An electric power storage control device
By introducing sliding mounting components and fixed adjustment mechanisms into the power storage control device, the problem of inconvenient disassembly of the connecting frame is solved, enabling rapid disassembly and limiting of electrical components, and improving operational convenience and installation efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- LIHE (TIANJIN) NEW ENERGY TECHNOLOGY GROUP CO LTD
- Filing Date
- 2025-12-15
- Publication Date
- 2026-06-19
AI Technical Summary
In existing power storage control devices, the disassembly of the connecting frame is inconvenient and can easily lead to the misalignment of electrical components, loosening or misalignment of wiring terminals, cumbersome operation, and insufficient limit function.
An energy storage control device was designed, which adopts a sliding mounting component and a fixed adjustment mechanism, including a limit component and a snap-fit component. The sliding and snap-fit structure enables simple disassembly and limiting of electrical components, and can adapt to electrical components of different sizes.
It enables quick disassembly and replacement of electrical components, avoids loose or misaligned wiring terminals, and improves installation efficiency and ease of operation.
Smart Images

Figure CN121417002B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of power control technology, specifically to a power energy storage control device. Background Technology
[0002] Power storage control devices are core equipment in power systems used to manage the charging and discharging process of energy storage units, optimize energy dispatch, and ensure stable system operation. Through real-time monitoring, intelligent control, and coordinated linkage of multiple components, they realize the storage and efficient release of electrical energy. PLC control cabinets are industrial automation control equipment that integrate programmable logic controllers and related electrical components, and are specifically designed to realize intelligent control and management of production equipment or industrial processes.
[0003] Chinese patent CN117177502B describes a power storage control device. This invention only requires inserting the component into the connecting frame and then sliding it into the trapezoidal groove. The operation is simple and convenient. Moreover, it can be easily removed and replaced during subsequent maintenance. Since the movable plate can be opened freely (and the restriction on the reciprocating rod is released), the sliding of the component and the connecting frame is not affected by the side walls of the chassis. The installation is fast and efficient. Furthermore, the components can be added or removed at will based on the original design.
[0004] Existing technology uses a side wall that is rotatably connected to the cabinet to facilitate the installation of mounting frames. These frames house individual electrical components, and several frames are slid onto a lifting frame assembly. A reciprocating rod, in conjunction with a movable plate, pushes the anti-slip plate to secure the frames. While this allows for some lateral and longitudinal adjustment of the electrical components, replacing a frame requires opening the side wall to slide it out. Opening the side wall causes the reciprocating rod inside the cabinet to reset, releasing the frames. Removing a damaged frame can interfere with other frames, causing them to shift. Furthermore, the lack of internal limiters for electrical components during disassembly can lead to component movement, loosening or misalignment of terminals, resulting in poor contact and short circuits. Additionally, removing a damaged frame requires simultaneously removing several frames in front of it, and disconnecting the installed wiring before removing the front frame. This makes the process time-consuming, labor-intensive, cumbersome, and inconvenient in actual use.
[0005] Therefore, the present invention provides an energy storage control device that is easy to disassemble and limits the electrical components. Summary of the Invention
[0006] To address the problem that the mounting frames used for installing electrical components in existing technologies are not easy to disassemble, a power storage control device has been designed.
[0007] The technical solution adopted by this invention to solve its technical problem is as follows: a power storage control device, including a cabinet, inside which are arranged several sets of slidingly mounted sliding components. Several sets of fixed adjustment mechanisms are slidably connected to one side of the sliding mounting components. Each fixed adjustment mechanism includes a mounting member with a protrusion on one side, a clamping part on the protruding side of the mounting member, and a slidably adjustable latching part on the other side of the mounting member. The clamping part includes two sets of symmetrically arranged limiting components and a first adjustment component at the bottom of the limiting components. The limiting components are used to limit the position of electrical components installed on the mounting member. The first adjustment component is used to adjust the limiting components to release the limiting of the electrical components. The latching part includes symmetrically arranged latching components and a second adjustment component at the bottom of the latching components. The latching components are used to latch the fixed adjustment mechanism onto the sliding mounting components. The second adjustment component is used to drive the latching part on one side to disengage, so that the fixed adjustment mechanism can be adjusted laterally along the sliding mounting group and can be disassembled and replaced.
