Gateway device for end pressure edge calculation for water supply

The design of the limiting component makes it easy to disassemble and clean the heat dissipation fins of the water supply gateway equipment, solving the problem of poor heat dissipation caused by dust accumulation, ensuring that the equipment can continuously and efficiently dissipate heat in complex environments, and improving the stability and reliability of the equipment.

CN224401556UActive Publication Date: 2026-06-23SHANGHAI YIWEI FLUID TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHANGHAI YIWEI FLUID TECH CO LTD
Filing Date
2025-08-15
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

The heat dissipation fins of existing water supply gateway equipment suffer from reduced heat dissipation performance due to dust accumulation, affecting the practicality and reliability of the equipment and making cleaning inconvenient.

Method used

A limiting component was designed, including a sliding base, a protective shell, and heat dissipation fins. Through the cooperation of a push block and a return spring, the heat dissipation fins can be easily disassembled and cleaned, ensuring the continuous heat dissipation efficiency.

Benefits of technology

This solves the problem of inconvenient cleaning of heat dissipation fins, ensures continuous and efficient heat dissipation of the equipment in environments with limited ventilation, avoids heat dissipation failure caused by dust accumulation, and improves the stability and reliability of the equipment.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a gateway equipment of end pressure edge calculation for water supply relates to control technical field. Gateway equipment of end pressure edge calculation for water supply, including edge calculation gateway main part and plug joint interface, be provided with spacing unit on edge calculation gateway main part, the sliding base, the protective shell and a plurality of heat dissipation fins in spacing unit, when the heat dissipation fin surface accumulates dust through spacing unit, the operator only needs to push the push block to the inboard, can drive the limit block compression reset spring and separate from the limit block card slot, then pull the protective shell can along T type block slide groove whole draw -out sliding base and heat dissipation fin, after cleaning, only need to push back to the original position of sliding base, reset spring can automatically push the limit block and enter the card slot and complete fixed, this design completely solved the inconvenient problem of traditional fixed heat dissipation structure cleaning, ensure that heat dissipation fin always maintains good heat dissipation efficiency, even in the pump house environment of limited ventilation condition.
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Description

Technical Field

[0001] This utility model relates to the field of control technology, and in particular to a gateway device for edge calculation of end pressure in water supply. Background Technology

[0002] In modern water supply systems, ensuring the stability and reliability of water supply is of paramount importance. With the rapid development of information technology, edge computing technology has been widely used in the water supply field. As a key node, the gateway device for edge computing of water supply terminal pressure undertakes important tasks such as data acquisition, processing, analysis, and communication with the upper system.

[0003] The operating environment of water supply systems is quite complex. Equipment installation sites such as pump rooms are typically characterized by high humidity and wide temperature variations. Especially in some large water supply facilities, equipment is densely packed, space is relatively small, and ventilation is limited. During long-term operation, the electronic components inside gateway devices, such as processors, communication modules, and storage chips, continuously generate heat. Taking a common edge computing gateway as an example, its high-performance processor consumes a lot of power and releases a large amount of heat when performing data processing operations. If this heat cannot be dissipated in a timely and effective manner, the internal temperature of the gateway device will continue to rise. When the temperature of the gateway device is too high, it will have many adverse effects on its performance and stability. On the one hand, high temperature will cause the performance of electronic components to degrade, and may also lead to sudden equipment failure, causing partial or even complete paralysis of the water supply system, which will cause great inconvenience to residents' lives and industrial production.

[0004] Currently, the most common way to dissipate heat in gateway devices on the market is to fix heat sink fins on the device casing to dissipate heat. However, over time, a lot of dust will accumulate between the heat sink fins. Since it is not easy to disassemble and clean them, the dust will seriously hinder the dissipation of heat, resulting in a gradual deterioration of the heat dissipation effect, which in turn reduces the practicality and reliability of the device. Utility Model Content

[0005] The purpose of this utility model is to at least solve one of the technical problems existing in the prior art, and to provide a gateway device for edge calculation of end pressure for water supply. This device can solve the problem that over time, a large amount of dust will accumulate between the heat dissipation fins. Since it is not easy to disassemble and clean, the dust will seriously hinder the dissipation of heat, resulting in a gradual deterioration of the heat dissipation effect, which in turn reduces the practicality and reliability of the device.

