CN217085862U - Rotary coin storage device with high-efficiency coin storage capacity - Google Patents

Abstract

The utility model discloses a rotary coin storage device with high-efficiency coin storage capacity, which comprises a main frame body; the coin storage unit is pivotally arranged on the main frame body and comprises at least two coin storage bins, the coin storage units are arranged to rotate along with the main frame body relative to the main frame body, the coin storage bins sequentially pass through a coin inlet position and a coin outlet position of the rotary coin storage device, tokens conveyed by the coin inlet position are stored in a first cavity of the coin storage units after passing through the coin storage bins of the coin inlet position, when the coin storage bins pass through the coin outlet position, the tokens in the first cavity are output to the outside of the rotary coin storage device from the coin outlet position, and all the coin storage bins do not output the tokens from the coin outlet position at the same time; the driving unit is used for driving the coin storage unit to rotate relative to the main frame body; the rotating shaft of the coin storage unit is connected to the main frame body through a bearing. Therefore, the coin storing speed of the rotary coin storing device is higher than that of the existing coin storing device; the coin storage device rotates continuously in the process of storing coins, the number of the coin storage bins is increased, and the attraction of the rotary coin storage device to players is greatly increased.

Description

Rotary coin storage device with high-efficiency coin storage capacity

Technical Field

The utility model relates to a store up the coin device, concretely relates to rotatory coin device of depositing with high-efficient coin storage ability.

Background

The conventional coin depositing device for rewarding tokens for game participants needs to superpose coins one by one, takes a long time, has long waiting time for a player, influences the game experience of the player, is not intuitive in the process of accumulating the stacked coins, and has no direct impression and irritation to the player.

In order to solve the above problems, the publication No. CN214175222U discloses a fast coin storage and discharge mechanism, which is provided with a coin tube for storing tokens and a coin discharge baffle plate disposed at the bottom end of the coin tube and capable of opening and closing an opening at the bottom of the coin tube, wherein when a player needs to obtain a token award, the opening at the bottom of the coin tube is opened by the coin discharge baffle plate, so that the tokens are accumulated in real time according to the award obtained by the player, and the expectation of the award of materials can be increased.

However, the above structure still has the following problems: the coin storage structure is single, only one coin cylinder is provided, the number of obtained tokens is not suspensory, and the attraction to players is low.

SUMMERY OF THE UTILITY MODEL

In order to solve the current lower problem of the appeal of depositing coin device deposit coin structure singleness, single coin section of thick bamboo to the player, according to the utility model discloses an aspect provides a rotatory coin device of depositing with high-efficient storage coin ability.

The rotary coin storage device with the efficient coin storage capacity comprises a main frame body; the coin storage unit is pivotally arranged on the main frame body and comprises at least two coin storage bins, the coin storage bins are arranged to sequentially pass through a coin inlet position and a coin outlet position of a rotary coin storage device with high-efficiency coin storage capacity along with the rotation of the coin storage unit relative to the main frame body, when the coin storage bins pass through the coin inlet position, tokens conveyed by the coin inlet position are stored in a first cavity of the coin storage bins, when the coin storage bins pass through the coin outlet position, the tokens in the first cavity are output to the outside of the rotary coin storage device with high-efficiency coin storage capacity from the coin outlet position, and all the coin storage bins do not output the tokens from the coin outlet position at the same time; the driving unit is used for driving the coin storage unit to rotate relative to the main frame body; wherein, the rotating shaft of the coin storage unit is connected with the main frame body through a bearing.

Therefore, the coin storing speed of the rotary coin storing device with the efficient coin storing capacity is higher than that of the conventional coin storing device; the coin storage device continuously rotates in the process of storing coins, the number of the coin storage bins is increased, and the attraction of the rotary coin storage device with high-efficiency coin storage capacity to players is greatly increased.

In some embodiments, the coin storage unit further comprises a first mounting seat which is pivotally arranged on the main frame body, each coin storage bin is pivotally arranged on the first mounting seat, and when no external force is applied to each coin storage bin, a first opening of a first cavity of each coin storage bin faces upwards; the coin storage bin is arranged on the main frame body and used for driving the coin storage bin which rotates to the coin outlet position to rotate relative to the first mounting seat so as to output the tokens in the first cavity from the coin outlet position to the outside of the rotary coin storage device with high-efficiency coin storage capacity; in particular, the longitudinal section of the first cavity perpendicular to the pivot axis thereof is semicircular; in particular, the pivot axis of the magazine is arranged in the magazine close to its first opening.

Therefore, the coin storage bin moving to the coin outlet position can rotate relative to the first mounting seat under the driving of the driving mechanism, namely, the coin storage bin is overturned under the driving of the driving mechanism so as to output the token in the first cavity from the coin outlet position to the outside of the rotary coin storage device with high-efficiency coin storage capacity; when the longitudinal section of the first cavity, which is vertical to the pivot shaft of the first cavity, is semicircular, the coin storage bin can keep swinging for a period of time after being overturned and unloaded, so that the number of the stored coins in the coin storage bin is not kept constant, suspense is increased, and the swinging amplitude of the coin storage bin is reduced along with the increase of the number of the stored tokens in the coin storage bin; when the pivot axis of the magazine is located at a position of the magazine close to the first opening, the amplitude of the oscillation of the magazine can be maximised so that the magazine oscillates under the drive of the drive mechanism to deliver tokens from its first cavity out of the first opening.

