CN110288765A - Flaky medium conveying device and cash recycling equipment - Google Patents

Abstract

The present invention relates to cash handling device technical fields, more particularly, to a kind of flaky medium conveying device and cash recycling equipment, to alleviate the technical issues of bi-directional medium transfer passage present in the relevant technologies is easy card plug bank note.The flaky medium conveying device includes first passage board group part, second channel board group part and driving assembly, flaky medium conveying device has first state and the second state, and driving assembly is for driving flaky medium conveying device to switch between the first state and a second state；When flaky medium conveying device is in first state, media transport path is formed between first passage board group part and second channel board group part, when flaky medium conveying device is in the second state, media transport path is opened wide.Flaky medium conveying device provided by the invention can effectively avoid bank note card plug.

Description

Sheet-like medium conveying device and cash recycling device

Technical Field

The invention relates to the technical field of cash processing equipment, in particular to a sheet medium conveying device and cash recycling processing equipment.

Background

The cash recycling processing equipment (bill recycling terminal) is a financial self-service equipment which combines various functions of cash recycling, deposit, withdrawal, temporary storage, clearing, counting, counterfeit identification, serial number recording, continuous and uninterrupted cash feeding, cash storage at the end of a day, inquiry and the like, and can realize recycling of RMB of various denominations of paper currency circulating in China.

The paper money processing device comprises an upper device and a lower device, wherein the upper device comprises a paper money identification module, the lower device comprises a safety box and a paper money box arranged in the safety box, and a bidirectional medium conveying channel is arranged between the upper device and the lower device and is used for conveying paper money into the paper money box after being identified by the paper money identification module during deposit or conveying the paper money in the paper money box during withdrawal.

The width of the existing bidirectional medium conveying channel is fixed, and due to the reasons of assembly error, machining error and the like, the bidirectional medium conveying channel can not be accurately communicated with an upper device or a lower device, so that paper money can not move smoothly and is blocked at the joint of the bidirectional medium conveying channel and the upper device or the lower device.

In addition, when the upper device or the lower device is pulled out, that is, when the upper device and the lower device are misaligned with each other, if bills remain in the bidirectional passage, the bills are easily torn during the process of pulling out the upper device or the lower device.

Disclosure of Invention

The invention aims to provide a sheet medium conveying device and a cash recycling device, which are used for solving the technical problem that paper money is easy to jam in a bidirectional medium conveying channel in the related technology.

In order to alleviate the technical problems, the technical scheme provided by the invention is as follows:

the sheet medium conveying device comprises a first channel plate assembly, a second channel plate assembly and a driving assembly, wherein the sheet medium conveying device has a first state and a second state, and the driving assembly is used for driving the sheet medium conveying device to be switched between the first state and the second state;

the first channel plate assembly comprises a first channel plate and a second channel plate which are adjacently arranged; the second channel plate assembly comprises a third channel plate and a fourth channel plate which are adjacently arranged, and the driving assembly is in transmission connection with the first channel plate;

when the sheet type medium conveying device is in a first state, the first channel plate is opposite to the third channel plate, a first channel is formed between the first channel plate and the third channel plate, the second channel plate is opposite to the fourth channel plate, a second channel is formed between the second channel plate and the fourth channel plate, and the first channel is communicated with the second channel to form a medium conveying channel;

when the sheet-like medium conveying device is in the second state, one end, away from the fourth channel plate, of the third channel plate is away from one end, away from the fourth channel plate, of the first channel plate, and/or one end, away from the first channel plate, of the second channel plate is away from one end, away from the third channel plate, of the fourth channel plate, so that the medium conveying channel is opened.

Further, each of the first channel plate and the second channel plate is movable in a direction away from the medium transport path, and/or each of the third channel plate and the fourth channel plate is movable in a direction away from the medium transport path to open the medium transport path.

Furthermore, the first channel plate and the second channel plate are in transmission connection through a first synchronous mechanism; the first synchronization mechanism is used for synchronously driving the first channel plate and the second channel plate to be close to or far away from the medium conveying channel.

Further, the first synchronization mechanism includes a first tooth-shaped portion provided at an end of the first channel plate close to the second channel plate, and a second tooth-shaped portion provided at an end of the second channel plate close to the first channel plate, the first tooth-shaped portion and the second tooth-shaped portion being engaged with each other.