[0006] To achieve the above objectives, this utility model provides the following technical solution: a gateway device for edge computing of end pressure in water supply, comprising an edge computing gateway body and a plug interface, wherein a limit component is provided on the edge computing gateway body;

[0007] The limiting assembly includes a sliding base, a protective shell, and multiple heat dissipation fins. The heat dissipation fins are fixedly mounted on the upper surface of the sliding base. T-shaped blocks are fixedly mounted on both outer walls of the sliding base. T-shaped block grooves are formed on both inner walls of the upper end of the edge computing gateway body. Limiting block slots are formed on the upper surface of the rear end of the edge computing gateway body. A protective shell is fixedly mounted on the outer wall of the rear end of the sliding base. A limiting block groove is formed at the end of the protective shell near the limiting block slot. A limiting block is slidably connected inside the limiting block groove. Push block slots are formed on both outer walls of the protective shell. Limiting blocks are slidably engaged inside both push block slots. Three return springs are provided inside each limiting block groove. Push blocks are slidably connected inside each push block slot.

[0008] Preferably, the sliding base is located inside the upper end of the edge computing gateway body, and the outer walls of the two T-shaped blocks are slidably connected to the interior of the corresponding T-shaped block grooves.

[0009] Preferably, one end of the limiting block near the limiting block slot extends slidably to the outside of the limiting block groove and is slidably connected to the inside of the corresponding limiting block groove.

[0010] Preferably, the two ends of the three reset springs are fixedly connected to the outer wall of one end of the limiting block and the inner wall of the limiting block groove, respectively.

[0011] Preferably, the plurality of heat dissipation fins form a heat dissipation area on the upper surface of the sliding base, and the interior of both push block grooves communicates with the interior of the limiting block groove.

[0012] Preferably, the ends of the two push blocks near the limiting block slide into the interior of the limiting block groove and are fixedly connected to the two sides of the limiting block.

[0013] Preferably, the outer walls on both sides of the two limiting blocks are in contact with the outer wall of the corresponding push block and the inner wall of the push block groove, respectively.

[0014] Preferably, the plurality of heat dissipation fins are parallel to each other and equally spaced on the upper surface of the sliding base.

[0015] Preferably, the three reset springs are evenly distributed in a straight line within the sliding groove of the limiting block.

[0016] Preferably, the outer wall of the pusher block is in close contact with the inner wall of the pusher block groove;

[0017] The outer wall of the push block away from the limit block is provided with anti-slip texture.

[0018] Compared with the prior art, the beneficial effects of this utility model are:

[0019] 1. This gateway device for calculating the edge pressure at the end of the water supply system allows operators to easily remove the limiting block from the slot when dust accumulates on the surface of the heat sink fins. This is achieved by pushing the limiting block inwards, which compresses the reset spring and disengages it from the limiting block slot. Then, pulling the protective shell allows the sliding base and heat sink fins to be pulled out along the T-shaped block groove. After cleaning, simply pushing the sliding base back into its original position allows the reset spring to automatically push the limiting block into the slot for fixation. This design completely solves the problem of inconvenient cleaning of traditional fixed heat sink structures, ensuring that the heat sink fins always maintain good heat dissipation efficiency. Even in pump room environments with limited ventilation, it can continuously and quickly dissipate the heat generated by components such as processors and communication modules, avoiding heat dissipation failure caused by dust accumulation. Attached Figure Description

[0020] The present invention will be further described below with reference to the accompanying drawings and embodiments:

[0021] Figure 1 This is a three-dimensional structural diagram of the present invention;

[0022] Figure 2 This is a schematic diagram of the external structure of the T-shaped block of this utility model;

[0023] Figure 3 This utility model Figure 2 A structural schematic diagram of the enlarged view at point A in the middle;

[0024] Figure 4 This is a schematic diagram of the internal structure of the protective shell of this utility model.

[0025] Reference numerals in the attached diagram: 1. Edge computing gateway body; 2. Plug interface; 3. T-shaped block groove; 4. Sliding base; 5. Heat dissipation fins; 6. Protective shell; 7. Limiting block; 8. T-shaped block; 9. Reset spring; 10. Push block groove; 11. Push block; 12. Limiting block groove; 13. Limiting block; 14. Limiting block groove. Detailed Implementation

[0026] This section will describe in detail the specific embodiments of the present utility model. The preferred embodiments of the present utility model are shown in the accompanying drawings. The purpose of the drawings is to supplement the textual description with graphics, so that people can intuitively and vividly understand each technical feature and the overall technical solution of the present utility model, but they should not be construed as limiting the scope of protection of the present utility model.

[0027] In the description of this utility model, it should be understood that the directional descriptions, such as up, down, front, back, left, right, etc., indicate the directional or positional relationship based on the directional or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this utility model and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this utility model.

