CN116754740A - Water quality monitor based on continuous monitoring technology - Google Patents

Abstract

The invention discloses a water quality monitor based on continuous monitoring technology, which belongs to the field of environmental protection detection technology. A water quality monitor based on continuous monitoring technology, including a mounting plate. A connector is arranged on the outside of the mounting plate. A floating ring is connected to the mounting plate through the connector. A monitor and a mobile component are arranged above the mounting plate. Below the mounting plate A sampling component is provided, and the sampling component is connected to the monitor and the mobile component respectively. This water quality monitor based on continuous monitoring technology sets the sampling component so that the device can sample water at different depths by controlling the depth of the installation box in the water area, thus avoiding the need for workers to manually sample water sources. , reducing the labor intensity of the staff, and because the water at different depths is sampled, the device can more comprehensively monitor the water quality in the water area through the monitor, improving the monitoring effect of the device.

Description

A water quality monitor based on continuous monitoring technology

Technical field

The present invention relates to the technical field of environmental protection detection, and more specifically, to a water quality monitor based on continuous monitoring technology.

Background technique

Water quality monitoring is the process of monitoring and measuring the types of pollutants, concentrations and changing trends of various pollutants in water bodies, and evaluating water quality conditions. Implementing water quality monitoring in water source areas can more effectively and safely ensure the safety of people's drinking water and prevent drinking water pollution. Affecting people's health without knowing it. In the existing technology, for the monitoring of water quality, workers generally sample the water source at regular intervals, and then add the collected water samples to the water quality monitor. , which results in higher labor intensity for staff and also reduces the monitoring efficiency of the water quality monitor.

Based on this, the present invention designs a water quality monitor based on continuous monitoring technology to solve the above problems.

Contents of the invention

Technical issues to be solved

The purpose of the present invention is to provide a water quality monitor based on continuous monitoring technology to solve the problems raised in the above background technology.

A water quality monitor based on continuous monitoring technology, including a mounting plate. A connector is arranged on the outside of the mounting plate. A floating ring is connected to the mounting plate through the connector. A monitor and a mobile device are arranged above the mounting plate. component, a sampling component is provided below the installation plate, and the sampling component is connected to the monitor and the mobile component respectively. A battery is provided above the installation plate on one side of the mobile component, and the battery is connected to the mobile component respectively. The power source and the monitor are electrically connected, and a bracket is provided above the mounting plate on the other side of the mobile component. A solar panel is installed above the bracket, and the solar panel is electrically connected to the battery. A cleaning component is provided on the outside of the solar panel, and the cleaning component is connected to the moving component.

Preferably, the moving assembly includes a mounting bracket arranged below the mounting plate. A driving rod is connected to the outside of the mounting bracket. One end of the driving rod is connected to a turntable. A number of turbine blades are provided on the outside of the turntable. The other end of the driving rod is connected with a driving assembly.

Preferably, the driving assembly includes a mounting seat disposed above the mounting plate. A rotating shaft is connected to the outside of the mounting seat. One end of the rotating shaft is connected to a driving wheel. The outside of the driving wheel is sleeved. There is a belt, and the driving wheel is connected to the driven wheel through the belt. The driven wheel is connected to the end of the driving rod. The other end of the rotating shaft is connected to a circular gear. The circular gear A defective gear is meshed with the outside of one, one side of the defective gear is connected to the sampling component, and a motor is provided on the other side of the defective gear, and the output shaft of the motor is connected to the defective gear.

Preferably, the sampling assembly includes a two-way screw that is rotatably connected below the installation plate. The top of the two-way screw penetrates the installation plate and is connected to a transmission assembly. The transmission assembly is connected to the incomplete gear, and the outer side of the two-way screw is connected to There is a threaded sleeve. The bottom end of the threaded sleeve is connected to an installation box. A water pump is installed in the inner cavity of the installation box. The water inlet end of the water pump is connected to a water inlet pipe. The water inlet pipe runs through the installation box and toward the installation box. Extend outward, and the water outlet end of the water pump is connected with a hose, and the end of the hose away from the water pump is connected with the monitor.

