CN210037544U - Cement soil infiltration equipment - Google Patents

Cement soil infiltration equipment Download PDF

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Publication number
CN210037544U
CN210037544U CN201920440257.7U CN201920440257U CN210037544U CN 210037544 U CN210037544 U CN 210037544U CN 201920440257 U CN201920440257 U CN 201920440257U CN 210037544 U CN210037544 U CN 210037544U
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water
pressure chamber
cement
soil
soil cement
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胡琦
胡焕
方华建
黄星迪
黄天明
竹相
朱海娣
邓以亮
李健平
娄泽峰
王涛
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Dongtong Geotechnical Technology Co Ltd
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Dongtong Geotechnical Technology Co Ltd
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Abstract

The utility model discloses a soil cement infiltration equipment aims at providing one kind and both can carry out the impermeability test of soil cement, can carry out the experimental soil cement infiltration equipment of the osmotic coefficient of soil cement again. The water tank is internally provided with a closed inner cavity for containing water, and the lower part of the water tank is provided with a drainage interface; the pressurizing equipment pressurizes the closed inner cavity; the cement soil infiltration device comprises a vacuum bag, a chassis, an upper cover plate, a pressurizing body positioned between the chassis and the upper cover plate, a pressure chamber arranged on the pressurizing body and penetrating through the upper end surface and the lower end surface of the pressurizing body, a lower sealing ring arranged between the chassis and the lower end surface of the pressurizing body, an upper sealing ring arranged between the upper cover plate and the upper end surface of the pressurizing body, a water inlet pipe arranged on the chassis and communicated with the pressure chamber, a connecting pipeline used for connecting a drainage interface and the water inlet pipe, and a pressure regulating valve arranged on the connecting pipeline.

Description

Cement soil infiltration equipment
Technical Field
The utility model relates to a geotechnical engineering technical field, concretely relates to soil cement infiltration equipment.
Background
The underground cement-soil continuous wall constructed by the TRD construction method and the SMW construction method mainly plays a role in seepage prevention and water stop. The impermeability of the cement-soil continuous wall should meet the self-impermeability requirement of the wall, and the impermeability coefficient should not be larger than 1 x 10-7 cm/s. In the case of the laboratory permeation device mentioned in the current cement-soil related industry standard cement-soil mix design rule, the amount of water that permeates one day and night is rarely about 11mL in terms of the maximum allowable permeation coefficient of 1X 10-7cm/s and the permeation pressure of 0.1MPa (10 m head); however, the current cement soil penetration test is difficult to operate, and the current cement soil penetration test is influenced by water evaporation due to the fact that the amount of penetration water of the penetration test is small, so that the accuracy of the measured penetration test data is inaccurate, and the measurement accuracy of the penetration test is influenced.
SUMMERY OF THE UTILITY MODEL
The utility model aims at providing a both can carry out the impermeability test of cement soil, can carry out the osmotic coefficient test of cement soil again to in the osmotic coefficient test of cement soil, can effectively eliminate because of osmotic test's infiltration water yield is little, receives the water evaporation influence, and reduces the problem of survey accuracy, thereby improves the cement soil infiltration equipment of the experimental survey precision of osmotic coefficient.
The technical scheme of the utility model is that:
a soil cement infiltration apparatus comprising: the water tank is internally provided with a closed inner cavity for containing water, and the lower part of the water tank is provided with a drainage interface; the pressurizing equipment pressurizes the closed inner cavity; the cement soil infiltration device comprises a vacuum bag, a chassis, an upper cover plate, a pressurizing body positioned between the chassis and the upper cover plate, a pressure chamber arranged on the pressurizing body and penetrating through the upper end surface and the lower end surface of the pressurizing body, a lower sealing ring arranged between the chassis and the lower end surface of the pressurizing body, an upper sealing ring arranged between the upper cover plate and the upper end surface of the pressurizing body, a water inlet pipe arranged on the chassis and communicated with the pressure chamber, a connecting pipeline used for connecting a drainage interface and the water inlet pipe, and a pressure regulating valve arranged on the connecting pipeline, a drain pipe communicated with the upper part of the pressure chamber is arranged on the outer lateral surface of the pressurizing body, a drain valve is arranged on the drain pipe, the upper cover plate is provided with a water outlet pipe communicated with the pressure chamber, the pressure chamber is used for placing a cement soil sample to be detected, and the cement soil sample placed in the pressure chamber is hermetically connected with the inner side surface of the pressure chamber; the vacuum bag is used for being connected with the water outlet pipe so that water drained by the water outlet pipe flows into the vacuum bag.
