DE19850285A1 - Method and device for sorting fluorescent lamps - Google Patents

Abstract

The invention relates to a method and a device for sorting fluorescent lamps according to their luminescent mixtures which lamps have a cylindrical lamp body (1) with a right and a left end and with a symbol imprinted thereon. The fluorescent lamps are fed to an inspection station (10) which comprises stop devices (11, 12) defining an inspection surface (13) which the respective lamp body (1) to be examined contacts. A camera (21) with an image processing system (30) linked thereto is positioned in the direction of the symbol imprint of the respective lamp body (1) to be examined. A turning device (15, 16) in the inspection station (10) is used to turn the respective lamp body (1) to be examined. The camera (21) transmits pixel signals to the image processing system (30) which recovers image data from the pixel data. The image processing system (30) contains image memories with data for recorded symbols and an image comparative device which correlates the image data with the recorded symbol data. The respective fluorescent tube is withdrawn from the inspection station (10) and directed to one of several sorting paths via a distribution system (25).

Description

The invention relates to a method and a Device for sorting fluorescent lamps by Phosphor mixtures.

When recycling fluorescent lamps, it is important to recover the phosphor. The different However, fluorescent lamp manufacturers use different additives to the basic phosphor what the recovery of the basic phosphor is extremely difficult makes.

To avoid these difficulties the inventor developed a concept, not the phosphor want to regain as such, but the Fluorescent mixtures, as in the different Lamp types from different manufacturers occur.

The invention is therefore based on the object Method and device for sorting Fluorescent lamps create what sorting by Fluorescent mixtures enabled.

The task is based on the Method steps of claim 1 or the features of Claim 3 solved and by the further measures of Subclaims designed and developed.

The individual to be examined Fluorescent lamps fed to an inspection station so that a predetermined distance from at least one camera exhibit. The fluorescent lamp is rotated around the one in the Read the imprint near the lamp base and to be supplied to an image processing system. The imprint  generally includes a company logo with a Type identification from letters and numbers. The Image processing system contains a memory for Pre-entry of such company logos and type designations, see above that by comparison, the fluorescent tube examined in each case can be assigned to the manufacturer and the lamp type. This makes it possible to consider the fluorescent lamps sort their phosphor mixes.

The print is on fluorescent lamps only at one end in a range of about 80 mm Width from the end of the fluorescent body. If used up Fluorescent lamps are delivered, is the distribution of the Arbitrarily with imprint or without imprint. To this Addressing a problem can be a double one Pass through the detection system, where before the second run the previously unrecognized Fluorescent lamps are rotated by 180 ° so that you right end passed the camera.

But it is also possible to provide two cameras each on an assigned end of the lamp body be judged. In this design of the invention one of the cameras designed to be movable adapt to different lengths of fluorescent tubes can be in the range between 350 and 1800 mm long can.

To support the lamps in the inspection station can be two spaced angles are used, the connecting lines to each other Alignment prism result. The support angles are in sufficient distance from the ends of the fluorescent lamps to avoid arranging the image inspection by the cameras to disturb. One of the support angles is designed to be movable the specified length range from 350 to 1800 mm in length to be able to adapt the fluorescent lamps.

Details of the invention are based on the Drawing explained. It shows:

Fig. 1 is a schematic overall view

FIG. 2 shows an enlarged detail from FIG. 1.

Fluorescent lamps 1 are brought individually from a cup conveyor 2 to an infeed conveyor 3 , which consists of an inclined runway. A guide cover surface 4 ensures that the fluorescent tubes 1 arrive horizontally aligned in an inspection station 10 . In the inspection station 10 , stops 11 and 12 are provided, which in the present case are designed as stop angles and, in connection with one another, span a prism in order to keep the lamp body of the fluorescent tube 1 at a defined distance from a right camera 21 or a left camera 22 . The prism spanned by the angular stops 11 and 12 contains two surfaces at right angles to one another, each of which can be used as an inspection plane in association with the cameras 21 and 22, respectively. In the exemplary embodiment shown, the stop surface 13 , which is steeper relative to the rolling surface 3 , is to be used as the inspection plane. Accordingly, the viewing directions of the cameras 21 and 22 are oriented perpendicular to this plane 13 , and the distance between the cameras is selected so that the plane 13 is sharply imaged in the camera.

Each stop angle 11 or 12 is assigned roller pairs 15 and 16 , respectively, which are arranged tangentially to the stop plane 13 , as best shown in FIG. 2. A friction roller drive 17 or 18 is assigned to each of the rollers 15 or 16 in order to drive the respective roller 15 or 16 and thus to rotate the lamp body 1 located in the inspection station.

The stop bracket 11 and the associated rollers 15 are arranged in a stationary manner, while the stop bracket 12 can be moved with the associated rollers 16 in the direction of extension of the inspection station 10 , as indicated by the double arrow 19 . The stop angle 12 including the rollers 16 can be shifted by means of a spindle and a guide, which has not been shown for reasons of clarity.

To the same extent as the stop angle 12 can be shifted, the camera 22 can also be shifted parallel to the longitudinal extent of the inspection station 10 , as indicated by the arrow 23 . A spindle and guide can be used for this purpose, other displacement means can also be used. By shifting the stop angle 12 and the camera 22 , it is possible to adapt the device to changing lengths of the lamp bodies 1 . If the device is designed for a maximum length of the lamp body 1 of 1800 mm, the stop angle 11 is located at a distance of approximately 150 mm from the end of the lamp body 1 . The movable stop bracket 12 can be moved up to a distance of 150 mm from the end of the lamp body 1 . If shorter lamps are due for inspection, the movable stop angle is moved to the right in the drawing to leave about 150 mm free at the end of the lamp body. The camera 21 is arranged in a stationary manner and is aligned with an end region of the lamp body 1 of 80 mm in width, on which the manufacturer's imprint with the manufacturer's symbol and type identification can be expected. The movable camera 22 is aimed at the respective end of the lamp body 1 , specifically to an area likewise 80 mm wide.

