CN113670727A - Concrete test block maintenance and loading integrated system and construction method - Google Patents

Abstract

The invention provides a concrete test block curing and loading integrated system and a construction method, wherein the system comprises an intelligent curing test system and an intelligent loading test system, and an automatic control curing, transportation, test block testing, data uploading and residual sample cleaning unmanned management are completed by applying an intelligent transportation trolley, a temperature and humidity integrated sensor, a two-dimensional code scanning gun, a six-axis intelligent mechanical arm, two pressure testing machines, a waste transportation channel and the like; the intelligent test system consists of highly intelligent and automatic subsystems, and all the subsystems work cooperatively, so that the interference of human factors on the test process can be completely avoided, and the fairness of the test results is ensured.

Description

Concrete test block maintenance and loading integrated system and construction method

Technical Field

The invention relates to the technical field of concrete detection, in particular to a concrete test block curing and loading integrated system and a construction method.

Background

The construction quality of the concrete is directly related to the quality of the whole project, so that how to ensure the strength and the quality of the concrete is very important. The compressive strength of the concrete test block is an important index for representing the performance of the concrete, so that the concrete test block is manufactured by sampling to carry out pressure test when the construction of a concrete project is carried out, and the performance of the concrete used in the construction is judged.

At present, various problems exist in the concrete test block of the construction site from the stages of sampling, curing and forming and pressure testing, for example: standard curing conditions are not adopted for curing, the curing time does not reach the standard, and the artificial influence factors of the experimental result are large. In addition, aiming at large-scale engineering, the number of concrete test blocks is large, so that the workload of a field laboratory is large, the management difficulty is increased, and the reliability of an experimental result is reduced.

Disclosure of Invention

The invention aims to provide a concrete test block curing and loading integrated system which is reasonable in structure, can completely avoid interference of human factors, and is high in intelligentization degree, automation degree and working efficiency and a construction method.

In order to solve the technical problem, the invention provides a concrete test block maintenance and loading integrated construction method, which comprises the following steps:

step 1) sampling a concrete test block: sampling concrete test blocks of the concrete, generating a unique two-dimensional code identifier for each concrete test block, and realizing automatic tracking and tracing of the test blocks through the two-dimensional code identifiers; the generated two-dimensional codes are pasted on the side wall of the concrete test block, then the concrete test block is placed on an intelligent transport trolley and sent to a standard curing workshop for curing operation, wherein the concrete test blocks in the same batch are placed on the same test block placing frame;

step 2), automatic maintenance operation: temperature and humidity control: during maintenance, detecting the temperature and humidity conditions in a standard maintenance workshop and the temperature condition of outdoor atmosphere in real time through a computer and a temperature and humidity integrated sensor; maintenance information recording: during maintenance, recording temperature and humidity information of a standard maintenance workshop in real time through a temperature and humidity integrated sensor, and storing the temperature and humidity information in a two-dimensional code identifier; controlling time nodes: the curing time of each batch of concrete test blocks is recorded by a computer at the background, and after the specified curing time is reached, an instruction is automatically sent to the intelligent conveying trolley, and the trolley is controlled to exit from a standard curing workshop and enter a loading workshop for testing;

step 3), automatic loading of the concrete test block: reading concrete test block information: after the intelligent transport trolley drives into the specified position of the loading workshop from the standard maintenance workshop (2), the system automatically locks a safety protection door of the loading workshop; placing concrete test blocks on a code scanning device and a pressure testing machine in sequence; placing the test block in place: placing the concrete test block on a pressure testing machine by a six-axis mechanical arm, adjusting the placing position of the concrete test block by a photoelectric sensor on the six-axis mechanical arm, determining whether the placing position of the concrete test block is accurate, and if the concrete test block has deviation, adjusting the concrete test block to be centered by the six-axis mechanical arm; thirdly, loading a press machine: after the test block is put in place, the six mechanical arms retract to a safe position, then the control system starts the pressure testing machine to load the concrete test block, and pressure testing data are automatically recorded; and fourthly, uploading test results: after the pressure test is finished, the system automatically uploads the test result to a computer of a control center, and the concrete test block which is unqualified in the test is marked in the system; fifthly, cleaning the residual sample: and after the concrete test block is crushed, loading the concrete test block into the cellular residual sample box, and then carrying out loading test on the next concrete test block.

