Technology is the core driving force for social development, and human society is gradually moving towards a more intelligent era with one round of technological revolution after another. In the inspection and testing industry, artificial intelligence and robotics are also effect

Technology is the core driving force for social development. Human society is gradually moving towards a more intelligent era with one round of technological revolution after another. In the inspection and testing industry, artificial intelligence and robotics are also effective driving forces for the transformation and upgrading of the industry.

In recent years, the core technology of robots has made significant breakthroughs. In the past, traditional industrial robots mainly followed a series of control instructions to complete tasks. With the development of artificial intelligence technology in areas such as perception, human-computer interaction, action control, and intelligent decision-making, robots are gradually being upgraded. For example, robot vision can enable sorting robots to recognize objects more accurately, and the sensing system can sense the surrounding environment.

According to statistics from the Ministry of Industry and Information Technology, my country's industrial robot production in 2020 was 237,068 units, a year-on-year increase of 19.1%; the operating revenue of industrial robot manufacturing enterprises above designated size nationwide was 53.17 billion yuan, a year-on-year increase of 6%, and the total profit was 1.77 billion yuan, a year-on-year increase of 1.77 billion yuan. It fell by 26.9%, and the decline narrowed by 24.4 percentage points compared with the first three quarters of last year. In December 2020, the national industrial robot production reached 29,706 units, a year-on-year increase of 32.4%. With the rapid development of advanced technologies such as artificial intelligence, robots have rapidly penetrated from the industrial field to the service industry. Service robots have shown a broader market space than industrial robots.

In addition, artificial intelligence is also developing at a rapid pace. Recently, IT and Internet companies in the United States have increased their investment in the fields of robotics and artificial intelligence, including multinational companies such as Google, FaceBook, and Microsoft. Our country has also included the term "artificial intelligence" in the national "14th Five-Year Plan" outline. Artificial intelligence has entered an inflection point of explosive growth.

So, what is the inevitable connection between robots, artificial intelligence, and the inspection and testing industry? Judging from the current development situation, my country's inspection and testing marketization mechanism is taking shape, domestic third-party testing is gradually liberalized, and everything is showing a trend of entering a better environment. But at the same time, relevant people also found that the concentration of the inspection and testing industry is low, with state-owned, foreign-funded, and private inspection and testing institutions dividing the market. The inspection and testing industry urgently needs to integrate resources through mechanism reform and technological innovation. Labor-intensive, The degree of automation, intelligence and standardization also needs to be further improved.

As labor prices rise, the "demographic dividend" of China's manufacturing industry is disappearing. At the same time, technological progress and industrial upgrading have led to the gradual reduction of "machine" costs, and "machine substitution" has become a new development trend. Inspection institutions such as SGS have successively developed intelligent inspection systems based on robots. Taking advantage of the advantages of robots, extremely high efficiency, accuracy and consistency can be achieved, while effectively reducing the impact of manual operations and human errors on inspection quality and efficiency.

In addition, the use of intelligent robots is particularly important when labor intensity is high and the environment is harsh. For example, in container inspection, quarantine and fumigation processing, the intelligent mobile robot platform can replace manpower to complete the delivery, concentration detection, environmental residue detection and other tasks of fumigants such as methyl bromide, phosphine, and ethyl acetate, freeing workers from toxic and harmful risks and Freed from harsh environment.

Based on the combination of artificial intelligence and the inspection and testing industry, people use VR, AR, MR and other technologies to form a new inspection and testing training and certification system. The inspection and testing training and certification model based on the new model of artificial intelligence will bring development opportunities to the inspection and testing industry, and has broad application prospects in observational learning, operational learning, social learning and research learning. The broad prospects of the inspection and testing market further highlight the necessity of leading the industry towards intelligence, improving inspection accuracy and efficiency through intelligent collaborative robot operation, extending the value chain of third-party inspection with the help of intelligence, and providing first-hand production for relevant industry decisions. Information will effectively promote the reform and rise of the inspection industry. In the future era of Internet big data for inspection and testing, if you want to be a trendsetter of the era, you must create the core competitiveness of "I have what others don't have, and I am one step ahead, and I have expertise and skills that are superior to others" in order to remain invincible.

