CN112067329A - 3D printer delivery detection system, printer, detection method and storage medium - Google Patents

Abstract

The invention relates to a 3D printer delivery detection system, a printer, a detection method and a storage medium. The 3D printer delivery detection system comprises a software detection system, a hardware detection system and a data reporting system; the software detection system comprises a part detection unit, an equipment function detection unit and a printing product detection unit, wherein each detection unit comprises a data receiving module, a data analysis module and a data feedback module which are electrically connected; the data receiving module is used for receiving detection data provided by the hardware detection system; the data analysis module compares preset data with data of the data receiving module to judge whether the analysis meets the factory standards of the corresponding units; and the data reporting system reports the detection passing according to the delivery standard-reaching detection result of the feedback module of each detection unit. The 3D printer delivery detection system, the printer, the detection method and the storage medium have high detection efficiency and are comprehensive in detection.

Description

3D printer delivery detection system, printer, detection method and storage medium

Technical Field

The invention relates to the technical field of 3D printing, in particular to a factory detection system of a 3D printer, the printer, a detection method and a storage medium.

Background

With the gradual maturity of 3D printing technology, the sand mould 3D printer that the casting field used has obtained the wide application, and the market demand of 3D printer rises year by year. However, due to the fact that the 3D printer system is complex, functions related to machinery, electric control and software are numerous, in the batch production process, delivery inspection process items are numerous, inspection automation degree is low, and manpower and material resources are consumed very much. Particularly, the abnormal alarm function of the system needs to be triggered manually, so that the condition of missing inspection sometimes occurs, and the detection of the software function is more a soft rib in factory inspection, so that the stability and the reliability of equipment qualified in factory inspection after factory shipment are severely limited. In general, the factory detection method of the 3D printer is incomplete, the detection time is long, the detection efficiency is low, and the production cost is increased.

Disclosure of Invention

Therefore, it is necessary to provide a 3D printer factory detection system, a printer, a detection method, and a storage medium with high detection efficiency and comprehensive detection for solving the problems of low factory detection efficiency, long detection time, and high production cost of a 3D printer in the prior art.

A3D printer delivery detection system comprises a software detection system, a hardware detection system and a data reporting system; the software detection system comprises a part detection unit, an equipment function detection unit and a printed product detection unit, wherein each detection unit comprises a data receiving module, a data analysis module and a data feedback module which are electrically connected; the data receiving module is used for receiving detection data provided by the hardware detection system; the data analysis module compares preset data with data of the data receiving module to judge whether the analysis meets the factory standards of the corresponding units; the data feedback module feeds back a detection result according to the analysis result of the analysis module; and the data reporting system reports the detection passing according to the delivery standard detection result of the feedback module of each detection unit.

In one embodiment, the hardware detection system at least comprises an EMC detector, a ground resistance tester, a sensor tester, a laser interferometer, a tension tester, a density tester, a three-dimensional scanner, a visual recognition instrument and a hardware watchdog.

In one embodiment, the data detected by the component detecting unit at least includes: the installation straightness of the spray head, the flatness of a bottom plate of the printing head, the angle of a sand scraping plate of the sand spreader, the straightness of the sand scraping plate of the sand spreader, the lifting precision of a lifting mechanism of the working box, the flatness of a bottom plate of the working box and the straightness of an X-axis guide rail.

In one embodiment, the equipment function detection unit at least comprises a sand mulling unit, a printing head unit, a sand spreader unit, a liquid material station unit and a sand cleaning station unit; the detection data of the sand mulling unit at least comprises weighing system calibration, setting of the amount of mulling, setting of the mulling time, setting of the proportion of a curing agent, detection of the uniformity of mulling, detection of the temperature of the mulling sand and setting of the stirring speed of the mulling sand; the detection data of the printing head unit at least comprises a printing head power supply test value, a printing head board card temperature test value, a printing head communication test value, a printing head nozzle ink jet waveform test value, a printing head negative pressure test value and a printing head nozzle ejection rate test value; the detection data of the sand spreader unit at least comprises a sand level sensor setting test value, a vibration frequency setting test value and a sand outlet gap setting test value; a sander speed setting test value and a print layer thickness setting test value; the detection data of the liquid station unit at least comprises the liquid level of each liquid bucket, an upper limit alarm value and the flow of the resin flowmeter; the detection data of the sand cleaning station unit at least comprises parameters of each frequency converter, the operation state of the sand cleaning station and the operation state of each roller way detection sensor of the rotary box changing station.