In some embodiments, the coin storage bin is provided with a weight block, and the weight block is arranged so that the weight of the side of the weight block close to the bottom of the first cavity is larger than the weight of the side of the weight block close to the first opening. Therefore, when the coin storage bin swings, the coin storage bin can be ensured to gradually return to the state that the first opening faces upwards even though the coin storage bin does not store tokens under the assistance of the balancing weight.

In some embodiments, the pivot axis of the magazine is parallel to the pivot axis of the first mount. Therefore, the coin storage bin of the coin outlet position can be gradually overturned under the driving of the driving mechanism while the driving unit drives the first mounting seat to drive the first mounting seat to rotate; even if the driving mechanism is kept still, the coin storage bin of the coin outlet position on the rotating first mounting seat can be driven to gradually turn over, so that the arrangement mode of the driving mechanism is simplified.

In some embodiments, the rotary coin storage device with high coin storage capacity further comprises an adjusting block arranged on at least one side of the main frame body, wherein the adjusting block is arranged in such a way that when a first opening of a first cavity of the coin storage bin, which is moved to the position of the adjusting block, faces upwards, at least one of the coin storage bin and the balancing weight abuts against the side wall of the adjusting block; in particular, the adjusting block is arranged at the position between the coin inlet position and the coin outlet position of the main frame body.

Therefore, when the coin storage bin is driven by the first mounting seat to move to the position of the adjusting block and keeps swinging, the swinging coin storage bin or the adjusting block on the coin storage bin can collide with the adjusting block in the process that the coin storage bin rotates along with the first mounting seat, and the swinging amplitude of the coin storage bin rotating along with the first mounting seat can be gradually reduced under the limitation of the adjusting block so as to store the token at the coin inlet position.

In some embodiments, a surface of at least one of the hopper and the weight block facing the adjustment block is provided with a first slope, the first slope being arranged such that a distance from a side near the first opening to a bottom near the first cavity to the adjustment block facing the first slope gradually decreases; in particular, the first inclined surface is arranged to incline toward the side of the adjusting block toward which the first inclined surface faces as the distance from the first opening increases.

Therefore, when the first inclined plane is in contact with the adjusting block, the swinging amplitude of the coin storage bin can be gradually adjusted through the adjusting block, so that the phenomenon that the abrasion rate of the first inclined plane is high due to the fact that the swinging amplitude of the coin storage bin is large due to the fact that the adjusting amplitude of the adjusting block is large is avoided; when the first inclined plane is arranged to incline to one side where the adjusting block faces towards the first inclined plane along with the increase of the distance between the first inclined plane and the first opening, the adjusting block can further ensure that the adjusting block gradually reduces the swing amplitude of the coin storage bin by abutting against the first inclined plane until the first opening faces upwards along with the rotation of the coin storage bin along with the first mounting seat.

In some embodiments, all of the coin bins are distributed on the same circumference of the first mounting base centered on the location of the pivot axis of the first mounting base. Therefore, the function of driving all the coin storage bins passing through the coin outlet position to overturn can be realized by arranging one driving mechanism, and the structure of the rotary coin storage device with high-efficiency coin storage capacity is simplified.

In some embodiments, the rotary coin storage device with high-efficiency coin storage capacity further comprises a stripper plate arranged on the main frame body and positioned at the coin outlet position; the two discharging plates are obliquely arranged below the coin storage bin, and the bottoms of the two discharging plates are respectively communicated with a coin outlet of the rotary coin storage device with high-efficiency coin storage capacity; the coin storage unit is arranged to output the token in the first cavity to one of the discharge plates through the coin storage bin of the coin outlet position when the driving unit drives the coin storage unit to rotate forwards; when the driving unit drives the coin storage bin to rotate reversely, the token in the first cavity is output to the other unloading plate through the coin storage bin of the coin outlet position; in particular, the tops of the two stripper plates are connected.

Because the two discharging plates are connected with the two coin outlet openings, and the coin storage bin positioned at the coin outlet position can be controlled by adjusting the rotation direction of the driving unit to output the token onto any discharging plate, the coin outlet efficiency is increased, the selection range of the coin storage bin for coin outlet is increased, and the possibility of the coin storage bin for coin outlet is increased; when the top of two stripper is connected, can follow the token that deposits coin storehouse and export to on the stripper and can follow coin outlet output completely, avoid falling to this rotatory deposit coin device's that has high-efficient storage coin ability other positions from depositing the token that coin storehouse was exported, reduce the work of clearance token.

In some embodiments, the driving mechanism comprises a gear lever for driving the coin storage bin which rotates along with the first mounting seat and moves to the coin outlet position to rotate around a pivot shaft of the gear lever; and a driving module for driving the gear lever to move to contact with at least one of the coin storage bin and the balancing weight of the coin outlet position or move to be separated from the coin storage bin and the balancing weight of the coin outlet position; particularly, the surface of the blocking rod, which is contacted with the coin storage bin or the balancing weight, is arranged into a convex arc shape; in particular, the part of the gear lever, which is contacted with the coin storage bin or the balancing weight, is provided with a first roller which rotates around a rotating shaft parallel to a pivot shaft of the coin storage bin.

