Reviewing and measuring device for water conservancy project

By employing organic polymer materials and a waterproof layer design in the water conservancy engineering verification measurement device, combined with a variety of detachable measurement probes, the problem of insufficient waterproof and anti-slip performance of traditional measuring tools in water conservancy engineering has been solved, achieving stable and accurate measurement in complex environments.

CN224471089UActive Publication Date: 2026-07-07SHENZHEN SHENSHUI WATER RESOURCES CONSULTING CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHENZHEN SHENSHUI WATER RESOURCES CONSULTING CO LTD
Filing Date
2025-09-18
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

Existing measuring tools are not effective at preventing water damage and slipping during the construction and acceptance of water conservancy projects, resulting in poor reliability in high humidity, water stains, mud and dust environments, affecting operational safety and measurement accuracy.

Method used

A water conservancy engineering verification and measurement device was designed. The handheld area is covered with organic polymer material, a waterproof layer is set between the probe mounting base and the main body of the device, and it is equipped with a variety of detachable measurement probes, including a three-claw structure pipe inner diameter measurement probe, a double-needle positioning thickness measurement probe and a float-type liquid level measurement probe. It has wireless communication and data storage functions.

Benefits of technology

It maintains good anti-slip performance and waterproof properties in humid, watery, and dusty environments, ensuring long-term stable operation of the device, improving the accuracy and safety of measurements, and meeting the measurement needs of complex environments in water conservancy projects.

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Abstract

A kind of water project rechecking measurement device.It includes: device main body, by hand-held area and display area are constituted, the outer surface of hand-held area is covered with organic polymer material, for antiskid and waterproof;Probe mounting seat is set to the top of device main body, waterproof layer is clamped between probe mounting seat and device main body, and when probe mounting seat is fixed to device main body, waterproof layer is pressed tightly on the upper end surface of device main body, to form sealed structure;Measuring probe is detachably connected with probe mounting seat, for carrying out the rechecking measurement of water project.The outer surface of hand-held area is covered with organic polymer material, with waterproof, moisture-proof effect, avoid water vapor into the inside of main body to affect the reliability of device.In addition, waterproof layer is clamped between probe mounting seat and device main body, and when mounting seat is fixed, it is pressed tightly and is formed into sealed structure, effectively blocks the infiltration of external liquid or moisture into the inside of device, so as to improve the applicability of device in the complex environment of water project.
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Description

Technical Field

[0001] This utility model relates to the field of water conservancy engineering, specifically to a verification and measurement device for water conservancy engineering. Background Technology

[0002] Common engineering surveying tools include measuring tapes, calipers, and laser rangefinders. These tools are mostly designed for general building construction environments, typically requiring a dry and clean operating environment. However, during the construction and acceptance of waterworks projects, the site often presents complex environmental conditions such as high humidity, water stains, mud, and dust, making traditional surveying tools significantly inadequate in their application.

[0003] First, traditional measuring equipment lacks effective waterproof and moisture-proof designs, making it prone to water ingress, corrosion, or failure in wet or high-humidity conditions, thus hindering long-term stable operation. Second, the handles of traditional tools often lack anti-slip structures, making them prone to slipping and falling when the operator is in a damp environment or wearing gloves, affecting operational safety and measurement accuracy.

[0004] In addition, waterworks project acceptance often requires equipment to be used in open-air, water-related, or even pool or pipeline environments. Traditional measuring tools lack adaptability to these scenarios, resulting in poor reliability and insufficient practicality in waterworks project verification measurements.

[0005] Therefore, existing measuring tools generally lack waterproof and anti-slip properties to adapt to the complex environment of water conservancy projects, and cannot meet the needs of verification measuring devices during the construction and acceptance phase of water conservancy projects. Utility Model Content

[0006] The purpose of this utility model is to address the deficiencies and shortcomings of the existing technology by providing a verification and measurement device for water conservancy projects, thereby improving the waterproof and anti-slip performance of the composite measurement device.

[0007] To achieve the above objectives, the technical solution adopted by this utility model is as follows:

[0008] A verification and measurement device for water conservancy projects, comprising:

[0009] The main body of the device consists of a handheld area and a display area. The outer surface of the handheld area is covered with an organic polymer material for anti-slip and waterproof purposes.

[0010] A probe mounting base is disposed above the main body of the device. A waterproof layer is sandwiched between the probe mounting base and the main body of the device. When the probe mounting base is fixed to the main body of the device, the waterproof layer is pressed tightly against the upper surface of the main body of the device to form a sealed structure.

