WO1993011882A1 - Optical inspection and sorting device, in particular for foodstuffs - Google Patents

Abstract

An optical device for inspecting and sorting individual free falling objects (B) has a laser scanner (4) arranged at the periphery of an inspection zone (PZ). The reflected light is collected all around by the ends (3) of light guides and transmitted for evaluation purposes to a control device (ST) that controls a sorting device (5) arranged downstream of the inspection zone (PZ) according to predetermined inspection criteria. A light guide web (9) that surrounds the inspection zone (PZ) captures directly incident laser light and the evaluation of the reflected light is controlled depending on the captured direct laser light. This device is particularly suitable for sorting peeled potatoes and wet goods.

Description

 Optical testing and sorting device, in particular for food

The invention relates to a device for optically checking and sorting objects, in particular foodstuffs, which are guided serially in free fall through a test zone, around which a plurality of light sources and at least one reflected light receiver are circumferentially arranged, the light signals of which are opto-electrically converted in a control device Predetermined limit values are compared, if they are exceeded or undershot, a control signal is generated in a microprocessor, which acts on a sorting switch, which is arranged below the test zone.

Such a device is known from DE 36 14 400 Cl, in which in particular agricultural products such as peas, beans or the like are occasionally bypassed an optical test device, the product error detection signal of which controls a downstream product switch, whereby defective objects are driven. In the optical test device, the isolated objects are illuminated by light sources distributed around the circumference of the transport path. The light reflected from the test objects is picked up by assigned light receivers and converted electrically with regard to impermissible signal folc ^; i evaluated. The incandescent lamps used for lighting provide global lighting for the objects and the light receivers likewise capture the object as a whole with respect to a background adapted to the average object, so that the received signals only provide a global statement about the optical properties of a product, which is only sufficient for a rough assessment, for example a degree of maturity. However, this device does not display an approximately punctiform damaged area, for example a worming sting, a mold patch, etc., which means that its area of use is very limited. In addition, the device is only suitable for the optical assessment of dry objects, since moist surfaces, depending on their angular position to the light source and the light receiver, supply strongly fluctuating signals due to the different reflections.

Furthermore, an optical inspection and sorting device is known from the brochure of Key Technology Inc., USA, Opti Sort, 8/89, in which the individual objects are each inclined from above with several electronic cameras with electro-optical line converters, so-called CCD Arrays, scanned at high speed and whose signals are evaluated with respect to predetermined limit values. However, due to the limited depth of field of the camera lenses, this only enables the precise detection of small objects with approximately the same diameter or thickness, e.g. of potato sticks. The camera devices and the evaluation electronics are very complex and expensive.

Furthermore, a test device is known from DE 31 23 184 C2 in which a radial laser beam is deflected axially to the axis of rotation of a rotationally symmetrical test object, the object in each case on one Rotary device supplied, held there during testing, wherein several reflective light receivers with respect to the different inclinations of the surfaces of the object to the laser beam are differently aligned and axially offset, the electrical signals of which are fed to an evaluation processor which, depending on the evaluation result, ejects the object controls the rotating device in different output trays. This device is only suitable for objects with precisely defined shapes and has a relatively low throughput, since the objects have to be detected, rotated and released individually. In addition, the areas close to the ax are not optically detected and thus remain unchecked. Several photodiodes are required for the detection of light from different radiation directions.

Furthermore, DE 30 222 750 AI discloses an optical scanning device for illuminated objects carried on a band, a bundle of the radiation reflected from the object being guided via a focusing and scanning optical-mechanical arrangement to a plurality of reflected light receivers which are sensitive to different light wavelengths is. In addition, part of the reflected light is taken up by optical fibers, one end of which is arranged around the evaluated light beam and coated with a reference fluorescent paint, and the other ends of which are guided to a reference photocell, the signal of which serves as a color reference signal for evaluating the signals of the other light receivers. This device is only suitable for scanning an object side and requires a high mechanical and optical effort as well as several photo sensors; nevertheless, only the reflected light from one direction is detected.

It is an object of the invention to disclose a relatively simple optical testing and sorting device which reliably assesses and sorts objects of widely different sizes and different levels of moisture for the presence of small-area damaged areas of different colors.

