WO2011019244A2 - Media stacking apparatus of automatic media dispenser - Google Patents

Abstract

The present invention relates to a media stacking apparatus of an automatic media dispenser, wherein a stacking plate (34) is movably installed in a stacking space (32) which is formed between mounting frames (30), media are stacked on the stacking plate (34), and a diverter (40) is rotated in both directions by a driving source and determines a transferring path of the media inserted through an entrance (36). In addition, the invention comprises a pressurizing member (66) which is rotated by receiving power from the driving source, and pressurizes abnormally-stacked media so that the pressurized media may smoothly be stacked on the stacking plate (34). Thus, according to the present invention, when an abnormal medium is inserted, the pressurizing member presses the upper side of the medium whereby the medium is stably stacked on the stacking plate. Accordingly, the invention is capable of preventing a jam between the medium and another medium which is injected later. Further, since the diverter and the pressurizing member are driven with the one driving source, the number of components is reduced.

Description

Media integration device of media dispenser

The present invention relates to a media dispenser, and more particularly, to a media accumulation apparatus for stably accumulating media in a media collection unit provided inside the media dispenser.

The automatic media dispenser can pay or receive media such as cash, checks, slips, receipts, and various forms of paper. An example of such a media dispenser is an automated-teller machine. The automated teller machine is a device that allows customers to directly deposit or withdraw cash or checks without going through a bank window. Such automated teller machines are widely used to provide efficient banking and customer convenience.

1 is a side view showing the configuration of a media accumulation apparatus for a media dispenser according to the prior art.

According to this, the appearance of the media accumulation apparatus is formed by the mounting frame (2). The mounting frame 2 is generally made of a metal material, and is installed at predetermined intervals on both sides of the media accumulation apparatus.

An integrated space 4 is formed between the mounting frames 2 to accumulate the medium m. In the integrated space 4, the medium m is drawn in from the top and accumulated one by one. In the integrated space 4 an abnormal medium m, for example a damaged or crumpled medium m, is accumulated.

In addition, the integrated plate 6 is installed to be elevated in the integrated space 32. The integrated plate 6 is the portion where the medium m is substantially integrated. The integrated plate 6 is elevated in the integrated space 4 in a state of being connected with the belt.

An inlet 8 is formed in the upper portion of the mounting frame 2 to allow the medium m to be drawn in. The medium passing through the inlet 8 is divided into two conveying channels 9 and 10 and conveyed. The normal medium m is transported to the first transport channel 9, and the abnormal medium m is transported along the second transport channel 10 to be integrated in the integrated space 4. An end of the second transfer channel 10 communicates with the integrated space 4, and the medium m accumulated in the integrated space 4 may be directly recovered by an operator.

Meanwhile, the path m of the medium m is determined by the diverter 12. The diverter 12 is rotatably mounted to the mounting frame 2. The diverter 12 receives power from the solenoid 24 and rotates in both directions to shield one of the passages connected to the first and second transfer channels 9 and 10. That is, the diverter 12 blocks a passage to the second transfer channel 10 when the normal medium m is input, and opens a passage to the first transfer channel 9 when the abnormal medium m is injected. Blocking to determine the transport path of the medium (m).

And an inlet roller 14 is rotatably installed in a portion adjacent to the inlet 8. The inlet roller 14 serves to guide the medium m drawn into the inlet 8 so that it can be conveyed toward the diverter 12.

In the first and second transfer channels 9 and 10, feed rollers 16 for feeding the medium m are rotatably installed. Meanwhile, the discharge roller 18 is rotatably installed at the end of the first transfer channel 9. The discharge roller 18 serves to guide the medium (m) one by one in the first transfer channel (9).

In addition, the controller 20 is rotatably installed at the end of the second transfer channel 10. The controller 20 guides the medium m passing through the second transfer channel 10 to be integrated into the integrated space 4. A plurality of stacking wheels 22 are provided on the roller shaft of the controller 20. The stacking wheel 22 strikes the upper surface of the medium m discharged from the second transfer channel 10 so that the medium m can be stably integrated in the integrated plate 6. The stacking wheel 22 may be provided on the roller shaft at a plurality of predetermined intervals.

