CN105136595A - Data acquisition and traceability system and method for detection of concrete strength through rebound method - Google Patents

Abstract

The invention discloses a data acquisition and traceability system for detection of concrete strength through a rebound method; the system is used for data acquisition and traceability of detection of the concrete strength and includes a data acquisition instrument, a cloud computing platform and an identification sticker with an RFID radio frequency chip; the data acquisition instrument is used for typing in engineering information and detection information of a measured component, reading code text information of the surface of the identification sticker and identification information in the RFID, and transmitting the engineering information, the detection information, the code text information and the identification information to the cloud computing platform; the code text information or the identification information is associated with corresponding code text information or identification information stored in the cloud computing platform or the data acquisition instrument for traceability. The invention also discloses a data acquisition and traceability method for detection of the concrete strength through the rebound method. With adopting of the system and the method, the detection information of a measured region can be subjected to paperless real-time acquisition and be uploaded, the detection information is efficiently processed, the problem that the detection information is falsified in an original data transmission process is avoided, and the source also can be quickly traced.

Description

Translated fromChinese

回弹法检测混凝土强度的数据采集、溯源系统及其方法Data acquisition, traceability system and method for detecting concrete strength by rebound method

技术领域technical field

本发明属于混凝土抗压强度检测技术领域，具体涉及一种回弹法检测混凝土强度的数据采集、溯源系统及其方法。The invention belongs to the technical field of concrete compressive strength detection, and in particular relates to a data acquisition and traceability system and a method for detecting concrete strength by a rebound method.

背景技术Background technique

回弹法是用一弹簧驱动的重锤，通过弹击杆(传力杆)，弹击混凝土表面，并测出重锤被反弹回来的距离，以回弹值(反弹距离与弹簧初始长度之比)作为与强度相关的指标，来推定混凝土强度的一种方法。回弹法主要采用的设备是回弹仪。回弹仪可以分为数式回弹仪和指针直读式回弹仪(机械式回弹仪)。回弹法的主要工作流程是：测试检测区域的碳化深度，使用回弹仪在该区域测得16个回弹值，并记录下碳化深度和回弹值，按照《回弹法检测混凝土抗压强度技术规程》JGJ/T23-2011等现行规范的计算方法进行抗压强度推算。The rebound method is to use a spring-driven heavy hammer to hit the concrete surface through the bullet rod (dowel), and measure the distance that the heavy hammer is bounced back, and use the rebound value (the difference between the rebound distance and the initial length of the spring) Ratio) is used as a strength-related index to estimate the strength of concrete. The main equipment used in the rebound method is the rebound instrument. The rebound hammer can be divided into a digital rebound hammer and a pointer direct reading rebound hammer (mechanical rebound hammer). The main workflow of the rebound method is: test the carbonation depth of the detection area, use the rebound meter to measure 16 rebound values in this area, and record the carbonation depth and rebound value, and test the concrete compression resistance according to the rebound method The compressive strength is estimated by the calculation method of current specifications such as Strength Technical Regulations JGJ/T23-2011.

在实际检测中，现有的工作模式存在以下几方面的问题：1、由于数字式回弹仪成本高及维护保养困难的原因，仍以机械式回弹仪为主，采用机械式回弹仪需要人工在纸上抄录和送回室内再次录入计算机处理大批量的回弹值，效率低，还易出错；2、无法对检测过程进行监管，原始数据在出报告前容易被篡改，从而难以保证检测数据的真实性；3、被测构件测区因批荡或粉刷无法溯源。In actual testing, the existing working mode has the following problems: 1. Due to the high cost of the digital rebound hammer and the difficulty in maintenance, the mechanical rebound hammer is still the main one, and the mechanical rebound hammer is adopted It is necessary to manually transcribe on paper and send it back to the room to enter the computer again to process a large number of rebound values, which is inefficient and error-prone. The authenticity of the test data; 3. The test area of the tested component cannot be traced due to plastering or painting.

发明内容Contents of the invention

为了解决上述问题，本发明的目的是提供一种回弹法检测混凝土强度的数据采集、溯源系统，能够对测区的项目信息和检测信息进行无纸化实时采集并上传，高效处理检测信息并避免其在原始资料传送过程中被篡改的问题，还能用于溯源。In order to solve the above problems, the purpose of the present invention is to provide a data acquisition and traceability system for detecting concrete strength by rebound method, which can collect and upload the project information and detection information of the measurement area in real time without paper, efficiently process the detection information and It can avoid the problem of tampering during the transmission of the original data, and it can also be used for traceability.

