CN209690208U - Rich water thin silt construction freezing method effect simulation system - Google Patents
Rich water thin silt construction freezing method effect simulation system Download PDFInfo
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- CN209690208U CN209690208U CN201822183916.1U CN201822183916U CN209690208U CN 209690208 U CN209690208 U CN 209690208U CN 201822183916 U CN201822183916 U CN 201822183916U CN 209690208 U CN209690208 U CN 209690208U
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Abstract
The utility model discloses a kind of rich water thin silt construction freezing method effect simulation systems, including simulated experiment case, brine circulation system, multiple detection components, data collecting instrument and computer, the simulated experiment case includes that buffering divides water cavity and soil body chamber, buffering divides water cavity side to be connected to the seepage flow brine tank of peripheral hardware, buffering divides the other side of water cavity to be connected with soil body chamber, soil body chamber can be penetrated by buffering the moisture divided in water cavity, the soil body is intracavitary to set the model soil body, and the model soil body includes the clay layer B of the clay layer A of lower part, the fine sand layer at middle part and top;The cold end of the brine circulation system is connected with the model soil body.The utility model has the following beneficial effects: the apparatus and method of the utility model can effectively simulate the construction freezing method in rich water thin silt, obtain qualitative conclusion, the influence factor for studying rich water fine sand layer manual pipe jacking effect, provides theoretical foundation for the critical issue of construction freezing method.
Description
Technical field
The utility model relates to a kind of experimental provisions, and in particular to a kind of rich water thin silt construction freezing method effect mould
Quasi- system.
Background technique
China has all built subway in many cities, because of the difference in city, locating for regional geology condition also have difference.
When needing the subway built to be located at high pressure-bearing water-rich sand layer (such as No. 12 line gardens way stations of Wuhan subway), excavation of foundation pit depth
Greatly, geological conditions and surrounding enviroment are complicated, underground bearing water head height, are level-one ultra-deep foundation pit, environmental effect is bright in digging process
It is aobvious.For meet No. 4 line stations are installed under the subway line shield in this region, need under the main structure of subway station of operation into
Row frozen construction abolishes original and goes along with sb. to guard him ground-connecting-wall, and freezes the effect of thin silt, freezes the mechanical property of the soil body and freeze curtain
The stability of curtain will abolish portal and shield crossing construction generates potential risk.If frozen construction at a distance from structure base slab not
Foot excessively freezes or owes to freeze that existing gardens way station main structure will be caused to deform, leads to security risk, to engineering construction
The control of journey and decision bring huge challenge;And when frozen construction when the flow velocity of water, frozen construction freezing pipe distribution spacing with
And the salt content of underground water is an important factor for influencing frozen construction effect.Based on this, need for construction freezing method to periphery
Environment and existing subway station influence development system research, and the research for rich water thin silt construction freezing method effect is
The most important thing.
In order to study rich water thin silt construction freezing method effect, the experimental study for carrying out indoor model is one
Kind is relatively more intuitive and has the mode of reference frame.
Summary of the invention
The purpose of this utility model is that in view of the deficiencies of the prior art, providing a kind of rich water thin silt freezing process
Construction effect simulation system.
The technical solution adopted in the utility model are as follows: a kind of rich water thin silt construction freezing method effect simulation system,
Including simulated experiment case, brine circulation system, multiple detection components, data collecting instrument and computer, the simulated experiment luggage
The soil body chamber that buffering is divided water cavity and simulated is included, buffering divides water cavity side to pass through the seepage flow salt water of point water inlet pipe in water chamber and peripheral hardware
Case connection, buffering divide the other side of water cavity to be connected with soil body chamber, and soil body chamber can be penetrated by buffering the moisture divided in water cavity, and the soil body is intracavitary
The model soil body is set, the model soil body includes the clay layer B of the clay layer A of lower part, the fine sand layer at middle part and top;The salt water follows
The cold end of loop system is connected with the model soil body, provides cold source for the model soil body;The detection components dispersed placement is in the model soil body
Interior, detection components, data collecting instrument and computer are sequentially connected, the parameter of each measuring point in the detection components detection model soil body, and
Parameter signal is sent to data collecting instrument;The parameter signal of data collecting instrument acquisition testing component transmission is simultaneously transmitted to calculating
Machine.
According to the above scheme, the simulated experiment case is additionally provided with the storage chamber being connected to by outlet pipe with external reservoir, stores
The two sides that water cavity and buffering divide water cavity to be respectively arranged on simulated experiment case.The buffering is divided between water cavity and soil body chamber, soil body chamber with
Between storage chamber, separated respectively by being provided with the partition of window, tile strainer on the window.