[0008] Furthermore, the fixing and adjusting mechanism also includes a latching block protruding on one side of the mounting component. The latching assembly includes a first latching block and a second latching block symmetrically arranged on the side of the mounting component away from the latching block, and rotating components symmetrically arranged inside the first latching block and the second latching block. The limiting component is slidably connected to the mounting component, the first latching block is fixedly connected to the mounting component, the second latching block is fixedly connected to the second adjusting component, one end of the rotating component located inside the first latching block is rotatably connected to the mounting component, and one end of the rotating component located inside the second latching block is rotatably connected to the second adjusting component.
[0009] Furthermore, the limiting component includes a mounting frame and an adjusting block slidably connected inside the mounting frame. A first fixing rod is provided inside the mounting frame, and a first spring is sleeved on the outside of the first fixing rod. A first sliding member is symmetrically arranged and fixedly connected to the bottom of the mounting frame. A second fixing rod is slidably connected inside the first sliding member, and a second spring is sleeved on the outside of the second fixing rod. The mounting frame is slidably connected to the mounting member through the first sliding member. Sliding blocks arranged in an inverted T shape are provided on both sides of the adjusting block. The sliding blocks are slidably connected to the first fixing rod. The first fixing rod and the first spring are symmetrically arranged about the sliding blocks. The second fixing rod is fixedly connected to the mounting member.
[0010] Furthermore, the first adjustment assembly includes a first driving member slidably connected to the mounting component, a transmission gear drivenly connected to one end of the first driving member, a slide rod drivenly connected to the outer bottom of the transmission gear and a transmission member with an elastic element in the middle, a slide plate slidably connected to the end of the slide rod away from the transmission gear, a first gear set drivenly connected to the end of the transmission member away from the transmission gear, and two sets of L-shaped sliding top rods drivenly connected to the outer upper end of the first gear set.
[0011] Furthermore, the second adjustment component includes a second sliding member slidably installed inside one side of the mounting component, a third fixed rod symmetrically arranged inside the second sliding member, a third spring sleeved on the outside of the third fixed rod, a second driving member fixedly connected to one side of the second sliding member, a buckle symmetrically arranged inside the second driving member, the second driving member slidably connected inside the mounting component, one end of the second driving member protruding to the outside of the mounting component, and the third spring being disposed on the third fixed rods on both sides of the second sliding member, with both ends of the third spring being fixedly connected to the second sliding member and the mounting component respectively.
[0012] Furthermore, the end of the first driving member away from the transmission gear protrudes to the outside of the mounting member. The transmission gear and the first gear set are rotatably mounted inside the mounting member. The transmission member, the slide rod, and the slide plate are slidably mounted inside the mounting member. The first gear set includes two sets of gears, an upper set and a rotating shaft inside the gears. The upper gear is connected to the sliding push rod, and the lower gear is connected to the transmission member.
[0013] Furthermore, the mounting component includes a limiting block disposed inside the slide groove that is slidably connected to the second driving component, and a third sliding component that is slidably installed inside the slide groove. The limiting block is used to limit the second sliding component in conjunction with the buckle, so that the second buckle is engaged with the sliding mounting component to fix the fixing adjustment mechanism. The third sliding component is used to reset the second sliding component in conjunction with the buckle, so that when the fixing adjustment mechanism is disassembled, the second sliding component drives the second buckle to reset.