为实现上述目的，本发明按以下技术方案予以实现的：To achieve the above object, the present invention is realized according to the following technical solutions:

本发明所述回弹法检测混凝土强度的数据采集溯源系统，用于对混凝土强度检测的数据采集和溯源，包括数据采集仪、云计算平台和标识贴；The data acquisition and traceability system for detecting concrete strength by the rebound method of the present invention is used for data acquisition and traceability of concrete strength detection, including a data acquisition instrument, a cloud computing platform and a label;

其中，所述标识贴上设有RFID射频芯片，用于标记混凝土的被测构件的测区；Wherein, the label is pasted with an RFID radio frequency chip, which is used to mark the measuring area of the measured component of the concrete;

所述数据采集仪用于获取被测构件的工程信息和检测信息、读取所述标识贴上的表面的码文信息和RFID内的标识信息，并将所述工程信息、检测信息、码文信息和标识信息传输至云计算平台，所述码文信息和标识信息与存储于云计算平台或数据采集仪中对应的码文信息或标识信息相关联以供溯源。The data acquisition instrument is used to obtain the engineering information and detection information of the component under test, read the code information on the surface on which the logo is pasted and the identification information in the RFID, and collect the engineering information, detection information, code text The information and identification information are transmitted to the cloud computing platform, and the code information and identification information are associated with the corresponding code information or identification information stored in the cloud computing platform or data collector for traceability.

进一步地，所述标识贴为条形码或二维码标识贴。Further, the identification sticker is a barcode or a two-dimensional code identification sticker.

进一步地，所述数据采集仪包括摄像模块、扫描模块、光电转换器、读取模块、输入模块和存储模块；所述摄像模块将拍摄的检测工地、检测人员以及被测区域的照片发送至所述存储模块；所述扫描模块将扫描的标识贴表面的码文信息传输至所述光电转换器，所述光电转换器将所述码文信息转换为数字信息并发送至所述存储模块；所述读取模块对读取的所述RFID射频芯片中的标识信息发送至所述存储模块；所述输入模块将录入的工程信息和检测信息发送至存储模块。Further, the data acquisition instrument includes a camera module, a scanning module, a photoelectric converter, a reading module, an input module and a storage module; The storage module; the scanning module transmits the code information on the surface of the scanned label sticker to the photoelectric converter, and the photoelectric converter converts the code information into digital information and sends it to the storage module; The reading module sends the read identification information in the RFID radio frequency chip to the storage module; the input module sends the entered engineering information and detection information to the storage module.

进一步地，所述数据采集仪上GPS定位模块，用于对检测工地进行定位。Further, the GPS positioning module on the data acquisition instrument is used to locate the inspection site.

进一步地，所述数据采集仪与所述云计算平台通过无线连接。Further, the data collector is wirelessly connected to the cloud computing platform.

进一步地，所述云计算模块包括有加密运算模块，用于对接收的标识信息进行加密、解码。Further, the cloud computing module includes an encryption operation module for encrypting and decoding the received identification information.

为了解决上述问题，本发明的目的是提供一种回弹法检测混凝土强度的数据采集、溯源方法，能对被测构件及其测区进行数据的快速采集和溯源。In order to solve the above problems, the object of the present invention is to provide a data acquisition and traceability method for detecting concrete strength by the rebound method, which can quickly collect and trace data on the measured component and its measurement area.

为实现上述目的，本发明按以下技术方案予以实现的：To achieve the above object, the present invention is realized according to the following technical solutions:

本发明所述的回弹法检测混凝土强度的数据采集、溯源方法，包括采集和溯源步骤；The data acquisition and traceability method for detecting concrete strength by the rebound method of the present invention includes the steps of collection and traceability;

其中，所述采集步骤具体为：Wherein, the collection steps are specifically:

通过数据采集仪获取被测构件的工程信息和检测信息，并实时上传至云计算平台；Obtain the engineering information and detection information of the tested components through the data acquisition instrument, and upload them to the cloud computing platform in real time;