According to the above scheme, the brine circulation system includes refrigeration unit, brine tank and multiple groups freezing pipe, the refrigeration machine
The heat source pipeline of group is connected to the entrance of brine tank, and the outlet of brine tank passes through pipeline respectively and is connected to freezing pipe, and freezing pipe is worn
Crossing the bottom plate of simulated experiment case, to protrude into the soil body intracavitary, and horizontal interval is embedded in fine sand layer.
According to the above scheme, the brine tank is connected to by pipeline with the entrance of water pump A, and the entrance of water pump A and brine distributing ring connects
Logical, the outlet of brine distributing ring is connected to by freezing water inlet pipe with the entrance of each freezing pipe respectively, and the outlet of each freezing pipe is freezed back
Flow tube is connected with the entrance of brine collecting ring, and the outlet of brine collecting ring is connected to brine tank.
According to the above scheme, the brine circulation system further includes constant temperature water tank, and the outlet of brine collecting ring passes through pipeline and constant temperature
Water tank connection, constant temperature water tank are connected to by pipeline with brine distributing ring, and constant temperature water tank is connected to through water pump B with a point water inlet pipe in water chamber.
According to the above scheme, the freezing pipe includes being all made of inner and outer tubes made of copper pipe, the outer wall and outer tube of inner tube
Inner wall formed return flow line;One end of said inner tube, which is equipped with, freezes water inlet, and the other end of inner tube is connected to return flow line;Institute
It states outer tube and offers and freeze refluxing opening;It is described to freeze water inlet pipe and be connected with water inlet is freezed, freeze return pipe and freezes refluxing opening
It is connected.
According to the above scheme, the detection components include multiple temperature sensors and multiple pressure gauges, the temperature sensor
Dispersion is embedded at each temperature measuring point of fine sand layer respectively with pressure gauge.
According to the above scheme, the buffering, which is divided, fills stone in water cavity.
The utility model has the following beneficial effects: the apparatus and method of the utility model are with can effectively simulating rich water Extra-fine sand
Construction freezing method in layer is simulated when seepage velocity, amount of salt in groundwater, freezing tube spacing difference, the difference of freezing efficiency,
To obtain qualitative conclusion, the influence factor of rich water fine sand layer manual pipe jacking effect is studied, is the key of construction freezing method
Problem provides theoretical foundation;Method described in the utility model is easy to operate, adaptable.
Detailed description of the invention
Fig. 1 is the overall structure diagram of one specific embodiment of the utility model.
Fig. 2 is the schematic diagram of simulated experiment case in the present embodiment.
Fig. 3 is the structural schematic diagram of freezing pipe in the present embodiment.
Fig. 4 is the arrangement schematic diagram one of freezing pipe and temperature measuring point in the present embodiment.
Fig. 5 is the arrangement schematic diagram two of freezing pipe and temperature measuring point in the present embodiment.
Wherein: 1, simulated experiment case;1.1, buffering divides water cavity;1.2, divide water inlet pipe in water chamber;1.3, clay layer A;1.4, powder
Fine sand layer;1.5, clay layer B;1.6, storage chamber outlet pipe;1.7, storage chamber;1.8, strainer;2, data collecting instrument;3, it calculates
Machine;4, reservoir;5, refrigeration unit;6, brine tank;7, freezing pipe;7.1, freeze water inlet;7.2, freeze refluxing opening;8, water pump
A;9, brine distributing ring;10, freeze water inlet pipe;11, freeze return pipe;12, brine collecting ring;13, water pump B;14, seepage flow brine tank;15, permanent
Reservoir;16, temperature measuring point;17, water pump C.
Specific embodiment
The utility model in order to better understand is in the following with reference to the drawings and specific embodiments made the utility model further
Ground description.
A kind of rich water thin silt construction freezing method effect simulation system as depicted in figs. 1 and 2, including simulated experiment
Case 1, brine circulation system, multiple detection components, data collecting instrument 2 and computer 3, the simulated experiment case 1 include buffering point
Water cavity 1.1 and the soil body chamber simulated, buffering divide 1.1 side of water cavity to pass through the seepage flow salt of point water inlet pipe in water chamber 1.2 and peripheral hardware
The connection of water tank 14 (divides equipped with water pump C17) between water inlet pipe in water chamber 1.2 and the seepage flow brine tank 14 of peripheral hardware, buffering divides water cavity 1.1
The other side be connected with soil body chamber, soil body chamber can be penetrated by buffering the moisture that divides in water cavity 1.1, and the soil body is intracavitary to set the model soil body;Institute
The cold end for stating brine circulation system is connected with the model soil body, provides cold source for the model soil body;The detection components dispersed placement in
In model clay body, detection components, data collecting instrument 2 and computer 3 are sequentially connected, each measuring point in the detection components detection model soil body
Parameter, and parameter signal is sent to data collecting instrument 2;The parameter signal that 2 acquisition testing component of data collecting instrument is sent is simultaneously
It is transmitted to computer 3.