Therefore, the movement of the gear lever can be controlled through the driving module, and whether the gear lever controls the coin storage bin of the coin outlet position to turn over or not is further controlled, so that whether the coin storage bin of the coin outlet position turns over or not can be controlled according to requirements; when the surface of the blocking rod, which is contacted with the coin storage bin or the balancing weight, is arranged into a convex arc shape, the contact abrasion of the blocking rod, the coin storage bin and the balancing weight can be reduced; when the position of the gear lever, which is in contact with the coin storage bin or the balancing weight, is provided with the first roller which rotates around the rotating shaft parallel to the pivot shaft of the coin storage bin, the contact abrasion of the gear lever, the coin storage bin and the balancing weight can be further reduced.

In some embodiments, the drive module is configured to drive the lever to reciprocate in the direction of the pivot axis of the first mount. This can simplify the structure of the drive module.

Drawings

Fig. 1 is a schematic structural diagram of a rotary coin storage device with high-efficiency coin storage capability according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of a first perspective view of the rotary coin storage device with high coin storage capability shown in FIG. 1;

FIG. 3 is a second perspective view of the rotary coin storage device of FIG. 1 with high coin storage capability;

FIG. 4 is a schematic cross-sectional view taken along A-A of the rotary coin storage device with high coin storage capacity shown in FIG. 3;

FIG. 5 is a schematic view of the rotary depositing device of FIG. 1 with high efficiency depositing capacity with the depositing bin in a dispensing state;

fig. 6 is a schematic structural view of a rotary coin storage device with high coin storage capacity without a main frame according to an embodiment of the present invention;

FIG. 7 is a third perspective view of the rotary coin storage device of FIG. 1 with high coin storage capability;

FIG. 8 is a schematic diagram of a fourth perspective view of the rotary coin storage device with high coin storage capability shown in FIG. 1;

FIG. 9 is an enlarged view of the coin rotary depositing device with high coin storage capacity shown in FIG. 8 at B;

fig. 10 is a schematic structural diagram of a driving mechanism for driving the coin storage bin to turn over of the rotary coin storage device with high coin storage capacity according to an embodiment of the present invention;

FIG. 11 is a schematic view of the drive mechanism of FIG. 10 in a first state;

FIG. 12 is a schematic structural view of the drive mechanism of FIG. 10 in a second state;

FIG. 13 is a schematic view of the drive mechanism of FIG. 10 from another perspective;

FIG. 14 is a schematic cross-sectional view of the drive mechanism of FIG. 13 taken along the line C-C;

reference numerals: 100. a main frame body; 101. a coin inlet position; 102. a coin outlet position; 103. a coin inlet; 104. a coin outlet; 20. a coin storage unit; 21. a coin storage bin; 211. a first cavity; 212. a first opening; 213. a second pivot shaft; 22. a first mounting seat; 221. a first pivot shaft; 23. a drive mechanism; 231. a gear lever; 2311. a first roller; 232. a drive module; 2321. a second rotating electric machine; 2322. a second transmission module; 23221. a second guide rail; 23222. a second slider; 23223. a third pivot axis; 2323. a first moving structure; 23231. a first guide rail; 23232. a first slider; 233. a support; 234. a third moving structure; 2341. a third slider; 2342. a fourth pivot shaft; 235. swinging arms; 236. a detection module; 237. a fifth pivot shaft; 24. a balancing weight; 241. a first inclined plane; 30. a drive unit; 40. an adjusting block; 50. and (4) a stripper plate.

Detailed Description

It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict.

It is further noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element. The terms used herein are generally terms commonly used by those skilled in the art, and if they are inconsistent with such commonly used terms, the terms herein control.

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Fig. 1 to 14 schematically show a rotary coin storage device according to an embodiment of the present invention.

As shown in fig. 1 to 3 and 5, the rotary coin storage device includes a main frame 100, a coin storage unit 20 and a driving unit 30; wherein, the rotary coin storage device is provided with a coin inlet position 101 corresponding to a coin inlet 103 of the rotary coin storage device and a coin outlet position 102 corresponding to a coin outlet 104 of the rotary coin storage device; the coin storage unit 20 is pivotally arranged on the main frame body 100, the coin storage unit 20 comprises at least two coin storage bins 21, the coin storage bins 21 are integrally formed or processed with a first cavity 211 for storing the coins, the first cavity 211 is communicated with the outside through a first opening 212, the coin storage unit 20 is arranged to be rotated along with the coin storage unit 20 relative to the main frame body 100, the coin storage bins 21 sequentially pass through the coin inlet position 101 and the coin outlet position 102, when the coin storage bins 21 pass through the coin inlet position 101, the coins conveyed by the coin inlet position 101 are stored in the first cavity 211 of the coin storage bins 21 (shown in figure 2), when the coin storage bins 21 pass through the coin outlet position 102, the coins in the first cavity 211 are output from the coin outlet position 102 to the outside of the rotary coin storage device with high coin storage capacity (shown in figure 5), and when all the coin storage bins 21 do not output the coins from the coin outlet position 102 simultaneously; the driving unit 30 is used for driving the coin depositing unit 20 to rotate around the pivot shaft thereof relative to the main frame 100.

