Patent Description:
It is known to provide public waste dumpsters with sensors, typically using ultrasonic or infrared technology, in order to determine the fill level of the dumpster and/or the volume of the delivered waste. The sensed data can be transmitted to an operations center, for example for the purpose of monitoring and planning the routes of vehicles adapted to empty the dumpsters as well as for the purpose of providing a spot pricing of the waste delivered by the individual user.

The present invention advantageously relates particularly to the latter application. <CIT> discloses an apparatus for the automatic classification of the volume of waste delivered into a dumpster, according to the preamble of claim <NUM>.

Some known systems of the above cited type, for example the system described in <CIT> in the name of this same Applicant, provide for calculating the volume of the delivered waste on the basis of the difference between the fill level measured before and after delivery.

Such systems, while being very accurate in determining the volume of the waste, have the drawback of being rather expensive to provide indeed because of said accuracy, which for many applications may be excessive compared to actual needs.

As is known, in fact, waste bags can be classified according to standard formats set by the local public administration [for example, <NUM> liters (small), <NUM> liters (medium), <NUM> liters (large), and <NUM> liters (oversized)], and in most cases it is only required to classify the waste delivered into the dumpster on the basis of the standard formats rather than determining its exact volume.

To this end, other known systems provide for detecting the volume of the bag on the basis of a tag associated with the bag, a bag which, therefore, must be of a special type.

Systems of this type meet the above cited classification requirement but have other drawbacks.

First of all, of course, the reliability of the system depends on the diligence of users in using only special bags fitted with tags, which moreover have a much higher cost than traditional bags, and in not throwing in loose waste, which the system cannot detect.

Moreover, also in order to promote the use of such special bags, it is advisable for the local administration to provide an efficient bag distribution system, with correlated logistical difficulties and costs.

An additional drawback of known systems is that the tags can easily become damaged during distribution and/or transport of the bags, whether empty or full, given the flexibility and lightness of the medium to which the tags are fixed (i.e., typically, the plastic sheet of which the bag is made). As is well known to the person skilled in the art, this circumstance considerably reduces the reliability of the system.

In addition to the drawbacks described above, it should be considered that depending on local regulations, the presence of the tag may cause the bag to become special waste, with consequent complications in relation to the planning and application of separate collection.

In view of the above, the aim of the present invention is to provide a method and an apparatus for the automatic classification of the format of waste delivered into a public dumpster equipped with sensors which overcomes the drawbacks cited above of known systems and in particular allows to classify the format of delivered waste with high accuracy and reliability, regardless of whether it is generic loose waste, a traditional waste bag, or a recovery bag of any format and in any state of preservation, all of the above with considerably reduced costs with respect to known systems.

Within this aim, an object of the invention is to provide a method and an apparatus that can be easily optimized, in terms of cost and detection accuracy, as a function of the different classifications provided by local administrations.

This aim and this object, as well as others that will become better apparent from the following description, are achieved by a method and an apparatus having the characteristics set forth in the accompanying independent claims, while the dependent claims define other advantageous, albeit secondary, characteristics of the invention.

The invention will now be described in greater detail, with reference to some preferred but not exclusive embodiments thereof, illustrated by way of non-limiting example in the accompanying drawings, wherein:.

With reference to <FIG>, a generic dumpster <NUM> provided with a lid <NUM> is adapted to hold a plurality of waste bags S1, S2, S3, S4 and of generic loose waste.

In <FIG>, the bags S1, S2, S3, S4 are of a standard format and have respective nominal volumes V1, V2, V3, V4, for example <NUM> liters, <NUM> liters, <NUM> liters, and <NUM> liters, respectively.

The dumpster <NUM> is provided with a plurality of optical sensors <NUM> placed in an elevated position that does not interfere with the area adapted to accommodate the waste. In this embodiment, the optical sensors <NUM> are placed proximate to the lid <NUM> and are functionally directed toward the bottom 10a of the dumpster <NUM>.

