CN214200582U - Spectacle lens optical property measuring device - Google Patents

Abstract

The utility model discloses a spectacle lens optical property measuring device. The device can realize real-time online detection of the yellowing degree of the spectacle lens on the convection production line and carry out real-time screening work on unqualified products. The device adopts the detector to collect the broad spectrum at one time, thereby greatly shortening the detection time. The device adopts two modes of transmission and reflection to cooperate with the measurement of the yellowing degree of the spectacle lens, thereby increasing the reliability and the accuracy of the device. The light source of the device adopts the light evening device to homogenize light, and simultaneously adopts a pulse type illumination mode, thereby being beneficial to the improvement of the measurement accuracy. This device can realize that unqualified product is automatic to be screened out, has saved the manpower greatly, can in time send out the police dispatch newspaper if unqualified product is more in the production line simultaneously, warns this batch product qualification rate low, must in time check raw and other materials quality or optimize processing technology parameter.

Description

Spectacle lens optical property measuring device

Technical Field

The utility model relates to a lens detection area, concretely relates to spectacle lens optical property measuring device.

Background

China is known as the "kingdom of eyeglasses" throughout the world. According to the research report of the world health organization, the myopia population in China currently exceeds 6 hundred million, and accounts for nearly half of the population in China. The myopia rates of high school students and college students exceed 7, and the myopia rate of primary school students is close to 50%. China is one of the countries with the highest incidence rate of myopia in the world at present.

The quality of the lens directly affects the health of vision, so that the national quality supervision department lists metering equipment such as a lensmeter, a optometry lens, an optometry machine and the like as metering instruments for forced verification. The state also provides a series of national standard guidelines and regulations for the production and processing of eyeglasses.

Yellowness or yellowness index is an important parameter for the quality of ophthalmic lenses. The yellowness index refers to the yellowness of the lenses relative to the light source of the International Commission on illumination (CIE) standard C, using magnesium oxide as a reference. It is an important technical index for evaluating the quality and the aging degree of the plastic lens. The yellowing and transparency of the lens are related to the manufacturing process and are influenced by the use environment conditions, so that the manufacturing quality and the use performance can be inferred by testing the transparency and the yellowing of the lens. If the lens becomes yellow in color, its transparency is reduced and its handling properties are deteriorated, which can be explained by the aging mechanism of the polymer. Since the lens is inevitably exposed to air during its formation, storage and use, the aging is mainly oxidation, and heat and light accelerate the oxidation, so called thermo-oxidative aging. The photo-oxidative aging is mainly used in the outdoor atmosphere. The rate of oxidation depends on the molecular structure of the polymer, and as a result, molecular chains are broken or decomposed, changing the molecular structure of the polymer, thereby discoloring and embrittling the article, and reducing transparency, tensile strength, and the like. For example, PC lenses are easily oxidized and thermally decomposed during molding, and the aliphatic bonds are rapidly hydrolyzed, thereby reducing the molecular weight, deteriorating the mechanical properties and yellowing the color. PS lenses turn yellow under the action of sunlight, and the color depth is related to the content and the performance of impurities.

In addition, in recent years, resin lenses have been excellent in overall performance, but have also been highly yellowed due to complicated processing. The quantity of blue light prevention lenses in the current market is continuously increased, and the blue light prevention lenses are popular with consumers. However, the blue light-proof lens generally adopts a coating process to filter blue light, and the blue light with the wavelength of 465-455 nm is also over-reflected or absorbed while the blue light with the wavelength of 400-455nm is filtered, so that the display distortion of object color is caused, and the yellowing degree of the lens is increased.

The method has very important application value for measuring the yellowing factor of the spectacle lens because the factors influencing the yellowing factor of the optical resin lens are more and are an important technical index for judging the manufacturing quality and the use value of the lens.

However, the existing yellowing measurement field of spectacle lenses still has a plurality of defects:

(1) at present, most of the yellowing degree measurement is in the field of chemical materials, and only opaque materials and transparent flat materials can be measured. The spectacle lens has a certain concave-convex surface, so that a certain deflection effect is generated on the transmitted light and the reflected light. These devices are difficult to detect on clear ophthalmic lenses having a certain concave-convex surface.