[0011] A measuring probe, detachably connected to the probe mounting base, is used for verification measurements of water conservancy projects.

[0012] The present invention further includes a display screen in the display area for displaying measurement data and data related to the review results.

[0013] The present invention further includes a wireless communication module within the main body of the device. The wireless communication module includes a wireless connection button and a connection status indicator light. The wireless communication module is used to transmit measurement data to an external device.

[0014] The device also includes a power module, which comprises an energy storage component and a charging interface, and the charging interface is covered with a flexible protective shell.

[0015] The present invention further includes a data storage and processing module within the main body of the device, used for calculating and storing the measurement data collected by the measuring probe.

[0016] The present invention further includes a three-claw structure pipe inner diameter measuring probe, which includes a main body and three measuring claws distributed circumferentially. The three measuring claws elastically open or close relative to the main body for measuring the inner diameter of the pipe.

[0017] The present invention further includes a measuring probe comprising a dual-needle positioning thickness measuring probe, wherein the dual-needle positioning thickness measuring probe comprises a planar plate and two measuring needles arranged parallel to the planar plate, the distance between the two measuring needles being adjustable, for measuring the thickness of the component.

[0018] The present invention further includes a float-type liquid level measuring probe, which includes a retractable probe rod and a float sensing head disposed at the end of the retractable probe rod. The retractable probe rod is used to insert into the liquid to be measured, and the float sensing head is used to sense the liquid level height.

[0019] The present invention is further characterized in that the bottom of the measuring probe is provided with a probe fixing screw, and the probe mounting base is provided with an internal thread structure that cooperates with the probe fixing screw. The probe fixing screw can be screwed into the probe mounting base to realize the detachable connection of the measuring probe.

[0020] The present invention further provides that the handheld area and the display area of ​​the main body of the device are integrally formed, the handheld area is located at the lower part of the display area for gripping, and the main body of the device is made of polymer material and metal material.

[0021] The present invention further includes a laser ranging component on the top of the main body of the device, which consists of a transmitter and a receiver.

[0022] The beneficial effects of this utility model after adopting the above technical solution are as follows: The outer surface of the handheld area is coated with organic polymer material, which not only maintains good anti-slip performance in high humidity or water-related environments, improving operational stability and safety, but also has waterproof and moisture-proof functions, preventing moisture from entering the main body and affecting the reliability of the device. Furthermore, a waterproof layer is sandwiched between the probe mounting base and the main body of the device, and is pressed tightly together to form a sealed structure when the mounting base is fixed, effectively preventing external liquids or moisture from seeping into the device, thereby improving the applicability of the device in complex water conservancy engineering environments. Therefore, this utility model can work stably for a long time at water conservancy engineering construction and acceptance sites in humid, water-rich, and dusty environments, ensuring the accuracy and safety of verification measurements, and has the advantages of good waterproofness, anti-slip properties, and environmental adaptability. Attached Figure Description

[0023] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art 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.

[0024] Figure 1 This is a schematic diagram of the structure of a verification and measurement device for water conservancy projects;

[0025] Figure 2 This is a schematic diagram of the structure of a three-claw pipe inner diameter measuring probe;

[0026] Figure 3 This is a schematic diagram of the structure of a dual-needle positioning thickness measurement probe;

[0027] Figure 4 This is a schematic diagram of the structure of a float-type liquid level measuring probe.

[0028] Explanation of reference numerals in the attached figures:

[0029] 1. Main body of the device; 2. Handheld area; 4. Charging interface; 5. Flexible protective shell; 6. Display screen; 7. Wireless connection button; 8. Connection status indicator light; 10. Laser ranging component; 11. Waterproof layer; 12. Probe fixing screw; 14. Three measuring claws; 21. Flat plate; 26. Telescopic probe; 27. Float sensor head;

[0030] 3. Power button; 9. Measurement button; 13. Main body (three-jaw probe part); 15. Hook-shaped measuring jaw (II); 16. Hook-shaped measuring jaw (III); 17. Fixing screw (three-jaw probe connection); 18. Connecting platform (three-jaw probe); 19. Adjusting knob (three-jaw probe); 20. Fixing screw (double-needle probe connection); 22. Measuring needle; 23. Measuring needle; 24. Adjusting knob (double-needle probe); 25. Fixing screw (float probe connection); 28. Connecting platform (float probe). Detailed Implementation

[0031] The present invention will be further described in detail below with reference to the accompanying drawings.