Preferably, the transmission assembly includes two bearing frames arranged above the mounting plate, a rotating rod is rotatably connected between the two bearing frames, one end of the rotating rod penetrates the bearing frame and is connected to the incomplete gear, and The other end of the rotating rod penetrates the bearing frame and is connected to a bevel gear one. The outside of the bevel gear one is meshed with a bevel gear two. A connecting shaft is connected below the bevel gear two. The connecting shaft is far away from the bevel gear. One end of the second gear runs through the mounting plate and is connected to the two-way screw.

Preferably, a movable sleeve is connected above the installation box, and a guide rod is slidably connected to the inner cavity of the movable sleeve. One end of the guide rod away from the movable sleeve is connected to the bottom of the installation plate.

Preferably, the cleaning assembly includes two support frames arranged above the installation plate and on both sides of the solar panel. A threaded rod is rotatably connected between the two support frames. One end of the threaded rod passes through the support frame and is connected to The linkage component, and the other end of the threaded rod penetrates the support frame and is connected to the spring. The outside of the spring is connected to a mounting plate. The installation plate is connected to the support frame and the spring respectively. The outside of the threaded rod is connected to a movable block, the outer side of the movable block is connected with a mounting block, the mounting block is parallel to the solar panel, and a cleaning cotton is provided below the mounting block, and the cleaning cotton is in contact with the solar panel.

Preferably, the linkage assembly includes a fixed seat disposed above the mounting plate. A mounting shaft is rotatably connected to the outside of the fixed seat, and a second circular gear is connected to the outside of the mounting shaft. The second circular gear is connected to the incomplete The gears are meshed, and the end of the installation shaft is connected to the driving wheel 2. The outer side of the driving wheel 2 is covered with a belt 2, and the driving wheel 2 is connected to the driven wheel 2 through the belt 2. The outer side of the driven wheel 2 is connected There is a drive shaft that passes through the support frame and is connected to the threaded rod.

Preferably, the cleaning assembly further includes two fixing brackets arranged above the mounting plate and on both sides of the solar panel. A limiting rod is connected between the two fixing brackets, and a connecting block is connected to the outside of the limiting rod. The connecting block is connected with the mounting block.

beneficial effects

Compared with the existing technology, the advantages of the present invention are:

1) In the present invention, by setting the sampling component, the device controls the depth of the installation box in the water area, so that the device can sample water at different depths, thereby avoiding the need for workers to manually sample water sources and reducing the cost of water source sampling. The labor intensity of the staff is reduced, and due to the sampling of water at different depths, the device can more comprehensively monitor the water quality in the water area through the monitor, which improves the monitoring effect of the device.

2) In the present invention, by setting up the cleaning component, the device can clean the debris above the solar panel, thereby avoiding the solar panel being covered with debris, which will reduce the solar panel's effect on absorbing sunlight, thereby improving This improves the battery life of the device, enables the device to continuously monitor water, and improves the working efficiency of the device.

3) In the present invention, by arranging the moving component, the device can drive the turbine blades to rotate, so that the device can generate power, so that the device can move freely in the water area, so that the device can move to different positions in the water area. Conducting water quality monitoring increases the monitoring range of the device, thereby improving the practical performance of the device.

Description of the drawings

Figure 1 is a schematic diagram of the overall structure of the present invention;

Figure 2 is an enlarged view of the structure at point A in Figure 1 of the present invention;

Figure 3 is an enlarged view of the structure at B in Figure 1 of the present invention;

Figure 4 is a schematic diagram of the overall structure of the present invention from another perspective;

Figure 5 is an enlarged view of the structure at C in Figure 4 of the present invention;

Figure 6 is a cross-sectional view of the installation box structure of the present invention;

Figure 7 is a schematic structural diagram of the solar panel of the present invention.

