CN108198330B - Bidirectional gate mechanism - Google Patents

Abstract

The invention discloses a two-way gate mechanism, comprising: a frame-type base, a banknote outlet gate mechanism and a banknote inlet gate mechanism; the two sides of the base are respectively provided with a banknote outlet and a banknote inlet; the banknote outlet gate mechanism comprises a banknote outlet gate baffle and a banknote outlet driving device for driving the banknote outlet gate baffle to open or close a banknote outlet; the banknote inlet gate mechanism comprises a banknote inlet gate baffle and a banknote inlet driving device for driving the banknote inlet gate baffle to open or close a banknote inlet; the middle part of the base is provided with a power bin, and the banknote outlet driving device and the banknote inlet driving device are arranged in the power bin. The two-way gate mechanism integrates the banknote outlet gate mechanism, the banknote inlet gate mechanism and the two groups of power devices together through the base, adopts a modularized integrated design, is convenient to be connected to the existing automatic teller machine, and meets the requirement of large-amount cash transaction.

Description

Bidirectional gate mechanism

Technical Field

The invention relates to an automatic teller machine, in particular to an integrated bidirectional gate mechanism with a banknote outlet and a banknote inlet.

Background

The existing CRS automatic teller machine in the current market mainly has the following structural designs:

first kind: the bill inlet is an open gate-free mechanism or a hand-push gate mechanism, and the bill outlet adopts a plastic gate mechanism on the cash recycling machine as a protective gate. The disadvantages of this approach are: the cash inlet is not provided with a gate mechanism, so that objects are easy to drop into the cash inlet, the cash recycling machine cash inlet mechanism is damaged, and the cash can not be normally fed; the banknote inlet adopts a hand-push type gate mechanism, which can effectively prevent articles from falling in, but the hand-push type gate is often opened and closed, so that the use of customers is inconvenient; the cash outlet adopts a gate mechanism on the cash recycling machine, and cannot meet the national security requirements.

Second kind: the automatic teller machine with the same gate for the banknote outlet and the banknote inlet has two kinds of hand pushing mechanism and automatic mechanism. The single gate can meet the functions of banknote discharging and banknote feeding, supports small-amount transaction, has low efficiency of large-amount transaction and can not meet the security requirement by hand pushing.

Third kind: the cash outlet and the cash inlet are both of an automatic gate mechanism, and the cash inlet meets the security requirement, and the cash outlet cannot meet the security requirement in the anti-prying performance because of adopting an automatic turning-up mode.

Fourth kind: the banknote outlet and the banknote inlet are both provided with an automatic gate mechanism, and accord with the security requirements, but a split gate mechanism is adopted. The split gate mechanism occupies a large space in design form, and the financial institutions currently require miniaturization as much as possible on the modeling of the CRS automatic teller machine, and meanwhile, functional modules are more and more. If the split type structural design is adopted, the layout of other functional modules can be influenced, and the modeling design of the product can be limited.

Disclosure of Invention

The object of the present invention is to provide a bi-directional gate mechanism to solve at least one of the above technical problems.

According to one aspect of the present invention, there is provided a bi-directional gate mechanism comprising a frame-shaped base, and a banknote outlet gate mechanism and a banknote inlet gate mechanism; the two sides of the base are respectively provided with a banknote outlet and a banknote inlet; the banknote outlet gate mechanism comprises a banknote outlet gate baffle and a banknote outlet driving device for driving the banknote outlet gate baffle to open or close a banknote outlet; the banknote inlet gate mechanism comprises a banknote inlet gate baffle and a banknote inlet driving device for driving the banknote inlet gate baffle to open or close a banknote inlet; the middle part of the base is provided with a power bin, and the banknote outlet driving device and the banknote inlet driving device are arranged in the power bin.

The two-way gate mechanism integrates the banknote outlet gate mechanism, the banknote inlet gate mechanism and the two groups of power devices together through the base, adopts a modularized integrated design, is convenient to be connected to the existing automatic teller machine, and meets the requirement of large-amount cash transaction.

