Temporary storage device for sheet medium

Abstract

A sheet-like medium temporary storage device includes a storage coiling block, configured to reel up and store sheet-like medium and being a circular roller with a cavity at the center; a thin coiling tape, having one end fixedly connected to an outer surface of the storage coiling block and configured to reel up the sheet-like medium and wind the sheet-like medium around the storage coiling block; a recycling coiling block, configured to reel up and recycle the thin coiling tape, wherein another end of the thin coiling tape is fixed to an outer surface of the recycling coiling block; and a power motor arranged in the cavity and configured to drive the storage coiling block to rotate and control the recycling coiling block to rotate. One end of the cavity is opened, and at least two air disturbance vanes are uniformly arranged at another end of the cavity.

Claims

1. A sheet-like medium temporary storage device, comprising: a storage coiling block, configured to reel up and store sheet-like medium and being a circular roller with a cavity at the center; a thin coiling tape, which has one end fixedly connected to an outer surface of the storage coiling block and is configured to reel up the sheet-like medium and wind the sheet-like medium around the storage coiling block, to temporarily store the sheet-like medium; a recycling coiling block, configured to support the thin coiling tape and reel up and recycle the thin coiling tape, wherein another end of the thin coiling tape is fixed to an outer surface of the recycling coiling block; and a power motor, which is arranged in the cavity of the storage coiling block and configured to drive the storage coiling block to rotate and control the recycling coiling block to rotate through a belt; and wherein one end of the cavity in the center of the storage coiling block is opened to allow the power motor to be insertedly mounted in the storage coiling block, at least two air disturbance vanes are uniformly arranged at another end of the cavity, the air disturbance vanes extend from an outer wall to an axis of the storage coiling block and form a support frame of the power motor around the axis of the storage coiling block, and a clearance is formed between the air disturbance vanes, to ensure air exchange between inside and outside of the storage coiling block in the case that the storage coiling block rotates.

2. The sheet-like medium temporary storage device according to claim 1, wherein the number of the air disturbance vanes is four, and the four air disturbance vanes are uniformly distributed on an end surface of the storage coiling block.

3. The sheet-like medium temporary storage device according to claim 1, wherein the air disturbance blades form an irregular Z-shaped trend along a circumferential direction.

4. The sheet-like medium temporary storage device according to claim 1, wherein two of the thin coiling tapes are provided, two of the recycling coiling blocks are correspondingly provided, the two thin coiling tapes are respectively wound around the two recycling coiling blocks, another ends of the two thin coiling tapes are stacked and fixed on the outer surface of the storage coiling block, and parts of the two thin coiling tapes between the recycling coiling blocks and the storage coiling block form a clamping state.

5. The sheet-like medium temporary storage device according to claim 2, wherein the air disturbance blades form an irregular Z-shaped trend along a circumferential direction.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a schematic view showing a sheet-like medium temporary storage device according to the present application;

(2) FIG. 2 is a top view of the device shown in FIG. 1;

(3) FIG. 3 is a partially sectional view showing the cooperation of a storage coiling block and a motor of the device in FIG. 1;

(4) FIG. 4 is a partially sectional view of the storage coiling block of the device in FIG. 1;

(5) FIG. 5 is a schematic view showing an air passage when the storage coiling block of the device in FIG. 1 rotates;

(6) FIG. 6 is a schematic view showing internal cross-sectional areas of the storage coiling block of the device in FIG. 1;

(7) FIG. 7 is a schematic view showing the wind direction when the storage coiling block of the device in FIG. 1 rotates in a positive direction; and

(8) FIG. 8 is a schematic view showing the wind direction when the storage coiling block of the device in FIG. 1 rotates in a reverse direction.

(9) TABLE-US-00001 Reference numerals: 100 sheet-like medium (including but not limited to banknote, check, security and other valuable documents, which is collectively referred to as banknote for convenience), 101 recycling coiling block; 102 thin coiling tape, 103 guide shaft of the thin 104 small driving wheel, coiling tape, 105 big driving wheel, 106 driving belt, 107 mounting plate, 108 coiling block rotation shaft, 201 storage coiling block, 202 power motor, 301 motor supporting frame, 302 air disturbance vane, 303 storage zone of the coiling V.sub.k air speed of a driving air port, block, V.sub.r air speed in a heat-dissipating passage of the motor, d.sub.1 diameter of a handle of the coiling block, d.sub.2 width of a cross section of the power motor, S.sub.1 cross sectional area of the interior of the coiling block, S.sub.2 cross sectional area of the handle of the coiling block, S.sub.3 cross sectional area of the power motor, S.sub.k area of the driving air port, S.sub.r area of heat-dissipating passage of the motor.

