EP1560164A1 - Method and system for the verification of a mailing's height in order to frank it - Google Patents

Abstract

The method involves detecting presence of a mail article with respect to a given point of reference surface, at distances (d1, d2) near and away from the surface. The distance (d2) corresponds to dimensional threshold. Ratio of presence durations (t1, t2) of the article is compared with a value, by a comparing module (33). Height of the article is considered greater than the threshold if the ratio is greater than the value. The value is equal to 1-~I, where epsilon represents a corrector coefficient lower than 1 depending on detection tolerances of presence of the article. An independent claim is also included for a system of determining mails postage amount, including a mail article height verifying device.

Description

The present invention relates to the field of mail processing. In particular, it relates to a franking system that includes a simple device for ascertaining the height H _i of a mail piece with respect to at least one dimensional threshold SH defining a postal rate arrangement.

We already know, for example, by US document 6,006,210 (Pitney Bowes) a mail processing machine with a possibility of dimensional pricing.

This machine provides a true measure of the height of mail item via a diode array. This apparently simple solution is however extremely expensive in practice. Indeed, it supposes both the use of a bar of length and means to ensure that the mail item be perfectly "teased", that is to say that it is not crooked by relative to the reference face of the machine.

In practice, except for the use of other Generally complex positioning, it turns out that a biased bias often occurs and its magnitude depends on the nature of the machine and that of the conveyed article.

Also known from the US Patent 6,169,978 (Siemens) a sophisticated system for determining the dimensions of the article transported in order to allocate a specific amount of postage. This system also assumes that all items conveyed are well positioned, referenced. Otherwise, the measures dimensional would be wrong and the postage values too.

The present invention aims to remedy the aforementioned drawbacks and to allow verification on the fly of the height H _i of a mail piece for franking purposes, without the need to proceed to the exact measurement of this height H _i nor to position the mail piece in a perfectly "stuck" manner, that is to say in a position strictly parallel to the reference surface of the machine from which the checks or measurements are made.

The invention thus aims to implement a simple method and to achieve an economical and yet reliable device that allows, without use of complex technical devices, to easily determine and on the fly the category of postal tariff to which must belong an article of mail, depending on the value of a given dimension, such as height, of this article of mail.

These objects are achieved in accordance with the invention by means of a method of verifying the height H _i of a mail piece for franking purposes and with respect to at least one dimensional threshold SH defining a postal rate change. each mail piece having longitudinal peripheral edges of length D _i and transverse peripheral edges of height H _i , which method is characterized in that the mail items are circulated at a constant speed V along an reference surface such that each article is in contact with said reference surface, at least on a portion of one of its longitudinal edges, in that the presence of an article with respect to a point is detected given the reference surface, on the one hand at a first distance d1 close to the reference surface perpendicular to it, and secondly to a second distance d ₂ remote of the reference surface perpendicular thereto and corresponding to said dimensional threshold SH, in that the first and second periods of presence t ₁ , t ₂ of the same article are detected at said first and second distances d ₁ , d ₂ with respect to the reference surface, in that the ratio t ₂ / t ₁ of the second and first durations of presence at the second distance d ₂ and the first distance d ₁ are compared to a value equal to (1-ε) where ε represents a correction coefficient lower than 1 depending on the detection tolerances of the presence of an article, and in that it is considered that the height H _i of an article is greater than the dimensional threshold SH if, and only if, the relation t ₂ / t ₁ > 1-ε is satisfied.

Advantageously, the coefficient ε can be between about 0.005 and 0.05, and preferably about 0.01.

It is also possible to determine the length D _i of an article from the duration of presence t1 and the speed of movement V of the articles.

According to the invention, there is specially provided a device for verifying the height H _i of a mail piece for franking purposes with respect to at least one dimensional threshold SH defining a postal rate change, each item of mail having longitudinal peripheral edges of length D _i and transverse peripheral edges of height H _i , which device is characterized in that it comprises a conveyor for flat transport of mail items at a constant speed V along a guide defining a reference surface parallel to the direction of movement of the mailpieces placed on the conveyor, jogging means for placing each article in contact with said reference surface at least on a part of one of its longitudinal edges, a first detection device made active when detecting the presence of an article with respect to a given point of the surface of r preferably at a first distance d ₁ close to the reference surface perpendicularly thereto, at least one second detection device made active when detecting the presence of an article with respect to a given point of the reference surface at a second distance d ₂ away from the reference surface perpendicularly thereto and corresponding to said dimensional threshold SH, a counting device of the first and second durations t ₁ and t ₂ during which the first and second detection devices are rendered active during the passage of an article and a calculating and comparing device for calculating the ratio t ₂ / t _{1 of} said second and first durations t ₂ , t ₁ , comparing this ratio t ₂ / t ₁ to an equal threshold value at (1-ε) where ε represents a correction coefficient lower than 1 depending on the detection tolerances of the presence of an article and to provide information that the high ur H _i of an article is greater than the dimensional threshold SH if, and only if, the relation t ₂ / t ₁ > 1-ε is verified.

