Abstract:
An optical paper sorter that uses diffuse reflectance to identify a sheet of paper as either white or non-white. An illuminating fiber optic bundle carries light from a tungsten halogen lamp onto a sheet of paper. A receiving trifurcated fiber optic bundle collects light that is diffusely reflected from the sheet of paper. The light in each branch of the receiving fiber bundle is incident upon a detector after passing through a color filter positioned between the end of the fiber bundle and the detector. At each detector a specific isolated color (blue, green or red) in the visible range of the electromagnetic spectrum is incident, causing a photo electric voltage to be produced that is proportional to the intensity of the isolated component. A processor uses the mean and standard deviation of relative reflectances that are obtained based on the three voltage signals to determine if the paper is predominantly white or non-white. An air ejection device can be triggered to release a blast of air upon identifying the paper as white, or alternatively, non-white.

Description:
BACKGROUND OF THE INVENTION 
     The present invention relates to an optical paper sorter, and in particular to a device and method for determining if a piece of paper is white or non-white. 
     In the paper recycling business, different grades of paper typically have different values, and thus there is a need to sort incoming recyclable paper products into various grades. Generally, the value of white paper exceeds the value of paper that is not white, and accordingly it is common to separate white recyclable paper from non-white recyclable paper. In the past, such sorting has been done manually, which tends to be expensive and has a varying degree of accuracy. 
     In other industries, the use of diffuse reflectance analysis has been applied to assist in sorting various types of work pieces, based on colour. For example, U.S. Pat. No. 4,278,538 issued Jul. 14, 1981 to Lawrence et al discloses a sorting system for sorting telephone caps of uniform colour in which diffuse reflection from the caps is analyzed to determine the colour of the telephone caps. However, despite the use of diffuse reflectance analysis in other industries, it has not been adopted in the paper sorting industry. A unique problem faced in determining if a sheet of paper is white or non-white is that recyclable material, by its nature, generally includes printed or graphic information on its surface. Accordingly, in order to successfully distinguish between non-white and white paper products, an automated sorting system must be able to, with reasonable accuracy, distinguish white paper having printed and graphics material on its surface from non-white paper (which may also include white elements). 
     Accordingly, it is desirable to provide a device and method for determining the dominant colour of a piece of paper, and more particularly for determining whether a piece of paper can be categorized as white or non-white. It is also desirable to provide a device for redirecting pieces of paper depending on if they are white or non-white. 
     SUMMARY OF THE INVENTION 
     The present invention provides an optical sorter that measures the diffuse reflectance of an incident light beam on a piece of paper or other workpiece, and processes the measured values to catagorize the piece of paper or other workpiece as falling within one of two possible colour classifications. 
     According to one aspect of the invention, there is provided a device for determining the dominant colour of a workpiece. The device includes a light source for directing a beam of light at the workpiece to illuminate the workpiece, and an optical detection system for receiving light diffusely reflected off the workpiece, isolating three different spectral components of the reflected light, measuring the intensity of each of the three different spectral components and generating electrical signals representative of the intensity of each of the three different spectral components. A processor responsive to the electrical signals generated by the detection system is operable to determine a relative reflectance for each of the three spectral components, determine a mean of the three relative reflectances, determine a standard deviation of the three relative reflectances, and determine, by comparing the mean and standard deviation to predetermined threshold values, a probable dominant colour of the workpiece. Preferably, the optical detection system includes three photo detectors for receiving light diffusely reflected off the workpieces, and filters positioned between the photo detectors and the workpiece for isolating the reflected light into the three different spectral components such that each of the three photo detectors receives a different one of the spectral components and generates an electrical output representative of the intensity thereof. 
     Preferably , the processor is configured to determine the relative reflectance for each of the three spectral components by comparing the intensity of each of the three spectral components to predetermined reference intensity values obtained in respect of a reference workpiece of a known colour classification, and the processor is configured to determine the probable colour of the workpiece by classifying the workpiece as falling into one of two possible colour classifications, one of which is the known colour classification. 
