CN115761975B - Banknote counting method - Google Patents

Abstract

The application relates to the technical field of banknote processing, in particular to a banknote counting method, which utilizes a banknote counting module (CS), an identification module (BV), a core channel (TP) and a temporary storage module (TS) in a deposit core to rapidly identify and count banknotes, wherein the banknote counting module (CS) comprises four groups of sensors with the numbers of U1, U2, U3 and U4 arranged at a banknote inlet of the core, wherein the banknote inlet is separated into a banknote storage port and a banknote rejection port by a middle push plate of the banknote counting module (CS); a D1 sensor is arranged on a channel between the banknote counting module (CS) and the identification module (BV), a D2 sensor is arranged on the identification module (BV), a D3 sensor is arranged on the movement channel (TP), and a storage box (RB) and a recovery box (AB) are arranged below the movement channel (TP). The application can optimize the banknote counting flow, shorten the single business processing time, improve the business handling efficiency of the bank and bring good use experience to the user.

Description

Banknote counting method

Technical Field

The application relates to the technical field of banknote processing, in particular to a banknote counting method.

Background

The self-service financial equipment is generally used in a bank hall or is independently distributed in a mall or a street, the self-service machine equipment of the prior banking website is very advanced, besides the conventional cash depositing and withdrawing integrated machine, the self-service non-cash equipment of super teller such as a self-service intelligent terminal, an STM (secure messaging service), a VTM (virtual machine) and the like is commonly used, the equipment can replace more than 80% of the business of a bank counter, and the general business such as transfer, inquiry, printing, card opening, decryption, loss reporting, large deposit bill, financial purchasing and the like can be transacted on the self-service non-cash equipment, so that the counter pressure of the bank is greatly relieved.

Taking a conventional cash recycling machine as an example, in the process of executing deposit, the conventional self-service equipment transfers one banknote to a corresponding storage module (a temporary storage port or a banknote rejecting port) after identifying and judging the fact that the banknote is true, then identifies and transfers the next banknote, and circulates until the last banknote is processed; the total time for processing one business is determined according to the number of deposited banknotes multiplied by the processing time of a single banknote, if the number of banknotes is large, the time cost for the single business is high, so that the business efficiency of the bank is reduced, and meanwhile, bad use experience is brought to the user.

Disclosure of Invention

In order to solve part or all of the technical problems, the application provides a banknote counting method which can optimize banknote counting flow, shorten single business processing time, improve business efficiency of banks and bring good use experience to users.

The invention provides a banknote counting method, which utilizes a banknote counting module (CS), an identification module (BV), a core channel (TP) and a temporary storage module (TS) in a deposit core to rapidly identify and count banknotes, wherein the banknote counting module (CS) comprises four groups of sensors with the numbers U1, U2, U3 and U4 arranged at a banknote inlet of the core, wherein the banknote inlet is separated into a banknote storage port and a banknote rejection port by a middle push plate of the banknote counting module (CS); a D1 sensor is arranged on a channel between the banknote counting module (CS) and the identification module (BV), a D2 sensor is arranged on the identification module (BV), a D3 sensor is arranged on the movement channel (TP), and a storage box (RB) and a recovery box (AB) are arranged below the movement channel (TP); the method comprises the following steps:

s1: the equipment is electrified and initialized, a middle push plate of a banknote counting module (CS) moves to a position close to a U3 sensor under the action of a push plate motor, and a front push plate of the banknote counting module (CS) moves to a position close to a U4 sensor under the action of the push plate motor so as to be convenient for placing banknotes in a banknote inlet;

s2: the method comprises the steps of placing a banknote into a banknote inlet, specifically into a banknote storage inlet, then executing a banknote counting instruction issued by a controller, enabling all channels of the whole machine core to start running at the moment, and entering a rapid banknote counting process;

S3: based on the step S2, specifically, the middle push plate moves towards the direction of the banknote friction mechanism close to the banknote counting module (CS) under the action of the push plate motor, and pushes the banknote to synchronously move towards the direction of the banknote friction mechanism until the U2 sensor is shielded by the banknote, at the moment, the U2 sensor sends a signal to the controller, the controller controls the banknote friction motor of the banknote friction mechanism to start rotating to rub the banknote, and the first banknote is rubbed into the banknote friction channel;

s4: in step S3, after the first bill is rubbed into the bill rubbing channel, the number of bills at the bill storing port is reduced, the pressing force of the middle push plate on the bills is loosened, at the moment, the controller synchronously controls the push plate motor to rotate while controlling the bill rubbing motor to rotate, the middle push plate is pushed to drive the rest bills to continuously move towards the direction close to the bill rubbing mechanism until the U2 sensor is continuously shielded until the U2 sensor is not shielded, the U1 sensor is shielded, and the state indicates that all the bills placed in the bill storing port are rubbed into the bill rubbing channel;