DETAILED DESCRIPTION

(10) In order to further illustrate the sheet-like medium temporary storage device according to the present application, the sheet-like medium temporary storage device of the present application is described hereinafter in detail in conjunction with a preferable embodiment and drawings.

(11) FIGS. 1 and 2 are schematic views of a sheet-like medium temporary storage device of the present application. The sheet-like medium temporary storage device includes a storage coiling block 201 which is configured to wind and store a sheet-like medium 100 and is embodied as a circular roller with a cavity in the center, a thin coiling tape 102, a recycling coiling block 101 and a power motor 202 arranged in the cavity of the storage coiling block 201. The thin coiling tape 102 is configured to wind the sheet-like medium 100 around the storage coiling block 201 to be temporarily stored, has one end fixedly connected to an outer surface of the storage coiling block 201, and another end fixed to an outer surface of the recycling coiling block 101. The recycling coiling block 101 is configured to support the thin coiling tape 102 and to reel up and recycle the thin coiling tape 102. The power motor 202 has a first power output shaft 2021, and the storage coiling block 201 is driven by the first power output shaft 2021 to rotate. The power motor 202 further has a second power output shaft 2022, a big driving wheel 105 is fixed on the second power output shaft 2022, and the big driving wheel 105 is driven by the second power output shaft 2022 to rotate, and the power of the big driving wheel 105 is used to drive the recycling coiling block 101 via a driving belt 106. The recycling coiling block 101 has a coiling block rotation shaft 108, one end of the coiling block rotation shaft 108 is provided with a small driving wheel 104, and the driving belt 106 is wound around the small driving wheel 104 and the big driving wheel 105. To fixedly mount the sheet-like medium temporary storage device, the device further includes a mounting plate 107, and the second power output shaft 2022 and the coiling block rotation shaft 108 are rotatably mounted on the mounting plate 107.

(12) The sheet-like medium temporary storage device according to the present embodiment includes two recycling coiling blocks 101, and two corresponding thin coiling tapes 102 and two corresponding small driving wheels 104. The two thin coiling tapes 102 are configured to clamp the sheet-like medium 100 and wind the sheet-like medium 100 around the storage coiling block 201, to temporarily store the sheet-like medium 100. The two small driving wheels 104 are respectively arranged on two coiling block rotation shafts 108 which are rotatably arranged on the mounting plate 107, and the driving belt 106 is mounted on the big driving wheel 105 and the two small driving wheels 104 and is configured to transmit power between the big driving wheel 105 and the two small driving wheels 104.

(13) Each of the two thin coiling tapes 102 has sufficient length, and has one end mounted on the respective recycling coiling block 101, and another end mounted on the storage coiling block 201 after passing through a respective guiding shaft 103 of the thin coiling tape, and the remaining length of each of the two thin coiling tapes is wound around the recycling coiling block 101 to be reserved.

(14) Referring to FIGS. 3 and 4, one end of the cavity at the center of the storage coiling block 201 is opened, the storage coiling block 201 is fixedly arranged on the first power output shaft of the power motor 202, and covers the surface of the power motor 202 and is rotatable. Four air disturbance vanes 302 are uniformly arranged on another end of the cavity at the center of the storage coiling block 201, and extend from an outer wall 303 toward the axis of the storage coiling block, to form a power motor supporting frame 301 around the axis of the storage coiling block. Each of the air disturbance vanes 302 forms an irregular Z-shaped trend along the circumferential direction, and clearances are formed between the adjacent air disturbance vanes 302, to ensure air exchange inside and outside the storage coiling block 201 when the storage coiling block 201 rotates, and the clearances form a driving air port 203.

(15) The condition of the air passage when the storage coiling block rotates is further illustrated in conjunction with FIG. 5. When the storage coiling block 201 is driven by the power motor 202 to rotate, the air disturbance vanes 302 on the storage coiling block 201 drives air to flow, the air passes through a heat-dissipating passage 204 formed between the surface of the power motor 202 and the inner surface of the storage coiling block 201 and takes away the heat at the surface of the motor. A flow speed of the air at the driving air port 203 of the storage coiling block 201 is V.sub.k, and a flow speed of the air in the heat-dissipating passage 204 on the surface of the power motor 202 is V.sub.r. As shown in FIG. 5, which is a schematic view showing cross sectional areas of the interior of the storage coiling block 201, an internal cross sectional area of the storage coiling block 201 is S.sub.1, a cross sectional area of the motor supporting frame is S.sub.2, and a cross sectional area of the power motor is S.sub.3. A width d.sub.2 of the cross section of the power motor is greater than a width d.sub.1 of the motor supporting frame 301, thus S.sub.3>S.sub.2. As shown in the figure, an area S.sub.k of the driving air port 203 of the storage coiling block 201 satisfies an expression of S.sub.k=S.sub.1S.sub.2, an area S.sub.r of the heat-dissipating passage 204 satisfies an expression of S.sub.r=S.sub.1S.sub.3, therefore, the relationship between the area S.sub.k of the driving air port 203 and the area S.sub.r of the heat-dissipating passage 204 satisfies an expression of S.sub.k>S.sub.r. The relationship between the flow speed V.sub.r of the air in the heat-dissipating passage 204 and the flow speed V.sub.k of the air at the driving air port 203 satisfies an expression of V.sub.r=V.sub.k(S.sub.k/S.sub.r)>V.sub.k. The flow speed of the airflow formed at the driving air port 203 is increased when passing through the heat-dissipating passage 204 due to the decrease of the passage section, thereby expediting the heat dissipation on the surface of the motor.