Preferably, the model soil body includes the clay layer A1.3, the fine sand layer 1.4 at middle part and the clay on top of lower part
Layer B1.5.
Preferably, the simulated experiment case 1 is additionally provided with (is stored by the storage chamber 1.7 that outlet pipe is connected to external reservoir 4
Water cavity 1.7 is connected to by storage chamber outlet pipe 1.6 with reservoir 4), storage chamber 1.7 and buffering divide water cavity 1.1 to be respectively arranged on simulation
The two sides of experimental box 1.The buffering is divided between water cavity 1.1 and soil body chamber, between soil body chamber and storage chamber 1.7, is passed through respectively
The partition for being provided with window separates, and tiles strainer 1.8 (can be metal mesh) on the window, and geotechnological gauze is coated on strainer 1.8, with
Layer of sand is stopped to flow and play a role in filtering.
Preferably, the brine circulation system includes refrigeration unit 5, brine tank 6 and multiple groups freezing pipe 7, the refrigeration machine
The heat source pipeline of group 5 is connected to the entrance of brine tank 66, and the outlet of brine tank 6 passes through pipeline respectively and is connected to freezing pipe 7, freezes
It is intracavitary that the bottom plate that pipe 7 passes through simulated experiment case 1 protrudes into the soil body, and horizontal interval is embedded in fine sand layer 1.4.
Preferably, the brine tank 6 is connected to the entrance of water pump A8 by pipeline and (configures salt water control valve on the pipeline
Door), water pump A8 is connected to the entrance of brine distributing ring 9, and the outlet of brine distributing ring 9 is respectively by freezing water inlet pipe 10 and each freezing pipe 7
Entrance connection, the outlet of each freezing pipe 7 are freezed return pipe 11 and are connected with the entrance of brine collecting ring 12, the outlet of brine collecting ring 12 and salt
The connection of water tank 6 (configures salt water control valve) on the pipeline.Preferably, the brine circulation system further includes constant temperature water tank 15,
The outlet of brine collecting ring 12 be connected to constant temperature water tank 15 by pipeline (arranging clear water control valve on the pipeline), constant temperature water tank 15 and
Be connected to by pipeline with brine distributing ring 9 (on the pipeline be arranged clear water control valve), constant temperature water tank 15 through water pump B13 and divide water cavity into
Water pipe 1.2 is connected to.
Preferably, the freezing pipe 7 includes being all made of inner and outer tubes made of copper pipe, the outer wall of inner tube and outer tube it is interior
Wall forms return flow line;One end of said inner tube, which is equipped with, freezes water inlet 7.1, and the other end of inner tube is connected to return flow line;Institute
It states outer tube and offers and freeze refluxing opening 7.2;It is described to freeze water inlet pipe 10 and be connected with water inlet 7.1 is freezed, freeze return pipe 11 with
Freeze refluxing opening 7.2 to be connected.
Preferably, the detection components include multiple temperature sensors and multiple pressure gauges, the temperature sensor and pressure
Dispersion is embedded at each temperature measuring point 16 of fine sand layer 1.4 power meter respectively;Temperature measuring point 16 also is provided with around freezing pipe 7.
Preferably, the buffering, which is divided in water cavity 1.1, fills stone, prevents the current scour powder of point water inlet pipe in water chamber 1.2 thin
Layer of sand 1.4 and there is quicksand phenomenon, while obtain uniform water flow and resist layer of sand lateral pressure.