The solution to the problem is that the light sources are each formed by a laser scanner, the deflection planes of which are essentially perpendicular to an object drop direction, and these laser light sources cyclically sequentially detect an object circumferential sector for approximately one deflection period, and that the light receivers are optical fibers Are fiber optic bundles, the ends of which are fed to an opto-electric reflected light converter, the output signal, the reflected light signal, of which is fed to the control device for comparison with the limit values and a further evaluation, and that a direct light receiver is arranged on all sides around the test zone at such a height, that the laser scanner beams always hit it when they do not hit an object, and that this direct light receiver leads to an opto-electrical direct light converter whose direct light signal is fed to the control device.

Advantageous refinements are specified in the subclaims.

The device allows the optical assessment of objects of different diameters and shapes with high resolution, because of their entire surface is scanned closely spaced during passage with relatively thin laser beams of low dispersion.

Furthermore, the light receiver device, which consists of a large number of light guide ends oriented at different angles to the object surface and to the laser beams and which bundle the received light to an electro-optical converter, permits the evaluation of dry and moist-glossy surfaces, since the so caused averaging of the reflected light over many radiation directions eliminates disturbing gloss effects.

The assessment of objects of different sizes is facilitated by the fact that the control of the signal evaluation takes place in such a way that direct laser light, which occurs on the opposite side of the laser when the object is not present, is detected with separate light receiver means and the evaluation of the reflected light with respect to the evaluation time and the evaluation threshold is controlled as a function of the signals of the light detected in this way.

Because of the combination of the reflected light and also the direct light with separate glass fiber bundles, the opto-electrical converters each consist of one photodiode, so that a very simple serial signal evaluation of the two photodiode signals is possible.

The high speed of modern electronic means enables the lasers, each of which encompasses an angular segment area of the object circumferentially, to be activated cyclically one after the other, so that overlap of reflected light from different laser beams does not occur during the evaluation and only a single evaluation electronics channel for the successively occurring line segment signals which the individual lasers generate one after the other is required.

The evaluation of the reflected light of a test object is carried out by multiple analysis of the signal sequences obtained, which can be assigned to an object. Preferably, the following parameters are to be specified in each case according to the conditions: A brightness transmission range, the upper and lower brightness limit values of which can be set, a lower one permissible defect signal length in a line segment length, an upper permissible number of line segments with a defect signal for an object, an upper permissible number of defects per specified object line length and a maximum defect signal length sum per specified object line length. A defect on the object results in a signal outside the permissible brightness limit values during the line scan, that is, a defect signal.

It is advantageously provided to constantly flush the lasers and the deflection devices of the laser beams with cleaned air in the direction of the conveying device, so that in addition to the cooling effect, a cleaning effect is achieved which prevents dust deposits in the beam path.

In a simple embodiment, it is provided that only one laser, with a deflection device and a plurality of deflection mirrors, be arranged around the object area at different angles, so that the different angle segments are acted upon one after the other by laser radiation, either directly or by the deflection by one of the mirrors.

The new device is particularly suitable for quality assessment and sorting of peeled objects, especially potatoes. It makes it possible to peel the potato, instead of strongly peeling it down to a standard size, as usual, so that only a small amount of waste is produced, and to re-peel the potatoes that have even larger imperfections or deep eyes feed so that an optimal potato utilization takes place. This also makes it expensive to dispose of Peeling waste is significantly reduced below the usual 50%.

Advantageous configurations are shown in FIGS. 1 to 7.

Fig. 1 shows a potato peeling system with a testing and sorting system in the circuit;

Fig. 2 shows the testing and sorting device, partially opened;

Fig. 3 shows a section of the test device;

Fig. 4 shows an enlargement of a cross section of an optical fiber for direct light detection with a beam path scheme;

Fig. 5 shows a cross section of a light guide tape, ^• 'enlarged;

Fig. 6 shows a plan view of the light guide tape in the device enlarged with the beam path; .

7 shows a block diagram of the signal evaluation device.

Figure 1 shows a peeling device (1) of known type, which is set to thin peeling. Raw material (A) is introduced into the feed hopper (10). The peeled potatoes (B) leave the peeling device (1) on the other side, from where they are removed by the elevator (11) and passed through a separating lock (12) and successively from above the inlet (20) of the test and sorting device (2) are supplied. This has on the underside a first direct outlet 21) through which the accepted peeled potatoes (D) exit and a second, controlled feed Outlet (22), which is followed by a conveyor (23) which conveys the sorted potatoes (C) into the feed hopper (10) of the peeling machine (1), where the peeling takes place.

