Cement detection device with movable sampling structure

By combining components such as support frames, motors, and slide rails, the cement testing equipment achieves a fully automated sampling and testing process, solving the problem of low efficiency in manual sampling, improving testing efficiency and accuracy, and enhancing the ease of use and intelligence of the equipment.

CN224366049UActive Publication Date: 2026-06-16ZHEJIANG ZHONGJIU ENGINEERING RESEARCH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
ZHEJIANG ZHONGJIU ENGINEERING RESEARCH CO LTD
Filing Date
2025-06-27
Publication Date
2026-06-16

AI Technical Summary

Technical Problem

Existing cement testing equipment is not fully automated in the sampling process, requiring manual assistance, which limits testing efficiency and accuracy.

Method used

The sampling mechanism is automated by combining components such as a support frame, motor, slide rail, sliding block, lifting plate, suction pump and cylinder. The display screen and control area provide an intuitive operating interface, realizing full automation from sampling to testing.

Benefits of technology

It significantly improves testing efficiency and accuracy, reduces human error, has a simple structure, enhances ease of use and intelligence, and extends the equipment's lifespan.

✦ Generated by Eureka AI based on patent content.

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  • Figure CN224366049U_ABST
    Figure CN224366049U_ABST
Patent Text Reader

Abstract

The utility model discloses a cement detection equipment with movable sampling structure relates to cement detection technical field, including detection instrument, the top fixed connection of detection instrument has support frame, the outside fixed connection of support frame has motor, the outside of detection instrument is equipped with sampling mechanism, sampling mechanism includes and displacement subassembly material taking subassembly, material taking subassembly and displacement subassembly mutually cooperate and use, material taking subassembly includes slide rail, the outside fixed connection of slide rail in support frame, the outside slide connection of slide rail has sliding block, the outside fixed connection of sliding block has connecting block. The utility model discloses a cement detection equipment with movable sampling structure, in whole work flow, motor, suction pump and multiple section air cylinder cooperation have realized the whole process automation from sampling to detection, have promoted detection efficiency and accuracy greatly, have avoided the error that manual operation can bring simultaneously, simple structure, and the practicality is stronger.
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Description

Technical Field

[0001] This utility model relates to the field of cement testing technology, and in particular to a cement testing device with an active sampling structure. Background Technology

[0002] Cement testing is a process that uses physical, chemical, or instrumental analytical methods to determine various dimensions of cement and the content of harmful substances, ensuring that it meets national standards and quality requirements, and is used to guarantee the safety and durability of building construction.

[0003] A search revealed a cement testing device with an active sampling structure (authorization announcement number: CN 217277133U), which "includes a support assembly assembly, a support positioning assembly, a cement storage assembly, a lifting and adjusting assembly, a cement transfer assembly, and a cement testing assembly. This cement testing device is equipped with a support positioning assembly consisting of a storage tray, a feeding tray, and sliding rollers to position the storage tank to be tested, allowing multiple storage tanks to be stored sequentially in the storage tray and feeding tray, ensuring an orderly testing process. Furthermore, it is equipped with a lifting and adjusting assembly consisting of a lifting guide rail, a lifting seat plate, a lifting screw, and an adjusting motor, which can drive the cement transfer assembly consisting of a transfer pipe and a transfer pump to rise or fall, facilitating the replacement of the storage tank containing the cement sample and improving testing efficiency."

[0004] Based on the aforementioned technologies, the applicant believes that these technologies rely on manual pushing of the storage tank on the rollers, which does not achieve full automation and still requires manual assistance in actual use. In response to the above problems, we have launched a cement testing device with a movable sampling structure. Utility Model Content

[0005] This utility model discloses a cement testing device with a movable sampling structure, which aims to solve the technical problem that manual pushing of the storage tank on the rollers does not achieve full automation and still requires manual assistance in actual use.

[0006] To achieve the above objectives, the present invention adopts the following technical solution:

[0007] A cement testing device with a movable sampling structure includes a testing instrument. A support frame is fixedly connected to the top of the testing instrument. A motor is fixedly connected to the outside of the support frame. A sampling mechanism is provided on the outside of the testing instrument. The sampling mechanism includes a material taking component and a displacement component, which cooperate with each other. The material taking component includes a slide rail, which is fixedly connected to the outside of the support frame. A sliding block is slidably connected to the outside of the slide rail. A connecting block is fixedly connected to the outside of the sliding block. A lifting plate is slidably connected inside the connecting block. A rotating plate is fixedly connected to the output end of the motor. The other end of the rotating plate is rotatably connected to the lifting plate. An L-shaped support plate is fixedly connected to the outside of the lifting plate. A suction pump is installed on the top of the L-shaped support plate. A suction head is fixedly connected to the suction end of the suction pump.