On the other hand, the mounting frame 2 is provided with a solenoid 24 acting as a drive source. The solenoid 24 provides power required for driving the diverter 12.

The plunger 25 is installed on the solenoid 24 so as to be movable in and out of the solenoid 24. The plunger 25 normally protrudes out of the solenoid 24 and is inserted into the solenoid 24 when an electromagnetic force is applied to the solenoid 24.

In addition, the driving member 26 is rotatably installed at the tip of the plunger 25. The driving member 26 receives power from the solenoid 24 and transmits the power to the diverter 12. The driving member 26 is formed with a guide slot 27 is inserted into the guide pin (P) guide. The guide slot 60 has a long hole shape for interlocking with the diverter member 28.

A diverter member 28 is rotatably connected to one end of the drive member 26. One end of the diverter member 28 is provided with an interlocking pin (P), the interlocking pin (P) is rotated while being guided along the guide slot (27). One side of the diverter member 28 is connected to the diverter 12 to rotate the diverter 12.

However, the prior art as described above has the following problems.

In the prior art, an abnormal medium m is integrated into the integrated space 4. Therefore, when the integration of the medium m is completed, the integrated plate 6 is raised. In this case, as illustrated in FIG. 1, the wrinkled or bent medium m may be caught by the stacking wheel 22 disposed on the upper part of the integrated space 4, and thus may not be normally integrated.

When the medium m is abnormally accumulated in this manner, since the medium m to be subsequently accumulated is not evenly accumulated, jams may occur between the media m. Jams like this may cause device malfunctions. In addition, if the medium m is not evenly integrated, there is a problem that the volume of the integrated space 4 is also reduced.

Accordingly, an object of the present invention is to solve the problems of the prior art as described above, and to uniformly integrate an abnormally integrated medium.

Another object of the present invention is to reduce the number of parts used in the media accumulation apparatus.

Technical problems to be achieved by the present invention are not limited to the above-mentioned technical problems, and other technical problems not mentioned above will be clearly understood by those skilled in the art from the following description. Could be.

According to a feature of the present invention for achieving the above object, the mounting frame; An integrated plate movably installed in an integrated space formed between the mounting frames, for accumulating media; A diverter configured to determine a conveying path of a medium that is rotated in both directions by a driving source and is drawn in; It is characterized in that it comprises a pressing member for rotating the power received from the drive source, pressurizing the abnormally integrated medium evenly integrated on the integrated plate.

According to another feature of the invention, the mounting frame; An integrated plate movably installed in an integrated space formed between the mounting frames, for accumulating media; A diverter configured to determine a conveying path of a medium that is rotated in both directions by a driving source and is drawn in; A pressing member which is rotated by receiving power from the driving source and presses and presses an upper surface of the medium integrated in the integrated plate; And an auxiliary pressurizing member for guiding the medium introduced into the integrated space and pressurizing the medium together with the pressing member when the integrated plate is raised in a state in which the medium is integrated.

The diverter is controlled so that normal media is transported to the first transport channel, abnormal media is transported to the second transport channel, and an end of the second transport channel is in communication with the integrated space.

The pressing member may be rotated upward when the medium is introduced into the integrated space to prevent interference with the medium.

The driving source is a solenoid in which the plunger is movable in and out, and a driving member is rotatably provided at the tip of the plunger, and the driving member transmits the power transmitted from the solenoid to the diverter and the pressing member. It features.

The pressing member is rotatably connected to the interlocking member through a rotating shaft, the pressing member is characterized in that a plurality is installed on the rotating shaft.

The auxiliary pressing member is rotated while the integrated plate is raised and pressurized by the medium, and is hooked on the end of the pressing member so that the pressing member is rotated in the direction of pressing the medium.

The media accumulation apparatus of the present invention is characterized in that it further comprises a drive source for simultaneously transmitting power to the diverter and the pressing member.

The media accumulation device of the present invention, the drive source for transmitting power to the diverter and the pressing member at the same time; And a sensor for sensing the auxiliary pressing member rotated while pressurizing the medium to transmit a stop signal to the integrated plate.