Figure 2 shows the testing and sorting device (2) partially opened and cut. The objects, the potatoes (B), which are to be optically assessed, fall from the inlet (20) in free fall through the test zone (PZ) and from there into the sorting zone (SZ), from where the potatoes continue to fall if judged well and roll to the outlet (21) or fall into the second outlet (22), deflected by controlled blowing nozzles (5), and roll out there.

A flat, ring-shaped housing (6, 61, 62) is arranged around the test zone (PZ), on the outer ring wall (6) of which a plurality of laser scanners (4) are arranged, equally distributed over the circumference, the alternating laser beams (Eil, E12 , E2, E3) enter the ring interior through narrow slits (40) and cover the central area in the test zone (PZ) in a fan-like manner, sweep horizontally so that the test specimens (B) are scanned on all sides.

To receive the laser light reflected from the test object (B), the end faces (3) of light guides are arranged radially all around on the ring wall (6). The light guides are guided to the outside and run together to form a photo bundle (30) in an evaluation and control device (ST).

Furthermore, a light guide flat band (9) is arranged all around along the ring wall (6), which is arranged so that the Laser light bundle (Eil, E12, E2, E3) falls directly on it when there is no test object (B) in the beam path, i.e. when there is no test object in the test zone (PZ) or the laser beam is just so far laterally deflected that he runs past the test object just present, as is always the case with the laser beam (Eil, E12), which is deflected to the edge of the fan. The flat ribbon light guide (9) is also combined at the end to form a light guide bundle (90) and fed to the control device (ST).

- The control device (ST) in turn controls the laser scanners (4) cyclically and it controls the valves (50) of the blowing nozzles (5) fed with compressed air (P).

Figure 3 shows an enlarged section of the test device, partially opened. The Laserscaπner (4) consists of a laser diode (7), the laser beam (El), deflected by an electromagnetically controlled periodically pivoted mirror (8), enters the annular space through a horizontal slot (40) in the ring wall (6). The annular space is largely closed by a base plate (62) and a cover plate (61), and there are only openings in it for the serial passage of the test objects. The ring wall (6) has internal steps (63, 64) on the front, in which the top and bottom plates (61, 62) are held centered.

The ring wall (6) has a circumferential groove on the outside

(65), in which the light guide bundle (30) is guided, and from where the light guide ends (3) through holes

(66) are branched into the ring interior. On the entire circumference of the ring wall (6) 50 to 100 light guide ends (3) are arranged evenly distributed, so that light scattered in very different directions on the object hits the different light guide ends (3) and is brought together by the light guide bundle (30).

In the area of the direct laser light beam paths (E3), the light guide strip (9) is arranged all round above the light guide ends (3). The light guides of the band (9) are arranged so close to one another and have such a small diameter that the laser beam always hits at least one light guide of the band (9) when it does not hit a test object.

Figure 4 shows the schematic beam path in an optical fiber (91) of the optical fiber ribbon. The laser beam (E) penetrates the optical fiber (91) from the side and is focused by its cylindrical lens effect. The focus (F) is on the other side of the fiber (91) on the ring wall (6). In the area of the beam exit from the fiber (91), this is roughened by a bevel (S), so that light incident there from inside is scattered there as scattered light (ES) and light coming back from the reflecting ring wall (6) as scattered light (ES ) is distributed in the optical fiber (91).

Figure 5 shows a section of the light guide tape (9), enlarged, in cross section with the schematic useful beam profiles of the laser beam (E). The individual optical fibers (91, 92, 93, 94) are through narrow retaining webs _. (95) connected to each other and thus held at a defined short distance from each other.

Figure 6 shows a plan view of the light guide tape (9), enlarged, with the useful beam path. The incident Laser light (E) and the light reflected from the ring wall (6) is partly scattered as flat by the cut (S) of the fiber as scattered light (SL) into the

_*

Fiber released that the angle of the total reflection on the fiber wall is undershot and light is guided to the ends of the light guide (91), where the light arriving there is evaluated.