[0008] The sampling mechanism is automated through the cooperation of the support frame and motor. The design of the slide rail and sliding block enables the sampling components to move horizontally, while the connection between the rotating plate and the lifting plate enables precise vertical control. The L-shaped support plate fixes the suction pump and suction head, ensuring a stable and reliable sampling process and significantly improving sampling efficiency and accuracy.

[0009] In a preferred embodiment, the displacement assembly includes a mounting frame disposed on the outer side of the detection instrument. The mounting frame has equally spaced slots inside, into which sorting tubes are inserted. A fixing block is symmetrically fixedly connected to the side of the detection instrument near the mounting frame. A sliding rod is symmetrically fixedly connected between two fixing blocks. A displacement block is slidably connected to the outer side of the two sliding rods. The top of the displacement block is fixedly connected to the bottom of the mounting frame. A multi-section cylinder is fixedly connected to the outer side of the detection instrument, near the mounting frame, with the telescopic end of the multi-section cylinder fixedly connected to the displacement block.

[0010] The placement frame and classification tube of the displacement assembly enable the classified storage of samples, facilitating the management of different batches of cement samples. The cooperation of the sliding rod and displacement block allows the placement frame to move horizontally, and the extension and retraction drive of the multi-section cylinder enables automated displacement, reducing manual intervention and improving the automation level of the testing process.

[0011] In a preferred embodiment, the top of the detection instrument is provided with a detection slot, and the detection slot, the material handling component, and the displacement component are used in conjunction with each other.

[0012] The detection tank design allows the detection instrument to work seamlessly with the material handling and displacement components, ensuring that the sampled cement can directly enter the detection process, avoiding contamination or loss during sample transfer, and improving the reliability of the detection results.

[0013] In a preferred embodiment, a display screen is fixedly connected to the outside of the testing instrument, and a control area is provided on the outside of the testing instrument, on the side closest to the display screen.

[0014] The design of the display screen and control area provides users with an intuitive operating interface and display of test data, facilitating real-time monitoring and adjustment of test parameters, and enhancing the ease of use of the equipment and the human-computer interaction experience.

[0015] In a preferred embodiment, a protective cover is fixedly connected to the outside of the motor, and heat dissipation slots are equidistantly provided inside the protective cover.

[0016] The combination of the protective cover and the heat dissipation trough effectively protects the motor from the influence of the external environment, while the ventilation design of the heat dissipation trough prevents the motor from overheating and extends the service life of the equipment.

[0017] In a preferred embodiment, the motor, suction pump, and multi-stage cylinder are all electrically connected to an external controller.

[0018] The electrical connection between the motor, suction pump, and multi-section cylinder and the external controller enables centralized control of the equipment. Users can operate the equipment with one button on the controller, further enhancing the intelligence and automation level of the equipment.

[0019] The cement testing device with a movable sampling structure provided by this utility model has the following advantages:

[0020] Firstly, the entire process is automated by the combination of motor, suction pump and multi-section cylinder, from sampling to testing, which greatly improves testing efficiency and accuracy, while avoiding errors that may be caused by manual operation. It has a simple structure and strong practicality.

[0021] Secondly, the design of the display screen and control area provides users with an intuitive operating interface and test data display, facilitating real-time monitoring and adjustment of test parameters, thus enhancing the ease of use and human-machine interaction experience. The combination of a protective cover and heat dissipation vents effectively protects the motor from external environmental influences, while the ventilation design of the heat dissipation vents prevents the motor from overheating, extending the equipment's lifespan. The electrical connection between the motor, suction pump, and multi-section cylinders and an external controller enables centralized control of the equipment. Users can operate the equipment with a single button press via the controller, further enhancing its intelligence and automation level. Attached Figure Description

[0022] Figure 1 This is a three-dimensional schematic diagram of a cement testing device with an active sampling structure proposed in this utility model.

[0023] Figure 2 This is a three-dimensional rear view schematic diagram of a cement testing device with an active sampling structure proposed in this utility model.

[0024] Figure 3 This is a three-dimensional schematic diagram of the sampling component of a cement testing device with an active sampling structure proposed in this utility model.

[0025] Figure 4 This is a three-dimensional schematic diagram of the displacement component of a cement testing device with a movable sampling structure proposed in this utility model.

[0026] Figure 5 This is a three-dimensional schematic diagram of a cement testing device with an active sampling structure proposed in this utility model.

