A groundwater source water outlet monitoring device
Through innovative design of the installation and sealing components, the problems of time-consuming and laborious connection and insufficient sealing of existing devices have been solved, achieving rapid connection and effective sealing, improving work efficiency and preventing leakage.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- YILIANG DIYUAN DRINKING WATER IND & TRADE CO LTD
- Filing Date
- 2025-08-13
- Publication Date
- 2026-07-14
AI Technical Summary
The existing underground water source monitoring devices are time-consuming and labor-intensive to connect to water pipes, and their sealing is insufficient, making them prone to leakage.
The design incorporates mounting and sealing components. The mounting component enables quick connection through the cooperation of a slider and a rotating ring, while the sealing component enhances sealing through the cooperation of a piston and an air chamber.
It enables quick connection and effective sealing between the device and water pipes, improving work efficiency and preventing leakage problems.
Smart Images

Figure CN224500600U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of groundwater source monitoring technology, and in particular to a groundwater source outflow monitoring device. Background Technology
[0002] Groundwater is a water resource existing in the pores of rocks and soil below the Earth's surface. It is formed by atmospheric precipitation and surface runoff infiltration. Its distribution is affected by geological, topographical, and climatic factors. It is mainly divided into three categories: perched water, unconfined water, and confined water. It is characterized by stable water volume, good water quality, wide distribution, but slow regeneration. It is widely used in agriculture, industry, and daily life. However, it currently faces problems such as geological disasters caused by over-exploitation, water quality deterioration caused by pollution, and reduced recharge. It needs to be protected through measures such as rational planning of extraction, pollution control, artificial recharge, and enhanced monitoring to achieve sustainable utilization.
[0003] During the extraction of groundwater, it is necessary to monitor its water quality, thus requiring the use of monitoring devices. However, current monitoring devices have relatively simple structures, and their connection to water pipes is mostly achieved through flanges and bolts. Although this method is simple to operate, it is time-consuming, labor-intensive, and inefficient. In addition, most of them rely on gaskets for sealing, which are prone to breakage and deformation over time, leading to leakage at the connection. Therefore, this application proposes a groundwater source effluent monitoring device to meet the requirements. Utility Model Content
[0004] In order to overcome the shortcomings of existing devices, such as the time-consuming and labor-intensive connection with water pipes and the lack of sealing that can lead to leakage, this utility model provides a groundwater source outflow monitoring device.
[0005] The technical implementation scheme of this utility model is as follows: a groundwater source water discharge monitoring device, comprising a body, a detection probe installed inside the body, a filter screen installed on one side of the detection probe inside the body, a baffle installed on the other side of the detection probe inside the body, a motor with a drive shaft fixedly connected to the baffle installed on the top of the body, the motor and the detection probe being electrically connected, connecting pipes installed on both sides of the body, water inlet pipes provided on both sides of the connecting pipes, a mounting base fixedly connected to the outer periphery of the outer end of the connecting pipe, a connecting base fixedly connected to the outer periphery of the end of the water inlet pipe near the connecting pipe, and a mounting component and a sealing component provided at the connection between the mounting base and the connecting base.
[0006] Optionally, the mounting assembly includes a mounting groove, a mounting block, a mounting hole, a first connecting groove, and a mounting rod. The mounting groove is formed on the side surface of the mounting base near the connecting base. The mounting block is fixedly connected to the side of the connecting base near the mounting base and is adapted to the size of the mounting groove. The mounting hole passes through the mounting block. The first connecting groove is formed inside the mounting base and communicates with the mounting groove. The mounting rod is slidably connected to the first connecting groove and is adapted to the size of the mounting hole.
[0007] Optionally, the mounting assembly further includes a rotating groove, a rotating ring, and a first connecting rod. The rotating groove is formed inside the mounting base and communicates with the first connecting groove. The rotating ring is rotatably connected to the rotating groove. The first connecting rod is slidably connected to the first connecting groove and its two ends are respectively fixedly connected to the mounting rod and the rotating ring.