The coefficient ε is preferably between about 0.005 and 0.05, and preferably close to 0.01.

The first and second detection devices can understand optical sensors.

According to a particular embodiment, the device for counting comprises at least one optical encoder.

The device may further comprise a device for calculating the length D _i of an article from the first duration of presence t ₁ and the speed V of movement of the articles.

The invention also relates to a system for determining the postage franking amount, comprising a device for measuring the weight and dimensions of mailpieces, with a device for verifying the height H _i of an article of mailpiece. mail as defined above.

• la figure 1 est une vue schématique de dessus montrant le principe d'un procédé et d'un dispositif de vérification au vol de dimensions d'un article de courrier à des fins d'affranchissement qui mettent en oeuvre l'invention ;
• les figures 2 à 5 montrent différents exemples de détermination des dimensions d'un article de courrier selon le procédé conforme à l'invention ;
• la figure 6 est un schéma-bloc montrant les éléments principaux d'un exemple de circuit de traitement pouvant être incorporé dans le dispositif selon l'invention ; et
• la figure 7 est un organigramme montrant un exemple de diverses étapes mises en oeuvre dans le procédé de vérification au vol de la hauteur d'un article de courrier selon l'invention.

Other characteristics and advantages of the invention will emerge from the following description of particular embodiments, given by way of example, with reference to the appended drawings, in which:

• Figure 1 is a schematic top view showing the principle of a method and a device for verifying the dimensions of a mail piece for postage purposes which implement the invention;
• Figures 2 to 5 show different examples of determining the dimensions of a mail piece according to the method according to the invention;
• Figure 6 is a block diagram showing the main elements of an exemplary processing circuit that can be incorporated in the device according to the invention; and
• Figure 7 is a flowchart showing an example of various steps implemented in the method of checking theft of the height of a mailpiece according to the invention.

The pricing of mail items is based on criteria of weight and size of the folds (thickness, length of the envelope, height of the envelope).

• soit de vérifier que les dimensions de l'enveloppe sont supérieures à des seuils,
• soit de vérifier que le rapport entre la longueur et la hauteur est compris entre deux limites (exemples : 1,3 < R < 2,5 pour les USA, R < racine carrée de 2 pour l'Allemagne).

It's about :

• verify that the dimensions of the envelope are greater than thresholds,
• or to check that the ratio between length and height is between two limits (examples: 1.3 <R <2.5 for USA, R <square root of 2 for Germany).

To automatically assign the appropriate tariff for each fold in a non-homogeneous batch, there is a machine upstream franking, a device that measures the weight and dimensions of each envelope, and transmits this information to a tariff calculator. The Measurements of the dimensions are then made by suitable sensors in the routing of the envelopes between the feeder and the base postage.

According to the invention, the verification of the height H ₁ , respectively H ₂ , of an envelope 1, respectively 2, with respect to a predefined threshold SH can be carried out in a very simple way since an envelope 1, respectively 2 , disposed flat on a belt 6 of a conveyor moving at a constant speed V in the direction of the arrow F of FIG. 1, is at least partially pressed against a fold guide K having a reference surface 5 parallel to the direction of movement of the envelopes 1, 2, that is to say that means are provided for placing each article 1, respectively 2, in contact with the reference surface 5 at least on a part of one of the longitudinal edges of length D ₁ , respectively D ₂ .

It should be noted that if the invention requires a minimum jogging on a part of the length of a mail piece, on the other hand, she allows to solve, without using mechanical means of repositioning of envelopes, the problem of envelopes which, in practice, are not rigorously positioned, but are slightly crooked, as shown in Figures 4 and 5, without however, that the bias is too marked. In practice, the invention takes envelopes whose longitudinal edges can form a angle α of the order of 0 to 5 ° with the reference surface 5, whether for 3-sided envelopes whose rear edge is farthest of the reference surface (Figure 4) or for skewed envelopes 3 whose leading edge is furthest from the reference surface 5 (Figure 5).

