CN217537874U - Concrete detects restoration monitoring integration protection system - Google Patents

Abstract

The utility model provides a concrete inspection restores monitoring integration protection system relates to building structure protection technical field, and the main objective provides a protection sealing effect well and conveniently overhauls and the integration protection system of monitoring. The system includes a protection module; a sensor; a processor; and a warning device. Wherein, protection module includes: a building envelope structure; a protective sealing layer; a separate cavity layer. The outer surface of the building envelope structure body is provided with a protective sealing layer, the interior of the building envelope structure body is provided with a plurality of independent cavity layers in a layered mode, the outer surface of the protective sealing layer is provided with a cavity opening, and a sensor and a sealing cover can be installed in the cavity opening. The sensor is in signal connection with the processor; the processor is in signal connection with the early warning device.

Description

Concrete detection, repair and monitoring integrated protection system

Technical Field

The utility model belongs to the technical field of the building protection technique and specifically relates to a concrete detects restores monitoring integration protection system is related to.

Background

The building field in recent decades in China is rapidly developed, and countless property loss and civil disputes are brought about by water leakage problems of various buildings every year. In the prior art, when the waterproof and anticorrosion sealing construction is carried out on cracks and defective parts of a concrete structure foundation surface, the quality of a protective sealing layer can not meet the quality requirements of the waterproof, anticorrosion and protection of the full sealing of a reinforced concrete structure body due to various reasons.

The existing waterproof and anticorrosive sealing detection technology for the concrete structure body cannot detect the sealing effect of a protection system, so that the sealing quality problem of the system is caused, and leakage is caused. After the protection system and the building are delivered and operated, the prior art cannot provide a 24-hour uninterrupted monitoring system and cannot timely monitor the leakage condition of the water leakage part.

The above problems cause the functional failure of the protective layer of the building, and the system cannot detect and monitor in real time. Thereby causing the life span of the building structure to be shortened and the building protection function and the safety of the building structure to be affected. A lot of important losses occur in China due to various building protection problems.

In order to solve the problems, a cast-in-place reinforced concrete building envelope containing a cavity needs to be developed, so that nondestructive maintenance and real-time monitoring on the protection sealing performance of the building envelope are realized.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a concrete inspection restores monitoring integration protection system to protection system and concrete structure defect that arouse to the sealed problem of envelope structure among the solution prior art are difficult to detect, monitor and prosthetic problem. The utility model provides a plurality of technical effects that preferred technical scheme among a great deal of technical scheme can produce see the explanation below in detail.

In order to achieve the above purpose, the utility model provides a following technical scheme:

the utility model provides a pair of concrete inspection restores monitoring integration protection system, include:

a protection module, the protection module comprising:

(1) The building envelope structure body is a cast-in-place reinforced concrete building envelope structure body,

(2) The protective sealing layer is arranged on the outer surface of the building enclosure structure body,

(3) The independent cavity layers are arranged in a layered mode along the thickness direction of the building enclosure structure body, any one layer of independent cavity layer is provided with at least one cavity opening, the cavity opening is formed in the outer surface of the protective sealing layer, and a sensor and/or a sealing cover is installed at the cavity opening;

the sensor is arranged at least one cavity opening of the independent cavity layers on the same layer;

a processor, the sensor in signal connection with the processor;

and the processor is in signal connection with the early warning device.

On the basis of the technical scheme, the utility model discloses can also do following improvement.

As a further improvement, the number of the protection modules is a plurality of, two of adjacent arrangement the protection modules are provided with the same thickness the independent cavity layer is communicated with the layer.

As a further improvement of the present invention, any one of the independent cavity layers is formed by at least one pore channel located in the same layer; when the number of the pore passages in the same layer is multiple, the pore passages are communicated with each other.

As a further improvement of the utility model, the pore is formed by laying after the degradable pipe in the enclosure structure body degrades.

As a further improvement of the present invention, a sensor or a sealing cover is arranged at least one opening of the cavity of any one of the protection modules; all of the individual cavity layers can be sealed by the sealing cover and/or the sensor.

As a further improvement of the present invention, the sensor is at least one or more of a vacuum sensor, a humidity sensor, and a gas sensor.

