CN220339364U - Sedimentation monitoring device - Google Patents

Abstract

The utility model relates to the technical field of settlement monitoring devices and discloses a settlement monitoring device which comprises a floating marker post fixed on a building wall body and a reference component fixed in a soil layer in a pouring mode, wherein an electrode contact is arranged at the front end of the floating marker post, a resistor is fixedly arranged in the reference component, the electrode contact is movably contacted with the resistor, and a test box is further fixedly arranged on the floating marker post. The conductive needle is positioned in the middle of the resistor, the resistance value detected by the conductive needle is recorded as a reference value, the conductive needle moves after the foundation where the wall body is positioned is settled, the resistance changes, the movement amount of the conductive needle is converted through the change value, and in addition, the resistor can horizontally move in the resistor outer shell, so that when the building wall body is inclined and deflected.

Description

Sedimentation monitoring device

Technical Field

The utility model relates to the technical field of sedimentation monitoring devices, in particular to a sedimentation monitoring device.

Background

The utility model provides a foundation subsides monitoring devices is disclosed to prior art (CN 218346286U), concretely relates to foundation subsides monitoring technology field, this application includes wall body, dipperstick, mark needle and brace table, the bottom of brace table is provided with supports adjusting device, the top of brace table is provided with telescoping device, support adjusting device includes the cylinder piece, the surface and the brace table fixed connection of cylinder piece, the one end rotation of cylinder piece is connected with first threaded rod, the surface threaded connection of first threaded rod has the screw rectangular rod, threaded through-hole has all been seted up at the both ends of screw rectangular rod, threaded through-hole's inner wall threaded connection has the second threaded rod, the bottom rotation of second threaded rod is connected with the slipmat, this application is through setting up support adjusting device for adjustable horizontal position when the brace table is placed on uneven road surface, but under the effect of second independent height-adjusting threaded rod, makes it can carry out secondary adjustment on original regulation basis.

However, due to the structural design of the measuring ruler 4 and the marking needle 5, the two can only perform displacement in the vertical direction, but the existing building settlement is inclined at the same time of the lower side, and in such a case, the measuring ruler 4 and the marking needle 5 can displace in the horizontal direction to cause the side walls of the measuring ruler 4 and the marking needle 5 to abut against each other and be blocked.

Disclosure of Invention

The utility model aims to solve the technical problems that: in order to overcome the problems presented above, a sedimentation monitoring device is provided which solves the problems presented above.

The utility model solves the technical problems by adopting the following technical scheme:

the utility model provides a subside monitoring devices, includes the floating pole of fixing on building wall to and pour the benchmark part of fixing in the soil layer the front end of floating pole is equipped with electrode contact the fixed resistance that is equipped with in the benchmark part, electrode contact mobilizable with resistance contact still be fixed on the floating pole be equipped with the test box be equipped with resistance electric connection's resistance value detection part and with the signal transmitter of the outside transmission of change resistance value in the test box, still be equipped with the battery to the power supply of electrical apparatus in the test box.

Preferably, the device further comprises a reference rod poured in the soil layer, wherein a resistor outer shell is fixedly arranged at the upper end of the reference rod, a resistor is arranged in the resistor outer shell, and the resistor is in an upward open cylinder shape.

Preferably, two symmetrical conductive needles are fixedly arranged at the front end of the floating pole, a first wire connected with the conductive needles is buried in the floating pole, the other end of the first wire is connected with a power supply, and the conductive needles are propped against the inner wall of the resistor in a sliding manner.

Preferably, the lower end of the resistor is connected with a second wire extending outwards, the resistance value detection component is connected in series on a circuit of the second wire and a power supply, a permanent magnet block is fixedly arranged at the insulation part of the lower end of the resistor, and the permanent magnet block is magnetically adsorbed with the bottom wall of the resistor shell.

Preferably, a supporting rod is fixedly arranged at the upper end of the reference rod, an indicating transparent sheet is fixedly arranged on the supporting rod, the indicating transparent sheet is a transparent material flat sheet, a plurality of equally spaced concentric circle indicating lines are arranged on the indicating transparent sheet, and a laser spot lamp for emitting light upwards is fixedly arranged on the floating rod.

Preferably, the floating pole is sleeved with a rain-proof sleeve which is opened downwards, and the rain-proof sleeve is not contacted with the resistor outer shell.

The utility model has the advantages and positive effects that: after the installation is finished, the conductive needle is positioned in the middle of the resistor, the resistance value detected by the resistor is recorded as a reference value, when the foundation where the wall body is positioned is settled, the conductive needle moves, the resistance changes, the movement amount of the conductive needle is converted through the change value, in addition, the resistor can horizontally move in the resistor outer shell, when the building wall body is obliquely deflected, the resistor can horizontally move, the relative movement of the floating post and the resistor is ensured, and the distance to which direction the building wall body is deflected can be known by observing the concentric circle indication line indicated by the laser after the laser spot lamp is opened, so that the device is more scientific and reasonable compared with the prior art.

Drawings

The utility model will be further described with reference to the drawings and examples.

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic view of the structure of FIG. 1;

fig. 3 is an enlarged schematic view of fig. 1.

Detailed Description

The utility model will now be described in further detail with reference to the accompanying drawings. The drawings are simplified schematic representations which merely illustrate the basic structure of the utility model and therefore show only the structures which are relevant to the utility model.