Furthermore, the third channel plate and the fourth channel plate are in transmission connection through a second synchronization mechanism, and the second synchronization mechanism is used for synchronously driving the third channel plate and the fourth channel plate to be close to or far away from the medium conveying channel.

Still further, the second synchronizing mechanism includes a third tooth portion provided at an end of the third channel plate close to the fourth channel plate, and a fourth tooth portion provided at an end of the fourth channel plate close to the third channel plate, the third tooth portion and the fourth tooth portion being engaged.

Still further, the first channel plate assembly and the second channel plate assembly are symmetrically disposed about the media transport channel.

Furthermore, the driving assembly includes a third synchronization mechanism, and the third synchronization mechanism is connected to the first channel plate and the third channel plate, respectively, and is configured to synchronously drive the first channel plate and the third channel plate to approach or depart from the medium conveying channel.

Further, the third synchronizing mechanism comprises a first gear and a second gear which are connected in a meshing manner;

the first gear is coaxially and fixedly connected with the first channel plate, and the second gear is coaxially and fixedly connected with the third channel plate;

or,

the first gear is coaxially and fixedly connected with the second channel plate, and the second gear is coaxially and fixedly connected with the fourth channel plate.

A cash recycling device includes the sheet-like medium conveyance device according to any one of the above.

By combining the technical scheme, the technical effect analysis that the sheet medium conveying device provided by the invention can achieve is as follows:

the sheet medium conveying device provided by the invention comprises a first channel plate assembly, a second channel plate assembly and a driving assembly, wherein the sheet medium conveying device has a first state and a second state, and the driving assembly is used for driving the sheet medium conveying device to be switched between the first state and the second state. The first channel plate assembly comprises a first channel plate and a second channel plate which are adjacently arranged; the second channel plate assembly comprises a third channel plate and a fourth channel plate which are adjacently arranged, and the driving assembly is in transmission connection with the first channel plate;

when the sheet type medium conveying device is in a first state, the first channel plate is opposite to the third channel plate, a first channel is formed between the first channel plate and the third channel plate, the second channel plate is opposite to the fourth channel plate, a second channel is formed between the second channel plate and the fourth channel plate, and the first channel is communicated with the second channel to form a medium conveying channel;

when the sheet-like medium conveying device is in the second state, one end, away from the fourth channel plate, of the third channel plate is away from one end, away from the fourth channel plate, of the first channel plate, and/or one end, away from the first channel plate, of the second channel plate is away from one end, away from the third channel plate, of the fourth channel plate, so that the medium conveying channel is opened.

When the sheet-like medium conveying device normally conveys the sheet-like medium, the sheet-like medium conveying device is in the first state. When the sheet type medium conveying device is relatively dislocated with the upstream device and/or the downstream device, the sheet type medium conveying device is changed from the first state to the second state, at the moment, the first channel plate is separated from the third channel plate to open the first channel, and/or the second channel plate is separated from the fourth channel plate to open the second channel. The first channel and/or the second channel in the open state can effectively prevent the sheet media from being jammed at the inlet and outlet of the first channel and/or the inlet and outlet of the second channel, and the problem that the conventional sheet media is jammed at the joint of the bidirectional media conveying channel and the upper device or the lower device is solved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention or related technologies, the drawings used in the description of the embodiments or related technologies will be briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

Fig. 1 is a schematic overall structural diagram of a sheet-like medium conveying device according to an embodiment of the present invention;

fig. 2 is a schematic cross-sectional structure diagram of a sheet-like medium conveying device in a first state according to an embodiment of the present invention;

fig. 3 is a schematic cross-sectional structure diagram of a sheet-like medium conveying device in a second state according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of a first channel plate in a sheet-like medium conveying device according to an embodiment of the present invention;

fig. 5 is a side view of a first channel plate in a sheet-like medium conveyance device according to an embodiment of the present invention;

fig. 6 is a schematic view of the overall structure of the cash recycling device according to the embodiment of the present invention.