As a further improvement, the processor can receive the monitoring value collected by the sensor and analyze and pass through the monitoring value the early warning device issues the monitoring early warning.

The utility model provides a construction method for making concrete detection, restoration and monitoring integration protection system, including following step:

s1: based on the preset design requirement of the enclosure structure, installing a reinforcing steel bar net rack on a construction site, and fixing the degradable pipe for constructing the pore passage on the corresponding position of the reinforcing steel bar net rack according to the design requirement;

s2: installing a structure pouring template outside the reinforced net rack, then carrying out concrete pouring, curing and demolding on the reinforced net rack fixed with the degradable pipes to obtain the enclosure structure body, and obtaining the pore channel after the degradable pipes are degraded to form the independent cavity layer;

s3: constructing the protective sealing layer on the building envelope structure, and checking and accepting the sealing performance of the protective sealing layer;

s4: after the protection sealing layer is qualified in acceptance, the protection module is arranged in at least one cavity opening and is sealed through a sealing cover, the independent cavity layer is arranged on the sensor and is located at the outside of the protection module, the processor is connected with the early warning device through signals, the processor can monitor the sensor value in the independent cavity layer, when the sensor value is abnormal, the processor sends early warning information to the early warning device, and the early warning device sends early warning signals.

As a further improvement of the present invention, the S3 step further includes:

s31: carrying out vacuumizing detection on the independent cavity layer closest to the protective sealing layer in the enclosure structure body so as to judge whether the protective sealing layer is qualified;

s32: if the protective sealing layer is qualified, executing the step S4; if the protective sealing layer is not qualified, executing the step S33;

s33: repairing the regional protection sealing layer of the part; and/or performing reverse-operation nondestructive protective sealing material grouting repair on the independent cavity layer subjected to the vacuumizing treatment in the step S31 so as to obtain a protective sealing system meeting the design requirement.

As a further improvement of the present invention, the present invention further comprises:

when the sensor monitors that the state of a monitored value in the independent cavity layer is abnormal, vacuumizing and detecting at least one independent cavity layer which is not provided with the sensor, and if the vacuum state can not be maintained, injecting protective sealing material into the independent cavity layer which can not maintain the vacuum state for repairing;

and when the problem that the monitoring numerical value detected by the sensor is abnormal still cannot be solved after the independent cavity layers without the sensors are repaired, injecting protective sealing materials into the independent cavity layers with the sensors for final repair treatment.

Compared with the prior art, the utility model discloses the embodiment of preferred provides a concrete detection restores monitoring integration protection system possesses following beneficial effect:

(1) The utility model discloses compare in current reinforced concrete envelope structure, reinforced concrete envelope shaping back, no cross construction, its construction is not influenced by ambient temperature, and the construction speed is fast, can shorten building protection construction cycle simultaneously greatly, utilizes built-in pore, carries out nondestructive test to concrete structure's the sealed effect of protection, can reduce envelope protection construction cost.

(2) The utility model discloses a protection system nondestructive test, monitoring system can make reinforced concrete envelope barrier property and structural security more reliable, and its construction quality detectable, can monitor can effectively guarantee building protection system and building structure life-span.

(3) The utility model discloses because the built-in cavity of envelope structure through detecting, monitoring cavity seal, can carry out the continuous monitoring of 24h to envelope structure's the sealed effect of protection, realize the dynamic quality monitoring to envelope and protection system.

(4) During construction and after construction is finished, once cracks or defects in the building envelope are detected, protective sealing materials can be injected into the independent sealing layer to implement nondestructive repair construction, and the problem that the defect repair difficulty of the traditional protective layer and the reinforced concrete internal structure is high is effectively solved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the description below are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a cross-sectional view of a protection module of the concrete detection, repair and monitoring integrated protection system of the present invention;

FIG. 2 is a cross-sectional view of an enclosure structure in the concrete inspection, repair and monitoring integrated protection system of the present invention;

FIG. 3 is an exemplary illustration of the arrangement of the orifices of FIG. 2;

fig. 4 is the utility model relates to a monitoring flow schematic diagram among concrete inspection restoration monitoring integration protection system.