The invention has the following beneficial effects:

1. compared with the prior art, the automatic mechanical equipment is used for operating the processes of test block maintenance, pressure test and the like, so that the automatic, mechanical and intelligent operation of the whole processes of automatic maintenance, automatic positioning, automatic code scanning, automatic testing, data recording, residual sample cleaning and the like is realized, the labor intensity of operators is reduced, the interference of human factors to the test process can be completely avoided, the fairness of the test result is ensured, and the technical benefit advantage is obvious.

2. According to the invention, when the concrete test block is sampled, a unique two-dimensional code label is generated for identification, and the sampling information, the maintenance environment information, the experiment result and other whole process information of the test block are stored in the two-dimensional code label, so that the monitoring, management, tracking and recording are convenient, and the reliability of the experiment result is improved.

3. According to the invention, the mechanical arm is adopted to replace manual operation, the automation degree is high, and no staff is required to participate, so that on one hand, the labor intensity of a tester is reduced, the tester is prevented from being accidentally injured by splashing of crushed test block chips, and the safety guarantee is improved; on the other hand, the detection speed of the sample is greatly improved, and the working efficiency is improved.

4. According to the invention, the automatic residual sample cleaning device is arranged, so that broken sample scraps can be cleaned in time without manual cleaning, and the efficiency is high.

5. The code scanning device provided by the invention can realize automatic adjustment of the code scanning of the test block and unmanned operation.

Drawings

FIG. 1 is a schematic layout of an integrated system for maintaining and loading concrete test blocks;

FIG. 2 is a construction flow chart of the concrete test block maintenance and loading integrated system;

FIG. 3 is a schematic view of a code scanning apparatus;

FIG. 4 is a top view of FIG. 3;

FIG. 5 is a schematic view of the ejector;

FIG. 6 is a top view of FIG. 5;

FIG. 7 is a layout view of an automatic residual sample removing apparatus;

fig. 8 is a left side view of a-a in fig. 7.

Wherein: 1-operation monitoring plant; 2-standard maintenance shop; 3-loading plant; 4-two-dimensional code scanning gun; 5-computer; 6-two-dimensional code printer; 7-control center; 8-hand-held terminal; 9-temperature and humidity integrated sensor; 10-concrete test block; 11-Intelligent vehicle; 12-test block placing rack; 13-waste transport channel; 14-code scanning device; 15-cell type residual sample box; 16-compression testing machine; 17-a push-out device; 18-six-axis mechanical arm; 19-balance assist lever; 20-telescopic shaft; 21-limiting plate; 22-push plate; 23-bottom plate; 24-hydraulic lifting column; 25-a base; 26-a cross-bar; 27-vertical bar; 28, a limiting block; 29-bolted lug plate; 30-scanning probe; 31-test block pushing device; 32-two-dimensional code; 33-slide way; 34-conveyor belt.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments that can be derived by one of ordinary skill in the art from the embodiments given herein are intended to be within the scope of the present invention.

It will be understood by those skilled in the art that in the present disclosure, the terms "longitudinal," "lateral," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in an orientation or positional relationship indicated in the drawings for ease of description and simplicity of description, and do not indicate or imply that the referenced devices or components must be constructed and operated in a particular orientation and thus are not to be considered limiting.

It is understood that the terms "a" and "an" should be interpreted as meaning that a number of one element or element is one in one embodiment, while a number of other elements is one in another embodiment, and the terms "a" and "an" should not be interpreted as limiting the number.

The technical solution of the present invention is further explained with reference to fig. 1 to 8.

The invention provides a concrete test block maintenance and loading integrated system which comprises an intelligent maintenance test system and an intelligent loading test system.