FIG. 7 shows the control device (ST) in a block diagram. This consists of a program-controlled microprocessor (MP), which controls electrical circuits via an address bus (AB) and supplies the respective controlled circuit with data or receives data from it via a data bus (DB). The circuits external to the microprocessor (MP) are to be provided at the processing speeds which are customary today in order to achieve a sufficient processing speed which can be achieved with a thorough inspection of freely falling objects (B). If faster microprocessors (MP) are available at affordable prices, the functions of the external circuits can also be carried out in whole or in part directly in such processors.

The timing of the function sequence in the control device (ST) is carried out by an electronic clock generator (CD. This controls a time counter (CT), the upper digits of which control the four lasers (L1-L4) one after the other via a decoder (DI).

If there is no object (B) in the laser beam path, the direct laser light is picked up by the light guide band (9) and by the light guide bundle (90) emanating therefrom onto a direct light receiver (DL) conducted and there converted opto-electrically and amplified in a first amplifier (VI). The direct light signal (DL) obtained in this way is evaluated in a first threshold value comparator (S1), which emits gap signals (L1, L2) when the direct light is absent, which signals the presence of an object (B) in the laser beam path.

If an object (B) is present in the laser beam path, reflected light is generated, which is collected via the light guide bundle (30) and fed to the reflected light receiver (RL), whose opto-electrically converted signal is amplified in a second amplifier (V2) and then to one second threshold comparator (S2) is compared with a predetermined upper and a lower threshold (SO, SU). These respective threshold values (SO, SU) to be specified are successively given by the microprocessor (MP) via the data bus (DB) to a digital-to-analog converter, the analog output signals of which are stored in two holding circuits (HI, H2), and from there the second threshold comparator The output signal of the second comparator (S2) is a defect signal (SF) which indicates that the permissible brightness range between the predetermined limit values (SO, SU) is under or exceeded.

If the gap signal (L2) and the defect signal (SF) are present, a counting process is released in a counter (CT1), the counter content (Z) of which is therefore a measure of the size of the defects. The counter content (Z) is controlled by the microprocessor (MP) and compared via a computer unit (ALU) with predetermined comparison values stored in a register block (R1). If the limit value is exceeded the microprocessor (MP) gives control signals to the switch controller (50).

It is provided that it is checked whether either a single defect exceeds a maximum length or whether the number of defects or whether the sum of the defect lengths of an object or a segment, which were determined in a single scanning process of one of the laser beams, exceed other assigned upper limit values . The presence of an object during a segment scan is reported to the microprocessor (MP) by the beginning and the end of the gap signal (L1).

The described functions of this circuit arrangement can also be carried out with presettable counters instead of with a computer unit (ALU) and a register block (Rl), which are loaded with the upper limit values in some cases and which, after counting down during the fault signal at a zero crossing, are activated by the microprocessor (MP) deliver interrogable signal.

The microprocessor (MP) is connected in a known manner to an input device (E) for entering the limit values and comparison values and the program, and is equipped with a program and data memory. As a result, the device can be effortlessly adapted to the goods to be tested and the test conditions to adjust.

The direct light detection and the scattered light detection can also be carried out in each case with similar optical fiber devices, in particular with an optical fiber tape. Since the direct light produces a higher light yield at the receiver than the scattered light, the gap signal can also compensate Receiver signal such as the defect signal can be obtained by the receiver signal is fed to a further threshold switch with a high threshold voltage. As a result, only an optical fiber ribbon and an opto-electrical converter are required.

Furthermore, the entire scope of the object can be scanned with a reduced number of laser scanners if a mirror is arranged in a partial area of the scanner deflection which lies next to the test zone and directs the laser beam onto another peripheral segment of the object. Deflecting mirrors can also be arranged on both sides of the test zone, so that the object is scanned in a fan-like manner from three different basic directions during a scanner deflection cycle.

The scanner deflection mirrors are preferably controlled with linearly rising and falling currents in galvanometer coils, so that there is an approximately linear relationship between the duration of a defect signal and the extent of a defect. Accordingly, the counting of the time pulses during the duration of a defect signal yields a count result that corresponds directly to the defect size. If a linear deflection is chosen instead of a sinusoidal one, it is advisable to limit the linearity error so far that only the middle, somewhat linear, area cuts through the test zone. The deflection speed is expediently chosen so that an all-round object scanning, that is, the entire cyclical sequence of all laser scans takes place at a time in which the test object has traveled the falling distance in the test zone by a load beam thickness. As a result, the scanning strips adjoin one another. As an alternative to the sector-by-sector switching of the lasers, they can also be switched at the clock frequency, so that a punctiform scanning takes place all around, the points of a laser being spatially adjacent to one another if the deflection path corresponds approximately to the laser beam diameter during a laser follow-up cycle. This type of laser control requires a slower beam deflection frequency, which increases the life of the scanner. The fault location signals are then evaluated in the time-division multiplex in the counters assigned to the individual lasers. The counter contents obtained in this way are then evaluated in the manner described above.