[0014] Furthermore, the sliding mounting assembly includes a sliding mounting bracket for engaging and fixing the adjustment mechanism, a slide rail on one side of the sliding mounting bracket, adjustment grooves inside both ends of the sliding mounting bracket, a fixing member rotatably mounted inside the adjustment groove, sliders at both ends of the sliding mounting bracket away from the slide rail, one end of the fixing member protruding to the outside of the slider, one end of the fixing member having an elastic element connected to the inner wall of the adjustment groove, and the other end of the fixing member protruding to the outside of the sliding mounting bracket, for fixing and releasing the sliding adjustment assembly for longitudinal adjustment, and the sliding mounting assembly engaging with the fixing adjustment mechanism via the slide rail.
[0015] Furthermore, the sliding mounting assembly has a fixed mechanism slidably connected to one side of the slider. The fixed mechanism includes a fixed frame that is fixedly connected to the cabinet, a groove inside the fixed frame, and evenly distributed fixing holes inside the groove. Both ends of the sliding mounting frame are slidably connected to the inside of the groove through the slider. The end of the fixing member that protrudes to the outside of the slider engages with the fixing hole to fix the sliding mounting assembly.
[0016] The beneficial effects of this invention are:
[0017] (1) The power storage control device of the present invention can remove the second locking block from the slide rail by pulling the second driving component and cooperating with the second sliding component. Then the fixed adjustment mechanism can be removed for replacement and subsequent processing. The operation is simple and each fixed adjustment mechanism can be quickly disassembled and replaced individually, so as not to interfere with other electrical components and avoid the problems of loose or misaligned wiring terminals, poor contact and short circuit.
[0018] (2) The power storage control device of the present invention can clamp and fix electrical components installed on the fixed adjustment mechanism to limit their movement by setting the limit component. This avoids the problem of electrical components being easily affected and shifting when other electrical components are disassembled due to the lack of limit function. Then, by adjusting the sliding adjustment block inside the mounting frame and cooperating with the first sliding part at the bottom of the mounting frame, it can be adapted to electrical components of various sizes without the need to frequently replace the fixed adjustment mechanism, thereby further improving the installation efficiency of electrical components. Attached Figure Description
[0019] The present invention will be further described below with reference to the accompanying drawings and embodiments.
[0020] Figure 1 This is a schematic diagram of the main structure of the present invention;
[0021] Figure 2 This is a schematic diagram of the internal structure of the cabinet when it is opened according to the present invention;
[0022] Figure 3 This is a schematic diagram of the fixing mechanism structure of the present invention;
[0023] Figure 4 For the present invention Figure 3 A magnified view of part A;
[0024] Figure 5 This is a partial sectional view of the fixing frame of the present invention;
[0025] Figure 6 This is a partial sectional view of the sliding mounting bracket of the present invention;
[0026] Figure 7 This is a schematic diagram of the sliding mounting component structure of the present invention;
[0027] Figure 8 For the present invention Figure 7 A magnified view of section B;
[0028] Figure 9 This is a schematic diagram of the fastener structure of the present invention;
[0029] Figure 10 This is a schematic diagram of the fixed adjustment mechanism of the present invention;
[0030] Figure 11 This is a side view of the fixed adjustment mechanism of the present invention;
[0031] Figure 12 This is a partial cross-sectional view of the mounting component of the present invention;
[0032] Figure 13 This is a partial cross-sectional view of the mounting frame of the present invention;
[0033] Figure 14 This is a schematic diagram of the adjusting block structure of the present invention;
[0034] Figure 15 This is a schematic diagram of the structure of the first adjustment component of the present invention;
[0035] Figure 16 This is a schematic diagram of the rotating component structure of the present invention;
[0036] Figure 17 For the present invention Figure 16 A magnified view of a portion at point C;
[0037] Figure 18 This is a partial cross-sectional view of the second card block of the present invention;
[0038] Figure 19 For the present invention Figure 18 A magnified view of a portion at point D;
[0039] Figure 20 This is a schematic diagram of the structure of the second adjustment component of the present invention;
[0040] Figure 21 This is a schematic diagram of the rotating component structure of the present invention;
[0041] Figure 22 This is a partial cross-sectional view of the electrical components of the present invention;
[0042] Figure 23 This is a schematic diagram of the fixing and adjusting mechanism for installing electrical components according to the present invention;
[0043] Figure 24 This is a schematic diagram of the fixing and adjusting mechanism for installing large-sized electrical components according to the present invention.
