US3749923A

US3749923A - Optical label inspecting apparatus

Info

Publication number: US3749923A
Application number: US00185092A
Authority: US
Inventors: R Husome
Original assignee: Acurex Corp
Current assignee: Acurex Corp
Priority date: 1971-09-30
Filing date: 1971-09-30
Publication date: 1973-07-31
Anticipated expiration: 1990-07-31

Abstract

A container label inspector apparatus utilizing light reflected from the container to detect a missing or misapplied label on tin, aluminum, glass, or other reflective containers and serving to reject containers having missing or misapplied labels.

Description

United States Patent 11 1 Husome July 31, 1973 [54] OPTICAL LABEL INSPECTING APPARATUS 3,003,629 10/1961 Henderson 209/ 1 1 1.7 X 3,203,547 8/1965 Giulie et a1. 209/1 11.7 X [75] 3,289,832 12/1966 Ramsay 209 1117 x [73] Assignee: Acurex Corporation, Mountain Cahf' Primary Examiner-James W. Lawrence [22] Filed: Sept. 30, 1971 Assistant Examiner--T. N. Grigsby Att0mey- Flehr, Hohbach, Test, Albritton & [2]] Appl. No.. 185,092 Herbert 52 us. c1 250/223, 209/111.7, 356/240 ABSTRACT [51] Int. Cl... B07c 5/342, G01n 21/16, 606m 7/00 A t 1 t ht [58] Field of Search 250/223 B, 223; f

flected from the contamer to detect a m1ss1ng or m1sap- 356/240, 209/111.5, 111.7

plled label on tm, alummum, glass, or other reflectwe 56] References Cited songiinzirssaamllizejrgrgiltso reject containers having miss- UNITED STATES PATENTS g pp 2,800,226 7/1957 Drennan 250/223 B 2 Claims, 4 Drawing Figures PAIENTEU 1 I915 3.749.923

SHEEI 1 0F 3 ROBERT G. HUSOME INVENTOR.

BY 5 444x25. WW

ATTORNEYS Y PATENTED 3 1 973 SHEET 3 BF 3 ROBERT G. HUSOME I NVEN TOR.

BY 124W Mum WW ATTORNEYS 1 OPTICAL LABEL INSPECTING APPARATUS BACKGROUND OF THE INVENTION This invention relates generally to label sensors and more particularly to optical label sensors. In the canning industry, labels are generally placed on glass, tin and aluminum containers by a labelling machine. The containers leaving the labelling machine are inspected to assure that the labels have been properly applied. When a misapplied or missing label is detected, the container is rejected.

Prior art devices for inspecting containers have depended upon the conductivity of the container to thereby either provide a circuit between a feeler disposed to engage one end of the can and the container, or no circuit, indicating that a label is present and properly applied.

Such apparatus has not been useful in connection with anodized aluminum containers wherein the surface coating forms an insulating layer, or with glass containers.

OBJECTS AND SUMMARY OF THE INVENTION It is a general object of the present invention to provide a label inspecting apparatus which can be used in connection with containers having conductive and nonconductive surfaces.

The foregoing and other objects of the invention are achieved by a label inspection machine in which the container is guided by guide rails past an inspection station disposed along said lay rail. A light source projects a light beam parallel to the surface of the container towards a detector and serves to detect end flaps which have not been properly secured to the can. Furthermore, the machine includes a second light source which projects a beam of light onto the container near one end and aphotoelectric cell disposed to receive the reflected light beam and provide an increased output signal when a label is not present or is misapplied.

BRIEF DESCRIPTION OF THE DRAWING FIG. 1 is a schematic diagram of a label inspection machine in accordance with the present invention.

FIG. 2 is an enlarged view of the label inspection device used in connection with an aluminum container. FIG. 3 is a block diagram showing the electrical circuit which is responsive to an increase in reflected light from the container or interrupted light by the label.