In one embodiment, the printed product detection unit comprises a printed test block detection unit and a printed result product detection unit; the printing test block detection unit comprises density detection, compression resistance detection, tensile detection and line detection; the detection unit of the printing result product comprises length detection, width detection, height detection, inclined plane detection, curved surface detection and gas evolution detection.

In one embodiment, the software detection system further includes a communication detection unit, and the communication detection unit determines whether the software detection system meets the factory detection standard according to communication detection data provided by the hardware detection system and by comparing with standard data.

In one embodiment, the software detection system interfaces with the MES system through data sharing.

In one embodiment, the storage mode of the detection data of the software detection system includes at least one of database storage, cloud platform storage and print report storage.

In one embodiment, the software detection system is provided in a 3D printer.

In one embodiment, the data reporting system includes a voice reporting module, and the voice reporting module performs voice reporting according to the detection result that each detection unit passes the factory standard.

In one embodiment, the data reporting system includes a validation module that includes a signature sub-module or a fingerprint sub-module.

A3D printer comprises the 3D printer factory detection system in any one of the embodiments.

A detection method is detected by adopting the 3D printer delivery detection system of any embodiment, and comprises the following steps: acquiring detection data according to a hardware detection system; analyzing whether the detection data meet the delivery standards of all detection units of the software detection system; and when all the detection units meet the delivery standard, feeding back delivery detection results by adopting a data reporting system.

A computer-readable storage medium, wherein a computer program is stored on the computer-readable storage medium, and when being executed by a processor, the computer program implements the steps of the detection method of the 3D printer factory detection system according to any one of the above embodiments.

According to the 3D printer delivery detection system, the printer, the detection method and the storage medium, data acquisition is performed through the hardware detection system, so that the detection efficiency is greatly improved, the waste of manpower and material resources is reduced, and the cost is saved; and transmitting the data to a software detection system for analysis and judgment, and reporting a final detection result through a reporting system when the parts detection unit, the equipment function detection unit and the printing product detection unit are comprehensively detected and analyzed to reach the factory standard. Therefore, the 3D printer factory detection is more standard and comprehensive through the 3D printer factory detection system, and the problems of factory omission or inaccurate detection caused by non-standard operation are reduced.

Detailed Description

In order that the invention may be more fully understood, preferred embodiments of the invention are now described. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

In one embodiment, a 3D printer factory detection system includes a software detection system, a hardware detection system, and a data reporting system; the software detection system comprises a part detection unit, an equipment function detection unit and a printing product detection unit, wherein each detection unit comprises a data receiving module, a data analysis module and a data feedback module which are electrically connected; the data receiving module is used for receiving detection data provided by the hardware detection system; the data analysis module judges whether the analysis accords with the factory standard of the corresponding unit according to the data comparison preset data of the data receiving module; the data feedback module feeds back a detection result according to the analysis result of the analysis module; and the data reporting system reports the detection passing according to the delivery standard-reaching detection result of the feedback module of each detection unit.

In one embodiment, the 3D printer comprises the 3D printer factory detection system.

In one embodiment, a detection method using the factory detection system of the 3D printer includes the following steps: acquiring detection data according to a hardware detection system; analyzing whether the detection data meet the delivery standards of all detection units of the software detection system; and when all the detection units meet the delivery standard, feeding back delivery detection results by adopting a data reporting system.

In an embodiment, a computer readable storage medium, on which a computer program is stored, the computer program, when being executed by a processor, implementing the steps of the detection method of the 3D printer factory detection system according to claim 13.

