FR2901291A1 - Soil settlement measuring device for e.g. construction, has sensor integrated to foundations and transmitting signal relative to settlement of soil to acquiring unit, where signal corresponds to difference between two pressures - Google Patents

Abstract

The device has an acquiring unit (40), and a sensor (10) integrated to foundations (2) and transmitting a signal e.g. electrical current, relative to settlement of soil (4) to the acquiring unit. The sensor is arranged interior of the foundations, where the signal corresponds to a difference between two pressures. The acquiring unit displays information, relative to the settlement depending on the signal, on a screen and transmits the information to a remote displaying unit, where the pressures are respectively measured between two inputs (11, 12) of the sensor.

Description

It therefore becomes very important to be able to measure the settlement at

  using a suitable device to determine when the settlement of the soil is stabilized. According to a second operating mode, depending on the nature of the soil in particular, it may be preferable not to consolidate the soil in a conventional manner for economic and environmental reasons. During the manufacture of a dyke, for example, an operator carries out the foundations of the dam in the ground and then covers them with the embankment constituting the structure of the dike. As before, it is important to measure soil compaction to appreciate the consolidation of this soil. Indeed, for security reasons, the operator will not be able to complete the dyke, for example a road passing on this dike, as long as the consolidation of the soil will not be completed. This measure of settlements can be applied to any structure whose settlements are to be monitored over time. As a result, it is found that at least two procedures for manufacturing a construction require the use of a soil compaction device. Usually, a surveyor measures the displacement of a point of the foundations of the construction. Indeed, the displacement of the foundations being caused by a settlement of the soil on which they rest, the measurement of this displacement is therefore representative of the soil compaction. The surveyor therefore measures the displacement of the foundations with respect to a fixed point which is not subjected to settlement, such as a point around the construction, using a measuring means operating with a laser for example.

  Note that when the construction is carried out according to the second operating mode, it is appropriate that the structure of the construction is provided with an orifice so that the surveyor can measure the displacement of the foundations. This hole must be practiced in the structure or be provided during the realization of the latter. Although effective, the measurement method used may possibly lead to inaccuracies that distort the result. It is understood that to be representative, it is necessary that the measurement method is reproducible very precisely so that the indication relating to the settlement is interpretable. If the measurement conditions vary from one point to another, the settlement can not be accurately evaluated. As a result, only the geometer's know-how guarantees a good reproducibility of the settlement measures. In addition, this solution is binding in the context of the second operating mode since it involves the formation of an orifice in the construction. The present invention aims to provide an active device for measuring soil compaction supporting a construction, overcoming the limitations mentioned above allowing easy to make a reliable measurement. According to the invention, a device for measuring soil compaction supporting a construction provided with foundations is remarkable in that it comprises an acquisition means and a sensor, said sensor being secured to said foundations and sending a signal relative to the settlement of said ground by means of acquisition.

  As a result, when the soil settles due to the weight of the construction, the foundations tend to sink deeper into the soil. It is the same for the sensor which is secured to these foundations, being fixed to the bottom of the foundations or even arranged inside these foundations. The sensor then sends a signal representative of the displacement that it has undergone by means of acquisition. This device is relatively simple and does not require destructive acts of construction for its layout. In addition, no operator must intervene to perform the measurement, the device being automatic, which ensures reliable and representative measures of settlement. According to a first embodiment, the acquisition means displays, on a screen provided for this purpose, information relating to the settlement which depends on the signal sent by the sensor. According to a second embodiment, the acquisition means transmits information, which depends on the signal sent by the sensor, relating to the settlement to a remote display means. This display means can then be in the premises of the operator carrying out the construction for example. As a result, it will not be useful to move to the construction to visualize the settlement information. The transmission of this information to the remote display means can be done by usual means, means implementing the teletransmission principles for example.

  In addition, the acquisition means may optionally process the signal received by the sensor so that the information is displayed in a particular format. Furthermore, the signal sent by the sensor to the acquisition means corresponds to a difference between a first and a second pressure, these first and second pressures being respectively measured between a first and a second sensor inputs. The device then advantageously comprises a first pipe opening on the one hand on the first input of said sensor, as well as on the other hand in the open air on a determined reference plane which is not subjected to the settlement of the soil supporting the construction . Therefore, the first input of the sensor measures a first static pressure of the air taken at the end of the first pipe which opens onto a fixed reference plane, the reference plane not likely to collapse under the effect of the compression of the ground supporting the construction. Furthermore, the device comprises a second pipe filled with water which opens on said second input of said sensor as well as on said reference plane. By definition, the reference plane is vertically higher than the sensor. More specifically, the second pipe opens on the reference plane at the bottom of a main tank, the level of water contained in the main tank being maintained at a fixed height relative to the reference plane via a setting means. The sensor then measures a second pressure equal to the sum of the static pressure of the air, exerted on the level of water in the reservoir at the reference plane, and the pressure exerted by the measured water column. extends from the second inlet of the sensor to the water level maintained at a fixed height, said measured water column thus including a primary column contained by the second pipe plus a secondary water column contained in the main reservoir .

