A coin lifting machine
By using vertically inclined lifting modules and modular design, combined with single-motor drive and compact transmission structure, the problem of large footprint of coin lifting machines has been solved, achieving efficient coin transport and improved space utilization.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SUZHOU RIBAO TECH
- Filing Date
- 2025-08-14
- Publication Date
- 2026-06-30
AI Technical Summary
Existing coin hoists occupy too much space, making them difficult to promote and apply in places with limited space. Furthermore, when multiple devices are used together, the connections are bulky and the pipelines are exposed, making it difficult to adjust and optimize them flexibly.
The lifting module adopts a vertically inclined arrangement and a modular structure design, combined with a single motor driven reversing component and a compact transmission structure. The hopper component is set at the bottom of the lifting module, and the conveying mechanism is located at the top, forming a compact three-dimensional frame that reduces redundant parts and space occupation.
It significantly improves space utilization, reduces equipment size and footprint, is suitable for space-constrained environments, and enables efficient coin transfer and flexible space adjustment.
Smart Images

Figure CN224429479U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of coin lifting technology, and in particular to a coin lifting machine. Background Technology
[0002] Coin lifts are commonly used in banks, public transportation companies, supermarkets, and other commercial establishments that need to handle large quantities of coins. Coin lifts process coins by mechanically lifting and transferring them from one location to another, enabling the continuous flow of coins between different processing stages.
[0003] However, coin lifts in practical applications generally have the problem of excessive floor space, which to some extent limits their promotion and application in places with limited space. When multiple existing coin lifts are used together, the connections between the functional units are bulky and the pipelines are exposed, resulting in a larger overall system that is difficult to adjust flexibly and optimize space according to actual needs. Utility Model Content
[0004] In view of the shortcomings of the prior art described above, the purpose of this utility model is to provide a coin lifting machine to solve the problem of the large space occupied by the coin lifting machine in the prior art.
[0005] To achieve the above and other related objectives, this utility model provides the following technical solution: a coin lifting machine, comprising: a chassis module disposed at the bottom end of the coin lifting machine; a lifting module vertically and inclinedly connected to the chassis module; the lifting module including a reversing component and a lifting drive component, the lifting drive component being connected to the reversing component, the lifting drive component including a single drive motor for driving and changing the transmission direction of the lifting module; a hopper component disposed at the bottom of the lifting module; a conveying mechanism disposed at the top of the lifting module; and a support base, with its two ends respectively connected to the lifting module and the chassis module.
[0006] The above technical solution significantly improves space utilization through the vertically inclined lifting modules and modular structural design. It employs a single-motor driven reversing assembly to achieve power transmission and direction conversion, simplifying the transmission structure and reducing the space occupied by redundant components. The hopper assembly is located at the bottom of the lifting module, and the conveying mechanism is located at the top, forming a compact and stable three-dimensional frame with the support base and chassis module. This allows the equipment to achieve efficient vertical lifting while occupying only a small ground projection area, making it suitable for space-constrained environments and achieving the technical effect of small footprint and high space utilization.
[0007] In one embodiment of this utility model, a drive roller is provided on the drive single motor, a power bearing is provided on the drive roller, and the power bearing is connected to a power shaft; the power shaft is connected to a reversing assembly.
[0008] To achieve the above technical solution, this utility model integrates a drive roller on a single drive motor and connects it sequentially to a power bearing and a power shaft, ultimately transmitting the power to the reversing assembly. This achieves a high degree of integration and compact structure of the power transmission path, effectively reducing the space required for traditional multi-motor or multi-stage transmissions and improving the layout density and space utilization of internal components.
[0009] In one embodiment of the present invention, the reversing assembly includes a transmission bracket, a first transmission shaft, a transmission sprocket, a drive sprocket, a first bevel gear, and a chain; the first transmission shaft passes through the transmission bracket, and the transmission sprocket and the first bevel gear are sleeved on the first transmission shaft; the drive sprocket is sleeved on the drive shaft; the drive sprocket and the transmission sprocket are correspondingly arranged, and their outer rings mesh with the chain.
[0010] To achieve the above technical solution, the reversing component integrates a first transmission shaft on the transmission bracket and coaxially connects the transmission sprocket with the first bevel gear. The drive sprocket on the power shaft and the transmission sprocket are connected by chain meshing, which realizes efficient power transmission and steering in the vertical direction. The overall structure is compact and the layout is reasonable. It effectively utilizes axial space and improves the utilization efficiency of the internal space of the equipment. This makes the coin lifting machine more compact while meeting functional requirements, and significantly reduces the overall volume and floor space.