The cement soil infiltration equipment can be used for performing an impermeability test and a permeability coefficient test of cement soil, and can effectively solve the problem that the determination accuracy is reduced due to the influence of water evaporation caused by small amount of infiltration water of the permeability test in the permeability coefficient test of cement soil, so that the determination accuracy of the permeability coefficient test is improved; meanwhile, the utilization rate of the cement soil infiltration equipment is improved, the economic cost of the equipment is reduced, and the repeated configuration of test instruments is reduced.
Preferably, the middle part of the pressure chamber is a conical chamber, the inner diameter of the conical chamber is gradually reduced from bottom to top, and the soil cement sample is conical corresponding to the conical chamber. So, in the penetration test process, water pressure passes through the bottom that the inlet tube on chassis got into the pressure chamber, on the bottom surface of effect offal soil sample, with the up jack-up of soil cement sample to be favorable to making the medial surface sealing connection of soil cement sample and pressure chamber.
Preferably, the outer side surface of the soil cement sample is coated with a wax sealing layer to seal the outer side surface of the soil cement sample, and the gap between the side surface of the soil cement sample and the side surface of the pressure chamber is filled with the wax sealing layer to form a sealed connection between the outer side surface of the soil cement sample and the inner side surface of the pressure chamber. So, can be with the whole lateral surface of sealed cement soil sample, can also guarantee to form sealing connection between the lateral surface of cement soil sample and the medial surface of pressure chamber to in avoiding the penetration test process, water pressure overflows through the clearance between the lateral surface of cement soil sample and the medial surface of pressure chamber, and influences the experimental survey precision of impermeability test and osmotic coefficient.
Preferably, the cement soil infiltration device further comprises a water-permeable stone slab, the water-permeable stone slab is arranged in the pressure chamber and is positioned below the cement soil sample, and the cement soil sample is supported on the chassis through the water-permeable stone slab.
Preferably, the upper part of the pressure chamber is a cylindrical upper chamber, and the connecting port between the water discharge pipe and the pressure chamber is positioned on the side wall of the cylindrical upper chamber.
Preferably, the pressing body is mounted on the chassis by bolts.
Preferably, the upper cover plate is mounted on the base plate or the pressing body by bolts.
Preferably, the pressure distribution valve body comprises a water inlet interface and a plurality of water outlet interfaces communicated with the water inlet interface, the connecting pipeline comprises a front connecting pipe for connecting the water outlet interface with the water inlet interface and a rear connecting pipe for connecting the water outlet interface with the water inlet pipe, the rear connecting pipes correspond to the water outlet interfaces one to one, the pressure regulating valves are arranged on the rear connecting pipes and correspond to the rear connecting pipes one to one, and water inlet pipe valves are arranged on the water inlet pipes. So, advance water piping connection through back connecting pipe and the cement soil penetrant unit who corresponds, can carry out the penetration test on a plurality of cement soil penetrant units simultaneously, carry out the penetration test of multiunit difference simultaneously through the different osmotic pressure of the pressure regulator valve control on the back connecting pipe.
Preferably, the water outlet interface is provided with a water outlet interface valve.
Preferably, the upper surface of the chassis is provided with a lower limiting groove with an upward opening, the lower end of the pressurizing body is positioned in the lower limiting groove, and the lower sealing ring is positioned between the lower end surface of the pressurizing body and the bottom surface of the lower limiting groove.
Preferably, the lower surface of the upper cover plate is provided with an upper limiting groove with a downward opening, the upper end of the pressurizing body is positioned in the upper limiting groove, and the upper sealing ring is positioned between the inner top surface of the upper limiting groove and the upper end surface of the pressurizing body.
A penetration test method by using cement soil penetration equipment sequentially comprises the following steps:
firstly, wiping the surface of a cement soil sample clean, then coating the side surface of the cement soil sample with melted wax, and forming a wax sealing layer on the side surface of the cement soil sample to seal the outer side surface of the cement soil sample; then, putting the cement soil sample and the permeable stone plate into a pressure chamber, and supporting the cement soil sample on the chassis through the permeable stone plate; then, the pressurizing body is locked and installed on the chassis through bolts, so that the lower sealing ring is connected with the chassis and the lower end face of the pressurizing body in a sealing mode, meanwhile, a wax sealing layer of the cement soil sample is filled in a gap between the side face of the cement soil sample and the side face of the pressure chamber, and sealing connection is formed between the outer side face of the cement soil sample and the inner side face of the pressure chamber; therefore, the outer side surface of the cement soil sample and the inner side surface of the pressure chamber can be in sealing connection, and the whole outer side surface of the cement soil sample is sealed, so that the phenomenon that the water pressure overflows through a gap between the outer side surface of the cement soil sample and the inner side surface of the pressure chamber in the penetration test process to influence the measurement precision of the impermeability test and the permeability coefficient test is avoided;
discharging air in the connecting pipeline, and then connecting a water inlet pipe and a water discharging interface through the connecting pipeline;
secondly, adjusting the pressure of the pressure regulating valve to be P0;
secondly, pressurizing the closed inner cavity by using pressurizing equipment, so that water in the water tank enters the bottom of the pressure chamber through a connecting pipeline and a water inlet pipe and passes through the permeable stone plate, the osmotic pressure with the water pressure of P0 is applied to the cement soil sample, and the osmotic pressure is kept for h hours;
and then, gradually increasing the water pressure entering the pressure chamber through a pressure regulating valve so as to gradually increase the osmotic pressure applied to the cement soil sample, keeping the osmotic pressure of each stage for h hours until water seeps out of the upper surface of the cement soil sample, and recording the osmotic pressure P1 at the moment. Thus, the impermeability test of the soil cement sample was performed, and the osmotic pressure P1 of the soil cement sample was measured.