Today, there are roughly three options and paths for intelligent testing laboratories:

A. The task is single and the types of instruments and equipment used are not many. There are related instrument and equipment manufacturers that provide a variety of optional integrated system solutions to build integrated experiments. The laboratory is intelligent;

B, the laboratory intelligent robot/system replaces the staff, and according to intelligent testing methods, procedures, and processes, the robot realizes the operation of instruments and equipment to form an intelligent laboratory;

C, AI technology has been integrated, Empowering the instruments and equipment used, an artificial intelligence robot/system can completely replace the staff, or even replace researchers and experts, to form and achieve a completely artificial intelligence laboratory.

Robots are generally divided into service robots and industrial robots. Service robots mostly refer to robots used to serve human life needs, while industrial robots are generally used for production needs. The robots in this article refer to industrial robots. Although they have different shapes and appearances, they are all very important tools for realizing laboratory automation. Usually we use degrees of freedom/joints to label robots. Similar to human arms, the more degrees of freedom/joints, the better the flexibility. In domestic laboratories, we can often see robots. In the field of scientific instruments, many companies have launched robots with different functions. We will introduce them with examples and conduct a brief analysis.

The liquid handling robotic arm used in Note 2 of Tecan’s fully automatic liquid handling workstation is a common three-degree-of-freedom robot form in clinical practice. Its advantage is high-throughput pipetting, which can process many samples at one time, and can even add 3 robots. Arm (mechanical gripper) is used to increase sample processing speed, which can greatly improve work efficiency and pipetting accuracy.

Pipetting robot arm Picture from: Tecan official website

Thermofisher’s SCARA robot arm is different from the robot arm in the picture above which only has 3 degrees of freedom. This SCARA robot arm has 4 degrees of freedom Note 3. It is worth mentioning that the robotic arm is equipped with a visual part that can perform visual teaching, which is very friendly to the experimenter's operation.

Spinnaker Picture from: Thermofisher official website

In addition to a few manufacturers developing their own special manipulators, more companies choose to use general-purpose manipulators with very mature technology on the market. Like the robot researcher mentioned in the previous article, they use a 7-axis robot. Below the robot is a positionable control cabinet. The robot has 7 degrees of freedom, is very flexible, and is relatively expensive.

Shimadzu also recently launched a direct reading/fluorometer automation system using a general-purpose manipulator Note 4. The XYZ manipulator has three degrees of freedom, which is sufficient for some processes in the laboratory and is cost-effective. It can be used for handling and moving samples at a given location. The six-axis manipulator has 6 degrees of freedom, so it has good flexibility and speed. It has a wider range of applications and can complete more complex processes and work. The general reach speed is 2m/s.

Six-axis robot Picture from: Shimadzu official website

XYZ robot Picture from: Shimadzu official website

In addition to analytical instrument companies, many equipment integrators are also actively deploying laboratory robots. For example, last year, Alfa Smith used a six-axis manipulator to complete the sample transfer process in the smart laboratory integrated by Conch Cement, and finally completed the sample testing.

Conch Cement Intelligent Integrated Experiment Center

Instron’s testing machine also uses a six-axis manipulator to form a fully automatic testing system.

Pictures of Instron’s robotic arm test system are from: Instron official website

Some robots have already shined in different fields. Although they are not yet used in laboratories, they have great application prospects for future smart laboratories. Let’s give a simple example below. introduce.

ABB's two-arm robot YuMi is a human-machine collaborative robotic arm. Different from ordinary robots, the robot has 14 degrees of freedom. It is very fast and flexible among collaborative robots. This will have advantages in handling some complex actions in future laboratories.

ABB's YuMi picture comes from: ABB official website

Parallel robots, commonly known as spider hands, are generally used to sort products on the assembly line. With the vision system, the spider hands are even more powerful and the sorting speed is very fast. This robot is suitable for future sorting in pipeline inspection by third-party inspection agencies, which can significantly reduce labor costs.

Fanuc's parallel robot Picture from: Fanuc official website

Hundreds of AGV cars running around in large logistics warehouses are also a hot type of robots at the moment. Similar transfer robots have been deployed in some third-party testing institutions. The entire process from warehousing, consumables, samples to testing can be completed by such robots, and the accuracy and efficiency will be greatly improved. Traditional specimen transfer within the laboratory is generally carried manually. This method is inefficient and requires manpower. For some laboratories with short TAT time requirements, frequent specimen transfer requirements, and relatively large space, intelligent robots are used. The transportation system can effectively solve such problems, help improve work efficiency, and ensure TAT. The intelligent robot specimen transportation system integrates sensor technology, mobile technology, operation control technology, artificial intelligence and other technologies. It has the visual sensors, auditory sensors and tactile sensors of human eyes, ears and skin. Through these systems, it can perceive the environment and make dynamic decisions. and planning, implementing behavioral control and task execution.

