guide wheel (25) are respectively arranged with electrothermal tube left limit switch (28) and electrothermal tube right limit switch (27), described electrothermal tube front limit switch (31), limit switch (30) after electrothermal tube, electrothermal tube left limit switch (28) is all connected with the input end of microcontroller (13-1) with electrothermal tube right limit switch (27).

6. according to indoor frozen soil Moisture Transfer Rule simulation system according to claim 1, it is characterized in that: in each layer, the square net of multiple described soil temperature-moisture sensors (33) in 1m × 1m is evenly laid, and in multilayer, the multiple described soil temperature-moisture sensor (33) of adjacent two layers is all laid up and down relatively by the equidistant from distance of 0.5m.

7. utilize indoor frozen soil Moisture Transfer Rule simulation system as claimed in claim 4 to carry out the method for measuring of indoor frozen soil Moisture Transfer Rule characteristic parameter, it is characterized in that the method comprises the following steps:

Step one, structure geologic model: operate multiple lifting jack (5), after making geologic model groove (4) be in horizontal positioned, the top that soil sample (4-1) layering is filled into geologic model groove (4) interior pottery clay plates (4-3) will be tested, and carry out soil sample and ram and fill; Then, then operate multiple lifting jack (5), the gradient of adjustment geologic model groove (4) is the test gradient;

Step 2, assembling snowfall point simulation mechanism: ice cube (3-7) is put into ice storage cylinder (3-3), anti-for ice cube bull stick (3-8) is inserted in cylinder hole (3-9), and open seal cover (3-1) is connected to ice storage cylinder (3-3) top; Described ice cube (3-7) is cylindrical ice cube;

Step 3, optimum configurations: at the total snowfall Q of the upper input of computing machine (8) _zwith electrothermal tube heating-up temperature T ₃, computing machine (8) is according to formula calculate the falling head limit value h of single ice cube (3-7) ₀, and by serial communication circuit (13-2) by the falling head limit value h of single ice cube (3-7) ₀with electrothermal tube heating-up temperature T ₃be transferred to microcontroller (13-1); Wherein, S is the cross-sectional area of single ice cube (3-7), and n is the quantity of ice cube (3-7);

Step 4, measure test soil sample freeze before initial aqueous rate: multiple soil temperature-moisture sensor (33) carries out one-time detection to the temperature and humidity of test soil sample (4-1) respectively and the temperature signal at the multiple test point places detected test soil sample (4-1) and moisture signal is transferred to microcontroller (13-1), the temperature signal of multiple test point places test soil sample (4-1) that microcontroller (13-1) is received again and moisture signal pass through serial communication circuit (13-2) real-time Transmission to computing machine (8), computing machine (8) receives and records temperature signal and the moisture signal at multiple test point place test soil sample (4-1), and by each test point place test soil sample (4-1) moisture signal be recorded as each test point place test soil sample freeze before initial aqueous rate θ _o,

Step 5, simulation frozen soil environment and measure test soil sample freeze before valley water percentage: regulate cold-hot integrated machine (7) temperature be frozen soil environment temperature T ₄, the temperature in simulation system casing (1) declines gradually and reaches frozen soil environment temperature T ₄process in, multiple soil temperature-moisture sensor (33) carries out periodically detecting to the temperature and humidity of test soil sample (4-1) respectively and the temperature signal of multiple test point places test soil sample (4-1) detected and moisture signal is transferred to microcontroller (13-1), the temperature signal of multiple test point places test soil sample (4-1) that microcontroller (13-1) is received again and moisture signal pass through serial communication circuit (13-2) real-time Transmission to computing machine (8), computing machine (8) receives and records temperature signal and the moisture signal of multiple test point place test soil sample (4-1) of each sampling instant, and the humidity of each multiple sampling instant in test point place is arranged from big to small, and each test point place is arranged in last humidity value be recorded as this test point place test soil sample freeze before valley water percentage θ _v,