The determination of the dimensions of the envelopes 1, 2, 3 (FIGS. 1 to 5), that is to say the length D ₁ , D ₂ , D ₃ , as well as the determination that the height H ₁ , H ₂ , H ₃ is greater than or less than at least one threshold SH, can be done in a simple manner using measuring devices which can be constituted by simple sensors C ₁ , C ₂ changing state when an envelope passes at their level.

It can thus be seen that in FIG. 1, the envelope 1 is about to pass at the level of the two sensors C ₁ , C ₂ placed at a fixed station opposite the travel path of the conveyor belt 6, while the envelope 2 of height H ₂ smaller than the height H ₁ of the envelope 1 will then pass only at the level of the sensor 1.

The sensors C ₁ and C ₂ are placed with respect to a given point 7 of a line of the reference surface 5 perpendicular to the belt 6 of the conveyor, respectively at a distance d ₁ close to the reference surface 5, perpendicular to it, and at a distance d ₂ away from the reference surface 5, perpendicular to it and corresponding to a dimensional threshold SH relative to which it is desired to determine if the height H ₁ , H ₂ , H ₃ of a mail item 1, 2, 3 is or is not superior.

Regarding the height (or width) of a document 1, 2, 3, it is not a matter of actually measuring that magnitude, but of determine whether or not this magnitude is greater than the predefined threshold SH.

An envelope 1, 2 or 3 during its course on the strip 6 passing in front of the reference surface 5 passes to the first sensor C ₁ which triggers itself, when it detects an envelope presence, the count of pulses resulting for example from an optical coder the number of pulses, that is to say the duration t ₁ during which the sensor C ₁ detects the presence of an envelope, makes it possible inter alia to deduce the length D ₁ , D ₂ , D ₃ of document 1, 2 or 3, since the constant speed V of displacement of the strip 6 is known.

When the sensor C2 detects the presence of an envelope 1, 2 or 3, this sensor C ₂ triggers in the same way the counting of pulses from for example an optical encoder the number of pulses, that is to say say the duration t ₂ during which the sensor C ₂ detects the presence of an envelope, makes it possible to define a length L ₂ for masking the sensor C ₂ by an envelope 1, 2 or 3, and especially in combination with the duration t ₁ (or length L ₁ ) to reliably determine whether an envelope actually has a height H _i greater than the predefined threshold SH.

The comparison of the durations t ₂ and t ₁ (or lengths L ₂ and L ₁ ) determined from the detection of the activation of the sensors C ₁ and C ₂ makes it possible to verify that the exceeding of the threshold is not due. a bad positioning of an envelope that would be crooked.

It is therefore important to ensure that the value t ₂ is close to the value t ₁ (or the value L ₂ close to the value L ₁ ).

The ratio t ₂ / t _{1 is} thus compared with a value equal to 1-ε where ε represents a correction factor less than 1 depending on the tolerances of the detectors C ₁ , C ₂ and the dimensions of the envelopes of the same format, and considers that the height H _i (for example H ₁ , H ₂ , H ₃ ) of an article (for example 1, 2, 3) is greater than the threshold SH if, and only if, the relation t ₂ / t ₁ > 1-ε is verified.

The value ε can be advantageously of the order of 0.01, but can also depending on the case be between about 0.005 and 0.05.

As noted above, exceeding one SH threshold in many cases leads to a change of tariff for the amount of postage to be applied, regardless of the weight the mail item weighed or estimated.

It is thus important that the threshold SH is not artificially considered as exceeded because of a cross positioning which causes the temporary activation of the sensor C ₂ .

The fact of detecting the height H (or width) of a mail article by monitoring the activation of the sensor C ₂ continuously over a period of time makes it possible to guarantee, by comparison with the same tracking performed on the activation of the sensor C ₁ , to ensure that the threshold is effectively exceeded.

For example, if an envelope 3 is angled at an angle α (FIGS. 4 and 5), with a tolerance coefficient ε = 0.01, if t ₂ / t ₁ <at, 99 the threshold SH will be considered not exceeded while a system of measurement or envelope width estimation of the state of the art, would have estimated otherwise. Indeed, the lower point P farthest from the reference surface 5 of the fold guide 4 is actually at a distance greater than SH from the reference surface 5 (jogging). Taking into account the detection by the sensor C ₂ (optical concealment) of this width or height H ₃ over the entire length D ₃ of the mail article is a way of verifying the exceeding of the threshold. The same approach applies for each additional threshold SH _i which can be chosen with each time a sensor C _i similar to the sensor C ₂ disposed at the distance d _i corresponding to the threshold SH _i with respect to the point H of the reference surface. 5.

