An intelligent programmable control cabinet and ultrasonic washing system
By combining sliding blocks and bolt holes to adjust and limit the mechanism, the problem of inconvenient installation of components in the control cabinet is solved, realizing flexible installation and a neat control cabinet design, and reducing the risk of failure.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- 施朗智能科技(江苏)有限公司
- Filing Date
- 2025-07-29
- Publication Date
- 2026-07-03
Smart Images

Figure CN224460282U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of control cabinet technology, and more specifically, to an intelligent programmable control cabinet and an ultrasonic washing system. Background Technology
[0002] An ultrasonic cleaning system consists of an ultrasonic generator, a transducer, a washing tank, and an intelligent programmable control cabinet. It achieves automated control through a programmable logic controller or microcontroller, and can adjust parameters such as cleaning time, temperature, and power. It also integrates protection functions. This equipment system uses the mechanical effect generated by ultrasonic vibration to clean items. It is widely used in industrial, medical, scientific research, and home fields, and is especially suitable for cleaning precision parts, complex structural parts, or items with tiny gaps or blind holes. Its cleaning efficiency and cleanliness are far superior to traditional manual cleaning or spray cleaning.
[0003] The integrated management and control of various electrical devices in an ultrasonic washing system requires a control cabinet. External devices are connected to the control modules inside the control cabinet to achieve the management and control of various devices.
[0004] In existing technologies, components inside control cabinets are typically mounted directly onto beams or vertical bars within the cabinet using fixed brackets or bolts. However, the screw hole positions of different specifications of electrical components vary, and once the mounting position of the fixed bracket is determined, it is difficult to adjust flexibly. This results in some components being unable to be easily installed due to mismatched screw holes, requiring additional processing or replacement of brackets, increasing installation costs and time. Therefore, we propose an intelligent programmable control cabinet and an ultrasonic washing system. Utility Model Content
[0005] The purpose of this utility model is to overcome the shortcomings of the existing technology, adapt to the needs of reality, and provide an intelligent programmable control cabinet and ultrasonic washing system to solve the technical problem that the screw hole position of the current control cabinet fixing bracket is fixed and it is difficult to adapt to the screw holes of components of different specifications.
[0006] To solve the above-mentioned technical problems, this utility model provides the following technical solution: an intelligent programmable control cabinet, including a control cabinet body, an adjustment mechanism, and a limiting mechanism. A vertical mounting rod is fixedly installed inside the control cabinet body, and horizontal mounting rods are fixedly installed on the vertical mounting rod from top to bottom. The adjustment mechanism includes a mounting frame and a sliding frame. The mounting frame is slidably mounted on a corresponding groove on the horizontal mounting rod via a sliding block. The sliding frame is slidably mounted inside the mounting frame. The limiting mechanism includes a first toothed block and a second toothed block. The first toothed block is slidably mounted inside the sliding frame, and the second toothed block is fixedly mounted inside the mounting frame. The position of the sliding frame inside the mounting frame is controlled by the engagement and limiting of the second toothed block and the first toothed block.
[0007] Preferably, the adjustment mechanism further includes a first bolt hole, which is located at the top front of the mounting bracket. The sliding block is fixedly installed on the back of the mounting bracket. An adjustment groove is provided at the bottom front of the mounting bracket. The sliding bracket is slidably installed inside the adjustment groove. A second bolt hole is provided on the front of the sliding bracket.
[0008] Preferably, the limiting mechanism further includes a first connecting rod, which is rotatably mounted inside the cavity of the sliding frame via a rotating shaft. A second connecting rod is rotatably mounted at the end of the first connecting rod. A fixed frame is rotatably mounted at the end of the second connecting rod away from the first connecting rod. A third connecting rod is rotatably mounted at the end of the first connecting rod away from the second connecting rod. A sliding frame that is slidably mounted to the sliding frame is fixedly mounted on the outside of the fixed frame. A spring is fixedly mounted between the sliding frame and the sliding frame. A sliding groove is provided at the position corresponding to the button plate on the sliding frame. The button plate passes through the sliding groove and is fixedly mounted to the sliding frame. A wire placement groove is provided on the outside of the button plate. A guide arc plate is fixedly mounted at the wire inlet end of the wire placement groove. The first toothed block is fixedly mounted on the outside of the sliding frame.
[0009] Preferably, the sliding frame, the fixed frame, the spring, the button plate, the first toothed block and the second toothed block are all symmetrically distributed with respect to the sliding frame, and the other fixed frame is rotatably installed with the third connecting rod.
[0010] Preferably, the inlet end of the wire placement groove is provided with a guide arc plate, and the guide arc plate has a gradually narrowing guide channel.