In the present embodiment, the overall dimensions of simulated experiment case 1 are 1.5m × 1m × 1.5m (L × W × H), wherein buffering point
The width of water cavity 1.1, soil body chamber and storage chamber 1.7 is respectively 0.1m, 1.3m and 0.1m.The side plate of simulated experiment case 1 uses 5mm
Thick and 10mm thickness steel plate be made (freezing pipe 7 is installed in the wherein steel plate aperture of 10mm thickness, the steel plate outside of aperture with 20cm away from
From multiple groups floor is equidistantly spaced from, to guarantee the rigidity of simulated experiment case 1).The model soil body in simulated experiment case 1 includes 0.2m
The clay layer B1.5, clay layer A1.3 and clay layer B1.5 of the fine sand layer 1.4 of thick clay layer A1.3,1.2m thickness, 0.2m thickness
For heat-insulated and water proof.Buffering, which is divided, fills the stone that partial size is about 10mm in water cavity 1.1, prevent the water of point water inlet pipe in water chamber 1.2
Stream washes away fine sand layer 1.4 and quicksand phenomenon occurs, while obtaining uniform water flow and resisting layer of sand lateral pressure.Window size
For 1000mm × 600mm.The length of freezing pipe 7 is 300mm.Freeze return pipe and freeze water inlet pipe 10 specification be respectively adopted be The low temperature resistant hose of pressure resistance.The temperature sensor is copper-constantan thermocouple sensor.Described point of water cavity
Water inlet pipe 1.2 is all made of with storage chamber outlet pipe 1.6Steel pipe, and it is furnished with control valve, flowmeter, pressure
Table by control valve, flowmeter, water pressure gauge, and then controls sand bed seepage flow speed.Three pressures are set in fine sand layer 1.4
Power table measures the water pressure in fine sand layer 1.4.
Below according to the design of the present embodiment, rich water thin silt construction freezing method effect simulation experimental method is carried out
Explanation.The parameter likelihood ratio of experimental provision model sees attached list 1, the contracting of experiment geometry than mainly according to the diameter of existing freezing pipe 7 with
Influence of Temperature Field range determines, using φ 15mm × 1mm seamless copper pipe come φ 146mm × 8mm in model engineering in the present embodiment
Freezing pipe 7, geometric similarity is than being about 1:10.During the experiment, the influence for research 7 spacing of freezing pipe to experiment effect, freezes
Knot pipe 7 is arranged using following methods: freezing pipe 7 takes 5 × 5 arrangements, needs 25 freezing pipes 7 altogether, opens up on simulated experiment case 1
59 7 preformed holes of freezing pipe, each 7 preformed hole of freezing pipe can meet freezing pipe 7 and divide equipped with sealing devices such as bolt and waterstop pads
Not with the arrangement mode of tri- kinds of interval Ss of 5cm, 10cm, 15cm.Relative position such as Fig. 4 and Fig. 5 institute of freezing pipe 7 and temperature measuring point 16
Show;In vertical plane of the model experiment spacing from 15cm, arranged on the interarea of frozen region, interface, axial plane with the spacing of S/2
Temperature measuring point 16;14 temperature measuring points 16 are respectively arranged at four angles of frost wall (outer surface of freezing pipe 7), and upstream and downstream middle section is each
2 temperature measuring points 16 are laid, upstream and downstream freezing pipe 7 in experimentation is monitored and hands over circle and frost wall development, among frost wall
4 temperature measuring points 16 are laid for monitoring frost wall in-house development in region, and frozen region amounts to 64 temperature measuring points 16;Except frozen region
Axial plane, interface, interarea are arranged outside measuring point, and salt water liquid in-out pipeline also carries out temperature monitoring.It is rich in method described in the utility model
The freezing efficiency of pigment fine sand Freezing stratum as rapid construction is evaluated according to the temperature of temperature measuring point 16, and temperature is lower, and effect is better;Freeze
Spacing, salt water salt content and the percolation flow velocity of pipe 7 are the variables for influencing final 16 temperature of temperature measuring point height (freezing efficiency).