The two cameras 21 and 22 are connected to an image processing system 30 which can record digital image information coming from the cameras as pixel signals and compare it with stored image information. This stored image information relates to the imprints to be expected at the end of the lamp body, specifically with regard to the manufacturer and lamp type. In general, company symbols or logos and letter-number combinations are printed, the size of the print depends on the lamp type. If the lamp body 1 is rotated during the test and the imprint moves through the field of view of the camera 21 , then the company logo and the type identification are read in the order we are used to.

On the other hand, if the symbol print is at the left end of the lamp body, then the camera 22 reads the symbol print backwards. The processing in the image processing system takes this into account. If the image processing system has a monitor 31 for control purposes, then this is fed so that the imprint appears in the correct reading direction for humans.

A turnout control 32 is connected to the image processing unit 30 and ensures that the lamp body being tested in each case is sorted correctly. This takes place in an outfeed conveyor section 24 , which can be designed as an inclined runway with a series of flaps 25 . By reversing the rollers 15 and 16 , the lamp body located in the inspection station 10 is raised above the height of the stop angle 11 and 12 and then reaches the runway 24 in order to roll down thereon. Each flap 25 has a flap drive, which is connected to the switch control 32 . The switch controller 32 has as many outputs as light substance mixtures plus a further output for unidentified light substance mixtures. The respective outputs of the switch control 32 are assigned to the flaps 25 , so that when a certain class of fluorescent tubes is determined by manufacturer and lamp type or types, to which a specific fluorescent mixture is assigned, an assigned flap 25 is opened and the rolling down fluorescent tube in one below it located container lands.

The new sorting method enables a relative rapid determination of the class of the examined Fluorescent tube. It can take up to 2 seconds 0.5 seconds. The selectivity of the Recognition of the symbol imprint is very high, with under "Symbol imprint" both the company logo and the Type marking is to be understood. Lamps whose Affiliation cannot be clearly determined in processed in the usual way. In this way  those recovered from the fluorescent tubes Fluorescent mixtures of extremely high quality recovered as not disturbed by foreign mixtures. The Obtaining the phosphor mixtures from the Fluorescent tubes is done in the usual way by opening the Fluorescent tubes and blowing out the coating with Compressed air.

Claims (7)

1. Method for sorting fluorescent lamps according to fluorescent mixtures which have a cylindrical lamp body with right and left ends and with a symbol print, with the following features:

• a) Fluorescent lamps are conveyed into an inspection station which have stop means ( 11 , 12 ) for defining an inspection plane ( 13 ) against which the lamp body ( 1 ) to be examined in each case rests;
• b) a camera ( 21 ) with a connected image processing system ( 30 ) is pointed at the symbol imprint of the lamp body ( 1 ) to be examined in each case;
• c) a rotating device ( 15 , 16 ) in the inspection station ( 10 ) is started in order to rotate the lamp body ( 1 ) to be examined in each case;
• d) the camera ( 21 ) outputs pixel signals to the image processing system ( 30 ), which extracts image data from the pixel signals;
• e) the image processing system ( 30 ) contains image memories with data for input symbols and an image comparison device which correlates the image data with the input symbol data;
• f) the fluorescent lamp examined in each case is conveyed out of the inspection station ( 10 ) and directed into one of several sorting paths via a switch system ( 25 ).

2. The method according to claim 1, characterized in that the promotion of fluorescent lamps takes place in a horizontal orientation of the lamp body ( 1 ) and that the fluorescent lamps enter an angular prism as a stop means ( 11 , 12 ). 3. Device for performing the method according to claim 1 or 2, with the following features:
an infeed conveyor line ( 3 ) for fluorescent lamps, on which a stop surface ( 13 ) for the lamp bodies ( 1 ) is provided to define an inspection plane, the ends of the lamp bodies ( 1 ) remaining free from the stop surface;
a rotating device for the lamp body in contact;
at least one camera ( 21 ), the image plane of which is aligned with the inspection plane ( 13 ) in the region of one of the ends of the lamp body ( 1 );
an image processing system ( 30 ) connected to the at least one camera ( 21 ) for extracting image data from pixel signals, further comprising image memory with data for input symbols and having an image comparison device which correlates the image data with the input symbol data;
an outfeed conveyor section ( 24 ) with a controllable switch system ( 25 ) which is connected to the inspection station ( 10 ) and can be controlled by the image processing systems ( 30 , 32 ). 4. Device according to one of claims 4 to 6, characterized in that one of the cameras ( 22 ) parallel to the inspection plane ( 13 ) can be moved to adapt to different lengths of the lamp body ( 1 ). 5. The device according to claim 4, characterized in that the inlet section ( 3 ) is designed as an inclined surface, at the lower end of which there are two stop angles ( 11 , 12 ) which are at a predetermined distance from the right or left end of the lamp body ( 1 ) are arranged and define a prism body in connection with each other. 6. The device according to claim 5, characterized in that the one bracket ( 11 ) stationary and the other bracket ( 12 ) along the prism body is movable in order to adapt the support of the lamp body ( 1 ) different lengths of the lamp body. 7. Device according to one of claims 4 to 6, characterized in that one of the cameras ( 22 ) can be moved parallel to the inspection plane ( 13 ) in order to adapt to different lengths of the lamp body ( 1 ).