[0028] In the description of this utility model, terms such as greater than, less than, and exceeding are understood to exclude the stated number, while terms such as above, below, and within are understood to include the stated number. The use of terms like "first" and "second" is merely for distinguishing technical features and should not be construed as indicating or implying relative importance, or implicitly indicating the quantity or sequence of the indicated technical features.

[0029] In the description of this utility model, unless otherwise explicitly defined, terms such as "setting," "installation," and "connection" should be interpreted broadly, and those skilled in the art can reasonably determine the specific meaning of the above terms in this utility model in conjunction with the specific content of the technical solution.

[0030] Please see Figure 1-4 This utility model provides a technical solution: a gateway device for edge calculation of end pressure for water supply, including an edge calculation gateway body 1 and a plug interface 2;

[0031] A limit component is installed on the main body 1 of the edge computing gateway;

[0032] The limiting assembly includes a sliding base 4, a protective shell 6, and multiple heat dissipation fins 5. All heat dissipation fins 5 are fixedly mounted on the upper surface of the sliding base 4. T-shaped blocks 8 are fixedly mounted on the outer walls of both sides of the sliding base 4. T-shaped block grooves 3 are formed on the inner walls of both sides of the upper end of the edge computing gateway body 1. The sliding base 4 is located inside the upper end of the edge computing gateway body 1. The outer walls of the two T-shaped blocks 8 are slidably connected to the interior of their respective T-shaped block grooves 3. A limiting block slot 12 is formed on the upper surface of the rear end of the edge computing gateway body 1. A protective shell 6 is fixedly mounted on the outer wall of the rear end of the sliding base 4. A limiting block groove 14 is formed at the end of the protective shell 6 near the limiting block groove 12. A limiting block 13 is slidably connected inside the limiting block groove 14. The end of the limiting block 13 near the limiting block groove 12 extends slidably to the outside of the limiting block groove 14 and is respectively connected to the corresponding... The internal sliding connection of the limiting block slot 12 is provided. Push block slots 10 are provided on both outer walls of the protective shell 6. The internal sliding connection of the two push block slots 10 is limited by the limiting block 7. The internal sliding connection of the limiting block groove 14 is provided with three return springs 9. The two ends of the three return springs 9 are fixedly connected to the outer wall of one end of the limiting block 13 and the inner wall of the limiting block groove 14, respectively. The internal sliding connection of the two push block slots 10 is a push block 11. Multiple heat dissipation fins 5 form a heat dissipation area on the upper surface of the sliding base 4. The internal connection of the two push block slots 10 is connected to the internal connection of the limiting block groove 14. The two push blocks 11 are slidably extended into the internal connection of the limiting block groove 14 near the limiting block 13 and are fixedly connected to the two sides of the limiting block 13. The two outer walls of the two limiting blocks 7 are respectively in contact with the outer wall of the corresponding push block 11 and the inner wall of the push block slot 10.

[0033] The plug interface 2 is fixedly installed on the outer wall of the front end of the edge computing gateway body 1. The edge computing gateway body 1 is electrically connected to the plug interface 2. Fixing plates are installed on the lower outer walls of both sides of the edge computing gateway body 1.

[0034] Furthermore, when using this device, firstly, when the water supply terminal pressure edge computing gateway device is working, the edge computing gateway body 1 collects, analyzes, and calculates the pressure data of the water supply terminal through the internal edge computing module. The plug interface 2 is responsible for connecting with external sensors, transmission lines, etc., to realize data input and output, as well as the power supply of the device. Then, during the operation of the device, the internal components generate heat. At this time, the heat dissipation area composed of multiple heat dissipation fins 5 on the upper surface of the sliding base 4 plays a role. By increasing the heat dissipation area, the heat is quickly transferred to the air, thereby reducing the internal temperature of the edge computing gateway body 1 and ensuring stable operation of the device. Then, when it is necessary to adjust the internal pressure of the device... When performing maintenance or cleaning the heat sink fins 5, first pull the handle of the limit block 7 to remove it from the inside of the push block groove 10. Then push the push blocks 11 in the push block grooves 10 on both sides of the protective shell 6 upwards. The push blocks 11 drive the limit blocks 13 fixedly connected to them to slide in the limit block slide groove 14. At this time, the limit blocks 13 compress the three return springs 9 in the limit block slide groove 14. At the same time, the end of the limit blocks 13 near the limit block groove 12 exits from the limit block groove 12. Pull the protective shell 6 to drive the sliding base 4 to slide outwards along the T-shaped block slide groove 3 at the upper end of the edge computing gateway body 1 through the T-shaped blocks 8 on both sides until the sliding base 4 completely slides out of the edge computing gateway body 1, and then maintenance or cleaning work can be carried out.