(2) The traditional detection process needs steps such as light splitting and the like, the measurement time of a single sample is long, and the method cannot adapt to the production line operation mode of modern spectacle lenses.

(3) Due to the characteristics of the spectacle lens and the influence of the production environment, the influence of the stray light of the measurement background of the yellowing degree is particularly obvious, and the traditional detection cannot adapt to the real-time online detection application scene, so that the reliability and the accuracy are greatly reduced.

(4) The traditional detection method cannot screen unqualified products in real time, needs a large amount of manpower and material resources, wastes time and labor, and is not beneficial to the modern production process.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art, the utility model provides an eyeglass lens optical property measuring device. The device comprises five subsystems, namely a transmission type yellowing degree measuring system (T), a reflection type yellowing degree measuring system (F), a lens position detecting system (W), a control processing system (C) and a lens screening system (S). The device can realize real-time online detection of the yellowing degree of the spectacle lens on the convection production line and carry out real-time screening work on unqualified products. The device adopts the detector to collect the broad spectrum at one time, thereby greatly shortening the detection time. The device adopts two modes of transmission and reflection to cooperate with the measurement of the yellowing degree of the spectacle lens, thereby increasing the reliability and the accuracy of the device. The light source of the device adopts the light evening device to even light, so that the uniformity of the light source is better. Meanwhile, the pulse type illumination mode is adopted, so that the instability of signals generated by the jitter of the ambient light and the sample to be measured is effectively avoided, and the measurement accuracy is improved. This device can realize that unqualified product is automatic to be screened out, has saved the manpower greatly, can in time send out the police dispatch newspaper if unqualified product is more in the production line simultaneously, warns this batch product qualification rate low, must in time check raw and other materials quality or optimize processing technology parameter.

The technical solution of the utility model is as follows:

the device comprises five subsystems, namely a transmission type yellowing degree measuring system (T), a reflection type yellowing degree measuring system (F), a lens position detecting system (W), a control processing system (C) and a lens screening system (S).

The transmission-type yellowing degree measurement system (T) comprises: light emitted by the red LED array 1 and the blue LED array 2 is homogenized by the first homogenizer 3, enters the first collimating system 5 through the first lens 4, is spatially filtered by the first aperture diaphragm 6, and then is irradiated onto a spectacle lens 13 to be measured on the production line 12 through the first shutter 7. A slit is arranged in the middle of the production line 12 to ensure that light emitted by the red LED array 1 and the blue LED array 2 can reach the spectacle lens to be measured. After light transmitted from the spectacle lens 13 to be measured sequentially passes through the zoom lens B composed of the second lens 801, the third lens 802, the fourth lens 803 and the fifth lens 804, a red light part in a spectrum enters the first detector 807 through the transmission of the first optical filter 805, and is collected, and a blue light part in the spectrum enters the second detector 809 through the reflection of the first optical filter 805 and the third optical filter 808. The zoom lens B can realize a zoom function through the zoom controller 810, and can ensure that light transmitted through the to-be-measured spectacle lens 13 with different diopters can be collected by the detector. The red LED array 1, the blue LED array 2, the first shutter 7, the first detector 807, the second detector 809 and the zoom controller 810 are respectively connected with the control processing system (C).

The reflective yellowing measurement system (F) comprises N reflective yellowing measurement modules FMODLE which are same in structure and symmetrically distributed by taking the center of the spectacle lens 13 to be measured as the spherical center. And the detection direction of the reflective yellowness measurement module FMODULE and the optical axis direction of the spectacle lens 13 to be measured form 45 degrees +/-2 degrees or 85 degrees +/-2 degrees. The N reflection type yellowness measurement modules FMODULE are respectively connected with the control processing system (C).

The reflective yellowness measurement module FMODULE comprises: light emitted by the white light LED array F1 is homogenized by the second light homogenizer F2, enters the second collimation system F4 through the sixth lens F3, is spatially filtered by the second aperture diaphragm F5, and is incident on the spectacle lens to be tested 13 on the production line 12 through the second shutter F6. The red light part of the light reflected and scattered by the spectacle lens 13 to be measured is incident on the third detector F8 through the fourth filter F7, and the blue light part is incident on the fourth detector F10 through the fifth filter F9. The white light LED array F1, the third detector F8 and the fourth detector F10 are respectively connected with the control processing system (C).