Step 6, carry out Simulation of Snowfall and measure test soil sample freeze after stable aqueous rate: regulate cold-hot integrated machine (7) temperature be snowfall temperature T ₁after, operation computing machine (8), start snowfall pattern, computing machine (8) sends the signal of snowfall pattern startup to microcontroller (13-1) by serial communication circuit (13-2), microcontroller (13-1) drives snowfall motor (3-5) to rotate by the first motor driver (13-6), snowfall motor (3-5) driven rotary is cut skates (3-4) and is rotated, cutting ice cube (3-7) produces snowfall, in snowfall, ultrasonic distance-measuring sensor (3-10) detects the falling head of ice storage cylinder (3-3) ice cube (3-7) described in one of them and in real time by the falling head real-time Transmission of ice cube (3-7) that detects to microcontroller (13-1), the falling head of the ice cube (3-7) that microcontroller (13-1) is received and the falling head limit value h of single ice cube (3-7) ₀compare, when the falling head of ice cube (3-7) reaches the falling head limit value h of single ice cube (3-7) ₀time, microcontroller (13-1) drives snowfall motor (3-5) to stop operating by the first motor driver (13-6), and total snowfall now reaches Q _z, simultaneously, in snowfall, multiple soil temperature-moisture sensor (33) carries out periodically detecting to the temperature and humidity of test soil sample (4-1) respectively and the temperature signal of the multiple test point place test soil samples detected and moisture signal is transferred to microcontroller (13-1), the temperature signal of multiple test point places test soil sample (4-1) that microcontroller (13-1) is received again and moisture signal pass through serial communication circuit (13-2) real-time Transmission to computing machine (8), computing machine (8) receives and records temperature signal and the moisture signal of multiple test point place test soil sample (4-1) of each sampling instant, and the humidity of each multiple sampling instant in test point place is arranged according to time order and function order, when the humidity differences of adjacent two sampling instants is less than or equal to 1%, illustrate that the humidity at this test point place test soil sample (4-1) is stable, the humidity value of a rear sampling instant in adjacent two sampling instants is recorded as this test point place test soil sample freeze after stable aqueous rate θ _f,

Step 7, carry out solar radiation thermal simulation: regulate the temperature of cold-hot integrated machine (7) to be that temperature T is infiltrated in snowfall ₂after, operation computing machine (8), start snowfall and infiltrate pattern, computing machine (8) by serial communication circuit (13-2) send snowfall infiltrate pattern start signal to microcontroller (13-1), the current supply circuit of electrothermal tube (14) connected by microcontroller (13-1) pilot relay (13-9), electrothermal tube (14) starts heating, in electrothermal tube (14) heating process, the heating-up temperature of electrothermal tube temperature sensor (29) to electrothermal tube (14) detects and in real time by the signal real-time Transmission that detects to microcontroller (13-1), the heating-up temperature detected value that microcontroller (13-1) is received and electrothermal tube heating-up temperature T ₃compare, when heating-up temperature detected value reaches electrothermal tube heating-up temperature T ₃time, microcontroller (13-1) pilot relay (13-9) disconnects the current supply circuit of electrothermal tube (14), and electrothermal tube (14) stops heating, when heating-up temperature detected value is lower than electrothermal tube heating-up temperature T ₃time, the current supply circuit of electrothermal tube (14) connected by microcontroller (13-1) pilot relay (13-9), and electrothermal tube (14) starts heating, thus makes the heating-up temperature of electrothermal tube (14) remain T ₃, in electrothermal tube (14) heating process, pressing electrothermal tube side-to-side movement button (13-3) or electrothermal tube seesaws after button (13-4), microcontroller (13-1) controls electrothermal tube (14) side-to-side movement or seesaw in simulation system casing (1), carries out solar radiation thermal simulation,

Step 8, carry out snowfall infiltrate observe and measure test soil sample melt after stable aqueous rate and the peak value water percentage of test soil sample when melting: electrothermal tube (14) heating in step 7 makes in the snowfall ablation procedure in step 6, and the water that melts in non-infiltration test soil sample (4-1) flows out and is in charge of (10-1) through measurements of too much root snowfall run-off and snowfall run-off measurement house steward (10-2) flows in snowfall run-off measurement measuring cup (11) in multiple described snowfall run-off measured hole; The water that melts oozed out in test soil sample (4-1) goes out in milliosmolarity measured hole to flow out from multiple described snowfall and goes out milliosmolarity measurements through too much root snowfall to be in charge of (10-3) and snowfall and to go out milliosmolarity measurement house steward (10-4) and flow into snowfall and go out in milliosmolarity measurement measuring cup (12); simultaneously, multiple soil temperature-moisture sensor (33) carries out periodically detecting to the temperature and humidity of test soil sample (4-1) respectively and the temperature signal of the multiple test point place test soil samples detected and moisture signal is transferred to microcontroller (13-1), the temperature signal of multiple test point places test soil sample (4-1) that microcontroller (13-1) is received again and moisture signal pass through serial communication circuit (13-2) real-time Transmission to computing machine (8), computing machine (8) receives and records temperature signal and the moisture signal of multiple test point place test soil sample (4-1) of each sampling instant, and the humidity of each multiple sampling instant in test point place is arranged according to time order and function order, when the humidity differences of adjacent two sampling instants is less than or equal to 1%, illustrate that the humidity at this test point place test soil sample (4-1) is stable, the humidity value of a rear sampling instant in adjacent two sampling instants is recorded as this test point place test soil sample melt after stable aqueous rate θ _e, and computing machine (8) also arranges from big to small to the humidity of each multiple sampling instant in test point place, and each test point place is arranged in the most front humidity value and is recorded as peak value water percentage θ when this test point place test soil sample melts _p, simultaneously, flow sensor (9) carries out periodically detecting and the signal detected being exported to microcontroller (13-1) to the discharge that melts of oozing out test soil sample (4-1), the discharge that melts of test soil sample (4-1) that what microcontroller (13-1) was received ooze out is transferred to computing machine (8) by serial communication circuit (13-2), and computing machine (8) calls flow curve drafting module and draws out the curve melting discharge t change in time oozing out test soil sample (4-1), check the curve melting discharge t change in time oozing out test soil sample (4-1) be presented on computing machine (8), when ooze out test soil sample (4-1) melt discharge in time t change curve tends in straight line time, illustrate that snowfall is infiltrated stable, now, check that snowfall run-off measures the amount melting water in measuring cup (11) in non-infiltration test soil sample (4-1), and be snowfall run-off Q by this read-record _j, check that snowfall goes out milliosmolarity and measures in measuring cup (12) amount melting water of oozing out in test soil sample (4-1), and be that snowfall goes out milliosmolarity Q by this read-record _c,

