Energy-saving monitoring data fast collector
By combining the sponge block drive mechanism and the liquid supply component, efficient cleaning of the data acquisition device surface is achieved, solving the heat dissipation and data accuracy problems caused by dust adhesion, and improving the stability and ease of maintenance of the equipment.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Filing Date
- 2025-08-04
- Publication Date
- 2026-07-14
AI Technical Summary
In outdoor environments, data acquisition devices are prone to accumulating a large amount of dust, affecting their heat dissipation performance and data acquisition accuracy. Existing brush cleaning methods are prone to generating static electricity, attracting more dust, and are easily worn, making it difficult to meet the needs of continuous and efficient dust removal.
It adopts a sponge block combined with a drive mechanism, a liquid supply component and a clearance mechanism. The sponge block is driven to rotate by a servo motor and delivers cleaning liquid. Combined with a linear motor, it achieves efficient cleaning of the sponge block. The quick-install component makes it easy to replace the sponge block.
It effectively removes dust from the surface and key parts of the data acquisition unit, ensuring the accuracy and stability of data acquisition, reducing maintenance difficulty, and improving the convenience and automation level of equipment maintenance.
Smart Images

Figure CN224499566U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of data acquisition technology, and in particular to a rapid data acquisition device for energy-saving monitoring. Background Technology
[0002] In the field of energy conservation monitoring, data acquisition devices are used as key equipment in various outdoor scenarios, such as industrial plants, urban public facilities, and buildings, to collect key information such as energy consumption data and equipment operating parameters in real time, providing important basis for energy conservation analysis and decision-making.
[0003] However, due to prolonged exposure to outdoor environments, the surface of the data acquisition unit is highly susceptible to dust accumulation. This dust not only affects the heat dissipation performance of the acquisition unit, leading to increased operating temperature and decreased stability, but it can also directly cover the sensing components or interfaces of the data acquisition unit, interfering with signal transmission and reception, resulting in reduced data acquisition accuracy, slower response speed, and even data loss, seriously affecting the accuracy and efficiency of energy-saving monitoring.
[0004] To address the adverse effects of dust on data acquisition devices, existing technologies often employ contact friction between brush bristles and the device surface for dust removal. However, the brush bristles may generate static electricity during friction, which can actually attract more dust. Furthermore, the bristles are prone to wear and deformation after prolonged use, further reducing cleaning effectiveness and failing to meet the continuous and efficient dust removal requirements of data acquisition devices in outdoor environments. Therefore, this invention proposes an energy-saving rapid data acquisition device for monitoring. Utility Model Content
[0005] The purpose of this invention is to address the problem that in outdoor environments, data acquisition devices are prone to accumulating a large amount of dust, affecting their performance and data acquisition effect. Existing brush cleaning methods suffer from problems such as static electricity attracting more dust and brush bristles easily wearing down and deforming, resulting in poor cleaning effect. This invention proposes an energy-saving rapid data acquisition device for monitoring.
[0006] The technical solution of this utility model is as follows: an energy-saving monitoring data rapid acquisition device, including a base, a data acquisition body installed on the top of the base; a sponge block located above the data acquisition body; a quick-release assembly disposed on the sponge block, the quick-release assembly realizing the replacement and assembly of the sponge block; a drive mechanism located above the quick-release assembly, the drive mechanism driving the sponge block to rotate through the quick-release assembly to clean the data acquisition body; a liquid supply assembly disposed on the base, the liquid supply assembly being used to deliver cleaning liquid into the sponge block; and a clearance mechanism installed on the top of the base, the clearance mechanism being used to move the sponge block to make way after cleaning.
[0007] Optionally, the quick-installation assembly includes a fixing plate fixedly connected to the top of the sponge block. A through hole is provided in the middle of the fixing plate. Two sets of symmetrically arranged limiting blocks are fixedly connected to the top of the fixing plate. The limiting blocks are L-shaped. Mounting brackets are slidably connected to the two sets of limiting blocks. A first baffle is fixedly connected to one end of the mounting bracket.