Intelligent specimen transport robot in the laboratory Picture source: CGTN

In addition, there are underwater robots, flip-up robots, high/low temperature robots, food robots, etc. for various special needs in various industries.

High and low temperature experimental collaborative robot image source: Chinese Academy of Sciences

Ford Motor Company's "Robutt" simulation robot test seat durability device is a robot test device that can imitate human hip movements. It can replace the traditional old-fashioned pneumatic cylinder test that moves up and down. The equipment can effectively carry out related seat life durability test projects. It can perfectly simulate the movement state of drivers and passengers when entering and exiting the vehicle, as well as various postures when sitting.

"Robutt" is built based on the hip size of a medium-sized man and can simulate the experience of most drivers and passengers. It can perform up to 25,000 sitting and standing movements to test the wear and tear of the seat after 10 years of use. The entire test process can be completed in only 3 weeks. This kind of frequency is impossible for real people to achieve, even superhuman beings would be daunted by it.

Its working principle and process are simply this: Engineers use a special cushion that can sense pressure to analyze and determine the most suitable sitting posture for consumers. Through the data collected by this pressure pad, "Robutt" can simulate the most common getting in and out of the vehicle and riding postures, and test the wear resistance of the seat fabric. Ford also said that the test has begun to be applied to all Ford models in Europe.

Motor vehicle seat durability test robot picture source: Ford Motor Company

The following inspection and detection application system is an actual development project case of Delta Instrument Company:

Smart door lock life durability test system

1. Equipment usage:

Electronic/Fingerprint The door lock life durability test system is used to conduct simulated behavior tests on electronic anti-theft locks and other products such as biometric door opening, fingerprint door opening, key door opening, password door opening, magnetic card door opening, face recognition door opening, mechanical key unlocking, etc. This system provides multiple Several test modes are available for test selection, complying with GA374-2019, GB 21556-2008 general technical conditions for lock safety, JG/T 394-2012, IEC 62692 digital door lock system standard, UL294 access control system, UL1037, BHMA A156.25, BHMA A156.13, BHMA A156.36 and other relevant standard test requirements. An integrated life test system specially designed for the research and development of password electronic door locks, fingerprint electronic door locks, and card smart door locks; meets the standard: the number of repeated opening and closing times in JG/T394-2012 "General Technical Requirements for Building Intelligent Door Locks" is 6.14.

2. Main compliance standards:

) Chapter 5.10 "Durability" requirements in the GA374-2019 "Electronic Anti-theft Lock" standard;

) Chapter 7.5.1.3 "Battery capacity" in the GA701-2007 "General Technical Requirements for Fingerprint Anti-theft Locks" standard and undervoltage indication test" requirements;

) The test requirements for "Number of Repeated Openings and Closings" in Section 6.14 of the JG/T394-2012 "General Technical Requirements for Building Intelligent Door Locks" standard.

3. Robot testing principle:

Electronic/fingerprint smart door lock life durability testing system uses a collaborative six-axis robot as a driver to simulate and restore the actual unlocking scene. The entire structure of the robotic arm is a space-jointed type with multiple free dimensions and can be used to Measure electronic locks to achieve precise positioning. The robotic arm is made of hard aluminum alloy material and has a hollow pipe structure, which not only ensures high stiffness of the arm, but also reduces the weight of the arm and reduces the load on the motor. The control system uses PLC to set and control the action sequence of the servo motor, and has both timing and counting functions. The sensor switch of the mechanical arm detects the status of each working point and determines the quality of the sample electronic lock, thereby making corresponding decisions. deal with.