通过数据采集仪扫描贴于测区上所述标识贴表面的码文信息或读取所述RFID射频芯片上的标识信息，与存储于云计算平台或数据采集仪中的码文信息或标识信息相关联；Use the data collector to scan the code information pasted on the surface of the identification sticker on the survey area or read the identification information on the RFID radio frequency chip, and store the code information or identification information in the cloud computing platform or data acquisition instrument Associated;

所述溯源步骤具体为：The traceability steps are specifically:

通过数据采集仪扫描贴于测区上所述标识贴表面的码文信息或读取所述RFID射频芯片上的标识信息，调出对应的工程信息和检测信息。Use the data acquisition instrument to scan the code information pasted on the surface of the label sticker on the survey area or read the label information on the RFID radio frequency chip, and call out the corresponding engineering information and detection information.

进一步地，还包括加密的步骤，具体为：Further, an encryption step is also included, specifically:

从所述RFID射频芯片获取的标识信息需要通过云计算平台内的加密运算模块进行解码换算后，得到与存储于数据采集仪或云计算平台内相关联的标识信息。The identification information obtained from the RFID radio frequency chip needs to be decoded and converted by the encryption operation module in the cloud computing platform to obtain the identification information associated with the storage in the data collector or the cloud computing platform.

进一步地，所述工程信息包括工程项目名称、项目地址、项目负责人和施工单位；Further, the engineering information includes engineering project name, project address, project leader and construction unit;

所述检测信息包括检测工地、检测人员和被测构件的图片信息和回弹检测过程中的检测数据。The detection information includes the detection site, the detection personnel and the picture information of the component under test, and the detection data during the springback detection process.

进一步地，还包括定位的步骤，具体为：Further, a positioning step is also included, specifically:

所述数据采集仪上的GPS定位模块自动获取检测工地的坐标位置。The GPS positioning module on the data acquisition instrument automatically acquires the coordinate position of the detection site.

与现有技术相比，本发明的有益效果是：Compared with prior art, the beneficial effect of the present invention is:

本发明所述的回弹法检测混凝土强度的数据采集、溯源系统，首先是通过数据采集仪实现采集功能，即获取检测现场的检测信息以及工程信息的，并且该工程信息与检测信息实时上传至云计算平台，其中通过数据采集仪扫描贴于测区上所述标识贴表面的码文信息或读取所述RFID射频芯片上的标识信息，与存储于云计算平台或数据采集仪中的码文信息或标识信息相关联，目的在于为后期的溯源提供准备。The data acquisition and traceability system for detecting the strength of concrete by the rebound method described in the present invention first realizes the acquisition function through the data acquisition instrument, that is, obtains the detection information and engineering information of the detection site, and uploads the engineering information and detection information to the Cloud computing platform, wherein the code text information pasted on the surface of the identification sticker on the measurement area is scanned by the data acquisition device or the identification information on the RFID radio frequency chip is read, and the code information stored in the cloud computing platform or the data acquisition device It is associated with document information or identification information in order to provide preparation for later traceability.

当后期需要溯源时，只需读取贴于测区的标识贴表面的码文信息即可，如果被测构件已经粉刷或批荡，即标识贴被遮盖，则通过读取的RFID射频芯片，从而能够从云计算平台调出对应的工程信息和检测信息，实现快速溯源。同时，所述云计算平台还能根据检测信息自动生成检测报告，无需等检测人员在现场抄录完数据，回到室内再录入到计算机内，因此大大提高了检测效率。When traceability is required in the later stage, it is only necessary to read the code information on the surface of the label stickers pasted in the measurement area. If the component under test has been painted or plastered, that is, the label stickers are covered, the read RFID radio frequency chip, In this way, the corresponding engineering information and detection information can be called out from the cloud computing platform to achieve rapid traceability. At the same time, the cloud computing platform can also automatically generate a test report based on the test information, without waiting for the test personnel to finish transcribing the data on site, and then enter it into the computer after returning to the room, thus greatly improving the test efficiency.

本发明所述的回弹法检测混凝土强度的数据采集、溯源方法，通过对贴有RFID射频芯片的标识贴进行读取，与存储的码文信息或标识信息相关联，从而可以对被测构件及其测区进行的位置以及工程信息和检测信息快速溯源。The data acquisition and traceability method for detecting concrete strength by the rebound method of the present invention reads the identification stickers with RFID radio frequency chips and associates them with the stored code information or identification information, so that the measured components can be The location of the survey area, as well as the engineering information and detection information can be quickly traced.