The lens position detection system (W) comprises a signal generator 10 and a signal detector 11, and the signal generator 10 and the signal detector 11 are respectively connected with the control processing system (C).

The lens sorting system (S) includes a retractable robot arm and a storage box for temporarily storing the defective ophthalmic lens.

The distance range between the second lens 801 and the spectacle lens 13 to be measured is 2-10 cm.

The red LED array 1 may adopt 1 LED or an array of n × n (n is 1, 2, 3 … …) LEDs, and the central wavelength range of the LEDs is 650nm ± 50 nm.

The blue LED array 2 may adopt 1 LED or an array of n × n (n is 1, 2, 3 … …) LEDs, and the central wavelength range of the LEDs is 450nm ± 50 nm.

The first lens 4 is a positive lens, and the focal length range is 5cm to 50 cm.

The light-transmitting aperture of the first aperture diaphragm 6 is adjustable, and the adjustable range is 1 cm-7 cm.

The second lens 801 is a positive lens, the third lens 802 is a positive lens, the fourth lens 803 is a negative lens, and the fifth lens 804 is a positive lens.

The first optical filter 805 is a reflective high-pass filter, the cut-off wavelength is 550nm +/-50 nm, the transmittance of light with the wavelength of more than 600nm is greater than 95%, and the reflectance of light with the wavelength of less than 500nm is greater than 90%.

The second filter 806 is a band-pass filter, the light-transmitting range is 400nm to 500nm, and the average transmittance is greater than 90%.

The third optical filter 808 is a band-pass optical filter, the light-passing range is 600nm to 700nm, and the average transmittance is more than 90%.

The sixth lens F3 is a positive lens with a focal length ranging from 5cm to 50 cm.

The fourth optical filter F7 is a band-pass filter, the light-passing range is 600nm to 700nm, and the average transmittance is more than 90%.

The fifth optical filter F9 is a band-pass optical filter, the light-passing range is 400nm to 500nm, and the average transmittance is more than 90%.

When the spectacle lens to be measured is not placed, the signal sent by the signal generator 10 enters the signal detector 11 after passing through the production line 12.

The optical performance measuring device for the spectacle lens has the following working principle:

firstly, system initialization:

1. and the red LED array 1 and the blue LED array 2 and the white LED array F1 are lightened to ensure stable light emission.

2. When the spectacle lens 13 to be tested is not placed, the first shutter 7 is opened, the second shutter F6 is closed, light emitted by the red LED array 1 and the blue LED array 2 is collimated by uniform light and then is directly collected to the first detector 807 and the second detector 809 by the zoom lens B, and at the moment, the first detector 807 and the second detector 809 output signals power1 and power2 respectively.

3. A standard white board is placed in an area to be detected, a second shutter F6 is opened, a first shutter 7 is closed, light emitted by a white light LED array F1 is collimated through uniform light and then reflected and scattered by the standard white board, and a part of light is transmitted to a third detector F8 and a fourth detector F10 through a fourth optical filter F7 and a fifth optical filter F9 respectively. The third detector F8 and the fourth detector F10 output signals power3 and power4, respectively.

4. The spectacle lens 13 to be measured is placed in an area to be measured, light emitted by the red LED array 1 and the blue LED array 2 passes through the spectacle lens 13 to be measured after being collimated by even light, and the spectacle lens 13 to be measured has certain diopter, so that the originally collimated light can generate a dispersing effect. The zoom lens B is continuously zoomed by the zoom controller 810, and the position where the output value of the first probe 807 is maximum is found within the entire zoom range. When the zoom lens B is at the position, the divergent light can be effectively collected to the first detector 807 and the second detector 809, and the zoom lens B keeps the position fixed in the batch detection.

Transmission yellowing measurement

1. In the production process of the spectacle lens, the spectacle lens 13 to be measured advances on the production line 12, when the front edge of the spectacle lens 13 to be measured moves between the signal generator 10 and the signal detector 11, the signal detector 11 cannot detect the signal sent by the signal generator 10 due to the shielding of the spectacle lens 13 to be measured, and at the moment, the signal detector 11 outputs a low-level signal to indicate that the spectacle lens to be measured has moved to a proper position, and the device is triggered to measure.