FIG. 2 shows an example where an envelope 2 is suitably jogged along the reference surface 5 and has a height H ₂ less than SH. In this case, the sensor C ₂ is never activated and the device emits a value L ₂ = 0, whereas the sensor C ₁ serves to provide a value L ₁ defining the length D ₂ of the envelope 2.

FIG. 3 shows an example where an envelope 1 is suitably tapped along the reference surface 5 and has a height H ₁ greater than SH. In this case, the sensor C ₂ is activated for a duration t ₂ corresponding to a masking length L ₂ equal to the masking length L ₁ determined from the activation of the sensor C ₁ . The device transmits the information that the height H ₁ is greater than the threshold SH and the sensor C ₁ serves to provide a value L ₁ defining the length D ₁ of the envelope 1.

The case of FIGS. 4 and 5, where an envelope 3 is angled with respect to the reference surface 5 has been previously described and it has been seen that the envelope 3 has been considered to have a height H ₃ lower than the threshold SH , although the sensor C ₂ was activated for a time corresponding to a masking length L ₂ , since these values t ₂ and L ₂ were much lower than the values t ₁ and L ₁ determined from the sensor C ₁ .

The sensor C _1, however, makes it possible to satisfactorily determine the length D ₃ of the envelope 3 from the quantity L ₁ by giving the length D ₃ the value of the quantity L ₁ , since the angle α is low and does not exceed about 5 °.

Whether the envelopes 1, 2, 3 are slightly through, the device according to the invention makes it possible to determine in flight their length and to check their height with respect to a predefined threshold SH, without the need to mechanically straighten the envelopes of where they have been partially stamped against the reference surface 5 of the fold guide 4.

With reference to FIG. 6, an example circuit of FIG. treatment that can be implemented within the framework of the device according to the invention.

Modules 11, 12 respectively detect the activation of the sensors C ₁ and C ₂ . Here, activation is defined as the state of the sensors C ₁ and C ₂ when a mail item passes in their vicinity and, for example, in the case of optical sensors, interrupts a light beam emitted by the sensors.

The modules 11, 12 sensitive to the activation of the sensors C ₁ and C ₂ respectively control a unit 31 for managing counters 21, 22 which themselves deliver information t ₁ and t ₂ respectively corresponding to the duration of presence of a same article of mail next to the sensors C ₁ and C ₂ respectively.

The data t ₁ and t ₂ are applied to a module 32 for calculating the ratio t ₂ / t ₁ , which ratio t ₂ / t ₁ is applied to a module 33 for comparing the ratio t ₂ / t ₁ with a value 1 ε. The output of the module 33 is applied to a module 36 providing the information according to which the height H _i of the mail article is or not greater than a predetermined threshold SH. A module 35 also performs the calculation of the masking length L ₁ (to which the length D _i of the envelope corresponds) from the value t 1 coming from the counter 21 and from the value of the speed V of displacement of the belt 6 of the conveyor.

An example of data processing according to the method according to the invention will be explained with reference to the flowchart of the figure 7.

A test 101 examines whether the sensor Ci is activated. If it is not the case, there is a return to the entry of this test 101. If the sensor is activated, it proceeds to step 102 of starting the counting of the duration of the activation of the sensor C ₁ then a test 103 examines whether the sensor C ₁ is still activated. When the test 102 detects the end of the activation of the sensor C ₁ , proceed to step 104 of stopping the counting of the duration of the activation of the sensor C ₁ , then to the step 105 of determining the value L ₁ in step 106 of resetting the counter associated with the sensor C ₁ . The output of step 106 is connected to the input of test 101 to reset the process.

The output of the test 101 is further connected to a test 107 which examines whether the sensor C ₂ is activated. If this is not the case, a test 108 is applied to examine whether the end of the counting of the activation duration of the sensor C ₁ has occurred. If so, a step 109 determines that the value L ₂ is zero. If no, there is a return to the entry of test 107.

If the test 107 detects the activation of the sensor C ₂ , it proceeds to a step 110 of starting the counting of the activation duration of the sensor C ₂ . Then, a test 111 examines whether the sensor C ₂ is still activated. If the sensor C ₂ is no longer activated, it proceeds to a step 112 of stopping the count of the duration of the activation of the sensor C ₂ , then to a step 113 of the determination of the value L ₂ and to a step 114 of resetting the counter associated with the sensor C ₂ . The outputs of steps 105, 107, 113 are connected to the input of a step 115 for calculating the ratio L ₂ / L ₁ . Then, we go to a test 116 to examine whether L ₂ / L ₁ > SH. If yes, step 117 displays H>SH; if not, step 118 displays H = 0.