附图说明Description of drawings

下面结合附图对本发明的具体实施方式作进一步详细的说明，其中：Below in conjunction with accompanying drawing, specific embodiment of the present invention is described in further detail, wherein:

图1是本发明实施例提供的一种回弹法检测混凝土强度的数据采集溯源系统的结构示意框图；Fig. 1 is a schematic structural block diagram of a data acquisition and traceability system for detecting concrete strength by a rebound method provided by an embodiment of the present invention;

图2是本发明实施例提供的一种回弹法检测混凝土强度的数据采集溯源系统中数据采集仪的结构示意框图。Fig. 2 is a schematic block diagram of the structure of a data acquisition instrument in a data acquisition and traceability system for detecting concrete strength by a rebound method provided by an embodiment of the present invention.

图中：In the picture:

1：标识贴1: Logo sticker

2：数据采集仪2: Data acquisition instrument

21：摄像模块22：扫描模块23：光电转换器24：读取模块21: camera module 22: scanning module 23: photoelectric converter 24: reading module

25：输入模块26：存储模块27：GPS定位模块25: Input module 26: Storage module 27: GPS positioning module

3：云计算平台3: Cloud Computing Platform

31：加密运算模块31: Encryption operation module

具体实施方式Detailed ways

以下结合附图对本发明的优选实施例进行说明，应当理解，此处所描述的优选实施例仅用于说明和解释本发明，并不用于限定本发明。The preferred embodiments of the present invention will be described below in conjunction with the accompanying drawings. It should be understood that the preferred embodiments described here are only used to illustrate and explain the present invention, and are not intended to limit the present invention.

本发明所述的回弹法检测混凝土强度的数据采集溯源系统，采用带有RFID射频芯片的标识贴1对混凝土的被测构件的测区进行标记，保证了在进行完回弹检测后，即被测构件被批荡或粉刷后，依然能轻松溯源，即实现了可隐藏溯源。同时数据采集仪2内置有采集信息的应用程序，实现无纸化操作，避免了检测过程中人工将检测数据记录在纸上的方式，而且该过程中的相关检测信息都实时上传至云计算平台3，并且避免了人为对原始记录篡改的问题，其对以上信息进行存储，并高速运算，还能自动生成检测报告，无需将记录在纸上的检测数据送回室内，再次录入计算机中才能得出检测结果的方式，因此又进一步提高了检测的效率，以及检测的时效性，并且还可以随时将其信息调用。The data acquisition and traceability system for detecting concrete strength by the rebound method of the present invention uses the identification sticker 1 with the RFID radio frequency chip to mark the measurement area of the concrete component to be tested, which ensures that after the rebound detection is completed, the After the component under test is plastered or painted, it can still be traced easily, that is, the hidden traceability is realized. At the same time, the data acquisition instrument 2 has a built-in application program for collecting information, which realizes paperless operation and avoids the way of manually recording the detection data on paper during the detection process, and the relevant detection information in the process is uploaded to the cloud computing platform in real time 3. It also avoids the problem of man-made tampering of original records. It stores the above information and performs high-speed calculations. It can also automatically generate test reports. It is not necessary to send the test data recorded on paper back to the room and enter it into the computer again to obtain Therefore, the detection efficiency and the timeliness of the detection are further improved, and the information can be called at any time.

如图1所示，本发明所述的回弹法检测混凝土的数据采集溯源系统，包括标识贴1、数据采集仪2和云计算平台3。As shown in FIG. 1 , the data acquisition and traceability system for detecting concrete by rebound method according to the present invention includes a label sticker 1 , a data acquisition instrument 2 and a cloud computing platform 3 .