2. After receiving the low level signal sent by the signal detector 11, the control processing system (C) opens the first shutter 7, so that the light sent by the red LED array 1 and the blue LED array 2 passes through the spectacle lens 13 to be detected after being collimated by uniform light, and is further effectively collected to the first detector 807 and the second detector 809 by the zoom lens B. The first detector 807 and the second detector 809 output signals power5 and power6, respectively.

Third, data processing

And (3) calculating the yellowing degree of the lens according to the formula of 1- (power6/power2)/(power5/power1), comparing the yellowing degree with a set threshold value, and if the yellowing degree is less than the threshold value, indicating that the quality of the spectacle lens is qualified. This measurement is ended. If the value is larger than the threshold value, the quality of the lens is possibly unqualified, and the reflective yellowing degree measurement process is started.

Four, reflection type yellowing measurement

And after the control processing system (C) judges that the transmission type yellowing degree is unqualified, the second shutter F6 is opened, at the moment, light emitted by the white light LED array F1 is collimated by uniform light and then is irradiated onto the lens 13 to be detected, and after the light is reflected and scattered by the lens 13 to be detected, a part of the light is irradiated onto the third detector F8 and the fourth detector F10 through the fourth optical filter F7 and the fifth optical filter F9 respectively. At the same time, the first shutter 7 is closed, and the light from the red LED array 1 and the blue LED array 2 cannot strike the spectacle lens 13 to be measured. It is ensured that the light received at the third detector F8 and the fourth detector F10 is both reflected and scattered light and no transmitted light. The third detector F8 and the fourth detector F10 output signals power7(1) and power8(1), respectively.

If the reflective yellowing measurement system (F) comprises N reflective yellowing measurement modules FMODULE. Then a series of detector output signals power7(2), power8(2), power7(3), power8 (3) … … power7(N), and power8(N) can be obtained simultaneously.

By the formula Y_{Inverse direction}N reflection yellowness Y can be obtained by 1-power8(N)/power7(N)_{Inverse direction}(N) N reflection yellowness Y is needed for N reflection yellowness factors which may cause strong stray signals received by partial detectors due to mirror reflection_{Inverse direction}(N) statistical analysis was performed. And eliminating obvious deviation from the average value. For residual reflection yellowing degree Y_{Inverse direction}(N) averaging to obtain Y_{Inverse equilibrium}. If Y is_{Inverse equilibrium}If the value is less than (1-power4/power3), the quality of the lens is qualified, and the measurement is finished. If Y is_{Inverse equilibrium}If the value is greater than (1-power4/power3), the quality of the lens is not qualified, and a screening procedure is started.

Fifthly, screening out procedure

After the quality of the lenses is determined to be unqualified through the measurement of the transmission type and the reflection type, the control processing system (C) starts a screening program, sends an instruction to the mechanical arm, the mechanical arm pops up automatically, the unqualified lenses are pushed down from the production line 12, and the lenses fall into a storage box beside the production line. If the number of unqualified spectacle lenses exceeds a certain threshold value, the system automatically gives an alarm to warn that the product of the batch has low qualification rate, and the quality of raw materials needs to be checked in time or the processing technological parameters need to be optimized.

The above steps are completely automatically processed under the control of the control processing system (C), and unqualified spectacle lenses can be quickly and effectively screened out.

The utility model has the advantages that:

1. the utility model discloses can realize carrying out real-time on-line measuring to the degree of yellowing of the lens on the flowing water production line to carry out real-time screening work to unqualified product.

2. The utility model discloses a detector is once only wide spectrum to be collected, has shortened check-out time greatly.

3. The utility model discloses a degree of yellowing of lens is measured in the cooperation of transmission-type and reflective dual mode, has increased the reliability and the accuracy of device.

4. The utility model discloses an illuminating source adopts dodging ware to carry out dodging, makes illuminating source's homogeneity better. Meanwhile, the pulse type illumination mode is adopted, so that the instability of signals generated by the jitter of the ambient light and the sample to be measured is effectively avoided, and the measurement accuracy is improved.

5. The yellowing degree calculation adopts a wide spectrum (400-500 nm and 600-700 nm) integration mode, and the data is more accurate.

