A goods carrying device for logistics storage
The adjustable handling mechanism solves the problem of insufficient adaptability of traditional equipment to goods of different sizes, realizing efficient and safe cargo handling and improving the operational efficiency and safety of logistics warehousing.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- WEIFANG CHUFAN CULTURE MEDIA CO LTD
- Filing Date
- 2025-06-06
- Publication Date
- 2026-06-05
AI Technical Summary
Existing cargo handling equipment lacks flexibility to adapt to goods of different sizes and shapes, requiring operators to frequently change handling tools, reducing work efficiency, and also presenting problems of instability and safety.
The adjustable handling mechanism, including adjusting blocks, spring-supported positioning rods, and telescopic main and secondary compression rods, allows for adjustment of the width of the carrying platform to accommodate goods of different sizes, enhancing the flexibility and stability of the device.
It improves handling efficiency and safety, reduces tool replacement frequency, lowers operational difficulty and maintenance costs, and ensures the safety and reliability of goods during handling.
Smart Images

Figure CN224324004U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of logistics cargo handling technology, and in particular relates to a cargo handling device for logistics warehousing. Background Technology
[0002] In the logistics and warehousing industry, the handling and transfer of goods are key aspects of daily operations. With the booming development of e-commerce and the continuous growth of warehousing demand, the requirements for goods handling equipment are also increasing. However, existing goods handling equipment still has some unresolved issues in practical applications. Traditional handling equipment is often designed in a single way and lacks flexibility in adapting to goods of different sizes, shapes, and weights. This leads to operators having to frequently change handling tools of different specifications during the handling process, which greatly reduces work efficiency. In addition, some handling equipment is insufficient in terms of stability and safety, and is prone to goods tipping over or being damaged during handling, posing safety hazards to warehouse management.
[0003] Based on the technical effects of existing technologies and solutions, there are still areas that need optimization: traditional handling devices often lack flexibility in adapting to goods of different widths. This device, through an adjustable handling mechanism, especially through adjusting blocks, spring-supported positioning rods, and telescopic main and secondary compression rods, can easily adjust the width of the carrying platform, thereby adapting to goods of different sizes and greatly improving the flexibility and applicability of handling. Utility Model Content
[0004] To address the problems existing in the prior art, this utility model provides a cargo handling device for logistics warehousing. Traditional handling devices often lack flexibility in adapting to goods of different widths. This device, through an adjustable handling mechanism, particularly through an adjusting block, a spring-supported positioning rod, and telescopic main and secondary compression rods, can easily adjust the width of the carrying platform, thereby adapting to goods of different sizes and greatly improving the flexibility and applicability of handling.
[0005] This utility model is implemented as follows: a cargo handling device for logistics warehousing.
[0006] A conveying mechanism includes a conveying plate, with several rollers at each of the four ends of the bottom of the conveying plate, and a pusher on the left side of the conveying plate;
[0007] An adjustment mechanism is provided, comprising adjustment plates disposed at both ends of the top of the conveying plate, an adjustment groove being provided on the top of the adjustment plate, an adjustment block being slidably connected to the surface of the adjustment groove, a pulling component and a positioning component being respectively disposed inside the top of the adjustment block, and a squeezing component being disposed on the inner wall of the adjustment block.
[0008] In a preferred embodiment of this invention, the pulling assembly includes a pulling groove formed on the inner wall of the adjusting block. The top of the pulling groove extends to the outer side of the adjusting block. A pulling rod is slidably connected to the surface of the pulling groove. Pulling blocks are provided on both the left and right sides of the pulling rod. The sliding cooperation between the pulling rod and the pulling groove simplifies the position adjustment operation of the adjusting block, making it easier for users to quickly adjust the position of the adjusting block manually and improving efficiency.
[0009] In a preferred embodiment of this invention, the positioning component includes a positioning rod disposed inside the adjusting block. Positioning plates are provided on both sides of the positioning rod, and a support rod is provided on the right side of each positioning plate. The right side of the support rod extends through to the right side of a support column. The bottom of the support column is fixedly connected to the inner wall of the adjusting block. A spring is sleeved on the surface of the support rod, and the left and right sides of the spring are fixedly connected to the opposite sides of the positioning rod and the support column, respectively. The spring force causes the positioning rod to automatically reset, achieving rapid locking of the adjusting block within the adjusting groove. The linkage design between the support rod and the positioning plates enhances positioning stability, prevents accidental slippage of the adjusting block during handling, and ensures cargo safety.