Intelligence maintenance test system constitute by operation monitoring workshop 1 and standard maintenance workshop 2, all install the humiture integration sensor 9 that detects the humiture inside and outside 2 standard maintenance workshops, be equipped with the two-dimensional code in operation monitoring workshop 1 and sweep yard rifle 4, computer 5, two-dimensional code printer 6, control center 7, handheld terminal 8, just the yard rifle 4, two-dimensional code printer 6, control center 7, handheld terminal 8, humiture integration sensor 9 are swept to the two-dimensional code and are connected with computer 5. After the concrete test block 10 is sampled, the unique two-dimensional code 32 is printed out through the two-dimensional code printer 6, the two-dimensional code 32 is pasted on the concrete test block 10 and then placed on the intelligent transport trolley 11, and the intelligent transport trolley 11 automatically enters the standard maintenance workshop 2 to perform maintenance operation.

Specifically, during the maintenance operation, detect the inside humiture data of standard maintenance workshop 2 through humiture integration sensor 9, later with humiture data transmission to computer 5 in save, the staff can observe real-time humiture data through handheld terminal 8 this moment, and whether surpass according to humiture data through control center 7 and set for the threshold value, come temperature and humidity to regulate and control in the standard maintenance workshop 2, when needs are to each item data and the maintenance of concrete test block 10, when the loading flow is looked over, sweep yard rifle 4 through the two-dimensional code and discern two-dimensional code 32, and then carry out solitary discernment to every concrete test block 10.

The intelligent loading test system comprises a waste material transportation channel 13, a code scanning device 14, a cellular type residual sample box 15, a pressure tester 16, a pushing device 17 and a six-axis mechanical arm 18; after the curing operation is completed, the intelligent transport trolley 11 carries the cured concrete test block 10, drives the cured concrete test block into the loading workshop 3, unloads the test block placing frame 12 with the concrete test block 10 placed therein, a six-axis mechanical arm 18 and at least two pressure testing machines 16 are arranged in the loading workshop 3, the six-axis mechanical arm 18 places the concrete test block 10 on the code scanning device 14 to automatically scan codes and identify the codes, and then places the concrete test block on the pressure testing machines 16, the pressure testing machines 16 start loading, test results are automatically uploaded after the loading is completed, crushed concrete test block 10 residues are sent into the waste transport channel 13 through the pushing device 17, and finally the crushed concrete test block 10 residues are placed into the cell type residual sample box 15.

The push-out device 17 comprises a balance auxiliary rod 19, a telescopic shaft 20, a limiting plate 21, a push plate 22, a bottom plate 23, a hydraulic lifting column 24 and a base 25, wherein the base 25 is of a cuboid hollow steel structure, the hydraulic lifting column 24 is arranged in the base 25, the bottom plate 23 is arranged at the top of the hydraulic lifting column 24, the limiting plate 21 is arranged on one side of the bottom plate 23, the telescopic shaft 20 is arranged in the middle of the bottom plate 23 and penetrates through the limiting plate 21 to be connected with the push plate 22, the balance auxiliary rod 19 is movably arranged on the limiting plate 21 in a penetrating mode, and one end of the balance auxiliary rod is connected with the push plate 22; when needs promote concrete test block 10 residue, the extension telescopic shaft promotes the push pedal and removes, and the moving direction of push pedal is guided through the balanced auxiliary rod that is located the telescopic shaft both sides at the in-process that the push pedal removed, guarantees the accuracy of push pedal moving direction, still can be through the height of hydraulic lifting column adjustment bottom plate simultaneously, and then the height that the adjustment push pedal promoted.

The waste transport channel 13 consists of a slide way 33 and a conveyor belt 34, the slide way 33 is connected with the compression testing machine 16, one end of the conveyor belt 34 is arranged below the slide way 33, and the other end of the conveyor belt is communicated with the chamber type residual sample box 15; wherein the slide is the slope setting to concrete test block residue is on the landing to the conveyer belt downwards.