[0032] This specific embodiment is merely an explanation of the present utility model and is not intended to limit the present utility model. After reading this specification, those skilled in the art can make modifications to this embodiment without contributing any inventive element, but as long as they are within the scope of the claims of the present utility model, they are protected by patent law.

[0033] This embodiment relates to a verification and measurement device for water conservancy projects, referring to... Figure 1 The device includes a main body 1, which consists of a handheld area 2 and a display area. The outer surface of the handheld area 2 is covered with an organic polymer material for anti-slip and waterproof purposes. A probe mounting base is located above the main body 1. A waterproof layer 11 is sandwiched between the probe mounting base and the main body 1. When the probe mounting base is fixed to the main body 1, the waterproof layer 11 is pressed tightly against the upper surface of the main body 1 to form a sealed structure. A measuring probe is detachably connected to the probe mounting base and is used for verification measurements in water conservancy projects.

[0034] The main body 1 of the above-mentioned device can be composed of a cuboid shape with dimensions of approximately 220mm × 85mm × 45mm (length × width × height). The upper part is a display area for mounting a touch screen 6 and measuring components, and the lower part is a handheld area 2 for holding and operating. The preferred length is approximately 650mm.

[0035] The aforementioned handheld area 2 may be located in the lower half of the main body 1 of the device for gripping operation, preferably with a length of about 650 mm, and the outer surface is covered with anti-slip and moisture-proof material so as to ensure stable grip in wet or water-filled environments.

[0036] The aforementioned display area may be located in the upper half of the main body 1 of the device, with an embedded high-definition touch screen 6 for displaying measurement data, menu information, and data related to BIM review results. The screen size is preferably 100mm × 75mm.

[0037] The aforementioned organic polymer material can be silicone or other flexible organic polymer elastomers, used to cover the surface of the handheld area 2 to provide anti-slip, moisture-proof and protective functions.

[0038] The aforementioned probe mounting base can be a structural component fixed to the upper end of the device body 1, used for installing and replacing measuring probes with different functions. A waterproof layer 11 is sandwiched between the bottom of the probe mounting base and the device body 1 to ensure sealing. Preferably, the probe mounting base is provided with a connecting structure that cooperates with the probe fixing screw 12 to realize the detachable installation of the probe.

[0039] The aforementioned waterproof layer 11 may be made of a flexible and elastic waterproof material, preferably a silicone gasket, which is pressed tight when the probe mounting seat is locked to ensure a sealed connection between the probe interface and the device body 1, preventing moisture and dust from entering the device.

[0040] The aforementioned measuring probe can be one of a variety of replaceable probes to meet the measurement needs of different scenarios in water conservancy projects, including: a three-claw structure pipe inner diameter measuring probe, suitable for measuring the inner diameter of pipes or circular holes; a dual-needle positioning thickness measuring probe, suitable for measuring the thickness of components; and a float-type liquid level measuring probe, suitable for measuring water level or liquid level height.

[0041] Specifically, the outer surface of the handheld area 2 is covered with organic polymer material, which provides a non-slip grip and moisture-proof performance even in high humidity or water-related environments. A probe mounting base is set on the top of the main body 1, and a waterproof layer 11 is sandwiched between the probe mounting base and the main body 1. When the probe mounting base is fixed, the waterproof layer 11 is pressed tightly against the upper surface of the main body 1, thereby forming a sealed structure to prevent moisture from entering the interior of the main body. The measuring probe is detachably connected to the probe mounting base, and different probes can be replaced according to the verification requirements to measure parameters such as dimensions or liquid levels at the water conservancy construction site.

[0042] Preferably, refer to Figure 1 The display area includes a screen 6 for displaying measurement data and data related to the review results. The screen 6 can be a high-definition touchscreen embedded in the front of the main body 1 of the device, preferably 100mm × 75mm in size, for displaying BIM review result data, measurement result data obtained from verification measurements, and menu operation data.

[0043] Preferably, refer to Figure 1 The main body 1 of the device is equipped with a wireless communication module, which includes a wireless connection button 7 and a connection status indicator 8. The wireless communication module is used to transmit measurement data to external devices. The main body 1 of the device is also equipped with a power module, which includes an energy storage component and a charging interface 4. The charging interface 4 is covered with a flexible protective shell 5.