6. The utility model discloses can realize that unqualified product is automatic to be sieved and remove, save the manpower greatly, if can in time send out the police dispatch newspaper in the production line when unqualified product is more simultaneously, warn this batch product qualification rate low, must in time check raw and other materials quality or optimize processing technology parameter.

Drawings

FIG. 1 is a schematic view of an apparatus for measuring optical properties of an eyeglass lens

FIG. 2 is a schematic view of a FMODULE structure of a reflection-type yellowness measurement module

FIG. 3 is a schematic diagram of FMODULE spatial distribution of a reflection-type yellowness measurement module

FIG. 4 is a schematic view of the working state of an apparatus for measuring the optical properties of spectacle lenses

Detailed Description

In order to make the objects, features and advantages of the present invention more obvious and understandable, the drawings in the embodiments of the present invention are combined below to clearly and completely describe the technical solutions in the embodiments of the present invention, and obviously, the embodiments described below are only some embodiments of the present invention, but not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

Fig. 1 is a schematic structural diagram of an embodiment of the present invention for realizing an optical performance measuring device for eyeglasses. The device comprises five subsystems, namely a transmission type yellowing degree measuring system (T), a reflection type yellowing degree measuring system (F), a lens position detecting system (W), a control processing system (C) and a lens screening system (S).

The transmission-type yellowing degree measurement system (T) comprises: light emitted by the red LED array 1 and the blue LED array 2 is homogenized by the first homogenizer 3, enters the first collimating system 5 through the first lens 4, is spatially filtered by the first aperture diaphragm 6, and then is irradiated onto a spectacle lens 13 to be measured on the production line 12 through the first shutter 7. A slit is arranged in the middle of the production line 12 to ensure that light emitted by the red LED array 1 and the blue LED array 2 can reach the spectacle lens to be measured. After light transmitted from the spectacle lens 13 to be measured sequentially passes through the zoom lens B composed of the second lens 801, the third lens 802, the fourth lens 803 and the fifth lens 804, a red light part in a spectrum enters the first detector 807 through the transmission of the first optical filter 805, and is collected, and a blue light part in the spectrum enters the second detector 809 through the reflection of the first optical filter 805 and the third optical filter 808. The zoom lens B can realize a zoom function through the zoom controller 810, and can ensure that all light transmitted from the spectacle lens 13 to be measured with different diopters is collected by the detector. The red LED array 1, the blue LED array 2, the first shutter 7, the first detector 807, the second detector 809 and the zoom controller 810 are respectively connected with the control processing system (C).

As shown in fig. 2, fig. 2 is a schematic structural diagram of a reflective yellowness measurement module FMODULE. The reflective yellowness measurement module FMODULE comprises: light emitted by the white light LED array F1 is homogenized by the second light homogenizer F2, enters the second collimation system F4 through the sixth lens F3, is spatially filtered by the second aperture diaphragm F5, and is incident on the spectacle lens to be tested 13 on the production line 12 through the second shutter F6. The red light part of the light reflected and scattered by the spectacle lens 13 to be measured is incident on the third detector F8 through the fourth filter F7, and the blue light part is incident on the fourth detector F10 through the fifth filter F9. The white light LED array F1, the third detector F8 and the fourth detector F10 are respectively connected with the control processing system (C).

The lens position detection system (W) comprises a signal generator 10 and a signal detector 11, and the signal generator 10 and the signal detector 11 are respectively connected with the control processing system (C).

The lens sorting system (S) includes a retractable robot arm and a storage box for temporarily storing the defective ophthalmic lens.

The distance range between the second lens 801 and the spectacle lens 13 to be measured is 2-10 cm.

The red LED array 1 may adopt 1 LED or an array of n × n (n is 1, 2, 3 … …) LEDs, and the central wavelength range of the LEDs is 650nm ± 50 nm.

The blue LED array 2 may adopt 1 LED or an array of n × n (n is 1, 2, 3 … …) LEDs, and the central wavelength range of the LEDs is 450nm ± 50 nm.

The first light uniformizing device and the second light uniformizing device adopt 1mm double-sided frosted PC light uniformizing sheets

The first lens 4 is a positive lens, and the focal length range is 5cm to 50 cm.