Description of numbers in the figure: 1. Mounting plate; 2. Connector; 3. Floating ring; 4. Monitor; 5. Moving component; 51. Mounting frame; 52. Driving rod; 53. Turntable; 54. Turbine blades; 55 , driven wheel one; 56. belt one; 57. mounting seat; 58. rotating shaft; 59. driving wheel one; 510. circular gear one; 511. motor; 512. incomplete gear; 6. sampling component; 61. two-way Screw; 62, threaded sleeve; 63, guide rod; 64, movable sleeve; 65, installation box; 66, water pump; 67, water inlet pipe; 68, hose; 69, bearing frame; 610, rotating rod; 611, Bevel gear one; 612, bevel gear two; 613, connecting shaft; 7, battery; 8, bracket; 9, solar panel; 10, cleaning component; 101, support frame; 102, threaded rod; 103, movable block; 104. Installation block; 105. Fixed frame; 106. Limiting rod; 107. Connecting block; 108. Fixing seat; 109. Installation shaft; 1010. Circular gear two; 1011. Driving wheel two; 1012. Belt two; 1013 , driven wheel two; 1014, drive shaft; 1015, installation plate; 1016, spring.

Detailed ways

Embodiment: Please refer to Figure 1-7. A water quality monitor based on continuous monitoring technology includes a mounting plate 1. A connector 2 is provided on the outside of the mounting plate 1. The mounting plate 1 is connected to a floating ring 3 through the connector 2. The monitor 4 and the mobile component 5 are arranged above the installation plate 1. The sampling component 6 is arranged below the installation plate 1. The sampling component 6 is connected to the monitor 4 and the mobile component 5 respectively. The mobile component 5 is located above the installation plate 1. A battery 7 is provided on one side of the mobile component 5. The battery 7 is electrically connected to the power source of the mobile component 5 and the monitor 4 respectively. A bracket 8 is installed above the mounting plate 1 and on the other side of the mobile component 5. The bracket 8 is installed above the There is a solar panel 9, which is electrically connected to the battery 7. A cleaning component 10 is provided on the outside of the solar panel 9, and the cleaning component 10 is connected to the moving component 5.

The moving assembly 5 includes a mounting bracket 51 arranged below the mounting plate 1. A driving rod 52 is connected to the outside of the mounting bracket 51. One end of the driving rod 52 is connected to a turntable 53. A number of turbine blades 54 are provided on the outside of the turntable 53. The driving rod The other end of 52 is connected with a driving assembly. The driving assembly includes a mounting seat 57 arranged above the mounting plate 1. A rotating shaft 58 is connected to the outside of the mounting seat 57. One end of the rotating shaft 58 is connected to a driving wheel 59, and a driving wheel 59. The outside of 59 is covered with a belt 56, and the driving wheel 59 is connected to the driven wheel 55 through the belt 56. The driven wheel 55 is connected to the end of the driving rod 52, and the other end of the rotating shaft 58 is connected to a circular Gear one 510, the outer side of the circular gear 510 is meshed with the incomplete gear 512, one side of the incomplete gear 512 is connected to the sampling assembly 6, and the other side of the incomplete gear 512 is provided with a motor 511, the output shaft of the motor 511 is connected to the incomplete gear 510. Gear 512 is connected.

Specifically, the device is first placed in the water area, and then the motor 511 is controlled to work so that the motor 511 drives the incomplete gear 512 fixedly connected to its output shaft to rotate. When the incomplete gear 512 meshes with the circular gear 510, the incomplete gear 512 It will drive the circular gear 510 meshed with it to rotate, so that the circular gear 510 drives the rotating shaft 58 fixedly connected to it to rotate. When the rotating shaft 58 rotates, it will drive the driving wheel 59 fixedly connected to it to rotate, so that The driving wheel 59 drives the driven wheel 55 to rotate through the belt 56. When the driven wheel 55 rotates, it will drive the driving rod 52 fixedly connected to it to rotate, so that the driving rod 52 drives the turntable 53 fixedly connected to it to rotate. The turntable 53 When rotating, the turbine blades 54 fixedly connected with the turbine blades 54 will be driven to rotate, thereby causing the device to generate power to move.

By arranging the moving component 5, the device can drive the turbine blades 54 to rotate, so that the device generates power, so that the device can move freely in the water area, so that the device can monitor water quality at different locations in the water area, improving The monitoring range of the device is increased, thereby improving the practical performance of the device.