[0011] In one embodiment of the present invention, lifting outer shells are provided on both sides of the lifting module, and a lifting belt, a belt limiting block, and a lifting driven wheel assembly are provided inside the lifting outer shells; the lifting drive assembly is correspondingly provided with the lifting driven wheel assembly, and a lifting belt is provided on the outer ring; the belt limiting block is provided on the inner wall of the lifting outer shell.
[0012] The above technical solution not only improves operational stability and safety through this structure, but also makes full use of vertical space to achieve a three-dimensional layout, reducing the space required for external protection and guiding mechanisms, further improving the overall space utilization of the equipment, making the lifting module structure more compact, and significantly reducing the equipment volume and floor space.
[0013] In one embodiment of the present invention, the conveying mechanism is vertically connected to the lifting module and includes a set of driven conveying rollers, a conveyor belt, and a second bevel gear. The driven conveying rollers are fitted with a conveyor belt, and the second bevel gear is disposed on the driven conveying rollers close to the lifting module and meshes with and rotates with the first bevel gear.
[0014] To achieve the above technical solution, the conveying mechanism is vertically connected to the lifting module. By mounting a conveyor belt on the driven roller and using the meshing of the second bevel gear with the first bevel gear in the lifting module to achieve power transmission, the vertical motion is efficiently converted into horizontal conveying power. There is no need to configure an independent motor or complex transmission device. The orthogonal layout of the space is fully utilized, effectively reducing the horizontal and vertical space occupied by the equipment and significantly improving the overall space utilization rate.
[0015] In one embodiment of the present invention, the chassis module includes a chassis base plate, wheels, reinforcing side plates, a material leakage trough, and baffles; four sets of wheels are installed at the bottom end of the chassis base plate, and reinforcing side plates are provided on both sides of the chassis base plate; a material leakage trough is opened on the chassis base plate, and a baffle is installed on the material leakage trough; the material leakage trough is connected to the lifting module.
[0016] By implementing the above technical solution, the integrated design effectively utilizes the bottom space, further improving the overall space utilization and compact layout of the equipment.
[0017] In one embodiment of the present invention, the hopper assembly includes a connecting base plate, a connecting cover plate, a hopper gate, a hopper bin, and a flow restrictor; the connecting cover plate is provided on the side of the connecting base plate, the hopper gate is provided on the connecting cover plate and the connecting base plate, the hopper bin is provided inside the hopper gate, and the flow restrictor is provided inside the hopper bin; the opening of the hopper bin is opened on the connecting base plate and is correspondingly provided with the lifting module.
[0018] To achieve the above technical solution, the structure integrates material storage, flow control and connection functions into a compact space. The vertical docking lifting module optimizes the material transfer path, reduces horizontal space occupation, facilitates maintenance, and significantly improves the overall space utilization and operational reliability of the equipment.
[0019] As described above, the coin lifting machine of this utility model has the following beneficial effects: The vertically inclined lifting module and modular structure design significantly improve space utilization. It uses a single motor drive and a transmission reversing component to achieve power transmission and direction conversion, simplifying the transmission structure and reducing the space occupied by redundant components. The hopper assembly is located at the bottom of the lifting module, and the conveying mechanism is located at the top, forming a compact and stable three-dimensional frame with the support base and chassis module. This allows the equipment to achieve efficient vertical lifting while occupying only a small ground projection area, making it suitable for space-constrained environments and achieving the technical effect of small footprint and high space utilization. Attached Figure Description
[0020] Figure 1 The diagram shown is a structural schematic of a coin lifting machine disclosed in an embodiment of this utility model.
[0021] Figure 2The image shown is a detailed structural diagram of the first part of the lifting module of a coin lifting machine disclosed in an embodiment of this utility model.
[0022] Figure 3 The diagram shown is a structural schematic of the lifting drive component and reversing component of the lifting module of a coin lifting machine disclosed in an embodiment of this utility model.
[0023] Figure 4 The image shown is a detailed structural diagram of the second part of the lifting module of a coin lifting machine disclosed in an embodiment of this utility model.
[0024] Figure 5 The image shown is a detailed structural diagram of the linkage between the lifting module and the conveying module of a coin lifting machine disclosed in an embodiment of this utility model.