[0008] Optionally, a second baffle is provided on the side of the mounting bracket away from the first baffle. At least one set of first connecting blocks are fixedly connected to both ends of the second baffle. A screw passes through the first connecting block, and a second connecting block is threaded onto the screw. The second connecting block is fixedly connected to the mounting bracket.
[0009] Optionally, the drive mechanism includes a vertically arranged side plate, and a fixed frame is fixedly connected to the side plate near the mounting frame. The fixed frame is L-shaped, and a servo motor is mounted on the fixed frame. The output end of the servo motor passes through the fixed frame and is fixedly connected to a first gear. A second gear is provided on one side of the first gear and meshes with it. A rotating cylinder is fixedly connected to the second gear, and the rotating cylinder is fixedly connected to the top of the mounting frame.
[0010] Optionally, the outer ring of the rotating cylinder is rotatably connected to a first positioning plate via a bearing, and the first positioning plate is fixedly connected to the side plate.
[0011] Optionally, the liquid supply assembly includes a water tank installed on one side of the base. A miniature water pump is connected to the bottom of the water tank via a pipe. The miniature water pump is installed on the base. The output end of the miniature water pump is connected to a liquid outlet pipe via a pipe. One end of the liquid outlet pipe passes through the rotating cylinder and the mounting bracket and is fixedly connected to a liquid outlet box. The liquid outlet box is hollow and communicates with the liquid outlet pipe. The bottom of the liquid outlet box contacts the sponge block and has through holes arranged in a ring array.
[0012] Optionally, the outlet pipe is rotatably connected to the rotating cylinder and the mounting bracket via a bearing, and a second positioning plate is fixedly connected to the outer ring of the outlet pipe. The second positioning plate is fixedly connected to the side plate and the fixing bracket.
[0013] Optionally, the clearance mechanism includes a linear motor mounted on the top of the base, a push rod motor mounted on the moving end of the linear motor, a moving block fixedly connected to the output end of the push rod motor, the moving block fixedly connected to the side plate, and multiple sets of sliding rods mounted on the moving end of the linear motor, with sliders slidably connected to the sliding rods, the sliders fixedly connected to the side plate.
[0014] Optionally, the base is equipped with a battery and a control module, and the data acquisition unit, servo motor, micro water pump, linear motor and push rod motor are all electrically connected to the control module.
[0015] In summary, this application includes at least one of the following beneficial technical effects:
[0016] This invention delivers cleaning fluid to the sponge block through a water tank, a micro water pump, an outlet pipe, and an outlet box in the liquid supply component. In conjunction with the servo motor, first gear, second gear, and rotating cylinder of the drive mechanism, the sponge block rotates. The push rod motor of the clearance mechanism ensures that the sponge block makes close contact with the data acquisition unit body. This can efficiently remove dust from the surface and key parts of the data acquisition unit body, solve the problem of incomplete cleaning by existing brush cleaning methods, reduce dust interference with data acquisition, and ensure the accuracy and stability of data acquisition.
[0017] Furthermore, the quick-installation components, such as the fixing plate, limiting block, mounting bracket, second baffle, and screws, make the replacement of the sponge block simple and convenient, reducing the difficulty of maintenance.
[0018] In summary, this invention can efficiently remove dust from the surface of the data acquisition device, ensuring the accuracy and stability of data acquisition, and also improving the convenience and automation level of equipment maintenance. Attached Figure Description
[0019] Figure 1 This is a structural diagram of a rapid data acquisition device for energy-saving monitoring.
[0020] Figure 2 This is a cross-sectional structural diagram of the quick-installation component;
[0021] Figure 3 This is a cross-sectional structural diagram of the yielding mechanism;
[0022] Figure 4 yes Figure 1 Enlarged diagram of point A in the middle.