The parameter likelihood ratio table of 1 experimental provision model of table
A kind of rich water thin silt construction freezing method effect simulation method, specifically comprises the following steps:
Step 1: providing each component of above-mentioned experimental provision and installing, is filled in the model soil body and freezing pipe 7, temperature pass
Leak test is suppressed before sensor installation, guarantees leakproofness, safety, promotes to test and smoothly stablizes progress;
Step 2: the infiltration coefficient of measurement fine sand layer 1.4: taking experiment to carry out indoor Seepage Experiment with Extra-fine sand, use
The infiltration coefficient of constant head infiltration coefficient experiment test layer of sand, for calculating corresponding flow different in flow rate;
Step 3: filling the model soil body, and freezing pipe 7 and sensor are installed: spreading in the bottom of soil body chamber with a thickness of 20cm
Clay layer A1.3 (point two layers fill, every layer of 10cm tamps while filling, and guarantees that clay layer A1.3 filling is closely knit);It fills out
Fine sand layer 1.4 is built, is tamped in filling;The position and 16 position of each temperature measuring point (as shown in Figure 4 and Figure 5) of freezing pipe 7 are designed,
Freezing pipe 7 and temperature sensor embedment are fixed, each region filling is paid attention to during filling uniformly, freezing pipe 7 is avoided to occur
Inclination;After fine sand layer 1.4 fills completion, compacting is paved into upper surface fills clay layer B1.5 and (fill, every layer point two layers
10cm tamps while filling, and guarantees that argillic horizon filling is closely knit), finally the thermocouple wire of temperature sensor is summarized,
Draw simulated experiment case 1;
Step 4: open brine circulation system, make constant temperature clear water uniformly, it is continuous, flow slowly into fine sand layer 1.4, to point
After the rate of discharge of water inlet pipe in water chamber 1.2 is stablized, by observing flowmeter, constantly regulate valve in point water inlet pipe in water chamber 1.2 and open
Degree, until obtaining percolation flow velocity needed for experiment;Refrigeration unit 5 is adjusted, salt water in brine tank 6 is made to reach design temperature (this
Experimental design temperature is -25 DEG C), the salt water control valve on 7 tunnel of each water pump and freezing pipe is opened, the number of each temperature sensor is acquired
According to until the Extra-fine sand outside freezing pipe freezes and freezing range extends to designated position (the utility model is for studying each parameter
To the affecting laws of freezing efficiency, therefore designated position can be set in the utility model, and specific bit is set to freezing pipe 7 in the present embodiment
The outside 1cm of radial surface), close brine freezing valve, stop freezing, record freezing pipe 7 outside freeze fine sand layer extension
To the time of designated position;
Step 5: restoring 1.4 temperature of fine sand layer: closing salt water control valve, open each clear water control valve, freezing
Clear water circulation is formed in pipe 7, restores 1.4 temperature of fine sand layer;
Step 6: stop freezing pipe 7 in clear water circulation, repeat step 4 and five progress percolation flow velocities be respectively 0m/d,
10m/d, 20m/d, 40m/d and 60m/d's freezes to test, and acquires the data of each temperature sensor, freezes outside record freezing pipe 7
Fine sand layer expands to the time of designated position;
Step 7: stopping experimental provision, the model soil body is dug out, changes 7 spacing of freezing pipe, repeats step 3~five, respectively
The experiment that 7 spacing of freezing pipe is 15cm, 10cm is carried out, the data of each temperature sensor, the powder freezed outside record freezing pipe 7 are acquired
Fine sand layer expands to the time of designated position;
Step 8: closing the Clean water valve of osmotic system, 500mg/L salt water is prepared in the calcium chloride of seepage flow brine tank 14,
Salt water valve is opened, the salt water of 500mg/L is passed through into fine sand layer 1.4, after water outlet salt content to be detected reaches 500mg/L
Step 4~step 6 is repeated, the saliferous seepage flow Extra-fine sand that salt content is respectively 500mg/L, 1g/L, 2g/L is carried out respectively and freezes
Experiment acquires experimental data;
Step 9: handling acquisition data, draws the collected measuring point temperature of institute and change over time curve;Pass through number
According to screening, obtain each 16 temperature of temperature measuring point under different situations and change over time trend, judged according to temperature changing trend practical
Extra-fine sand freezing efficiency in work progress: if freeze-off time is identical, temperature change is bigger, i.e. the temperature of temperature measuring point 16 is lower, then
Illustrate that freezing efficiency is better;Conversely, temperature change is little if freeze-off time is identical, both the temperature of temperature measuring point 16 was higher, then illustrated
Freezing efficiency is relatively free of so good.In the present embodiment, 7 spacing of freezing pipe is smaller, freezes faster, and construction effect is better;Salt water
Salt content is bigger, freezes faster, and construction effect is better;Percolation flow velocity is bigger, freezes faster, and construction effect is better.
Above description is merely a prefered embodiment of the utility model, is not intended to limit the utility model, for
For those skilled in the art, various modifications and changes may be made to the present invention.All spirit and original in the utility model
Within then, any modification, equivalent replacement, improvement and so on be should be included within the scope of protection of this utility model.