In the present invention, when the medium is abnormally accumulated, the pressing member and the auxiliary pressing member press the upper surface of the medium so that they can be integrated evenly. Therefore, there is an effect that is prevented from occurring after the input medium and jam. In this way, evenly accumulating media can maximize the volume of the integrated space.

In addition, in the present invention, since the diverter and the pressing member can be driven by one driving source, the number of parts is reduced.

1 is a side view showing the configuration of a media accumulation apparatus for an automatic media dispenser according to the prior art.

Figure 2 is a side view showing the configuration of a media accumulation apparatus of the automatic teller machine according to the first embodiment of the present invention.

3 is a side view showing a state in which the medium is pressed by the media accumulation device of the automatic teller machine according to the first embodiment of the present invention.

Figure 4 is a side view showing the configuration of a media accumulation apparatus for a media dispenser according to a second embodiment of the present invention.

5 is a side view showing a state in which the medium is pressed by the media accumulation device of the automatic teller machine according to the second embodiment of the present invention.

6 is an operational state diagram showing a process in which the medium is pressurized by the media accumulation device of the automatic media dispenser according to the second embodiment of the present invention.

Hereinafter, a preferred embodiment of a media accumulation apparatus for a media dispenser according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a side view showing the configuration of a media accumulator of a media dispenser according to a first embodiment of the present invention, and FIG. 3 is a pressurized medium by a media accumulator of a media dispenser according to a first embodiment of the present invention. It is the side view which showed the state.

As shown in these figures, the appearance of the media accumulation apparatus is formed by the mounting frame 30. The mounting frame 30 is generally made of a metal material, and is installed at predetermined intervals on both sides of the media accumulation apparatus. Of course, the mounting frame 30 may be installed on both sides as well as other parts of the media storage device.

An integrated space 32 is formed between the mounting frames 30 to accumulate the medium m. The integrated space 32 has a substantially rectangular parallelepiped shape, and the media m are drawn in from the top to be integrated one by one. In this embodiment, the integrated space 32 is used as a recovery space for accumulating an abnormal medium m, for example, a crumpled or curved medium m.

In addition, an integrated plate 34 is installed to be elevated in the integrated space 32. The integrated plate 34 is the portion where the medium m is substantially integrated. The integrated plate 34 is elevated in the integrated space 32 while being connected to the belt. The integrated plate 34 is controlled to rise when the integration of the medium m is completed.

An inlet 36 is formed on the mounting frame 30 to allow the medium m to be drawn in. The medium passing through the inlet 36 is divided into two conveying channels 37 and 38 and conveyed. In the first embodiment, the normal medium m is transported to the first transport channel 37, and the abnormal medium m is transported along the second transport channel 38 to be integrated in the integrated space 32. An end of the second transfer channel 38 communicates with the integrated space 32, and the medium m accumulated in the integrated space 32 may be directly recovered by an operator.

Meanwhile, the path m of the medium m is determined by the diverter 40. The diverter 40 is rotatably installed on the mounting frame 30. The diverter 40 receives power from the solenoid 54 and rotates in both directions to shield one of the passages connected to the first and second transfer channels 37 and 38. That is, the diverter 40 blocks a passage to the second transfer channel 38 when the normal medium m is input, and opens a passage to the first transfer channel 37 when the abnormal medium m is injected. Blocking to determine the transport path of the medium (m).

And an inlet roller 42 is rotatably installed in a portion adjacent to the inlet 36. The inlet roller 42 serves to guide the medium m drawn into the inlet 36 to be transferred toward the diverter 40.

The first and second conveying rollers 44 and 46 are rotatably installed in the first and second conveying channels 37 and 38, respectively, for conveying the medium m. The first conveying roller 44 conveys the medium m fed into the first conveying channel 37, and the second conveying roller 46 feeds the medium m fed into the second conveying channel 38. Transfer it. Meanwhile, the discharge roller 48 is rotatably installed at the end of the first transfer channel 37. The discharge roller 48 serves to guide the medium m to be discharged one by one in the first transfer channel 37.