In figure 1, a building envelope; 2. an independent cavity layer; 3. a protective sealing layer; 4. a duct; 5. a sensor; 6. a sealing cover; 7. cavity opening, 7a, left cavity opening, 7b, right cavity opening, 7c, hollow cavity opening.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the technical solutions of the present invention will be described in detail below. It is to be understood that the embodiments described are only some embodiments of the invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative efforts belong to the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and to simplify the description, but do not indicate or imply that the device or element 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. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the present invention can be understood as the case may be, by those of ordinary skill in the art.

The technical solution of the present invention will be specifically described below with reference to the accompanying drawings.

As illustrated in fig. 1, the utility model provides a concrete detection, repair and monitoring integrated protection system, which comprises a protection module; a processor; an early warning device; wherein the protection module includes: the structure comprises an enclosure structure body 1, wherein the enclosure structure body 1 is a cast-in-place reinforced concrete enclosure structure body, the protective sealing layer 3 is arranged on the outer surface of the enclosure structure body 1, a plurality of pore passages 4 are arranged in the enclosure structure body 1 in layers along the thickness direction, the pore passages 4 on the same layer are mutually communicated, the pore passages 4 on different layers are not mutually communicated to form an independent cavity layer 2, at least one cavity opening 7 is arranged on any layer of the independent cavity layer 2, the cavity opening 7 is arranged on the outer surface of the protective sealing layer 3, and a sensor 5 and/or a sealing cover 6 can be arranged on the cavity opening 7;

the sensor 5 is in signal connection with the processor;

the processor is in signal connection with the early warning device.

The protection modules are arranged in a partition mode according to design requirements, the arrangement number of the protection modules is determined according to the design requirements, the adjacent protection modules are internally provided with independent cavity layers which can be communicated with each other on the same layer or not according to the design requirements, and consecutive independent cavity layers formed by the communication mode of crossing the protection modules on the same layer are viewed with the independent cavity layers.

The number and the arrangement mode of independent cavity layer set up according to the design requirement and form in the envelope according to the design requirement independent cavity layer the number and the arrangement mode of pore are under the prerequisite of guaranteeing that envelope 1's intensity and bearing effect satisfy the design requirement, and the number of independent cavity layer 2 in envelope 1 can be three or even more, only need guarantee that all independent cavity layers 2 between mutually independent set up and each other not communicate can.

The pore canal is formed by degrading a degradable pipe laid in the enclosure structure body.

A sensor or a sealing cover is arranged at least one opening of the cavity of any one protection module; all of the individual cavity layers can be sealed by the sealing cover and/or the sensor.

The sensor can select any one or more of a vacuum sensor, a humidity sensor and a gas sensor according to monitoring design requirements.

When the intelligent monitoring system is used, the sensor is responsible for collecting monitoring values, the processor is responsible for processing, analyzing and monitoring values, and the early warning device is responsible for issuing monitoring and early warning.

Example 1:

as shown in fig. 1-3, the utility model provides a pair of concrete detects and restores monitoring integration protection system's envelope structure 1 on be provided with three independent cavity layer 2, and three independent cavity layer 2 is arranged along this envelope structure 1's thickness direction layering respectively, as shown in fig. 2.

In order to ensure that the independent cavity layer 2 can meet the design requirements, as an optional embodiment, the single degradable pipe is arranged in a serpentine shape along the length and/or width direction of the building envelope structure 1, and the structure of the duct 4 is shown in fig. 3.

In this embodiment, cavity openings 7 located on the outer surface of the protective sealing layer 3 are formed at two ends of three independent cavity layers 2 with different depths in the building envelope 1, as shown in fig. 2, the cavity openings of the independent cavity layers 2 are a left cavity opening 7a, a hollow cavity opening 7c, and a right cavity opening 7b. As an alternative embodiment, the hole 4 forming the independent cavity layer 2 is constructed by a degradable pipe penetrating into the building envelope 1. After the reinforced concrete structure of the building envelope structure 1 is hardened and the degradable pipe is degraded, three independent cavity layers 2 formed by the pore channels 4 are formed.

It is noted that the degradable tube may be a capillary tube.

Independent cavity layer 2 can be arranged by single degradable pipe and degrade and form single channel cavity pore 4, also can set up and make the net piece by the pipeline that many degradable pipes connected through connected modes such as concatenation, bonding or threaded connection, forms the netted independent cavity layer of constituteing by many pore 4 after the degradation. May be set according to a specific design.