Step 9: frozen soil Moisture Transfer Rule snowfall Infiltration characteristics parameter calculates, and detailed process is:

Step 901, according to formula Q _r=Q _z-Q _j, calculate snowfall infiltration capacity Q _r;

Step 902, according to formula Δ S=Q _r-Q _ccalculate water deficit amount Δ S;

Step 903, according to formula calculate snowfall infiltration rate V _r;

Step 904, according to formula calculate snowfall to go out to ooze rate V _c;

Step 905, according to formula calculate snowfall infiltrated water α;

In step 903 and step 904, t is the time.

8. in accordance with the method for claim 7, it is characterized in that: in step 7, press electrothermal tube side-to-side movement button (13-3) or electrothermal tube to seesaw button (13-4), make electrothermal tube (14) side-to-side movement or seesaw in simulation system casing (1), the detailed process of carrying out solar radiation thermal simulation is: when pressing electrothermal tube side-to-side movement button (13-3), microcontroller (13-1) drives electrothermal tube side-to-side movement motor (13-3) to rotate by the second motor driver (13-7), electrothermal tube side-to-side movement motor (13-3) drives described 3rd electrothermal tube side-to-side movement sprocket rotation, described 3rd electrothermal tube side-to-side movement sprocket wheel drives the first electrothermal tube side-to-side movement sprocket wheel (25) to rotate by electrothermal tube side-to-side movement chain (20), first electrothermal tube side-to-side movement sprocket wheel (25) drives electrothermal tube left and right active movement guide wheel (26) to rotate, electrothermal tube left and right active movement guide wheel (26) drives the side of door type framework (16) along wherein electrothermal tube side-to-side movement guide rail (18) motion, simultaneously, electrothermal tube left and right driven motions guide wheel (25) drives the opposite side of door type framework (16) driven along another electrothermal tube side-to-side movement guide rail (18), door type framework (16) drives electrothermal tube to seesaw dolly (15) side-to-side movement in simulation system casing (1), electrothermal tube seesaw dolly (15) drive electrothermal tube (14) side-to-side movement in simulation system casing (1), when press electrothermal tube seesaw button (13-4) time, microcontroller (13-1) by the 3rd motor driver (13-8) drive electrothermal tube seesaw motor (13-4) rotate, electrothermal tube seesaw motor (22) drive described second electrothermal tube seesaw belt wheel rotate, the described second electrothermal tube belt wheel that seesaws drives the described electrothermal tube belt (23) that seesaws to rotate around described second electrothermal tube belt wheel and the first electrothermal tube belt wheel (24) that seesaws that seesaws, the described electrothermal tube belt (23) that seesaws drives the electrothermal tube dolly (15) that seesaws to seesaw in simulation system casing (1), electrothermal tube seesaw dolly (15) drive electrothermal tube (14) seesaw in simulation system casing (1).

9. in accordance with the method for claim 7, it is characterized in that: electrothermal tube heating-up temperature T in step 3 ₃value be 20 DEG C ~ 80 DEG C, frozen soil environment temperature T in step 5 ₄value be-20 DEG C ~ 30 DEG C, snowfall temperature T in step 6 ₁value be-25 DEG C ~ 0 DEG C, in step 7, temperature T is infiltrated in snowfall ₂value be-20 DEG C ~ 20 DEG C.