4. Technical features:

. The servo motor is used as the transmission power source; the system is driven by a collaborative six-axis robot, which is agile and free and within reach. It can be used with sensors and deep learning to conduct detection tests of multi-dimensional movements of electronic locks;

. It uses a six-axis robot to operate in multiple dimensions, which can truly simulate human arm and finger movements;

, uses a highly elastic silicone fingerprint film to replace fingers to unlock fingerprints, with a wide range of fingerprints and a more realistic simulation effect;

, combines various types of anti-theft Electronic locks, smart electronic locks, fingerprint locks and other products can be tested separately on one system;

. This system can test samples 24 hours a day without manual attendance, which greatly improves detection efficiency and liberates labor;

. It has a power-off protection function and can continue testing without manual intervention after powering on;

. It can record the number and time of the switch experiment;

. It has the function of presetting the number of experiments and the experimental time;

. It has the function of presetting the number of experiments and the experimental time;

. Completion and error alarm functions;

0, one-time investment, low later maintenance costs, lifetime free software upgrades, reducing the testing cost of experiments;

1, the main configuration components of the system, such as drive motors, touch screens, PLCs, data acquisition cards and other key Components should be of internationally renowned brands to improve the grade and reliability of the equipment and meet the requirements of relevant tests;

2, the system's voltage, current, temperature, force value, frequency and other technical parameter accuracy requirements comply with CTL-251B Require.

5. Robot test steps:

. Fingerprint unlocking test process:

A. Pull up the outer handle to release the square tongue

B. Release the safety button inside the door to release the safety

C. Push up the sliding cover of the housing and power on

D. Press the fingerprint button

E. Press down Handle

F. Move the simulated door to open the door

G. Push down the sliding cover of the housing and power on

H. Reset the handle, and the robotic arm applies 50N force to close the simulated door

. Password unlocking test process:

A. Pull up the outer handle to open the square tongue

B. Door The inner safety button activates the safety tongue

C. Push up the sliding cover of the casing and power on

D. Press the virtual password key

E. Press down on the handle

F. Move the simulated door to open the door

G. Push down the sliding cover of the casing and power on

H. Reset the handle, mechanical Apply 50N force to the arm to close the simulated door

. Magnetic card unlocking test process:

A. Pull up the outer handle to pull out the square tongue

B. Use the safety button inside the door to pull out the safety tongue

C. Push up the sliding cover of the housing and power on

D. Swipe the card

E. Press down on the handle

F. Move the simulated door to open the door

G. Push down the sliding cover of the housing and power on

H. Reset the handle, and the robotic arm applies 50N force to close the simulated door

. AI face recognition unlocking test process:

A. Start the simulated avatar heating system

B. Scan Face recognition module

C. Pull up the outer handle to release the square tongue

D. Use the safety button inside the door to release the safety

E. Push up the sliding cover of the housing to power on

F. Press down on the handle

G. Move the simulated door to open the door

H. Reset the handle and the robotic arm Apply force to close the simulated door

. Mechanical key unlocking test process:

A. Insert the mechanical key

B. Turn the key clockwise to open the door lock

C. Turn the key counterclockwise to close the door lock

Household appliance door switch life durability test system

1. Equipment overview:

household appliance door switch life durability test system can comply with IEC60335-1/GB4706.1 "Safety of Household and Similar Electrical Appliances Part 1: General Requirements", IEC60335-2-24:2007/GB 4706.13 -2014 "Special requirements for the safety of refrigeration appliances, ice cream machines and ice machines for household and similar electrical appliances", IEC60335-2-7/GB4706.24-2008 "Special requirements for the safety of washing machines for household and similar electrical appliances" and GB /T 8059-2016 "Household and Similar Refrigeration Appliances" standard Chapter 10 "Durability Test of Doors, Covers and Drawers" and other requirements. This test system is an intelligent robot automatic test equipment designed and manufactured according to the standard test requirements for the service life of door locks and hinges of various refrigerators, washing machines, microwave ovens, ovens, and disinfection cabinets. , different specifications of washing machines, flexible and comprehensive various indicator settings and action simulations.

2. Testing principle:

Smart switch door life durability test system uses the most advanced collaborative six-axis robot as a driver to simulate and restore the real scene of actual door opening and closing of tested refrigerators, washing machines and other products. The entire structure of the collaborative robot arm is a space joint It has multiple degrees of freedom and can accurately position the product under test. The robotic arm is made of hard aluminum alloy material and has a hollow pipe structure, which not only ensures high stiffness of the arm, but also reduces the weight of the arm and reduces the load on the motor. The control system uses PLC to set and control the action sequence of the servo motor, and also has timing and counting functions. The sensor switch of the mechanical arm detects the status of each working point, and determines the quality of the sample, so as to make corresponding processing.

