Intelligent water supply system comprehensive damping and supporting device
By using a comprehensive vibration reduction and support device for the intelligent water supply system, the problems of unstable water pump position and water hammer effect are solved, thereby improving the stability and service life of the water supply system, simplifying the construction process, and providing a good user experience.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- LIUHEFENG (TIANJIN) TECHNOLOGY CO LTD
- Filing Date
- 2025-06-24
- Publication Date
- 2026-06-09
Smart Images

Figure CN224339153U_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of building engineering technology, and more specifically, to a comprehensive vibration reduction and support device for intelligent water supply systems. Background Technology
[0002] In water supply systems, the stable operation of water pumps is crucial for ensuring continuous water supply and stable pressure. However, in practical applications, factors such as foundation settlement and equipment vibration often affect the positional stability of water pumps, leading to decreased water supply efficiency or even equipment damage. At the same time, pressure fluctuations and water hammer effects at the outlet are also important factors affecting water quality. Furthermore, for water supply pipelines under complex or special conditions, such as long-distance transportation, large terrain undulations, and large pipe diameters, the layout of pipelines and the design of support structures also face many challenges, resulting in a poor user experience. Utility Model Content
[0003] To address the above deficiencies, this application provides a comprehensive vibration damping and support device for an intelligent water supply system. In a water supply system, the stable operation of the water pump is crucial for ensuring continuous water supply and stable pressure. However, in practical applications, factors such as foundation settlement and equipment vibration often affect the positional stability of the water pump, leading to decreased water supply efficiency or even equipment damage. Simultaneously, pressure fluctuations and water hammer effects at the outlet are also significant factors affecting water supply quality. Furthermore, for water supply pipelines under complex or special conditions, such as long-distance transport, large terrain undulations, and large pipe diameters, the layout of the pipeline and the design of the support structure also face numerous challenges.
[0004] This application is implemented as follows:
[0005] This application provides a comprehensive shock absorption and support device for an intelligent water supply system, including a base, a support plate, a shock absorber, a water supply pump, a water supply pipeline, a drill bit, a first column, a water outlet buffer mechanism, a fixing mechanism, a height adjustment mechanism, and a locking mechanism, wherein the support plate is slidably inserted into the base;
[0006] The shock absorber is fixed between the base and the support plate, the water pump is fixed on the upper surface of the support plate, one end of the water supply pipeline is fixed on the second connecting plate, and the upper end of the drill bit is fixed on the lower surface of the first column.
[0007] The outlet buffer mechanism is installed between the outlet of the water supply pump and the water supply pipeline; the outlet buffer mechanism is set to enhance the buffering capacity at the outlet and reduce the water hammer effect.
[0008] The fixing mechanism is installed on the hollow column, and the fixing mechanism is set up to fix the hollow column and the first column together;
[0009] The height adjustment mechanism is installed on the connecting column, and the height adjustment mechanism is set to adjust the height of the second block;
[0010] The locking mechanism is installed on the second column, and the locking mechanism is used to install the second column onto the water supply pipeline.
[0011] In one embodiment of this application, a connecting ear plate is further included, which is fixed to the outer wall of the base.
[0012] In one embodiment of this application, the outlet buffer mechanism includes a metal bellows, a first connecting plate, a first connecting rod, a spring, a second connecting rod, and a second connecting plate. The two ends of the metal bellows are respectively fixed to the first connecting plate and the second connecting plate. One end of the second connecting rod is fixed to the outer wall of the second connecting plate, and one end of the first connecting rod is fixed to the outer wall of the first connecting plate. The spring is fixedly installed between the other end of the second connecting rod and the other end of the first connecting rod.
[0013] In one embodiment of this application, the fixing mechanism includes a connecting column, an L-shaped rod, and a first locking member. One end of the connecting column is fixed to the upper surface of the first column, and the upper end of the connecting column is rotatably disposed on the lower surface of the hollow column. The L-shaped rod is fixed to the outer wall of the hollow column, and the first locking member is threaded through the hollow column. The first locking member and the first column are correspondingly arranged.
[0014] In one embodiment of this application, the height adjustment mechanism includes a hollow column, a second column, a slider, and a second locking member. The upper end of the connecting column is rotatably disposed on the lower surface of the hollow column. The second column is slidably disposed inside the hollow column. The slider is fixed to the outer wall of the second column and is slidably disposed on the hollow column. A threaded groove is provided on the hollow column. The second locking member is threaded through the slider, and the end of the second locking member is threaded in the threaded groove.