In addition, the controller 50 is rotatably installed at the end of the second transfer channel 38. The controller 50 guides the medium m passing through the second transfer channel 38 to be integrated into the integrated space 32. A plurality of stacking wheels 52 are provided on the roller shaft of the controller 50. The stacking wheel 52 strikes an upper surface of the medium m discharged from the second transfer channel 38 so that the medium m is evenly integrated in the integrated plate 34. A plurality of stacking wheels 52 may be provided on the roller shaft at predetermined intervals.

On the other hand, the mounting frame 30 is provided with a solenoid 54 acting as a drive source. The solenoid 54 provides power for driving the diverter 40 and the pressing member 66. Thus, in this embodiment, the solenoid 54, which is the driving source for driving the diverter 40, is also used to drive the pressing member 66, so that a separate driving source does not need to be used.

The solenoid 54 is provided with a plunger 56 to be movable in and out of the solenoid 54. The plunger 56 normally protrudes out of the solenoid 54 and is inserted into the solenoid 54 when electromagnetic force is applied to the solenoid 54.

In addition, a driving member 58 is rotatably installed at the tip of the plunger 56. The driving member 58 receives power from the solenoid 54 and transmits the power to the diverter 40 and the pressing member 66. The driving member 58 is formed with a guide slot 60 is inserted into the guide pin (P). In the present embodiment, a total of three guide slots 60 are provided, and may be configured in various numbers according to the shape and position of the driving member 58. The guide slot 60 has a long hole shape for interlocking with the diverter member 62 and the interlocking member 64.

A diverter member 62 is rotatably connected to one end of the driving member 58. One end of the diverter member 62 is provided with an interlocking pin (P), the interlocking pin (P) is rotated while being guided along the guide slot (60). One side of the diverter member 62 is connected to the diverter 40 to rotate the diverter 40.

On the other hand, the other end of the drive member 58, the interlocking member 64 is rotatably connected. The interlocking member 64 is also provided with an interlocking pin P, and the interlocking pin P is inserted into the guide slot 60 and guided.

One end of the interlocking member 64 is provided with a pressing member 66 rotatably installed on the rotation shaft 66 '. The pressing member 66 rotates by receiving power from the solenoid 54 and serves to press the abnormally integrated medium m evenly. A plurality of the pressing members 66 may be installed at predetermined intervals along the rotation shaft 66 ′.

Since the medium m introduced into the integrated space 32 is an abnormal (damaged or crumpled) medium m, the medium m is not normally integrated in the integrated plate 34, and thus, in the component such as the stacking wheel 52 as shown in FIG. 2. I can take it. In this case, since the media (m) and jams are introduced later, the abnormally integrated media (m) should be evenly integrated on the integration plate (34). To this end, the pressing member 66 is rotated so that the medium m can be normally integrated in the integrated plate 34. The pressing member 66 presses the medium m caught on the stacking wheel 52 or the like as shown in FIG. 3 so as to be normally integrated in the integrated plate 34.

In this embodiment, the pressing member 66 is rotated downward only when the medium m is transferred through the first transfer channel 37 to press the upper surface of the medium m. When the medium m is transferred through the second transfer channel 38, the medium m is rotated upward so that interference does not occur while the medium m is introduced. That is, since the pressing member 66 is located above the integrated space 32, interference may occur while the medium m is discharged through the second transfer channel 38. Therefore, to prevent this is to control the rotation of the pressing member 66 as described above.

The pressing member 66 is formed by bending a tip of a metal plate that is approximately one side long. Therefore, the bent end portion presses one surface of the medium m.

Next, the operation of the media accumulation apparatus of the automatic teller machine according to the first embodiment of the present invention having the above configuration will be described in detail.

Referring to FIG. 2, an electromagnetic force is applied to the solenoid 54 when the abnormal medium m is drawn in the direction of the arrow through the inlet 36. Then, the plunger 56 is inserted therein by the electromagnetic force of the solenoid 54.