According to the 3D printer delivery detection system, the printer, the detection method and the storage medium, data acquisition is performed through the hardware detection system, so that the detection efficiency is greatly improved, the waste of manpower and material resources is reduced, and the cost is saved; and transmitting the data to a software detection system for analysis and judgment, and reporting a final detection result through a reporting system when the parts detection unit, the equipment function detection unit and the printing product detection unit are comprehensively detected and analyzed to reach the factory standard. Therefore, the 3D printer factory detection is more standard and comprehensive through the 3D printer factory detection system, and the problems of factory omission or inaccurate detection caused by non-standard operation are reduced.

The 3D printer factory detection system is described below with reference to specific embodiments to further understand the inventive concept of the 3D printer factory detection system.

In one embodiment, the 3D printer factory detection system comprises a software detection system, a hardware detection system and a data reporting system; specifically, the software detection system can be independently operated on hardware outside the device, including on intelligent terminals such as a computer, a tablet computer, a mobile phone, and the like. In one embodiment, the software detection system is provided in a 3D printer. Namely, when the 3D printer conditions allow, the software detection system can also run on the hardware of the 3D printer, including the industrial personal computer, the CPU of the PLC and the like, and can display the operation interface of the software detection system on the operation terminal so as to facilitate the operation. Specifically, the software detection system is connected with the detected 3D printer in a network communication mode, so that data on the 3D printer can be acquired, and data can be issued to the 3D printer. In one embodiment, the hardware detection system at least comprises an EMC detector, a ground resistance tester, a sensor tester, a laser interferometer, a tension tester, a density tester, a three-dimensional scanner, a visual recognition instrument and a hardware watchdog. That is, the hardware detection system is some detection device and instrument that the software detection system needs to be assisted by. The 3D printer leaves the factory and comprehensively detects mainly including detecting the spare part of 3D printer, the function of 3D printer and the product that 3D printer printed. The data reporting system is used for reporting that the parts of the 3D printer, the functions of the 3D printer and the products printed by the 3D printer are qualified when the detection results of the parts, the functions and the products are qualified, and the data reporting system can be delivered from a factory. In one embodiment, the data reporting system includes a voice reporting module, and the voice reporting module performs voice reporting according to the detection result that each detection unit passes the factory standard. That is, the data reporting system may report the detection result by voice. Further, the data reporting system comprises a validation module, and the validation module comprises a signature sub-module or a fingerprint identification sub-module. That is to say, the mode of finally confirming that the factory inspection is qualified and effective needs to be confirmed by signing or checking a card in a fingerprint identification mode, so that the precision of the factory inspection can be further ensured.

In one embodiment, the software detection system comprises a part detection unit, an equipment function detection unit and a printed product detection unit, wherein each detection unit comprises a data receiving module, a data analysis module and a data feedback module which are electrically connected; the data receiving module is used for receiving detection data provided by the hardware detection system; the data analysis module compares preset data with data of the data receiving module to judge whether the analysis meets the factory standards of the corresponding units; the data feedback module feeds back a detection result according to the analysis result of the analysis module; and the data reporting system reports the detection passing according to the delivery standard-reaching detection result of the feedback module of each detection unit. It should be emphasized that each detection unit includes a corresponding data receiving module, a data analysis module and a data feedback module, and the data receiving mode of the data receiving module, the data analysis mode of the data analysis module is not consistent according to the different adopted modes of the corresponding detection units, and the data feedback module is also inconsistent for the data report that whether the data report meets the factory detection result, for example, some feedback information is a temperature value, some feedback information is a frequency value, and some feedback information is a state value.

In one embodiment, the data detected by the component detecting unit at least includes: the device comprises a spray head installation straightness, a printing head bottom plate flatness, a sand spreader sand scraping plate angle, a sand spreader sand scraping plate straightness, a work box lifting mechanism lifting precision, a work box bottom plate flatness and an X-axis guide rail straightness. That is, the data detected by the part detection unit includes different data conditions that affect the final printing effect of the 3D printer on the part. It should be noted that, the 3D printer factory inspection system sets a limit value for the parameter of each part according to the design drawing, after the inspection is completed, the test value of the inspection system can be automatically read into the filling box, or manually output into the filling box, and if the test value is within the limit value, the display accuracy of the system is qualified. And when the detection parameters of all the parts reach the limit value, the parts can be judged to be qualified.