[0023] Figure label:
[0024] 1. Base; 2. Data acquisition unit body; 3. Sponge block; 4. Quick-release assembly; 41. Fixing plate; 42. Through hole; 43. Limiting block; 44. Mounting bracket; 45. First baffle; 46. Second baffle; 47. First connecting block; 48. Screw; 49. Second connecting block;
[0025] 5. Drive mechanism; 51. Side plate; 52. Fixing frame; 53. Servo motor; 54. First gear; 55. Second gear; 56. Rotating cylinder; 57. First positioning plate;
[0026] 6. Liquid supply assembly; 61. Water tank; 62. Miniature water pump; 63. Liquid outlet pipe; 64. Liquid outlet box; 65. Second positioning plate;
[0027] 7. Yielding mechanism; 71. Linear motor; 72. Push rod motor; 73. Moving block; 74. Sliding rod; 75. Sliding block. Detailed Implementation
[0028] The technical solution of this utility model will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are some embodiments of this utility model, but not all embodiments.
[0029] The components of the present invention embodiments described and shown in the accompanying drawings can typically be arranged and designed in a variety of different configurations. Therefore, the following detailed description of the embodiments of the present invention provided in the drawings is not intended to limit the scope of the claimed invention, but merely to illustrate selected embodiments of the invention.
[0030] Based on the embodiments of this utility model, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of this utility model.
[0031] In the description of this utility model, it should be noted that the terms "center," "upper," "lower," "left," "right," "vertical," "horizontal," "inner," and "outer," etc., indicating the orientation or positional relationship, are based on the orientation or positional relationship shown in the accompanying drawings and 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, and therefore should not be construed as a limitation of this utility model. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and should not be construed as indicating or implying relative importance.
[0032] In the description of this utility model, it should be noted that, unless otherwise explicitly specified and limited, the terms "installation," "connection," and "joining" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral connection; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; and they can refer to the internal connection of two components. Those skilled in the art can understand the specific meaning of the above terms in this utility model based on the specific circumstances.
[0033] Example
[0034] like Figure 1 As shown, this utility model proposes an energy-saving monitoring data rapid acquisition device, including a base 1, a data acquisition body 2 installed on top of the base 1, and the data acquisition body 2 capable of rapid data acquisition. A sponge block 3 is located above the data acquisition body 2; the sponge block 3 rotates after contacting the data acquisition body 2 to clean it.
[0035] For further details, please refer to Figure 1 , Figure 2 and Figure 4 As shown, the aforementioned collector is mounted on the sponge block 3 via a quick-release assembly 4, which enables the replacement and assembly of the sponge block 3. The quick-release assembly 4 includes a fixing plate 41 fixedly connected to the top of the sponge block 3. A through hole 42 is provided in the middle of the fixing plate 41. Two sets of symmetrically arranged limiting blocks 43 are fixedly connected to the top of the fixing plate 41. The limiting blocks 43 have an L-shaped structure. The fixing plate 41, limiting blocks 43, and sponge block 3 are integrated, allowing for simultaneous replacement when the sponge block 3 needs to be replaced. Mounting brackets 44 are slidably connected to the two sets of limiting blocks 43. The arrangement of the limiting blocks 43 and mounting brackets 44 facilitates the installation and removal of the sponge block 3. A first baffle 45 is fixedly connected to one end of the mounting bracket 44, preventing the limiting blocks 43 from sliding out from that end. A second baffle 46 is provided on the side of the mounting bracket 44 away from the first baffle 45. At least one set of first connecting blocks 47 are fixedly connected to both ends of the second baffle 46. A screw 48 passes through the first connecting block 47, and a second connecting block 49 is threaded onto the screw 48. The second connecting block 49 is fixedly connected to the mounting bracket 44. The second baffle 46 is fixed to the side of the mounting bracket 44 away from the first baffle 45 by the arrangement of the first connecting block 47, screw 48 and second connecting block 49, preventing the limiting block 43 from sliding out of the mounting bracket 44, thereby fixing the position of the sponge block 3. At the same time, the screw 48 facilitates the disassembly of the second baffle 46, making it convenient to remove and replace the sponge block 3.