As shown in fig. 1-2, the independent cavity layer 2 at the middle position is vacuumized and provided with a micro vacuum sensor 5 at the hollow cavity opening 7c, and the other five cavity openings are sealed by sealing covers 6.

The micro vacuum sensor 5 may be configured to break the sealing effect of the individual cavity layer 2 by sensing the pressure in the respective individual cavity layer 2. If the tightness of the independent cavity layer 2 is good, it indicates that the protection module has a good protection and sealing effect, otherwise, it indicates that there are gaps or insufficient tamping compactness in the protection and sealing layer and the cast-in-place reinforced concrete structure, and the corresponding part needs to be subjected to nondestructive maintenance.

As shown in fig. 4, miniature vacuum sensor 5 is responsible for gathering monitoring value, the treater is responsible for handling analysis monitoring value, early warning device is responsible for publishing monitoring early warning, in order to reach above-mentioned effect conveniently, miniature vacuum sensor 5 with be located the outside treater signal connection of protection module, treater signal connection early warning device, the treater can pass through the sensor monitoring sensor value in the independent cavity layer, when sensor value is unusual, the treater sends early warning information and gives early warning device, and early warning device sends early warning signal, and in addition, this early warning device still includes a show end, and this show end can show above-mentioned information and publish early warning information.

The micro vacuum sensor 5 and the processor, the processor and the early warning device can be in signal connection by adopting equipment and a connection method in the prior art, and the specific structure and the working principle of the micro vacuum sensor are in the prior art, and are not described again.

Example 2:

the embodiment provides a method for realizing a concrete detection, repair and monitoring integrated protection system, which comprises the following steps:

s1: based on the preset design requirement of the enclosure structure, installing a reinforcing steel bar net rack on a construction site, and fixing the degradable pipe for constructing the pore passage on the corresponding position of the reinforcing steel bar net rack according to the design requirement;

s2: installing a structure pouring template outside the reinforcing steel bar net rack, then carrying out concrete pouring, curing and demolding on the reinforcing steel bar net rack fixed with the degradable pipes to obtain the enclosure structure body, and obtaining the pore channel after the degradable pipes are degraded to form the independent cavity layer;

s3: constructing the protective sealing layer on the building envelope structure, and checking and accepting the sealing performance of the protective sealing layer;

s4: after the protection sealing layer is qualified in acceptance, it is corresponding protection module's at least one set up the sensor in the cavity opening to seal through the closing cap independent cavity layer, the sensor with be located the outside treater signal connection of protection module, treater signal connection early warning device, the treater can pass through the sensor monitoring independent intraformational sensor value of cavity, when sensor value is unusual, the treater sends early warning information and gives early warning device, and early warning device sends early warning signal.

After the construction of the building envelope structure 1 and the protective sealing layer 3 is completed, the airtightness of the protective sealing layer needs to be checked, and the checking and accepting steps are as follows:

s31: vacuumizing and detecting the independent cavity layer 3 closest to the protective sealing layer in the building envelope to judge whether the protective sealing layer is qualified or not;

s32: if the protective sealing layer 2 is qualified, executing a step S4; if the protective sealing layer is not qualified, executing step S33;

s33: repairing the regional protection sealing layer 2 of the part; and/or performing reverse-construction nondestructive protective sealing material grouting repair on the independent cavity layer subjected to the vacuumizing treatment in the step S31 so as to obtain a protective sealing system meeting the design requirement.

It should be noted that after the processing of the step S33, the independent cavity layer 2 on the other side of the interior of the building envelope 1 closest to the protective sealing layer 3 needs to be vacuumized to determine whether the protective sealing layer 3 is qualified, and if the detection result is unqualified, the step S33 may be repeated for multiple times until a protective sealing system meeting the design requirement is obtained.

The concrete detection, repair and monitoring integrated protection system obtained after the treatment steps can meet design requirements, and after acceptance is qualified, a sensor can be installed at one cavity opening c according to the design requirements and other cavity openings are subjected to sealing treatment. In the daily maintenance process, the protection module can be dynamically monitored for a long time through the processor and the early warning device which are connected with the sensor.