其中，所述标识贴1用于标记混凝土被测构件的测区的标识信息，其通过两个方面实现，第一，所述标识贴1本身是一维条码，可以直观读取，也可以是二维码，通过扫描读取，二者的共同点就是以条码或黑白相间的图像直接呈现于标识贴2的表面；第二，所述标识贴1带有RFID射频芯片，其可以内置所述标识贴1内，可以是置于其后，需通过写卡器写入用于标记的标识信息，其内部的标识信息可以是与标识贴1表面的一维条码或二维码标记的信息一致，也可以是不一致的，不一致的情况是通过云计算平台3进行了加密处理。同时不管是标识贴1表面的一维条码或二维码标记的标识信息，还是RFID射频芯片内的标识信息都是通过云计算平台3统一管理的。Wherein, the identification sticker 1 is used to mark the identification information of the measuring area of the concrete component under test, which is realized in two aspects. First, the identification sticker 1 itself is a one-dimensional barcode, which can be read intuitively, or it can be The two-dimensional code is read by scanning, and the common point of the two is that a barcode or a black and white image is directly presented on the surface of the label sticker 2; secondly, the label sticker 1 has an RFID radio frequency chip, which can be built in the In the logo sticker 1, it can be placed behind it, and the identification information for marking needs to be written through a card writer. The internal logo information can be consistent with the information marked on the surface of the logo sticker 1. One-dimensional barcode or two-dimensional code , may also be inconsistent, and in the case of inconsistency, encryption processing is performed through the cloud computing platform 3 . At the same time, no matter whether it is the identification information of the one-dimensional barcode or the two-dimensional code on the surface of the identification sticker 1, or the identification information in the RFID radio frequency chip, it is all managed through the cloud computing platform 3 in a unified manner.

如图2所示，所述数据采集仪2包括有摄像模块21、扫描模块22、光电转换器23、读取模块24、输入模块25和存储模块26；所述摄像模块21用于拍摄，可以对检测工地，检测人员，以及被测区域进行拍照，该拍摄的照片都被存储于存储模块26内。所述扫描模块22用于扫描标识贴1表面的码文信息(一维条码或二维码)，然后经过光电转换器23转换为数字信息，该数字信息存储于存储模块26内；所述读取模块24用于读取RFID射频芯片内的信息，其利用了无线射频方式进行非接触双向数据传输，与传统的条形码的读取相比，读取速度更快，并且无磨损，也不受环境影响，寿命长，便于使用。所述输入模块25用于录入检测数据，可以是键盘或者触摸屏的形式输入。所述存储模块26则用于存储以上各种信息，并且所述各种信息都被上传至云计算平台，检测数据信息则通过其可以自动生成检测报告，同时其他信息便于后期随时调用，大大方便了后期的监管。As shown in Figure 2, the data acquisition instrument 2 includes a camera module 21, a scanning module 22, a photoelectric converter 23, a reading module 24, an input module 25 and a storage module 26; the camera module 21 is used for shooting and can Take photos of the inspection site, inspection personnel, and the area to be inspected, and the photographs are all stored in the storage module 26 . The scanning module 22 is used to scan the code information (one-dimensional barcode or two-dimensional code) on the surface of the identification sticker 1, and then convert it into digital information through the photoelectric converter 23, and the digital information is stored in the storage module 26; The fetching module 24 is used to read the information in the RFID radio frequency chip, which utilizes the wireless radio frequency mode to carry out non-contact two-way data transmission, compared with the reading of traditional barcodes, the reading speed is faster, and it is free from wear and tear and is not affected Environmental impact, long life, easy to use. The input module 25 is used for inputting detection data, which may be input in the form of a keyboard or a touch screen. The storage module 26 is used to store the above various information, and the various information is uploaded to the cloud computing platform, and the detection data information can automatically generate a detection report through it, and other information is convenient for calling at any time later, which is very convenient later supervision.

所述云计算平台3则是充当了存储数据、处理数据的设备，具有易管理、系统化的特点。The cloud computing platform 3 acts as a device for storing and processing data, and has the characteristics of easy management and systematization.

同时，为了提高标识信息的机密性，即只有内部人员才能读取到RFID射频芯片内的标识信息对应的真实信息，所述云计算平台3内还设有加密运算模块31，其提供经过加密后的标识信息，然后通过写卡器写人所述RFID射频芯片内，在外部人员读取相关标识信息后，也是不知道该标识信息对应的真实信息，无法调用或下载云计算平台上该测点的检测信息，其是需要通过加密运算模块31进行解码后才能取得的。At the same time, in order to improve the confidentiality of the identification information, that is, only insiders can read the real information corresponding to the identification information in the RFID radio frequency chip, the cloud computing platform 3 is also provided with an encryption operation module 31, which provides encrypted information. The identification information, and then write it into the RFID radio frequency chip through the card writer. After the external personnel read the relevant identification information, they do not know the real information corresponding to the identification information, and cannot call or download the measurement point on the cloud computing platform. The detection information can only be obtained after being decoded by the encryption operation module 31 .