The optical sensors <NUM> are connected to a control unit CU programmed to detect the surface profile of the waste inside the dumpster <NUM> on the basis of the signals received from the optical sensors. The expression "surface profile," in the present description and in the claims, means the three-dimensional reconstruction of the overall surface of the mass of waste inside the dumpster that is detectable from above by means of the optical sensors <NUM>. Of course, this is an average profile estimated on the basis of the detections made.

As shown schematically in <FIG>, in a per se conventional manner, the optical sensors <NUM> may comprise an emitter 12E adapted to emit a light beam in the infrared range, and a receiver 12R adapted to receive the return light beam by reflection on the generic object located in front. The distance h from the object is calculated on the basis of the time elapsed between the emission of the light beam and its reception.

Advantageously, it is possible to use sensors based on the technology known as ToF (Time of Flight), provided with a low-power laser emitter with a wavelength of <NUM> having a grid of <NUM>×<NUM> sensors of the SPAD (Single Photon Avalanche Diode) type. This grid allows to derive one or more distance measurements (which in turn are derived from a subset of adjacent SPADs with a minimum size of 4x4). By way of example, commercial sensors of this type are the VL53L1, VL53L3, VL53L5 models (and their submodels) manufactured by STMicroelectronics NV.

In a per se known manner, the dumpster <NUM> can also be equipped with a mechanized hatch <NUM> associated with an authentication system ID which uses per se conventional technologies, for example Radio Frequency IDentification (RFID), Near Field Communication (NFC), alphanumeric codes, bar codes, QR codes, and the like. The user, by authenticating via the authentication system ID, causes the hatch <NUM> to open so that he can deliver the waste.

As shown in <FIG>, in this embodiment the optical sensors <NUM> are distributed on a horizontal plane along longitudinal rows and transverse rows which are equally spaced by an interval d so as to form an array.

Advantageously, the optical sensors <NUM> may be incorporated into a plurality of electronic devices of the type described in <CIT> in the name of the same Applicant, wherein each of the devices may include, for example, a longitudinal row of optical sensors <NUM>.

In the classification method according to the invention, the control unit CU is programmed to:.

In a per se known manner, the format information generated as above may be stored by the control unit CU for later retrieval by an operator, or (if the control unit CU is provided with a communication system) transmitted directly to a central unit (not shown), for example for the purpose of spot pricing.

It should be noted that in the method according to the invention, the preset threshold values are numerical data that can be determined experimentally and normally will not correspond to the nominal volumes of the standard bags according to the classification adopted.

Merely by way of example, if the local classification provides for the formats of <NUM> liters (small), <NUM> liters (medium), <NUM> liters (large) and <NUM> liters (oversized), the threshold values converted to liters may be <NUM>, <NUM>, <NUM> and <NUM>, respectively.

It is evident that the greater the number of sensors <NUM>, the more accurate the datum obtained will be. However, increasing the number of sensors inevitably leads to an increase in cost, which for many applications may be unjustified.

In order to further minimize the number of sensors required to recognize the format to which the delivered waste belongs, the density of sensors in relation to the chosen spatial distribution (which density, in the example described here, is directly correlated to the interval d between the longitudinal and transverse rows of sensors) is advantageously determined in a preliminary learning and calibration procedure which comprises the following steps:.

In the embodiment described here, the learning and calibration procedure provides for performing a first detection starting from an empty configuration of the dumpster (<FIG>) and then, for each bag format, a series of successive detections by placing the bag S in different positions on the bottom 10a of the dumpster <NUM> (<FIG>).

New measurements are then made with the bag in a raised position relative to the bottom 10a of the dumpster, for example on a platform <NUM> appropriately adapted for the purpose (<FIG>).

The same method is then repeated with the bag positioned at increasingly greater heights from the bottom, until a situation corresponding to a substantially complete filling level of the dumpster <NUM> is achieved.

The greater the number of detections made in different positions, the greater the accuracy of the statistical datum that can be inferred.