[0010] In a preferred embodiment of this invention, the extrusion assembly includes a main extrusion rod disposed on the inner wall of the adjusting block, a secondary extrusion rod slidably connected to the inner wall of the main extrusion rod, pin holes being provided on the left and right sides of the main extrusion rod and the secondary extrusion rod, and a plurality of pin holes being provided on the surface of the secondary extrusion rod, with pins provided on the inner wall of the pin holes. The telescopic design of the main extrusion rod and the secondary extrusion rod allows the lateral length of the adjusting block to adapt to different cargo widths. The cooperation of the pins with the multiple pin holes provides multiple fixed positions, enhancing the load-bearing capacity and adjustment accuracy of the device.
[0011] As a preferred embodiment of this utility model, the inner wall of the adjusting block is provided with a stroke groove, and a stroke column is provided on the surface of the stroke groove. The top of the stroke column is fixedly connected to the bottom of the positioning plate. The stroke groove limits the movement range of the stroke column, preventing the positioning plate from failing due to excessive displacement, thus improving the durability and operational safety of the positioning component.
[0012] As a preferred embodiment of this utility model, a pull rope is provided on the right side of the support rod. One side of the pull rope is fixedly connected to the bottom of the pull block. The pull rope enables the linkage between the pull component and the positioning component. The operation of the pull block can simultaneously release the locking of the positioning rod, making the adjustment process smoother and reducing the complexity of user operation.
[0013] As a preferred embodiment of this utility model, the inner wall of the adjustment groove is provided with a plurality of positioning grooves, and the plurality of positioning grooves are used in conjunction with positioning rods. Through the fixed position provided by the multiple positioning grooves, the adjustment block is ensured to be accurately positioned in the adjustment groove, thereby enhancing the adaptability of the device to goods of different sizes and preventing displacement caused by vibration during handling.
[0014] Compared with the prior art, the beneficial effects of this utility model are as follows:
[0015] 1. The main advantage of this cargo handling device for logistics and warehousing lies in its significantly improved handling efficiency and flexibility. Through innovative adjustment and locking mechanisms, the device can easily adapt to cargo of different widths without the need for frequent changes of handling tools, thereby greatly saving time and labor costs. At the same time, its stable structure and strong load-bearing capacity ensure safety and reliability during the handling process, effectively avoiding the risks of cargo damage and personal injury, and providing strong support for the efficient operation of the logistics and warehousing industry.
[0016] 2. In addition, the handling device has additional advantages such as convenient operation and low maintenance cost. Its design is simple and clear, and operators can quickly get started without professional training, which greatly reduces the difficulty of operation. At the same time, the wear resistance and durability of the device have been optimized, and it can still maintain good performance under long-term use, reducing the frequency of maintenance and replacement, and further reducing the cost of warehouse management. Attached Figure Description
[0017] Figure 1 This is a schematic diagram of the handling mechanism provided in an embodiment of the present utility model;
[0018] Figure 2 This is provided by the embodiment of the present utility model. Figure 1 A magnified view of a portion of point A in the middle;
[0019] Figure 3 This is a schematic diagram of the extrusion assembly provided in an embodiment of the present invention;
[0020] Figure 4 This is a schematic diagram of the pulling component and the positioning component provided in an embodiment of the present utility model.
[0021] In the diagram: 100, conveying mechanism; 101, conveying plate; 102, roller; 103, pusher; 200, adjusting mechanism; 201, adjusting plate; 202, adjusting groove; 203, adjusting block; 204, pulling assembly; 204a, pulling groove; 204b, pulling rod; 204c, pulling block; 205, positioning assembly; 205a, positioning rod; 205b, positioning plate; 205c, support rod; 205d, support column; 205e, spring; 206, extrusion assembly; 206a, main extrusion rod; 206b, secondary extrusion rod; 206c, pin hole; 206d, pin; 207, stroke groove; 208, stroke column; 209, pull rope; 210, positioning groove. Detailed Implementation
[0022] To further understand the invention content, features and effects of this utility model, the following embodiments are provided, and detailed descriptions are given in conjunction with the accompanying drawings.
[0023] The structure of this utility model will now be described in detail with reference to the accompanying drawings.
[0024] like Figures 1 to 4 As shown in the figure, this utility model provides a cargo handling device for logistics warehousing.
[0025] The conveying mechanism 100 includes a conveying plate 101, with several rollers 102 at each of the four ends of the bottom of the conveying plate 101, and a pusher 103 on the left side of the conveying plate 101.
[0026] The adjustment mechanism 200 includes adjustment plates 201 disposed at both ends of the top of the conveying plate 101. The top of the adjustment plate 201 is provided with an adjustment groove 202. An adjustment block 203 is slidably connected to the surface of the adjustment groove 202. A pulling component 204 and a positioning component 205 are respectively disposed inside the top of the adjustment block 203. A pressing component 206 is disposed on the inner wall of the adjustment block 203.