FIG. 4 is a detailed circuit diagram of the amplifier associated with the reflected light photodiode.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Referring to FIG. 1, the apparatus includes two pairs of spaced

support legs

11, 12 and 13, 14. The legs include telescoped sections to provide a height adjustment. Stabilizing members 16 and 17 are disposed longitudinally on the apparatus and secured to the spaced the opposite direction thereby moving the rails together. The rails are adapted to abut the two ends of the containers to guide them as they roll on the spaced

longitudinal support rails

28 and 29. The

rails

28 and 29 are supported on the rails 26a and 26b. The

support rails

28 and 29 include

blade portions

32 and 33 which are moved by a solenoid 34. When the solenoid is energized, the

rail portions

32, 33 move outwardly and the container 31 is no longer supported and falls into reject chute 36.

In operation, the container 31 is applied at the end 41 of the apparatus. With the rails being slightly inclined, the container rolls downwardly toward the end 42 past inspection station 43.

The inspection station 43 includes arms 46 and 47 supported from the rails 26a and 26b. The arm 46 serves to support a photodetector 45. The height of the detector is adjustable along the arm 46. The arm 47 supports a light source 48 which projects a beam parallel to the top edge of the can towards a detector 45. The height of the light source is adjustable whereby it can be aligned with the photodetector. The light source and the photodetector serve to detect whether the endsv of the label have been suitably secured. If the label ends have not been suitably secured, they intercept the light beam and generate an electrical signal which is employed, as will be presently described, to generate a reject signal.

A second light source 51 and photodetector 52 are placed whereby the detector 52 receives light'reflected from the surface of the container 31. Making reference particularly to FIG. 2, the container shown is an aluminum container with a reinforcing ring or indenture 53. The light source projects a light beam on the surface 54 which reflects the light upward to the photodetector 52. The photodetector is mounted in a lens tube assembly which provides a field of view which is clearly defined and limited to a narrow segment of the conical surface of interest whereby extraneous light and the like is rejected. It is preferable to employ specularly reflected light. Consequently, the light source and photodetector are located so that the angle of incidence of the light from the source and the viewing angle of the detector are equal.

If a label is properly applied, the reinforcing ring is covered and very little light is reflected by the label into the photodetector, whereas if the ring is missing, sub stantial light is reflected. When the amount of light striking the photodetector exceeds the level represented by light reflected from a label, a reject signal is generated.

Referring to FIG. 3, the electrical circuitry associated with the lamps and photocells is shown in block diagram. The input from the supply line 61 is applied to a dc. power supply which converts 6O hertz single phase voltage to a 12 volt dc. voltage. The supply line is also connected to relay 63 and quadrac 64.

The output from the 12 volt d.c. supply is applied to lamp regulator 66 which regulates the voltage and applies a voltage to the

light sources

48 and 51 previously described. The photodetector or

photodiodes

45 and 52 are shown receiving the direct and reflected light respectively. The output from the photodiode 45 is applied to an amplifier 67 which includes filter means for filtering out noise pulses which might be present in the industrial environment. This prevents the noise pulses from causing spurious operation The amplifier provides a negative output pulse whenever the light path is interrupted. The negative pulse is applied to the OR gate 68. The output from the OR gate drives one-shot multivibrator 69. The pulse width of the one-shot multivibrator is adjusted by width adjustment 71. The output of the multivibrator is applied to relay driver circuit 72 to drive the relay 63 which controls quadrac 64. The quadrac controls the application of power to the reject solenoid 73. When the solenoid is energized, the

reject blades

32, 33 are withdrawn to reject the mislabelled container. Thus, a negative pulse from photodiode 45 due to loose flaps on the label forms a negative pulse which controls the reject solenoid to reject the container.

The amplifier circuit 74 receives the signal from the photodiode 52 and processes the positive signal to give a negative output pulse when the label is misapplied. The negative pulse is applied to the OR gate to thereby operate the solenoid in the manner just described to reject the container. The amplifier 74 includes a sensitivity control for controlling the sensitivity of the circuit to thereby provide a means for differentiating between light reflected from labels and that reflected from the surface of the container.