The light-transmitting aperture of the first aperture diaphragm 6 is adjustable, and the adjustable range is 1 cm-7 cm.

The second lens 801 is a positive lens, the third lens 802 is a positive lens, the fourth lens 803 is a negative lens, and the fifth lens 804 is a positive lens.

The first optical filter 805 is a reflective high-pass filter, the cut-off wavelength is 550nm +/-50 nm, the transmittance of light with the wavelength of more than 600nm is greater than 95%, and the reflectance of light with the wavelength of less than 500nm is greater than 90%.

The second filter 806 is a band-pass filter, the light-transmitting range is 400nm to 500nm, and the average transmittance is greater than 90%.

The third optical filter 808 is a band-pass optical filter, the light-passing range is 600nm to 700nm, and the average transmittance is more than 90%.

The reflective yellowing measurement system (F) includes N (N is 2, 4, 6 …) reflective yellowing measurement modules FMODULE having the same structure and symmetrically distributed by taking the center of the spectacle lens 13 to be measured as the spherical center. In the schematic diagram of the embodiment shown in fig. 1, N is 4, that is, 901, 902, 903, and 904 are 4 reflective yellowness measurement modules fmodulle having the same structure but different positions. And the detection direction of the reflective yellowness measurement module FMODULE and the optical axis direction of the spectacle lens 13 to be measured form 45 degrees +/-2 degrees or 85 degrees +/-2 degrees. The N reflection type yellowness measurement modules FMODULE are respectively connected with the control processing system (C). To express the spatial distribution of the reflective yellowness measurement module FMODULE more intuitively, fig. 3 may be referred to, where fig. 3 is a schematic diagram of the spatial distribution of the reflective yellowness measurement module FMODULE when N takes a value of 8.

The sixth lens F3 is a positive lens with a focal length ranging from 5cm to 50 cm.

The fourth optical filter F7 is a band-pass filter, the light-passing range is 600nm to 700nm, and the average transmittance is more than 90%.

The fifth optical filter F9 is a band-pass optical filter, the light-passing range is 400nm to 500nm, and the average transmittance is more than 90%.

When the spectacle lens to be measured is not placed, the signal sent by the signal generator 10 enters the signal detector 11 after passing through the production line 12.

The working principle and the process of the spectacle lens optical performance measuring device comprise the following steps:

firstly, system initialization:

1. and the red LED array 1 and the blue LED array 2 and the white LED array F1 are lightened to ensure stable light emission.

2. When the spectacle lens 13 to be tested is not placed, the first shutter 7 is opened, the second shutter F6 is closed, light emitted by the red LED array 1 and the blue LED array 2 is collimated by uniform light and then is directly collected to the first detector 807 and the second detector 809 by the zoom lens B, and at the moment, the first detector 807 and the second detector 809 output signals power1 and power2 respectively.

3. A standard white board is placed in an area to be detected, a second shutter F6 is opened, a first shutter 7 is closed, light emitted by a white light LED array F1 is collimated through uniform light and then reflected and scattered by the standard white board, and a part of light is transmitted to a third detector F8 and a fourth detector F10 through a fourth optical filter F7 and a fifth optical filter F9 respectively. The third detector F8 and the fourth detector F10 output signals power3 and power4, respectively.

4. The spectacle lens 13 to be measured is placed in an area to be measured, light emitted by the red LED array 1 and the blue LED array 2 passes through the spectacle lens 13 to be measured after being collimated by even light, and the spectacle lens 13 to be measured has certain diopter, so that the originally collimated light can generate a dispersing effect. The zoom lens B is continuously zoomed by the zoom controller 810, and the position where the output value of the first probe 807 is maximum is found within the entire zoom range. When the zoom lens B is at the position, the divergent light can be effectively collected to the first detector 807 and the second detector 809, and the zoom lens B keeps the position fixed in the batch detection.

Transmission yellowing measurement

1. In the production process of the spectacle lens, the spectacle lens 13 to be measured advances on the production line 12, when the front edge of the spectacle lens 13 to be measured moves between the signal generator 10 and the signal detector 11, the signal detector 11 cannot detect the signal sent by the signal generator 10 due to the shielding of the spectacle lens 13 to be measured, and at the moment, the signal detector 11 outputs a low-level signal to indicate that the spectacle lens to be measured has moved to a proper position, and the device is triggered to measure.