[0008] Optionally, the mounting assembly further includes a slide groove, a slider, and a spring. The slide groove is formed on the side surface of the mounting base away from the connecting base and communicates with the rotating groove. The slider is fixedly connected to the side of the rotating ring away from the first connecting rod and slidably connected to the slide groove. The spring is installed inside the slide groove and its two ends are fixedly connected to one side of the slider and one side of the inner wall of the slide groove, respectively.
[0009] Optionally, the sealing assembly includes a sealing groove, an annular groove, a sealing ring, an air chamber, and a piston. The sealing groove is formed on the side surface of the connecting seat near the mounting seat. The annular groove is formed on the side surface of the mounting seat near the connecting seat. The sealing ring is made of rubber and is hollow inside. The sealing ring is installed inside the annular groove and, after expansion, matches the size of the sealing groove. The air chamber is formed inside the mounting seat and one end is connected to the sealing ring through a through hole. The piston is slidably connected to the air chamber and is sized to match it.
[0010] Optionally, the sealing assembly further includes a second connecting groove, a push rod, and a second connecting rod. The second connecting groove is formed inside the mounting base and communicates with the rotating groove and one end of the air chamber. The push rod is slidably connected to the second connecting groove and the air chamber and is fixedly connected to the side of the piston away from the through hole. The second connecting rod is slidably connected to the second connecting groove and its two ends are fixedly connected to the rotating ring and the push rod, respectively.
[0011] This utility model has the following advantages:
[0012] 1. This utility model features an installation assembly. A sliding block along a groove compresses a spring. During this process, a rotating ring rotates along the groove as the sliding block moves. Simultaneously, a first connecting rod drives an installation rod to slide along the first connecting groove as the rotating ring rotates. When the installation rod moves with the first connecting rod until it exits and re-enters the first connecting groove, the mounting block of the connecting seat is placed in the groove. The sliding block is then released, causing the spring to rebound and drive the rotating ring to rotate in the opposite direction. This resets the first connecting rod and the installation rod. When the installation rod is inserted into the mounting hole, the mounting block is fixed in the mounting groove, thus completing the installation of the mounting seat and the connecting seat. This design simplifies and speeds up the connection between the machine body and the water pipe, effectively improving work efficiency.
[0013] 2. This utility model, by incorporating a sealing component, allows the second connecting rod to drive the push rod and the second connecting groove to slide along with the rotating ring during the connection process between the mounting base and the connecting base. The push rod then drives the piston to slide along the air chamber and draws air from the sealing ring into the air chamber through the through hole. When the sealing ring deflates and is submerged in the annular groove, the mounting base and the connecting base are connected. After the connection is complete, the spring returns and drives the piston to reset via the rotating ring. At this time, the piston sends air from the air chamber into the sealing ring. When the sealing ring expands to fit tightly against the sealing groove, the connection between the mounting base and the connecting base is sealed. This design effectively enhances the sealing performance of the connection between the mounting base and the connecting base, effectively preventing leakage due to insufficient sealing. Attached Figure Description
[0014] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0015] Figure 2 This is a schematic diagram of the internal structure of the body of this utility model;
[0016] Figure 3 This is a schematic diagram of the surface structure of the mounting base of this utility model;
[0017] Figure 4 This is a schematic diagram of the internal structure of the mounting base of this utility model. Figure 1 ;
[0018] Figure 5 This is a schematic diagram of the internal structure of the mounting base of this utility model. Figure 2 ;
[0019] Figure 6 This is a schematic diagram of the back structure of the mounting base of this utility model;
[0020] Figure 7 This is a schematic diagram of the surface structure of the connector of this utility model.
[0021] The meanings of the reference numerals in the figure are as follows: 1. Body; 2. Detection probe; 3. Filter screen; 4. Baffle; 5. Motor; 6. Connecting pipe; 7. Water inlet pipe; 8. Mounting base; 9. Connecting base; 10. Mounting assembly; 101. Mounting groove; 102. Mounting block; 103. Mounting hole; 104. First connecting groove; 105. Mounting rod; 106. Rotary groove; 107. Rotary ring; 108. First connecting rod; 109. Sliding groove; 1010. Sliding block; 1011. Spring; 11. Sealing assembly; 111. Sealing groove; 112. Annular groove; 113. Sealing ring; 114. Air chamber; 115. Piston; 116. Second connecting groove; 117. Push rod; 118. Second connecting rod. Detailed Implementation
[0022] To make the objectives, technical solutions, and advantages of this utility model clearer, a further detailed description of this utility model will be provided below in conjunction with the accompanying drawings. It is hereby declared that the directional terms such as up, down, left, right, front, back, inside, and outside that appear or will appear in this document are based solely on the accompanying drawings and are not intended to specifically limit this utility model.
