A kind of for shock absorption impermeable concrete block storage stacking machine
By designing a palletizer with a clamping and moving part, the problem of stable clamping of blocks of different specifications was solved, realizing precise palletizing and automated operation of concrete blocks, and improving palletizing efficiency and positional accuracy.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- ZHEJIANG HANGSHI BUILDING MATERIALS CO LTD
- Filing Date
- 2025-08-05
- Publication Date
- 2026-07-10
Smart Images

Figure CN224477625U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of block storage technology, and in particular relates to a palletizing machine for storing shock-absorbing and impermeable concrete blocks. Background Technology
[0002] Shock-absorbing and waterproof concrete blocks are concrete products made with special proportions and processes. They combine shock absorption and buffering properties with waterproof and impermeable characteristics. They are often used in building walls and other applications where structural stability and waterproofing are required. Palletizing machines are used for storage because they can automate and neatly stack the blocks, which not only improves the utilization of storage space and reduces the labor intensity and errors of manual handling, but also prevents damage to the blocks due to uneven stress through standardized stacking, thus ensuring product quality and management efficiency during storage.
[0003] However, the existing devices, due to their relatively simple clamping method, are difficult to stably clamp concrete blocks of different specifications and shapes. This problem will reduce the continuity and overall efficiency of concrete block stacking. Utility Model Content
[0004] The purpose of this utility model is to provide a palletizing machine for storing shock-absorbing and impermeable concrete blocks. By setting up a clamping part, it solves the problem that the relatively simple clamping method makes it difficult to stably clamp concrete blocks of different specifications and shapes, which would reduce the continuity and overall efficiency of concrete block palletizing.
[0005] To solve the above-mentioned technical problems, this utility model is achieved through the following technical solution:
[0006] This utility model relates to a stacking machine for storing shock-absorbing and impermeable concrete blocks, comprising a support plate and further comprising: a clamping part disposed on the support plate; a moving part disposed at the bottom of the support plate; the clamping part comprising a clamping assembly mounted on the support plate; and a driving assembly mounted on the clamping assembly; the clamping assembly comprising a plurality of grooves formed on the top of the support plate, wherein each groove has a slider slidably connected to its inner wall, each slider has an anti-slip clamp fixedly connected to its bottom, and each slider has a sliding rod fixedly connected to its top; a rotating shaft is rotatably connected to the top of the support plate, and an arc-shaped groove turntable is fitted on the outer wall of the rotating shaft; the tops of each sliding rod extend into the arc-shaped groove turntable and are slidably connected to it; wherein, four grooves are formed, and each of the four grooves has a slider slidably connected to it.
[0007] Furthermore, the movable part includes a movable component mounted on the bottom of the support plate; and a lifting component mounted on the top of the movable component; wherein the lifting component is used in conjunction with the movable component.
[0008] Furthermore, the drive assembly includes a top plate fixedly connected to the top of the support plate, a motor sleeve fixedly connected to the top of the top plate, a motor mounted on the motor sleeve, and the output shaft of the motor fixedly connected to the rotating shaft via a coupling. A sliding element is provided on the top plate. The top end of the rotating shaft extends beyond the top plate and is rotatably connected to it. The motor sleeve provides a stable mounting base for the motor, the coupling ensures stable power transmission from the motor to the rotating shaft, and the rotatably connected rotating shaft cooperates with the sliding element to provide power support for the operation of related components, thereby improving the stability and reliability of the drive process.
[0009] Furthermore, the moving component includes a counterweight frame disposed at the bottom of the support plate. A motor sleeve two is fixedly connected to the right side of the counterweight frame, and a motor two is mounted on the motor sleeve two. The output shaft of the motor two is fixedly connected to a screw rod via a coupling. A slider three is threadedly connected to the outer wall of the screw rod, and the slider three is slidably connected to the counterweight frame. The screw rod passes through the counterweight frame and is rotatably connected to the counterweight frame. The motor sleeve two provides stable mounting support for the motor two. The coupling ensures efficient transmission of motor power to the screw rod. The threaded connection between the screw rod and the slider three, combined with the slidable connection between the slider three and the counterweight frame, realizes the conversion of power into moving motion. The rotatably connected screw rod ensures smooth operation and improves the stability and driving effectiveness of the moving component.