2. After receiving the low level signal sent by the signal detector 11, the control processing system (C) opens the first shutter 7, so that the light sent by the red LED array 1 and the blue LED array 2 passes through the spectacle lens 13 to be detected after being collimated by uniform light, and is further effectively collected to the first detector 807 and the second detector 809 by the zoom lens B. The first detector 807 and the second detector 809 output signals power5 and power6, respectively.

Third, data processing

And (3) calculating the yellowing degree of the lens according to the formula of 1- (power6/power2)/(power5/power1), comparing the yellowing degree with a set threshold value, and if the yellowing degree is less than the threshold value, indicating that the quality of the spectacle lens is qualified. This measurement is ended. If the value is larger than the threshold value, the quality of the lens is possibly unqualified, and the reflective yellowing degree measurement process is started.

Four, reflection type yellowing measurement

And after the control processing system (C) judges that the transmission type yellowing degree is unqualified, the second shutter F6 is opened, at the moment, light emitted by the white light LED array F1 is collimated by uniform light and then is irradiated onto the lens 13 to be detected, and after the light is reflected and scattered by the lens 13 to be detected, a part of the light is irradiated onto the third detector F8 and the fourth detector F10 through the fourth optical filter F7 and the fifth optical filter F9 respectively. At the same time, the first shutter 7 is closed, and the light from the red LED array 1 and the blue LED array 2 cannot strike the spectacle lens 13 to be measured. It is ensured that the light received at the third detector F8 and the fourth detector F10 is both reflected and scattered light and no transmitted light. The third detector F8 and the fourth detector F10 output signals power7(1) and power8(1), respectively.

If the reflective yellowing measurement system (F) comprises N reflective yellowing measurement modules FMODULE. Then a series of detector output signals power7(2), power8(2), power7(3), power8 (3) … … power7(N), and power8(N) can be obtained simultaneously.

By the formula Y_{Inverse direction}N reflection yellowness Y can be obtained by 1-power8(N)/power7(N)_{Inverse direction}(N) N reflection yellowness Y is needed for N reflection yellowness factors which may cause strong stray signals received by partial detectors due to mirror reflection_{Inverse direction}(N) statistical analysis was performed. And eliminating obvious deviation from the average value. For residual reflection yellowing degree Y_{Inverse direction}(N) averaging to obtain Y_{Inverse equilibrium}. If Y is_{Inverse equilibrium}If the value is less than (1-power4/power3), the quality of the lens is qualified, and the measurement is finished. If Y is_{Inverse equilibrium}If the value is greater than (1-power4/power3), the quality of the lens is not qualified, and a screening procedure is started.

Fifthly, screening out procedure

After the quality of the lenses is determined to be unqualified through two-wheel measurement of a transmission type and a reflection type, the control processing system (C) starts a screening program, sends an instruction to the mechanical arm, the mechanical arm pops up automatically, the unqualified lenses are pushed down from the production line 12, and the lenses fall into a storage box beside the production line, as shown in figure 4. If the number of unqualified spectacle lenses exceeds a certain threshold value, the system automatically gives an alarm to warn that the product of the batch has low qualification rate, and the quality of raw materials needs to be checked in time or the processing technological parameters need to be optimized.

The above steps are completely automatically processed under the control of the control processing system (C), and unqualified spectacle lenses can be quickly and effectively screened out.

The above list of details is only for the concrete description of the feasible embodiments of the present invention, they are not used to limit the protection scope of the present invention, and all the equivalent ways or modifications not departing from the present invention should be included in the protection scope of the present invention.