When the plunger 56 is moved to the inside of the solenoid 54, the driving member 58 is also moved upwards, and the diverter member 62 guided to the interlocking pin P in association with the plunger 56 moves counterclockwise. Is rotated. The diverter 40 is also rotated in conjunction with the rotation of the diverter member 62 to block the first transfer channel 37 as shown in FIG. 2. The medium m is thus conveyed along the second conveyance channel 38. That is, the medium m is conveyed by the second feed roller 46 and is fed into the integrated space 32 along the controller 50. And the stacking wheel 52 of the controller 50 strikes the upper surface of the medium m so that the medium m can be evenly integrated on the integrated plate 34.

At this time, in conjunction with the movement of the drive member 58, the interlocking member 64 is rotated counterclockwise, and the pressing member 66 is also rotated counterclockwise. As such, when the pressing member 66 is rotated, interference with the medium m introduced through the second transfer channel 38 into the integrated space 32 does not occur. The abnormal medium m accumulated on the integrated plate 34 may be recovered separately by an operator.

Next, when the normal medium (m) is injected, the electromagnetic force applied to the solenoid 54 is cut off. Then, the electromagnetic force attracting the plunger 56 is removed, so the plunger 56 protrudes outward. In addition, the drive member 58 is moved downward in association with the movement of the plunger 56.

As described above, when the driving member 58 is moved downward, the diverter member 62 is rotated clockwise, and the diverter 40 is also rotated clockwise in association with the diverter member 62. The diverter 40 then blocks the second transfer channel 38 and the medium m is conveyed along the first transfer channel 37. The medium m conveyed along the first conveying channel 37 is normally discharged by the discharge roller 48 to be delivered to the customer or temporarily collected.

At this time, in conjunction with the driving of the drive member 58, the interlocking member 64 is rotated in the clockwise direction. In addition, together with the interlocking member 64, the pressing member 66 is also rotated in the clockwise direction. Then, the pressing member 66 may press the upper surface of the abnormally integrated medium m to be evenly integrated on the integrated plate 34. As such, when the medium m is not fed toward the integrated plate 34, the pressing member 66 presses the medium m, so that the medium m may be more evenly aligned.

On the other hand, it will be described below with respect to another embodiment of the media accumulation apparatus of the present invention.

Figure 4 is a side view showing the configuration of the media dispenser of the media dispenser according to a second embodiment of the present invention, Figure 5 is a pressurized medium by the media accumulator of the media dispenser according to a second embodiment of the present invention. Figure 6 is a side view showing the state, Figure 6 is an operating state diagram showing the process of pressing the medium by the media accumulation device of the automatic teller machine according to the second embodiment of the present invention.

As shown in these figures, the appearance of the media accumulation apparatus is formed by the mounting frame 130. The mounting frame 130 is generally made of a metal material, and is installed at predetermined intervals on both sides of the media accumulation apparatus. Of course, the mounting frame 130 may be installed on both sides of the media storage device as well as other parts.

An integration space 132 is formed between the mounting frames 130 to accumulate the medium m. The integrated space 132 has a substantially rectangular parallelepiped shape, and the media m are drawn in from the top to be integrated one by one. In this embodiment, the integrated space 132 is utilized as a recovery space for accumulating abnormal media m, for example, crumpled or curved media m.

In addition, an integrated plate 134 is installed to be elevated in the integrated space 132. The integrated plate 134 is a portion where the medium m is substantially integrated. The integrated plate 134 is elevated in the integrated space 132 in a state of being connected to the belt. The integrated plate 134 is controlled to be raised when the integration of the medium m is completed.

An upper portion of the mounting frame 130 is formed with an inlet 136 for introducing the medium (m). The medium passing through the inlet 136 is divided into two transport channels 137 and 138 and transported. In this embodiment, the normal medium m is transferred to the first transport channel 137, and the abnormal medium m is transported along the second transport channel 138 to be integrated in the integrated space 132. An end of the second transfer channel 138 communicates with the integrated space 132, and the medium m accumulated in the integrated space 132 may be directly recovered by an operator.