[0036] Furthermore, such as Figure 1 and Figure 2As shown, the data acquisition device also includes a drive mechanism 5 located above the quick-release assembly 4. The drive mechanism 5 drives the sponge block 3 to rotate via the quick-release assembly 4 to clean the data acquisition device body 2. The drive mechanism 5 includes a vertically arranged side plate 51. A fixing frame 52 is fixedly connected to the side plate 51 near the mounting frame 44. The fixing frame 52 is L-shaped and a servo motor 53 is mounted on the fixing frame 52. The output end of the servo motor 53 passes through the fixing frame 52 and is fixedly connected to a first gear 54. After the servo motor 53 starts, it drives the first gear 54 to rotate. A second gear 55 is provided on one side of the first gear 54 and meshes with it. When the servo motor 53 rotates, it drives the second gear 55 to rotate through the first gear 54. A rotating cylinder 56 is fixedly connected to the second gear 55. The rotating cylinder 56 is fixedly connected to the top of the mounting frame 44. When the second gear 55 rotates, it drives the mounting frame 44 to rotate through the rotating cylinder 56, thereby driving the sponge block 3 to rotate. When the sponge block 3 rotates, it effectively cleans the surface of the data acquisition device body 2. The outer ring of the rotating cylinder 56 is rotatably connected to the first positioning plate 57 via a bearing. The first positioning plate 57 is fixedly connected to the side plate 51. The setting of the first positioning plate 57 enables the rotating cylinder 56 to maintain its original position and rotate.
[0037] It should be noted that a protective cover can be installed on the outside of the aforementioned drive mechanism 5, which has the function of dustproofing and waterproofing, and protecting the normal operation of the internal components.
[0038] Specifically, the aforementioned collector also includes a liquid supply assembly 6 mounted on the base 1, which is used to deliver cleaning fluid to the sponge block 3. The liquid supply assembly 6 includes a water tank 61 installed on one side of the base 1. The water tank 61 holds the cleaning fluid, and its side has an inlet that fits a sealing cap for easy addition of cleaning fluid. A level sensor is installed in the water tank 61 to detect the remaining cleaning fluid level in real time, sending a signal to the control module when the cleaning fluid is insufficient. The control module then sends a signal to the remote control console or triggers an alarm light and buzzer on the base 1 to prompt staff to add cleaning fluid promptly. A miniature water pump 62 is connected to the bottom of the water tank 61 via a pipe. The miniature water pump 62 is mounted on the base 1, and its output is connected to an outlet pipe 63 via a pipe. When the miniature water pump 62 starts, it delivers the cleaning fluid from the water tank 61 to the outlet pipe 63. One end of the liquid outlet pipe 63 passes through the rotating cylinder 56 and the mounting bracket 44 and is fixedly connected to the liquid outlet box 64. The liquid outlet box 64 is hollow and communicates with the liquid outlet pipe 63. The bottom of the liquid outlet box 64 contacts the sponge block 3 and has through holes arranged in a ring array. The cleaning liquid in the liquid outlet pipe 63 flows into the liquid outlet box 64 and flows out through multiple through holes to wet the sponge block 3, improving the cleaning effect of the sponge block 3. The liquid outlet pipe 63 is rotatably connected to the rotating cylinder 56 and the mounting bracket 44 via a bearing. A second positioning plate 65 is fixedly connected to the outer ring of the liquid outlet pipe 63. The second positioning plate 65 is fixedly connected to the side plate 51 and the fixing bracket 52. The position of the second positioning plate 65 is fixed to prevent the liquid outlet pipe 63 from rotating.