S5: in step S3, after the first banknote is rubbed into the banknote rubbing channel, when the first banknote moves to the position of the D1 sensor and the D1 sensor is blocked, the D1 sensor sends a request for identifying the authenticity of the banknote to the identification module (BV), and when the first banknote continues to move to the position of the D2 sensor and the D2 sensor is blocked, the D2 sensor sends an instruction for executing the identification of the authenticity of the banknote to the identification module (BV), and at this time, the identification module (BV) starts to acquire the image of the banknote to identify the authenticity of the banknote;

S6: based on the step S5, the first banknote after being identified by the identification module (BV) continues to move to the machine core channel (TP), when the first banknote moves to the position of the D3 sensor and shields the D3 sensor, the D3 sensor sends a signal to the controller, the controller receives the banknote identification result fed back by the identification module (BV), analyzes the identification result, and controls the switching direction of the reverser at the tail end of the machine core channel (TP) according to different identification results so as to determine the final trend and storage position of the banknote;

S7: based on step S6, when the identification result of the first banknote is true banknote, the controller controls the reverser to switch to the lower channel (also referred to as banknote feeding channel) of the movement channel (TP), so that the banknote feeding channel of the movement channel (TP) is conducted, and the first banknote enters the temporary storage module (TS) through the banknote feeding channel;

S8: based on step S6, when the identification result of the first banknote is false banknote, the controller controls the diverter to switch to the upper channel (also called banknote rejecting channel) of the movement channel (TP), so that the banknote rejecting channel of the movement channel (TP) is conducted, and the first banknote enters the banknote rejecting port of the banknote counting module (CS) through the banknote rejecting channel;

S9: based on step S4, after the remaining bank note is pressed by the middle push plate again, the middle push plate pushes the remaining bank note to continuously move towards the direction close to the bank note rubbing mechanism under the action of the push plate motor, and as the bank note rubbing motor of the bank note rubbing mechanism always rotates, the second bank note and the following bank note can be rubbed into the bank note rubbing channel in sequence, and the processing process of the second bank note and the following bank note is consistent with the processing process of the first bank note in steps S5-S8;

S10: based on step S9, when the banknote is rubbed into the banknote rubbing mechanism continuously, a plurality of banknotes are continuously recognized and transferred in the channel in the state, and after the last banknote is rubbed into the banknote rubbing mechanism, whether the banknote is recognized and transferred in the channel is judged by whether the D1 sensor, the D2 sensor and the D3 sensor are shielded;

S11: based on step S10, if none of the D1 sensor, the D2 sensor, and the D3 sensor is blocked, it indicates that the last banknote has completed the recognition transfer, and the whole banknote counting process ends.

Further, step S11 is followed by further including, after all the real banknotes enter the temporary storage module (TS) through the banknote feeding channel, if the user clicks to confirm deposit, reversely transferring the banknotes in the temporary storage module (TS) into the storage box (RB) through the banknote feeding channel; if the user does not confirm within the preset time, the banknote in the temporary storage module (TS) is reversely transmitted into the recovery box (AB) through the banknote-conveying channel; if the user clicks to cancel deposit, the gate of the temporary storage module (TS) is directly opened, and the user takes off the banknote; if the user does not take the bills in the appointed time, the gate of the temporary storage module (TS) is closed, and the bills in the temporary storage module (TS) are reversely conveyed into the recovery box (AB) through the bill conveying channel.

According to the technical scheme, in the banknote counting method, the fact that a plurality of banknotes exist in the channel at the same time can be continuously identified and counted, and the banknote counting process is optimized, so that the continuous and unified operation process is integrated into the banknote counting method, the single-service processing time is shortened, the service efficiency of a bank is improved, and good use experience is brought to a user.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. Like elements or portions are generally identified by like reference numerals throughout the several figures. In the drawings, elements or portions thereof are not necessarily drawn to scale.