Illustratively, the driving unit 30 may be implemented to include a first rotating motor having a base mounted on the main frame 100, and a rotating shaft connected to the coin storage unit 20. The driving unit 30 may also be implemented to include a first rotating motor and a first transmission module (as shown in fig. 4 and 6), which may be implemented as a pulley belt transmission mechanism or a gear engagement transmission mechanism; also can realize being other drive mechanism commonly used, the utility model discloses do not do the injecing to first drive module's concrete implementation, as long as first drive module can be with the power transmission of first rotation motor output to depositing coin unit 20, it connects can to drive to deposit coin unit 20 relative main frame body 100 rotation. The driving unit 30 can also be implemented as a driving unit 30 commonly used in the prior art, as long as the driving unit 30 can drive the coin storage unit 20 to rotate relative to the main frame 100, and the present invention is not limited to the specific implementation manner of the driving unit 30. Preferably, as shown in fig. 4, the support of the main frame body 100 to the coin storage unit 20 is improved, and at the same time, the friction force of the rotation of the coin storage unit 20 relative to the main frame body 100 is reduced, the rotating shaft of the coin storage unit 20, the rotating shaft of the first rotating motor or the rotating shaft of the first transmission module are connected to the main frame body 100 through a bearing, and the specific connection mode is a mode commonly used in the prior art, and the present invention does not limit the specific connection mode.

Fig. 2, 5 and 6 schematically show a first embodiment of the coin depositing unit 20, and as shown in fig. 2, the coin depositing unit 20 further includes a first mounting seat 22 and a driving mechanism 23; the first mounting seat 22 is pivotally disposed on the main frame 100, specifically, when the driving unit 30 is a first rotating motor, the first mounting seat 22 can be pivotally disposed on the main frame 100 by being directly connected to a rotating shaft of the first rotating motor, and when the driving unit 30 includes a first rotating motor and a first transmission module, the first mounting seat 22 can be directly connected to a rotating shaft of the first transmission module, preferably, the driving unit 30, the first transmission module or the rotating shaft of the first mounting seat 22 is pivotally connected to the main frame 100 by a bearing, so as to reduce resistance to rotation; each coin storage bin 21 can be pivotally arranged on the first mounting seat 22, and the mode that the coin storage bins 21 can be pivotally arranged on the first mounting seat 22 can be realized in such a way that the rotating shaft of the coin storage bins 21 can be pivotally connected to the first mounting seat 22 through a bearing, and the specific connection mode can be realized by adopting a common mode in the prior art; when each coin storage bin 21 is not subjected to external force, the first opening 212 of the first cavity 211 of each coin storage bin is arranged upwards; the driving mechanism 23 is disposed on the main frame 100, and the driving mechanism 23 is configured to drive the coin storage 21 rotated to the coin outlet 102 to rotate around its own pivot axis relative to the first mounting seat 22, so as to output the token in the first cavity 211 from the coin outlet 102 to the outside of the rotary coin storage device with high coin storage capacity.

As a first embodiment of the driving mechanism 23, the driving mechanism 23 may be implemented as a lever 231 provided on the main frame 100, and the lever 231 is provided to enable the hopper 21 rotated to the dispensing position 102 to be gradually reversed while being hindered by the lever 231 while following the rotation of the first mounting seat 22 until the tokens in the first cavity 211 thereof are discharged from the dispensing position 102 to the outside of the rotary depositing device having a high coin-storing capability.

Since the depositing unit 20 is driven by the driving unit 30 to rotate relative to the main frame 100, the depositing unit 20 has at least two depositing bins 21, when the depositing bins 21 move to the coin outlet position 102, the tokens stored in the coin inlet position 101 are output from the coin outlet position 102 to the outside of the rotary depositing device with high-efficiency coin storage capability, and the depositing unit 20 is also set that all the depositing bins 21 do not output the tokens from the coin outlet position 102 at the same time, so that when one of the depositing bins 21 moves to the coin outlet position 102, the other depositing bins 21 can move to the coin inlet position 101, thereby the coin storage speed of the rotary depositing device with high-efficiency coin storage capability is higher than that of the existing depositing device; moreover, since the coin depositing device is continuously rotated during the coin depositing process and the number of the coin depositing bins 21 is increased, the attraction of the rotary coin depositing device with high coin storing capability to the player is greatly increased.

As one of preferred embodiments of the depositing unit 20, as shown in fig. 1 to 3, all the depositing bins 21 are distributed on the same circumference of the first mounting seat 22 with the position of the pivot axis of the first mounting seat 22 as the center of the circle. Therefore, the function of driving all the coin storage bins 21 passing through the coin outlet position 102 to turn over can be realized by arranging one driving mechanism 23, and the structure of the rotary coin storage device with high-efficiency coin storage capacity is simplified.

As one of the preferred embodiments of the magazine 21, as shown in fig. 4, the pivot axis (second pivot axis 213) of the magazine 21 is parallel to the pivot axis (first pivot axis 221) of the first mounting base 22. So that the coin storage 21 of the coin outlet 102 can drive the coin storage 21 of the coin outlet 102 on the rotating first mounting seat 22 to gradually turn over even if the driving mechanism 23 is kept still while the driving unit 30 drives the first mounting seat 22 to rotate, thereby simplifying the arrangement mode of the driving mechanism 23.

As one of the preferred embodiments of the magazine 21, as shown in fig. 7 and 8, the longitudinal section of the first cavity 211 perpendicular to its pivot axis is semicircular, and the arc-shaped part of the semicircle is the bottom of the first cavity 211. So that the coin storage bin 21 can keep swinging for a period of time after being overturned and unloaded, the number of the stored coins in the coin storage bin 21 is not kept constant, suspense is increased, and the swinging amplitude of the coin storage bin 21 is gradually reduced along with the increase of the number of the stored tokens in the coin storage bin 21.