Meanwhile, the transport path of the medium m is determined by the diverter 140. The diverter 140 is rotatably installed on the mounting frame 130. The diverter 140 receives power from the solenoid 154 and rotates in both directions to shield one of the passages connected to the first and second transfer channels 137 and 138. That is, the diverter 140 blocks a passage to the second transfer channel 138 when the normal medium m is input, and opens a passage to the first transfer channel 137 when the abnormal medium m is input. Blocking to determine the transport path of the medium (m).

And an inlet roller 142 is rotatably installed at a portion adjacent to the inlet 136. The inlet roller 142 serves to guide the medium m introduced into the inlet 136 to be transferred toward the diverter 140.

The first and second transfer rollers 144 and 146 are rotatably installed in the first and second transfer channels 137 and 138, respectively, for transporting the medium m. The first conveying roller 144 conveys the medium m fed into the first conveying channel 137, and the second conveying roller 146 feeds the medium m fed into the second conveying channel 138. Transfer it. Meanwhile, the discharge roller 148 is rotatably installed at the end of the first transfer channel 137. The discharge roller 148 serves to guide the medium (m) one by one in the first transfer channel (137).

In addition, the controller 150 is rotatably installed at the end of the second transfer channel 138. The controller 150 guides the medium m passing through the second transfer channel 138 to be integrated into the integrated space 132. A plurality of stacking wheels 152 are provided on the roller shaft of the controller 150. The stacking wheel 152 strikes the upper surface of the medium m discharged from the second transfer channel 138 to allow the medium m to be evenly integrated in the integrated plate 134. A plurality of stacking wheels 152 may be provided on the roller shaft at predetermined intervals.

On the other hand, the mounting frame 130 is provided with a solenoid 154 acting as a drive source. The solenoid 154 provides power required for driving the diverter 140 and the pressing member 166. Thus, in this embodiment, the solenoid 154, which is the driving source for driving the diverter 140, is also used to drive the pressing member 166, so that a separate driving source does not need to be used.

The plunger 156 is installed on the solenoid 154 so as to be movable in and out of the solenoid 154. The plunger 156 normally protrudes out of the solenoid 154 and is inserted into the solenoid 154 when electromagnetic force is applied to the solenoid 154.

In addition, a driving member 158 is rotatably installed at the tip of the plunger 156. The driving member 158 receives power from the solenoid 154 and transmits the power to the diverter 140 and the pressing member 166. The driving member 158 is formed with a guide slot 160 is inserted into the guide pin (P) guide. In the present embodiment, a total of three guide slots 160 are provided, and may be configured in various numbers according to the shape and position of the driving member 158. The guide slot 160 has a long hole shape for interlocking with the diverter member 162 and the interlocking member 164.

The diverter member 162 is rotatably connected to one end of the driving member 158. One end of the diverter member 162 is provided with an interlocking pin (P), the interlocking pin (P) is rotated while being guided along the guide slot (160). One side of the diverter member 162 is connected to the diverter 140 to rotate the diverter 140.

Meanwhile, the other end of the driving member 158 is rotatably connected to the interlocking member 164. The interlocking member 164 is also provided with an interlocking pin (P), the interlocking pin (P) is inserted into the guide slot 160 is guided.

One end of the interlocking member 164 is provided with a pressing member 166 rotatably mounted on the rotation shaft 166 ′. The pressing member 166 rotates by receiving power from the solenoid 154 and serves to press the medium m. The plurality of pressing members 166 may be installed at predetermined intervals along the rotation shaft 166 ′. The pressing member 166 presses the upper surface of the medium m while the medium m is integrated in the integrated plate 134 so that the medium m can be evenly aligned. Since the medium m introduced into the integrated plate 134 is an abnormal (damaged or crumpled) medium m, the medium m may be pressed evenly through the pressing member 166 to uniformly integrate the medium m.

In this embodiment, the pressing member 166 is rotated downward only when the medium m is transferred through the first transfer channel 137 to press the upper surface of the medium m. When the medium m is transferred through the second transfer channel 138, the medium m is rotated upward so that interference does not occur while the medium m is introduced. That is, since the pressing member 166 is located above the integrated space 132, interference may occur while the medium m is discharged through the second transfer channel 138. Therefore, to prevent this is to control the rotation of the pressing member 166 as described above.