[0044] The wireless communication module can have a built-in communication protocol chip, supporting wireless connection with computer devices that have BIM review results via Bluetooth, and also supporting independent measurement and data storage without a wireless connection. Preferably, the handheld unit 1 is equipped with a Bluetooth connection button 7 and a signal indicator light 8. Pressing the wireless connection button 7 initiates a signal search and enters connection mode; when the Bluetooth connection is successful, the indicator light 8 is blue, and when not connected, the indicator light 8 is red. In offline environments, measurement data can also be transmitted wiredly via the Type-C charging port 4, or wirelessly synchronized after connecting via Bluetooth.

[0045] The power module can use a built-in rechargeable lithium battery as an energy storage component, which can be charged through the Type-C charging port 4 on the left side of the casing to meet the portable power supply needs on site. Preferably, the Type-C charging port 4 is covered with a flexible protective shell 5 (such as a dustproof rubber shell) to prevent dust and moisture from entering the interface. The battery capacity can be configured according to usage requirements, and the aforementioned Type-C charging port 4 also has data transmission capabilities, thus enabling data interaction while providing power.

[0046] Preferably, refer to Figure 1 The main body 1 of the device is equipped with a data storage and processing module for calculating and storing the measurement data collected by the measuring probe. The data storage and processing module can be a combination of a central processing unit and a storage chip located inside the handheld main body 1, below the display screen 6. The storage chip preferably has a capacity of more than 4G to support offline storage of various types of measurement data, such as laser ranging results, three-jaw inner diameter measuring probe results, dual-needle thickness measuring probe results, and float level measuring probe results.

[0047] Furthermore, the data storage and processing module has built-in software functions, including a measurement mode switching module and a verification result comparison module.

[0048] Measurement mode switching module: Can be used offline or with external device connection. Four modes can be selected via the display screen 6: "Laser Measurement," "Inner Diameter Measurement," "Thickness Measurement," and "Liquid Level Measurement." After selecting a mode, press the measurement button 9 to start the measurement. Pressing the measurement button 9 again will obtain new raw data. The module processes the raw data and displays and stores the final measurement result.

[0049] Verification Result Comparison Module: When the tool is connected to an external device, the BIM review results related to size or distance can be selected from the external device via display screen 6, and the design dimensions, specification dimensions and on-site measurement results will be displayed synchronously.

[0050] Preferably, refer to Figure 2The measuring probe includes a three-jaw pipe inner diameter measuring probe, consisting of a main rod 13 and three measuring jaws 14, 15, and 16 distributed circumferentially. The three measuring jaws elastically open or close relative to the main rod 13 to measure the inner diameter of the pipe. The three jaws are connected to the probe mounting base of the device body 1 via a fixing screw 17, and an adjustment knob 19 is provided on the connecting platform 18 to adjust the opening and closing of the three jaws.

[0051] Preferably, refer to Figure 3 The measuring probe includes a dual-needle positioning thickness measuring probe, which consists of a flat plate 21 and two parallel measuring needles 22 and 23. The distance between the measuring needles can be adjusted by adjusting the knob 24. The probe is connected to the probe mounting base by a fixing screw 20.

[0052] Preferably, refer to Figure 4 The measuring probe includes a float-type liquid level measuring probe, which consists of a telescopic probe rod 26 and a float sensing head 27. The probe is connected to the probe mounting base of the main body 1 of the device through a fixing screw 25 and is fixed through a connecting platform 28.

[0053] Preferably, refer to Figure 1 The device also has a laser ranging component 10 on the top of its main body. The component consists of a transmitter and a receiver. When the measurement button 9 is pressed, the laser ranging component 10 emits a laser and receives the reflected signal, thereby calculating the straight-line distance to the target. The measurement data is displayed on the screen 6.

[0054] When powered on, the user starts the device by pressing the power button 3, and then can select the laser ranging component 10 or various contact probes for measurement as needed; pressing the measurement button 9 will start the measurement and complete the data acquisition.

[0055] It should be noted that the usage process of any waterworks engineering verification and measurement device provided in this utility model embodiment can be specifically described through the following implementation process:

[0056] During implementation, acceptance or measurement personnel can first charge the main body 1 of the device through the charging interface 4 to ensure normal operation of the equipment. To start the device, press the power button 3. If no external equipment connection is required, the user can directly select the desired measurement mode through the display screen 6 and use the laser ranging component 10 or different contact measurement probes (such as a three-jaw inner diameter probe, including the main body rod 13, three measuring jaws 14, 15, 16; a dual-needle thickness probe, including a flat plate 21, measuring needles 22, 23, and adjusting knob 24; and a float level probe, including a retractable probe rod 26, a float sensing head 27, and a connecting platform 28) for measurement. Then, pressing the measurement button 9 will start the measurement and complete data acquisition. The obtained measurement data can be displayed in real time on the display screen 6 and can be stored or transmitted.