FIG. 4 is a detailed circuit diagram of the amplifier 74 which provides the negative output pulse when there is a misapplied label, which pulse is then employed to reject the container. Photodiode 52 is connected to the input terminals of an integrated circuit operational amplifier 76. Capacitor 77 is connected across the input terminals of the amplifier 76 and filters out noise pulses which might be present in the industrial environment, preventing them from causing spurious operation. The cathode lead of the photodiode 52 is connected to the non-inverting input of amplifier 76 and also a dc voltage produced by Zener diode 77 and resistor 78 is connected to this terminal. The anode of the photodiode 52 is connected to the inverting input of the amplifier 76 and via a resistor 79 connected to potentiometer 78. The voltage on the arm of the potentiometer 78 is adjustable between zero and a plus voltage regulated by Zener diode 86. This arrangement supplies a reverse bias current to the diode 52 adjustable from zero to a current corresponding to the voltage. For example, the voltage might be adjustable from zero to +7 volts and the current would vary from zero to 7 microamps, if resistor 79 was 1 megohm.

When the diode 52 is not illuminated by reflective light, the bias current causes a voltage drop across the amplifier 76 inputs. Diode 81 limits the voltage drop to about 0.6 volts maximum. The polarity of this voltage drop is minus at the inverting input of the amplifier 76 with respect to the non-inverting input, causing the output of the amplifier to become positive.

When diode 52 is illuminated, its photocurrent opposes the bias current supplied through the resistor 79. With sufficient illumination, its photocurrent will exceed the bias current causing a reversal of polarity at the input of the amplifier 76. When this occurs, the output of the amplifier 76 goes negative (towards ground). Since resistor 78 adjusts the bias current, it also sets the photocell light level required to change the polarity of the input of the amplifier 76. When setting up the machine, the resistor 78 is adjusted so that amplifier 76 output remains positive when a labelled can is present but goes negative when an unlabelled container is centered under the photocell lens tube assembly. The output of the amplifier 76 drives the base of transistor 82 via resistor 83 and diode 84. As long as the output of the amplifier 76 is positive, diode 84 is reverse biased and the transistor 82 remains turned off. When the output of the amplifier 76 goes negative indicating the presence of an unlabelled or mislabelled can, diode 84 conducts current to the base of the transistor 82 turning it on. The collector of the transistor 82 is coupled to the timing circuits, resistors 87 and capacitor 88 of the machine and conduction of transistor 82 results in a pulse to the OR gate 68, which pulse then activates the reject mechanism previously described.

Thus, it is seen that there has been provided a label inspection machine which serves to reject the containers having no labels or misapplied labels or containers in which the end flaps-of the label are not firmly affixed. The system is simple in operation and is adaptable for use with not only cans which have conductive surfaces, but also with aluminum cans having an insulating film on their surface and with glass containers.

1 claim:

1. In a container label inspection machine including guide rails for receiving and guiding containers, an inspection station disposed along said rails for inspecting a container having a reinforcing ring in the form of a V-shaped groove, said container adapted to move past said station and rejection means responsive to a reject signal for rejecting defectively labelled containers, the improvement comprising a light source for projecting a light beam onto one surface of said groove, means including a photoresponsive device mounted in a lens tube assembly to provide a defined, limited field of view whereby to reject extraneous light and receive light reflected from said surface of the groove, said means including said photoresponsive device and said light source located so that the angle of incidence of the light and the angle of the field of view are equal whereby said photoresponsive device receives specularly reflected light, said photoresponsive device serving to provide an electrical output signal when the reflected light exceeds a predetermined level to provide a reject signal to said rejection means to reject a defectively labelled container.

2. A container inspection label machine as in claim 1 wherein said container is an aluminum container having a reinforcing rim and said light source projects a light beam onto one surface of said rim and said photoresponsive device is disposed to receive specular reflections from said surface and provide the electrical signal for the control means.