Icon: 100-a first channel plate assembly; 200-a second channel plate assembly; 110-a first channel plate; 120-a second channel plate; 210-a third channel plate; 220-a fourth channel plate;

111-the open end of the first channel; 112 — a connection end of the first channel;

121-the open end of the second channel; 122 — a connection end of a second channel;

211-the open end of the third channel; 212-the connection end of the third channel;

221-the open end of the fourth channel; 222 — a connection end of a fourth channel;

101-a first channel; 102-a second channel; 300-a first synchronization mechanism; 310-a first profile; 320-second tooth profile; 400-a second synchronization mechanism; 410-third profile; 420-fourth tooth form; 500-a drive assembly; 511-a third synchronization mechanism; 511-a first gear; 512-a second gear; 1-a sheet-like medium conveyance device; 2-upper unit; 3-lower device; 21-a coin-in mechanism; 22-coin dispensing mechanism; 23-temporary storage mechanism; 24-a common channel; 31-money box.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Embodiment 1 and embodiment 2 are described in detail below with reference to the accompanying drawings:

example 1

The embodiment provides a sheet type medium conveying device 1, which comprises a first channel plate assembly 100, a second channel plate assembly 200 and a driving assembly 500, wherein the sheet type medium conveying device 1 has a first state and a second state, and the driving assembly 500 is used for driving the sheet type medium conveying device 1 to be switched between the first state and the second state; the first channel plate assembly 100 includes a first channel plate 110 and a second channel plate 120 adjacently disposed; the second channel plate assembly 200 comprises a third channel plate 210 and a fourth channel plate 220 which are adjacently arranged, and the driving assembly 500 is in transmission connection with the first channel plate 110; when the sheet-like medium conveying device 1 is in the first state, the first channel plate 110 is opposite to the third channel plate 210, a first channel 101 is formed between the first channel plate and the third channel plate, the second channel plate 120 is opposite to the fourth channel plate 220, a second channel 102 is formed between the first channel plate and the fourth channel plate, and the first channel 101 is communicated with the second channel 102 to form a medium conveying channel; when the sheet-like medium transporting device 1 is in the second state, the end of the first channel plate 110 away from the second channel plate 120 is away from the end of the third channel plate 210 away from the fourth channel plate 220, and/or the end of the second channel plate 120 away from the first channel plate 110 is away from the end of the fourth channel plate 220 away from the third channel plate 210, so as to open the medium transporting channel.

The beneficial effects that can be achieved by the sheet-like medium conveyance device 1 provided in the present embodiment are analyzed as follows:

when the sheet-like medium conveyance device 1 normally conveys the sheet-like medium, the sheet-like medium conveyance device 1 is in the first state. When the sheet-like medium conveying device 1 is misaligned with the upstream device and/or the downstream device, the sheet-like medium conveying device 1 is changed from the first state to the second state, and at this time, the end of the first channel plate 110 away from the second channel plate 120 is away from the end of the third channel plate 210 away from the fourth channel plate 220 to open the first channel 101, and/or the end of the second channel plate 120 away from the first channel plate 110 is away from the end of the fourth channel plate 220 away from the third channel plate 210 to open the second channel 102. The first channel 101 and/or the second channel 102 in the open state can effectively avoid the problem that the sheet-like media are jammed at the inlet and the outlet of the first channel 101 and/or the inlet and the outlet of the second channel 102.

In the alternatives of this embodiment, it is preferable that: the first channel plate 110, the second channel plate 120, the third channel plate 210, and the fourth channel plate 220 implement an open media transport channel in various ways:

for example, case one: the third channel plate 210 is stationary, and the end of the first channel plate 110 away from the second channel plate 120 is gradually away from the end of the third channel plate 210 away from the fourth channel plate 220, which means that referring to fig. 2, the third channel plate 210 is stationary, and the top end of the first channel plate 110 rotates to the left to open the first channel 101. Case two: the fourth channel plate 220 is stationary, and the end of the second channel plate 120 away from the first channel plate 110 is gradually away from the end of the fourth channel plate 220 away from the third channel plate 210, which means that referring to fig. 2, the fourth channel plate 220 is stationary and the second channel plate 120 rotates to the left to open the second channel 102. In addition, the first and second cases may occur alternatively or simultaneously.

For another example, the first channel plate 110 and the second channel plate 120 can each be moved away from the medium conveyance path, and/or the third channel plate 210 and the fourth channel plate 220 can each be moved away from the medium conveyance path to open the medium conveyance path. This means that, referring to fig. 3, the first channel plate 110 is rotated to the left and the third channel plate 210 is rotated to the right, thereby opening the first channel 101, and/or the second channel plate 120 is rotated to the left and the fourth channel plate 220 is rotated to the right, thereby opening the second channel 102. In addition, the first channel plate 110 and the third channel plate 210 may rotate to both sides simultaneously, and the second channel plate 120 and the fourth channel plate 220 may rotate to both sides simultaneously.