Claims (8)
1. a kind of rich water thin silt construction freezing method effect simulation system, which is characterized in that including simulated experiment case, salt water
The circulatory system, multiple detection components, data collecting instrument and computer, the simulated experiment case include that buffering divides water cavity and carries out mould
Quasi- soil body chamber, buffering divide water cavity side to be connected to seepage flow brine tank, and buffering divides the other side of water cavity to be connected with soil body chamber, buffer
Divide the moisture in water cavity that can penetrate into soil body chamber, the soil body is intracavitary to set the model soil body, and the model soil body includes the clay layer A of lower part, middle part
Fine sand layer and top clay layer B;The cold end of the brine circulation system is connected with the model soil body, provides for the model soil body
Cold source;In in model clay body, detection components, data collecting instrument and computer are sequentially connected the detection components dispersed placement, inspection
The parameter of each measuring point in component detection model clay body is surveyed, and parameter signal is sent to data collecting instrument;Data collecting instrument acquisition
The parameter signal of detection components transmission is simultaneously transmitted to computer.
2. rich water thin silt construction freezing method effect simulation system as described in claim 1, which is characterized in that the mould
Draft experiment case is additionally provided with the storage chamber being connected to by outlet pipe with external reservoir, and storage chamber and buffering divide water cavity to be respectively arranged on mould
The two sides of draft experiment case;The buffering is divided between water cavity and soil body chamber, between soil body chamber and storage chamber, respectively by being provided with window
The partition of mouth separates, and tile strainer on the window.
3. rich water thin silt construction freezing method effect simulation system as described in claim 1, which is characterized in that the salt
Water circulation system includes refrigeration unit, brine tank and multiple groups freezing pipe, the heat source pipeline of the refrigeration unit and entering for brine tank
Mouth connection, the outlet of brine tank pass through pipeline respectively and are connected to freezing pipe, and the bottom plate that freezing pipe passes through simulated experiment case protrudes into soil
In body cavity, and horizontal interval is embedded in fine sand layer.
4. rich water thin silt construction freezing method effect simulation system as claimed in claim 3, which is characterized in that the salt
Water tank is connected to by pipeline with the entrance of water pump A, and water pump A is connected to the entrance of brine distributing ring, and the outlet of brine distributing ring passes through jelly respectively
Knot water inlet pipe is connected to the entrance of each freezing pipe, and the outlet of each freezing pipe is freezed return pipe and is connected with the entrance of brine collecting ring, collection
The outlet of liquid circle is connected to brine tank.
5. rich water thin silt construction freezing method effect simulation system as claimed in claim 3, which is characterized in that the salt
Water circulation system further includes constant temperature water tank, and the outlet of brine collecting ring is connected to by pipeline with constant temperature water tank, constant temperature water tank with pass through pipe
Road is connected to brine distributing ring, and constant temperature water tank is connected to through water pump B with a point water inlet pipe in water chamber.
6. rich water thin silt construction freezing method effect simulation system as claimed in claim 4, which is characterized in that the jelly
Knot pipe includes being all made of inner and outer tubes made of copper pipe, and the outer wall of inner tube and the inner wall of outer tube form return flow line;In described
One end of pipe, which is equipped with, freezes water inlet, and the other end of inner tube is connected to return flow line;The outer tube, which offers, freezes refluxing opening;Institute
State and freeze water inlet pipe and be connected with water inlet is freezed, freeze return pipe with freeze refluxing opening and be connected.
7. rich water thin silt construction freezing method effect simulation system as described in claim 1, which is characterized in that the inspection
Surveying component includes multiple temperature sensors and multiple pressure gauges, and dispersion is embedded in powder respectively for the temperature sensor and pressure gauge
At each temperature measuring point of fine sand layer.
8. rich water thin silt construction freezing method effect simulation system as claimed in claim 2, which is characterized in that described slow
Punching, which divides, fills stone in water cavity.
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN109540959A (en) * | 2018-12-25 | 2019-03-29 | 武汉市市政建设集团有限公司 | Rich water thin silt construction freezing method effect simulation system and method |
CN109557128A (en) * | 2018-12-10 | 2019-04-02 | 重庆大学 | A kind of simulation test case for frozen construction |
-
2018
- 2018-12-25 CN CN201822183916.1U patent/CN209690208U/en active Active
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN109557128A (en) * | 2018-12-10 | 2019-04-02 | 重庆大学 | A kind of simulation test case for frozen construction |
CN109557128B (en) * | 2018-12-10 | 2021-06-29 | 重庆大学 | Simulation test box for freezing construction |
CN109540959A (en) * | 2018-12-25 | 2019-03-29 | 武汉市市政建设集团有限公司 | Rich water thin silt construction freezing method effect simulation system and method |
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