Preferably, the second step is followed by the steps of: thirdly, after the water outlet of the water outlet pipe is stable, the upper cover plate is locked and installed on the chassis or the pressurizing body through the bolt, so that the upper sealing ring is connected with the upper end surfaces of the upper cover plate and the pressurizing body in a sealing manner; and then, closing the drainage valve, connecting a vacuum bag on the water outlet pipe after bubbles in the water outlet pipe are removed completely, enabling water drained by the water outlet pipe to flow into the vacuum bag, and measuring the quality of the vacuum bag in real time in the process. Therefore, the quality of the seepage water flowing into the vacuum bag can be obtained by weighing the quality of the vacuum bag in real time, and then the seepage water quality data obtained by weighing in real time is displayed as a time-seepage water quality curve on a chart to obtain the permeability coefficient of the cement soil sample, so that the permeability coefficient test of the cement soil sample is realized; meanwhile, in the whole penetration test process, the closed inner cavity, the connecting pipeline, the pressure chamber and the inner cavity of the vacuum bag connected with the water outlet pipe are all closed test environments, so that the influence of water evaporation in the penetration test process can be eliminated, the problem that the measurement accuracy is reduced due to the fact that the amount of penetration water in the penetration test is small and the influence of water evaporation is avoided, and the measurement accuracy of the penetration coefficient test is improved.
A penetration test method by using cement soil penetration equipment sequentially comprises the following steps:
firstly, placing a plurality of cement soil penetration devices on a test site, discharging air in a connecting pipeline and a pressure distribution valve body, and then connecting the cement soil penetration devices with water inlet pipes of the corresponding cement soil penetration devices through rear connecting pipes, wherein the rear connecting pipes correspond to the cement soil penetration devices one by one;
secondly, a penetration test is carried out on one of the cemented soil penetration devices, which specifically comprises the following steps:
(1) wiping the surface of the cement soil sample, then coating the side surface of the cement soil sample with the molten wax, and forming a wax sealing layer on the side surface of the cement soil sample to seal the outer side surface of the cement soil sample; then, putting the cement soil sample and the permeable stone plate into a pressure chamber, and supporting the cement soil sample on the chassis through the permeable stone plate; then, the pressurizing body is locked and installed on the chassis through bolts, so that the lower sealing ring is connected with the chassis and the lower end face of the pressurizing body in a sealing mode, meanwhile, a wax sealing layer of the cement soil sample is filled in a gap between the side face of the cement soil sample and the side face of the pressure chamber, and sealing connection is formed between the outer side face of the cement soil sample and the inner side face of the pressure chamber;
(2) adjusting the pressure of the corresponding pressure regulating valve to be P0, and opening a water inlet pipe valve arranged on the corresponding cement soil penetration device;
secondly, pressurizing the closed inner cavity by using pressurizing equipment to ensure that water in the water tank enters the bottom of the pressure chamber where the corresponding cement soil permeation device is placed through the front connecting pipe, the corresponding rear connecting pipe and the water inlet pipe and penetrates through the permeable stone plate, so that the permeation pressure with the water pressure of P0 is applied to the cement soil sample, and the permeation pressure is kept for h hours;
then, gradually increasing the water pressure entering the pressure chamber through the pressure regulating valve so as to gradually increase the osmotic pressure applied to the cement soil sample, keeping the osmotic pressure of each stage for h hours until water seeps out of the upper surface of the cement soil sample, and recording the osmotic pressure P1 at the moment;
(3) when the water outlet of the water outlet pipe is stable, the upper cover plate is locked and installed on the chassis or the pressurizing body through the bolts, so that the upper sealing ring is connected with the upper end surfaces of the upper cover plate and the pressurizing body in a sealing manner; and then, closing the drainage valve, connecting a vacuum bag on the water outlet pipe after bubbles in the water outlet pipe are removed completely, enabling water drained by the water outlet pipe to flow into the vacuum bag, and measuring the quality of the vacuum bag in real time in the process.