(16) Referring to FIGS. 7 and 8, the directions of air exchange when the storage coiling block 201 rotates positively or reversely is further illustrated. In this embodiment, the air is drawn from the heat-dissipating passage when the power motor 202 rotates in a positive direction, and an inclining direction of the air disturbance vanes 302 is the positive direction. Of course, an arrangement direction of the vanes may be positive direction or reverse direction according to different inclining directions of the air disturbance vanes 302, both of which may realize the object of the present application.

(17) A heat dissipation process of the power motor when the sheet-like medium temporary storage device is operating is further illustrated in conjunction with FIGS. 1 to 8. When a sheet-like medium 100 is sent into the sheet-like medium temporary storage device, a sheet inlet formed between the two guiding shafts 103 of the thin coiling tapes and the two thin coiling tapes 102 is configured to receive the sheet-like medium 100, the power motor 202 drives the storage coiling block 201 and the big driving wheel 105 to rotate in the positive direction, the big driving wheel 105 then drives the two small driving wheels 104 to rotate in the positive direction via the drive belt 106, and the two small driving wheels 104 respectively drive two recycling coiling blocks 101 to rotate in the positive direction through two small coiling block rotation shafts 108, and the two recycling coiling blocks 101 respectively release the two thin coiling tapes 102 pre-stored on the two recycling coiling blocks 101 step by step, to wind the sheet-like medium clamped between the two thin coiling tapes 102 around the storage coiling block 201, thereby accomplishing a storage process of the sheet-like mediums. In the above process, the air disturbance vanes 302 at one end of the storage coiling block 201 rotates around the first power output shaft of the power motor when the storage coiling block 201 rotates. Due to the inclined arrangement of the air disturbance vanes, the inclined surfaces of the air disturbance vanes strike air particles when the air disturbance vanes rotate, which accelerates the movement of the air particles and changes the movement direction of the air particles, and an airflow flowing from the heat-dissipating passage 204 toward the driving air port 203 is formed. Due to the airflow, heat in the heat-dissipating passage 204 generated by the operation of the power motor 202 is taken away by the air in contact with the heat-dissipating passage 204, thereby realizing the object of fast cooling of the power motor.

(18) Conversely, when the power motor 202 rotates in the reverse direction, the storage coiling block 201 and the big driving wheel 105 are driven to rotate in the reverse direction, the two thin coiling tapes 102 clamping the sheet-like medium 100 are released from the storage coiling block 201, and the two recycling coiling blocks 101 recycle the thin coiling tapes 102 step by step, to release the clamped sheet-like medium piece by piece, thereby accomplishing a discharging function of the sheet-like mediums temporarily stored on the storage coiling block 201. In the above process, the air disturbance vanes 302 at one end of the storage coiling block 201 rotates around the first power output shaft of the power motor when the storage coiling block 201 rotates in the reverse direction. Due to the inclined arrangement of the air disturbance vanes, the inclined surfaces of the air disturbance vanes strike air particles when the air disturbance vanes rotate, which accelerates the movement of the air particles and changes the movement direction of the air particles, and an airflow flowing from the driving air port 203 toward the heat-dissipating passage 204 is formed. Due to the airflow, heat in the heat-dissipating passage 204 generated by the operation of the power motor 202 is taken away by the air in contact with the heat-dissipating passage 204, thereby realizing the object of fast cooling of the power motor.

(19) Besides, the air disturbance vanes 302, that is the vanes of the coiling block, are arranged obliquely, and a ventilation space is provided between each two adjacent air disturbance vanes 302, thus even if the power motor stops rotating, that is the storage coiling block 201 stops rotating, heat generated inside the storage coiling block 201 during the operation of the power motor 202 may also be dissipated from these ventilation spaces in a manner of heat convection, which accelerates the natural cooling of the power motor.

(20) The embodiments described hereinabove are only preferable implementations of the present application, and are not intended to limit the present application, and the scope of the present application is defined by the claim. For the person skilled in the art, a few of modifications and improvements may be made to the present application without departing from the principle of the present application, and these modifications and improvements are also deemed to fall into the scope of the present application.