As one of the preferred embodiments of the magazine 21, as shown in fig. 4 and 8, the pivot axis of the magazine 21 is provided at a position of the magazine 21 close to the first opening 212 thereof. To maximise the amplitude of oscillation of the magazine 21 so that the magazine 21 oscillates under the drive of the drive mechanism 23 to output tokens in its first cavity 211 out of the first opening 212.

As one of preferred embodiments of the hopper 21, as shown in fig. 2, 5 and 6, the hopper 21 is provided with a weight 24, and the weight 24 is disposed such that the weight of the side thereof near the bottom of the first cavity 211 is greater than the weight of the side thereof near the first opening 212. When the coin storage bin 21 swings, the weight 24 can ensure that the coin storage bin 21 can gradually return to the state that the first opening 212 faces upwards even though no coin is stored, so that the coin storage bin 21 can store the coin at the coin inlet 101.

In a preferred embodiment, as shown in fig. 1 to 3 and 5, the rotary coin storage device with high coin storage capacity further comprises an adjusting block 40 arranged on at least one side of the main frame body 100 on the first mounting seat 22, wherein the adjusting block 40 is arranged such that at least one of the coin storage bin 21 and the weight block 24 abuts against a side wall of the adjusting block 40 when the first opening 212 of the first cavity 211 of the coin storage bin 21 moved to the position where the adjusting block 40 is located faces upward. Therefore, when the coin storage bin 21 is driven by the first mounting seat 22 to move to the position where the adjusting block 40 is located and still keeps swinging, in the process that the coin storage bin 21 rotates along with the first mounting seat 22, the swinging coin storage bin 21 or the adjusting block 40 on the coin storage bin 21 collides with the adjusting block 40, and under the limitation of the adjusting block 40, the swinging amplitude of the coin storage bin 21 rotating along with the first mounting seat 22 is gradually reduced.

Referring to fig. 1 to 3 and 5, a preferred embodiment of the regulating block 40 is shown in which the regulating block 40 is provided at a position of the main frame 100 between the coin inlet 101 and the coin outlet 102 so that the oscillation range of the hopper 21 is reduced to no more oscillation before moving to the coin inlet 101 so that the hopper 21 stores tokens at the coin inlet 101. Preferably, the adjusting blocks 40 are arranged on both sides of the main frame 100, which are located on the first mounting seat 22, so that when the driving unit 30 drives the first mounting seat 22 to rotate forward and backward, the adjusting blocks 40 can ensure that the swing amplitude of the coin storage 21 is gradually reduced to no longer swing before moving to the coin inlet 101, for example, when the driving unit 30 drives the first mounting seat 22 to rotate forward, the adjusting block 40 on one side controls the swing amplitude of the coin storage 21 to be gradually reduced to no longer swing before moving to the coin inlet 101; when the driving unit 30 drives the first mounting seat 22 to rotate reversely, the adjusting block 40 on the other side controls the coin storage bin 21 to gradually reduce the swing amplitude to no longer swing before moving to the coin inlet 101.

In addition to the setting of the setting block 40, a preferred embodiment of the magazine 21 and/or the weight 24 is shown in fig. 1, 2, 5 and 6, wherein the surface of at least one of the magazine 21 and the weight 24 facing the setting block 40 is provided with a first inclined surface 241, the first inclined surface 241 being arranged such that its distance from the side close to the first opening 212 to the bottom close to the first cavity 211 to the setting block 40 it faces gradually decreases. Therefore, when the first inclined surface 241 is in contact with the adjusting block 40, the swinging amplitude of the coin storage bin 21 can be gradually adjusted through the adjusting block 40, so that the phenomenon that the swinging amplitude of the coin storage bin 21 causes higher abrasion rate of the first inclined surface 241 due to larger adjusting amplitude of the adjusting block 40 is avoided. Preferably, the first inclined surface 241 is arranged to incline towards the side of the adjusting block 40 facing the first inclined surface 241 as the distance from the first opening 212 increases, so as to further ensure that, as the coin storage 21 rotates along with the first mounting seat 22, the adjusting block 40 makes the coin storage 21 gradually reduce the swing amplitude by abutting against the first inclined surface 241 until the first opening 212 faces upwards; moreover, when the first inclined surface 241 is provided on the weight block 24, it is possible to ensure that the weight of the weight block 24 near the first opening 212 is less than the weight of the weight block near the bottom of the first cavity 211 without adding other structures.

In some preferred embodiments, as shown in fig. 1 to 3, the rotary coin depositing device with high coin storage capacity further includes a discharge plate 50 provided on the main frame 100 at the coin discharge position 102; the two discharging plates 50 are obliquely arranged below the coin storage bin 21, and the bottoms of the two discharging plates 50 are respectively communicated with two coin outlet openings 104 of the rotary coin storage device with high-efficiency coin storage capacity; the depositing unit 20 is configured to output the tokens in the first cavity 211 to one of the discharge plates 50 through the depositing hopper 21 of the dispensing position 102 when the driving unit 30 drives the depositing unit to rotate forward; when the driving unit 30 drives the reverse rotation thereof, the medal in the first cavity 211 is discharged to the other discharge plate 50 through the hopper 21 of the dispensing position 102. To increase the coin discharging efficiency and increase the selection range of the coin storage bin 21 for discharging coins, and increase the possibility of the coin storage bin 21 for discharging coins. Preferably, the top portions of the two stripper plates 50 are connected. So that the token discharged from the coin storage 21 to the discharging plate 50 can be completely discharged from the coin outlet 104, thereby preventing the token discharged from the coin storage 21 from falling to other positions of the rotary coin storage device having a high coin storage capacity and reducing the work of cleaning the token.