As to the shape and structure of the first channel plate assembly 100 and the second channel plate assembly 200, more specifically, please refer to fig. 1 to 5 together:

the first channel plate 110 includes an open end 111 and a connection end 112, the second channel plate 120 includes an open end 121 and a connection end 122, the connection end 112 of the first channel plate 110 is connected to the connection end 122 of the second channel plate 120, and the first channel plate 110 can rotate in a direction gradually away from the medium transportation path with the connection end 112 of the first channel plate 110 as a center, the second channel plate 120 can rotate in a direction gradually away from the medium transportation path with the connection end 122 of the second channel plate 120 as a center, and the first channel plate 110 and the second channel plate 120 synchronously rotate in opposite directions, in other words, in a view angle of fig. 2, the first channel plate 110 rotates in a counterclockwise direction with the connection end 112 of the first channel plate 110 as a center, and the second channel plate 120 rotates in a clockwise direction with the connection end 122 of the second channel plate 120 as a center.

The third channel plate 210 includes an open end 211 and a connection end 212, the fourth channel plate 220 includes an open end 221 and a connection end 222, the connection end 212 of the third channel plate 210 is connected to the connection end 222 of the fourth channel plate 220, and the third channel plate 210 can rotate in a direction gradually away from the medium transportation channel with the connection end 212 of the third channel plate 210 as a center, the fourth channel plate 220 can rotate in a direction gradually away from the medium transportation channel with the connection end 222 of the fourth channel plate 220 as a center, and the third channel plate 210 and the fourth channel plate 220 rotate in opposite directions synchronously, in other words, in a view angle of fig. 2, the third channel plate 210 rotates in a clockwise direction with the connection end 212 of the third channel plate 210 as a center, and the fourth channel plate 220 rotates in a counterclockwise direction with the connection end 222 of the fourth channel plate 220 as a center.

It should be noted that: the structure of the first channel plate assembly 100 and the second channel plate assembly 200 may include three cases, which are respectively:

in the first case, the first channel plate assembly 100 includes the first channel plate 110 and the second channel plate 120, the shape and structure of the second channel plate assembly 200 are not limited (for example, the third channel plate 210 and the fourth channel plate 220 are integrally formed), and both the first channel plate 110 and the second channel plate 120 can move in a direction away from the medium transport channel to open the medium transport channel.

In the second case, the second channel plate assembly 200 includes the third channel plate 210 and the fourth channel plate 220, the shape and structure of the first channel plate assembly 100 are not limited (for example, the first channel plate 110 and the second channel plate 120 are integrally formed), and both the third channel plate 210 and the fourth channel plate 220 can move in a direction away from the medium transport channel to open the medium transport channel.

Case three, the first channel plate assembly 100 includes the first channel plate 110 and the second channel plate 120, and the second channel plate assembly 200 includes the third channel plate 210 and the fourth channel plate 220, the first channel plate 110 and the third channel plate 210 are simultaneously moved in a direction away from the medium feeding path to open the medium feeding path, or the second channel plate 120 and the fourth channel plate 220 are simultaneously moved in a direction away from the medium feeding path to open the medium feeding path.

In the alternative of this embodiment, it is preferable that the first channel plate 110 and the second channel plate 120 are in transmission connection through the first synchronization mechanism 300; the first synchronization mechanism 300 is used to synchronously bring the first channel plate 110 and the second channel plate 120 close to or away from the medium conveying channel.

The shape and structure of the first synchronization mechanism 300 may be variously set, and detailed embodiments are described below:

for example: the first synchronization mechanism 300 includes a first tooth portion 310 provided at the connection end 112 of the first channel plate 110, and a second tooth portion 320 provided at the connection end 122 of the second channel plate 120, the first tooth portion 310 and the second tooth portion 320 being engaged. The rotation of the first tooth-shaped portion 310 drives the second tooth-shaped portion 320 to rotate synchronously, the first tooth-shaped portion 310 drives the first channel plate 110 to rotate in the rotation process, the second tooth-shaped portion 320 drives the second channel plate 120 to rotate in the rotation process, and the first channel plate 110 and the second channel plate 120 can rotate synchronously and reversely through the synchronous rotation of the first tooth-shaped portion 310 and the second tooth-shaped portion 320.