[0011] Preferably, the spring normally causes the sliding frame to move outward, so that the first toothed block and the second toothed block mesh.
[0012] Preferably, the components are fixedly mounted on the front of the mounting bracket by bolts.
[0013] An ultrasonic washing system includes the aforementioned intelligent programmable control cabinet.
[0014] Compared with the prior art, the beneficial effects of this utility model are:
[0015] 1. This utility model utilizes a sliding block that slides into the groove of the mounting crossbar, allowing for lateral adjustment of the mounting position to meet various lateral installation requirements. The sliding bracket is slidably installed within the adjustment groove of the mounting frame. Combined with the engagement of the first and second bolt holes, the longitudinal position of the sliding bracket within the mounting frame can be adjusted to accommodate the screw hole distribution of different components. Through dual lateral and longitudinal adjustment, convenient installation of components of different specifications can be achieved without replacing the bracket, improving installation flexibility and solving the problem of fixed screw hole positions on control cabinet mounting brackets, making it difficult to adapt to the screw holes of different component specifications.
[0016] 2. This utility model also features a wire storage groove on the surface of the mounting plate to store the connecting wires and prevent them from becoming tangled. The guide arc plate at the entrance of the wire storage groove is designed with a gradually narrowing guide channel, which can guide the connecting wires to quickly pass into the wire storage groove, reducing the problems of wire tangling and squeezing. This not only maintains the cleanliness of the inside of the control cabinet, but also reduces the risk of failure caused by messy wires, and facilitates later inspection and maintenance. Attached Figure Description
[0017] Figure 1 This is a schematic diagram of the external structure of this utility model;
[0018] Figure 2 This is a schematic diagram of the internal structure of the present invention;
[0019] Figure 3 This is a schematic diagram of the adjustment mechanism structure of this utility model;
[0020] Figure 4 This is a schematic diagram of the adjustment mechanism structure of this utility model;
[0021] Figure 5 For the present utility model Figure 4 Enlarged schematic diagram of the structure at point A in the middle;
[0022] Figure 6 This is a front cross-sectional view of the limiting mechanism of this utility model;
[0023] Figure 7 This is a schematic diagram of the top cross-sectional structure of the limiting mechanism of this utility model.
[0024] The following are the labels in the diagram: 1. Control cabinet body; 11. Mounting vertical rod; 12. Mounting horizontal rod; 121. Slide groove; 2. Adjustment mechanism; 21. Mounting bracket; 211. Fixing bolt; 212. Sliding block; 22. First bolt hole; 23. Sliding frame; 24. Second bolt hole; 3. Limiting mechanism; 31. First connecting rod; 311. Rotating shaft; 32. Second connecting rod; 321. Third connecting rod; 33. Sliding frame; 331. Fixing bracket; 34. Spring; 35. Button plate; 351. Cable tray; 352. Guide arc plate; 36. First toothed block; 37. Second toothed block; 4. Components. Detailed Implementation
[0025] Example 1: As Figures 1 to 7 As shown, this utility model relates to an intelligent programmable control cabinet, including a control cabinet body 1, an adjustment mechanism 2, and a limiting mechanism 3. A vertical mounting rod 11 is fixedly installed inside the control cabinet body 1, and horizontal mounting rods 12 are fixedly installed on the vertical mounting rod 11 from top to bottom. The adjustment mechanism 2 includes a mounting frame 21 and a sliding frame 23. The mounting frame 21 is slidably mounted on a corresponding groove 121 on the horizontal mounting rod 12 via a sliding block 212. The sliding frame 23 is slidably mounted inside the mounting frame 21. The limiting mechanism 3 includes a first toothed block 36 and a second toothed block 37. The first toothed block 36 is slidably mounted inside the sliding frame 23, and the second toothed block 37 is fixedly mounted on the mounting frame 21. Inside the mounting bracket 21, the position of the sliding bracket 23 is controlled by the meshing and limiting of the second toothed block 37 and the first toothed block 36. The component 4 is fixedly installed on the front of the mounting bracket 21 by bolts. Through the adjustment mechanism 2, the mounting bracket 21 slides with the sliding groove 121 of the mounting crossbar 12 via the sliding block 212, and its position can be adjusted laterally along the mounting crossbar 12 to meet different lateral installation requirements. The sliding bracket 23 is slidably installed in the adjustment groove of the mounting bracket 21. Combined with the cooperation of the first bolt hole 22 and the second bolt hole 24, the longitudinal position of the sliding bracket 23 in the mounting bracket 21 can be adjusted to adapt the positions of the first bolt hole 22 and the second bolt hole 24 to the screw hole distribution of different components 4. Through dual adjustment in both the lateral and longitudinal directions, the convenient installation of components 4 of different specifications can be achieved without replacing the bracket, improving installation flexibility and solving the problem that the screw hole position of the control cabinet fixing bracket is fixed and difficult to adapt to the screw holes of components 4 of different specifications.