And thirdly, returning to the second step, and synchronously performing a penetration test on each cement soil penetration device. So, can carry out the penetration test on a plurality of soil cement penetrant unit simultaneously, carry out the different penetration test of multiunit simultaneously through the different osmotic pressure of the pressure regulator valve control on the back connecting pipe, improve experimental efficiency and the utilization ratio of equipment.
The utility model has the advantages that: the permeability resistance test of the cement soil and the permeability coefficient test of the cement soil can be carried out, and in the permeability coefficient test of the cement soil, the problem that the determination accuracy is reduced due to the fact that the amount of permeation water in the permeability test is small and the permeation water is affected by water evaporation can be effectively solved, so that the determination accuracy of the permeability coefficient test is improved.
Drawings
Fig. 1 is a schematic structural diagram of a soil cement infiltration apparatus according to a first embodiment of the present invention.
Fig. 2 is a schematic structural diagram of a soil cement permeation device according to a first embodiment of the present invention.
Fig. 3 is a schematic structural view of a soil cement infiltration apparatus according to a second embodiment of the present invention.
In the figure:
the water tank 1, the drainage interface 1.1 and the pressurization interface 1.2;
a supercharging device 2;
the device comprises a cement soil permeation device 3, a vacuum bag 3.0, a chassis 3.1, a pressurizing body 3.2, an upper cover plate 3.3, a pressure chamber 3.4, a conical cavity 3.41, a cylindrical upper cavity 3.42, a cylindrical lower cavity 3.43, a lower sealing ring 3.5, an upper sealing ring 3.6, a cement soil sample 3.7, a permeable stone plate 3.8, a water inlet pipe 3.9, a water inlet pipe valve 3.10, a water outlet pipe 3.11, a water outlet valve 3.12, a water outlet pipe 3.13 and a water outlet pipe valve 3.14;
a connecting pipeline 4, a front connecting pipe 4.1 and a rear connecting pipe 4.2;
a pressure regulating valve 5;
a pressure distribution valve body 6, a water inlet interface 6.1 and a water outlet interface 6.2.
Detailed Description
To make the objects, technical solutions and advantages of embodiments of the present invention clearer, the embodiments of the present invention are clearly explained and illustrated below with reference to the accompanying drawings, but the following embodiments are only preferred embodiments of the present invention, not all embodiments. Based on the embodiments in the embodiment, other embodiments obtained by those skilled in the art without any creative work belong to the protection scope of the present invention.
Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below by referring to the drawings are exemplary only for explaining the present solution, and are not construed as limiting the present solution.
These and other aspects of embodiments of the invention will be apparent with reference to the following description and attached drawings. In the description and drawings, particular embodiments of the invention have been disclosed in detail as being indicative of some of the ways in which the principles of the embodiments of the invention may be practiced, but it is understood that the scope of the embodiments of the invention is not limited thereby. On the contrary, the embodiments of the invention include all changes, modifications and equivalents coming within the spirit and terms of the claims appended hereto.
In the description of the present invention, it is to be understood that the terms "thickness", "upper", "lower", "horizontal", "top", "bottom", "inner", "outer", "circumferential", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are used merely for convenience of description and simplification of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., and "a plurality" means one or more unless specifically limited otherwise.
In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly, e.g., as fixed or removable connections or integral parts, either mechanically or electrically, or in communication with each other; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.
The first embodiment is as follows: as shown in fig. 1, the cemented soil infiltration apparatus includes a water tank 1, a pressurizing apparatus 2, and a cemented soil infiltration device 3.
The water tank 1 is internally provided with a closed inner cavity for containing water, and the lower part of the water tank is provided with a water discharge connector 1.1. In this embodiment, the upper portion of the water tank is provided with a pressurization interface 1.2.
The pressurization equipment 2 pressurizes the closed inner cavity, and specifically, the pressurization equipment pressurizes the closed inner cavity through a pressurization interface. In this embodiment, the supercharging device is an air booster pump or an air compressor, and an outlet of the air booster pump or the air compressor is connected with the supercharging interface through a supercharging pipeline.
As shown in fig. 1 and 2, the soil cement infiltration device comprises a vacuum bag 3.0, a permeable stone plate 3.8, a chassis 3.1, an upper cover plate 3.3, a pressurizing body 3.2 positioned between the chassis and the upper cover plate, a pressure chamber 3.4 arranged on the pressurizing body and penetrating through the upper end surface and the lower end surface of the pressurizing body, a lower sealing ring 3.5 arranged between the chassis and the lower end surface of the pressurizing body, an upper sealing ring 3.6 arranged between the upper cover plate and the upper end surface of the pressurizing body, a water inlet pipe 3.9 arranged on the chassis and communicated with the pressure chamber, a connecting pipeline 4 for connecting a drainage interface and the water inlet pipe, and a pressure regulating valve 5 arranged on the connecting pipeline. The pressurizing body is installed on the chassis through bolts. The upper cover plate is mounted on the chassis or the pressurizing body through bolts, and in the embodiment, the upper cover plate is mounted on the chassis through bolts. The water inlet pipe is provided with a water inlet pipe valve 3.10. The outer side surface of the pressurizing body is provided with a drain pipe 3.11 communicated with the upper part of the pressure chamber, and the drain pipe is provided with a drain valve 3.12. The upper cover plate is provided with a water outlet pipe 3.13 communicated with the pressure chamber, and the water outlet pipe is provided with a water outlet pipe valve 3.14.