Sweep sign indicating number device 14 include base 25, horizontal pole 26, montant 27, stopper 28, bolt otic placode 29, scanning probe 30 and test block thrust unit 31, base 25 top surface edge sets up montant 27, horizontal pole 26 is fixed on montant 27 upper portion through bolt otic placode 29, scanning probe 30 sets up on horizontal pole 26, stopper 28 is equipped with two at least, and when the stopper was equipped with two, two stoppers set up respectively in the corner both sides that are close to with montant 27, and the length direction extension line of two stoppers is 90 contained angles, test block thrust unit 31 sets up the diagonal of contained angle between two stoppers 28.

Specifically, test block thrust unit 31 includes telescopic link and slurcam, and it removes to drive the slurcam through the telescopic link extension to promote the concrete test block through the slurcam.

Sweep sign indicating number device 14 through earlier with concrete test block 10 be equipped with the one side of two-dimensional code 32 place up at base 25 top surface, start test block thrust unit 31 and promote concrete test block 10 and lean on stopper 28, two-dimensional code 32 is just being in sweeping sign indicating number probe 30 below this moment, realize that the code is swept in the automatic adjustment, reads two-dimensional code 32 information.

The construction method of the concrete test block maintenance and loading integrated system comprises the following steps:

1) sampling a concrete test block: sampling concrete test blocks 10 of concrete according to engineering requirements, generating a unique two-dimensional code 32 identifier for each concrete test block 10, automatically tracking and tracing the concrete test blocks 10 through the two-dimensional code 32 identifier, storing the marks, engineering names, pouring dates, pouring positions, concrete mix proportion, production batches, maintenance methods and the like of the concrete in the two-dimensional code 32, and storing subsequent process information in the two-dimensional code 32, wherein the sampling method mainly comprises the following steps: temperature and humidity information of a maintenance workshop, maintenance time, loading time, pressure test results and the like. The generated two-dimensional codes 32 are adhered to the side wall of the concrete test block 10, then are placed on the intelligent transport trolley 11 and sent into the standard curing workshop 2 for curing operation, and the concrete test blocks 10 in the same batch are placed on the same test block placing frame 12.

2) Automatic maintenance work

Temperature and humidity control: during maintenance, the temperature and humidity conditions in the standard maintenance workshop 2 and the temperature condition of outdoor atmosphere are detected in real time through the computer 5 and the temperature and humidity integrated sensor 9; when the temperature in the standard curing workshop 2 exceeds a set threshold value, the temperature is adjusted by an air conditioner in the standard curing workshop 9, and when the humidity in the standard curing workshop 9 exceeds the set threshold value, the spraying equipment is controlled to be opened by a temperature and humidity controller for adjustment, so that the aim of automatically adjusting the temperature and the humidity in the standard curing workshop 2 is fulfilled, and the automatic and unmanned control of the curing operation is realized.

Maintenance information recording: during maintenance, temperature and humidity information of the standard maintenance workshop 2 is recorded in real time through the temperature and humidity integrated sensor 9 and stored in the two-dimensional code 32 identification, so that whether each concrete test block 10 is subjected to maintenance operation under standard maintenance conditions or not can be checked at a later stage; when the temperature and humidity in the standard maintenance workshop 2 cannot reach the standard maintenance conditions and exceed the error allowed by the standard, the concrete test blocks 10 of the current batch are directly discarded.

Controlling time nodes: the maintenance time of each batch of concrete test blocks 10 is recorded by the computer 5 at the background, and after the specified maintenance time is reached, an instruction is automatically sent to the intelligent conveying trolley 11, and the trolley is controlled to exit the standard maintenance workshop 2 and enter the loading workshop 3 for testing.