Claims (7)

1. The device for measuring the optical performance of the spectacle lens is characterized by comprising five subsystems, namely a transmission type yellowing degree measuring system (T), a reflection type yellowing degree measuring system (F), a lens position detecting system (W), a control processing system (C) and a lens screening system (S);

the transmission-type yellowing degree measurement system (T) comprises: the system comprises a red LED array (1) and a blue LED array (2), wherein light emitted by the red LED array and the blue LED array enters a first collimation system (5) through a first lens (4) after being homogenized by a first homogenizer (3), and is filtered by a first pinhole diaphragm (6) in space and then is made to strike a spectacle lens (13) to be tested on a production line (12) through a first shutter (7); a slit is arranged in the middle of the production line (12) to ensure that light emitted by the red LED array (1) and the blue LED array (2) can reach the spectacle lens to be tested; after light transmitted by the spectacle lens (13) to be tested sequentially passes through a zoom lens B consisting of a second lens (801), a third lens (802), a fourth lens (803) and a fifth lens (804), a red light part in a spectrum enters a first detector (807) through the transmission of a first optical filter (805) and is collected, and a blue light part in the spectrum enters a second detector (809) through the reflection of the first optical filter (805) and the third optical filter (808) and is collected; the zoom lens B realizes a zooming function through a zooming controller (810), so that light transmitted by the spectacle lens (13) to be detected with different diopters can be collected by the detector; the red LED array (1), the blue LED array (2), the first shutter (7), the first detector (807), the second detector (809) and the zoom controller (810) are respectively connected with the control processing system (C);

the reflective yellowing measurement system (F) comprises N reflective yellowing measurement modules FMODULE which are same in structure and symmetrically distributed by taking the center of the spectacle lens (13) to be measured as the spherical center; the detection direction of the reflective yellowness measurement module FMODULE and the optical axis direction of the spectacle lens (13) to be measured form an angle of 45 degrees +/-2 degrees or an angle of 85 degrees +/-2 degrees;

the reflective yellowness measurement module FMODULE comprises: the white light LED array (F1), the light emitted by the white light LED array enters a second collimation system (F4) through a sixth lens (F3) after being homogenized by a second light homogenizer (F2), the light is subjected to spatial filtering by a second pinhole diaphragm (F5), the light is incident on a spectacle lens (13) to be detected on a production line (12) through a second shutter (F6), the red light part in the light reflected and scattered by the spectacle lens (13) to be detected is incident on a third detector (F8) through a fourth optical filter (F7), and the blue light part is incident on a fourth detector (F10) through a fifth optical filter (F9); the white light LED array (F1), the third detector (F8) and the fourth detector (F10) are respectively connected with the control processing system (C);

the lens position detection system (W) comprises a signal generator (10) and a signal detector (11), and the signal generator (10) and the signal detector (11) are respectively connected with the control processing system (C); when the spectacle lens to be measured is not placed, the signal sent by the signal generator (10) enters the signal detector (11) after passing through the production line (12).

2. An ophthalmic lens optical performance measuring device according to claim 1, characterized in that the distance of the second lens element (801) from the ophthalmic lens (13) to be measured is in the range of 2-10 cm.

3. The device for measuring the optical performance of the eyeglasses according to claim 1, wherein the red LED array (1) is 1 LED or an array of n x n LEDs, wherein n is 1, 2, 3 … …, and the central wavelength range of the LEDs is 650nm ± 50 nm.

4. The device for measuring the optical performance of the eyeglasses according to claim 1, wherein the blue LED array (2) is 1 LED or an array of n × n LEDs, n is 1, 2, 3 … …, and the central wavelength range of the LEDs is 450nm ± 50 nm.

5. An ophthalmic lens optical performance measuring device according to claim 1, characterized in that said first lens (4) is a positive lens with a focal length in the range of 5cm to 50 cm;

the light-transmitting aperture of the first aperture diaphragm (6) is adjustable, and the adjustable range is 1 cm-7 cm.

6. An ophthalmic lens optical performance measuring device according to claim 1, characterized in that said sixth lens (F3) is a positive lens with a focal length ranging from 5cm to 50 cm;

the fourth optical filter (F7) is a band-pass optical filter, the light-passing range is 600nm to 700nm, and the average transmittance is more than 90%;

the fifth filter (F9) is a band-pass filter, the light-passing range is 400nm to 500nm, and the average transmittance is more than 90%.

7. An eyeglass optical performance measurement device as set forth in claim 1, characterized in that it further comprises a lens screening system (S) comprising a retractable robot arm and a storage bin for storing rejected eyeglass lenses, the retractable robot arm being capable of pushing rejected eyeglass lenses into the storage bin.

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