另外，为了实现对检测地点进行自动定位的功能，所述数据采集仪2内还设有GPS定位模块27。In addition, in order to realize the function of automatically locating the detection location, the data acquisition instrument 2 is also provided with a GPS positioning module 27 .

其中，所述数据采集仪2利用对检测中的每个环节进行拍照记录，保证了检测的过程中的检测信息的真实性，便于后期查证。Wherein, the data acquisition instrument 2 takes pictures and records each link in the detection to ensure the authenticity of the detection information in the detection process, which is convenient for later verification.

以上是对本发明所述的回弹法检测混凝土强度的数据采集溯源系统的说明，以下对采用该系统记性呢采集溯源的方法进行具体描述：The above is the description of the data acquisition and traceability system for the rebound method of the present invention to detect the strength of concrete, and the method for adopting the system memory collection and traceability is described in detail below:

本发明所述的回弹法检测混凝土强度的数据采集、溯源方法，包括采集和溯源步骤。The data collection and traceability method for detecting concrete strength by the rebound method of the present invention includes the steps of collection and traceability.

其中，所述采集步骤具体为：Wherein, the collection steps are specifically:

通过数据采集仪2上获取被测构件的工程信息和检测信息，并实时无线上传至云计算平台。其中，所述工程信息包括有工程项目信息、检测工地、检测人员和被测构件的图片信息，目的在于为采集检测的真实信息提供多重保障。所述检测信息包括有回弹检测过程中的每一个检测数据、根据该检测数据得出的检测结果、以及最终综合检测结果得出的检测报告。The engineering information and detection information of the component under test are obtained through the data acquisition instrument 2, and wirelessly uploaded to the cloud computing platform in real time. Wherein, the engineering information includes engineering project information, inspection site, inspection personnel and picture information of the tested components, with the purpose of providing multiple guarantees for collecting the real information of inspection. The detection information includes each detection data in the springback detection process, the detection results obtained according to the detection data, and the detection report obtained from the final comprehensive detection results.

检测完成后，在测区采用防撕技术贴上标识贴1。以上数据采集仪2是通过输入模块25录入工程项目信息，并在检测过程中录入每次回弹测试后的回弹值；同时，采用摄像模块21拍摄检测工地、检测人员以及被测构件的图片信息；采用扫描模块22扫描标识贴1表面的一维条码或二维码的码文信息，并通过光电转换器23进行转换为数字信息，采用读取模块24读取RFID射频信息内的标识信息，所述经过转换后的码文信息与标识信息与存储于云计算平台3内的码文信息或标识信息相关联，为后期溯源提供准备。After the test is completed, use the anti-tear technology to affix the identification sticker 1 on the test area. The above data acquisition instrument 2 enters the engineering project information through the input module 25, and enters the rebound value after each rebound test in the detection process; at the same time, the camera module 21 is used to shoot the picture information of the inspection site, inspection personnel and tested components Use the scanning module 22 to scan the code information of the one-dimensional barcode or the two-dimensional code on the surface of the label 1, and convert it into digital information through the photoelectric converter 23, and use the reading module 24 to read the identification information in the RFID radio frequency information, The converted code text information and identification information are associated with the code text information or identification information stored in the cloud computing platform 3 to provide preparation for later traceability.

该采集过程中，采用无纸化操作，并且通过数据采集仪2录入的检测数据直接上传至云计算平台3进行数据处理，无需再次录入的操作，避免了频繁操作以及原始数据被篡改的漏洞问题。所述的数据采集仪2内安装有应用程序，实现信息化管理，同时其GPS定位功能以及拍照功能都有利于保证检测数据的真实性和全面性，同时，在录入工程信息和检测信息时均对应有操作时间记录，进一步避免时候更改检测数据的可能性。In the collection process, paperless operation is adopted, and the detection data entered by the data collection instrument 2 is directly uploaded to the cloud computing platform 3 for data processing, without the need for re-entry operations, avoiding the loopholes of frequent operations and tampering of original data . Application programs are installed in the data acquisition instrument 2 to realize informatization management. Meanwhile, its GPS positioning function and camera function are conducive to ensuring the authenticity and comprehensiveness of the detection data. At the same time, when entering engineering information and detection information, the Correspondingly, there is a record of the operation time to further avoid the possibility of changing the detection data at any time.