[0044] In the diagram: 1. Cabinet body; 2. Fixing mechanism; 21. Fixing bracket; 22. Slide groove; 23. Fixing hole; 3. Sliding mounting assembly; 31. Sliding mounting bracket; 32. Slide rail; 33. Adjustment groove; 34. Fixing component; 4. Fixing and adjusting mechanism; 41. Mounting component; 411. Limiting block; 412. Third sliding component; 42. Snap-fit block; 43. Limiting assembly; 431. Mounting frame; 432. Adjusting block; 433. First fixing rod; 434. First spring; 435. First sliding component; 436. 437. Second fixed rod; 44. Second spring; 45. First adjusting component; 46. First driving component; 47. Transmission gear; 48. Slide rod; 49. Slide plate; 40. Transmission component; 41. First gear set; 42. Sliding top rod; 43. First locking block; 44. Rotating component; 45. Second locking block; 46. Second adjusting component; 47. Second adjusting component; 48. Second sliding component; 49. Third fixed rod; 40. Third spring; 41. Second driving component; 42. Fastening component; 43. Electrical component. Detailed Implementation
[0045] To make the technical means, technical features, objectives and effects of this invention easier to understand, the invention will be further described below in conjunction with specific embodiments.
[0046] Example: Figure 1 - Figure 24 As shown, the power storage control device of the present invention includes a cabinet 1. Several sets of sliding mounting components 3 are slidably installed inside the cabinet 1. Several sets of fixed adjustment mechanisms 4 are slidably connected to one side of each sliding mounting component 3. Each fixed adjustment mechanism 4 includes a mounting member 41 with a protrusion on one side, a clamping part on the protruding side of the mounting member 41, and a slidably adjustable latching part on the other side of the mounting member 41. The clamping part includes two sets of symmetrically arranged limiting components 43 and a first adjustment component 44 at the bottom of the limiting components 43. The limiting components 43 are used to limit the position of electrical components 5 installed on the mounting member 41. The first adjustment component 44 is used to adjust the limiting components 43 to release the limiting of the electrical components 5. The latching part includes symmetrically arranged latching components and a second adjustment component 48 at the bottom of the latching components. The latching components are used to latch the fixed adjustment mechanism 4 onto the sliding mounting component 3. The second adjustment component 48 is used to drive the latching part 485 on one side to disengage, allowing the fixed adjustment mechanism 4 to be adjusted laterally along the sliding mounting assembly and to be disassembled and replaced.
[0047] Specifically, the fixed adjustment mechanism 4 can be adapted to electrical components 5 within a certain width and height range. For electrical components 5 that are wider and within the adaptation range, two sets of fixed adjustment mechanisms 4 can be used in combination for installation, or the adapted fixed adjustment mechanism 4 can be replaced for installation. The sliding mounting assembly 3 is inserted into the sliding groove 22 opened inside the fixed frame 21 by the sliders on both sides of the sliding mounting bracket 31, and the sliding mounting assembly 3 is fixed on the fixed frame 21 by the cooperation of the fixing member 34 and the fixing hole 23. The second driving member 484 drives the second locking block 47 to slide, so that the fixed adjustment mechanism 4 can be placed on the slide rail 32 of the sliding mounting assembly 3, and the fixed adjustment mechanism 4 is locked on the sliding mounting assembly 3 by the cooperation of the first locking block 45.