[0057] If an external device needs to be connected, the device can be wired via charging port 4, or the Bluetooth search function can be activated by pressing the wireless connection button 7. The connection is complete when the connection status indicator 8 turns blue. At this time, the BIM review result data stored on the external computer can be transmitted to the device. After completing the on-site measurement, the user can compare the design data and measured results from the BIM review stage through the display screen 6 and select "Pass" or "Requires Review". When "Requires Review" is selected, the corresponding BIM review result ID, component ID, and measurement data will be automatically and synchronously transmitted to the computer device for further archiving and processing.

[0058] Therefore, the waterworks engineering verification and measurement device provided by this utility model can meet the measurement needs of multiple scenarios in the construction and acceptance stage, and realize the real-time synchronization of BIM review results and on-site verification results, which greatly improves the efficiency of on-site measurement and the accuracy of review and verification of waterworks engineering.

[0059] The above is only used to illustrate the technical solution of this utility model and not to limit it. Any other modifications or equivalent substitutions made by those skilled in the art to the technical solution of this utility model, as long as they do not depart from the spirit and scope of the technical solution of this utility model, should be covered within the scope of the claims of this utility model.

Claims

1. A verification and measurement device for water conservancy projects, characterized in that, include: The main body of the device (1) consists of a handheld area (2) and a display area. The outer surface of the handheld area (2) is covered with an organic polymer material for anti-slip and waterproof purposes. A probe mounting base is disposed above the main body (1) of the device. A waterproof layer (11) is sandwiched between the probe mounting base and the main body (1). When the probe mounting base is fixed to the main body (1), the waterproof layer (11) is pressed tightly against the upper surface of the main body (1) of the device to form a sealed structure. A measuring probe, detachably connected to the probe mounting base, is used for verification measurements of water conservancy projects.

2. The verification and measurement device for water conservancy projects according to claim 1, characterized in that, The display area is equipped with a display screen (6) for displaying measurement data and data related to the review results.

3. The verification and measurement device for water conservancy projects according to claim 1, characterized in that, The device body (1) is provided with a wireless communication module, which includes a wireless connection button (7) and a connection status indicator (8). The wireless communication module is used to transmit measurement data to an external device. The device body (1) is also provided with a power module, which includes an energy storage component and a charging interface (4). The charging interface (4) is covered with a flexible protective shell (5).

4. The verification and measurement device for water conservancy projects according to claim 1, characterized in that, The main body (1) of the device is provided with a data storage and processing module for calculating and storing the measurement data collected by the measuring probe.

5. The verification and measurement device for water conservancy projects according to claim 1, characterized in that, The measuring probe includes a three-claw structure pipe inner diameter measuring probe, which includes a main rod and three measuring claws (14) distributed circumferentially. The three measuring claws (14) elastically open or close relative to the main rod for measuring the inner diameter of the pipe.

6. The verification and measurement device for water conservancy projects according to claim 1, characterized in that, The measuring probe includes a dual-needle positioning thickness measuring probe, which includes a flat plate (21) and two measuring needles arranged parallel to each other on the flat plate (21). The distance between the two measuring needles is adjustable and used to measure the thickness of the component.

7. The verification and measurement device for water conservancy projects according to claim 1, characterized in that, The measuring probe includes a float-type liquid level measuring probe, which includes a retractable probe rod (26) and a float sensing head (27) disposed at the end of the retractable probe rod (26). The retractable probe rod (26) is used to insert into the liquid to be measured, and the float sensing head (27) is used to sense the liquid level height.

8. The verification and measurement device for water conservancy projects according to any one of claims 5 to 7, characterized in that, The bottom of the measuring probe is provided with a probe fixing screw (12), and the probe mounting base is provided with an internal thread structure that cooperates with the probe fixing screw (12). The probe fixing screw (12) can be screwed into the probe mounting base to realize the detachable connection of the measuring probe.

9. The verification and measurement device for water conservancy projects according to claim 1, characterized in that, The handheld area (2) of the main body (1) of the device is integrally formed with the display area. The handheld area (2) is located at the lower part of the display area and is used for holding. The main body (1) of the device is made of polymer material and metal material.

10. The verification and measurement device for water conservancy projects according to claim 1, characterized in that, The device body (1) is also provided with a laser ranging component (10) on the top, which is composed of a transmitter and a receiver.