     According to a further aspect of the invention, there is provided a paper sorting device for determining if the dominant color classification of a piece of paper is white or non-white, comprising a light source for directing a beam of light at the paper to illuminate it, and an optical detection system for receiving light diffusely reflected off the paper, isolating three different spectral components of the reflected light, measuring the intensity of each of the three different spectral components and generating electrical signals representative of the intensity of each of the three different spectral components. A processor responsive to the electrical signals generated by the detection system is operable to determine a relative reflectance for each of the three spectral components, determine a mean of the three relative reflectances, determine a standard deviation of the three relative reflectances, and determine, by comparing the mean and standard deviation to predetermined threshold values, whether the paper is white or non-white. Preferably, the wavelength ranges of the three spectral components are generally 400 nm-525 nm, 475 nm-650 nm, and 600 nm-800 nm, respectively. Conveniently, the device may include a conveyor system for advancing pieces of paper to and through a sampling station at which the light source is located, and an ejection device connected to said processor and being operable to selectively redirect a paper sample from the conveyor system, the processor being configured to cause the ejection device to redirect the paper sample from the conveyor system based on the determination of whether the paper sample is white or non-white. 
     According to still a further aspect of the invention, there is provided a method for classifying paper samples into one of two colour classifications, comprising the steps of directing a beam of visible light on the paper sample to illuminate a paper sample, measuring the intensity of three different spectral components in the light which is diffusely reflected off the paper sample, determining, based on the measured intensities, a relative reflectance for each of the three spectral components, determining a mean of the three relative reflectances, determining a standard deviation of the three relative reflectances, and comparing the mean and the standard deviation to predetermined values and classifying the paper sample as falling within one of two possible colour classifications based on the comparison results. Preferably, the two colour classifications are white and non-white and the first spectral component corresponds to the colour blue, the second spectral component corresponds to the colour green, and the third spectral component corresponds to the colour red. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     In the drawings: 
     FIG. 1 is a graph showing the absolute reflectance of a perfect diffuser; 
     FIG. 2 is a graph showing the spectral reflectance curves for selected colours; 
     FIG. 3 is a diagram of a device for determining the colour of a workpiece, in accordance with the present invention; and 
     FIG. 4 is a simplified side view of the device of FIG. 3 located in a paper sorting system. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     When a light beam strikes the surface of a piece of paper, both specular and diffuse reflections occur. For specular reflectance, the angle of incidence equals the angle of reflection, and the spectral distribution of the incident light energy is preserved. Specular reflectance determines the mirror like properties of a surface and is a measure of the surface gloss or shine. Some of the light beam that strikes the surface of the paper penetrates the first layer of the fibrous structure of the paper and experiences absorption and multiple internal reflection. The absorption of some, or all of the wave lengths in the light beam takes place as a result of absorbing elements or pigments contained within the paper. The wave lengths that are not absorbed experience scattering and multiple reflections and are finally re-emitted from the surface as diffuse reflection. This diffuse reflection is what is responsible for the colour, or colours, seen by the human eye. Diffuse reflectance is emitted in all directions and is not dependant on the direction of the incident light beam. 
     Objects that are white in colour appear white when viewed under normal light because almost all the light that is incident gets diffusely reflected from the surface of the object. The perception of the colour of the object as “white” is equivalent to preserving the integrity of the incident light. A “perfect diffuser” is one that will diffusely reflect all the light that is incident upon it. White objects approximate the properties of a perfect diffuser, especially in the visible region (400-700 nm) of light. A perfect diffuser will reflect each wave length in the visible region fully such that a plot of absolute reflectance (“[R]”) for the perfect diffuser verses wave length will result in a horizontal line at [R] equals 1.0, as shown in FIG. 1 (absolute reflectance being the intensity of reflected light to the intensity of the incident light). 
     Given the difficulty in measuring the intensity of incident light, a more practical method of quantifying the reflectance from a sample surface is to determine a reflectance for the sample surface relative to that of a standard or reference surface. In particular, a relative reflectance (“[% R]”) can be calculated as follows:          [     %                 R     ]     =       Intensity                 Of                 Reflected                 Light                 From                 Sample       Intensity                 Of                 Reflected                 Light                 From                 Standard                              
     The use of relative reflectance to obtain spectral curves for surfaces liminates the need for measuring the intensity of the incident light. The same standard or reference surface, whose absolute reflectance is known (or approximately known), can be used as a reference to obtain reflectance values for various samples. FIG. 2 illustrates the spectral curves for selected colours in terms of relative reflectance verses wavelength (λ) for light wavelengths in the visible 400-700 nm range. The spectral curve for a sample white surface, as indicated by reference numeral  12  in FIG. 2, resembles that of a perfect diffuser due to its flatness and high relative reflectance values. A spectral curve for a black surface is indicated by reference number  14  in FIG.  2 . As with the spectral curve for the white surface, the spectral curve for the black surface is also flat, however the black surface has very low relative reflectance values. An ideally white surface has a relative reflectance of 100%, whereas an ideally black surface has a relative reflectance of 0% throughout the 400-700 nm range. The spectral curves for colour surfaces lack flatness and reveal peaks and dips in certain regions of the visible light, depending on the colours. For example, the spectral curve for a blue surface (indicated by reference numeral  18 ) shows a peak in the blue region (450-500 nm) and a dip in the red region (600-700 nm) indicating that a substantial amount of the red component of the incident light is being absorbed by the material. Similarly, the spectral curve for a red surface reveals a maximum relative reflectance in the red region and a minimum relative reflectance in the violet-blue region. 