FIG. 1 is a schematic view of a part of a deposit movement to which the present banknote counting method is applied according to an embodiment of the present invention;

FIG. 2 is a schematic layout diagram intended to show the specific distribution locations of the relevant sensors.

Detailed Description

The application is described in further detail below with reference to fig. 1-2.

As shown in fig. 1-2, embodiments of the present invention provide a banknote counting method. The banknote counting method utilizes a banknote counting module (CS), an identification module (BV), a core channel (TP) and a temporary storage module (TS) in a deposit core to rapidly identify and count banknotes, wherein the banknote counting module (CS) comprises four groups of sensors with the numbers of U1, U2, U3 and U4 arranged at a banknote inlet of the core, and the banknote inlet is divided into a banknote storage port and a banknote rejection port by a middle push plate of the banknote counting module (CS); a D1 sensor is arranged on a channel between the banknote counting module (CS) and the identification module (BV), a D2 sensor is arranged on the identification module (BV), a D3 sensor is arranged on the movement channel (TP), and a storage box (RB) and a recovery box (AB) are arranged below the movement channel (TP); the method comprises the following steps:

S1: the equipment is electrified and initialized, a middle push plate of a banknote counting module (CS) moves to a position close to a U3 sensor under the action of a push plate motor, and a front push plate of the banknote counting module (CS) moves to a position close to a U4 sensor under the action of the push plate motor so as to be convenient for placing banknotes in a banknote inlet; (with reference to fig. 1, the sensors in the banknote inlet are sequentially arranged from left to right as a U3 sensor, a U1 sensor, a U2 sensor and a U4 sensor).

S2: the method comprises the steps of placing a banknote into a banknote inlet, specifically into a banknote storage inlet, then executing a banknote counting instruction issued by a controller, enabling all channels of the whole machine core to start running at the moment, and entering a rapid banknote counting process;

S3: based on the step S2, specifically, the middle push plate moves towards the direction of the banknote friction mechanism close to the banknote counting module (CS) under the action of the push plate motor, and pushes the banknote to synchronously move towards the direction of the banknote friction mechanism until the U2 sensor is shielded by the banknote, at the moment, the U2 sensor sends a signal to the controller, the controller controls the banknote friction motor of the banknote friction mechanism (the banknote friction motor adopts a hybrid stepping motor capable of outputting a large moment) to start rotating to rub the banknote, and the first banknote is rubbed into the banknote friction channel;

s4: in step S3, after the first bill is rubbed into the bill rubbing channel, the number of bills at the bill storing port is reduced, the pressing force of the middle push plate on the bills is loosened, at the moment, the controller synchronously controls the push plate motor to rotate while controlling the bill rubbing motor to rotate, the middle push plate is pushed to drive the rest bills to continuously move towards the direction close to the bill rubbing mechanism until the U2 sensor is continuously shielded until the U2 sensor is not shielded, the U1 sensor is shielded, and the state indicates that all the bills placed in the bill storing port are rubbed into the bill rubbing channel;

S5: in step S3, after the first banknote is rubbed into the banknote rubbing channel, when the first banknote moves to the position of the D1 sensor and the D1 sensor is blocked, the D1 sensor sends a request for identifying the authenticity of the banknote to the identification module (BV), and when the first banknote continues to move to the position of the D2 sensor and the D2 sensor is blocked, the D2 sensor sends an instruction for executing the identification of the authenticity of the banknote to the identification module (BV), and at this time, the identification module (BV) starts to acquire the image of the banknote to identify the authenticity of the banknote;

S6: based on the step S5, the first banknote after being identified by the identification module (BV) continues to move to the machine core channel (TP), when the first banknote moves to the position of the D3 sensor and shields the D3 sensor, the D3 sensor sends a signal to the controller, the controller receives the banknote identification result fed back by the identification module (BV), analyzes the identification result, and controls the switching direction of the reverser at the tail end of the machine core channel (TP) according to different identification results so as to determine the final trend and storage position of the banknote;

S7: based on step S6, when the identification result of the first banknote is true banknote, the controller controls the reverser to switch to the lower channel (also referred to as banknote feeding channel) of the movement channel (TP), so that the banknote feeding channel of the movement channel (TP) is conducted, and the first banknote enters the temporary storage module (TS) through the banknote feeding channel;

S8: based on step S6, when the identification result of the first banknote is false banknote, the controller controls the diverter to switch to the upper channel (also called banknote rejecting channel) of the movement channel (TP), so that the banknote rejecting channel of the movement channel (TP) is conducted, and the first banknote enters the banknote rejecting port of the banknote counting module (CS) through the banknote rejecting channel;