The pressure chamber 3.4 is used for placing a soil cement sample 3.7 to be detected, and the soil cement sample placed in the pressure chamber is hermetically connected with the inner side surface of the pressure chamber. The soil cement sample placed in the pressure chamber is located below the connection port between the drain pipe and the pressure chamber. The vacuum bag 3.0 is used for connecting with the water outlet pipe 3.13, so that water drained from the water outlet pipe flows into the vacuum bag. In this embodiment, the vacuum bag is connected to the water outlet pipe in a sealing manner.
The middle part of the pressure chamber is a conical chamber 3.41, and the inner diameter of the conical chamber is gradually reduced from bottom to top. The soil cement sample 3.7 is also conical in shape corresponding to the conical chamber. So, in the penetration test process, water pressure passes through the bottom that the inlet tube on chassis got into the pressure chamber, on the bottom surface of effect offal soil sample, with the up jack-up of soil cement sample to be favorable to making the medial surface sealing connection of soil cement sample and pressure chamber.
The outer side of the soil cement sample is coated with a wax sealing layer (not shown in the figure) to seal the outer side of the soil cement sample, and a gap between the side of the soil cement sample and the side of the pressure chamber is filled through the wax sealing layer to form sealing connection between the outer side of the soil cement sample and the inner side of the pressure chamber. So, can be with the whole lateral surface of sealed cement soil sample, can also guarantee to form sealing connection between the lateral surface of cement soil sample and the medial surface of pressure chamber to in avoiding the penetration test process, water pressure overflows through the clearance between the lateral surface of cement soil sample and the medial surface of pressure chamber, and influences the experimental survey precision of impermeability test and osmotic coefficient.
The upper part of the pressure chamber is a cylindrical upper chamber 3.42 which is positioned above the conical chamber and is communicated with the conical chamber. The connecting port between the water discharge pipe and the pressure chamber is positioned on the side wall of the cylindrical upper cavity. The lower part of the pressure chamber is a cylindrical lower chamber 3.43 which is located below the conical chamber and has the same inner diameter as the bottom of the conical chamber.
The permeable stone slab 3.8 is provided with a plurality of gaps which penetrate through the upper and lower surfaces of the permeable stone slab. The slabstone that permeates water sets up in the pressure chamber and is located the below of cement soil sample, and in this embodiment, the slabstone that permeates water is located cylindrical cavity down indoor, and the slabstone that permeates water is circular, and the external diameter of the slabstone that permeates water and the internal diameter cooperation of cylindrical cavity down. The cement soil sample is supported on the chassis through the permeable stone plate.
The upper surface on chassis is equipped with opening lower limiting groove up, and the lower extreme of pressurization body is located lower limiting groove, carries on spacingly through lower limiting groove to the lower extreme of pressurization body. The lower sealing ring is positioned between the lower end surface of the pressing body and the bottom surface of the lower limiting groove.
The lower surface of the upper cover plate is provided with an upper limiting groove with a downward opening, and the upper end of the pressurizing body is positioned in the upper limiting groove. The upper sealing ring is positioned between the inner top surface of the upper limiting groove and the upper end surface of the pressurizing body.
The cement soil infiltration equipment of the embodiment can be used for carrying out an impermeability test of cement soil and an infiltration coefficient test of cement soil, and can effectively solve the problem that the measurement accuracy is reduced due to the fact that the infiltration water amount of the infiltration test is small and the infiltration coefficient test is influenced by water evaporation in the infiltration coefficient test of cement soil, so that the measurement accuracy of the infiltration coefficient test is improved; meanwhile, the utilization rate of the cement soil infiltration equipment is improved, the economic cost of the equipment is reduced, and the repeated configuration of test instruments is reduced; the specific penetration test method is shown in the specific example III and the specific example IV.