  However, the fixed height separating the water level in the main reservoir from the reference plane is maintained at a constant value. Thus, when the sensor moves under the effect of soil compaction, the primary water column contained in the second pipe increases which increases by the same the water column measured by the sensor and therefore the second pressure. Therefore, the signal sent to the acquisition means, proportional to the difference between the second pressure and the first pressure, increases in turn. An operator will therefore be able to record the increase in the settlement by displaying on the acquisition means according to the first embodiment, or on the remote display means according to the second embodiment, information processed by the acquisition means. which depends on the signal sent by the sensor.

  Advantageously, the adjusting means comprises a water discharge means arranged in the main reservoir, a first end of the discharge means opening to the fixed height at which water is maintained in the main tank.

  The water level can not then exceed this fixed height of water. In fact, if the volume of water were to increase, the surplus water, relative to the water level at the fixed height, would be automatically evacuated by the evacuation means, a pipe for example.

  In addition, the adjustment means is ideally provided with a secondary reservoir secured to a second end of the discharge means. The excess water mentioned above is then discharged into the secondary tank.

  Furthermore, according to a variant of the invention, the adjustment means is provided with a pump transferring the water contained in the secondary tank to the main tank. This pump is used to inject water into the main tank so that the water level is constant, the volume of water present in the main tank may decrease under the effect of soil compaction. In addition, a length, variable over time as a function of settlement, separating the sensor from the reference plane, the first pipe is advantageously able to cover this variable length, regardless of the extent of soil compaction. Similarly, a length, variable over time depending on the settlement of the soil on which the construction is based, separating the sensor from the reference plane, the second pipe is able to cover this variable length regardless of the extent of settlement. Finally, the sensor sending to the acquisition means a signal relating to the settlement of the ground via an electrical connection, this electrical connection is dimensioned in order to be able to connect said sensor to the acquisition means irrespective of the extent of the settlement.

  The invention and its advantages will appear in more detail in the context of the description which follows with exemplary embodiments given by way of illustration with reference to the appended figures which represent: FIGS. 1 and 2, schematic views of the device according to FIG. The invention supporting a construction is not compacted, - and - Figure 3, a schematic view of the means of adjustment of the device according to the invention. The elements present in several separate figures are assigned a single reference. Figure 1 shows a schematic view of a device for measuring the settlement of a soil.

  A construction 1, a gravity dam for example, is arranged in a valley V. This construction is provided with foundations 2, arranged on a floor 4, and embankments 3. The floor 4 supporting the foundations 2 of the building 1 having has not been prepared to support the construction 1, it is important to measure the settlement of the soil 4 before finishing the construction 1, for example before making a road on the top 3 'of this construction 1. The device according to the invention for measuring the settlement of the ground 4 comprises a sensor 10 secured to the foundations 2. In Figure 1, the sensor 10 is fixed on the bottom 2 'of the foundations 2 in contact with the ground 4. However, the sensor 10 can be fixed to other areas of the foundations 2 of the construction 1, or even be arranged in the foundations 2 being embedded within these foundations 2. The sensor 10 sends a signal, representative of the settlement of the ground 4 to a means d 40 acquisition. This signal is determined by the sensor 10 as a function of a differential pressure calculated by the sensor 10 between a first pressure, measured at a first input 11 of the sensor 10, and a second pressure measured at a second input 12 of the sensor 10.

  Therefore, the first inlet 11 is connected to a first lower portion 13 'of a first pipe 13, the first upper portion 13 "to a reference plane 20. Note that this reference plane 20 is appropriately selected by a surveyor, for example, so as not to suffer the effect of soil compaction 4 supporting the construction 1. Even if the floor 4 is tilted, the reference plane 20 will not move, so the first pipe 13 opens firstly on the first input 11 of the sensor 10 and secondly in the open air on the reference plane 20. Thus, the first pressure measured by the sensor 10 at its first inlet 11 substantially corresponds to the static pressure of the air at the reference plane 20. In contrast, the second inlet 12 is connected to the second lower portion 14 'of a second pipe 14, the second upper portion 14 "of the second pipe 14 giving on the reference plane 20 to inside a main tank 31. As a result, the second pipe 14 opens on the one hand to the second input 12 of the sensor 10 and, on the other hand, on the reference plane 20 to the bottom 31 'of a main tank 31. The reservoir main 31 is filled with water to a water level 21 which is maintained, by a control means not shown in Figures 1 and 2, at a fixed height H1 relative to the reference plane 20. This means of adjustment thus prevents the water level 21 from rising or falling by blocking it at a fixed height H1 with respect to the reference plane 20.