In some embodiments, the banknote outlet gate mechanism of the bidirectional gate mechanism comprises a banknote outlet driving wheel set and a banknote outlet driven wheel set which are arranged in parallel, and a banknote outlet synchronous component; the banknote discharging driving wheel set and the banknote discharging driven wheel set are hinged with the base, the banknote discharging synchronous component is sleeved on the banknote discharging driving wheel set and the banknote discharging driven wheel set, and the banknote discharging gate baffle is arranged on the banknote discharging synchronous component; the banknote discharging driving device drives the banknote discharging driving wheel set to rotate; the banknote feeding gate mechanism comprises a banknote feeding driving wheel set, a banknote feeding driven wheel set and a banknote feeding synchronous component which are arranged in parallel; the banknote feeding driving wheel set and the banknote feeding driven wheel set are hinged with the base, the banknote feeding synchronous component is sleeved on the banknote feeding driving wheel set and the banknote feeding driven wheel set, and the banknote feeding gate baffle is arranged on the banknote feeding synchronous component; the banknote feeding driving device drives the banknote feeding driving wheel set to rotate.

In some embodiments, two ends of a banknote discharging driving wheel set of the bidirectional gate mechanism are respectively hinged with the side wall of the power bin; the banknote discharging driven wheel group is arranged outside the base frame, and two ends of the banknote discharging driven wheel group are respectively hinged with the side wall of the base; two ends of the banknote feeding driving wheel set are respectively hinged with the side wall of the power bin; the banknote feeding driven wheel group is arranged outside the base frame, and two ends of the banknote feeding driven wheel group are respectively hinged with the side wall of the base.

In some embodiments, the bi-directional gate mechanism of the present invention further comprises a gate locking mechanism; the gate locking mechanism comprises a lock tongue arranged on the banknote inlet gate baffle or/and the banknote outlet gate baffle, and an electromagnetic bolt arranged on the base; the bolt is provided with a jack matched with the inserted bar of the electromagnetic bolt, and the inserted bar of the electromagnetic bolt is connected with the body through a pressure elastic component. Therefore, the anti-explosion, anti-prying and other security performances of the banknote inlet gate baffle or the banknote outlet gate baffle can be improved.

In some embodiments, a bevel or a cambered surface is arranged on one side, close to the outer frame of the base, of the lock tongue of the bidirectional gate mechanism. The arrangement of the inclined plane or the cambered surface can enable the operation of the gate locking mechanism to be smoother.

In some embodiments, through holes are arranged on the side wall of the base of the bidirectional gate mechanism, and the banknote inlet gate baffle plate or/and the banknote outlet gate baffle plate penetrate through the through holes, and the height of the through holes is matched with the thickness of the banknote inlet gate baffle plate or the banknote outlet gate baffle plate. Therefore, the anti-explosion, anti-prying and other security performances of the banknote inlet gate baffle or the banknote outlet gate baffle can be improved.

In some embodiments, the outer side surface of the base of the bidirectional gate mechanism is provided with a guide rail, and the edge of the banknote inlet gate baffle or the banknote outlet gate baffle is provided with a U-shaped roller bearing matched with the guide rail. The arrangement can enable the banknote inlet gate baffle or the banknote outlet gate baffle to run more stably and smoothly, and can also play the role of improving the security performance such as explosion protection, prying protection and the like.

In some embodiments, the bidirectional gate mechanism of the present invention further comprises a banknote output transmission component, the banknote output driving device drives the banknote output transmission component to rotate, and the banknote output transmission component drives the banknote output driving wheel set to rotate; the banknote feeding mechanism also comprises a banknote feeding transmission part, wherein the banknote feeding driving device drives the banknote feeding transmission part to rotate, and the banknote feeding transmission part drives the banknote feeding driving wheel set to rotate. The arrangement can make the space use of the two-way gate mechanism more effective and more reasonable.

In some embodiments, the base of the bidirectional gate mechanism is formed by connecting six sheet metal parts through fastening screws, three cavities of a banknote inlet, a power bin and a banknote outlet are formed, and all fasteners are arranged on the outer side surface of the base or in the power bin. Therefore, the surfaces of the banknote inlet and the banknote outlet are smooth, and the hand is prevented from being scratched during operation of a user.