[0015] In one embodiment of this application, a plurality of threaded grooves are provided, and the plurality of threaded grooves are linearly and equidistantly arranged on the hollow column.
[0016] In one embodiment of this application, a through hole is provided on the hollow column, and the slider passes through the through hole.
[0017] In one embodiment of this application, the locking mechanism includes a first locking block, a second locking block, a threaded rod, and a nut. The first locking block is fixed to the upper end of the second column, the second locking block is correspondingly arranged with the first locking block, the threaded rod passes through both the first locking block and the second locking block, and the nut is threaded onto the threaded rod.
[0018] The beneficial effects of this application are as follows: The intelligent water supply system integrated shock absorption and support device obtained by the above design achieves effective fixation and shock absorption of the water supply pump, enhances the buffering capacity at the outlet, and reduces the water hammer effect, significantly improving the stability and service life of the water supply system. In addition, the stable support in complex environments simplifies the construction process, shortens the construction period, and facilitates later maintenance, providing strong support for the safe operation of the water supply system and bringing a better user experience. Attached Figure Description
[0019] To more clearly illustrate the technical solutions of the embodiments of this application, the drawings used in the embodiments will be briefly introduced below. It should be understood that the following drawings only show some embodiments of this application and should not be regarded as a limitation of the scope. For those skilled in the art, other related drawings can be obtained from these drawings without creative effort.
[0020] Figure 1 This is a three-dimensional structural schematic diagram of the integrated shock absorption and support device for the intelligent water supply system provided in the embodiments of this application;
[0021] Figure 2 A cross-sectional view of the base provided for an embodiment of this application;
[0022] Figure 3 A three-dimensional structural diagram of the outlet buffer mechanism provided for the embodiments of this application;
[0023] Figure 4 A diagram showing the relationship between the fixing mechanism, the height adjustment mechanism, and the locking mechanism provided in the embodiments of this application;
[0024] Figure 5 Provided for the implementation of this application Figure 4 Enlarged view of region A in the middle;
[0025] Figure 6 An exploded view of the hollow column and the second column provided for an embodiment of this application;
[0026] Figure 7 A diagram showing the relationship between the first column and the hollow column provided for the embodiments of this application.
[0027] In the diagram: 110 - Base; 120 - Support plate; 130 - Connecting ear plate; 140 - Shock absorber; 150 - Water supply pump; 160 - Outlet buffer mechanism; 161 - Metal bellows; 162 - First connecting plate; 163 - First connecting rod; 164 - Spring; 165 - Second connecting rod; 166 - Second connecting plate; 170 - Water supply pipeline; 180 - Drill bit; 190 - First column; 191 - Fixing Mechanism; 1911-Connecting column; 1912-L-shaped rod; 1913-First locking element; 192-Height adjustment mechanism; 1921-Hollow column; 1922-Second column; 1923-Threaded groove; 1924-Slider; 1925-Second locking element; 1926-Through hole; 193-Locking mechanism; 1931-First locking block; 1932-Second locking block; 1933-Threaded rod; 1934-Nut. Detailed Implementation
[0028] To make the objectives, technical solutions, and advantages of the embodiments of this application clearer, 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 a part of the embodiments of this application, not all of them. Based on the embodiments of this application, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of this application.
[0029] Example
[0030] Please see Figures 1-7 This application provides a technical solution: a comprehensive shock absorption and support device for an intelligent water supply system, including a base 110, a support plate 120, a shock absorber 140, a water supply pump 150, a water supply pipeline 170, a drill bit 180, a first column 190, an outlet buffer mechanism 160, a fixing mechanism 191, a height adjustment mechanism 192, and a locking mechanism 193. The support plate 120 is slidably inserted on the base 110. It also includes a connecting ear plate 130, which is fixed on the outer wall of the base 110. The setting of the connecting ear plate 130 facilitates the installation of the base 110.
[0031] The shock absorber 140 is fixed between the base 110 and the support plate 120, the water pump 150 is fixed on the upper surface of the support plate 120, one end of the water supply pipe 170 is fixed on the second connecting plate 166, and the upper end of the drill bit 180 is fixed on the lower surface of the first column 190.
[0032] The outlet buffer mechanism 160 is installed between the outlet of the water supply pump 150 and the water supply pipeline 170. The outlet buffer mechanism 160 is set to enhance the buffering capacity at the outlet and reduce the water hammer effect. The outlet buffer mechanism 160 includes a metal corrugated pipe 161, a first connecting plate 162, a first connecting rod 163, a spring 164, a second connecting rod 165, and a second connecting plate 166. The two ends of the metal corrugated pipe 161 are respectively fixed to the first connecting plate 162 and the second connecting plate 166. One end of the second connecting rod 165 is fixed to the outer wall of the second connecting plate 166. One end of the first connecting rod 163 is fixed to the outer wall of the first connecting plate 162. A spring 164 is fixedly installed between the other end of the second connecting rod 165 and the other end of the first connecting rod 163.