The pressing member 166 is formed by bending the tip of the metal plate that is substantially one side. Therefore, the bent end portion presses one surface of the medium m. And the end of the pressing member 166 is hooked by the auxiliary pressing member 170 so that the pressing member 66 is rotated in the direction of pressing the medium (m).

The auxiliary pressing member 170 is rotatably installed between the mounting frame 130 and rotates about the rotating shaft 171. The auxiliary pressing member 170 performs two roles in this embodiment. First, the auxiliary pressing member 170 is installed in a direction substantially parallel to the second transfer channel 138 to guide the medium m introduced into the integrated space 132. Secondly, the auxiliary pressing member 170 serves to press one side of the medium m pushed by the integrated plate 134.

The auxiliary pressurizing member 170 does not press the entire surface of the medium m, but presses the left portion of the medium m as shown in FIG. 5. In addition, the integrated plate 134 is rotated in the process of being raised to walk on one side of the pressing member 166 so that the pressing member 166 is rotated in the direction of pressing the medium m. To this end, the rotating shaft 171 of the auxiliary pressing member 170 may be provided with an elastic member (not shown) for imparting an elastic force so that the auxiliary pressing member 170 is rotated in the direction of pressing the medium (m).

In addition, a sensing sensor 172 is installed at a portion adjacent to the auxiliary pressing member 170. The sensor 172 detects that the auxiliary pressing member 170 is rotated by the medium (m) to prevent the integrated plate 134 from rising. That is, when the integrated plate 134 is raised and the medium m is pressurized by the auxiliary pressurizing member 170 and the pressurizing member 166 and ascended by a predetermined height, the sensing sensor 172 is the auxiliary pressurizing member 170. By detecting the integrated plate 134 is to be stopped.

Next, the operation of the media accumulation apparatus of the automatic teller machine according to the second embodiment of the present invention having the above configuration will be described in detail.

Referring to FIG. 4, an electromagnetic force is applied to the solenoid 154 when the abnormal medium m is drawn in the direction of the arrow. Then, the plunger 156 is inserted therein by the electromagnetic force of the solenoid 154.

When the plunger 156 is moved in this manner, the driving member 158 is also moved upward, and the diverter member 162 guided to the interlocking pin P in association with the plunger 156 is rotated counterclockwise. The diverter 140 also rotates in conjunction with the rotation of the diverter member 162 to block the first transfer channel 137 as shown in FIG. 4. The medium m is thus conveyed along the second conveying channel 138. That is, the medium m is conveyed by the second feed roller 146 and is introduced into the integrated space 132 along with the controller 150. The stacking wheel 152 of the controller 150 hits the upper surface of the medium m so that the medium m can be evenly integrated on the integrated plate 134.

At this time, in conjunction with the movement of the drive member 158, the interlocking member 164 is rotated counterclockwise, and the pressing member 166 is also rotated counterclockwise. As such, when the pressing member 166 is rotated, interference with the medium m introduced through the second transfer channel 138 into the integrated space 132 does not occur. The abnormal medium m accumulated on the integrated plate 134 may be separately collected by an operator.

In addition, the auxiliary pressing member 170 is located in a direction parallel to the medium (m) that is introduced into the integrated space 132 so that the medium (m) evenly on the integrated plate 134 along one surface of the auxiliary pressing member 170. To be integrated.

Next, when the normal medium (m) is injected, the electromagnetic force applied to the solenoid 154 is cut off. Then, since the electromagnetic force attracting the plunger 156 is removed, the plunger 156 protrudes outward. In addition, the drive member 158 is moved downward in association with the movement of the plunger 156.

When the driving member 158 is moved in this manner, the diverter member 162 is rotated in the clockwise direction, and in conjunction with the diverter 140, the diverter 140 is also rotated in the clockwise direction. Then, the diverter 140 blocks the second transfer channel 138, and the medium m is transferred along the first transfer channel 137. The medium m conveyed along the first transport channel 137 is normally discharged by the discharge roller 148 and transferred or temporarily accumulated to the customer.