[0010] Furthermore, the lifting assembly includes a slide rod group fixedly connected to the top of the slider three. A top plate two is fixedly connected to the top of the slide rod group. A lifting plate is slidably connected to the outer wall of the slide rod group. A hydraulic push rod one is sleeved on the top plate two. The output end of the hydraulic push rod one is fixedly connected to the lifting plate. A movable component is provided on the lifting plate. The slide rod group consists of two slide rods. The slide rod group composed of two slide rods provides stable guiding support for the lifting plate. The hydraulic push rod one can drive the lifting plate to move up and down precisely along the slide rod group. The movable component can cooperate to realize related functions, thus improving the stability, accuracy and functionality of the lifting operation as a whole.
[0011] Furthermore, the sliding component includes two sliders two fixedly connected to the top of the top plate one. A rectangular plate is fixedly connected to the top of the top plate one. The two sliders two can provide stable sliding support. The rectangular plate can serve as a connecting or force-bearing component. The two work together to provide a basis for the sliding action of the related structure, ensure the stability of the sliding process, and help the smooth realization of the function of the drive component.
[0012] Furthermore, the moving component includes a slide bar frame fixedly connected to the front of the lifting plate. Both sliders extend into the slide bar frame and are slidably connected to it. A hydraulic push rod is fixedly connected to the slide bar frame, and the output end of the hydraulic push rod is fixedly connected to the rectangular plate. The hydraulic push rod is located inside the slide bar frame, which provides sliding guidance for the sliders, ensuring movement stability. The hydraulic push rod can drive the rectangular plate to move precisely, thus improving the overall stability and accuracy of the moving component's movement and enhancing the functional flexibility of the lifting assembly.
[0013] This utility model has the following beneficial effects:
[0014] 1. By setting up a clamping part, in the clamping operation of concrete block transfer and stacking, the clamping component is first moved to the top of the block, and then the motor is started. The motor drives the arc-shaped groove turntable to rotate through the rotating shaft. The sliding rod connected in the turntable drives the slider 1 and the anti-slip clamp at the bottom of the turntable to move towards the center synchronously to complete the clamping. This setting ensures the stability and accuracy of clamping through the synchronous action of multiple anti-slip clamps, adapts to the needs of blocks of different specifications, and the anti-slip clamps increase the friction to prevent the blocks from slipping and improve the reliability of clamping.
[0015] 2. By setting up a moving part, during the transfer and stacking process after the concrete blocks are clamped, hydraulic push rod one is first activated to raise and lower the block to a suitable height to avoid obstacles and create conditions for horizontal movement. Then, hydraulic push rod two in the sliding frame on the lifting plate is activated to move the block horizontally for initial adjustment of the stacking position. If precise adjustment is required, motor two can be activated to drive slider three and the block through the screw to achieve precise fine-tuning in the horizontal direction, ensuring accurate alignment and stacking position. After the position is determined, hydraulic push rod one is activated again to lower the block and place it stably, completing the stacking. This setting realizes fully automated operation from clamping to transfer and stacking, which not only greatly improves stacking efficiency, but also ensures the accuracy of stacking position through multi-level adjustment, reducing manual labor intensity and error rate.
[0016] Of course, any product implementing this utility model does not necessarily need to achieve all of the advantages described above at the same time. Attached Figure Description
[0017] To more clearly illustrate the technical solutions of the embodiments of this utility model, the accompanying drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0018] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0019] Figure 2 This is a partial cross-sectional view of the clamping part of this utility model;
[0020] Figure 3 This is an enlarged structural schematic diagram of the clamping part of this utility model;
[0021] Figure 4 This is a partial cross-sectional view of the movable part of this utility model;
[0022] Figure 5 This utility model Figure 2 A magnified structural diagram of A in the diagram.