[0033] The fixing mechanism 191 is installed on the hollow column 1921. The fixing mechanism 191 is set to fix the hollow column 1921 and the first column 190 together. The fixing mechanism 191 includes a connecting column 1911, an L-shaped rod 1912 and a first locking member 1913. One end of the connecting column 1911 is fixed to the upper surface of the first column 190, and the upper end of the connecting column 1911 is rotatably set on the lower surface of the hollow column 1921. The L-shaped rod 1912 is fixed to the outer wall of the hollow column 1921. The first locking member 1913 is threaded through the hollow column 1921. The first locking member 1913 and the first column 190 are correspondingly arranged. In this embodiment, both the first locking member 1913 and the second locking member 1925 are bolts.
[0034] A height adjustment mechanism 192 is mounted on the connecting column 1911. The height adjustment mechanism 192 is used to adjust the height of the second locking block 1932. The height adjustment mechanism 192 includes a hollow column 1921, a second column 1922, a slider 1924, and a second locking member 1925. The upper end of the connecting column 1911 is rotatably mounted on the lower surface of the hollow column 1921. The second column 1922 is slidably mounted inside the hollow column 1921. The slider 1924 is fixed to the outer wall of the second column 1922. A threaded groove 1923 is provided on the hollow column 1921. The second locking member 1925 is threaded through the slider 1924. The end thread of the second locking member 1925 is in the threaded groove 1923. Several threaded grooves 1923 are provided, and the several threaded grooves 1923 are linearly and equidistantly arranged on the hollow column 1921. A through hole 1926 is provided on the hollow column 1921. The slider 1924 passes through the through hole 1926. The through hole 1926 facilitates the movement of the slider 1924 on the hollow column 1921.
[0035] The locking mechanism 193 is installed on the second column 1922. The locking mechanism 193 is used to install the second column 1922 onto the water supply pipeline 170. The locking mechanism 193 includes a first locking block 1931, a second locking block 1932, a threaded rod 1933, and a nut 1934. The first locking block 1931 is fixed to the upper end of the second column 1922. The second locking block 1932 is correspondingly arranged with the first locking block 1931. The threaded rod 1933 passes through both the first locking block 1931 and the second locking block 1932. The nut 1934 is threaded onto the threaded rod 1933.
[0036] Specifically, the working principle of the intelligent water supply system's integrated shock absorption and support device is as follows: During use, the drill bit 180 is positioned to facilitate the installation of the first column 190 onto different terrains such as mountains, wetlands, and hard soil. Then, holding the hollow column 1921, the first locking member 1913 is rotated. The end of the first locking member 1913 presses against the outer wall of the first column 190, fixing the hollow column 1921 to the first column 190. Then, the second column 1922 is pulled to adjust the second column... The distance between the end of column 1922 and hollow column 1921 is such that the first locking block 1931 supports the water supply pipe 170. Then, the second column 1922 is held, and the second locking member 1925 is rotated so that the end of the second locking member 1925 enters the threaded groove 1923, thereby fixing the second column 1922 onto the hollow column 1921. Then, the second locking block 1932 is locked onto the water supply pipe 170, and then the threaded rod 1933 is passed through the second locking block in sequence. The first locking block 1932 and the second locking block 1931 are used to clamp and fix the water supply pipe 170, thus providing stable support for the water supply pipe 170. During the use of the water supply pump 150, the shock absorber 140 buffers the vibration generated by the water supply pump 150. The metal bellows 161 and the spring 164 enhance the buffering capacity at the outlet and reduce the water hammer effect. This intelligent water supply system integrates shock absorption and support devices to effectively fix and absorb the vibration of the water supply pump 150, enhance the buffering capacity at the outlet, and reduce the water hammer effect, significantly improving the stability and service life of the water supply system. In addition, the stable support in complex environments simplifies the construction process, shortens the construction period, and facilitates later maintenance, providing strong support for the safe operation of the water supply system and bringing a better user experience.
[0037] The above are merely embodiments of this application and are not intended to limit the scope of protection of this application. Various modifications and variations can be made to this application by those skilled in the art. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of this application should be included within the scope of protection of this application. It should be noted that similar reference numerals and letters in the following figures indicate similar items; therefore, once an item is defined in one figure, it does not need to be further defined and explained in subsequent figures.