[0026] It should be noted that the electrical equipment in the external ultrasonic washing system is connected to component 3 via a connecting cable, thereby enabling intelligent programming control of the external electrical equipment. Since this technology is a commonly used and recognized technique in the field, it is not described in detail in this application.
[0027] Furthermore, such as Figures 2 to 5As shown, the adjustment mechanism 2 also includes a first bolt hole 22, which is located on the top front of the mounting bracket 21. A sliding block 212 is fixedly installed on the back of the mounting bracket 21. An adjustment groove is provided on the bottom front of the mounting bracket 21. A sliding bracket 23 is slidably installed inside the adjustment groove. A second bolt hole 24 is provided on the front of the sliding bracket 23. The mounting bracket 21 forms a precise sliding fit with the sliding groove 121 of the mounting crossbar 12 through the sliding block 212. The operator can push the mounting bracket 21 to slide smoothly along the mounting crossbar 12 according to the lateral layout requirements of the component 4. After adjusting to the appropriate position, it can be quickly locked by the fixing bolt 211 to ensure that the lateral position is fixed and reliable.
[0028] Furthermore, such as Figures 5 to 7 As shown, the limiting mechanism 3 also includes a first connecting rod 31, which is rotatably mounted inside the cavity of the sliding frame 23 via a rotating shaft 311. A second connecting rod 32 is rotatably mounted at the end of the first connecting rod 31. A fixed frame 331 is rotatably mounted at the end of the second connecting rod 32 away from the first connecting rod 31. A third connecting rod 321 is rotatably mounted at the end of the first connecting rod 31 away from the second connecting rod 32. The sliding frame 33, the fixed frame 331, the spring 34, the pressing plate 35, the first toothed block 36, and the second toothed block 37 are all symmetrically distributed around the sliding frame 23. Another fixed frame 331 is rotatably mounted to the third connecting rod 321. A sliding frame 33 is slidably mounted to the outside of the fixed frame 331. A spring 34 is fixedly mounted between the sliding frame 33 and the sliding frame 23. Under normal conditions, the spring 34 causes the sliding frame 33 to move outward, causing the first connecting rod 321 to move outward. A toothed block 36 engages with a second toothed block 37. A sliding groove is provided at the corresponding position of the sliding frame 23 and the push plate 35. The push plate 35 passes through the sliding groove and is fixedly installed with the sliding frame 33. A wire placement groove 351 is provided on the outside of the push plate 35. A guide arc plate 352 is fixedly installed at the wire inlet end of the wire placement groove 351. The guide arc plate 352 has a tapered guide channel. The first toothed block 36 is fixedly installed on the outside of the sliding frame 33. The wire placement groove 351 on the surface of the push plate 35 can be used to store the connecting wires and avoid the wires from being scattered. The guide arc plate 352 at the inlet end of the wire placement groove 351 is designed with a tapered guide channel, which can guide the connecting wires to quickly pass into the wire placement groove 351, reducing the problem of wire tangling and squeezing. This not only maintains the cleanliness of the inside of the control cabinet body 1, but also reduces the risk of failure caused by messy wires, and facilitates later inspection and maintenance.
[0029] Example 2: An ultrasonic washing system, including the above-mentioned intelligent programmable control cabinet.
[0030] Working principle: This embodiment provides an intelligent programmable control cabinet and an ultrasonic washing system. During use, when installing the component 4, the position of the mounting bracket 21 on the mounting crossbar 12 can be adjusted first, so that the sliding block 212 on the back of the mounting bracket 21 slides inside the corresponding groove 121 on the mounting crossbar 12. After adjustment, the fixing bolt 211 is rotated, and the fixing bolt 211 is used to abut against the top of the mounting crossbar 12 to complete the fixing of the mounting bracket 21.
[0031] Pushing the button 35 inward causes the sliding frame 33 to compress the spring 34, storing energy in the spring 34. After the sliding frame 33 moves inward, the second connecting rod 32 pushes the first connecting rod 31 through the fixing bracket 331, causing the first connecting rod 31 to rotate around the rotating shaft 311, which in turn pulls the third connecting rod 321. The third connecting rod 321 then pulls the fixing bracket 331 on the other side, causing both sliding frames 33 to retract inward. This disengages the second toothed block 37 fixedly installed on the outer side of the sliding frame 33 from the locking limit of the first toothed block 36 fixedly installed on the inner wall of the mounting bracket 21. Pushing the button 35 upward allows adjustment of the position of the second bolt hole 24 located inside the sliding frame 23. Therefore, the positions of the first bolt hole 22 and the second bolt hole 24 can be adjusted according to the different bolt hole positions of the components 4 for the installation of different components 4.