Furthermore, the output of step 106 is connected to the input of the test 101 to reset the process after processing an item from mail.

The invention applies to a system for determining the amount of postage mail including a device for measuring the weight and dimensions of mail items, and in which is incorporated a verification device in flight of the height H _i an article of mail as described above. The device for measuring the weight of the flight may be arranged upstream or downstream of the verification device in flight from the height of a mailpiece.

Claims (9)

A method of verifying the height H _i of a mail item (1, 2, 3) at least one dimensional threshold SH defining a postal rate change, each mail piece (1, 2, 3) comprising longitudinal peripheral edges of length D _i and transverse peripheral edges of height H _i ,
characterized in that the mailpieces (1, 2, 3) are circulated at a constant speed V along a reference surface (5) in such a manner that each article is in contact with said reference (5) at least on a portion of one of its longitudinal edges, in which the presence of an article with respect to a given point (7) of the reference surface (5) of a part at a first distance d1 close to the reference surface (5) perpendicularly thereto, and secondly at a second distance d2 distant from the reference surface (5) perpendicular to it and corresponding to said dimensional threshold SH, in that first and second periods of presence t ₁ , t ₂ of the same article are detected at said first and second distances d ₁ , d ₂ with respect to the reference surface (5), in that the ratio t ₂ / t ₁ of the first and second durations of presence is compared with the second distance d ₂ and at the first distance d ₁ to a value equal to (1-ε) where ε represents a correction coefficient lower than 1 depending on the detection tolerances of the presence of an article, and in that one considers that the height H of an article is greater than the dimensional threshold SH if, and only if, the relation t ₂ / t ₁ > 1-ε is satisfied. Process according to Claim 1, characterized in that the coefficient ε is between approximately 0.005 and 0.05 and preferably close to 0.01. A method according to claim 1 or claim 2, characterized in that the length D _i of an article is further determined from the time of presence t _i and the speed of movement V of the articles. Device for verifying the height H _i of a mail article (1, 2, 3) for franking purposes with respect to at least one dimensional threshold SH defining a postal rate change, each article of mail ( 1, 2, 3) having longitudinal peripheral edges of length D _i and transverse peripheral edges of height H _i ,
characterized in that it comprises a conveyor (6) for flat transport of mail items (1, 2, 3) at a constant speed V along a guide (4) defining a parallel reference surface (5). in the direction of movement of the mailpieces (1, 2, 3) placed on the conveyor (6), jogging means for placing each article in contact with said reference surface (5) at least on a part of the one of its longitudinal edges, a first detection device (C ₁ , 11) made active when detecting the presence of an article with respect to a given point (7) of the reference surface (5) at a first distance d1 close to the reference surface (5) perpendicular to it, at least one second detection device (C ₂ , 12) made active when detecting the presence of an article with respect to a given point (7 ) from the reference surface (5) to a second distance d ₂ away from the reference surface (5) perpendicular thereto and corresponding to said dimensional threshold SH, a device (21, 22, 31) for counting the first and second durations t1 and t2 during which the first and second devices (C ₁ , 11, C ₂ , 12) are made active during the passage of an article and a device (32, 33, 34) for calculating and comparing to calculate the ratio t ₂ / t _{1 of} said second and first durations (t ₂ , t ₁ ), compare this ratio t ₂ / t ₁ to a threshold value equal to (1-ε) where ε represents a correction coefficient lower than 1 depending on the detection tolerances of the presence of an article and to provide information according to which the height H _i of an article is greater than the dimensional threshold SH if, and only if, the relation t ₂ / t ₁ > 1-ε is satisfied. Device according to Claim 4, characterized in that the coefficient ε is between approximately 0.005 and 0.05 and preferably close to 0.01. Arrangement according to Claim 4 or Claim 5, characterized in that the first and second detection devices (C ₁ , 11, C ₂ , 12) comprise optical sensors (C ₁ , C ₂ ). Device according to any one of claims 4 to 6, characterized in that the counting device (21, 22, 31) comprises at least one optical encoder. Device according to any one of claims 4 to 7, characterized in that it further comprises a device (35) for calculating the length D _i of an article from the first duration of presence t _i and the speed V of movement of articles (1, 2, 3). Mail postage amount determination system, comprising a measuring device, the weight and dimensions of mailpieces, characterized in that it comprises a device for checking the height H _i of an article mail according to any one of claims 4 to 8.

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