In a second embodiment, the remaining structure of the present embodiment refers to the first embodiment, and the difference therebetween is that:
as shown in fig. 3, the soil cement infiltration apparatus further includes a pressure distribution valve body 6. The pressure distribution valve body comprises a water inlet interface 6.1 and a plurality of water outlet interfaces 6.2 communicated with the water inlet interface. In this embodiment, a water outlet port valve (not shown) is disposed on the water outlet port. The connecting pipeline 4 comprises a front connecting pipe 4.1 for connecting the drainage interface and the water inlet interface and a rear connecting pipe 4.2 for connecting the water outlet interface and the water inlet pipe, and the rear connecting pipes correspond to the water outlet interfaces one to one. The pressure regulating valve 5 is arranged on the rear connecting pipe and corresponds to the rear connecting pipe one by one. So, through the inlet tube connection of back connecting pipe and the cement soil penetrant unit who corresponds, back connecting pipe and cement soil penetrant unit one-to-one realize setting up a plurality of cement soil penetrant unit in parallel, can carry out the penetration test on a plurality of cement soil penetrant unit simultaneously, carry out the penetration test of multiunit difference simultaneously through the different osmotic pressure of the pressure regulator control on the back connecting pipe.
The cement soil infiltration device of the embodiment can be used for performing an impermeability test of cement soil and a permeability coefficient test of cement soil, and the specific infiltration test method is shown in the fifth specific embodiment.
In a third embodiment, a penetration test method using a cemented soil penetration device is provided, and the specific structure of the cemented soil penetration device refers to the first embodiment.
The penetration test method using the cement soil penetration equipment sequentially comprises the following steps:
firstly, discharging air in a connecting pipeline, and then connecting a water inlet pipe and a water discharging interface through the connecting pipeline;
wiping the surface of the cement soil sample, then coating the side surface of the cement soil sample with the molten wax, and forming a wax sealing layer on the side surface of the cement soil sample to seal the outer side surface of the cement soil sample; then, putting the cement soil sample and the permeable stone plate into a pressure chamber, and supporting the cement soil sample on the chassis through the permeable stone plate; then, the pressurizing body is locked and installed on the chassis through bolts, so that the lower sealing ring is connected with the chassis and the lower end face of the pressurizing body in a sealing mode, meanwhile, a wax sealing layer of the cement soil sample is filled in a gap between the side face of the cement soil sample and the side face of the pressure chamber, and sealing connection is formed between the outer side face of the cement soil sample and the inner side face of the pressure chamber; therefore, the outer side surface of the cement soil sample and the inner side surface of the pressure chamber can be in sealing connection, and the whole outer side surface of the cement soil sample is sealed, so that the phenomenon that the water pressure overflows through a gap between the outer side surface of the cement soil sample and the inner side surface of the pressure chamber in the penetration test process to influence the measurement precision of the impermeability test and the permeability coefficient test is avoided;
second, the pressure of the pressure regulating valve is regulated to be P0, for example, P0 is 20 KPa;
then, the pressurizing equipment works to pressurize the closed inner cavity, so that water in the water tank enters the bottom of the pressure chamber through the connecting pipeline and the water inlet pipe and passes through the permeable stone plate, the infiltration pressure with the water pressure of P0 is applied to the cement soil sample, and the infiltration pressure is kept for h hours, for example, h is 1 hour;
then, the water pressure entering the pressure chamber is increased step by step through the pressure regulating valve, so that the osmotic pressure applied to the soil cement sample is increased step by step, and each stage of osmotic pressure is maintained for h hours, for example, h is 1 hour, until water seeps out from the upper surface of the soil cement sample, and the osmotic pressure P1 at this time is recorded. For example, each stage increases 20KPa until the water pressure in the pressure chamber reaches 100 KPa; then, each step is increased by 100KPa until water seeps out from the upper surface of the soil cement sample.
Thus, the impermeability test of the soil cement sample was performed, and the osmotic pressure P1 of the soil cement sample was measured. In the above steps, the upper port of the pressure chamber is in an open state, and the upper cover plate is not installed. The penetration test method using the soil cement penetration apparatus of this example is an impermeability test of a soil cement specimen.
In a fourth embodiment, a penetration test method using a soil cement penetration device is provided, and the concrete structure of the soil cement penetration device refers to the first embodiment.
The penetration test method using the soil cement penetration equipment in the embodiment refers to a third specific embodiment, and the differences are as follows:
the second step is followed by the steps of:
thirdly, after the water outlet of the water outlet pipe is stable, the upper cover plate is locked and installed on the chassis or the pressurizing body through the bolt, so that the upper sealing ring is connected with the upper end surfaces of the upper cover plate and the pressurizing body in a sealing manner;
and then, closing the drainage valve, connecting a vacuum bag on the water outlet pipe after bubbles in the water outlet pipe are removed, wherein the vacuum bag is hermetically connected with the water outlet pipe, so that water drained by the water outlet pipe flows into the vacuum bag, and the quality of the vacuum bag is measured in real time in the process.
Therefore, the quality of the seepage water flowing into the vacuum bag can be obtained by weighing the quality of the vacuum bag in real time, and then the seepage water quality data obtained by weighing in real time is displayed as a time-seepage water quality curve on a chart to obtain the permeability coefficient of the cement soil sample, so that the permeability coefficient test of the cement soil sample is realized; specifically, according to the time interval required by the test specification, a plurality of permeation water quality data are read and recorded, and are displayed as a time-permeation water quality curve on a graph, so that the permeability coefficient of the cement soil sample is obtained, and the permeability coefficient test of the cement soil sample is realized.