[0027] In the attached diagram: 1. Testing instrument; 2. Support frame; 3. Motor; 41. Slide rail; 42. Sliding block; 43. Connecting block; 44. Lifting plate; 45. L-shaped support plate; 46. Suction pump; 47. Suction head; 48. Rotating plate; 51. Placement frame; 52. Slot; 53. Classification tube; 54. Fixing block; 55. Slide rod; 56. Displacement block; 57. Multi-section cylinder; 6. Protective cover; 7. Heat dissipation groove; 8. Testing groove; 9. Display screen; 10. Control area. Detailed Implementation

[0028] The technical solutions of the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this application, and not all embodiments. The components of the embodiments of this application described and marked in the accompanying drawings can be arranged and designed in various different configurations. Therefore, the following detailed description of the embodiments of this application provided in the accompanying drawings is not intended to limit the scope of the claimed application, but merely represents selected embodiments of this application. All other embodiments obtained by those skilled in the art based on the embodiments of this application without inventive effort are within the scope of protection of this application.

[0029] The cement testing equipment with an active sampling structure disclosed in this utility model is mainly used in cement testing scenarios.

[0030] Reference Figures 1-5A cement testing device with a movable sampling structure includes a testing instrument 1. A support frame 2 is fixedly connected to the top of the testing instrument 1. A motor 3 is fixedly connected to the outside of the support frame 2. A sampling mechanism is provided on the outside of the testing instrument 1. The sampling mechanism includes a material taking component and a displacement component, which cooperate with each other. The material taking component includes a slide rail 41, which is fixedly connected to the outside of the support frame 2. A sliding block 42 is slidably connected to the outside of the slide rail 41. A connecting block 43 is fixedly connected to the outside of the sliding block 42. A lifting plate 44 is slidably connected inside the connecting block 43. A rotating plate 48 is fixedly connected to the output end of the motor 3. The other end of the rotating plate 48 is rotatably connected to the lifting plate 44. An L-shaped support plate 45 is fixedly connected to the outside of the lifting plate 44. A suction pump 46 is installed on the top of the L-shaped support plate 45. A suction head 47 is fixedly connected to the suction end of the suction pump 46. The displacement assembly includes a mounting frame 51, which is located on the outer side of the testing instrument 1. The mounting frame 51 has equally spaced slots 52 inside, into which sorting tubes 53 are inserted. Fixing blocks 54 are symmetrically fixedly connected to the side of the testing instrument 1 near the mounting frame 51. Sliding rods 55 are symmetrically fixedly connected between the two fixing blocks 54. Displacement blocks 56 are slidably connected to the outer sides of the two sliding rods 55. The top of the displacement blocks 56 is fixedly connected to the bottom of the mounting frame 51. A multi-section cylinder 57 is fixedly connected to the outer side of the testing instrument 1, near the mounting frame 51. The telescopic end of the multi-section cylinder 57 is fixedly connected to the displacement block 56. A testing groove 8 is provided on the top of the testing instrument 1. The testing groove 8, the material handling assembly, and the displacement assembly work together.

[0031] In this embodiment: the multi-section cylinder 57 in the displacement assembly pushes the displacement block 56 to move along the slide rod 55, causing the placement frame 51 and the internally inserted classification tube 53 to move horizontally, sequentially sending the samples to be tested to the sampling position. The motor 3 drives the rotating plate 48 to rotate, causing the lifting plate 44 to move up and down along the connecting block 43. The sliding block 42 slides horizontally along the slide rail 41, allowing the suction head 47 fixed on the L-shaped support plate 45 to be accurately inserted into cement samples at different depths. After the suction pump 46 extracts the sample through the suction head 47, it is directly transported to the detection tank 8 for analysis. In the entire workflow, the motor 3, suction pump 46, and multi-section cylinder 57 work together to achieve full automation from sampling to detection, greatly improving detection efficiency and accuracy, while avoiding errors that may be caused by manual operation. The structure is simple and highly practical.

[0032] The above technical solution, considering the need for manual pushing of the storage tank on the rollers, does not achieve full automation and requires manual assistance in actual use. To solve this problem, the specific operation is as follows:

[0033] Reference Figures 1-5In a preferred embodiment, a display screen 9 is fixedly connected to the outside of the detection instrument 1, and a control area 10 is provided on the outside of the detection instrument 1, near the display screen 9. A protective cover 6 is fixedly connected to the outside of the motor 3, and heat dissipation slots 7 are equidistantly provided inside the protective cover 6. The motor 3, the suction pump 46, and the multi-section cylinder 57 are all electrically connected to an external controller.