The specific detection and analysis process is as follows: the data receiving module of the part detection unit is adopted to receive corresponding detection data, then the data analysis module is adopted to compare the data of the data receiving module with a preset limit value, whether the data is in the limit value or not is judged, when a certain part is detected to be unqualified (the detection data is not in the limit value), the detection flow returns to an unqualified branch, and the part is sent for detection again after being processed in a replacement, repair or reassembly mode; if necessary, the parts in the parts need to be re-inspected to find the cause of the failure. The final detection result is fed back by the data feedback module according to the specific judgment result, and an operator performs unqualified inspection or qualified report according to the data list feedback signal.

In one embodiment, the equipment function detection unit at least comprises a sand mixing unit, a printing head unit, a sand spreader unit, a liquid material station unit and a sand cleaning station unit;

specifically, the detection data of the sand mulling unit at least comprises weighing system calibration, mulling amount setting, setting mulling time, curing agent proportion setting, mulling uniformity detection, mulling sand temperature detection and mulling stirring rotation speed setting. It should be noted that the above-mentioned detection data belong to the key parameters of the sand mulling unit, and setting errors may affect the quality of printed products, even discard the products. According to the actual situation, the system can set the test in the standby state and the test in the running process according to the actual process requirements, and the test items in the standby state are automatically skipped during the test in the running process; the test items in the running process are automatically skipped when testing in the standby test state.

Specifically, the detection data of the print head unit at least includes a print head power supply test value, a print head board temperature test value, a print head communication test value, a print head nozzle ink jet waveform test value, a print head negative pressure test value, and a print head nozzle ejection rate test value. Among them, the result of the head ejection rate test is one of the important factors in determining whether a printed product is acceptable. The detection process adopts the data receiving module as a camera, the printing test paper is photographed and scanned by the camera, the data analysis module judges whether the ink jet of the nozzle meets the factory requirement or not by comparing the image scanned by the camera with the image file issued to the print head module, and the data feedback module correspondingly feeds back the detection result.

Specifically, the detection data of the sand spreader unit at least comprises a sand level sensor setting test value, a vibration frequency setting test value and a sand outlet gap setting test value; a sander speed setting test value and a print layer thickness setting test value. It should be noted that whether the function of the sand level sensor is calibrated to be qualified directly relates to whether the sand spreading device can add sand normally, and if the function is not set properly, the sand spreading device can be caused to have no sand or too much sand overflows. The two parameters of the vibration frequency and the sand outlet gap determine the sand discharge amount of the sand spreader, the sand discharge amount is too large, the sand spreader pulls sand, and the printing product density is unqualified due to too small sand discharge amount.

Specifically, the detection data of the liquid station unit at least comprises the liquid level of each liquid bucket, an upper limit alarm value and the flow rate of the resin flowmeter. Wherein, the liquid level detection display value of the liquid material barrel is compared with the actual measurement value to detect whether the analysis precision is in the set range; the upper limit alarm is mainly used for preventing liquid material from overflowing to trigger alarm, and meanwhile, whether the alarm is triggered is judged, and whether the sensor is allowed to be normal is correspondingly checked; the resin flowmeter detects the real-time resin flow, needs to detect the acquired flow value and the actual flow to judge whether the flowmeter measures accurately, and can also judge whether the liquid adding pump works normally according to the flow value of the flowmeter.

Specifically, the detection data of the sand cleaning station unit at least comprises parameters of each frequency converter, the operation condition of the sand cleaning station and the operation condition of each roller way detection sensor of the rotary box changing station. Namely, if the parameter settings are normal, the sensors detect normally, the roller bed rotation box changing and sand cleaning functions of the sand cleaning station are normal, and the module function test of the sand cleaning station is normal.

In one embodiment, the printed product detection unit includes a printed test block detection unit and a printed result product detection unit;

the printing test block detection unit comprises density detection, compression resistance detection, tensile detection and line detection; note that the block detection is printing when the device has a printing capability in the first place, and is also verification of the device printing function. After the 3D printer prints out the test block, test the equipment test block through using detecting instrument such as drawing and pressing tester, density tester, test data is preferably in the detection system that dispatches from the factory through the network transmission, also can be typeeed by the special messenger manually. And comparing the standard value with a standard value set in a 3D printing factory detection system, and judging whether the test block meets the standard test block requirement. And under the condition that the indexes of the test block detection meet all requirements, the equipment is allowed to print product detection.