In the whole penetration test process, the closed inner cavity, the connecting pipeline, the pressure chamber and the inner cavity of the vacuum bag connected with the water outlet pipe are all closed test environments, so that the influence of water evaporation in the penetration test process can be eliminated, the problem that the determination accuracy is reduced due to the fact that the amount of penetration water in the penetration test is small and the influence of water evaporation is avoided, and the determination accuracy of the penetration coefficient test is improved.
In a fifth embodiment, a penetration test method using a cemented soil penetration device is described, and the specific structure of the cemented soil penetration device is as described in the second embodiment.
The penetration test method using the cement soil penetration equipment sequentially comprises the following steps:
firstly, placing a plurality of cement soil penetration devices on a test site, discharging air in a connecting pipeline and a pressure distribution valve body, and then connecting the cement soil penetration devices with water inlet pipes of the corresponding cement soil penetration devices through rear connecting pipes, wherein the rear connecting pipes correspond to the cement soil penetration devices one by one;
secondly, a penetration test is carried out on one of the cemented soil penetration devices, which specifically comprises the following steps:
(1) wiping the surface of the cement soil sample, then coating the side surface of the cement soil sample with the molten wax, and forming a wax sealing layer on the side surface of the cement soil sample to seal the outer side surface of the cement soil sample; then, putting the cement soil sample and the permeable stone plate into a pressure chamber, and supporting the cement soil sample on the chassis through the permeable stone plate; then, the pressurizing body is locked and installed on the chassis through bolts, so that the lower sealing ring is connected with the chassis and the lower end face of the pressurizing body in a sealing mode, meanwhile, a wax sealing layer of the cement soil sample is filled in a gap between the side face of the cement soil sample and the side face of the pressure chamber, and sealing connection is formed between the outer side face of the cement soil sample and the inner side face of the pressure chamber;
(2) regulating the pressure of the pressure regulating valve to be P0, for example, P0 is 20 KPa; opening a water inlet pipe valve arranged on the corresponding cement soil penetration device;
then, the pressurizing equipment works to pressurize the closed inner cavity, so that water in the water tank enters the bottom of the pressure chamber where the corresponding cement soil permeation device is placed through the front connecting pipe, the corresponding rear connecting pipe and the water inlet pipe and penetrates through the permeable stone plate, the permeation pressure with the water pressure of P0 is applied to the cement soil sample, and the permeation pressure is kept for h hours, for example, h is 1 hour;
then, gradually increasing the water pressure entering the pressure chamber through the pressure regulating valve so as to gradually increase the osmotic pressure applied to the cement soil sample, keeping the osmotic pressure of each stage for h hours until water seeps out of the upper surface of the cement soil sample, and recording the osmotic pressure P1 at the moment; for example, each stage increases 20KPa until the water pressure in the pressure chamber reaches 100 KPa; then, each step is increased by 100KPa until water seeps out from the upper surface of the soil cement sample. Thus, the impermeability test of the soil cement sample was performed, and the osmotic pressure P1 of the soil cement sample was measured. In the step (1) and the step (2), the upper port of the pressure chamber is in an open state, and the upper cover plate is not installed.
(3) When the water outlet of the water outlet pipe is stable, the upper cover plate is locked and installed on the chassis or the pressurizing body through the bolts, so that the upper sealing ring is connected with the upper end surfaces of the upper cover plate and the pressurizing body in a sealing manner; and then, closing the drainage valve, connecting a vacuum bag on the water outlet pipe after bubbles in the water outlet pipe are removed completely, enabling water drained by the water outlet pipe to flow into the vacuum bag, and measuring the quality of the vacuum bag in real time in the process. Therefore, the quality of the seepage water flowing into the vacuum bag can be obtained by weighing the quality of the vacuum bag in real time, and then the seepage water quality data obtained by weighing in real time is displayed as a time-seepage water quality curve on a chart to obtain the permeability coefficient of the cement soil sample, so that the permeability coefficient test of the cement soil sample is realized; specifically, according to the time interval required by the test specification, a plurality of permeation water quality data are read and recorded, and are displayed as a time-permeation water quality curve on a graph, so that the permeability coefficient of the cement soil sample is obtained, and the permeability coefficient test of the cement soil sample is realized.
And thirdly, returning to the second step, and synchronously performing a penetration test on each cement soil penetration device. So, can carry out the penetration test on a plurality of soil cement penetrant unit simultaneously, carry out the penetration test of multiunit difference simultaneously through the different osmotic pressure of the pressure regulator valve control on the back connecting pipe, improve experimental efficiency.