The sampling assembly 6 includes a two-way screw 61 that is rotatably connected below the installation plate 1. The top of the two-way screw 61 penetrates the installation plate 1 and is connected to a transmission assembly. The transmission assembly is connected to the incomplete gear 512. A threaded sleeve is connected to the outside of the two-way screw 61. 62. The bottom end of the threaded sleeve 62 is connected to an installation box 65. A water pump 66 is installed in the inner cavity of the installation box 65. The water inlet end of the water pump 66 is connected to a water inlet pipe 67. The water inlet pipe 67 penetrates the installation box 65 and extends outward. And the water outlet end of the water pump 66 is connected to a hose 68, and the end of the hose 68 away from the water pump 66 is connected to the monitor 4. The transmission assembly includes two bearing frames 69 arranged above the mounting plate 1, between the two bearing frames 69 A rotating rod 610 is rotatably connected. One end of the rotating rod 610 penetrates the bearing frame 69 and is connected to the incomplete gear 512, and the other end of the rotating rod 610 penetrates the bearing frame 69 and is connected to a bevel gear 611. The bevel gear 611 The second bevel gear 612 is meshed on the outside, and a connecting shaft 613 is connected below the second bevel gear 612. One end of the connecting shaft 613 away from the second bevel gear 612 penetrates the installation plate 1 and is connected to the two-way screw 61. In order to prevent installation The box 65 rotates following the threaded sleeve 62. A movable sleeve 64 is connected to the top of the installation box 65. The inner cavity of the movable sleeve 64 is slidingly connected with a guide rod 63. The end of the guide rod 63 away from the movable sleeve 64 is connected to the mounting plate 1. connected at the bottom.

Specifically, when the incomplete gear 512 rotates, it will drive the rotating rod 610 fixedly connected to it to rotate, so that the rotating rod 610 drives the bevel gear 611 fixedly connected to it to rotate, and the bevel gear 611 will drive the bevel gear 611 to rotate when it rotates. The meshed bevel gear 612 rotates, so that the bevel gear 612 drives the connecting shaft 613 fixedly connected with it to rotate. When the connecting shaft 613 rotates, it drives the two-way screw 61 fixedly connected with it to rotate, so that the threaded sleeve 62 Moving up and down under the limiting action of the guide rod 63 and the movable sleeve 64, the threaded sleeve 62 will drive the installation box 65 fixedly connected with it to move synchronously when the threaded sleeve 62 moves. When the incomplete gear 512 is out of mesh with the circular gear 510 , the installation box 65 stops moving. At this time, the water pump 66 is controlled to work, thereby pumping the water there through the water inlet pipe 67 and the hose 68 to the monitor 4 for detection.

By arranging the sampling component 6, the device can control the depth of the installation box 65 in the water area, so that the device can sample water at different depths, which improves the practical performance of the device, and since it can sample water at different depths, Sampling enables the device to more comprehensively monitor the water quality in the water area through the monitor 4, thereby improving the monitoring effect of the device.

The cleaning assembly 10 includes two support frames 101 arranged above the mounting plate 1 and on both sides of the solar panel 9. A threaded rod 102 is rotatably connected between the two support frames 101. One end of the threaded rod 102 penetrates the support frame 101 and is connected with a linkage. assembly, and the other end of the threaded rod 102 penetrates the support frame 101 and is connected to the spring 1016. The outside of the spring 1016 is connected to an installation plate 1015. The installation plate 1015 is connected to the support frame 101 and the spring 1016 respectively. The threaded rod 102 A movable block 103 is connected to the outside, and a mounting block 104 is connected to the outside of the movable block 103. The mounting block 104 is parallel to the solar panel 9, and a cleaning cotton is provided below the mounting block 104. The cleaning cotton is in contact with the solar panel 9. The linkage assembly includes The fixed base 108 is provided above the mounting plate 1. The outer side of the fixed base 108 is rotationally connected to a mounting shaft 109. The outer side of the mounting shaft 109 is connected to a circular gear 1010. The second circular gear 1010 meshes with the incomplete gear 512 and is installed. The end of the shaft 109 is connected to the driving wheel 1011. The outer side of the driving wheel 1011 is covered with a belt 1012. The driving wheel 1011 is connected to the driven wheel 1013 through the belt 1012. The outer side of the driven wheel 1013 is connected to the drive wheel. The shaft 1014 and the drive shaft 1014 pass through the support frame 101 and are connected to the threaded rod 102. In order to prevent the movable block 103 from rotating with the threaded rod 102, the cleaning assembly 10 also includes two disposed above the installation plate 1 and located on both sides of the solar panel 9 The fixed brackets 105 have a limiting rod 106 connected between the two fixed brackets 105. A connecting block 107 is connected to the outside of the limiting rod 106, and the connecting block 107 is connected to the mounting block 104.