[0025] Figure 6 The diagram shown is a schematic diagram of the chassis module structure of a coin lifting machine disclosed in an embodiment of this utility model.
[0026] Figure 7 The diagram shown is a schematic diagram of the hopper assembly structure of a coin lifting machine disclosed in an embodiment of this utility model.
[0027] Component labeling: 1. Chassis module; 101. Chassis base plate; 102. Wheel; 103. Reinforced side plate; 104. Material chute; 105. Baffle; 2. Lifting module; 21. Lifting drive assembly; 2101. Drive motor; 2102. Power bearing; 2103. Power shaft; 22. Reversing assembly; 2201. Transmission bracket; 2202. First transmission shaft; 2203. Transmission sprocket; 2204. Drive sprocket; 2205. First bevel gear; 22 06. Chain; 23. Lifting belt; 24. Lifting outer cover; 25. Belt limit block; 26. Lifting driven wheel assembly; 2601. Lifting driven roller; 2602. Lifting driven shaft; 27. Tensioner; 3. Hopper assembly; 301. Connecting base plate; 302. Connecting cover plate; 303. Hopper gate; 304. Hopper bin; 305. Flow restrictor; 4. Conveying mechanism; 401. Conveying driven roller; 402. Conveyor belt; 403. Second bevel gear; 5. Support base. Detailed Implementation
[0028] The following specific embodiments illustrate the implementation of this utility model. Those skilled in the art can easily understand other advantages and effects of this utility model from the content disclosed in this specification. It should be noted that, unless otherwise specified, the following embodiments and features can be combined with each other.
[0029] Please see Figure 1This utility model provides a coin lifting machine, including: a chassis module 1, which is disposed at the bottom end of the coin lifting machine; and a lifting module 2, which is vertically and inclinedly connected to the chassis module 1.
[0030] Please see Figure 2 The lifting module 2 includes a reversing component 22 and a lifting drive component 21. The lifting drive component 21 is connected to the reversing component 22. The lifting drive component 21 includes a single drive motor 2101, which is used to drive and change the transmission direction of the lifting module 2; a hopper component 3, which is located at the bottom of the lifting module 2; a conveying mechanism 4, which is located at the top of the lifting module 2; and a support base 5, which is connected to the lifting module 2 and the chassis module 1 at both ends respectively.
[0031] The vertically inclined lifting module 2 and modular structure design significantly improve space utilization. It employs a single-motor driven reversing assembly 22 to achieve power transmission and direction conversion, simplifying the transmission structure and reducing the space occupied by redundant components. The hopper assembly 3 is located at the bottom of the lifting module 2, and the conveying mechanism 4 is located at the top. Together with the support base 5 and the chassis module 1, they form a compact and stable three-dimensional frame. This allows the equipment to achieve efficient vertical lifting while occupying only a small ground projection area, making it suitable for space-constrained environments and achieving the technical effect of small footprint and high space utilization.
[0032] For further details, please refer to Figure 3 A drive roller is provided on the drive single motor 2101, and a power shaft 2103 bearing 2102 is provided on the drive roller. The power shaft 2103 bearing 2102 is connected to the power shaft 2103; the power shaft 2103 is connected to the reversing assembly 22.
[0033] By integrating a drive roller on the drive motor 2101 and connecting the power shaft 2103 bearing 2102 and the power shaft 2103 in sequence, and finally transmitting the power to the reversing assembly 22, a high degree of integration and structural compactness of the power transmission path is achieved, which effectively reduces the space occupation required by traditional multi-motor or multi-stage transmission and improves the layout density and space utilization of internal components.
[0034] Furthermore, the reversing assembly 22 includes a transmission bracket 2201, a first transmission shaft 2202, a transmission sprocket 2203, a drive sprocket 2204, a first bevel gear 2205, and a chain 2206; the first transmission shaft 2202 passes through the transmission bracket 2201, and the transmission sprocket 2203 and the first bevel gear 2205 are sleeved on the first transmission shaft 2202, and the drive sprocket 2204 is sleeved on the drive shaft 2103; the drive sprocket 2204 is correspondingly arranged with the transmission sprocket 2203, and its outer ring meshes with the chain 2206.