3) Automatic test block loading

Reading information of the concrete test block 10: after the intelligent transportation trolley 11 is driven into the specified position of the loading workshop 3 from the standard maintenance workshop 2, the system automatically locks the safety protection door of the loading workshop 3, thereby avoiding the influence on the operation of the six-axis mechanical arm 18 caused by the entering of irrelevant personnel and simultaneously avoiding the occurrence of safety accidents during the pressure test; placing the concrete test block 10 on the code scanning device 14 and the pressure testing machine 16 in sequence; specifically, the six-axis mechanical arm 18 is used for clamping the concrete test block 10 to the code scanning device 14, reading the information of the concrete test block 10, and then placing the concrete test block 10 on the pressure testing machine 16 through the six-axis mechanical arm 18 again.

Placing the test block in place: the concrete test block 10 is placed on the pressure testing machine 16 through the six-axis mechanical arm 18, the placing position of the concrete test block 10 is adjusted through the photoelectric sensor on the six-axis mechanical arm 18, whether the placing position of the concrete test block 10 is accurate or not is confirmed, and if deviation exists, the six-axis mechanical arm 18 adjusts centering, so that result deviation caused by manual centering failure is avoided.

Thirdly, loading a press machine: after the test block is put in place, the six-axis mechanical arm 18 retracts to a safe position, the control system starts the pressure tester 16 to load the concrete test block 10, and pressure test data are automatically recorded.

And fourthly, uploading test results: after the pressure test is finished, the system automatically uploads the test result to the computer 5 of the control center, so that the test result is prevented from being considered to be modified, the unqualified concrete test block 10 is marked in the system, and the later-stage check is facilitated.

Fifthly, cleaning the residual sample: after the concrete test block 10 is crushed, loading the concrete test block 10 into a cell type residual sample box 15, and then carrying out a loading test on the next concrete test block 10; specifically, the pushing device 17 is started to push the residues of the concrete test block 10 crushed on the compression testing machine 16 to the slideway 33, and the residues of the concrete test block 10 are conveyed out of the loading workshop 3 by the conveyer belt 34 and loaded into the cellular residual sample box 15 after sliding down on the conveyer belt 34.

The present invention is not limited to the above-mentioned preferred embodiments, and any other products in various forms can be obtained by anyone in the light of the present invention, but any changes in the shape or structure thereof, which have the same or similar technical solutions as those of the present application, fall within the protection scope of the present invention.

Claims (10)

1. A concrete test block maintenance and loading integrated construction method is characterized by comprising the following steps:

step 1) sampling a concrete test block: sampling concrete test blocks (10) of concrete, generating a unique two-dimensional code (32) identifier for each concrete test block (10), and realizing automatic tracking and tracing of the concrete test blocks (10) through the two-dimensional code (32) identifiers; the generated two-dimensional codes (32) are adhered to the side walls of the concrete test blocks (10), then the concrete test blocks are placed on an intelligent transport trolley (11), and the intelligent transport trolley is sent to a standard maintenance workshop (2) for maintenance operation, wherein the concrete test blocks (10) in the same batch are placed on the same test block placing frame (12);

step 2), automatic maintenance operation: temperature and humidity control: during maintenance, the temperature and humidity conditions in the standard maintenance workshop (2) and the temperature and humidity conditions of outdoor atmosphere are detected in real time through the computer (5) and the temperature and humidity integrated sensor (9); maintenance information recording: during maintenance, temperature and humidity information of the standard maintenance workshop (2) is recorded in real time through the temperature and humidity integrated sensor (9) and stored in the two-dimensional code (32) identification; controlling time nodes: the maintenance time of each batch of concrete test blocks (10) is recorded by the computer (5) at the background, and after the specified maintenance time is reached, an instruction is automatically issued to the intelligent conveying trolley (11), the trolley is controlled to exit the standard maintenance workshop (2), and the trolley enters the loading workshop (3) for testing;