     The present invention makes use of the differences in the spectral characteristics between white and non-white surfaces to determine what classification a piece of paper falls in. With reference to FIG. 3, the colour determination system of the present invention (indicated generally by reference numeral  10 ) includes a light source indicated generally by numeral  20 , an optical detection system, indicated generally by numeral  22 , a processing system, indicated generally by numeral  24 , and an ejection system, indicated generally by numeral  26 . The light source  20  is configured to direct a beam of light at a paper sample  28  for which the colour classification is being made, and includes a tungsten halogen light  30 , an illuminating fibre bundle  32 , and a focusing lens  34 . 
     The tungsten halogen light  30  is a preferred source of illumination as tungsten halogen lights have excellent stability and typically maintain 90% of their initial light output throughout their life. A tungsten halogen light is also a good source of visible radiation (400-700 nm) that is easily detectable by photo diode detectors. However, other light sources could also be used, such as a flourescent light. The fibre optic bundle  32  is preferably made of high grade fused silica with a flexible stainless steel sheathing, and guides the light output by the tungsten halogen light  32  to lens  34 . The lens  34  is preferably concave on its outer face in order to cause the light beam delivered by the fibre bundle  32  to converge to a focus. Conveniently, the spacing between the concave lens  34  and the transmitting end of the fibre bundle sheet  32  can be varied by positioning the end of the fibre closer to or away from the lens, thus allowing the diameter of the beam that is directed from the lens  34  to be varied. The lens  34  is supported such that it directs a light beam onto the paper sample  28  which is to be classified as either being white or non-white and which is located at a sampling station  29 . The lens  34  is positioned to illuminate the piece of paper normal to the surface of the paper so that the specular reflection will return along the same path as the incident light beam and not interfere extensively with the diffuse reflectance measurements taken by the detection system  22 . 
     The optical detection system  22  functions to receive light diffusely reflected off the paper sample  28 , isolate three different spectral components of the reflected light, measure the intensity of each of the three different spectral components, and generate electrical signals representative of the intensity of each of the three different spectral components. In particular, the detection system  22  includes a trifurcated fibre optic bundle  36 , filters  38 ,  40  and  42 , and three photo detectors  44 ,  46  and  48 . The trifurcated fiber bundle  36 , which acts as a three-way beam splitter, is made of glass with flexible stainless steel sheathing. A receiving end  50  is positioned to receive light reflected from the paper sample  28 . In one exemplary example, the fiber bundle  36  receives the reflected light with a cone angle of 64 degrees, thereby making it possible to collect a large amount of the reflected light. Conveniently, the glass fiber bundle  36  blocks radiation below 400 nm and above 1400 nm thus eliminating the need of using further long pass filters to eliminate wavelengths below 400 nm before the reflected light strikes the detectors. Each of the three output branches  52 ,  54  and  56  of the trifurcated fiber bundle  36  carries light of equal intensity. Trifurcating the reflected light equally allows for determination of the extent of variance in radiant power between the three isolated spectral components of visible light. One suitable trifurcated fiber bundle that can be used in the optical detection system  22  is Model No. 77536 available from Oriel (trade-mark). 
     The first filter  38  includes a visible bandpass filter and a blue dichroic filter, and is placed between the end of the first branch  52  and the first photo detector  44 . The filter  38  cuts off light having a wavelength of greater than 525 nm, allowing only a predominantly blue band (400-525 nm) to pass through and strike the detector  44 . As noted above, UV components (&lt;400 nm) are blocked by the fiber bundle  36  prior to reaching the filter  38 . 
     The second filter  40  includes a green dichroic filter and a visible bandpass filter and is positioned between the end of the second branch  54  and the detector  46 . The filter  40  cuts off wavelengths less than 475 nm and greater than 650 nm, and has a peak transmission in the wavelength range of 525 nm to 575 nm in the green region. Thus, the filter  40  allows only a predominantly green band to go through and strike the detector  46 . 