3. System technical features:

. It uses imported ultra-quiet servo motors as the transmission power source and uses a six-axis robot to operate in multiple dimensions, which can truly simulate the door opening and closing actions of human arms and fingers;

. Technology is the primary productive force. , intelligent robots have entered ordinary safety laboratories, showing the high-end style of the laboratory;

. Various types of refrigerators, washing machines, microwave ovens, ovens, disinfection cabinets and other products can be tested on one experimental system;

, can test samples 24 hours a day, without manual attendance, which greatly improves detection efficiency and liberates labor;

, has a power-off protection function, and can continue testing without manual intervention after power-on;

, can perform switch experiments Record the number of times and time recorded, with the function of presetting the number of experiments and presetting the experimental time;

, with the function of experiment completion and error alarm;

, one-time investment, low later maintenance costs, lifetime free software upgrades, reducing the detection of experiments cost.

4. Test steps and technical parameters:

. Test procedure for opening and closing the door:

A. Load the test load (freezing test package)

B. Open the door (the opening angle is from 0° to 5° to 15°)

C. The door is free to open

D. The door is closed (from the opening angle 45° to 40° to 35°)

E. The door is free to close

F. The door is opened cyclically

. Test station: one or more specimens can be tested according to customer requirements ;

. System test drive: The working method adopts six-axis robot operation, which is flexible and free and within reach. It can be used with sensors and deep learning to detect the three-dimensional movement of door opening and closing;

. The maximum load of the six-axis robot: 5Kg;

, Robot working radius: 900mm;

, Robot body rated current 7.3A rated voltage DC48V

, Maximum working speed: 3m/s

, Robot joint range of motion: J1 ±360° J2 ±360° J3 ±160° J4 ±360° J5 ± 360° J6 ±360°;

, joint maximum speed (°/s) J1 180°/s J2 180°/s J3 180°/s J4 180°/s J5 180°/s J6 180°/s;

0, End of robot arm: I/O DI 2 DO 2 AI 2 AO 0;

1, repeat positioning accuracy ±0.03mm;

2, number of control axes: 6 axes + external expansion axis;

3, fixing method of manipulator and door: vacuum suction cup or Customized silicone fixture;

4, communication method: TCP/IP, Modbus, EtherCAT, wireless network;

5, test times: 0~99999999 times can be preset;

6, test frequency: 0~15 times/min can be preset;

7, Control and operation: computer intelligent program control operation;

8, equipment power supply: AC220V 50/60 Hz; power: 1.25KW;

9, overall dimensions: (W*D*H) about 1250×750×1650mm;

0, weight: approx. 375Kg.

Smart toilet durability test system

Applied to the National Smart Toilet Product Quality Supervision and Inspection Center (Zhejiang) in Taizhou - the smart toilet durability test system compared to traditional testing equipment, this system innovatively uses mechanical vision and manipulators, which can It saves more than 80% of the installation time of inspection personnel. At present, the system has been used in the daily inspection process of the National Intelligent Toilet Product Quality Inspection Center and in the finalization of enterprise products.

smart toilet durability test system is suitable for testing the opening and closing life of smart toilet/smart toilet lids and rings (including slow drop type), seat rocking test, and pressure test; and can also verify the smart toilet remote control switch Lifetime durability is tested and verified.

1. According to standards:

JG/T285-2010 toilet bidet

GB/T23131-2019 electronic toilet

CBMF15-2019 smart toilet

GB/T34549-2017 sanitary ware smart toilet

JD0001-2016 Intelligent toilet seat

two , Test items:

GB/T23131-2019 Electronic toilet: Overall machine life (durability)

JG/T285-2010 Toilet bidet: Mechanical strength, reliability test

GB/T34549-2017 Sanitary ware smart toilet: Mechanical strength , Whole machine life

CBMF15-2019 Smart toilet: Mechanical strength, whole machine life

JD0001-2016 Smart toilet seat: Whole machine operation durability

Aluminum alloy door and window durability test system

1. Equipment overview:

New national standard aluminum alloy The door and window durability test system meets all the requirements of clauses 6.6.9 and 6.6.10 of the standard GB/T8478-2020 "Aluminum Alloy Doors and Windows", and can also meet the requirements of GB/T39529-2020 "General Technical Conditions for System Doors and Windows" and GB 17565-2007 "General Technical Conditions for Anti-Theft Security Doors". It is applicable to various test requirements for the mechanical properties of doors and windows, which are the ability of movable fans to maintain normal functions under the action of mechanical force. It can simulate and determine the mechanical properties of doors and windows based on their opening forms and usage characteristics. This testing system can be used to replace the bulky, single-function life testing machine driven by cylinders and motors in traditional building door and window inspection laboratories. One machine has multiple uses. The inspection methods and means of realizing test functions are flexible and changeable, and can realize a variety of The life durability test of doors, windows and hardware of various specifications can be extended to the opening and closing durability test of household appliance door covers, anti-theft doors, high-speed train doors, automobile doors and their parts, etc., with a wide range of applications.