S9: based on step S4, after the remaining bank note is pressed by the middle push plate again, the middle push plate pushes the remaining bank note to continuously move towards the direction close to the bank note rubbing mechanism under the action of the push plate motor, and as the bank note rubbing motor of the bank note rubbing mechanism always rotates, the second bank note and the following bank note can be rubbed into the bank note rubbing channel in sequence, and the processing process of the second bank note and the following bank note is consistent with the processing process of the first bank note in steps S5-S8;

s10: based on step S9, as the banknote is rubbed into the banknote rubbing mechanism continuously, a plurality of banknotes are continuously recognized and transferred in the channel in the state, and after the last banknote is rubbed into the banknote rubbing mechanism, whether the banknote is recognized and transferred in the channel is judged by whether the D1 sensor, the D2 sensor and the D3 sensor are shielded;

S11: based on the step S10, if the D1 sensor, the D2 sensor and the D3 sensor are not shielded, the last banknote is indicated to finish the recognition transfer, and the whole banknote counting process is finished;

S12: when all the true banknotes enter the temporary storage module (TS) through the banknote feeding channel, if a user clicks to confirm deposit, the banknotes in the temporary storage module (TS) are reversely transmitted into the storage box (RB) through the banknote feeding channel; if the user does not confirm within the preset time, the banknote in the temporary storage module (TS) is reversely transmitted into the recovery box (AB) through the banknote-conveying channel; if the user clicks to cancel deposit, the gate of the temporary storage module (TS) is directly opened, and the user takes off the banknote; if the user does not take the bills in the appointed time, the gate of the temporary storage module (TS) is closed, and the bills in the temporary storage module (TS) are reversely conveyed into the recovery box (AB) through the bill conveying channel.

In summary, the banknote counting method of the embodiment of the invention can realize that a plurality of banknotes exist in the channel at the same time and are continuously identified and counted, and the banknote counting process is optimized to integrate a continuous and unified operation process into the banknote counting method, so that the single service processing time is shortened, the service efficiency of a bank is improved, and good use experience is brought to users.

In the description of the present application, it should be understood that the orientation or positional relationship indicated by the terms "vertical", "horizontal", etc. are based on the orientation or positional relationship shown in the drawings, are merely for convenience of describing the present application and simplifying the description, and do not indicate or imply that the device or element in question must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present application.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. In the description of the present invention, the meaning of "plurality" is two or more unless specifically defined otherwise.

In the present application, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of two elements or the interaction relationship of the two elements. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art according to the specific circumstances.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present invention, and not for limiting the same; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some or all of the technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the invention, and are intended to be included within the scope of the appended claims and description. In particular, the technical features mentioned in the respective embodiments may be combined in any manner as long as there is no structural conflict. The present invention is not limited to the specific embodiments disclosed herein, but encompasses all technical solutions falling within the scope of the claims.

Claims (2)

1. A banknote counting method, which is characterized in that: the method comprises the steps of rapidly identifying and counting bills by using a bill counting module (CS), an identification module (BV), a machine core channel (TP) and a temporary storage module (TS) in a deposit machine core, wherein the bill counting module (CS) comprises four groups of sensors with the numbers of U1, U2, U3 and U4 arranged at a bill inlet of the machine core, and the bill inlet is separated into a bill storage port (CO) and a bill rejection port (DO) by a middle push plate of the bill counting module (CS); a D1 sensor is arranged on a channel between the banknote counting module (CS) and the identification module (BV), a D2 sensor is arranged on the identification module (BV), a D3 sensor is arranged on the movement channel (TP), and a storage box (RB) and a recovery box (AB) are arranged below the movement channel (TP); the method comprises the following steps:

S1: the equipment is electrified and initialized, a middle push plate of a banknote counting module (CS) moves to a position close to a U3 sensor under the action of a push plate motor, and a front push plate of the banknote counting module (CS) moves to a position close to a U4 sensor under the action of the push plate motor so as to be convenient for placing banknotes in a banknote inlet;

s2: putting the banknote into a banknote inlet, specifically into a banknote storage inlet (CO), then executing a banknote counting instruction issued by a controller, and enabling all channels of the whole machine core to start to run at the moment and enter a rapid banknote counting process;