[0023] A groundwater source effluent monitoring device includes a body 1, a detection probe 2 installed inside the body 1, a filter screen 3 installed on one side of the detection probe 2 inside the body 1, a baffle 4 installed on the other side of the detection probe 2 inside the body 1, a motor 5 with a drive shaft fixedly connected to the baffle 4 installed on the top of the body 1, the motor 5 and the detection probe 2 being electrically connected, connecting pipes 6 installed on both sides of the body 1, water inlet pipes 7 provided on both sides of the connecting pipes 6, mounting bases 8 fixedly connected to the outer periphery of the outer end of the connecting pipes 6, a connecting base 9 fixedly connected to the outer periphery of the end of the water inlet pipe 7 near the connecting pipe 6, and a mounting component 10 and a sealing component 11 provided at the connection between the mounting base 8 and the connecting base 9.
[0024] It should be noted that the installation component 10 makes the connection between the device and the water pipe simpler and faster, thereby effectively improving work efficiency, and the sealing component 11 can effectively enhance the sealing of the connection between the device and the water pipe, thereby avoiding water leakage due to insufficient sealing.
[0025] like Figure 4 and Figure 7 As shown, the mounting assembly 10 includes a mounting groove 101, a mounting block 102, a mounting hole 103, a first connecting groove 104, and a mounting rod 105. The mounting groove 101 is formed on the side surface of the mounting base 8 near the connecting base 9. The mounting block 102 is fixedly connected to the side of the connecting base 9 near the mounting base 8 and is adapted to the size of the mounting groove 101. The mounting hole 103 passes through the mounting block 102. The first connecting groove 104 is formed inside the mounting base 8 and communicates with the mounting groove 101. The mounting rod 105 is slidably connected to the first connecting groove 104 and is adapted to the size of the mounting hole 103.
[0026] It should be noted that the mounting block 102 is placed in the mounting groove 101, and then the mounting rod 105 is inserted into the mounting hole 103. At this time, the mounting block 102 can be fixed in the mounting groove 101, thereby completing the installation of the mounting base 8 and the connecting base 9.
[0027] like Figure 4 and Figure 5 As shown, the mounting assembly 10 also includes a rotating groove 106, a rotating ring 107, and a first connecting rod 108. The rotating groove 106 is opened inside the mounting base 8 and communicates with the first connecting groove 104. The rotating ring 107 is rotatably connected to the rotating groove 106. The first connecting rod 108 is slidably connected to the first connecting groove 104 and its two ends are respectively fixedly connected to the mounting rod 105 and the rotating ring 107.
[0028] It should be noted that rotating the rotating ring 107 along the rotating groove 106 can drive the mounting rod 105 to rotate synchronously in the first connecting groove 104 via the first connecting rod 108, thereby adjusting the position of the mounting rod 105.
[0029] like Figure 6 As shown, the mounting assembly 10 also includes a slide groove 109, a slider 1010, and a spring 1011. The slide groove 109 is formed on the side surface of the mounting base 8 away from the connecting base 9 and is connected to the rotating groove 106. The slider 1010 is fixedly connected to the side of the rotating ring 107 away from the first connecting rod 108 and is slidably connected to the slide groove 109. The spring 1011 is installed inside the slide groove 109 and its two ends are fixedly connected to one side of the slider 1010 and the inner wall of one side of the slide groove 109, respectively.
[0030] It should be noted that when the slider 1010 is slid along the slide groove 109 to compress the spring 1011, the rotating ring 107 will rotate along the rotating groove 106 as the slider 1010 slides. When the slider 1010 is released, the spring 1011 will rebound and drive the rotating ring 107 to rotate in the opposite direction through the slider 1010.