  The second pipe 14 giving on the bottom 31 'of the main tank 31, the second pipe 14 is filled with water, the main tank 31 feeding the second pipe 14 by gravity. Under these conditions, the sensor 10 measures at its second inlet 12 a second pressure equivalent to the sum of the static pressure of the air exerted on the water level 21 and the pressure of the measured water column 50 giving on the second inlet, this water column 50 having a variable height H2 and corresponding to the sum of the height of a primary water column 50 'disposed in the second pipe 14 and the height of a water column The sensor 10 then determines the difference between the first and second pressures, which corresponds to the pressure exerted by the measured water column 50 equal to the density of the first and second pressures. water multiplied by the constant of the acceleration and by the variable height H2 of this measured water column 50. It is noted that the sensor 10 makes it possible to overcome variations in the static pressure of the air, due to a modification conditions c which ensures a reliable measurement. There is no need to consider meteorological data, for example, to compare two separate measurements.

  The sensor 10 then delivers a signal, as a function of the measured difference in pressures, which is solely a function of the variable height H2 and therefore the settlement of the ground 4.

  This signal is an electric current, the intensity of which varies as a function of the measured pressure difference, which is sent to the acquisition means 40 of the device. According to a first embodiment, the acquisition means 40 displays information, relating to the signal transmitted by the sensor 10, on a screen arranged on one side of this acquisition means. An operator can then come daily to record the information displayed by the acquisition means to observe the evolution of the settlement.

  According to a second embodiment, the acquisition means 40 transmits information relating to the signal transmitted by the sensor 10 to a remote display means. An operator no longer needs to move, the information being displayed on a display means disposed in his office for example. Whatever the embodiment, the displayed information may correspond to the intensity of the signal. With the aid of suitable means, a calibration curve for example, the operator deduces the settlement of the soil.

  For example, the sensor, measuring a pressure difference of 10 millibars, sends a signal of 10 milliamperes to the acquisition means which deduces that the information to be displayed is an intensity of 10 milliamperes. The operator then uses ancillary means to conclude that the compaction of the soil 4 is about 10 centimeters. However, according to an automated variant, the acquisition means modifies the signal transmitted by the sensor so that the information displayed is information directly related to the settlement.

  For example, the sensor, measuring a pressure difference of 10 millibars, sends a signal of 10 milliamperes to the acquisition means which deduces that the information to be displayed is a settlement of about 10 centimeters. The operator does not need to perform conversions, this step being performed by the acquisition means. Figure 2 explains the operation of the device if soil compaction 4 occurs. When the floor 4 is sinking, the construction 1 tends to sink into the ground 4. The sensor 10 is secured to the foundations, this sensor 10 will also sink into the ground 4, according to the arrow F. Or, the level water level 21 reached by the measured water column 50 is maintained at a fixed height H1 relative to the reference plane 20. This reference plane 20 does not sag under the effect of soil compaction 4, the height variable H3 of the measured water column 50 increases. The signal sent by the sensor 10 to the acquisition means 40 therefore increases in turn, this increase being reflected on the information that the acquisition means 40 will display, on a screen disposed on one of its faces and / or on remote display means. For example, the sensor, measuring a pressure difference of 20 millibars, now sends a signal of 20 milliamperes which corresponds to a soil settlement 4 of about 20 centimeters, and no longer about 10 centimeters. An operator will then note that the ground 4 has settled down by observing the increase in the value of the displayed information. In addition, when the floor 4 is packed, the length L that must cover the first and second pipes 13, 14, necessarily increases due to the displacement of the sensor 10. This length L to be traveled is a length L variable. As a result, the first and second pipes 13, 14 are able to cover this variable length L, regardless of the soil settlement 4 and therefore the distance to travel. According to a variant of the invention, the first and second pipes 13, 14 are extensible. According to another variant of the invention, the first and second pipes 13, 14 sufficiently exceed the reference plane to cover the variable length L regardless of soil compaction. Nevertheless, care should be taken to verify that the entire second upper end 14 "of the second pipe 14 is below the water level 21. With reference to FIG. 3, the device according to the invention comprises a means of adjustment 30 to maintain the water level 21 of a main tank 31 at a fixed height H1 of a reference plane 20. This adjustable means 30 comprises an evacuation means 33, namely a pipe provided with a first and a second end 33 ', 33 ". The first end 33 'of the evacuation means 33 is arranged in the main tank 31 and opens out at the fixed water level 21. Thus, an overflow of water will be evacuated by the evacuation means 33 to the Outside the main tank 31. The volume of water contained in the main tank can not therefore exceed the fixed water level 21.