Once such detections have been performed, a statistical distribution curve is derived for each bag format, for example a Gaussian curve (<FIG>), and then the Gaussian curves related to the various formats are compared.

Should the Gaussian curves related to the various formats have excessive overlaps (<FIG>), it will be necessary to increase sensor density (i.e., reduce the interval d between sensors in the example described here), since the system is unable to discriminate between the various formats S1, S2, S3 and S4.

If, on the contrary, the Gaussian curves are found to be too far apart (<FIG>), sensor density can be reduced (i.e., the interval between sensors in the example described here can be increased) until the tolerable error threshold mentioned above is reached.

It has been found that with the calibration procedure described above, the interval d between the sensors distributed on a flat array as in the embodiment described here is correlated to the nominal volumes Vn of the n bag formats according to the relation <MAT> wherein <MAT> where <MAT> while <MAT>.

In the above formulas, Cd is a first coefficient comprised between <NUM> and <NUM>, while Cr is a second coefficient comprised between <NUM> and <NUM>.

In practice, dd is determined by calculating the value of Fn for each pair of consecutive bags in terms of nominal volume (in the above example, the first pair is constituted by the <NUM>-liter and <NUM>-liter bags, the second pair is constituted by the <NUM>-liter and <NUM>-liter bags, and the third pair is constituted by the <NUM>-liter and <NUM>-liter bags) and then selecting the minimum value from those calculated. Regarding dr, V<NUM> is the nominal volume of the next largest bag with respect to the standard minimum format (<NUM> liters in the example described above).

It has been found in practice that, with reference to the most common applications, the interval d is normally comprised between <NUM> and <NUM>.

Advantageously, the standard minimum bag format is a datum that can be stored in the control unit CU for the purpose of the minimum charge to be attributed to delivered waste. That is to say, any waste with a volume smaller than the minimum standard format will still be treated as a minimum standard format bag.

As the person skilled in the art will be able to appreciate, the method according to the invention, even more so in view of the preliminary learning and calibration procedure described above as particularly advantageous, makes it possible to classify with high accuracy the format that is to be assigned to the delivered waste, minimizing the number of sensors (with consequent cost containment) and without making an accurate measurement of the actual volume of the waste.

Moreover, the apparatus can be optimized on the basis of the specific classification adopted by the local administration, simply by varying the interval between the sensors.

Advantageously, the connections between the sensors <NUM>, the authentication system ID, and the control unit CU are provided by wireless technology, for example Bluetooth®, simplifying both the installation and the adaptation of the arrangement of the sensors <NUM> on the basis of the classification adopted by the local administration.

Moreover, as the person skilled in the art will appreciate, the elimination of wiring is particularly advantageous both in terms of cost and in relation to the specific application discussed here, since it makes the system less susceptible to damage and wear.

A preferred embodiment of the invention has been described, but the person skilled in the art may of course make several modifications and variations within the scope of the claims.

For example, the sensors could be distributed again on a flat array but spaced differently in the axial and transverse directions.

In another example, the sensors could have a spherical sector-like arrangement, in which the spacing between the sensors in the radial and/or angular direction can be varied during the learning and calibration procedure in order to optimize the operation of the system, as described above.

Claim 1:
A method for the automatic classification of the format of waste delivered into a public dumpster (<NUM>) provided with a plurality of optical sensors (<NUM>) which are arranged in an elevated position which does not interfere with the area adapted to accommodate the waste and are directed functionally toward the bottom (10a) of the dumpster (<NUM>), a control unit (CU) being programmed to detect the surface profile of the waste in the dumpster (<NUM>) on the basis of the signals received from said optical sensors (<NUM>), wherein said control unit (CU) is programmed to:
- calculate a volumetric datum on the basis of the difference between the surface profile of the waste detected after delivery and the surface profile detected before delivery,
- compare said calculated volumetric datum with threshold values which are preset on the basis of specific standard formats,
- on the basis of said comparison, associate the delivered waste with the corresponding format, and
- generate corresponding format information for subsequent processing.