[0027] refer to Figure 2 , 4 The pulling assembly 204 includes a pulling groove 204a formed in the inner wall of the adjusting block 203. The top of the pulling groove 204a extends to the outer side of the adjusting block 203. A pulling rod 204b is slidably connected to the surface of the pulling groove 204a. Pulling blocks 204c are provided on both the left and right sides of the pulling rod 204b.
[0028] The above solution simplifies the position adjustment operation of the adjusting block 203 by sliding the pull rod 204b with the pull groove 204a, making it easier for users to quickly adjust the position of the adjusting block 203 manually and improving efficiency.
[0029] refer to Figure 2 , 4 The positioning component 205 includes a positioning rod 205a disposed inside the adjusting block 203. Positioning plates 205b are disposed on both sides of the positioning rod 205a. A support rod 205c is disposed on the right side of the positioning plate 205b. The right side of the support rod 205c extends through to the right side of the support column 205d. The bottom of the support column 205d is fixedly connected to the inner wall of the adjusting block 203. A spring 205e is sleeved on the surface of the support rod 205c. The left and right sides of the spring 205e are fixedly connected to the opposite sides of the positioning rod 205a and the support column 205d, respectively.
[0030] The above solution is adopted: the spring force of the spring 205e causes the positioning rod 205a to automatically reset, realizing the quick locking of the adjusting block 203 in the adjusting groove 202. The linkage design between the support rod 205c and the positioning plate 205b enhances the positioning stability, prevents the adjusting block 203 from sliding accidentally during the handling process, and ensures the safety of the goods.
[0031] refer to Figure 1 , 3 The extrusion assembly 206 includes a main extrusion rod 206a disposed on the inner wall of the adjusting block 203, a secondary extrusion rod 206b slidably connected to the inner wall of the main extrusion rod 206a, pin holes 206c are opened on the left and right sides of the main extrusion rod 206a and the secondary extrusion rod 206b, a plurality of pin holes 206c are opened on the surface of the secondary extrusion rod 206b, and a pin 206d is disposed on the inner wall of the pin hole 206c.
[0032] The above solution allows the lateral length of the adjusting block 203 to adapt to different cargo widths through the telescopic design of the main extrusion rod 206a and the auxiliary extrusion rod 206b. The cooperation between the pin rod 206d and multiple pin holes 206c provides multiple fixed positions, enhancing the load-bearing capacity and adjustment accuracy of the device.
[0033] refer to Figure 2 , 4 The inner wall of the adjusting block 203 is provided with a stroke groove 207, and a stroke column 208 is provided on the surface of the stroke groove 207. The top of the stroke column 208 is fixedly connected to the bottom of the positioning plate 205b.
[0034] The above solution is adopted: the movement range of the stroke column 208 is limited by the stroke groove 207, so as to avoid the failure of the spring 205e or damage to the component due to excessive displacement of the positioning plate 205b, thereby improving the durability and operational safety of the positioning component 205.
[0035] refer to Figure 2 , 4 A pull rope 209 is provided on the right side of the support rod 205c, and one side of the pull rope 209 is fixedly connected to the bottom of the pull block 204c.
[0036] The above solution is adopted: the pulling component 204 and the positioning component 205 are linked by the pull rope 209. The operation of the pulling block 204c can simultaneously release the locking of the positioning rod 205a, making the adjustment process smoother and reducing the complexity of user operation.
[0037] refer to Figure 2 , 4 The inner wall of the adjustment groove 202 is provided with several positioning grooves 210, and the positioning grooves 210 are used in conjunction with the positioning rod 205a.
[0038] The above solution ensures that the adjusting block 203 is accurately positioned within the adjusting groove 202 by using the fixed positions provided by multiple positioning grooves 210, thereby enhancing the adaptability of the device to goods of different sizes and preventing displacement caused by vibration during handling.
[0039] The working principle of this utility model:
[0040] When using this conveying device;
[0041] The core of the device is the handling mechanism 100, the main body of which is a handling plate 101 with four-end rollers 102. The bottom rollers 102 provide low-friction movement capability, and the pusher 103 is used for manual control of direction and pushing. The handling plate 101 serves as a carrying platform, where goods can be placed directly and quickly transferred in the storage environment via the rollers 102.
[0042] The user manually controls the sliding of the adjusting block 203 by pulling the lever 204b and the pulling block 204c. When the lever 204b moves along the adjusting groove 202, it causes the adjusting block 203 to move laterally, thereby adjusting the distance between the two adjusting blocks 203 to adapt to the width of the goods. The adjusting block 203 is equipped with a positioning rod 205a supported by a spring 205e. When the adjusting block 203 slides to the target position, the spring 205e pushes the positioning rod 205a into the preset positioning groove 210 in the adjusting groove 202 to achieve mechanical locking and prevent the adjusting block 203 from accidentally shifting during handling. The main pressing rod 206a and the auxiliary pressing rod 206b can be telescopically adjusted in lateral length through the cooperation of the pin hole 206c and the pin 206d, further expanding the adjustment range to adapt to extra-wide goods or provide lateral clamping force to enhance stability.