Embodiments of the utility model are described in further detail below with reference to the attached drawing figures:

as shown in fig. 1-3, the settlement monitoring device comprises a floating pole 11 fixed on a building wall body 10, and a reference component poured and fixed in a soil layer, wherein the front end of the floating pole 11 is provided with an electrode contact, a resistor is fixedly arranged in the reference component, the electrode contact is movably contacted with the resistor, a test box 13 is fixedly arranged on the floating pole 11, a resistance value detection component electrically connected with the resistor and a signal transmitter 12 for transmitting a variable resistance value outwards are arranged in the test box 13, and a storage battery for supplying power to an electric device is further arranged in the test box 13.

Preferably, the device further comprises a reference rod 18 poured in a soil layer, a resistor outer shell 19 is fixedly arranged at the upper end of the reference rod 18, a resistor 22 is arranged in the resistor outer shell 19, and the resistor 22 is in an upward open cylinder shape.

Preferably, two symmetrical conductive needles 23 are fixedly arranged at the front end of the floating pole 11, a first wire 15 connected with the conductive needles 23 is embedded in the floating pole 11, the other end of the first wire 15 is connected with a power supply, and the conductive needles 23 are in sliding contact with the inner wall of the resistor 22.

Preferably, the lower end of the resistor 22 is connected with a second wire 14 extending outwards, the resistance value detecting component is connected in series with a circuit of the second wire 14 and the power supply, a permanent magnet block 24 is fixedly arranged on an insulating part at the lower end of the resistor 22, and the permanent magnet block 24 is magnetically adsorbed to the bottom wall of the resistor housing 19.

Preferably, a supporting rod 17 is fixedly arranged at the upper end of the reference rod 18, an indicating transparent sheet 21 is fixedly arranged on the supporting rod 17, the indicating transparent sheet 21 is a transparent flat sheet, a plurality of concentric circle indicating lines with equal intervals are arranged on the indicating transparent sheet 21, and a laser spot lamp 16 for emitting upward light is fixedly arranged on the floating mark rod 11.

Preferably, a rain-proof sleeve 20 which is opened downwards is sleeved on the floating pole 11, and the rain-proof sleeve 20 is not contacted with the resistor outer shell 19.

In particular, after the installation, the conductive needle 23 is located in the middle of the resistor 22, and the resistance value detected in this way is recorded as a reference value, when the foundation where the wall body is located is subsided, the conductive needle 23 will move, so that the resistance changes, and the movement amount of the conductive needle 23 is converted through the change value, in addition, the resistor 22 is designed to horizontally move in the resistor housing 19, so that when the building wall body 10 is obliquely deflected, the resistor 22 can translate, thereby ensuring the relative movement of the floating post 11 and the resistor 22, and by opening the laser spot lamp 16, the direction of which the building wall body 10 is deflected can be known by observing the concentric circle indication line indicated by the laser, so that the method is more scientific and reasonable compared with the prior art.

It should be emphasized that the examples described herein are illustrative rather than limiting, and therefore the utility model is not limited to the examples described in the detailed description, but rather falls within the scope of the utility model as defined by other embodiments derived from the technical solutions of the utility model by those skilled in the art.

Claims (6)

1. A sedimentation monitoring device, characterized in that: including fixing floating pole (11) on building wall (10) to and pour the benchmark part of fixing in the soil layer the front end of floating pole (11) is equipped with electrode contact fixed in the benchmark part be equipped with the resistance, electrode contact mobilizable with the resistance contact still be fixed on floating pole (11) be equipped with test box (13) be equipped with in test box (13) with resistance value detection part and with the signal transmitter (12) of the outside transmission of resistance value of change, still be equipped with the battery to the power supply of electrical components in test box (13).

2. A sedimentation monitoring device according to claim 1, wherein: the novel soil-layer resistor is characterized by further comprising a reference rod (18) poured into the soil layer, wherein a resistor outer shell (19) is fixedly arranged at the upper end of the reference rod (18), a resistor (22) is arranged in the resistor outer shell (19), and the resistor (22) is in a cylindrical shape with an upward opening.

3. A sedimentation monitoring device according to claim 2, wherein: the front end of the floating pole (11) is fixedly provided with two symmetrical conductive needles (23), a first lead (15) connected with the conductive needles (23) is buried in the floating pole (11), the other end of the first lead (15) is connected with a power supply, and the conductive needles (23) are in sliding abutting connection with the inner wall of the resistor (22).

4. A sedimentation monitoring device according to claim 3, wherein: the lower end of the resistor (22) is connected with a second lead (14) which extends outwards, the resistance value detection component is connected in series to a circuit of the second lead (14) and a power supply, a permanent magnet block (24) is fixedly arranged at the insulation part of the lower end of the resistor (22), and the permanent magnet block (24) is magnetically adsorbed with the bottom wall of the resistor shell (19).

5. A sedimentation monitoring device according to claim 4, wherein: the upper end of the reference rod (18) is fixedly provided with a supporting rod (17), the supporting rod (17) is fixedly provided with an indicating transparent sheet (21), the indicating transparent sheet (21) is a transparent material flat sheet, the indicating transparent sheet (21) is provided with a plurality of concentric circle indicating lines at equal intervals, and the floating rod (11) is fixedly provided with a laser spot lamp (16) for upwardly radiating light.

6. A sedimentation monitoring device according to claim 5, wherein: the floating post (11) is sleeved with a rain-proof sleeve (20) which is downwards opened, and the rain-proof sleeve (20) is not contacted with the resistor outer shell (19).