step 3), automatic loading of the concrete test block: reading information of a concrete test block (10): after the intelligent transport trolley (11) drives into the designated position of the loading workshop (3) from the standard maintenance workshop (2), the system automatically locks a safety protection door of the loading workshop (3); placing the concrete test block (10) on a code scanning device (14) and a pressure testing machine (16) in sequence; placing the test block in place: the concrete test block (10) is placed on a pressure testing machine (16) through a six-axis mechanical arm (18), the placing position of the concrete test block (10) is adjusted through a photoelectric sensor on the six-axis mechanical arm (18), whether the placing position of the concrete test block (10) is accurate or not is confirmed, and if deviation exists, the six-axis mechanical arm (18) adjusts and centers the concrete test block; thirdly, loading a press machine: after the test block is put in place, the six-axis mechanical arm (18) retracts to a safe position, then the control system starts the pressure tester (16) to load the concrete test block (10), and pressure test data are automatically recorded; and fourthly, uploading test results: after the pressure test is finished, the system automatically uploads the test result to a computer (5) of a control center, and the concrete test block (10) which is unqualified in the system is marked; fifthly, cleaning the residual sample: after the concrete test block (10) is crushed, the concrete test block (10) is loaded into a cell type residual sample box (15), and then the loading test of the next concrete test block (10) is carried out.

2. The concrete test block curing and loading integrated construction method according to claim 1, characterized in that: in the step 2), when the temperature in the standard curing workshop (2) exceeds a set threshold value or when the humidity in the standard curing workshop (9) exceeds a set threshold value, the temperature and the humidity in the standard curing workshop (2) are automatically adjusted.

3. The concrete test block curing and loading integrated construction method according to claim 2, characterized in that: in the step 2), when the temperature and humidity in the standard curing workshop (2) cannot reach the standard curing conditions and exceed the error allowed by the standard, directly discarding the concrete test blocks (10) of the current batch.

4. The concrete test block curing and loading integrated construction method according to claim 1, characterized in that: in the step 3), the six-axis mechanical arm (18) clamps the concrete test block (10) to the code scanning device (14), the information of the concrete test block (10) is read, and then the six-axis mechanical arm (18) puts the concrete test block (10) on the pressure testing machine (16).

5. The concrete test block curing and loading integrated construction method according to claim 1, characterized in that: in the step 3), the pushing device (17) is started to push the residues of the concrete test block (10) crushed on the compression testing machine (16) to the slide way (33), and after the residues of the concrete test block (10) slide onto the conveyor belt (34), the residues are conveyed out of the loading workshop (3) by the conveyor belt (34) and loaded into the cell type residual sample box (15).

6. The concrete test block curing and loading integrated construction method according to claim 5, characterized in that: ejecting device (17) include telescopic shaft (20), limiting plate (21), push pedal (22), bottom plate (23) one side is equipped with limiting plate (21), bottom plate (23) middle part is equipped with telescopic shaft (20) and passes limiting plate (21) and connect push pedal (22).

7. The concrete test block curing and loading integrated construction method according to claim 6, characterized in that: ejecting device (17) still include balanced auxiliary rod (19), hydraulic pressure lift post (24) and base (25), base (25) are cuboid hollow steel structure, and inside is equipped with hydraulic pressure lift post (24), hydraulic pressure lift post (24) top is equipped with bottom plate (23), balanced auxiliary rod (19) mobilizable wear to establish on limiting plate (21) and one end connection push pedal (22).

8. The concrete test block curing and loading integrated construction method according to claim 1, characterized in that: sweep sign indicating number device (14) include base (25), horizontal pole (26), montant (27), bolt otic placode (29), scanning probe (30), base (25) top surface edge sets up montant (27), horizontal pole (26) are fixed on montant (27) upper portion through bolt otic placode (29), scanning probe (30) set up on horizontal pole (26).

9. The concrete test block curing and loading integrated construction method according to claim 8, characterized in that: sweep a yard device (14) and still include stopper (28) and test block thrust unit (31), stopper (28) are equipped with two at least, and when the stopper was equipped with two, two stoppers set up respectively in the corner both sides that close on with montant (27), and the length direction extension line of two stoppers is 90 contained angles, test block thrust unit (31) set up the diagonal department of contained angle between two stopper (28).

10. The utility model provides a concrete test block maintenance loading integration system which characterized in that: the concrete test block maintenance and loading integrated construction method of any one of claims 1 to 9 is adopted.

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