  Moreover, the second end 33 "of the evacuation means 33 opens onto a secondary reservoir 32 by being secured to it, whereby the evacuation means 33 allows the main reservoir 31 to empty into a secondary reservoir 32 to maintain the water level 21 fixed in the main tank 31. In addition, the adjustment means 30 is equipped with a pump 35. This pump 35 is connected on the one hand to the secondary reservoir by a pipe 34 and on the other hand , to the main reservoir 31 via a pipe 36. The pump 35 of the control means then operates continuously to transfer the water contained in the secondary reservoir 32 into the main reservoir 31 along the arrow F1. the water level 21 fixed in the main reservoir 31 at a fixed height H1 relative to the reference plane 20. It is noted that the secondary reservoir is provided with a venting 32 'to avoid undergoing depression pro evoked by the suction created by the pump 35.

  The device according to the invention is perfectly reliable since the measurement of settlement depends exclusively on the settlement of the soil 4 supporting the foundations 2 of the construction 1, and not the know-how of a surveyor for example. Naturally, the present invention is subject to many variations as to its implementation. Although several embodiments have been described, it is clear that it is not conceivable to exhaustively identify all the possible modes. It is of course conceivable to replace a means described by equivalent means without departing from the scope of the present invention. Indeed, Figure 1 shows a single device for measuring soil compaction. Nevertheless, it is in particular conceivable to provide a plurality of devices to visualize the settlement of the soil more precisely. An operator will thus be able to determine which part of the ground 4 has settled.

Claims (12)

  1. Device for measuring soil compaction (4) supporting a construction (1) provided with foundations (2), characterized in that it comprises an acquisition means (40) and a sensor (10), said sensor ( 10) being secured to said foundations (2) and sending a signal relative to the settlement of said ground (4) to the acquisition means (40).   2. Device according to claim 1, characterized in that said acquisition means (40) displays on a screen information relating to said settlement depending on said signal.   3. Device according to any one of the preceding claims, characterized in that said acquisition means (40) transmits information, dependent on said signal, relative to said settlement to a remote display means.   4. Device according to any one of the preceding claims, characterized in that said sensor (10) is arranged inside the foundations (2).   5. Device according to any one of the preceding claims, characterized in that said signal corresponds to a difference between a first and a second pressure, said first and second pressures being respectively measured between a first and a second input (11, 12). said sensor (10).   6. Device according to claim 5, characterized in that said device comprises firstly a first pipe (13) opening on said first inlet (11) of said sensor (10) and in the open air on a plane of reference (20) which is not subjected to said settlement and secondly a second pipe (14) filled with water which opens on said second inlet (12) of said sensor (10) and on said reference (20).   7. Device according to claim 6, characterized in that said second pipe (14) opens on said reference plane (20) at the bottom (31 ') of a main tank (31), the water level (21) contained in said main tank (31) being maintained at a fixed height (H1) with respect to said reference plane (20) via a setting means (30).   8. Device according to claim 7, characterized in that said adjusting means (30) comprises an evacuation means (33) arranged in said main reservoir (31), a first end (33 ') of this evacuation means opening at said fixed height (H1) at which water is maintained in said main tank (31) relative to the reference plane (20).   9. Device according to any one of claims 7 to 8, characterized in that, said adjusting means (30) comprising an evacuation means (33) arranged in said main reservoir (31), said adjustment means (30). ) is provided with a secondary reservoir (32) secured to a second end (33 ") of said evacuation means (33).   10. Device according to claim 9, characterized in that said adjusting means (30) is provided with a pump (35) transferring the water contained in the secondary reservoir (32) to the main reservoir (31).   11. Device according to any one of the preceding claims, characterized in that a length (L) variable over time as a function of said settlement separating said sensor (10) from said reference plane (20), said first pipe (11). ) is able to cover said length (L) irrespective of the settlement.   12. Device according to any one of the preceding claims, characterized in that a length (L), variable over time as a function of said settlement, separating said sensor (10) from said reference plane (20), said second pipe (12) is able to cover said length (L) regardless of the settlement.