[0035] The reversing assembly 22 integrates the first drive shaft 2202 on the transmission bracket 2201 and coaxially connects the transmission sprocket 2203 with the first bevel gear 2205. It also engages with the drive sprocket 2204 on the power shaft 2103 and the transmission sprocket 2203 via a chain 2206, thus achieving efficient power transmission and steering in the vertical direction. The overall structure is compact and the layout is reasonable. It effectively utilizes axial space and improves the utilization efficiency of the internal space of the equipment. This makes the coin hoist more compact while meeting functional requirements, and significantly reduces the overall volume and floor space.
[0036] For further details, please refer to Figure 4 Lifting module 2 is provided with lifting outer shell 24 on both sides. Lifting outer shell 24 is provided with lifting belt 23, belt limiting block 25, and lifting driven wheel assembly 26. Lifting drive assembly 21 is provided correspondingly to lifting driven wheel assembly 26, and lifting belt 23 is provided on the outer ring. Belt limiting block 25 is provided on the inner wall of lifting outer shell 24.
[0037] This structure not only improves operational stability and safety, but also makes full use of vertical space to achieve a three-dimensional layout, reducing the space required for external protection and guidance mechanisms, further improving the overall space utilization of the equipment, making the lifting module 2 structure more compact, and significantly reducing the equipment volume and floor space.
[0038] For further details, please refer to Figure 5 The conveying mechanism 4 is vertically connected to the lifting module 2 and includes a set of conveying driven rollers 401, a conveyor belt 402, and a second bevel gear 403. The conveying driven rollers 401 are covered by the conveyor belt 402. The second bevel gear 403 is disposed on the conveying driven rollers 401 close to the lifting module 2 and meshes with the first bevel gear 2205 to rotate.
[0039] The conveying mechanism 4 is vertically connected to the lifting module 2. By mounting the conveyor belt 402 on the driven roller 401 and using the second bevel gear 403 to mesh with the first bevel gear 2205 in the lifting module 2, the power is transmitted efficiently, converting the vertical motion into horizontal conveying power. There is no need to configure an independent motor or complex transmission device. The orthogonal layout of the space is fully utilized, effectively reducing the horizontal and vertical space occupied by the equipment and significantly improving the overall space utilization rate.
[0040] For further details, please refer to Figure 6 The chassis module 1 includes a chassis base plate 101, wheels 102, reinforcing side plates 103, a material leakage chute 104, and a baffle 105. Four sets of wheels 102 are installed at the bottom of the chassis base plate 101, and reinforcing side plates 103 are provided on both sides of the chassis base plate 101. A material leakage chute 104 is opened on the chassis base plate 101, and a baffle 105 is installed on the material leakage chute 104. The material leakage chute 104 is connected to the lifting module 2.
[0041] This integrated design effectively utilizes the bottom space, further improving the overall space utilization and compact layout of the equipment.
[0042] For further details, please refer to Figure 7 The hopper assembly 3 includes a connecting base plate 301, a connecting cover plate 302, a hopper gate 303, a hopper bin 304, and a flow restrictor 305. The connecting cover plate 302 is provided on the side of the connecting base plate 301. The hopper gate 303 is provided on the connecting cover plate and the connecting base plate 301. The hopper bin 304 is provided inside the hopper gate 303. The flow restrictor 305 is provided inside the hopper bin 304. The opening of the hopper bin 304 is opened on the connecting base plate 301 and is correspondingly provided with the lifting module 2.
[0043] This structure integrates storage, flow control, and connection functions into a compact space. The vertical docking lifting module 2 optimizes the material transfer path, reduces horizontal space occupation, and facilitates maintenance, significantly improving the overall space utilization and operational reliability of the equipment.
[0044] Furthermore, the workflow of a coin lifting machine includes:
[0045] First, the operator pours the coins to be processed into the hopper chamber 304 of the hopper assembly 3. The coins flow downwards under the action of gravity and pass through the flow restriction hood 305 inside the hopper chamber 304 to achieve preliminary diversion and sorting, so as to avoid a large accumulation or blockage of coins and ensure that the coins enter the lifting area in an orderly manner in a single layer or in small stacks.
[0046] Furthermore, in the lifting module 2, the drive roller driven by the drive single motor 2101 drives the drive sprocket 2204 to rotate through the power shaft 2103 bearing 2102 and the power shaft 2103. The drive sprocket 2204 engages with the transmission sprocket 2203 in the reversing assembly 22 through the chain 2206, and transmits power to the first transmission shaft 2202.