[0039] Furthermore, such as Figures 1 to 3 As shown, a clearance mechanism 7 is installed on the top of the base 1. This mechanism is used to move the sponge block 3 to a safer position after cleaning, preventing it from interfering with the monitoring function of the data acquisition unit 2. The clearance mechanism 7 includes a linear motor 71 installed on the top of the base 1. The linear motor 71 moves the sponge block 3 laterally, facilitating its movement to the data acquisition unit 2 for cleaning. After cleaning, the sponge block 3 moves away from the data acquisition unit 2. A push rod motor 72 is installed at the moving end of the linear motor 71. A moving block 73 is fixedly connected to the output end of the push rod motor 72. The moving block 73 is fixedly connected to the side plate 51. When the push rod motor 72 is activated, it moves the sponge block 3 up and down. Once the sponge block 3 is above the data acquisition unit 2, the push rod motor 72 can then move the sponge block 3 downwards, bringing it closer to and squeezing the data acquisition unit 2. This causes the sponge block 3 to deform. Due to the elasticity of the sponge block 3, the friction between the sponge block 3 and the data acquisition unit 2 increases, thus improving the cleaning effect when the sponge block 3 rotates. The linear motor 71 is also equipped with multiple sets of slide rods 74. A slider 75 is slidably connected to the slide rod 74. The slider 75 is fixedly connected to the side plate 51. The arrangement of the slide rods 74 and the slider 75 prevents the side plate 51 from tilting.
[0040] The base 1 is equipped with a battery and a control module. The battery powers the entire device. The data acquisition unit 2, servo motor 53, micro water pump 62, linear motor 71 and push rod motor 72 are all electrically connected to the control module to realize the automatic control of the device. The control module is equipped with a remote transmission module to facilitate signal transmission and remote control.
[0041] In this embodiment, the linear motor 71 first drives the push rod motor 72, the moving block 73, and the side plate 51 on the moving end to move laterally, so that the sponge block 3 is precisely moved above the data acquisition unit 2. Then, the push rod motor 72 starts, and its output pushes the moving block 73 and the side plate 51 downwards, causing the sponge block 3 to approach and press against the data acquisition unit 2. During this process, the cooperation of the slide rod 74 and the slider 75 ensures the stable movement of the side plate 51, preventing tilting. The sponge block 3 deforms due to its own elasticity, increasing the friction with the data acquisition unit 2, providing better contact for subsequent cleaning.
[0042] Then, the control module synchronously starts the drive mechanism 5 and the liquid supply assembly 6. In the liquid supply assembly 6, the micro water pump 62 delivers the cleaning liquid in the water tank 61 to the outlet pipe 63 through a pipeline. The cleaning liquid flows into the outlet box 64 through the outlet pipe 63 and seeps out through the through hole at the bottom of the outlet box 64, wetting the sponge block 3 and enhancing its cleaning ability. At the same time, the servo motor 53 of the drive mechanism 5 starts, driving the first gear 54 at the output end to rotate. The first gear 54 meshes with and drives the second gear 55, causing the second gear 55 to drive the rotating cylinder 56 to rotate. Since the rotating cylinder 56 is fixedly connected to the mounting bracket 44, the mounting bracket 44 rotates accordingly, and drives the sponge block 3 to rotate synchronously through the fixing plate 41 of the quick-release assembly 4. During the friction between the rotating sponge block 3 and the data acquisition unit body 2, the surface dust is effectively removed.
[0043] After cleaning, the push rod motor 72 moves the sponge block 3 upward, disengaging it from the data acquisition unit 2. The linear motor 71 moves the sponge block 3 away from the data acquisition unit 2 to avoid interfering with its data acquisition function. The servo motor 53 and the miniature water pump 62 stop working.
[0044] When the sponge block 3 needs to be replaced, loosen the screw 48 on the second baffle 46 in the quick-release assembly 4, remove the second baffle 46, slide out the limiting block 43 on the mounting bracket 44, and then remove the fixing plate 41, sponge block 3 and limiting block 43 at the same time. After replacing the new assembly, the installation can be completed by reversing the operation.
[0045] The above specific embodiments are merely optional embodiments of this utility model. Based on the technical solution of this utility model and the relevant teachings of the above embodiments, those skilled in the art can make various alternative improvements and combinations to the above specific embodiments.