The acceptance and monitoring part in the construction process is described in detail by taking fig. 2 as an example:

(1) And (4) acceptance inspection:

after the construction is finished, in order to detect whether the structure of the corresponding protection sealing system meets the design requirements, the construction quality of the protection sealing layer 3 can be judged by adopting a temporary vacuumizing mode (no sensor needs to be installed at the moment) for the independent cavity layer 2 communicated with the left cavity opening 7 a. If the protective sealing layer has a leakage problem, the protective sealing layer itself can be repaired locally, or the independent cavity layer 2 communicated with the left cavity opening 7a can be repaired by grouting protective materials (reverse method protective repair treatment).

After the restoration detects the completion, to the sealed lid 6 of the one end installation of the independent cavity layer 2 in middle part, seal and the evacuation operation, then cavity opening 7c department installation miniature vacuum sensor 5 and seal cavity opening 7c in its other end, at this moment, the independent cavity layer 2 that is located the middle part is in the negative pressure state, can gather data and realize carrying out real-time supervision to this pressure value through this sensor. And if the data meets the design requirements, the repair is finished.

(2) Monitoring:

in the using and maintaining process of the building, the long-term monitoring of the protection module is realized through the sensor arranged at the opening 7c of the hollow cavity. In the later period, once the data at the sensor is found to be abnormal, it indicates that the closed state in the duct 2 corresponding to the hollow cavity opening 7c is damaged, and problems may occur in the protection system and structure. At this time, the temporary vacuuming detection (at this time, it is not necessary to install a sensor) of the communicated independent cavity layer 2 of the right cavity opening 7b may be selected to detect the state of the protection sealing system. If this independent cavity layer 2 can keep the vacuum state, then explain that the protection system still normally works, if this independent cavity layer 2 can't keep the vacuum state, explain that the protection system suffers destruction, at this moment, can select to inject flexible (or just tough) sealing protection material into the independent cavity layer 2 that communicates through right cavity opening 7b and realize restoreing again to the protection system.

If the independent cavity layer communicated with the left cavity opening 7a is in a cavity state (under the condition that repair is not needed in the previous acceptance stage), the operation can be optionally performed on the independent cavity layer.

If the data at the sensor is recovered to be normal after the repairing step, the repairing is successful; if the abnormality still occurs, the flexible sealing protective material can be injected into the independent cavity layer communicated with the hollow cavity opening 7c at this time so as to repair the protective structure.

The construction method can be applied to a building protection system by utilizing the existing detection and monitoring means and combining a specially designed protection system structure, thereby realizing the monitoring of the building protection system.

The following description will be made with reference to specific applications of the building envelope:

when the enclosure structure body is used as a reinforced concrete structure bottom plate, the construction steps are as follows:

1. and constructing the steel bar net rack according to the design requirement of the enclosure structure.

2. And synchronously carrying out installation and positioning construction of three layers of pipes (capillary net sheets) according to the design requirements of the flexible protection sealing system built in the structure. When the capillary net is installed, the capillary net can be fixed in a binding mode. In addition, the detection unit and the monitoring unit are installed in a channel synchronously.

3. And (5) installing a structural pouring template, and then pouring concrete. It should be noted that the ends of the tube need to be outside the structural casting form.

4. And maintaining and demolding the pouring plate structure according to the operation specification.

5. And (3) detecting according to the technical requirements of the reverse-construction method negative-pressure nondestructive protection detection, if the defect is detected, repairing the defect, and performing rechecking, wherein the next operation is performed after the rechecking is qualified.

6. And installing a sensor, a processor and an early warning device, and testing the sensor, the processor and the early warning device.

7. And after the test is finished, carrying out remote control service test delivery.

When the bottom plate is constructed on site, the protective sealing layer is required to be constructed according to the design requirement of a structural bottom plate protective system maintained by a reverse construction method3。

When the building envelope structure is used as an external wall maintenance structure (including the external walls of overground and underground buildings), the construction steps are as follows:

1. and constructing the steel bar net rack according to the design requirement of the enclosure structure.

2. And synchronously installing and positioning the three layers of pipes (capillary net sheets) according to the design requirements of the flexible protection sealing system arranged in the structure. When the capillary net is installed, the capillary net can be fixed in a binding mode. In addition, the detection unit and the monitoring unit are installed and connected with the channel synchronously.