[0023] The attached diagram lists the components represented by each number as follows:
[0024] 1. Support plate; 2. Clamping part; 21. Clamping assembly; 211. Slide groove; 212. Slider one; 213. Anti-slip clamp; 214. Slide rod; 215. Rotating shaft; 216. Arc groove turntable; 22. Drive assembly; 221. Top plate one; 222. Motor sleeve one; 223. Motor one; 224. Slider two; 225. Rectangular plate; 3. Moving part; 31. Moving assembly; 311. Counterweight frame; 312. Motor sleeve two; 313. Motor two; 314. Screw; 315. Slider three; 32. Lifting assembly; 321. Slide rod group; 322. Top plate two; 323. Lifting plate; 324. Hydraulic push rod one; 325. Slide rod frame; 326. Hydraulic push rod two. Detailed Implementation
[0025] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0026] Please see Figure 1-5 As shown, this utility model is a stacking machine for storing shock-absorbing and impermeable concrete blocks, including a support plate 1, and further including: a clamping part 2, which is disposed on the support plate 1; and a moving part 3, which is disposed at the bottom of the support plate 1.
[0027] The clamping part 2 includes a clamping assembly 21, which is mounted on the support plate 1; and a driving assembly 22, which is mounted on the clamping assembly 21. The clamping assembly 21 includes a plurality of sliding grooves 211 formed on the top of the support plate 1. Each of the sliding grooves 211 has a slider 212 slidably connected to its inner wall. Each of the sliders 212 has an anti-slip clamp 213 fixedly connected to its bottom. Each of the sliders 212 has a sliding rod 214 fixedly connected to its top. The top of the support plate 1 is rotatably connected to... A rotating shaft 215 is connected to the outer wall of the rotating shaft 215, and an arc-shaped groove turntable 216 is fitted on the outer wall of the rotating shaft 215. The top ends of several sliding rods 214 extend into the arc-shaped groove turntable 216 and are slidably connected to the arc-shaped groove turntable 216. Among them, four sliding grooves 211 are opened, and a slider 212 is slidably connected in each of the four sliding grooves 211. The driving assembly 22 includes a top plate 221 fixedly connected to the top of the support plate 1. A motor sleeve 222 is fixedly connected to the top of the top plate 221, and a motor sleeve 222 is fitted on the motor sleeve 222. Motor 223, the output shaft of which is fixedly connected to rotating shaft 215 via a coupling, and a sliding member is provided on top plate 221; wherein, the top end of rotating shaft 215 extends outside top plate 221 and is rotatably connected to top plate 221, the sliding member includes two sliders 224 fixedly connected to the top of top plate 221, and a rectangular plate 225 is fixedly connected to the top of top plate 221. By providing clamping part 2, in the clamping operation of concrete block transfer and stacking, clamping assembly 2 is first clamped. 1. Move to the top of the block, then start the motor 223. The motor drives the arc-shaped groove turntable 216 to rotate through the rotating shaft 215. The slide rod 214 connected in the turntable drives the slider 212 and the anti-slip clamp 213 that slide in the support plate 1 to move towards the center in a synchronized manner to complete the clamping. This setting ensures the stability and accuracy of clamping through the synchronous action of multiple anti-slip clamps, adapts to the needs of different block sizes, and the anti-slip clamps increase the friction to prevent the block from slipping, thus improving the reliability of clamping.
[0028] The moving part 3 includes a moving component 31, which is installed at the bottom of the support plate 1; and a lifting component 32, which is installed at the top of the moving component 31. The lifting component 32 is used in conjunction with the moving component 31. The moving component 31 includes a counterweight frame 311 located at the bottom of the support plate 1. A motor sleeve 312 is fixedly connected to the right side of the counterweight frame 311. A motor 313 is fitted onto the motor sleeve 312. The output shaft of the motor 313 is fixedly connected to a screw 314 via a coupling. A slider 315 is threadedly connected to the outer wall of the screw 314. The screw 314 is slidably connected to the counterweight frame 311; wherein, the screw 314 passes through the counterweight frame 311 and is rotatably connected to the counterweight frame 311. The lifting assembly 32 includes a slide rod group 321 fixedly connected to the top of the slider 315. The top of the slide rod group 321 is fixedly connected to the top plate 322. The outer wall of the slide rod group 321 is slidably connected to the lifting plate 323. A hydraulic push rod 324 is sleeved on the top plate 322. The output end of the hydraulic push rod 324 is fixedly connected to the lifting plate 323. A movable part is provided on the lifting plate 323. The slide rod group 321 consists of two slide rods. The movable part includes a screw fixedly connected to the top of the slider 315. The sliding frame 325 on the front of the lifting plate 323 has two sliders 224 extending into and slidably connected to the sliding frame 325. A hydraulic push rod 326 is fixedly connected to the sliding frame 325, and the output end of the hydraulic push rod 326 is fixedly connected to the rectangular plate 225. The hydraulic push rod 326 is located inside the sliding frame 325. By setting the moving part 3, during the transfer and stacking process after the concrete blocks are clamped, the hydraulic push rod 324 is first activated to make the lifting plate 323 lift the blocks to a suitable height to avoid obstacles and create conditions for horizontal movement. Then the lifting plate 323 is activated. The hydraulic push rod 326 inside the sliding frame 325 on the plate drives the block to move horizontally for initial adjustment of the stacking position. If precise adjustment is required, the motor 313 can be started, and the screw 314 drives the slider 315 and the block to achieve precise fine adjustment in the horizontal direction, ensuring accurate alignment of the stacking position. After the position is determined, the hydraulic push rod 324 is started again to make the lifting plate move the block down and place it stably, completing the stacking. This setting realizes the fully automated operation from clamping to transfer and stacking, which not only greatly improves the stacking efficiency, but also ensures the accuracy of the stacking position through multi-level adjustment, reducing the intensity of manual labor and the error rate.