     The third filter  42  is positioned between the end of the third branch  56  and the third photo detector  48 . The third filter  42  comprises a visible bandpass filter that cuts off infrared radiation (λ greater than 900 nm), and has very low transmission in the 700-900 nm range, and a red dichroic filter, which filters out light having a wavelength of less than 600 nm. Accordingly, the third filter  42  allows only a predominantly red band to strike the photo detector  48 . 
     The photo detectors  44 ,  46  and  48  each include a photo diode and an amplifier for measuring the intensity of the light beams received by the photo detectors and generating an electrical output signal that is proportional to the intensity. Thus, the photo detector  44  produces a voltage signal that is representative of the intensity of blue light diffusely reflected from the paper sample  28 , the photo detector  46  produces an electrical output signal that is representative of the intensity of green light diffusely reflected from the paper sample, and the third photo detector  48  produces an electrical output signal that is representative of the intensity of red light diffusely reflected from the paper  28 . The analog outputs of the three photo detectors are provided to an A/D convertor  58  which digitizes the three electrical signals for provision to digital computer  60 . One example of an acceptable photo diode for use in the present invention is model No. OPT 209 available from BURR-BROWN (trade-mark). The digital computer  60  and A/D convertor  58  are part of the processing system  24 . 
     The digital computer  60 , which can be a suitably configured personal computer, is programmed to determine a relative reflectance for each of the three spectral components, determine a mean of the three relative reflectances, determine a standard deviation of the three relative reflectances, and determine, by comparing the mean and standard deviation to predetermine threshold values, whether the paper sample  28  can be classified as white or non-white. In particular, the digital computer  60  is programed to perform these determinations as follows. The digital computer  60  determines a relative reflectance for each of the three spectral components by finding a ratio of the voltage signal generated by each of the detectors  44 ,  46  and  48  in respect of the light reflected from paper sample  28  and comparing the measured voltages to a preobtained reference voltage for each of the spectral components, as signified by the following three equations: 
      [% R ]blue= V   b sam/ V   b ref  (1) 
     
       
         [% R ]green= V   g sam/ V   g ref  (2) 
       
     
     
       
         [% R ]red= V   r sam/ V   r ref  (3) 
       
     
     where: 
     [%R] blue; [%R] green and [%R] red are the relative reflectances for the blue, green and red spectral components, respectively; 
     V b  sam, V g  sam and V r  sam are the magnitudes of the digitized voltage signals generated by the first detector  44 , second detector  46 , and third detector  48 , respectively, in respect of the paper sample  28 ; and 
     V b  ref, V g  ref and V r  ref are the magnitudes of predetermined reference voltage signals for the blue, green and red spectral components, respectively. 
     Preferably the predetermined reference voltage signals are stored values which have been obtained as a result of a preproduction calibration step in which the intensity of light reflected from a known white sheet of paper is measured for each of the three spectral regions by detectors  44 ,  46  and  48 , and such values stored by the digital computer  60  as V b  ref, V g  ref and V r  ref, respectively. 
     Once the digital computer  60  has calculated the relative reflectances in each of the three spectral components for the paper sample  28 , it then determines a mean of the three relative reflectances according to the following equation:                  [     R                 %     ]     _     =           [     %                 R     ]        blue     +       [     %                 R     ]        green     +       [     %                 R     ]        red       3             (   4   )                                
     where: 
     {overscore ([%R])} is the mean relative reflectance. 
     The digital computer then determines, a standard deviation of the relative reflectances for the paper sample  28  according to the following formula:                σ        [     R                 %     ]       =                   (         [     R                 %     ]        blue     -       [     R                 %     ]     _       )     2     +       (         [     R                 %     ]        green     -       [     R                 %     ]     _       )     2     +                 (         [     R                 %     ]        red     -       [     R                 %     ]     _       )     2           2               (   5   )                                
     As can be seen from the spectral curves in FIG. 2, in terms of relative reflectances, white surfaces exhibit high mean values and very low standard deviations. Black surfaces also exhibit a low standard deviation, but have a mean value that is much lower than that of white surfaces. The mean values of coloured surfaces vary, however they exhibit much higher standard deviation values in comparison to white and black surfaces. Accordingly, the digital computer  60  is configured to classify the piece of paper as either being white or non-white based on comparisons of the calculated mean to a predetermined threshold mean value, and the standard deviation to a predetermined threshold deviation value. In particular, digital computer  60  classifies the paper as white in the event the mean relative reflectance is greater than the predetermined mean value and the standard deviation is less than a predetermined deviation value. If the mean and standard deviation do not met these criteria, the paper sample  28  is classified as non-white. The classification algorithm is set out as follows: 
     IF {{overscore ([R%])}≧{overscore ([R%])} ref  and σ[R%]&lt;σ ref } THEN 
     SHEET=“WHITE” 
     ELSE 
     SHEET “NON-WHITE” 
     Where: 
     {overscore ([R%])}ref is the predetermined threshold mean relative reflectance, and 
     σ ref  is the predetermined threshold deviation. 