Drawings

FIG. 1 is a schematic view of a bi-directional gate mechanism according to an embodiment of the present invention;

FIG. 2 is a schematic view of the bi-directional gate mechanism of FIG. 1 from another angle;

FIG. 3 is an exploded view of the bi-directional gate mechanism of FIG. 1;

FIG. 4 is a schematic view showing a structure of a closing state of a shutter locking mechanism according to an embodiment of the present invention;

FIG. 5 is a schematic view showing the structure of the gate locking mechanism shown in FIG. 4 in an opened state;

fig. 6 is a schematic structural view of a U-shaped linear roller guide rail driving gate mechanism according to an embodiment of the present invention.

Detailed Description

The invention is described in further detail below with reference to the accompanying drawings.

Fig. 1 to 3 schematically show the structure of a bidirectional gate mechanism according to an embodiment of the present invention.

As shown in fig. 1 to 3, the bidirectional gate mechanism includes a base 30, a banknote outlet gate mechanism 10, and a banknote inlet gate mechanism 20.

The base 30 is formed by connecting six sheet metal parts through fastening screws, three spaces of a banknote inlet 32, a power bin 33 and a banknote outlet 31 are sequentially formed, and all fasteners are arranged on the outer side surface of the base 30 or in the power bin 33. This ensures that the inner surfaces of the banknote inlet 32 and the banknote outlet 31 are smooth, and prevents the user from scratching the hands during operation. In other embodiments, the six sheet metal parts may be formed by welding or other means.

The bill outlet 31 and the bill inlet 32 are respectively arranged at two sides of the base 30.

The banknote outlet shutter mechanism 10 includes a banknote outlet shutter plate 11, and a banknote outlet driving device 14 that drives the banknote outlet shutter plate 11 to open or close the banknote outlet 31. The banknote outlet gate mechanism 10 further comprises a banknote outlet driving wheel set 131, a banknote outlet driven wheel set 132 and a banknote outlet synchronizing component 122, which are arranged in parallel. The banknote discharging driving wheel set 131 and the banknote discharging driven wheel set 132 are hinged with the base 30, the hinged positions are positioned on the side wall of the power bin 33, and are arranged on the left side plate and the right side plate of the base 30 through flange bearings, and the positions are limited through split collars. The banknote output driven wheel set 132 is arranged outside the frame of the base 30, and two ends of the banknote output driven wheel set are respectively hinged with the side wall of the base 30. The banknote discharging synchronous component 122 is sleeved on the banknote discharging driving wheel group 131 and the banknote discharging driven wheel group 132, and the banknote discharging gate baffle 11 is fixedly arranged on the banknote discharging synchronous component 122 through the synchronous component pressing plate 133. The banknote discharging driving device 14 drives the banknote discharging driving wheel set 131 to rotate, the banknote discharging driving wheel set 131 drives the banknote discharging synchronous component 122 to rotate, the banknote discharging synchronous component 122 drives the banknote discharging gate baffle 11 to reciprocate along a straight line, and the banknote discharging driven wheel set 132 rotates along with the rotation of the banknote discharging driving wheel set 131. The banknote outlet gate mechanism 10 is also provided with a banknote outlet transmission part 121, and the banknote outlet driving device 14 drives the banknote outlet transmission part 121 to rotate, and the banknote outlet transmission part 121 drives the banknote outlet driving wheel set 131 to rotate.

The banknote gate mechanism 20 includes a banknote gate shutter 21, and a banknote gate drive device 24 that drives the banknote gate shutter 21 to open or close a banknote gate 32. And further comprises a banknote feeding driving wheel set 231, a banknote feeding driven wheel set 232 and a banknote feeding synchronous component 222 which are arranged in parallel. The banknote feeding driving wheel set 231 and the banknote feeding driven wheel set 232 are hinged with the base 30, the hinged positions are located on the side wall of the power bin 33, and are mounted on the left side plate and the right side plate of the base 30 through flange bearings, and the positions are limited through split collars. The paper money feeding passive wheel set 232 is arranged outside the frame of the base 30, and two ends of the paper money feeding passive wheel set are respectively hinged with the side wall of the base 30. The banknote inlet synchronous component 222 is sleeved on the banknote inlet driving wheel set 231 and the banknote inlet driven wheel set 232, and the banknote inlet gate baffle 21 is fixedly arranged on the banknote inlet synchronous component 222 through a synchronous component pressing plate. The banknote feeding driving device 24 drives the banknote feeding driving wheel set 231 to rotate, the banknote feeding driving wheel set 231 drives the banknote feeding synchronous component 222 to rotate, the banknote feeding synchronous component 222 drives the banknote feeding gate baffle 21 to reciprocate along a straight line, and the banknote feeding driven wheel set 232 rotates along with the rotation of the banknote feeding driving wheel set 231. The banknote feeding gate mechanism 20 is also provided with a banknote feeding transmission part 221, and the banknote feeding driving device 24 drives the banknote feeding transmission part 221 to rotate, and the banknote feeding transmission part 221 drives the banknote feeding driving wheel set 231 to rotate.