As a second embodiment of the driving mechanism 23, as shown in fig. 4, 6 to 14, the driving mechanism 23 includes a lever 231 and a driving module 232; the gear lever 231 is used for driving the coin storage bin 21 which rotates along with the first mounting seat 22 and moves to the coin outlet position 102 to rotate around a pivot shaft thereof; the driving module 232 is used for driving the gear lever 231 to move to be in contact with at least one of the coin storage bin 21 and the counterweight block 24 of the coin outlet position 102, or the driving module 232 is used for driving the gear lever 231 to move to be separated from the coin storage bin 21 and the counterweight block 24 of the coin outlet position 102. Therefore, the driving module 232 can control the gear lever 231 to move, and then the gear lever 231 can be controlled to control whether the coin storage bin 21 of the coin outlet 102 is turned over, so that whether the coin storage bin 21 of the coin outlet 102 is turned over can be controlled as required. Preferably, as shown in fig. 2, 5 and 6, the surface of the stopper rod 231 contacting the hopper 21 or the weight 24 is formed in a convex arc shape. To reduce contact wear of the stop lever 231, the hopper 21 and the weight 24. More preferably, a portion of the lever 231 contacting the hopper 21 or the weight 24 is provided with a first roller 2311 rotating about a rotation axis parallel to the pivot axis of the hopper 21. To further reduce contact wear of the stop lever 231, the magazine 21 and the weight 24.

In one embodiment of the driving module 232, as shown in fig. 11 and 12, the driving module 232 is configured to drive the lever 231 to reciprocate along the direction of the pivot axis of the first mounting seat 22. Thereby, the structure of the driving module 232 can be simplified. In general, in order to facilitate the attachment of the driving mechanism 23 to the main housing 100, the driving mechanism 23 includes a bracket 233, and the bracket 233 may be integrated with the main housing 100. Further, as shown in fig. 10, the driving module 232 is implemented to include a second rotating motor 2321, a second transmission module 2322 and a first moving structure 2323 provided on the bracket 233; wherein, the stop lever 231 is disposed on the first moving structure 2323; the second transmission module 2322 is configured to transmit the power of the second rotating motor 2321 to the first moving structure 2323, so that the first moving structure 2323 can drive the shift lever 231 to reciprocate along the direction of the pivot shaft of the first mounting seat 22.

As one implementation of the first moving structure 2323, as shown in fig. 10, 13 and 14, it includes a first guide 23231 provided on the bracket 233, and a first slider 23232 fitted on the first guide 23231; the first sliding block 23232 is connected to the second transmission module 2322 and the shift lever 231.

As one implementation of the second transmission module 2322, as shown in fig. 10, it is implemented as a second moving structure; one end of the second moving structure may be pivotally connected to the first slider 23232 about the third pivot axle 23223; the second rotating motor 2321 is configured to drive the second moving structure to swing so as to drive the first slider 23232 to reciprocate relative to the first guide rail 23231 along the movement direction limited by the first guide rail 23231. The second moving structure is driven to swing by the second rotating motor 2321, so that the first sliding block 23232 and the stop lever 231 connected to the first sliding block are driven to move along the direction limited by the first guide rail 23231, and a large driving device with the same volume as an air cylinder or a linear motor is not needed, so that the miniaturization of the rotary coin storage device with high-efficiency coin storage capacity is realized; in addition, because the air cylinder is not used, the complex structures such as the air passage and the like arranged in the rotary coin storage device with the high-efficiency coin storage capacity can be omitted, and the aim of simplifying the rotary coin storage device with the high-efficiency coin storage capacity can be fulfilled.

As one of the implementations of the second moving structure, as shown in fig. 10, the second moving structure includes a second guide 23221 connected to the second rotation motor 2321, and a second slider 23222 fitted on the second guide 23221; wherein, the first slider 23232 and the second slider 23222 are pivotably connected about the third pivot axis 23223. Specifically, the pivotable connection of the first slider 23232 and the second slider 23222 about the third pivot axis 23223 is implemented as: the second sliding block 23222 is a second roller, the second guiding rail 23221 is a sliding slot, and the third pivoting shaft 23223 is parallel to the rotating shaft of the second rotating motor 2321.

In some embodiments, as shown in fig. 10, the driving mechanism 23 further includes a third moving structure 234 and a swing arm 235, and the second moving structure is connected to the second rotating motor 2321 through the third moving structure 234 and the swing arm 235 in sequence; wherein the third moving structure 234 includes a third slider 2341 fitted with the second guide 23221; one end of the swing arm 235 is connected to the second rotating motor 2321, and the other end of the swing arm 235 is pivotally connected to the third slider 2341 through a fourth pivot axis 2342 parallel to the third pivot axis 23223; an end of the second guide 23221 facing away from the second slider 23222 is pivotally connected to the bracket 233 by a fifth pivot shaft 237 parallel to the third pivot shaft 23223; the third slider 2341 is disposed between the second slider 23222 and the fifth pivoting shaft 237. In a preferred embodiment, as shown in fig. 8 and 9, the first moving structure 2323 has a first limit position and a second limit position, when the first moving structure 2323 is located at one of the first limit position and the second limit position, the stop lever 231 connected to the first slider 23232 is located at a position where it can contact with the coin storage 21, and when the first moving structure 2323 is located at the other of the first limit position and the second limit position, the stop lever 231 is located at a position where it cannot contact with the coin storage 21, so as to control whether the stop lever 231 can function to bring the coin storage 21 to turn over by controlling the movement of the first moving structure; the end of the swing arm 235 opposite to the third slider 2341 is provided with a part to be inspected, which has a third limit position corresponding to the first limit position and a fourth limit position corresponding to the second limit position; the positions of the bracket 233 corresponding to the third limit position and the fourth limit position are respectively provided with a detection module 236 for detecting a portion to be detected. Illustratively, the detection module 236 is a sensor, such as a photoelectric sensor or an infrared sensor.