Specifically, when the incomplete gear 512 meshes with the second circular gear 1010, the incomplete gear 512 will drive the second circular gear 1010 to rotate, so that the second circular gear 1010 drives the second driving wheel 1011 fixedly connected with it to rotate, and the driving wheel When the second 1011 rotates, it will drive the driven wheel 1013 to rotate through the belt 2 1012, so that the driven wheel 1013 drives the drive shaft 1014 fixedly connected to it to rotate. When the drive shaft 1014 rotates, it will drive the threaded rod 102 fixedly connected to it. When the threaded rod 102 rotates, it will drive the movable block 103 that is threaded with it to move. At this time, due to the limiting effect of the limiting rod 106 and the connecting block 107, the movable block 103 will drive the installation block that is fixedly connected to it. 104 moves, when the installation block 104 moves to the side close to the installation plate 1015, the incomplete gear 512 and the circular gear 1010 are out of mesh. At this time, the spring 1016 will drive the threaded rod 102 to reverse due to elasticity, thereby causing the installation block to rotate. 104 moves to the initial position.

By arranging the cleaning component 10, the device can clean the debris above the solar panel 9, thereby preventing the solar panel 9 from being covered with debris, which will reduce the solar panel 9's effect on absorbing sunlight, thereby improving the efficiency of the device. The battery life enables the device to continuously monitor water and improves the working efficiency of the device.

The basic principles, main features and advantages of the present invention have been shown and described above. Those skilled in the industry should understand that the present invention is not limited by the above embodiments. The above embodiments and descriptions are only preferred examples of the present invention and are not used to limit the present invention. Under the premise, there will be various changes and improvements in the present invention, and these changes and improvements all fall within the scope of the claimed invention. The scope of protection of the present invention is defined by the appended claims and their equivalents.

Claims (9)