In the present embodiment, the banknote dispensing drive unit 14 and the banknote dispensing drive unit 24 are both dc motors, and are fixedly disposed on the left and right side plates of the power compartment 33 of the base 30. Thus, the power part and the transmission part of the whole bidirectional gate mechanism form a whole, and the modularized design is convenient for being connected to the existing automatic teller machine. In other embodiments, the banknote dispensing drive mechanism 14 and the banknote dispensing drive mechanism 24 may be driven by air cylinders or electromagnets.

In the present embodiment, the banknote output synchronizing member 122, the banknote input synchronizing member 222, the banknote output transmission member 121, and the banknote input transmission member 221 each employ a timing belt. The machine has the advantages of low noise, small volume, stable operation and lower processing cost in operation. In other embodiments, the banknote output synchronizing member 122, the banknote input synchronizing member 222, the banknote output transmission member 121, and the banknote input transmission member 221 may also employ racks or transmission chains, etc.

Fig. 4 schematically shows a structure of a closed state of a shutter lock mechanism according to an embodiment of the present invention.

As shown in fig. 4, the bi-directional gate mechanism may also include a gate locking mechanism. The gate locking mechanism is installed at the outer side of the right side wall of the base 30. The gate locking mechanism of the banknote gate mechanism 10 includes a lock tongue 111 provided on the banknote gate shutter 11, and an electromagnetic latch 50 provided on the base 30. The lock tongue 111 is fixed to the banknote outlet shutter 11 by a fastener, and can be regarded as a "moving member". The electromagnetic latch 50 is secured to the outer side of the base 30 by fasteners, which may be referred to as "fasteners". The dead bolt 111 is provided with a jack 54 which is matched with the inserted link 51 of the electromagnetic bolt 50, and the inserted link 51 of the electromagnetic bolt 50 is connected with the body 53 through a pressure elastic part 52. When the electromagnetic latch 50 is not energized, the plunger 51 is acted upon by the pressure elastic member 52 and is in an extended state. An inclined surface is arranged on one side of the lock tongue 111, which is close to the outer frame of the base 30. In other embodiments, the side of the latch 111 near the outer frame of the base 30 may be configured as a cambered surface.

When the banknote outlet shutter 11 moves from the "open state" to the "closed state", the insertion rod 51 of the electromagnetic latch 50 contacts the inclined surface of the lock tongue 111, the inclined surface gradually retracts the insertion rod 51 toward the body of the electromagnetic latch 50, the insertion rod 51 of the electromagnetic latch moves to the position of the insertion hole 54 on the lock tongue 111, and the insertion rod 51 of the electromagnetic latch 50 protrudes from the pressure elastic member 52 and is inserted into the insertion hole 54 on the lock tongue 111. The banknote outlet gate baffle 11 is in a locking state at this time, and external force cannot push the banknote outlet gate baffle 11 open. During this process, electromagnetic latch 50 is not energized.

Fig. 5 schematically shows a structure of the shutter lock mechanism shown in fig. 4 in an open state.

As shown in fig. 5, when the banknote outlet shutter 11 moves from the "closed state" to the "open state", the electromagnetic latch 50 is energized, the insertion rod 51 of the electromagnetic latch 50 is retracted, and after the insertion rod 51 is completely separated from the insertion hole 54, the banknote outlet driving device 14 drives the banknote outlet shutter 11 to move in a direction of opening the banknote outlet 31. When the dead bolt 111 is completely moved out of the working range of the electromagnetic bolt 50, the electromagnetic bolt 50 is powered off, and the inserted rod 51 of the electromagnetic bolt is extended to reset under the action of the pressure elastic part 52.