S3: based on the step S2, specifically, the middle push plate moves towards the direction of the banknote friction mechanism close to the banknote counting module (CS) under the action of the push plate motor, and pushes the banknote to synchronously move towards the direction of the banknote friction mechanism until the U2 sensor is shielded by the banknote, at the moment, the U2 sensor sends a signal to the controller, the controller controls the banknote friction motor of the banknote friction mechanism to start rotating to rub the banknote, and the first banknote is rubbed into the banknote friction channel;

S4: in step S3, after the first bill is rubbed into the bill rubbing channel, the number of bills at the bill storing port (CO) is reduced, the pressing force of the middle push plate on the bills is loosened, at the moment, the controller synchronously controls the push plate motor to rotate while controlling the bill rubbing motor to rotate, and the middle push plate drives the residual bills to continuously move towards the direction close to the bill rubbing mechanism until the U2 sensor is continuously shielded until the U2 sensor is not shielded, the U1 sensor is shielded, and the state indicates that all the bills placed in the bill storing port are rubbed into the bill rubbing channel;

S5: in step S3, after the first banknote is rubbed into the banknote rubbing channel, when the first banknote moves to the position of the D1 sensor and the D1 sensor is blocked, the D1 sensor sends a request for identifying the authenticity of the banknote to the identification module (BV), and when the first banknote continues to move to the position of the D2 sensor and the D2 sensor is blocked, the D2 sensor sends an instruction for executing the identification of the authenticity of the banknote to the identification module (BV), and at this time, the identification module (BV) starts to acquire the image of the banknote to identify the authenticity of the banknote;

S6: based on the step S5, the first bill which is identified by the identification module (BV) continues to move to the movement channel (TP), when the first bill moves to the position of the D3 sensor and shields the D3 sensor, the D3 sensor sends a signal to the controller, and the controller receives the bill identification result fed back by the identification module (BV), analyzes the identification result and is different; the identification result is that the switching direction of a commutator (DM) at the tail end of a movement channel (TP) is controlled to determine the final trend and storage position of the bank note;

S7: based on step S6, when the identification result of the first bill is true bill, the controller controls the reverser (DM) to switch to the bill feeding channel of the movement channel (TP), so that the bill feeding channel of the movement channel (TP) is conducted, and the first bill enters the temporary storage module (TS) through the bill feeding channel;

S8: based on step S6, when the identification result of the first bill is false bill, the controller controls the reverser (DM) to switch to the bill rejecting channel of the movement channel (TP) so that the bill rejecting channel of the movement channel (TP) is conducted, and the first bill enters the bill rejecting port of the bill counting module (CS) through the bill rejecting channel;

S9: based on step S4, after the remaining bank note is pressed by the middle push plate again, the middle push plate pushes the remaining bank note to continuously move towards the direction close to the bank note rubbing mechanism under the action of the push plate motor, and as the bank note rubbing motor of the bank note rubbing mechanism always rotates, the second bank note and the following bank note can be rubbed into the bank note rubbing channel in sequence, and the processing process of the second bank note and the following bank note is consistent with the processing process of the first bank note in steps S5-S8;

s10: based on step S9, as the banknote is rubbed into the banknote rubbing mechanism continuously, a plurality of banknotes are continuously recognized and transferred in the channel in the state, and after the last banknote is rubbed into the banknote rubbing mechanism, whether the banknote is recognized and transferred in the channel is judged by whether the D1 sensor, the D2 sensor and the D3 sensor are shielded;

S11: based on step S10, if none of the D1 sensor, the D2 sensor, and the D3 sensor is blocked, it indicates that the last banknote has completed the recognition transfer, and the whole banknote counting process ends.

2. A banknote counting method according to claim 1, wherein: after the step S11, after all the true banknotes enter the temporary storage module (TS) through the banknote feeding channel, if a user clicks to confirm deposit, the banknotes in the temporary storage module (TS) are reversely conveyed into the storage box (RB) through the banknote feeding channel; if the user does not confirm within the preset time, the banknote in the temporary storage module (TS) is reversely transmitted into the recovery box (AB) through the banknote-conveying channel; if the user clicks to cancel deposit, the gate of the temporary storage module (TS) is directly opened, and the user takes off the banknote; if the user does not take the bills in the appointed time, the gate of the temporary storage module (TS) is closed, and the bills in the temporary storage module (TS) are reversely conveyed into the recovery box (AB) through the bill conveying channel.