[0035] When dust accumulates on the surface of the heat sink 5, the operator only needs to push the push block 11 inward to drive the limit block 13 to compress the reset spring 9 and disengage from the limit block slot 12. Then, by pulling the protective shell 6, the sliding base 4 and the heat sink 5 can be pulled out as a whole along the T-shaped block slide groove 3. After cleaning, simply push the sliding base 4 back to its original position, and the reset spring 9 will automatically push the limit block 13 into the slot to complete the fixation. This design completely solves the problem of inconvenient cleaning of traditional fixed heat dissipation structures, ensuring that the heat sink 5 always maintains good heat dissipation efficiency. Even in pump room environments with limited ventilation, it can continuously and quickly dissipate the heat generated by components such as processors and communication modules, avoiding heat dissipation failure caused by dust accumulation.

[0036] Structural Description: Edge computing gateway main body 1: As the core load-bearing component of the entire device, it integrates edge computing related circuits and components for calculating water supply terminal pressure. A plug interface 2 is fixedly installed on its front outer wall and is electrically connected to the plug interface 2. Fixing plates are installed on the lower outer walls on both sides, which can be used to fix the device in a designated position. T-shaped block grooves 3 are opened on the inner walls on both sides of the upper end, and limit block slots 12 are opened on the upper surface of the rear end, providing a structural basis for the installation and limiting of the sliding base 4.

[0037] Plug interface 2: It is fixedly installed on the front outer wall of the edge computing gateway body 1 and electrically connected to the edge computing gateway body 1. It is mainly used to connect external lines to realize the transmission of data and power. It is the interface for the device to interact with external systems.

[0038] T-shaped block groove 3: It is formed on the inner walls of both sides of the upper end of the edge computing gateway body 1 and is slidably connected to the T-shaped blocks 8 on both sides of the sliding base 4. It provides guidance for the sliding base 4 to slide in the edge computing gateway body 1 and ensures that the sliding base 4 can only move in a specific direction.

[0039] Sliding base 4: Located inside the upper end of the edge computing gateway body 1, with multiple heat dissipation fins 5 fixedly installed on the upper surface, T-shaped blocks 8 fixedly installed on both outer walls, and a protective shell 6 fixedly installed on the rear outer wall. It is the mounting carrier for the heat dissipation fins 5 and the protective shell 6. It can slide inside the edge computing gateway body 1 through the cooperation of the T-shaped blocks 8 and the T-shaped block sliding groove 3.

[0040] Heat dissipation fins 5: Multiple heat dissipation fins 5 are fixedly installed on the upper surface of the sliding base 4, and form a heat dissipation area on the upper surface of the sliding base 4. Their main function is to dissipate the heat generated inside the edge computing gateway body 1 quickly by increasing the contact area with the air, so as to ensure that the device operates at a suitable temperature.

[0041] Protective shell 6: It is fixedly installed on the outer wall of the rear end of the sliding base 4. A limit block groove 14 is opened at one end near the limit block slot 12, and push block grooves 10 are opened on both outer walls. It protects the internal limit block 13, reset spring 9 and other components, and provides installation space for push block 11 and limit block 7.

[0042] Limiting block 7: It slides and engages inside the push block groove 10. Its two outer walls are respectively in contact with the outer wall of the corresponding push block 11 and the inner wall of the push block groove 10. Its function is to limit the position of the push block 11 and prevent the push block 11 from sliding arbitrarily when not in operation.

[0043] T-block 8: Fixedly installed on both outer walls of the sliding base 4, the outer wall is slidably connected to the inside of the T-block groove 3, and cooperates with the T-block groove 3 to ensure the stable sliding of the sliding base 4 and prevent it from shifting or falling off during movement;

[0044] Reset spring 9: It is set inside the limit block groove 14. There are three in total. Its two ends are fixedly connected to the outer wall of one end of the limit block 13 and the inner wall of the limit block groove 14, respectively. When the limit block 13 is pushed, it deforms and stores elastic potential energy. When the external force disappears, it can push the limit block 13 to reset.

[0045] Push block groove 10: It is opened on both outer walls of the protective shell 6, and communicates with the limit block groove 14 inside. It is slidably connected to the push block 11 and the limit block 7, providing space for the sliding of the push block 11 and the limit block 7, and realizing the linkage between the push block 11 and the limit block 13.

[0046] Push block 11: It is slidably connected inside the push block groove 10. One end near the limit block 13 extends slidably into the limit block groove 14 and is fixedly connected to both sides of the limit block 13. By pushing the push block 11, the limit block 13 can be moved. It is an operating component that controls the position of the limit block 13.