In the present embodiment, the pressure elastic member 52 employs a pressure spring. In other embodiments, the pressure spring 52 may also be a torsion spring, pneumatic cylinder, hydraulic cylinder, or the like.

Similarly, the banknote inlet shutter 21 may be controlled to be locked and unlocked by the shutter locking mechanism.

At two limit points of the reciprocating movement of the banknote outlet shutter 11, position sensors 37 are respectively provided, corresponding to the closed state and the open state of the banknote outlet shutter 11, respectively. When the banknote outlet gate baffle 11 moves from the open state to the closed state, the gate locking mechanism also works simultaneously at the moment of entering the closed state, and the gate plate cannot be pushed manually at the moment.

Before the banknote outlet gate baffle 11 is ready to run from the "closed state" to the "open state", the gate locking mechanism is unlocked at this time, so that the constraint of the gate locking mechanism on the banknote outlet gate baffle 11 is released, which corresponds to an automatic unlocking process.

Similarly, at two limit points of the reciprocating movement of the banknote gate baffle 21, position sensors 37 may be respectively provided, corresponding to the closed state and the open state of the banknote gate baffle 21, respectively.

The electromagnetic latch 50 can be controlled to be powered on and off by the control system 40 to control the locking and unlocking of the banknote outlet gate baffle 11 or the banknote inlet gate baffle 21 and the rotation states of the banknote outlet driving device 14 and the banknote inlet driving device 24, including the rotation direction, the rotation speed and the like.

Fig. 6 schematically shows the structure of a U-shaped linear roller guide drive gate mechanism according to one embodiment of the present invention.

As shown in fig. 6, a via hole 34 may be further provided on the sidewall of the base 30, the banknote inlet gate baffle 21 penetrates through the via hole 34, and the height of the via hole 34 is adapted to the thickness of the banknote inlet gate baffle 21 or the banknote outlet gate baffle 11.

Two outer side surfaces of the base 30 are respectively provided with a guide rail 35, two side edges of the banknote inlet gate baffle 21 are respectively provided with two groups of U-shaped roller bearings 36 matched with the guide rails 35, the U-shaped roller bearings 36 reciprocate along the guide rails 35, and two limit points of the reciprocating movement correspond to the opening state and the closing state of the banknote inlet gate baffle 21 respectively.

When an external force F acts on the banknote inlet gate baffle 21 from top to bottom, the banknote inlet gate baffle 21 generates certain bending deformation, and the deformed banknote inlet gate baffle 21 contacts the left and right side plates of the base 30, so that the destructive force is transferred to the left and right side plates of the base 30, and the U-shaped roller bearing 36 can be effectively prevented from falling out of the guide rail 35.

In this embodiment, the guide rail 35 is semi-cylindrical. In other embodiments, the guide rail 35 may be rectangular, cylindrical, or other cylindrical shape.

Similarly, the U-shaped linear roller guide rail transmission gate mechanism can also be arranged on the banknote outlet gate baffle 11. The side wall of the base 30 can be provided with a through hole 34 for the banknote outlet gate baffle 11 to penetrate, so that the security performance of the banknote outlet gate mechanism 10, such as explosion protection, prying protection and the like, is improved.

What has been described above is merely some embodiments of the present invention. It will be apparent to those skilled in the art that various modifications and improvements can be made without departing from the spirit of the invention.

Claims (8)

1. Two-way gate mechanism, its characterized in that includes: a frame-type base (30), a banknote outlet gate mechanism (10) and a banknote inlet gate mechanism (20);

two sides of the base (30) are respectively provided with a banknote outlet (31) and a banknote inlet (32);

the banknote outlet gate mechanism (10) comprises a banknote outlet gate baffle (11) and a banknote outlet driving device (14) for driving the banknote outlet gate baffle (11) to open or close the banknote outlet (31);

the banknote inlet gate mechanism (20) comprises a banknote inlet gate baffle (21) and a banknote inlet driving device (24) for driving the banknote inlet gate baffle (21) to open or close the banknote inlet (32);