[0043] When the user pulls the pull rod 204b outward, the pull block 204c pulls the support rod 205c through the pull rope 209, forcing the positioning rod 205a to disengage from the positioning groove 210 and release the locked state. At this time, the adjusting block 203 can slide freely. After the pull rod 204b is released, the spring 205e automatically resets, and the positioning rod 205a re-embeds into the nearest positioning groove 210 to complete the fixation. The cooperation between the stroke groove 207 and the stroke column 208 limits the movement range of the positioning plate 205b, preventing the spring 205e from being overloaded or the components from being misaligned, ensuring long-term durability. In addition, the multi-stage pin hole 206c design allows the user to select the fixed position according to the width of the goods, and the rigid support of the main extrusion rod 206a and the secondary extrusion rod 206b disperses the pressure on the goods, improving the load-bearing capacity.
[0044] In summary, this logistics warehousing cargo handling device addresses the common shortcomings of traditional handling devices, which often lack flexibility in adapting to goods of varying widths. This device, through its adjustable handling mechanism, particularly the adjusting blocks, spring-supported positioning rods, and telescopic main and secondary compression rods, can easily adjust the width of the carrying platform, thereby accommodating goods of different sizes and significantly improving handling flexibility and applicability.
[0045] It should be noted that, in this document, relational terms such as "first" and "second" are used only to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Furthermore, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such process, method, article, or apparatus.
[0046] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.
Claims
1. A cargo handling device for logistics warehousing, characterized in that: The conveying mechanism (100) includes a conveying plate (101), and a plurality of rollers (102) are provided at the four ends of the bottom of the conveying plate (101). A pusher (103) is provided on the left side of the conveying plate (101). An adjustment mechanism (200) is provided, comprising adjustment plates (201) disposed at both ends of the top of the conveying plate (101), an adjustment groove (202) is provided on the top of the adjustment plate (201), an adjustment block (203) is slidably connected to the surface of the adjustment groove (202), a pulling component (204) and a positioning component (205) are respectively disposed inside the top of the adjustment block (203), and a squeezing component (206) is disposed on the inner wall of the adjustment block (203).
2. The cargo handling device for logistics warehousing as described in claim 1, characterized in that: The pulling assembly (204) includes a pulling groove (204a) formed in the inner wall of the adjusting block (203). The top of the pulling groove (204a) extends to the outer side of the adjusting block (203). A pulling rod (204b) is slidably connected to the surface of the pulling groove (204a). Pulling blocks (204c) are provided on both the left and right sides of the pulling rod (204b).
3. The cargo handling device for logistics warehousing as described in claim 2, characterized in that: The positioning component (205) includes a positioning rod (205a) disposed inside the adjusting block (203). Positioning plates (205b) are provided on both sides of the positioning rod (205a). A support rod (205c) is provided on the right side of the positioning plate (205b). The right side of the support rod (205c) extends through to the right side of the support column (205d). The bottom of the support column (205d) is fixedly connected to the inner wall of the adjusting block (203). A spring (205e) is sleeved on the surface of the support rod (205c). The left and right sides of the spring (205e) are fixedly connected to the opposite sides of the positioning rod (205a) and the support column (205d), respectively.
4. A cargo handling device for logistics warehousing as described in claim 3, characterized in that: The extrusion assembly (206) includes a main extrusion rod (206a) disposed on the inner wall of the adjusting block (203). A secondary extrusion rod (206b) is slidably connected to the inner wall of the main extrusion rod (206a). Pin holes (206c) are provided on the left and right sides of the main extrusion rod (206a) and the secondary extrusion rod (206b). Several pin holes (206c) are provided on the surface of the secondary extrusion rod (206b). A pin (206d) is provided on the inner wall of the pin hole (206c).
5. A cargo handling device for logistics warehousing as described in claim 4, characterized in that: The inner wall of the adjusting block (203) is provided with a stroke groove (207), and a stroke column (208) is provided on the surface of the stroke groove (207). The top of the stroke column (208) is fixedly connected to the bottom of the positioning plate (205b).
6. A cargo handling device for logistics warehousing as described in claim 5, characterized in that: A pull rope (209) is provided on the right side of the support rod (205c), and one side of the pull rope (209) is fixedly connected to the bottom of the pull block (204c).
7. A cargo handling device for logistics warehousing as described in claim 6, characterized in that: The inner wall of the adjustment groove (202) is provided with a number of positioning grooves (210), and the positioning grooves (210) are used in conjunction with the positioning rod (205a).