[0047] Furthermore, the first bevel gear 2205 mounted on the first drive shaft 2202 meshes with the second bevel gear 403 of the conveying mechanism 4 to achieve vertical power steering. At the same time, the first drive shaft 2202 drives the lifting drive assembly 21 to operate, driving the lifting belt 23 to circulate between the lifting driven pulley assembly 26.
[0048] Furthermore, the coins are conveyed upwards by the lifting belt 23 along the inclined direction, and the lifting outer cover 24 on both sides and the belt limiting block 25 on the inner wall effectively prevent the belt from running off-center, ensuring smooth operation.
[0049] Furthermore, when the coin is lifted to the top, it enters the conveying mechanism 4, which is vertically connected to the lifting module 2. Power is transmitted to the conveying driven roller 401 through the meshing of the first bevel gear 2205 and the second bevel gear 403, which drives the conveyor belt 402 to operate and horizontally convey the coin to the next processing station, such as counting, sorting or packaging equipment, thus completing the entire lifting and output process.
[0050] Throughout its operation, this device, through its highly integrated transmission and structural design, achieves a continuous and space-saving workflow for coins, from feeding and vertical lifting to horizontal output.
[0051] The above embodiments are merely illustrative of the principles and effects of this utility model and are not intended to limit this utility model. All equivalent modifications or alterations made by those skilled in the art without departing from the spirit and technical concept disclosed in this utility model should still be covered by the claims of this utility model.
Claims
1. A coin lifting machine, characterized in that, include: The chassis module is located at the bottom of the coin lifting machine; The lifting module is vertically and inclinedly connected to the chassis module; the lifting module includes a reversing component and a lifting drive component, the lifting drive component is connected to the reversing component, and the lifting drive component includes a single drive motor for driving and changing the transmission direction of the lifting module; a hopper component is located at the bottom of the lifting module; a conveying mechanism is located at the top of the lifting module; and a support base is connected to the lifting module and the chassis module at both ends respectively.
2. The coin lifting machine according to claim 1, characterized in that, The drive motor is equipped with a drive roller, the drive roller is equipped with a power bearing, and the power bearing is connected to a power shaft; the power shaft is connected to a reversing assembly.
3. A coin lifting machine according to claim 2, characterized in that, The reversing assembly includes a transmission bracket, a first transmission shaft, a transmission sprocket, a drive sprocket, a first bevel gear, and a chain; the first transmission shaft passes through the transmission bracket, and the transmission sprocket and the first bevel gear are sleeved on the first transmission shaft; the drive sprocket is sleeved on the drive shaft; the drive sprocket and the transmission sprocket are correspondingly arranged, and their outer rings mesh with the chain.
4. A coin lifting machine according to claim 1, characterized in that, The lifting module is provided with lifting outer shells on both sides. The lifting outer shells are provided with lifting belts, belt limiting blocks, and lifting driven wheel assemblies. The lifting drive assembly is provided correspondingly to the lifting driven wheel assembly, and the lifting belt is provided on the outer ring. The belt limiting block is provided on the inner wall of the lifting outer shell.
5. A coin lifting machine according to claim 1, characterized in that, The conveying mechanism is vertically connected to the lifting module and includes a set of driven conveying rollers, a conveyor belt, and a second bevel gear. The driven conveying rollers are fitted with a conveyor belt, and the second bevel gear is mounted on the driven conveying rollers close to the lifting module and meshes with the first bevel gear for rotation.
6. A coin lifting machine according to claim 1, characterized in that, The chassis module includes a chassis base plate, wheels, reinforcing side plates, a material leakage trough, and baffles; four sets of wheels are installed at the bottom of the chassis base plate, and reinforcing side plates are provided on both sides of the chassis base plate; a material leakage trough is opened on the chassis base plate, and a baffle is installed on the material leakage trough; the material leakage trough is connected to the lifting module.
7. A coin lifting machine according to claim 1, characterized in that, The hopper assembly includes a connecting base plate, a connecting cover plate, a hopper gate, a hopper bin, and a flow restrictor; the connecting cover plate is provided on the side of the connecting base plate, the hopper gate is provided on the connecting cover plate and the connecting base plate, the hopper bin is provided inside the hopper gate, and the flow restrictor is provided inside the hopper bin; the opening of the hopper bin is opened on the connecting base plate and is correspondingly provided with the lifting module.