The above, only be the utility model discloses a preferred embodiment, it is not right the utility model discloses do any restriction, all according to the utility model discloses the technical entity all still belongs to any simple modification, change and equivalent transformation of doing above embodiment the utility model discloses technical scheme's protection scope.

Claims (10)

1. A soil cement infiltration apparatus, comprising:
the water tank is internally provided with a closed inner cavity for containing water, and the lower part of the water tank is provided with a drainage interface;
the pressurizing equipment pressurizes the closed inner cavity;
the cement soil infiltration device comprises a vacuum bag, a chassis, an upper cover plate, a pressurizing body positioned between the chassis and the upper cover plate, a pressure chamber arranged on the pressurizing body and penetrating through the upper end surface and the lower end surface of the pressurizing body, a lower sealing ring arranged between the chassis and the lower end surface of the pressurizing body, an upper sealing ring arranged between the upper cover plate and the upper end surface of the pressurizing body, a water inlet pipe arranged on the chassis and communicated with the pressure chamber, a connecting pipeline used for connecting a drainage interface and the water inlet pipe, and a pressure regulating valve arranged on the connecting pipeline, a drain pipe communicated with the upper part of the pressure chamber is arranged on the outer lateral surface of the pressurizing body, a drain valve is arranged on the drain pipe, the upper cover plate is provided with a water outlet pipe communicated with the pressure chamber, the pressure chamber is used for placing a cement soil sample to be detected, and the cement soil sample placed in the pressure chamber is hermetically connected with the inner side surface of the pressure chamber; the vacuum bag is used for being connected with the water outlet pipe so that water drained by the water outlet pipe flows into the vacuum bag.
2. The soil cement infiltration apparatus of claim 1, wherein the pressure chamber has a conical chamber in the middle, and the conical chamber has an inner diameter gradually decreasing from bottom to top, and the soil cement sample is conical corresponding to the conical chamber.
3. The soil cement infiltration apparatus of claim 2, wherein the outer side of the soil cement sample is coated with a wax sealing layer to seal the outer side of the soil cement sample, and a gap between the side of the soil cement sample and the side of the pressure chamber is filled with the wax sealing layer to form a sealed connection between the outer side of the soil cement sample and the inner side of the pressure chamber.
4. The soil cement infiltration apparatus of claim 2 or 3, wherein the soil cement infiltration device further comprises a water permeable stone slab disposed within the pressure chamber and below the soil cement specimen supported on the chassis by the water permeable stone slab.
5. The soil cement penetration apparatus as claimed in claim 2 or 3, wherein the upper part of said pressure chamber is a cylindrical upper chamber, and the connection port between said water discharge pipe and said pressure chamber is located on the side wall of said cylindrical upper chamber.
6. A soil cement infiltration apparatus according to claim 1, 2 or 3, wherein said pressurizing body is mounted on the chassis by means of bolts.
7. A soil cement infiltration apparatus according to claim 1, 2 or 3, wherein said upper cover plate is mounted on the chassis or the pressurizing body by means of bolts.
8. The soil cement penetration device as claimed in claim 1, 2 or 3, further comprising a pressure distribution valve body, wherein the pressure distribution valve body comprises a water inlet port and a plurality of water outlet ports communicated with the water inlet port, the connection pipe comprises a front connection pipe for connecting the water outlet port with the water inlet port and a rear connection pipe for connecting the water outlet port with the water inlet pipe, the rear connection pipes are in one-to-one correspondence with the water outlet ports, the pressure regulating valves are disposed on the rear connection pipes, the pressure regulating valves are in one-to-one correspondence with the rear connection pipes, and the water inlet pipe is provided with a water inlet pipe valve.
9. The soil cement infiltration apparatus of claim 8, wherein a water outlet port valve is provided on said water outlet port.
10. A soil cement infiltration apparatus according to claim 1, 2 or 3, wherein the upper surface of the base plate is provided with a lower retaining groove with an upward opening, the lower end of the pressurizing body is located in the lower retaining groove, and the lower seal ring is located between the lower end surface of the pressurizing body and the bottom surface of the lower retaining groove.
CN201920440257.7U 2019-04-02 2019-04-02 Cement soil infiltration equipment Active CN210037544U (en)

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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN109946213A (en) * 2019-04-02 2019-06-28 东通岩土科技股份有限公司 Soil cement penetration equipment and permeability test method
CN113418854A (en) * 2021-06-30 2021-09-21 中国建材检验认证集团咸阳有限公司 Device and method for measuring permeability coefficient of natural sodium bentonite impermeable liner

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN109946213A (en) * 2019-04-02 2019-06-28 东通岩土科技股份有限公司 Soil cement penetration equipment and permeability test method
CN113418854A (en) * 2021-06-30 2021-09-21 中国建材检验认证集团咸阳有限公司 Device and method for measuring permeability coefficient of natural sodium bentonite impermeable liner

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