2. Main functions of the equipment:

.1 meets the mechanical property test (opening and closing force) test requirements of anti-theft doors and aluminum alloy doors and windows;

.2 meets the test requirements of "repeated opening and closing durability test" of anti-theft doors and aluminum alloy doors and windows. .

3. Main technical parameters:

.1, accuracy: 0.1N

.2, deformation measurement range: ≥20mm

.3, the clamp should meet the requirements listed in Table 9 and Table 10 of the GB/T8478-2020 "Aluminum Alloy Doors and Windows" standard Clamps for all forms of doors and windows.

.4, the number of tests is 0~9999999 times, can be set, with power-off memory function;

.5, two sets of door and window installation frames;

.6, door and window (sash) opening speed: 0.2m/s~0.5m/ s is adjustable;

.7, opening force: real-time display, maximum value can be set, 0~100ON;

.8, opening position pause time: 1s~4s adjustable;

.9, maximum size of external doors and windows: ( Height*width*thickness) 2400*2000*150mm;

.10. Maximum size of lifting sliding doors and windows: (height*width*thickness) 2400×2000×150mm;

.11. Equipment overall dimensions: (length*width*height) 4200mm*2500mm*2800mm;

.12. Opening and closing durability test: The six-axis robot testing system controls the doors and windows to conduct various tests.

4. Equipment accessory configuration:

.1 1 set of six-axis robot control system

.2 1 set of door opening clamp

.3 1 set of specimen frame

.4 1 set of control cabinet

.5 1 set of computer

.6 Sample test 1 set of installation tools

Furniture Comprehensive Mechanics Intelligent Test System

Furniture Comprehensive Mechanics Testing Robot System is an upgrade developed for the traditional CNC machining industry motion control technology. It has an open structure and can be quickly reorganized according to specific application requirements. It adopts Based on the open structure of the network, the computing power of DSP is used to perform complex motion planning, high-speed real-time multi-axis interpolation, error compensation and kinematics and dynamics calculations to achieve high-precision, high-speed and smooth motion of motion control. This enables testing of the mechanical properties of furniture such as (tables, chairs, cabinets, beds).The mechanical performance test of furniture is a test that simulates the strength or endurance of various parts of the furniture under one-time or repeated loads during normal use and habitual misuse. The four sides of the specimen are loaded cyclically with specified force values ​​repeatedly. After a certain number of times, check whether there is any damage to the sample structure, function, etc., so as to understand the performance and defects of the product.

Cabinet and Cabinet Door Durability Test System Robot

Cabinet and Cabinet Door Durability Test System Robot is used to simulate cabinets and cabinet furniture’s ability to resist tipping under the conditions of bearing loads during daily use. The cabinet and cabinet door durability testing system robot is suitable for strength, fatigue and durability testing of cabinets and cabinet doors. Robot test loading pad: diameter 200mm.

According to the standard:

GB/T 10357.5-2011 "Furniture Mechanical Performance Test Part 5: Cabinet Strength and Durability"

l7.1.2.1 Sliding door vertical loading test

l7.1.4 Sliding door durability test

GB/T10357.4- 2013 4.4 Cabinet stability

GB/T10357.4-2013 4.5.2 Loading stability test when movable parts are opened

GB/T 18884.3-2015 4.6.2.7 Cabinet door durability test

GB/T 29498-2013 5.4.5.4 Wooden door Repeat Opening and closing durability performance

office chair durability test system robot

chair durability test robot system is suitable for testing the strength and durability of office chairs, joint testing of seat surface and chair back durability, armrest pillow durability, backrest and armrests Impact, forward stability performance. The supporting fixture can easily and conveniently adjust the loading position to adapt to specimens of different specifications. The positioning handle is convenient for positioning and improves work efficiency. The specimen clamping does not require tool coordination, making it simple, fast and convenient.