It has proven to be advantageous to slightly incline the scanning planes of the different lasers in different directions against the movement direction of the objects and / or to arrange them slightly offset. This results in a favorable detection of the end faces of the object lying in the direction of movement, since they are each scanned by at least one laser at an oblique angle of incidence.

The device can also be easily configured in a professional manner in such a way that rolling objects are optically completely scanned by arranging at least two laser arrangements one behind the other in the direction of movement of the objects, offset by about half the object circumference. The light receivers or at least the optoelectrical transducers are advantageously used in common for both arrangements, which is why all the lasers are controlled in succession and the light guides are brought together. The scanning arrangements and the light detections enclose only a partial circle of a little over 180 °.

Claims

Godfather claims 1. Device for optically checking and sorting objects (B), in particular food, which are passed serially in free fall through a test zone (PZ), around which several light sources (4) and at least one reflected light receiver are arranged circumferentially, the light signals of which are opto -electrically converted in a control device (ST) with predetermined limit values (SO,, Sü) are compared, if these are exceeded or exceeded, a control signal is generated in a microprocessor (MP), which acts on a sorting switch (5) which is below the Test zone (PZ) is arranged, characterized in that the light sources (4) are each formed by a laser scanner, the deflection planes of which are essentially perpendicular to an object fall direction, and these laser light sources (4) cyclically one after the other for approximately one deflection period Detect the object's peripheral sector and that the light receivers (3) are optical fibers of an optical fiber bundle (30), the ends of which are fed to an opto-electrical reflected light converter (RL), the output signal of which, the reflected light signal (RS), is sent to the control device (ST). Comparison with the limit values (SO, SU) and a further evaluation is provided, and that a direct light receiver (9) is arranged on all sides around the test zone (PZ) at such a height that the laser scanner beams (Eil, E12; E2, E3) always hit this if they do not hit an object (B), and that this direct light receiver (9) leads to an opto-electrical direct light converter (DL), the direct light signal (DS) of which is fed to the control device (ST). 2. Device according to ^claim 1, characterized in that the optical fibers of the optical fiber bundle (30) are each directed with one fiber end (3) ^' radially to the test zone (PZ) and these fiber ends (3) of the optical fiber bundle (30) circumferentially around the Test zone (PZ) is arranged evenly distributed. 3. Device according to claim 2, characterized in that the light guide bundle (30) consists of 50 to 100 light guide fibers. . Device according to claim 2 or 3, characterized in that the optical fiber or the fiber ends (3) are vertically adjacent to and outside the deflection plane of the laser scanner (4) are arranged. 5. Device according to one of the preceding claims, characterized. that the laser light sources (4) are several laser scanners (4) which are switched on cyclically one after the other. 6. Device according to one of claims 1 to 4, characterized in that the laser scanner light directly scans the existing object (B) in a first peripheral sector in a first deflection area in the test zone (PZ) and in at least one further deflection area, via a mirror redirected, another object circumferential sector is scanned in the test zone (PZ). 7. Device according to one of the preceding claims, characterized in that the direct light signal (DS) is fed to a first threshold switch (Sl), -whose output signals serve as gap signals (Ll, L2) for an enabling control of the evaluation of the reflected light signal (RS) in the control device (ST). 8. Device according to claim 7, characterized in that the direct light receiver (9) consists of an optical fiber strip (9) made of optical fibers (91-94), which are arranged closely adjacent in parallel one above the other and have a bevel (S.) on the failure side of a directly irradiated laser light (E). ) exhibit. 9. Device according to claim 8, characterized in that the optical fibers (91 - 94) of the optical fiber strip (9) are held on the annular housing (6) surrounding it at such a distance that ^the optical fiber (91 - 94 ) bundled directly incident laser light (E) is focused on the reflective surface of the housing (6). 10. Device according to one of claims 7 to 9, characterized in that the optical fibers (91 - 94) have such a diameter and such a small distance that the directly incident laser beam (E) always at least one of the optical fibers (91 - 94) meets. 