[0029] A specific application of this embodiment is as follows: During use, if it is necessary to clamp concrete blocks for easy transport and stacking, the operation steps are as follows: First, move the clamping assembly 21 to the top of the concrete block. Then, start the motor 223. The motor 223 will drive the arc-shaped groove turntable 216 to rotate via the rotating shaft 215. Since multiple sliding rods 214 are slidably connected inside the arc-shaped groove turntable 216, and the bottoms of these sliding rods 214 are fixedly connected to multiple sliders 212 sliding within the support plate 1, when the motor 223 drives the arc-shaped groove turntable 216 to rotate, multiple sliders 212 can be used to transport and stack the concrete blocks. The sliding rod 214, through its transmission mechanism, allows the slider 212 at its bottom to synchronously drive the anti-slip clamps 213 to converge towards the center, thus clamping the concrete block. This design enables the clamping of concrete blocks. The synchronous convergence of multiple anti-slip clamps 213 ensures the stability and accuracy of the clamping process, effectively adapting to the clamping requirements of concrete blocks of different specifications. Simultaneously, the anti-slip clamps 213 significantly increase the friction between themselves and the block, preventing the block from slipping during clamping and greatly improving the reliability of the clamping. When the concrete... After the concrete blocks are clamped, when they need to be transferred and stacked, hydraulic push rod 324 can be activated first to raise and lower the concrete blocks clamped on the lifting plate 323 to a suitable height to avoid surrounding obstacles and create conditions for subsequent horizontal movement and position adjustment. Next, hydraulic push rod 326 in the sliding frame 325 on the lifting plate 323 can be activated. Hydraulic push rod 326 can drive the concrete blocks clamped on the clamping assembly 21 to move horizontally and initially adjust them to the stacking position. If precise adjustment of the stacking position is required, motor 313 can be activated. Motor 313 drives slider 315 through screw 314. The hydraulic system precisely adjusts the horizontal position of the concrete blocks held on it to ensure that the blocks are accurately aligned with the stacking position. Once the position is adjusted, the hydraulic push rod 324 is activated again, causing it to move the concrete blocks held on the lifting plate 323 downwards until the blocks are stably placed at the stacking position, thus completing the stacking operation. This setup enables fully automated operation of the concrete blocks from clamping to transfer to stacking, which not only significantly improves stacking efficiency but also ensures the accuracy of the stacking position through multi-level adjustments, reducing the labor intensity and error rate of manual operation.
[0030] In the description of this specification, references to terms such as "an embodiment," "example," "specific example," etc., indicate that a specific feature, structure, material, or characteristic described in connection with that embodiment or example is included in at least one embodiment or example of the present invention. In this specification, the illustrative expressions of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the specific features, structures, materials, or characteristics described may be combined in any suitable manner in one or more embodiments or examples.