In other embodiments, the rotating shaft of the second rotating motor 2321 is directly connected to the second guide 23221.

What has been described above is merely some embodiments of the present invention. For those skilled in the art, without departing from the inventive concept, several modifications and improvements can be made, which all fall within the scope of the invention.

Claims (35)

1. Rotatory coin device of depositing with high-efficient coin storage ability which characterized in that includes:

a main frame body;

the coin storage unit is pivotally arranged on the main frame body and comprises at least two coin storage bins, the coin storage bins are arranged to sequentially pass through a coin inlet position and a coin outlet position of a rotary coin storage device with high-efficiency coin storage capacity along with the rotation of the coin storage unit relative to the main frame body, when the coin storage bins pass through the coin inlet position, tokens conveyed by the coin inlet position are stored in a first cavity of the coin storage bins, when the coin storage bins pass through the coin outlet position, the tokens in the first cavity are output to the outside of the rotary coin storage device with high-efficiency coin storage capacity from the coin outlet position, and all the coin storage bins do not output the tokens from the coin outlet position at the same time;

the driving unit is used for driving the coin storage unit to rotate relative to the main frame body; wherein the content of the first and second substances,

and the rotating shaft of the coin storage unit is connected to the main frame body through a bearing.

2. A rotary coin storage device with high efficiency coin storage capability according to claim 1 wherein said coin storage unit further comprises:

each coin storage bin is pivotally arranged on the first mounting seat, and a first opening of a first cavity of each coin storage bin is arranged upwards when the coin storage bin is not subjected to external force;

and the driving mechanism is arranged on the main frame body and used for driving the coin storage bin which rotates to the coin outlet position to rotate relative to the first mounting seat so as to output the token in the first cavity of the driving mechanism from the coin outlet position to the outside of the rotary coin storage device with high-efficiency coin storage capacity.

3. A rotary coin storage device with high efficiency coin storage capability according to claim 2 wherein the longitudinal section of the first cavity perpendicular to its pivot axis is semi-circular.

4. A rotary coin storage device with high efficiency coin storage capability according to claim 3 wherein the pivot axis of the coin storage magazine is located at a position of the coin storage magazine near its first opening.

5. The rotary coin storage device with high coin storage capacity as claimed in claim 2, wherein the coin storage bin is provided with a weight block, and the weight block is arranged so that the weight of the side of the weight block close to the bottom of the first cavity is greater than the weight of the side of the weight block close to the first opening.

6. A rotary coin storage device with high coin storage capacity as claimed in claim 3, wherein the coin storage bin is provided with a weight block, the weight block is arranged so that the weight of the side of the weight block near the bottom of the first cavity is greater than the weight of the side of the weight block near the first opening.

7. The rotary coin storage device with high coin storage capacity as claimed in claim 4, wherein the coin storage bin is provided with a weight block, and the weight block is arranged so that the weight of the side of the weight block close to the bottom of the first cavity is greater than the weight of the side of the weight block close to the first opening.

8. A rotary coin storage device with high efficiency coin storage capability according to claim 5 wherein the pivot axis of the coin storage magazine is parallel to the pivot axis of the first mounting block.

9. A rotary coin storage device with high efficiency coin storage capability according to claim 6 wherein the pivot axis of the coin storage magazine is parallel to the pivot axis of the first mounting block.

10. A rotary coin storage device with high efficiency coin storage capability according to claim 7 wherein the pivot axis of the coin storage magazine is parallel to the pivot axis of the first mounting block.

11. The rotary coin storage device with high coin storage capacity of claim 8 further comprising an adjusting block arranged on at least one side of the main frame body at the first mounting seat, wherein the adjusting block is arranged to abut against at least one of the coin storage bin and the weight block when the first opening of the first cavity of the coin storage bin where the adjusting block is located is moved upwards.

12. The rotary coin storage device with high coin storage capacity of claim 9 further comprising an adjusting block arranged on at least one side of the main frame body at the first mounting seat, wherein the adjusting block is arranged so that when the first opening of the first cavity of the coin storage bin where the adjusting block is located moves upwards, at least one of the coin storage bin and the balancing weight is abutted against the side wall of the adjusting block.

13. The rotary coin storage device with high coin storage capacity according to claim 10 further comprising an adjustment block provided on at least one side of the main frame body at the first mounting seat, wherein the adjustment block is configured such that when the first opening of the first cavity of the coin storage bin where the adjustment block is located is moved upward, at least one of the coin storage bin and the weight block abuts against a side wall of the adjustment block.

14. A rotary coin storage device with high coin storage efficiency as claimed in claim 11 wherein the adjustment block is provided at a position of the main frame between the coin in position and the coin out position.

15. A rotary coin storage device with high coin storage capacity as claimed in claim 12 wherein the adjustment block is provided at a position of the main frame between the coin in position and the coin out position.