其中，所述溯源步骤具体为:Wherein, the traceability step is specifically:

通过数据采集仪2扫描贴于测区上所述标识贴1表面的码文信息或读取所述RFID射频芯片上的标识信息，即可马上调出对应的工程信息和检测信息。By scanning the code information pasted on the surface of the identification sticker 1 on the measurement area by the data acquisition instrument 2 or reading the identification information on the RFID radio frequency chip, the corresponding engineering information and detection information can be called out immediately.

在上述溯源过程中，如果被测构件没有被粉刷或批荡，，则只需对测区外露的一维条码或二维码的码文信息进行扫描，获取对应的码文信息，该码文信息与存储于云计算平台3或数据采集仪2内的码文信息相关联后，从而对应从云计算平台3中调出对应的工程信息和检测信息，达到溯源的目的；如果被测构件已经被粉刷或批荡，则所述标识贴1被遮盖，采用数据采集仪2对被测构件表面扫寻RFID射频芯片，当扫到RFID芯片，也就确定了测区的准备位置，同时读取芯片的标识信息，该标识信息与存储于云计算平台3或数据采集仪2内的标识信息相关联后，从而对应从云计算平台3中调出对应的工程信息和检测信息，达到溯源的目的。In the above traceability process, if the component under test has not been painted or plastered, it is only necessary to scan the code text information of the one-dimensional barcode or two-dimensional code exposed in the measurement area to obtain the corresponding code text information. After the information is associated with the code information stored in the cloud computing platform 3 or the data acquisition instrument 2, the corresponding engineering information and detection information are called out from the cloud computing platform 3 to achieve the purpose of traceability; if the component under test has If it is painted or plastered, the label 1 is covered, and the data acquisition instrument 2 is used to scan the RFID radio frequency chip on the surface of the component under test. When the RFID chip is scanned, the preparation position of the measurement area is determined, and the read The identification information of the chip, after the identification information is associated with the identification information stored in the cloud computing platform 3 or the data acquisition instrument 2, the corresponding engineering information and detection information can be called out from the cloud computing platform 3 to achieve the purpose of traceability .

为了提高机密性，在所述数据采集仪2获取所述RFID射频芯片内的标识信息需要通过云计算平台3内的加密运算模块31进行解码换算后，得到与数据采集仪相关联的标识信息，进而才能对测区进行准确定位，并且调出对应的工程信息和检测信息。In order to improve confidentiality, after the data acquisition instrument 2 obtains the identification information in the RFID radio frequency chip, it needs to be decoded and converted by the encryption operation module 31 in the cloud computing platform 3 to obtain the identification information associated with the data acquisition instrument, Only then can the survey area be accurately positioned, and the corresponding engineering information and detection information can be called out.

为了提供更为充分、准确、可靠的工程信息，还包括通过GPS定位模块27对检测工地的坐标位置进行自动定位的步骤。In order to provide more sufficient, accurate and reliable engineering information, it also includes the step of automatically locating the coordinate position of the detection site through the GPS positioning module 27 .

在数据采集步骤之前，需要做如下准备工作，具体有：Before the data collection step, the following preparatory work needs to be done, specifically:

(1)制作标识贴(1) Making logo stickers

对标识贴中的RFID射频芯片写入标识信息，并贴于所述标识贴1上；该RFID射频芯片可以是贴于所述标识贴1的背面，可以是置于所述标识贴1的内部。同时其内部存储的标识信息可以是与标识贴1表面的一维条码或者二维码对应的标识信息一致，也可以是不一致，在不一致的情况下，当读取到的RFID射频芯片内的标识信息还需通过云计算平台3内的加密运算模块31完成加密和解码的。Write identification information to the RFID radio frequency chip in the identification sticker, and paste it on the identification sticker 1; the RFID radio frequency chip can be attached to the back of the identification sticker 1, and can be placed inside the identification sticker 1 . At the same time, the identification information stored inside it can be consistent with the identification information corresponding to the one-dimensional barcode or two-dimensional code on the surface of the identification sticker 1, or it can be inconsistent. In the case of inconsistency, when the identification information in the read RFID radio frequency chip The information also needs to be encrypted and decoded by the encryption operation module 31 in the cloud computing platform 3 .