3. And (5) installing a structural pouring template, and then pouring concrete. It should be noted that the ends of the tube need to be outside the structural casting form.

4. And maintaining and demolding the pouring plate structure according to the operation specification.

5. And detecting according to the technical requirements of negative pressure nondestructive protection detection of a reverse construction method, if the defects are detected, repairing the defects, and rechecking, wherein the next operation is performed after the rechecking is qualified.

6. And installing a sensor, a processor and an early warning device which are matched with the monitoring function, and testing the sensor, the processor and the early warning device.

7. And after the test is finished, carrying out remote control service test delivery.

When the external wall body is constructed on site, the protective sealing layer 3 is required to be constructed according to the design requirement of a structural bottom plate protective system maintained by a reverse construction method.

And (III) when the building enclosure structure is used as a reinforced concrete structure top plate, the construction steps are as follows:

1. and (5) carrying out structural pouring template installation construction according to the design requirements of the top plate of the enclosure structure.

2. And constructing the steel bar net rack according to the design requirement of the enclosure structure.

3. And synchronously installing and positioning the three layers of pipes (capillary net sheets) according to the design requirements of the flexible protection sealing system arranged in the structure. When the capillary net is installed, the capillary net can be fixed in a binding mode. In addition, the detection unit and the monitoring unit are installed in a channel synchronously.

4. And (6) pouring concrete. It should be noted that the ends of the tube need to be outside the structural casting form.

5. And maintaining and demolding the pouring plate structure according to the operation specification.

6. And (3) detecting according to the technical requirements of the reverse-construction method negative-pressure nondestructive protection detection, if the defect is detected, repairing the defect, and performing rechecking, wherein the next operation is performed after the rechecking is qualified.

7. And (3) installing a sensor, a processor and an early warning device which are matched with the monitoring function, and testing the sensor, the processor and the early warning device.

8. And after the test is finished, carrying out remote control service test delivery.

When the roof is constructed on site, the protective sealing layer 3 is required to be constructed according to the design requirement of a roof protection system of a top-down maintenance structure.

By the method, the construction and installation of the concrete detection, repair and monitoring integrated protection system can be realized.

Claims (7)

1. The utility model provides a concrete inspection restoration monitoring integration protection system which characterized in that includes:

the protective module comprises an enclosure structure body, a protective sealing layer and independent cavity layers, the enclosure structure body is a cast-in-place reinforced concrete enclosure structure body, the protective sealing layer is arranged on the outer surface of the enclosure structure body, the independent cavity layers are arranged in layers along the thickness direction of the enclosure structure body,

any layer of independent cavity layer is provided with at least one cavity opening, the cavity opening is arranged on the outer surface of the protective sealing layer, and a sensor and/or a sealing cover are/is arranged at the cavity opening;

the sensor is arranged at least one cavity opening of the independent cavity layers on the same layer;

a processor, the sensor in signal connection with the processor;

and the processor is in signal connection with the early warning device.

2. The concrete detecting, repairing and monitoring integrated protection system according to claim 1, wherein the number of the protection modules is multiple, and the independent cavities in two adjacent protection modules and with the same thickness are in layer communication.

3. The concrete detecting, repairing and monitoring integrated protection system according to claim 1, wherein any one of the independent cavity layers is formed by at least one hole channel located in the same layer; when the number of the pore passages in the same layer is multiple, the pore passages are communicated with each other.

4. The concrete detecting, repairing and monitoring integrated protection system according to claim 3, wherein the hole is formed by degradable pipes laid in the enclosure body after degradation.

5. The concrete detecting, repairing and monitoring integrated protection system according to claim 1, wherein a sensor or a sealing cover is arranged at least one cavity opening of any one of the protection modules; all of the individual cavity layers can be sealed by the sealing cover and/or the sensor.

6. The concrete inspection, repair and monitoring integrated protection system according to claim 1, wherein the sensor is at least one or more of a vacuum sensor, a humidity sensor, and a gas sensor.

7. The concrete detecting, repairing and monitoring integrated protection system according to claim 1, wherein the processor is capable of receiving and analyzing the monitoring values collected by the sensor and issuing a monitoring and early warning through the early warning device.

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