16. A rotary coin storage device with high coin storage capacity as claimed in claim 13 wherein the adjustment block is provided at a position of the main frame between the coin in position and the coin out position.

17. The rotary coin storage device with high coin storage capacity according to claim 11, wherein the surface of at least one of the coin storage bin and the weight block facing the adjusting block is provided with a first inclined surface, and the first inclined surface is arranged such that the distance from the side close to the first opening to the bottom close to the first cavity to the adjusting block facing the first inclined surface gradually decreases.

18. The rotary coin storage device with high coin storage capacity according to claim 12, wherein the surface of at least one of the coin storage bin and the weight block facing the adjusting block is provided with a first inclined surface, and the first inclined surface is arranged such that the distance from the side close to the first opening to the bottom close to the first cavity to the adjusting block facing the first inclined surface gradually decreases.

19. The rotary coin storage device with high coin storage capacity according to claim 13, wherein the surface of at least one of the coin storage bin and the weight block facing the adjusting block is provided with a first inclined surface, and the first inclined surface is arranged such that the distance from the side close to the first opening to the bottom close to the first cavity to the adjusting block facing the first inclined surface gradually decreases.

20. The rotary coin storage device with high coin storage capacity according to claim 14, wherein the surface of at least one of the coin storage bin and the weight block facing the adjusting block is provided with a first inclined surface, and the first inclined surface is arranged such that the distance from the side close to the first opening to the bottom close to the first cavity to the adjusting block facing the first inclined surface gradually decreases.

21. The rotary coin storage device with high coin storage capacity according to claim 15, wherein the surface of at least one of the coin storage bin and the weight block facing the adjusting block is provided with a first inclined surface, and the first inclined surface is arranged such that the distance from the side close to the first opening to the bottom close to the first cavity to the adjusting block facing the first inclined surface gradually decreases.

22. The rotary coin storage device with high coin storage capacity according to claim 16, wherein the surface of at least one of the coin storage bin and the weight block facing the adjusting block is provided with a first inclined surface, and the first inclined surface is arranged such that the distance from the side close to the first opening to the bottom close to the first cavity to the adjusting block facing the first inclined surface gradually decreases.

23. A rotary coin storage device with high efficiency coin storage capability according to claim 17 wherein the first inclined surface is arranged to incline to the side of the adjustment block it faces as its distance from the first opening increases.

24. A rotary coin storage device with high efficiency coin storage capability according to claim 18 wherein the first inclined surface is arranged to incline to the side of the adjustment block it faces as its distance from the first opening increases.

25. A rotary coin storage device with high efficiency coin storage capability according to claim 19 wherein the first inclined surface is arranged to incline to the side of the adjustment block it faces as its distance from the first opening increases.

26. A rotary coin storage device with high efficiency coin storage capability according to claim 20 wherein the first inclined surface is arranged to incline to the side of the adjustment block it faces as its distance from the first opening increases.

27. A rotary coin storage device with high efficiency coin storage capability according to claim 21 wherein the first inclined surface is arranged to incline to the side of the adjustment block it faces as its distance from the first opening increases.

28. A rotary coin storage device with high efficiency coin storage capability according to claim 22 wherein the first inclined surface is arranged to incline to the side of the adjustment block it faces as its distance from the first opening increases.

29. A rotary coin storage device with high coin storage capacity according to any one of claims 2 to 28, characterized in that all the coin storage bins are distributed on the same circumference of the first mounting base centered on the position of the pivot axis of the first mounting base.

30. A rotary coin storage device with high efficiency coin storage capability according to claim 29 further comprising a stripper plate positioned on said main frame at said coin discharge position;

the two discharging plates are obliquely arranged below the coin storage bin, and the bottoms of the two discharging plates are respectively communicated with a coin outlet of the rotary coin storage device with high-efficiency coin storage capacity;

the coin storage unit is arranged to output the tokens in the first cavity to one of the discharge plates through the coin storage bin of the coin outlet position when the driving unit drives the coin storage unit to rotate forwards; when the driving unit drives the coin box to rotate reversely, the token in the first cavity is output to the other unloading plate through the coin storage bin of the coin outlet position.

31. A rotary coin storage device with high efficiency coin storage capability according to claim 30 wherein the top of the two stripper plates are connected.

32. A rotary coin storage device with high efficiency coin storage capability according to any one of claims 5 to 28 wherein said drive mechanism comprises:

the gear lever is used for driving the coin storage bin which rotates along with the first mounting seat and moves to the coin outlet position to rotate around a pivot shaft of the coin storage bin;

and the driving module is used for driving the gear lever to move to be in contact with at least one of the coin storage bin and the balancing weight of the coin outlet position or move to be separated from the coin storage bin and the balancing weight of the coin outlet position.

33. A rotary coin storage device with high coin storage capacity as claimed in claim 32 wherein the surface of the lever in contact with the coin storage bin or weight is provided in a convex arc shape; particularly, a first roller rotating around a rotating shaft parallel to a pivot shaft of the coin storage bin is arranged at the position, in contact with the coin storage bin or the balancing weight, of the gear lever.

34. A rotary coin storage device with high efficiency coin storage capability according to claim 32 wherein the drive module is configured to drive the lever to reciprocate in the direction of the pivot axis of the first mount.

35. A rotary coin storage device having an efficient coin storage capability according to claim 33 wherein the drive module is configured to drive the lever to reciprocate along the direction of the pivot axis of the first mount.

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