At this time, in conjunction with the driving of the drive member 158, the interlocking member 164 is rotated in the clockwise direction. In addition, the pressing member 166 also rotates in a clockwise direction together with the interlocking member 164.

In this state, the integrated plate 134 rises in the direction of arrow ① as shown in FIG. The left portion of the medium m accumulated in the integrated plate 134 is in contact with the auxiliary pressing member 170. And the medium (m) is aligned while being pressed by the auxiliary pressing member 170 in the direction of the arrow ②. At this time, the auxiliary pressing member 170 is rotated in a clockwise direction about the rotating shaft 171.

Next, one side of the auxiliary pressing member 170 is hooked to the end of the pressing member 166. At this time, the pressing member 166 is rotated in the direction of the arrow ③ to press the medium (m). That is, the pressing member 166 pressurizes the medium m in the direction of arrow ④ to stably press the medium m together with the auxiliary pressing member 170.

As described above, when one side of the auxiliary pressing member 170 is detected by the sensor 172 in the process of rotating the auxiliary pressing member 170, the signal is transmitted to the integrated plate 134 to stop. In this embodiment, since the pressing member 166 and the auxiliary pressing member 170 pressurize the medium m together, the medium m may be more evenly integrated.

The scope of the present invention is not limited to the embodiments described above, but is defined by the claims, and various changes and modifications can be made by those skilled in the art within the scope of the claims. It is self evident.

The present invention can be applied to various media handlers that handle media to stably integrate not only abnormal media but also normal media in a predetermined integration space.

Claims (9)

1. A mounting frame;

   An integrated plate movably installed in an integrated space formed between the mounting frames, for accumulating media;

   A diverter configured to determine a conveying path of a medium that is rotated in both directions by a driving source and is drawn in;

   And a pressurizing member which rotates by receiving power from the driving source, pressurizes the abnormally integrated medium and evenly integrates the integrated plate on the integrated plate.
2. A mounting frame;

   An integrated plate movably installed in an integrated space formed between the mounting frames, for accumulating media;

   A diverter configured to determine a conveying path of a medium that is rotated in both directions by a driving source and is drawn in;

   A pressing member which is rotated by receiving power from the driving source and presses and presses an upper surface of the medium integrated in the integrated plate;

   And an auxiliary pressurizing member for guiding the medium introduced into the integrated space and pressurizing the medium together with the pressing member when the integrated plate is raised in a state in which the medium is accumulated.
3. The method according to claim 1 or 2,

   The diverter is controlled so that normal media is transported to the first transport channel and abnormal media is transported to the second transport channel, and an end of the second transport channel communicates with the integrated space. Integrated device.
4. The method of claim 3, wherein

   And the pressurizing member is rotated upward when the medium is introduced into the integrated space to prevent interference with the medium.
5. The method of claim 4, wherein

   The driving source is a solenoid in which the plunger is movable in and out, and a driving member is rotatably provided at the tip of the plunger, and the driving member transmits the power transmitted from the solenoid to the diverter and the pressing member. A media accumulation apparatus for an automatic media dispenser, characterized in that.
6. The method of claim 5,

   The pressurizing member is rotatably connected to the interlocking member through a rotating shaft, wherein the pressurizing member is a media accumulation device of the automatic media dispenser, characterized in that a plurality is installed on the rotating shaft.
7. The method of claim 2, wherein the auxiliary pressing member,

   And the integrated plate is rotated in the process of being raised and pressurized by the medium, so that the pressurizing member is rotated in the direction in which the pressurizing member presses the medium.
8. The method of claim 1, wherein the media storage device,

   And a drive source for simultaneously transmitting power to the diverter and the pressurizing member.
9. The method of claim 2, wherein the media storage device,

   A drive source for simultaneously transmitting power to the diverter and the pressing member; And

   And a sensing sensor which senses the auxiliary pressing member rotated while pressing the medium and transmits a stop signal to the integrated plate.

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