Specifically speaking, to make packaging machinery have good automation and flexibility, and to increase the degree of automation, it is necessary to adopt microcomputer technology, functional module technology, and monitor the work of multiple robots at the same time, so that the requirements for product changes can be simply transferred to the program. .
In the industrialization process of the packaging industry, manufacturing technology has been scaled up and diversified. Diversification and even individualized demands have further aggravated market competition. In order to reduce production costs, packaging companies have considered building a flexible production line to complete the flexible manufacturing of enterprises. Efficient servo control system provides support. In the development of packaging production lines, control plays an increasingly important role with integrated products/technology.
In order to complete the flexible production, it is required that the equipments in each process section in the packaging production line be closely coupled with each other, and the packaging production line is required to interact with other production lines. Because different controllers control different process sections or production lines respectively, this brings about problems of coordination between different controllers. Therefore, the International Packaging Association User Organization (OMAC/PACML) has expressed the structuring and standardized machine state management functions of the object package. Accordingly, a control system integrating this function can ensure that the user completes the entire line in less time and cost. Or even the whole plant production coordination.
With the continuous development and progress of science and technology, the future microelectronics, computers, industrial robots, image sensing technology and new materials will be more and more widely used in packaging machinery, and companies need to learn and introduce new technologies. It is advancing towards packaging equipment with high production efficiency, high degree of automation, good reliability, flexibility, and high technological content. Create a new type of packaging machinery, lead the packaging machinery to the direction of integration, high efficiency, and intelligent development.
375nm to 940nm Multimode wavelength LED are designed for microscopy and other applications that require multiple color channels.The LED current of each channel can be adjusted independently or modulated via an external voltage.The multi-wavelength LED system offer a compact housing with a backlit, easy-to-read LCD display. They are operated via the buttons on the front panel.
Features |
â– UV, Visible, and NIR Versions (from 375nm to 1550nm) â– The SMA connector is ideal for multimode fiber. â– Multi-wavelength fiber coupled LED available. |
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Data Sheet for Single Wavelength LED |
Model | Color |
Nominal Wavelength (nm) |
Bandwidth FWHM (nm) | Typical Φ600um Core Fiber Output Power SMA (mW) | Maximum Current CW (mA) | Forward Voltage (V) | Typical Lifetime (h) |
LFM375 |
UV |
375 | 9 | 3.0 | 1400 | 3.6 | ~10000 |
LFM395 | UV | 395 | 16 | 1.0 | 500 | 4.5 | ~10000 |
LFM405 | UV | 405 | 12 | 4.2 | 1400 | 3.45 | ~10000 |
LFM430 | Violet | 430 | 15 | 1.0 | 500 | 3.8 | ~10000 |
LFM460 | Royal Blue | 460 | 25 | 6.0 | 1000 | 3.6 | ~10000 |
LFM470 | Blue | 470 | 25 | 3.2 | 1000 | 3.2 | ~10000 |
LFM500 | Cyan | 500 | 30 | 2.2 | 1000 | 3.3 | ~10000 |
LFM530 | Green | 530 | 33 | 3.0 | 1000 | 3.2 | ~10000 |
LFM565 | Lime | 565 | 104 | 3.0 | 1000 | 3.1 | ~10000 |
LFM600 | Amber | 600 | 15 | 1.2 | 1000 | 2.6 | ~10000 |
LFM620 | Red | 620 | 18 | 5.5 | 1000 | 2.2 | ~10000 |
LFM625 | Red | 625 | 17 | 3.0 | 1000 | 2.2 | ~10000 |
LFM660 | Deep Red | 660 | 20 | 4.0 | 1200 | 2.6 | ~10000 |
LFM730 | Far Red | 730 | 37 | 1.5 | 1000 | 2.3 | ~10000 |
LFM808 | IR | 808 | 25 | 2.5 | 500 | 3.6 | ~10000 |
LFM850 | IR | 850 | 30 | 3.0 | 1500 | 3.85 | ~10000 |
LFM880 | IR | 880 | 50 | 1.0 | 1000 | 1.7 | ~10000 |
LFM940 | IR | 940 | 37 | 3.0 | 1000 | 2.75 | ~10000 |
LFM1050 | IR | 1050 | 37 | 2.0 | 600 | 1.4 | ~10000 |
LFM1550 | IR | 1550 | 102 | 1.0 | 700 | 1.1 | ~10000 |
Note:
1. The above testing data are only for reference, the actual spectrum of LED may change since the temperature or other parameters are different when operating the current.
2.The above data was tested by 600μm core diameter, 0.22 NA multimode fibers. Other core diameter fibers are available on request.
Laser Head | Power Supply |
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64 (L) ×46.5 (W) ×30 (H) mm3 |
114 (L) ×78 (W) ×71 (H) mm3 |
Data Sheet for Multi-wavelength LED |
Parameters | Indicators |
Available wavelength (nm) | 375-940 |
Output mode | Fiber output |
Fiber core diameter (μm) | 400, 600, 800, 1000 |
Fiber connector | SMA905 |
Output power (mW) | Related to fiber |
Power stability (rms, over 4 hours) | <3%, <5% |
Operating mode | CW, TTL or Analog on request |
Operating temperature (°C) | 10~35 |
Dimensions |
192(L)*241(w)*139.9(H)mm3 |
Input power |
12VDC 7A |
Cooling method |
By air |
Storage temperature (°C) |
-20~80 |
Lifetime (hours) |
10000 |
Fiber Specs |
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Fiber Coupled Led,Fiber Coupled Blue Led,Fiber Coupled Led 1550,Single Mode Fiber Coupled Led
Changchun New Industries Optoelectronics Technology Co., Ltd. , https://www.lasersciences.com