The detection unit of the printing result product comprises length detection, width detection, height detection, inclined plane detection, curved surface detection and gas evolution detection. The product printed before leaving the factory is designed elaborately, covers various irregular surfaces such as a cylindrical surface, a spherical surface and an inclined surface, and can verify the precision and the performance of the printed product in all directions. And detecting the printed product by using a three-dimensional scanner or a measuring arm, comparing the detection value with the size of the three-dimensional model, if the error is within a set range, determining that the printed product is qualified, and if not, adjusting related compensation parameters to compensate until the printed product is qualified.

In one embodiment, the software detection system further includes a communication detection unit, and the communication detection unit determines whether the software detection system meets the factory detection standard according to communication detection data provided by the hardware detection system and by comparing standard data. It should be noted that if the network communication is abnormal, the network communication cannot be qualified to leave the factory, so as to prevent the equipment from being unstable due to occasional flash. Meanwhile, the grounding resistance of the equipment can be tested by using a grounding resistance tester, EMC data of the equipment is detected by using the EMC tester, the data is collected into an outgoing detection system by using a communication or database access mode, whether the outgoing is qualified or not is judged by comparing the outgoing data with national standard data, and part of the testers can directly give out qualified and unqualified testing results. Therefore, the detection efficiency is greatly improved, the waste of manpower and material resources is reduced, and the cost is saved by the aid of the network communication mode auxiliary detection method.

In one embodiment, the software detection system interfaces with the MES system through data sharing. Namely, the factory detection system directly calls data detected in the production and manufacturing process or the acquisition and purchase process by establishing a data sharing mechanism with the MES system, so that the waste of manpower and material resources can be reduced.

In one embodiment, the storage manner of the detection data of the software detection system includes at least one of database storage, cloud platform storage and print report storage. That is to say, the storage manner of the detected data of the factory detection system may be that the data is directly stored in the local database of the factory detection system of the 3D printer, or the detected data is transmitted to the cloud platform for storage, so that the detected data is stored in the cloud platform as the first-hand data material of the device through data storage, and becomes a data support for device failure judgment in the future. In addition, the detection data can also be directly printed into a detection report, and the delivery report is used as a basis for issuing delivery qualification certificates.

In one embodiment, a 3D printer includes the 3D printer factory inspection system according to any one of the above embodiments.

In one embodiment, a detection method using the 3D printer factory detection system described in any one of the above embodiments includes the following steps:

acquiring detection data according to a hardware detection system;

analyzing whether the detection data meet the delivery standards of all detection units of the software detection system;

and when all the detection units meet the delivery standard, feeding back delivery detection results by adopting a data reporting system.

In one embodiment, a computer-readable storage medium stores thereon a computer program, and when executed by a processor, the computer program implements the steps of the detection method of the 3D printer factory detection system according to any one of the embodiments.

According to the 3D printer delivery detection system, the printer, the detection method and the storage medium, data acquisition is performed through the hardware detection system, so that the detection efficiency is greatly improved, the waste of manpower and material resources is reduced, and the cost is saved; and transmitting the data to a software detection system for analysis and judgment, and reporting a final detection result through a reporting system when the parts detection unit, the equipment function detection unit and the printing product detection unit are comprehensively detected and analyzed to reach the factory standard. Therefore, the 3D printer factory detection is more standard and comprehensive through the 3D printer factory detection system, and the problems of factory omission or inaccurate detection caused by non-standard operation are reduced.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (14)

1. A3D printer delivery detection system is characterized by comprising a software detection system, a hardware detection system and a data reporting system;

the software detection system comprises a part detection unit, an equipment function detection unit and a printing product detection unit, wherein each detection unit comprises a data receiving module, a data analysis module and a data feedback module which are electrically connected;

the data receiving module is used for receiving detection data provided by the hardware detection system;

the data analysis module compares preset data with data of the data receiving module to judge whether the analysis meets the factory standards of the corresponding units;

the data feedback module feeds back a detection result according to the analysis result of the analysis module;

and the data reporting system reports the detection passing according to the delivery standard-reaching detection result of the feedback module of each detection unit.