the middle part of the base (30) is provided with a power bin (33), and the banknote outlet driving device (14) and the banknote inlet driving device (24) are arranged in the power bin (33);

the banknote outlet gate mechanism (10) comprises a banknote outlet driving wheel set (131) and a banknote outlet driven wheel set (132) which are arranged in parallel, and a banknote outlet synchronous component (122);

the banknote discharging driving wheel set (131) and the banknote discharging driven wheel set (132) are hinged with the base (30), the banknote discharging synchronous component (122) is sleeved on the banknote discharging driving wheel set (131) and the banknote discharging driven wheel set (132), and the banknote discharging gate baffle (11) is arranged on the banknote discharging synchronous component (122);

the banknote discharging driving device (14) drives the banknote discharging driving wheel set (131) to rotate;

the banknote inlet gate mechanism (20) comprises a banknote inlet driving wheel set (231) and a banknote inlet driven wheel set (232) which are arranged in parallel, and a banknote inlet synchronous component (222);

the banknote feeding driving wheel set (231) and the banknote feeding driven wheel set (232) are hinged with the base (30), the banknote feeding synchronous component (222) is sleeved on the banknote feeding driving wheel set (231) and the banknote feeding driven wheel set (232), and the banknote feeding gate baffle (21) is arranged on the banknote feeding synchronous component (222);

the banknote feeding driving device (24) drives the banknote feeding driving wheel set (231) to rotate.

2. The bidirectional gate mechanism according to claim 1, wherein two ends of the banknote discharging driving wheel set (131) are respectively hinged with the side wall of the power bin (33);

the banknote discharging driven wheel set (132) is arranged outside the frame of the base (30), and two ends of the banknote discharging driven wheel set are respectively hinged with the side wall of the base (30);

two ends of the banknote feeding driving wheel set (231) are respectively hinged with the side wall of the power bin (33);

the paper money feeding passive wheel set (232) is arranged outside the frame of the base (30), and two ends of the paper money feeding passive wheel set are respectively hinged with the side wall of the base (30).

3. The bi-directional gate mechanism of claim 1 further comprising a gate locking mechanism;

the gate locking mechanism comprises a lock tongue (111) arranged on the banknote inlet gate baffle (21) or/and the banknote outlet gate baffle (11), and an electromagnetic bolt (50) arranged on the base (30);

the bolt (111) is provided with a jack (54) which is matched with the inserted rod (51) of the electromagnetic bolt (50), and the inserted rod (51) of the electromagnetic bolt is connected with the body (53) through a pressure elastic part (52).

4. A two-way gate mechanism according to claim 3, characterized in that a bevel or a cambered surface is provided on the side of the lock tongue (111) close to the outer frame of the base (30).

5. The bidirectional gate mechanism according to claim 1, wherein a via hole (34) is arranged on the side wall of the base (30), the banknote inlet gate baffle (21) and/or the banknote outlet gate baffle (11) penetrate through the via hole (34), and the height of the via hole (34) is adapted to the thickness of the banknote inlet gate baffle (21) and/or the banknote outlet gate baffle (11).

6. The bidirectional gate mechanism according to claim 5, wherein the outer side surface of the base (30) is provided with a guide rail (35), and the edge of the banknote inlet gate baffle (21) or the banknote outlet gate baffle (11) is provided with a U-shaped roller bearing (36) which is matched with the guide rail (35).

7. The bidirectional gate mechanism according to claim 1, further comprising a banknote output transmission component (121), wherein the banknote output driving device (14) drives the banknote output transmission component (121) to rotate, and the banknote output transmission component (121) drives the banknote output driving wheel set (131) to rotate;

the banknote feeding mechanism also comprises a banknote feeding transmission part (221), wherein the banknote feeding transmission part (221) is driven by the banknote feeding driving device (24) to rotate, and the banknote feeding transmission part (221) drives the banknote feeding driving wheel set (231) to rotate.

8. The bidirectional gate mechanism according to any one of claims 1 to 7, wherein the base (30) is formed by connecting six sheet metal parts through fastening screws, three cavities of a banknote inlet (32), a power bin (33) and a banknote outlet (31) are formed, and all fasteners are arranged on the outer side surface of the base (30) or in the power bin (33).