Mattress Durability Testing System Robot

Mattress Durability Testing System Robot is suitable for rolling tests on the central sleeping area of ​​the mattress pad using a roller of a certain weight to simulate the impact of human body rolling on the mattress during sleep. , conduct a loading durability test on the edge of the mattress with a loading pad of a specified shape and a specified force value, simulating the impact of a user sitting on the edge of the mattress and loading the mattress with the buttocks. After a certain number of loadings, the mattress height, edge height, hardness changes and mattress damage before and after the test are compared to evaluate the quality of the mattress.

Test items: including the following test and measurement items:

. Mat surface durability test

. Edge durability test

. Mattress height measurement

. Hardness value measurement

Mattress resilience test system robot

Mattress resilience test The system robot is suitable for simulating the impact of a spring mattress on the human hip during use to evaluate its fatigue life performance. Use a butt-shaped impact head to exert repeatable, controllable and countable impacts on the surface of the mattress and box spring unit, measure the support firmness of the mattress and box spring unit, and use the dimples formed on the surface of the mattress to measure the mattress and deformation of the box spring unit. The mattress resilience testing system robot uses a specific loading block to repeatedly impact the mattress to evaluate its durability and spring retention.

Sofa durability test system robot

Sofa durability test system robot is used to simulate the sofa's ability to withstand long-term repetitive loads under daily use. The sofa durability testing system robot mainly tests the durability of the seat, back and armrests of the sofa. During the test, a loading module of a certain shape and mass is repeatedly loaded on the seat, back and armrest surfaces in a prescribed loading form and frequency.

Sofa durability test system robot technical parameters:

. Seat loading module: 50kg diameter 200mm impact surface R341mm

. Back loading module: 200mmx100mm

. Armrest loading module: diameter 50mm

. Counterweight block: 70kg, diameter 350mm

.Loading frequency: 0.33 Hz～0.42Hz (20～25 times/min)

. Back loading block spacing: 300mm

. Armrest loading angle: 45 degrees

Car seat fatigue durability test system

Car seat fatigue durability test system The most advanced robot application Collaborative robot technology and automatic control and measurement are integrated into the fatigue test of car seats to achieve the integration and automation of seat testing and measurement. It can achieve precise control of the position and force of the action process and complete it during the action process. Measurement of characteristic parameters. This system can use robot drive control to repeatedly impact the seat at a certain speed and a certain load to test the durability and safety performance of the seat.

car seat fatigue durability test system is suitable for the car seat durability performance test specified in the national standard GB15083-2004 and the professional standard ZBT26008; its performance indicators can fully meet domestic and foreign standards, such as ECER17 (European Community Regulations) , FMVSS207 (U.S. Federal Regulations), national standards and the test requirements for seat durability and seat safety performance in the German Volkswagen EP standards.

test items:

, car seat cushion durability test;

, car seat cushion static stiffness test;

, car seat recliner alternating load durability test.

main technical parameters:

, loading stroke: 0~600mm;

, loading load: 0~200Kg (or specified);

, loading frequency 0~30 times/minute.

Car door opening and closing durability test system

Car door opening and closing durability test system is mainly used for side doors, engine hoods, and back doors (trunk lids) of small passenger cars, SUVs (off-road vehicles), and business MPVs. And the opening and closing durability test of the fuel filler cap; to verify whether the structure and strength of the four-door and two-cover system meet the product design requirements.

1. According to standards:

) GB15086 "Performance requirements and test methods for automobile door locks and door retaining parts"

) QC/T 586 "Automobile door hinges"

) QC/T323 "Automobile door locks and door retaining parts"

) QC/T 627 "Automotive Electric Door Lock Device"

) QJQ 6136-2010 "Opening and Closing Part System Reliability Test Method"

) Q/JSKW-B-0028-2020 "Passenger Car Opening and Closing Parts Durability Test Specification"

Note: Standards that do not indicate the year adopt the standards that are promulgated, revised or under revision.

2. Test items:

) Side door opening and closing durability test;

) Engine hood opening and closing durability test;

) Trunk lid opening and closing durability test;

) Closing speed performance test;

) Closing force performance test.

Intelligent Robot Fully Automatic Impact Test System

Intelligent Robot Fully Automatic Impact Test System integrates a metal material mechanical impact testing machine, an automatic temperature control low-temperature tank, visual positioning, robots, sorting and collection devices and information management software. It performs manual batch processing After the specimens are loaded, batched and tasks are assigned, the system will automatically carry out the cooling, insulation, loading and impact of the specimens, and automatically upload the test data after the test is completed, realizing a fully automatic impact test. The structure of the

intelligent robot fully automatic impact system is shown in the figure. The robot sets the parameters of the impact sample: the test time (from cooling environment to completion of impact) is less than 4.5s; the symmetry plane of the notch of the impact sample deviates from the anvil. The point is not larger than 0.1mm (the industry requirement is not larger than 0.5mm).After the test is completed, the system will determine whether the impact sample is qualified or not.