[0034] In this embodiment, the design of the display screen 9 and control area 10 provides users with an intuitive operating interface and display of detection data, facilitating real-time monitoring and adjustment of detection parameters, thus enhancing the ease of use and human-machine interaction experience. The combination of the protective cover 6 and the heat dissipation slot 7 effectively protects the motor 3 from external environmental influences, while the ventilation design of the heat dissipation slot 7 prevents the motor 3 from overheating, extending the equipment's service life. The electrical connection between the motor 3, suction pump 46, and multi-section cylinder 57 and the external controller enables centralized control of the equipment. Users can operate the equipment with a single button press via the controller, further enhancing the equipment's intelligence and automation level.

[0035] Working Principle: During operation, the multi-section cylinder 57 in the displacement assembly pushes the displacement block 56 to move along the slide rod 55, causing the placement frame 51 and the internally inserted classification tube 53 to move horizontally, sequentially delivering the samples to be tested to the sampling position. The motor 3 drives the rotating plate 48 to rotate, causing the lifting plate 44 to move up and down along the connecting block 43. The sliding block 42 slides horizontally along the slide rail 41, allowing the suction head 47, fixed on the L-shaped support plate 45, to be accurately inserted into cement samples at different depths. After the suction pump 46 extracts the sample through the suction head 47, it is directly transported to the detection tank 8 for analysis. Throughout the entire workflow, the motor 3, suction pump 46, and multi-section cylinder 57 are all coordinated and controlled by the controller, and the display screen 9 displays the detection data in real time, realizing full automation from sampling to detection, greatly improving detection efficiency and accuracy, while avoiding errors that may be caused by manual operation.

[0036] The above description is merely a preferred embodiment of this utility model, but the protection scope of this utility model is not limited thereto. The substitutions may be replacements of some structures, devices, or method steps, or they may be complete technical solutions. Equivalent substitutions or modifications made based on the technical solution and inventive concept of this utility model should all be covered within the protection scope of this utility model.

Claims

1. A cement testing device with an active sampling structure, comprising a testing instrument (1), characterized in that: The top of the testing instrument (1) is fixedly connected to a support frame (2), and the outside of the support frame (2) is fixedly connected to a motor (3). The outside of the testing instrument (1) is provided with a sampling mechanism, which includes a material taking component and a displacement component. The material taking component and the displacement component are used in cooperation with each other. The material handling assembly includes a slide rail (41), which is fixedly connected to the outside of the support frame (2). A sliding block (42) is slidably connected to the outside of the slide rail (41). A connecting block (43) is fixedly connected to the outside of the sliding block (42). A lifting plate (44) is slidably connected inside the connecting block (43). A rotating plate (48) is fixedly connected to the output end of the motor (3). The other end of the rotating plate (48) is rotatably connected to the lifting plate (44). An L-shaped support plate (45) is fixedly connected to the outside of the lifting plate (44). A suction pump (46) is installed on the top of the L-shaped support plate (45). A suction head (47) is fixedly connected to the suction end of the suction pump (46).

2. The cement testing equipment with a movable sampling structure according to claim 1, characterized in that: The displacement assembly includes a mounting frame (51), which is located on the outside of the detection instrument (1). The mounting frame (51) has slots (52) equidistantly spaced inside. A sorting tube (53) is inserted into the slot (52). A fixing block (54) is symmetrically fixedly connected to the side of the detection instrument (1) near the mounting frame (51). A sliding rod (55) is symmetrically fixedly connected between the two fixing blocks (54). A displacement block (56) is slidably connected to the outside of the two sliding rods (55). The top of the displacement block (56) is fixedly connected to the bottom of the mounting frame (51). A multi-section cylinder (57) is fixedly connected to the outside of the detection instrument (1) and to the side near the mounting frame (51). The telescopic end of the multi-section cylinder (57) is fixedly connected to the displacement block (56).

3. A cement testing device with an active sampling structure according to claim 1, characterized in that: The top of the testing instrument (1) is provided with a testing groove (8), and the testing groove (8), the material taking component and the displacement component are used in cooperation with each other.

4. A cement testing device with an active sampling structure according to claim 1, characterized in that: The outer side of the testing instrument (1) is fixedly connected to a display screen (9), and a control area (10) is provided on the outer side of the testing instrument (1) and on the side close to the display screen (9).

5. A cement testing device with an active sampling structure according to claim 1, characterized in that: A protective cover (6) is fixedly connected to the outside of the motor (3), and heat dissipation slots (7) are provided at equal intervals inside the protective cover (6).

6. A cement testing device with an active sampling structure according to claim 1, characterized in that: The motor (3), suction pump (46) and multi-section cylinder (57) are all electrically connected to an external controller.