[0031] The preferred embodiments of this utility model disclosed above are merely illustrative of the present utility model. These preferred embodiments do not exhaustively describe all details, nor do they limit the utility model to the specific implementations described. Clearly, many modifications and variations can be made based on the content of this specification. This specification selects and specifically describes these embodiments to better explain the principles and practical applications of this utility model, thereby enabling those skilled in the art to better understand and utilize it. This utility model is limited only by the claims and their full scope and equivalents.
Claims
1. A palletizing machine for storing shock-absorbing and impermeable concrete blocks, comprising a support plate (1), characterized in that, Also includes: Clamping part (2), the clamping part (2) is disposed on the support plate (1); A movable part (3) is provided at the bottom of the support plate (1); The clamping part (2) includes a clamping assembly (21), which is mounted on the support plate (1); A drive assembly (22) is mounted on a clamping assembly (21); The clamping assembly (21) includes several grooves (211) formed on the top of the support plate (1). The inner walls of the grooves (211) are slidably connected to sliders (212). The bottoms of the sliders (212) are fixedly connected to anti-slip clamps (213). The tops of the sliders (212) are fixedly connected to slide rods (214). The top of the support plate (1) is rotatably connected to a rotating shaft (215). The outer wall of the rotating shaft (215) is fitted with an arc-shaped groove turntable (216). The tops of the slide rods (214) extend into the arc-shaped groove turntable (216) and are slidably connected to the arc-shaped groove turntable (216). Among them, four slides (211) are provided, and each of the four slides (211) is slidably connected to a slider (212).
2. A palletizing machine for storing shock-absorbing and impermeable concrete blocks according to claim 1, characterized in that, The moving part (3) includes a moving component (31) mounted on the bottom of the support plate (1); and A lifting assembly (32) is mounted on top of a movable assembly (31); The lifting component (32) is used in conjunction with the moving component (31).
3. A palletizing machine for storing shock-absorbing and impermeable concrete blocks according to claim 2, characterized in that, The drive assembly (22) includes a top plate (221) fixedly connected to the top of the support plate (1), a motor sleeve (222) fixedly connected to the top of the top plate (221), a motor (223) sleeved on the motor sleeve (222), the output shaft of the motor (223) fixedly connected to the rotating shaft (215) through a coupling, and a sliding member provided on the top plate (221). The top end of the rotating shaft (215) extends to the outside of the top plate (221) and is rotatably connected to the top plate (221).
4. A palletizing machine for storing shock-absorbing and impermeable concrete blocks according to claim 3, characterized in that, The moving component (31) includes a counterweight frame (311) disposed at the bottom of the support plate (1). A motor sleeve (312) is fixedly connected to the right side of the counterweight frame (311). A motor (313) is sleeved on the motor sleeve (312). A screw (314) is fixedly connected to the output shaft of the motor (313) through a coupling. A slider (315) is threadedly connected to the outer wall of the screw (314). The slider (315) is slidably connected to the counterweight frame (311). The screw (314) passes through the counterweight frame (311) and is rotatably connected to the counterweight frame (311).
5. A palletizing machine for storing shock-absorbing and impermeable concrete blocks according to claim 4, characterized in that, The lifting assembly (32) includes a slide rod group (321) fixedly connected to the top of the slider three (315). The top of the slide rod group (321) is fixedly connected to the top plate two (322). The outer wall of the slide rod group (321) is slidably connected to the lifting plate (323). The top plate two (322) is fitted with a hydraulic push rod one (324). The output end of the hydraulic push rod one (324) is fixedly connected to the lifting plate (323). The lifting plate (323) is provided with a moving part. The slide block assembly (321) consists of two slide blocks.
6. A palletizing machine for storing shock-absorbing and impermeable concrete blocks according to claim 5, characterized in that, The sliding component includes two sliders (224) fixedly connected to the top of the top plate (221), and a rectangular plate (225) is fixedly connected to the top of the top plate (221).
7. A palletizing machine for storing shock-absorbing and impermeable concrete blocks according to claim 6, characterized in that, The movable component includes a slide frame (325) fixedly connected to the front of the lifting plate (323), and two sliders (224) extending into the slide frame (325) and slidably connected to the slide frame (325). A hydraulic push rod (326) is fixedly connected to the slide frame (325), and the output end of the hydraulic push rod (326) is fixedly connected to the rectangular plate (225). Hydraulic push rod 2 (326) is located inside slide rod frame (325).