1. A water quality monitor based on continuous monitoring technology, including a mounting plate (1), characterized in that: a connector (2) is provided on the outside of the mounting plate (1), and the mounting plate (1) is connected through The piece (2) is connected with a floating ring (3), a monitor (4) and a moving component (5) are provided above the installation plate (1), and a sampling component (6) is provided below the installation plate (1). ), the sampling component (6) is connected to the monitor (4) and the mobile component (5) respectively, and a battery (7) is provided above the installation plate (1) on one side of the mobile component (5), The battery (7) is electrically connected to the power source of the mobile component (5) and the monitor (4) respectively. A bracket (8) is provided above the mounting plate (1) on the other side of the mobile component (5). ), a solar panel (9) is installed above the bracket (8), the solar panel (9) is electrically connected to the battery (7), and a cleaning assembly (10) is provided outside the solar panel (9) , the cleaning component (10) is connected with the moving component (5). 2. A water quality monitor based on continuous monitoring technology according to claim 1, characterized in that: the mobile component (5) includes an installation frame (51) arranged below the installation plate (1), and the installation A driving rod (52) is connected through the outside of the frame (51). One end of the driving rod (52) is connected with a turntable (53). A number of turbine blades (54) are provided on the outside of the turntable (53). The other end of the driving rod (52) is connected with a driving assembly. 3. A water quality monitor based on continuous monitoring technology according to claim 2, characterized in that: the driving component includes a mounting seat (57) arranged above the mounting plate (1), and the mounting seat (57) ) is connected with a rotating shaft (58) on the outside, one end of the rotating shaft (58) is connected with a driving wheel (59), and a belt (56) is set on the outside of the driving wheel (59), and The driving wheel one (59) is connected to the driven wheel one (55) through the belt one (56). The driven wheel one (55) is connected to the end of the driving rod (52), and the other end of the rotating shaft (58) One end is connected with a circular gear (510), the outer side of the circular gear (510) is meshed with a defective gear (512), one side of the defective gear (512) is connected to the sampling assembly (6), and A motor (511) is provided on the other side of the incomplete gear (512), and the output shaft of the motor (511) is connected to the incomplete gear (512). 4. A water quality monitor based on continuous monitoring technology according to claim 1, characterized in that: the sampling assembly (6) includes a bidirectional screw (61) rotatably connected below the mounting plate (1), and the The top of the two-way screw (61) penetrates the mounting plate (1) and is connected to a transmission assembly. The transmission assembly is connected to the incomplete gear (512). A threaded sleeve (62) is connected to the outside of the two-way screw (61). The bottom end of the threaded sleeve (62) is connected to an installation box (65). A water pump (66) is installed in the inner cavity of the installation box (65). The water inlet end of the water pump (66) is connected to a water inlet pipe. (67), the water inlet pipe (67) runs through the installation box (65) and extends outward, and the water outlet end of the water pump (66) is connected with a hose (68), and the hose (68) is away from the water pump (66) One end is connected to the monitor (4). 5. A water quality monitor based on continuous monitoring technology according to claim 4, characterized in that: the transmission assembly includes two bearing frames (69) arranged above the mounting plate (1), and the two A rotating rod (610) is rotatably connected between the bearing frames (69). One end of the rotating rod (610) penetrates the bearing frame (69) and is connected to the incomplete gear (512), and the other end of the rotating rod (610) Penetrating the bearing frame (69) and connected to the bevel gear one (611), the outer side of the bevel gear one (611) is meshed with the bevel gear two (612), and the lower side of the bevel gear two (612) is connected There is a connecting shaft (613), and one end of the connecting shaft (613) away from the second bevel gear (612) penetrates the mounting plate (1) and is connected to the two-way screw (61). 6. A water quality monitor based on continuous monitoring technology according to claim 4, characterized in that: a movable sleeve (64) is connected above the installation box (65), and the movable sleeve (64) A guide rod (63) is slidably connected to the inner cavity of the guide rod (63), and one end of the guide rod (63) away from the movable sleeve (64) is connected to the bottom of the mounting plate (1). 7. A water quality monitor based on continuous monitoring technology according to claim 1, characterized in that: the cleaning component (10) includes two disposed above the installation plate (1) and located on both sides of the solar panel (9). A support frame (101), a threaded rod (102) is rotatably connected between the two support frames (101), one end of the threaded rod (102) penetrates the support frame (101) and is connected to a linkage component, and the threaded rod (102) The other end of the rod (102) penetrates the support frame (101) and is connected to a spring (1016). The outside of the spring (1016) is connected to a mounting plate (1015). The mounting plate (1015) is connected to the support frame respectively. (101) is connected to the spring (1016). The outside of the threaded rod (102) is connected with a movable block (103). The outside of the movable block (103) is connected with a mounting block (104). The mounting block (104) ) is parallel to the solar panel (9), and a cleaning cotton is provided below the installation block (104), and the cleaning cotton is in contact with the solar panel (9). 8. A water quality monitor based on continuous monitoring technology according to claim 7, characterized in that: the linkage component includes a fixed seat (108) arranged above the mounting plate (1), and the fixed seat (108) ) is rotatably connected to an installation shaft (109) on the outside, and a second circular gear (1010) is connected to the outside of the installation shaft (109). The second circular gear (1010) meshes with the incomplete gear (512), and The end of the installation shaft (109) is connected to the second driving wheel (1011). The outer side of the second driving wheel (1011) is covered with a second belt (1012), and the second driving wheel (1011) is connected by the second belt (1012). There is a second driven wheel (1013), and a driving shaft (1014) is connected to the outside of the second driven wheel (1013). The driving shaft (1014) penetrates the support frame (101) and is connected to the threaded rod (102). 9. A water quality monitor based on continuous monitoring technology according to claim 7, characterized in that: the cleaning component (10) also includes two disposed above the installation plate (1) and located on both sides of the solar panel (9). The two fixed brackets (105) are connected with a limiting rod (106), and a connecting block (107) is connected to the outside of the limiting rod (106). The connecting block (107) 107) is connected to the mounting block (104).