Further, the first tooth 310 is provided in a half-tooth structure, and specifically, the first tooth 310 is provided on a side of the first channel plate 110 facing away from the medium conveying channel. The second tooth-shaped portion 320 is provided in a half-tooth structure, and specifically, the second tooth-shaped portion 320 is provided on a side of the second channel plate 120 facing away from the medium conveying channel. In the above arrangement, the rotation angles of the first channel plate 110 and the second channel plate 120 are limited, and the first tooth-shaped portion 310 and the second tooth-shaped portion can make the first channel plate 110 and the second channel plate 120 always rotate outside the limit, with the connecting line of the first channel plate 110 and the second channel plate 120 in a linear state as the limit.

Another example is: the first synchronization mechanism 300 includes a torsion spring device, and in more detail, the connection end of the first channel plate 110 and the connection end of the second channel plate 120 are overlapped with each other and connected by a shaft, and the torsion spring device is located between the first channel plate 110 and the second channel plate 120 and sleeved on the shaft. When the first channel plate 110 and the second channel plate 120 are subjected to an external force, for example, a horizontal force (as viewed in fig. 2), the first channel plate 110 and the second channel plate 120 may move to a vertical direction against the external force of the torsion spring.

In an alternative of this embodiment, it is preferable that the third channel plate 210 and the fourth channel plate 220 are connected by a second synchronization mechanism 400, so as to synchronously drive the third channel plate 210 and the fourth channel plate 220 to approach or depart from the medium conveying channel.

The shape and structure of the second synchronization mechanism 400 can be variously set, and detailed embodiments are described below:

for example: the second synchronizing mechanism 400 includes a third tooth portion 410 provided at the connecting end 212 of the third channel plate 210, and a fourth tooth portion 420 provided at the connecting end 222 of the fourth channel plate 220, the third tooth portion 410 and the fourth tooth portion 420 being engaged. The rotation of the third tooth-shaped portion 410 drives the synchronous rotation of the fourth tooth-shaped portion 420, the third tooth-shaped portion 410 drives the third channel plate 210 to rotate in the rotation process, the fourth tooth-shaped portion 420 drives the fourth channel plate 220 to rotate in the rotation process, and the synchronous reverse rotation of the third channel plate 210 and the fourth channel plate 220 can be realized through the synchronous rotation of the third tooth-shaped portion 410 and the fourth tooth-shaped portion 420.

Further, for synchronous reverse rotation of the third channel plate 210 and the fourth channel plate 220, the third tooth 410 is disposed on a side of the third channel plate 210 facing away from the medium conveying channel, and the fourth channel plate 220 is disposed on a side of the fourth channel plate 220 facing away from the medium conveying channel. That is, the third teeth 410 are provided in a half-tooth structure, and specifically, the third teeth 410 are provided on a side facing away from the medium conveying passage. The fourth tooth-shaped portion 420 is configured as a half-tooth structure, specifically, the fourth tooth-shaped portion 420 is disposed on a side away from the medium conveying channel, and the above-mentioned configuration limits the rotation angle of the third channel plate 210 and the fourth channel plate 220, and the third tooth-shaped portion 410 and the fourth tooth-shaped portion enable the third channel plate 210 and the fourth channel plate 220 to rotate outside the limit all the time, with the connection line of the third channel plate 210 and the fourth channel plate 220 in a straight line state as a limit.

Another example is: the second synchronization mechanism 400 includes a torsion spring device, and in more detail, the connection end of the third channel plate 210 and the connection end of the fourth channel plate 220 are overlapped with each other and connected by a shaft, and the torsion spring device is located between the third channel plate 210 and the fourth channel plate 220 and sleeved on the shaft. When the third channel plate 210 and the fourth channel plate 220 are subjected to an external force, for example, a horizontal force (in the view of the figure), the external force may overcome the external force, so that the third channel plate 210 and the fourth channel plate 220 move to the vertical direction.