[0031] like Figure 3 and Figure 7 As shown, the sealing assembly 11 includes a sealing groove 111, an annular groove 112, a sealing ring 113, an air chamber 114, and a piston 115. The sealing groove 111 is formed on the side surface of the connecting seat 9 near the mounting seat 8. The annular groove 112 is formed on the side surface of the mounting seat 8 near the connecting seat 9. The sealing ring 113 is made of rubber and is hollow inside. The sealing ring 113 is installed inside the annular groove 112 and, after expansion, matches the size of the sealing groove 111. The air chamber 114 is formed inside the mounting seat 8 and one end is connected to the sealing ring 113 through a through hole. The piston 115 is slidably connected to the air chamber 114 and is sized to match it.
[0032] It should be noted that after the installation of the mounting base 8 and the connecting base 9 is completed, the piston 115 is slid along the air chamber 114 to send the air in the air chamber 114 to the sealing ring 113. When the sealing ring 113 expands to fit tightly with the sealing groove 111, the connection between the mounting base 8 and the connecting base 9 can be sealed.
[0033] like Figure 4 As shown, the sealing assembly 11 also includes a second connecting groove 116, a push rod 117, and a second connecting rod 118. The second connecting groove 116 is opened inside the mounting base 8 and is connected to the rotating groove 106 and one end of the air chamber 114. The push rod 117 is slidably connected to the second connecting groove 116 and the air chamber 114 and is fixedly connected to the side of the piston 115 away from the through hole. The second connecting rod 118 is slidably connected to the second connecting groove 116 and its two ends are fixedly connected to the rotating ring 107 and the push rod 117, respectively.
[0034] It should be noted that by sliding the second connecting rod 118 along the second connecting groove 116, the piston 115 can be driven by the push rod 117 to slide synchronously along the air chamber 114, thereby drawing the air in the sealing ring 113 into the air chamber 114 or sending the air in the air chamber 114 into the sealing ring 113.
[0035] In a specific application scenario, the slider 1010 first slides along the groove 109 to compress the spring 1011. During this process, the rotating ring 107 rotates along the rotating groove 106 as the slider 1010 slides. Simultaneously, the first connecting rod 108 and the second connecting rod 118 respectively drive the mounting rod 105 and the push rod 117 to slide along the first connecting groove 104 and the second connecting groove 116 as the rotating ring 107 rotates. The mounting rod 105 moves with the first connecting rod 108 until it moves out of the mounting groove 101 and into the first connecting groove 104. The piston 115 slides along the air chamber 114 and draws air from the sealing ring 113 into the air chamber 114 through the through hole. When the sealing ring 113 deflates and sinks into the annular groove 112, the mounting block 102 of the connecting seat 9 is placed in the mounting groove 101. Then, the slider 1010 is released, the spring 1011 rebounds, and the slider 1010 drives the rotating ring 107 to rotate in the opposite direction. The first connecting rod 108 and the second connecting rod 118 drive the mounting rod 105 and the piston 115 to reset. When the mounting rod 105 is inserted into the mounting hole 103, the mounting block 102 is fixed in the mounting groove 101, thus completing the installation of the mounting seat 8 and the connecting seat 9. At the same time, the piston 115 sends the air in the air chamber 114 to the sealing ring 113. When the sealing ring 113 expands to fit tightly with the sealing groove 111, the connection between the mounting seat 8 and the connecting seat 9 is sealed. Then, the water source is sent to the machine body 1 through the water inlet pipe 7 and the connecting pipe 6 to start the monitoring work. During the monitoring process, the filter screen 3 will first filter the garbage in the water source. Then, the detection probe 2 will detect the water source. If the water source is unqualified, the detection probe 2 will transmit a signal to the motor 5. The motor 5 will start and drive the baffle 4 to rotate through the drive shaft to close the machine body 1. If the water source is qualified, the detection probe 2 will transmit a signal to the motor 5 to reverse so that the baffle 4 opens.