Claims
1. An energy-saving monitoring data fast collector, characterized in that, Include: Base (1), data collector body (2) installed on the top of the base (1); Sponge block (3) above the data collector body (2); Quick assembly component (4) provided on the sponge block (3), the quick assembly component (4) realizes the replacement assembly of the sponge block (3), the quick assembly component (4) includes a fixed plate (41) fixedly connected to the top of the sponge block (3), a through hole (42) is formed in the middle of the fixed plate (41), two groups of limiting blocks (43) are symmetrically arranged on the top of the fixed plate (41), the limiting block (43) is L-shaped structure, the mounting bracket (44) is slidably connected to the two groups of limiting blocks (43), the first baffle (45) is fixedly connected to one end of the mounting bracket (44); The driving mechanism (5) above the quick assembly component (4), the driving mechanism (5) drives the sponge block (3) to rotate to clean the data collector body (2) through the quick assembly component (4); Liquid supply assembly (6) provided on the base (1), the liquid supply assembly (6) is used for conveying cleaning liquid to the sponge block (3); The installation of the base (1) on the top of the let mechanism (7), the let mechanism (7) is used for moving the sponge block (3) after cleaning.
2. The energy-saving monitoring data fast collector according to claim 1, characterized in that, The mounting bracket (44) is provided with a second baffle (46) away from the first baffle (45), at least one group of first connecting blocks (47) are fixedly connected to both ends of the second baffle (46), the screw (48) is arranged in the first connecting block (47), the second connecting block (49) is threadedly connected to the screw (48), and the second connecting block (49) is fixedly connected with the mounting bracket (44).
3. The energy-saving monitoring data fast collector according to claim 2, characterized in that, The driving mechanism (5) includes a vertical side plate (51), the side plate (51) is fixedly connected with a fixed frame (52) close to one side of the mounting bracket (44), the fixed frame (52) is L-shaped, the servo motor (53) is installed on the fixed frame (52), the output end of the servo motor (53) penetrates through the fixed frame (52) and is fixedly connected with the first gear (54), the first gear (54) is provided with the second gear (55) engaged with it on one side, the rotating cylinder (56) is fixedly connected to the top of the mounting bracket (44).
4. The energy-saving monitoring data fast collector according to claim 3, characterized in that, The rotating cylinder (56) is rotatably connected with the first positioning plate (57) through the bearing, and the first positioning plate (57) is fixedly connected with the side plate (51).
5. The energy-saving monitoring data fast collector according to claim 4, characterized in that, The liquid supply assembly (6) comprises a water tank (61) mounted on one side of the base (1), the bottom of the water tank (61) is connected with a micro water pump (62) through a pipeline, the micro water pump (62) is mounted on the base (1), the output end of the micro water pump (62) is connected with a liquid outlet pipe (63) through a pipeline, one end of the liquid outlet pipe (63) penetrates through the rotating cylinder (56) and the mounting frame (44) and is fixedly connected with a liquid outlet box (64), the liquid outlet box (64) is hollow and communicates with the liquid outlet pipe (63), the bottom of the liquid outlet box (64) is in contact with the sponge block (3) and is provided with through holes in the form of annular array.
6. The energy-saving monitoring data fast collector according to claim 5, characterized in that, The liquid outlet pipe (63) is rotatably connected with the rotating cylinder (56) and the mounting frame (44) through a bearing, and the outer ring of the liquid outlet pipe (63) is fixedly connected with a second positioning plate (65), the second positioning plate (65) is fixedly connected with the side plate (51) and the fixing frame (52).
7. The energy-saving monitoring data fast collector according to claim 6, characterized in that, The yield mechanism (7) comprises a linear motor (71) mounted on the top of the base (1), the moving end of the linear motor (71) is mounted with a push rod motor (72), the output end of the push rod motor (72) is fixedly connected with a moving block (73), the moving block (73) is fixedly connected with the side plate (51), and the moving end of the linear motor (71) is further mounted with a plurality of slide rods (74), the slide rods (74) are slidably connected with slide blocks (75), and the slide blocks (75) are fixedly connected with the side plate (51).
8. The energy-saving monitoring data fast collector according to claim 7, characterized in that, The base (1) is provided with a battery and a control module, and the data collector body (2), the servo motor (53), the micro water pump (62), the linear motor (71) and the push rod motor (72) are electrically connected with the control module.