This application is the National Phase of PCT Application No. PCT/CN2015/091036, filed Sep. 29, 2015, which claims priority to Chinese patent application No. 201510135943.X titled “BANKNOTE STACKING DEVICE AND BANKNOTE PROCESSING APPARATUS”, filed with the Chinese State Intellectual Property Office on Mar. 26, 2015, the entire disclosures of both applications are incorporated herein by reference.
The present application relates to sheet-type medium processing technology, and particularly to a banknote-type medium stacking device and a banknote processing apparatus having the stacking device.
With the continuous development of the economy, the amount of processing banknote is increasing, and the requirement for processing capacity of banknote processing apparatuses is also raised accordingly. Currently used banknote processing apparatuses generally can be divided into cash dispensers, cash deposit machines, cash recycle systems, currency sorters and the like by main functions. The main functions of these banknote processing apparatuses include basic self-service financial business such as banknote withdrawing, banknote depositing, and transfer accounts etc.
In a banknote processing apparatus, banknotes are generally stacked for being stored, thus, when processing a stack of banknotes, the stack of banknotes are required to be separated one by one by a conveying mechanism, and then are conveyed into a banknote identifier. After being identified by the banknote identifier, the separated banknotes are generally conveyed into a banknote stacking mechanism to be stacked again. Finally, the stacked banknotes are conveyed by the conveying mechanism to a next process, such as a process of outputting the stacked banknotes to a customer, a process of finishing the banknote withdrawing flow, etc. For making the whole stack of banknotes arranged tidily in the conveying process, and not causing technical issues such as misaligning and collapsing due to crossing of banknotes and further causing banknote conveying failure, the optimization of the banknote stacking device is an important subject in developing and designing a banknote processing apparatus. In currently used banknote stacking devices, banknotes are separated one by one by an impeller, and are stacked on a clamping mechanism similar to a manipulator, and the whole stack of banknotes are clamped and outputted by the manipulator. Besides a complex mechanical clamping mechanism and an impeller device, the above conveying mechanism also requires auxiliary mechanisms to cooperate with them to work, resulting in a complex whole mechanism, and with ever increasing number of banknotes processed by a banknote processing apparatus at one time, the volume of the stacking mechanism also gets larger and larger correspondingly, and cost is increased. Further, the technical issues, such as normal processing of the apparatus being affected due to deformation of banknotes, is apt to occur during the banknote conveying.
Accordingly, how to address the technical issue in the conventional technology that the conventional banknote stacking device has a complex structure, cannot stack a large number of banknotes tidily, has become a technical issue to be presently addressed by the person skilled in the art.
For addressing the technical issue that a conventional banknote stacking device has a complex mechanism and an insufficient reliability, a banknote stacking device is proposed according to the present application which has a simple structure, can stack a large number of banknotes and can stack reliably, and a banknote processing apparatus employing the stacking device is further proposed according to the present application.
The banknote stacking device according to the present application includes:
an input mechanism configured to convey banknotes one by one, which includes an upper conveying belt, a lower conveying belt, an upper conveying rotating shaft configured to drive the upper conveying belt, and a lower conveying rotating shaft configured to drive the lower conveying belt;
a stacking platform mechanism configured to stack and support banknotes conveyed by the input mechanism one by one, which includes a platform configured to carry banknotes, wherein the platform and two baffles arranged front and rear in a banknote conveying direction define a space for stacking and storing banknotes, and the platform is controlled by a lifting mechanism to selectively move up and down, and the platform is preferably driven by rotation of a step motor to achieve selective lifting and descending;
a pressing and conveying mechanism located above the stacking platform mechanism and configured to press banknotes and convey the banknotes stacked on the platform forward, wherein the pressing and conveying mechanism has a pressing rod, and the pressing rod has one end rotatably arranged on the upper conveying rotating shaft and another end forming a free end and falling freely towards the platform. The rotatable securing end and the free end of the pressing rod are respectively provided with a first concave wheel and a second concave wheel, and a first O-shaped belt is arranged on the first concave wheel and the second concave wheel, and the first concave wheel rotates synchronously with the upper conveying rotating shaft, the banknotes conveyed by the input mechanism one by one are conveyed into the stacking platform mechanism, and while the pressing and conveying mechanism presses the banknotes onto the stacking platform mechanism, the concave wheels and the O-shaped belts thereon of the pressing and conveying mechanism are synchronously driven forward, and the friction force between the O-shaped belts and the banknotes drives the banknotes to move forward to a position of the front baffle, which allows front ends of the banknotes to be aligned with the front baffle.