[0032] During the wiring process of electrical equipment and components 4 in the ultrasonic washing system, the connecting wire is placed at the wire placement groove 351 starting from the surface of the button plate 35 on either side. During the placement of the connecting wire, it first passes through the guide arc plate 352. Because the guide arc plate 352 is a cone-shaped funnel with a large opening at the inlet end and a small opening at the outlet end, it is convenient for the wiring to be quickly inserted and prevents the connecting wire from being scattered inside the control cabinet body 1.
[0033] The embodiments disclosed herein are preferred embodiments, but are not limited thereto. Those skilled in the art can readily grasp the spirit of this utility model based on the above embodiments and make different extensions and variations. However, as long as they do not depart from the spirit of this utility model, they are all within the protection scope of this utility model.
Claims
1. An intelligent programmable logic controller cabinet, characterized by, include, The control cabinet body (1) has a vertical mounting rod (11) fixedly installed inside it, and the vertical mounting rod (11) has a horizontal mounting rod (12) fixedly installed from top to bottom. Adjustment mechanism (2), the adjustment mechanism (2) includes mounting frame (21) and sliding frame (23), the mounting frame (21) is slidably mounted on the mounting crossbar (12) through sliding block (212) and slidably engaged with the corresponding sliding groove (121), the sliding frame (23) is slidably mounted on the inner side of the mounting frame (21); The limiting mechanism (3) includes a first toothed block (36) and a second toothed block (37). The first toothed block (36) is slidably installed on the inner side of the sliding frame (23), and the second toothed block (37) is fixedly installed on the inner side of the mounting frame (21). The position of the sliding frame (23) inside the mounting frame (21) is controlled by the engagement limit between the second toothed block (37) and the first toothed block (36).
2. The intelligent programmable control cabinet according to claim 1, characterized in that, The adjustment mechanism (2) further includes a first bolt hole (22), which is located on the top front of the mounting bracket (21). The sliding block (212) is fixedly installed on the back of the mounting bracket (21). An adjustment groove is provided on the bottom front of the mounting bracket (21). The sliding bracket (23) is slidably installed inside the adjustment groove. A second bolt hole (24) is provided on the front of the sliding bracket (23).
3. The intelligent programmable control cabinet according to claim 2, characterized in that, The limiting mechanism (3) further includes a first connecting rod (31), which is rotatably mounted inside the cavity of the sliding frame (23) via a rotating shaft (311). A second connecting rod (32) is rotatably mounted at the end of the first connecting rod (31). A fixed frame (331) is rotatably mounted at the end of the second connecting rod (32) away from the first connecting rod (31). A third connecting rod (321) is rotatably mounted at the end of the first connecting rod (31) away from the second connecting rod (32). A sliding frame (33) is fixedly mounted on the outside of the fixed frame (331) and slidably mounted on the sliding frame (23). A spring (34) is fixedly mounted between the sliding frame (33) and the sliding frame (23). The sliding frame (23) has a sliding groove at the corresponding position of the push plate (35), and the push plate (35) is fixedly installed through the sliding groove and the sliding frame (33). A wire placement groove (351) is provided on the outside of the push plate (35), and a guide arc plate (352) is fixedly installed at the wire inlet end of the wire placement groove (351). The first toothed block (36) is fixedly installed on the outside of the sliding frame (33).
4. The intelligent programmable control cabinet according to claim 3, characterized in that, The sliding frame (33), the fixed frame (331), the spring (34), the button plate (35), the first toothed block (36) and the second toothed block (37) are all symmetrically distributed with respect to the sliding frame (23), and the other fixed frame (331) is rotatably installed with the third connecting rod (321).
5. The intelligent programmable control cabinet according to claim 4, characterized in that, The inlet end of the wire placement groove (351) is provided with a guide arc plate (352), and the guide arc plate (352) has a gradually narrowing guide channel.
6. The intelligent programmable control cabinet according to claim 5, characterized in that, The spring (34) normally causes the sliding frame (33) to move outward, so that the first toothed block (36) and the second toothed block (37) mesh.
7. The intelligent programmable control cabinet according to claim 6, characterized in that, The mounting bracket (21) has components (4) fixedly mounted on its front side by bolts.
8. An ultrasonic washing system, characterized by, Including an intelligent programmable control cabinet as described in any one of claims 1 to 7.