[0047] Limiting block slot 12: It is formed on the upper rear surface of the edge computing gateway body 1 and is slidably connected to the limiting block 13. When the limiting block 13 is inserted into it, the sliding base 4 can be fixed in the edge computing gateway body 1 to prevent it from sliding.

[0048] Limiting block 13: It is slidably connected inside the limiting block groove 14, and one end near the limiting block slot 12 extends slidably to the outside of the limiting block groove 14 and is slidably connected to the limiting block slot 12. Under the action of the reset spring 9, it can be inserted into the limiting block slot 12 to achieve the limiting and fixing of the sliding base 4.

[0049] Limiting block groove 14: It is opened at one end of the protective shell 6 near the limiting block slot 12, and a limiting block 13 is slidably connected inside. It is also equipped with a reset spring 9, which provides a channel for the sliding of the limiting block 13 and supports the reset spring 9.

[0050] The embodiments of the present utility model have been described in detail above with reference to the accompanying drawings. However, the present utility model is not limited to the above embodiments. Within the scope of knowledge possessed by those skilled in the art, various changes can be made without departing from the spirit of the present utility model.

Claims

1. A gateway device for edge computing of water supply terminal pressure, comprising an edge computing gateway body (1) and a plug interface (2), characterized in that: A limit component is provided on the main body (1) of the edge computing gateway; The limiting assembly includes a sliding base (4), a protective shell (6), and multiple heat dissipation fins (5). The multiple heat dissipation fins (5) are all fixedly installed on the upper surface of the sliding base (4). T-shaped blocks (8) are fixedly installed on both sides of the outer wall of the sliding base (4). T-shaped block grooves (3) are opened on both sides of the upper inner wall of the edge computing gateway body (1). Limiting block slots (12) are opened on the upper surface of the rear end of the edge computing gateway body (1). A protective shell (6) is fixedly installed on the outer wall of the rear end of the sliding base (4). A limiting block groove (14) is opened at one end of the protective shell (6) near the limiting block slot (12). A limiting block (13) is slidably connected inside the limiting block groove (14). Push block slots (10) are opened on both sides of the outer wall of the protective shell (6). A limiting block (7) is slidably engaged inside the two push block slots (10). Three reset springs (9) are set inside the limiting block grooves (14). Push blocks (11) are slidably connected inside the two push block slots (10).

2. The gateway device for edge calculation of water supply terminal pressure according to claim 1, characterized in that: The sliding base (4) is located inside the upper end of the edge computing gateway body (1), and the outer walls of the two T-blocks (8) are respectively slidably connected to the interior of the corresponding T-block groove (3).

3. The gateway device for edge calculation of water supply terminal pressure according to claim 1, characterized in that: The end of the limiting block (13) near the limiting block slot (12) slides to the outside of the limiting block groove (14) and is slidably connected to the inside of the corresponding limiting block slot (12).

4. The gateway device for edge calculation of water supply terminal pressure according to claim 1, characterized in that: The two ends of the three reset springs (9) are respectively fixedly connected to the outer wall of one end of the limiting block (13) and the inner wall of the limiting block groove (14).

5. The gateway device for calculating the edge pressure of water supply terminals according to claim 1, characterized in that: Multiple heat dissipation fins (5) form a heat dissipation area on the upper surface of the sliding base (4), and the interior of the two push block grooves (10) is connected to the interior of the limiting block groove (14).

6. The gateway device for edge calculation of water supply terminal pressure according to claim 1, characterized in that: Both push blocks (11) extend into the interior of the limit block groove (14) near the end of the limit block (13) and are fixedly connected to the two sides of the limit block (13).

7. The gateway device for calculating the edge pressure of water supply terminals according to claim 1, characterized in that: The outer walls on both sides of the two limiting blocks (7) respectively contact the outer wall of the corresponding push block (11) and the inner wall of the push block groove (10).

8. The gateway device for edge calculation of water supply terminal pressure according to claim 1, characterized in that: Multiple heat dissipation fins (5) are parallel to each other and equally spaced on the upper surface of the sliding base (4).

9. The gateway device for edge calculation of water supply terminal pressure according to claim 1, characterized in that: The three reset springs (9) are evenly distributed in a straight line within the limit block groove (14).

10. The gateway device for edge calculation of end pressure for water supply according to claim 1, characterized in that: The outer wall of the push block (11) is in close contact with the inner wall of the push block groove (10); Among them, the outer wall of the push block (11) away from the limit block (13) is provided with anti-slip texture.