Preferably, the first concave wheel and a third concave wheel are respectively arranged on two sides of the rotatable coupled end of the pressing rod, and the second concave wheel and a fourth concave wheel are respectively arranged on two sides of the free end of the pressing rod. The first O-shaped belt is arranged on the first concave wheel and the second concave wheel to form a first driving belt-wheel set, and a second O-shaped belt is arranged on the third concave wheel and the fourth concave wheel to form a second driving belt-wheel set. The first concave wheel and the third concave wheel rotate synchronously with the upper conveying rotating shaft.
Preferably, a belt conveying part is provided on the platform, and the belt conveying part includes a flat belt and two flat belt pulleys configured to support and drive the flat belt. Each of the flat belt pulleys is mounted onto the platform via a pulley rotating shaft, and the pulley rotating shaft is equipped with a connecting gear configured to receive an external power.
Further, an elastic strip is further provided on the platform, and the elastic strip has two ends fixed onto the platform, and a middle portion forming an arched elastic platform part. The elastic platform part is higher than the flat belt by 1 mm to 2 mm in a free state, so as to prevent a first banknote from contacting with the flat belts when entering the platform, which may otherwise stop the moving of the banknote and cause untidy stacking of banknotes.
Further, two belt conveying parts and two elastic strips are provided on the platform, and the belt conveying parts and the elastic strips are symmetrical arranged in parallel with each other along a middle line of the platform in the banknote conveying direction.
Preferably, the banknote stacking device further includes an output mechanism configured to output a whole stack of banknotes stacked on the platform in stack. The output mechanism includes an upper output conveying belt and an upper output rotating shaft, and the upper output rotating shaft is controlled by a pressure spring to move up and down to self-adapt to the thickness of stacked banknotes.
Preferably, a protrusion is provided on each of edges, close to the front baffle and the rear baffle, of the platform, and ribs cooperating with the protrusions are formed on surfaces of the front baffle and the rear baffle at corresponding positions.
A banknote processing apparatus is further provided according to the present application, which includes a banknote inlet/outlet for depositing and withdrawing banknotes, a banknote conveying passage configured to convey banknotes, a banknote recycling box configured to recycle banknotes, and a banknote cassette configured to store banknotes, and the banknote processing apparatus is characterized in that the banknote processing apparatus further includes the banknote stacking device described above.
Compared with the conventional technology, the banknote stacking device according to the present application has the following advantages.
Due to employing the pressing and conveying mechanism, the banknote stacking device according to the present application has a simpler configuration and a lower cost than a normal manipulator-type clamping mechanism. While pressing the banknotes, the O-shaped belt conveys the banknotes forward to the position of the baffle, which can ensure the banknotes to be stacked tidily while preventing the banknotes from flying away.
For further elaborating a banknote stacking device according to the present application, the banknote stacking device is further described in detail hereinafter with reference to an illustration of a preferred embodiment of the present application.
Reference is made to
Referring to
Referring to
The lifting mechanism configured to control the platform 21 to move up and down is further described. The lifting mechanism is constituted by a synchronous belt 215 and a belt pulley 216 which are driven by a step motor, and the platform 21 is provided with a holding device 214 for the synchronous belt 215. The working principle of the stacking platform mechanism 2 in the process of banknote stacking and the process of banknote outputting after the banknote stacking is further described. Reference is made to
Referring to
Referring to
Referring to
In addition, as a certain number of banknotes enter the stacking platform mechanism 2, the stacking platform mechanism 2 is driven by the external motor to descend by a certain distance (for example, if the thickness of one banknote is counted as 0.1 mm, the platform descend by 2 mm when every twenty banknotes enter, which can be set according to a specific structure), as shown in
Referring to
A banknote processing device is further provided according to an embodiment of the present application, as shown in
The person skilled in the art may clearly know that, for convenience and concise of the description, the specific working process of the system, device, and unit described above may refer to the corresponding process in the embodiment of the method described above, which will not be described herein again.
The above description is only preferred embodiments of the present application. It should be noted that, the above preferred embodiments should not be deemed as a limitation to the present application, and the scope of the present application is defined by the claims of the present application. For the person skilled in the art, several improvements and modifications may be made to the present application without departing from the spirit and scope of the present application, and these improvements and modifications are also deemed to fall into the scope of the present application.
Number | Date | Country | Kind |
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2015 1 0135943 | Mar 2015 | CN | national |
Filing Document | Filing Date | Country | Kind |
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PCT/CN2015/091036 | 9/29/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2016/150138 | 9/29/2016 | WO | A |
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