In an alternative of this embodiment, it is preferable that the driving assembly 500 includes a third synchronizing mechanism 511, and the third synchronizing mechanism 511 is connected to the first channel plate assembly 100 and the second channel plate assembly 200 respectively, and is used for driving the first channel plate assembly 100 and the second channel plate assembly 200 to approach or move away from the medium conveying passage. Referring to fig. 1, the third synchronization mechanism 511 is respectively connected to the first channel plate 110 and the third channel plate 210, or the third synchronization mechanism 511 is respectively connected to the second channel plate 120 and the fourth channel plate 220.

In the alternative of the present embodiment, it is preferable that the third synchronizing mechanism 511 includes a first gear 511 and a second gear 512 that mesh with each other; the first gear 511 is connected with the first channel plate 110, and the second gear 512 is connected with the third channel plate 210; more specifically, the first gear 511 is coaxially and fixedly connected to the first tooth portion 310 of the first channel plate 110, and the second gear 512 is coaxially and fixedly connected to the third tooth portion 410 of the third channel plate 210. For example, in one driving manner, the first gear 511 drives the first channel plate 110 to rotate through the first tooth-shaped portion 310 of the first channel plate 110, the rotation of the first channel plate 110 drives the second channel plate 120 to rotate, meanwhile, the first gear 511 drives the second gear 512 to rotate, the second gear 512 drives the third channel plate 210 to rotate, the third channel plate 210 drives the fourth channel plate 220 to rotate, and the rotation processes of the above components are performed synchronously.

Alternatively, the first gear 511 is connected to the second channel plate 120, and the second gear 512 is connected to the fourth channel plate 220. More specifically, the first gear 511 is coaxially and fixedly connected to the second tooth-shaped portion 320 of the second channel plate 120, and the second gear 512 is coaxially and fixedly connected to the fourth tooth-shaped portion 420 of the fourth channel plate 220. For example, in one driving manner, the first gear 511 drives the second channel plate 120 to rotate through the second tooth-shaped portion 320 of the second channel plate 120, the second channel plate 120 drives the first channel plate 110 to rotate, meanwhile, the first gear 511 drives the second gear 512 to rotate, the second gear 512 drives the fourth channel plate 220 to rotate, the fourth channel plate 220 drives the third channel plate 210 to rotate, and the rotation processes of the above components are performed synchronously.

In an alternative of this embodiment, it is preferable that the driving assembly 500 further includes a power mechanism, and the power mechanism is connected to any one of the first channel plate 110, the second channel plate 120, the third channel plate 210, the fourth channel plate 220, the first gear 511, or the second gear 512. In other words, the first channel plate 110, the second channel plate 120, the third channel plate 210, the fourth channel plate 220, the first gear 511, or the second gear 512 may be all active components. The power mechanism may be, for example, a rotary electric machine.

Example 2

The present embodiment provides a cash recycling apparatus including an upper device 2, a lower device 3, and a sheet-like medium conveyance device 1 as described in the embodiment communicating between the upper device 2 and the lower device 3, wherein:

the upper device 2 comprises a coin inlet mechanism 21, a coin outlet mechanism 22, a temporary storage mechanism 23, a paper money identification mechanism and a channel for connecting the coin inlet mechanism 21, the coin outlet mechanism 22, the temporary storage mechanism 23 and the paper money identification mechanism, wherein the channel comprises a common channel 24, and the common channel 24 is connected with the lower device 3 through a plurality of sheet-like medium conveying devices 1.

The lower device 3 comprises a plurality of banknote boxes 31, each banknote box 31 is correspondingly provided with one sheet type medium conveying device 1, banknotes can enter the banknote box 31 from the common channel 24 through the sheet type medium conveying devices 1, and conversely, the banknotes can enter the common channel 24 from the banknote box 31 through the sheet type medium conveying devices 1.

In a normal working state, the sheet-like medium conveying device 1 is in a first state, the lateral gaps between the first channel plate 110 and the third channel plate 210 and the upper device 2 are small, and the lateral gaps between the second channel plate 120 and the fourth channel plate 220 and the lower device 3 are small, so that during normal conveying of paper money, the paper money always flows along the medium conveying channel and cannot enter the lateral gaps between the first channel plate 110 and the third channel plate 210 and the upper device 2 and the lateral gaps between the second channel plate 120 and the fourth channel plate 220 and the lower device 3.