11. Device according to one of the preceding claims, characterized in that an annular housing (6) is arranged around the test zone (PZ), on the annular wall (6) of which the light guide bundles (30, 90) are held on the outside and the light guide strip (9) is held on the inside and the optical fiber ends (3) are guided radially through holes (66) in the ring wall (6). 12. ^' Device according to claim 11, characterized in that the laser scanners (4) are mounted on the outside of the ring wall (6) and the laser beams (Eil, E12; E2, E3) are passed through horizontal slots (40). 13. The device according to claim 12, characterized in that cooling air is blown into the housing of the laser scanner (4), which exits through the slots (40) into the test zone (PZ). 14. Device according to one of claims 11 to 13, characterized in that the housing (6) is closed by an annular cover (61) and an annular base (62) except for object passages to the test zone (PZ). 15. The device according to claim 14, characterized in that the annular wall (6) has steps (63, 64) on the end in which the cover (61) and the base (62) are held in a centering manner. 16. Device according to one of the preceding claims, characterized in that the reflected light signal (RS) is compared with the predeterminable upper limit value (SO) and the predeterminable lower limit value (SU) in such a way that a defect signal (SF) is always obtained from one Threshold comparator (S2) is emitted when the reflected light signal (RS) lies outside one of the limit values (SO, SU). 17. The device according to claim 16, characterized in that when the defect signal (SF) and no direct light signal (DS) is present, a counter (CT1) is supplied with clock pulses in a counting manner, whose counter contents (Z) can be read out controlled by a microprocessor (MP) and are transferred from and to the register block (Rl) assigned to the previously active laser (Ll - L4) in a register assigned to the respective active laser (Ll - L4). . 18. The device according to claim 17, characterized in that the direct light signal (DS) is compared in a threshold value comparator (Sl) with a predeterminable threshold value, if the value falls below at least one gap signal (Ll, L2) is emitted by the threshold value comparator (Sl). is used to control the counter (CT1) and to control the evaluations by the microprocessor (MP). 19. The device according to claim 17 or 18, characterized in that the counter contents (Z) are compared with this if a predeterminable minimum size is exceeded and if the microprocessor (MP) is exceeded, the sorting switch (5) is acted upon. 20. The device according to claim 18, characterized in that the counter contents (Z) are summed over a predetermined period of time in which the gap signal (L2) is present and this counter sum is compared with a predetermined maximum value, if this value is exceeded, the sorting switch (5 ) is acted upon by the microprocessor (MP). 21. The device according to claim 18, characterized in that the number of defect signals (SF) is counted over a predetermined period of time in which the gap signal (L2) is present and this number of defects is compared with a predetermined maximum number If this is exceeded, the sorting switch (5) is acted upon by the microprocessor (MP). 22. Device according to one of the preceding claims, characterized in that the scanning planes of the laser beams (Eil, E2, E3) are arranged differently inclined and / or offset relative to the direction of movement of the objects (B). 23. The device according to claim 22, characterized in that the objects (B) are guided in a rolling manner in front of and / or in the test zone (PZ) and at least two laser scanners (4) and light detection arrangements (3, 9) in the direction of movement of the objects (B ) are arranged offset by approximately half an object circumference and that the laser scanners (4) and the light detection arrangements (3, 9) each enclose a partial circle of over 180 ° circumferentially. 24. The device according to claim 23, characterized in that all laser scanners (4) are operated in time multiplex and the light capture arrangements (3, 9) are combined on only one optoelectric converter (RL, DL). 25. Device according to one of the preceding claims, characterized in that the laser scanners (4) are controlled cyclically one after the other with the clock cycle and the error location signal (SF) is accordingly connected to the counters (CT1) and/or registers assigned to the individual laser scanners (4). Register block (Rl) is evaluated. 26. The device according to claim 25, characterized in that the control of the laser scanner (4) takes place cyclically at least so quickly that the deflection of the Laser beam (Eil, E2, E3) has progressed by at most the thickness of the laser beam. 27. Device according to one of the preceding claims, characterized in that it is connected to the output of a peeling device (1), which is particularly suitable for potatoes, via a separator (12) and an output (22) of the device behind the sorting switch ( 5) is connected to a peeling machine feed shaft (10).