Claims
1. A comprehensive vibration damping and support device for an intelligent water supply system, characterized in that, The system includes a base (110), a support plate (120), a shock absorber (140), a water pump (150), a water supply pipeline (170), a drill bit (180), a first column (190), an outlet buffer mechanism (160), a fixing mechanism (191), a height adjustment mechanism (192), and a locking mechanism (193). The support plate (120) is slidably inserted into the base (110). The shock absorber (140) is fixed between the base (110) and the support plate (120), the water pump (150) is fixed on the upper surface of the support plate (120), one end of the water supply pipe (170) is fixed on the second connecting plate (166), and the upper end of the drill bit (180) is fixed on the lower surface of the first column (190). The outlet buffer mechanism (160) is installed between the outlet of the water supply pump (150) and the water supply pipeline (170); The outlet buffer mechanism (160) is designed to enhance the buffering capacity at the outlet and reduce the water hammer effect; The fixing mechanism (191) is installed on the hollow column (1921), and the fixing mechanism (191) is set to fix the hollow column (1921) and the first column (190) together; The height adjustment mechanism (192) is installed on the connecting column (1911), and the height adjustment mechanism (192) is set to adjust the height of the second locking block (1932); The locking mechanism (193) is installed on the second column (1922), and the locking mechanism (193) is configured to install the second column (1922) onto the water supply pipeline (170).
2. The integrated vibration damping and support device for the intelligent water supply system according to claim 1, characterized in that, It also includes a connecting ear plate (130), which is fixed to the outer wall of the base (110).
3. The integrated vibration damping and support device for the intelligent water supply system according to claim 1, characterized in that, The outlet buffer mechanism (160) includes a metal bellows (161), a first connecting plate (162), a first connecting rod (163), a spring (164), a second connecting rod (165), and a second connecting plate (166). The two ends of the metal bellows (161) are respectively fixed to the first connecting plate (162) and the second connecting plate (166). One end of the second connecting rod (165) is fixed to the outer wall of the second connecting plate (166). One end of the first connecting rod (163) is fixed to the outer wall of the first connecting plate (162). The spring (164) is fixedly installed between the other end of the second connecting rod (165) and the other end of the first connecting rod (163).
4. The integrated vibration damping and support device for the intelligent water supply system according to claim 1, characterized in that, The fixing mechanism (191) includes a connecting column (1911), an L-shaped rod (1912), and a first locking member (1913). One end of the connecting column (1911) is fixed to the upper surface of the first column (190), and the upper end of the connecting column (1911) is rotatably disposed on the lower surface of the hollow column (1921). The L-shaped rod (1912) is fixed to the outer wall of the hollow column (1921), and the first locking member (1913) is threaded through the hollow column (1921). The first locking member (1913) and the first column (190) are correspondingly arranged.
5. The integrated vibration damping and support device for the intelligent water supply system according to claim 4, characterized in that, The height adjustment mechanism (192) includes a hollow column (1921), a second column (1922), a slider (1924), and a second locking member (1925). The upper end of the connecting column (1911) is rotatably disposed on the lower surface of the hollow column (1921). The second column (1922) is slidably disposed inside the hollow column (1921). The slider (1924) is fixed on the outer wall of the second column (1922) and is slidably disposed on the hollow column (1921). A threaded groove (1923) is provided on the hollow column (1921). The second locking member (1925) is threaded through the slider (1924), and the end of the second locking member (1925) is threaded in the threaded groove (1923).
6. The integrated vibration damping and support device for the intelligent water supply system according to claim 5, characterized in that, The threaded groove (1923) is provided in a plurality of places, and the plurality of threaded grooves (1923) are linearly and equidistantly arranged on the hollow column (1921).
7. The integrated vibration damping and support device for the intelligent water supply system according to claim 5, characterized in that, The hollow column (1921) has a through hole (1926), and the slider (1924) passes through the through hole (1926).
8. The integrated vibration damping and support device for the intelligent water supply system according to claim 5, characterized in that, The locking mechanism (193) includes a first locking block (1931), a second locking block (1932), a threaded rod (1933), and a nut (1934). The first locking block (1931) is fixed to the upper end of the second column (1922). The second locking block (1932) is correspondingly arranged with the first locking block (1931). The threaded rod (1933) passes through both the first locking block (1931) and the second locking block (1932). The nut (1934) is threaded onto the threaded rod (1933).