When the upper device 2 is pulled out, for example, in a left direction in fig. 6, at this time, the sheet type medium conveying device 1 is changed from the first state to the second state, the first channel plate 110 and the third channel plate 210 are opened to form an included angle, the second channel plate 120 and the fourth channel plate 220 are opened to form an included angle, a lateral gap between the first channel plate 110 and the third channel plate 210 and the upper device 2 is enlarged, and a lateral gap between the second channel plate 120 and the fourth channel plate 220 and the lower device 3 is enlarged, so even if there are banknotes in the sheet type medium conveying device 1 during the process of pulling out the upper device 2, a bent portion of the banknotes enters the lateral gap along with the pulling process, and the problem of the existing torn banknotes is effectively avoided.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the invention has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims (10)

1. The sheet medium conveying device is characterized by comprising a first channel plate assembly, a second channel plate assembly and a driving assembly, wherein the sheet medium conveying device is provided with a first state and a second state, and the driving assembly is used for driving the sheet medium conveying device to be switched between the first state and the second state;

the first channel plate assembly comprises a first channel plate and a second channel plate which are adjacently arranged; the second channel plate assembly comprises a third channel plate and a fourth channel plate which are adjacently arranged, and the driving assembly is in transmission connection with the first channel plate;

when the sheet medium conveying device is in a first state, the first channel plate is opposite to the third channel plate, a first channel is formed between the first channel plate and the third channel plate, the second channel plate is opposite to the fourth channel plate, a second channel is formed between the second channel plate and the fourth channel plate, and the first channel is communicated with the second channel to form a medium conveying channel;

when the sheet-like medium conveying device is in the second state, one end, far away from the third channel plate, of the first channel plate is far away from one end, far away from the fourth channel plate, of the third channel plate, and/or one end, far away from the first channel plate, of the second channel plate is far away from one end, far away from the third channel plate, of the fourth channel plate, so that the medium conveying channel is opened.

2. The sheet-like medium conveying apparatus according to claim 1,

the first channel plate and the second channel plate are each movable in a direction away from the medium transport path, and/or the third channel plate and the fourth channel plate are each movable in a direction away from the medium transport path to open the medium transport path.

3. The sheet-like medium conveying apparatus according to claim 2,

the first channel plate and the second channel plate are in transmission connection through a first synchronous mechanism; the first synchronization mechanism is used for synchronously driving the first channel plate and the second channel plate to be close to or far away from the medium conveying channel.

4. The sheet-like medium conveying apparatus according to claim 3,

the first synchronization mechanism includes a first tooth-shaped portion provided at an end of the first channel plate close to the second channel plate, and a second tooth-shaped portion provided at an end of the second channel plate close to the first channel plate, the first tooth-shaped portion and the second tooth-shaped portion being engaged with each other.

5. The sheet-like medium conveying apparatus according to claim 2,

the third channel plate and the fourth channel plate are in transmission connection through a second synchronization mechanism, and the second synchronization mechanism is used for synchronously driving the third channel plate and the fourth channel plate to be close to or far away from the medium conveying channel.

6. The sheet-like medium conveying apparatus according to claim 5,

the second synchronization mechanism includes a third tooth portion provided at an end of the third channel plate close to the fourth channel plate, and a fourth tooth portion provided at an end of the fourth channel plate close to the third channel plate, the third tooth portion and the fourth tooth portion being engaged with each other.

7. The sheet-like medium conveying apparatus according to claim 1,

the first channel plate assembly and the second channel plate assembly are symmetrically disposed about the media transport channel.

8. The sheet-like medium conveying apparatus according to claim 2,

the driving assembly comprises a third synchronizing mechanism, and the third synchronizing mechanism is respectively connected with the first channel plate and the third channel plate and is used for synchronously driving the first channel plate and the third channel plate to be close to or far away from the medium conveying channel.

9. The sheet-like medium conveying apparatus according to claim 8,

the third synchronous mechanism comprises a first gear and a second gear which are connected in a meshing manner;

the first gear is coaxially and fixedly connected with the first channel plate, and the second gear is coaxially and fixedly connected with the third channel plate;

or,

the first gear is coaxially and fixedly connected with the second channel plate, and the second gear is coaxially and fixedly connected with the fourth channel plate.

10. A cash recycling apparatus comprising the sheet-like medium conveyance device according to any one of claims 1 to 9.