2. The factory inspection system for 3D printers according to claim 1, wherein the hardware inspection system comprises at least an EMC detector, a ground resistance tester, a sensor tester, a laser interferometer, a tension and compression tester, a density tester, a three-dimensional scanner, a visual recognition device and a hardware watchdog.

3. The factory detection system for 3D printers according to claim 1, wherein the data detected by the component detection unit at least includes: the device comprises a spray head installation straightness, a printing head bottom plate flatness, a sand spreader sand scraping plate angle, a sand spreader sand scraping plate straightness, a work box lifting mechanism lifting precision, a work box bottom plate flatness and an X-axis guide rail straightness.

4. The factory detection system for the 3D printer according to claim 1, wherein the equipment function detection unit at least comprises a sand mulling unit, a printing head unit, a sand spreader unit, a liquid material station unit and a sand cleaning station unit;

the detection data of the sand mulling unit at least comprises weighing system calibration, setting of sand mulling amount, setting of sand mulling time, setting of curing agent proportion, detection of sand mulling uniformity, detection of sand mulling temperature and setting of sand mulling stirring rotating speed;

the detection data of the printing head unit at least comprises a printing head power supply test value, a printing head board card temperature test value, a printing head communication test value, a printing head nozzle ink jet waveform test value, a printing head negative pressure test value and a printing head nozzle ejection rate test value;

the detection data of the sand spreader unit at least comprises a sand level sensor setting test value, a vibration frequency setting test value and a sand outlet gap setting test value; a sander speed setting test value and a print layer thickness setting test value;

the detection data of the liquid station unit at least comprises the liquid level of each liquid bucket, an upper limit alarm value and the flow of the resin flowmeter;

and the detection data of the sand cleaning station unit at least comprises parameters of each frequency converter, the running condition of the sand cleaning station and the running condition of each roller way detection sensor of the rotary box changing station.

5. The factory detection system for 3D printers according to claim 1, wherein the printed product detection unit comprises a printed test block detection unit and a printed result product detection unit;

the printing test block detection unit comprises density detection, compression resistance detection, tensile detection and line detection;

the detection unit of the printing result product comprises length detection, width detection, height detection, inclined plane detection, curved surface detection and gas evolution detection.

6. The 3D printer factory detection system according to claim 1, wherein the software detection system further comprises a communication detection unit, and the communication detection unit determines whether the factory detection standard is met according to communication detection data provided by the hardware detection system and by comparing standard data.

7. The 3D factory detection system for printers as claimed in claim 1, wherein the software detection system is connected to the MES system through data sharing.

8. The factory inspection system for 3D printers according to claim 1, wherein the storage manner of the inspection data of the software inspection system includes at least one of database storage, cloud platform storage, and print report storage.

9. The 3D printer factory detection system according to claim 1, wherein the software detection system is provided in a 3D printer.

10. The factory detection system for 3D printers according to claim 1, wherein the data reporting system comprises a voice reporting module, and the voice reporting module performs voice reporting according to the factory standard detection result of each detection unit.

11. The 3D factory detection system for printers as claimed in claim 1, wherein the data reporting system comprises a validation module, and the validation module comprises a signature sub-module or a fingerprint sub-module.

12. A 3D printer, characterized by comprising the 3D printer factory inspection system according to any one of claims 1 to 11.

13. A detection method using the 3D printer factory detection system according to any one of claims 1 to 11, comprising the steps of:

acquiring detection data according to a hardware detection system;

analyzing whether the detection data meet the delivery standards of all detection units of the software detection system;

and when all the detection units meet the delivery standard, feeding back delivery detection results by adopting a data reporting system.

14. A computer-readable storage medium, wherein a computer program is stored on the computer-readable storage medium, and when executed by a processor, the computer program implements the detection method of the 3D printer factory detection system according to claim 13.