     The threshold mean relative reflectance and threshold standard deviation are preferably selected through experimentation dependent on the particular paper products sorted by the device  10 . It has been determined that a threshold mean relative reflectance of 50% and a threshold standard deviation of 5.0 provide a high degree of accuracy in separating non-white sheets from white sheets. Other threshold mean reflectance values and threshold standard deviation values could be used depending on how wide or narrow a range was desired to classify recycled paper sheets as “white”. It will be appreciated that the lower the threshold mean and the higher the threshold deviation, the broader the classification of “white” paper products would be. Preferably the threshold mean relative reflectance is a value that falls within a range of 50 to 70%, and the threshold standard deviation is a value that falls within a range of 3 to 5. 
     Once the digital computer  60  classifies the paper sample as non-white or white, it can display its determination on an output screen  62  and furthermore send, depending on whether or not the paper sample is white or non-white, an activation signal via A/D convertor  58  to the ejection system  26 . The ejection system  26  is configured to selectively redirect a sample of paper  28  depending on whether the digital computer has classified the paper as white or non-white. The digital computer  60  can be programed to send out an activation signal to redirect the paper  28  if it is non-white if it is desired to redirect non-white paper products, or alternatively can be programed to send out the activation signal when the paper sample is classified as white, in the event that it is desired to redirect white paper products. The ejection system includes an air compressor  64  connected to a normally closed solenoid valve  66  which controls the flow of air from the compressor  64  to an air nozzle  68 . Control of the solenoid valve  66  is effected by a relay card  70  which can operatively connect the power supply  72  to the solenoid valve  66 . Operation of the relay card  70  is controlled by the actuation signal received via A/D convertor  58  from the digital computer  60 . In particular, when the relay card  70  receives the activation signal, it electrically connects the power supply  72  to the solenoid valve  66 , causing the solenoid valve  66  to open momentarily thereby allowing a blast of compressed air from compressor  64  to be directed through the nozzle  68  at the paper  28  in order to redirect the sheet of paper  28 . 
     The colour determination system  10  is intended to be used in an automated high speed paper sorting line having, with reference to FIG. 4, a high speed conveyor system for moving sheets of paper to and through the colour determination system  10 . In one exemplary embodiment shown in FIG. 4, the conveyor system includes first and second conveyor belts  74  and  76 . The first conveyor belt  74  is elevated slightly above, and separated by a space from the second conveyor belt  76 . During normal operation, paper pieces moving along the conveyor belt  74  will, after leaving conveyor belt  74  land on the conveyor belt  76  unless redirected by a blast of air from air nozzle  68  into a collection bin  78 . The first conveyor belt  74  feeds recyclable paper in single sheets to the sampling station  29  of the colour determination system  10  which determines whether the sheets can be classified as white or non-white and causes air nozzle  68  to selectively redirect sheet samples  28  away from the second conveyor  76  and into the collection basket  78  depending on such determination. The conveyor belt  74  moves at a speed known to the digital computer  60 , and accordingly computer  60  is configured to activate the ejection system  26  at an appropriate time to direct a selected paper sample  28  into the waste basket  78 . Thus, it will be appreciated that during a particular recycling run the colour determination system  10  continuously classifies a steady stream of paper samples, and selectively redirects paper samples depending on whether they are classified as white or non-white. The determination method used by the digital computer  60  can, with reasonable accuracy, classify paper sheets having a large degree of printed matter thereon as white or non white, and thus functions to determine if the predominant colour of the paper product. 
     It will be appreciated that the device and method of the present invention could be adopted to sort objects other than paper into one of two possible colour classifications dependent on the dominant colour of such objects. 
     As will be apparent to those skilled in the art in the light of the foregoing disclosure, many alterations and modifications are possible in the practice of this invention without departing from the spirit or scope thereof. The foregoing description is of the preferred embodiments and is by way of example only, and is not to limit the scope of the invention.