Intelligent robot fully automatic impact system improves the intelligence level of laboratory equipment, can realize automatic heat preservation control of low-temperature tank, improves the stability of feeding rhythm, ensures the accuracy of sample placement, and realizes automatic transmission of data , enhances the standardization of test operations, eliminates human errors, and improves test accuracy and work efficiency.

1. Test standards:

The intelligent robot fully automatic impact test system complies with GB/T 229-2007 "Charpy Pendulum Impact Test Method for Metallic Materials" (or ISO 148-1: 2006

Metallic Materials—CharpyPendulumImpactTest—Part1: TestMethod) and ASTME23- 2012cStandardTestMethods

for Notched Bar Impact Testing of Metallic Materials for impact testing. Among them, GB/T 229-2007 (or ISO 148-1:2006)

is suitable for tests at room temperature and high and low temperatures, while ASTME23-2012c is suitable for tests at temperatures higher than -196°C. The intelligent robot fully automatic impact system is developed in accordance with the Charpy pendulum impact test standard requirements. Strict control is carried out in terms of sampling rhythm, sampling position, sample transmission, recording and reading of test data.

2. Test process:

Before using the intelligent robot fully automatic impact test system for impact testing, preparations must be made, including checking the status of the equipment and whether the sample meets the test standards, such as checking whether the pendulum is placed in place and the impact blade Whether the gap with the sample reaches the standard, whether the pointer returns to zero, whether the position of the impact system arm is accurate, etc. The test process is carried out in accordance with the methods specified in GB/T 229-2007 (or ISO 148-1:2006) or ASTM E23-2012c. The intelligent robot fully automatic impact test system is set according to the Charpy pendulum impact test standard. The impact test time is constant, ensuring the consistency of the test rhythm. The obtained test results have small deviations and more concentrated data distribution, reducing human errors and testing The volatility of the results reduces the probability of misjudgment and misjudgment of test results, and improves test efficiency and result accuracy.

Intelligent Robot Fully Automatic Tensile Testing Machine System

Intelligent Robot Fully Automatic Tensile Testing Machine System product integrates materials mechanics tensile testing machine, fully automatic measuring device, robot and information management software. It can manually conduct batch samples After the loading, batching and classification tasks are issued, the loading, measurement, centering, stretching, and waste sample classification of the samples are automatically carried out. The measurement data is automatically uploaded, the experimental results are automatically uploaded, and whether the sample is qualified or not is automatically determined. Fully automated tensile testing in the tensile laboratory. This test system improves the intelligence level of laboratory equipment, can realize automatic measurement and centering of samples, accurate data measurement, automatic transmission of test results, standardizes test operations, eliminates human errors, and improves test accuracy and Work efficiency. This test system represents the development level of intelligent technological equipment in laboratories in my country and will become the mainstream model for tensile testing in intelligent laboratories in my country.

Product innovation points:

. Integrated design of tensile testing in mechanics laboratory based on intelligence;

. Independently developed communication interface board to realize control of imported tensile testing machines;

. Developed background data management software to realize test Intelligent management functions such as sample batch processing, real-time judgment of test results, automatic data transmission, and real-time monitoring of equipment operating status;

, the arc design of the robot's gripper jaws can effectively ensure that the specimen remains flat when clamping a 60mm thick specimen. Vertical;

, fully automatic measuring device replaces traditional manual measurement, which improves accuracy and efficiency. Multiple measurement methods can be switched, and two working modes can be selected, which can be used online or offline. The structure is light and easy to move. The measurement accuracy reaches ±0.01mm, and the applicable spline range is: thickness 3~60mm, length 200~500mm;

, using a collaborative six-axis robot, has high repeatability positioning accuracy. The system has excellent stability and performance;

, production data visualization, and hierarchical management of operation screens.The safety protection system is complete. The protection interlocking of robot clamping claw protection, extensometer protection, and fully automatic measuring device is effective and reliable;

, qualified and unqualified samples can be classified and placed according to different requirements of the sample to facilitate the operator.