[0036] The embodiments of the present invention have been described in detail above with reference to the accompanying drawings. However, the present invention 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 invention.
Claims
1. A groundwater source outflow monitoring device, comprising a body (1), characterized in that, The body (1) is equipped with a detection probe (2). A filter screen (3) is installed on one side of the detection probe (2) inside the body (1). A baffle (4) is installed on the other side of the detection probe (2) inside the body (1). A motor (5) with a drive shaft fixedly connected to the baffle (4) is installed on the top of the body (1). There is an electrical connection between the motor (5) and the detection probe (2). Connecting pipes (6) are installed on both sides of the body (1). Water inlet pipes (7) are provided on both sides of the connecting pipes (6). A mounting seat (8) is fixedly connected to the outer periphery of the outer end of the connecting pipe (6). A connecting seat (9) is fixedly connected to the outer periphery of the end of the water inlet pipe (7) near the connecting pipe (6). An installation component (10) and a sealing component (11) are provided at the connection between the mounting seat (8) and the connecting seat (9).
2. The groundwater source outflow monitoring device according to claim 1, characterized in that, The mounting assembly (10) includes a mounting groove (101), a mounting block (102), a mounting hole (103), a first connecting groove (104), and a mounting rod (105). The mounting groove (101) is opened on the side surface of the mounting base (8) near the connecting base (9). The mounting block (102) is fixedly connected to the side of the connecting base (9) near the mounting base (8) and is adapted to the size of the mounting groove (101). The mounting hole (103) passes through the mounting block (102). The first connecting groove (104) is opened inside the mounting base (8) and communicates with the mounting groove (101). The mounting rod (105) is slidably connected to the first connecting groove (104) and is adapted to the size of the mounting hole (103).
3. The groundwater source outflow monitoring device according to claim 2, characterized in that, The mounting assembly (10) further includes a rotating groove (106), a rotating ring (107), and a first connecting rod (108). The rotating groove (106) is opened inside the mounting base (8) and communicates with the first connecting groove (104). The rotating ring (107) is rotatably connected to the rotating groove (106). The first connecting rod (108) is slidably connected to the first connecting groove (104) and its two ends are fixedly connected to the mounting rod (105) and the rotating ring (107), respectively.
4. The groundwater source outflow monitoring device according to claim 3, characterized in that, The mounting assembly (10) further includes a groove (109), a slider (1010), and a spring (1011). The groove (109) is opened on the side surface of the mounting base (8) away from the connecting base (9) and is connected to the rotating groove (106). The slider (1010) is fixedly connected to the side of the rotating ring (107) away from the first connecting rod (108) and slidably connected to the groove (109). The spring (1011) is installed inside the groove (109) and its two ends are fixedly connected to one side of the slider (1010) and the inner wall of one side of the groove (109), respectively.
5. The groundwater source outflow monitoring device according to claim 3, characterized in that, The sealing assembly (11) includes a sealing groove (111), an annular groove (112), a sealing ring (113), an air chamber (114), and a piston (115). The sealing groove (111) is opened on the side surface of the connecting seat (9) near the mounting seat (8). The annular groove (112) is opened on the side surface of the mounting seat (8) near the connecting seat (9). The sealing ring (113) is made of rubber and is hollow inside. The sealing ring (113) is installed inside the annular groove (112) and, after expansion, is adapted to the size of the sealing groove (111). The air chamber (114) is opened inside the mounting seat (8) and one end is connected to the sealing ring (113) through a through hole. The piston (115) is slidably connected to the air chamber (114) and is adapted to its size.
6. The groundwater source outflow monitoring device according to claim 5, characterized in that, The sealing assembly (11) further includes a second connecting groove (116), a push rod (117), and a second connecting rod (118). The second connecting groove (116) is opened inside the mounting base (8) and is connected to one end of the rotating groove (106) and the air chamber (114). The push rod (117) is slidably connected to the second connecting groove (116) and the air chamber (114) and is fixedly connected to the side of the piston (115) away from the through hole. The second connecting rod (118) is slidably connected to the second connecting groove (116) and its two ends are fixedly connected to the rotating ring (107) and the push rod (117), respectively.