(2)对测区进行回弹测试。(2) Conduct a rebound test on the test area.

以上所述，仅是本发明的较佳实施例而已，并非对本发明作任何形式上的限制，故凡是未脱离本发明技术方案内容，依据本发明的技术实质对以上实施例所作的任何修改、等同变化与修饰,均仍属于本发明技术方案的范围内。The above is only a preferred embodiment of the present invention, and is not intended to limit the present invention in any form. Therefore, any modification, Equivalent changes and modifications all still belong to the scope of the technical solutions of the present invention.

Claims (10)

1. the data acquisition of rebound method in concrete compressive strength detection, a traceability system, for the data acquisition of concrete strength inspection with trace to the source, is characterized in that:

Comprise data collecting instrument, cloud computing platform and mark label;

Wherein, described mark label is provided with RFID radio frequency chip, for marking the survey district of concrete tested component;

The identification information of described data collecting instrument in the code literary composition information that obtains the surface on the engineering information of tested component and Detection Information, the described mark label of reading and RFID, and described engineering information, Detection Information, code literary composition information and identification information are transferred to cloud computing platform, described code literary composition information or identification information be stored in the civilian information of code corresponding in cloud computing platform or data collecting instrument or identification information is associated for tracing to the source.

2. the data acquisition of rebound method in concrete compressive strength detection according to claim 1, traceability system, is characterized in that:

Described mark label is bar code or Quick Response Code mark label.

3. the data acquisition of rebound method in concrete compressive strength detection according to claim 1 and 2, traceability system, is characterized in that:

Described data collecting instrument comprises photographing module, scan module, photoelectric commutator, read module, load module and memory module;

Described photographing module for obtain detection building site, testing staff and tested region pictorial information;

Described scan module is for the civilian information transmission of the code extremely described photoelectric commutator on the mark label surface scanned;

Described photoelectric commutator is used for described code literary composition information to be converted to numerical information;

Described read module is for the identification information in the described RFID radio frequency chip that reads;

Described load module is used for typing engineering project information and Detection Information;

Described memory module is for storing described pictorial information, numerical information, identification information, engineering project information and Detection Information.

4. the data acquisition of rebound method in concrete compressive strength detection according to claim 3, traceability system, is characterized in that:

GPS locating module on described data collecting instrument, for positioning detection building site.

5. the data acquisition of rebound method in concrete compressive strength detection according to claim 1, traceability system, is characterized in that:

Described data collecting instrument and described cloud computing platform pass through wireless connections.

6. the data acquisition of rebound method in concrete compressive strength detection according to claim 1, traceability system, is characterized in that:

Described cloud computing module includes cryptographic calculation module, for being encrypted the identification information received, decoding.

7. the data acquisition of rebound method in concrete compressive strength detection, a source tracing method, is characterized in that:

Comprise collection and step of tracing to the source;

Wherein, described acquisition step is specially:

Obtained engineering information and the Detection Information of tested component by data collecting instrument, and be uploaded to cloud computing platform in real time;

Be affixed on the code literary composition information surveying described mark label surface in district or the identification information read on described RFID radio frequency chip by data collecting instrument scanning, be associated with the code literary composition information be stored in cloud computing platform or data collecting instrument or identification information;

Described step of tracing to the source is specially:

By data collecting instrument scan code literary composition information or identification information, recall corresponding engineering information and Detection Information.

8. the data acquisition of rebound method in concrete compressive strength detection according to claim 7, source tracing method, is characterized in that:

Also comprise the step of encryption, be specially:

After needing to carry out decoding conversion by the cryptographic calculation module in cloud computing platform from the identification information of described RFID radio frequency chip acquisition, obtain and be stored in the identification information be associated in data collecting instrument or cloud computing platform.

9. the data acquisition of rebound method in concrete compressive strength detection according to claim 7, source tracing method, is characterized in that:

Described engineering information comprises engineering project title, item address, project leader and unit in charge of construction;

Described Detection Information comprises the detection data detected in building site, the pictorial information of testing staff and tested component and checking spring range process.

10. the data acquisition of rebound method in concrete compressive strength detection according to claim 9, source tracing method, is characterized in that:

Also comprise the step of location, be specially:

GPS locating module automatic acquisition on described data collecting instrument detects the coordinate position in building site.