[0048] Pulling a set of limiting components 43 allows the electrical component 5, which has a buckle at the bottom, to be inserted into the snap-fit block 42. The buckle engages the snap-fit block 42, achieving initial fixation. The buckle at the bottom of the electrical component 5 is existing technology and will not be described in detail. Releasing the limiting components 43 allows them to automatically reset and work with another limiting component 43 to clamp and fix the electrical component 5. At the same time, the adjusting block 432 inside the limiting components 43 can be adjusted according to the thickness of both sides of the electrical component 5 to accommodate different electrical components 5. By pulling the adjusting block 432, it slides inside the mounting frame 431. When the required height of the electrical component 5 is reached, the adjusting block 432 can be released. Under the action of the first spring 434, the adjusting block 432 resets to limit and further clamp and fix the electrical component.
[0049] In this embodiment, the fixing adjustment mechanism 4 further includes a latching block 42 protruding on one side of the mounting member 41. The latching assembly includes a first latching block 45 and a second latching block 47 symmetrically arranged on the side of the mounting member 41 away from the latching block 42, and rotating members 46 symmetrically arranged inside the first latching block 45 and the second latching block 47. The limiting assembly 43 is slidably connected to the mounting member 41. The first latching block 45 is fixedly connected to the mounting member 41. The second latching block 47 is fixedly connected to the second adjustment assembly 48. One end of the rotating member 46 located inside the first latching block 45 is rotatably connected to the mounting member 41, and one end of the rotating member 46 located inside the second latching block 47 is rotatably connected to the second adjustment assembly 48.
[0050] Specifically, such as Figure 10 - Figure 21As shown, the mounting component 41 is used to install and fix the various internal structures of the adjustment mechanism 4. The snap-fit block 42 is used to engage with the bottom snap-fit of the electrical component 5. The limiting component 43 is used to further fix the electrical component 5. The first adjusting component 44 is used to adjust the limiting component 43 to release it from fixing the electrical component 5, and at the same time release the engagement between the electrical component 5 and the snap-fit block 42, so that the electrical component 5 can be removed. The first snap-fit block 45 and the second snap-fit block 47 are used in conjunction with the second adjusting component 48 to engage the slide rail 32, so that the adjustment mechanism 4 is fixed and disengaged from the sliding mounting component 3. The rotating component 46 can be set as a connecting component and a rotating wheel set on one side of the connecting component, and is rotatably connected with the mounting component 41 and the second sliding component 481 in conjunction with the torsion spring, so that the rotating component 46 fits against the slide rail 32 under the action of the torsion spring, making it easier for the adjustment mechanism 4 to move laterally. At the same time, the rotating component 46 can also be set as any other structure that can achieve the same effect.
[0051] In this embodiment, the limiting component 43 includes a mounting frame 431 and an adjusting block 432 slidably connected inside the mounting frame 431. A first fixing rod 433 is provided inside the mounting frame 431, and a first spring 434 is sleeved on the outside of the first fixing rod 433. A first sliding member 435 is symmetrically arranged and fixedly connected to the bottom of the mounting frame 431. A second fixing rod 436 is slidably connected inside the first sliding member 435, and a second spring 437 is sleeved on the outside of the second fixing rod 436. The mounting frame 431 is slidably connected to the mounting member 41 through the first sliding member 435. Sliding blocks arranged in an inverted T shape are provided on both sides of the adjusting block 432. The sliding blocks are slidably connected to the first fixing rod 433. The first fixing rod 433 and the first spring 434 are symmetrically arranged about the sliding blocks. The second fixing rod 436 is fixedly connected to the mounting member 41.
[0052] Specifically, such as Figure 12 - Figure 14 As shown, the mounting frame 431 is used to mount the adjusting block 432 and the first fixing rod 433. The sliders on both sides of the adjusting block 432 are slidably mounted inside the limiting groove set inside the mounting frame 431. The maximum adjustment distance of the adjusting block 432 is less than the size of the limiting groove. When the adjusting block 432 is adjusted, it compresses the first spring 434 and slides on the first fixing rod 433. The adjusting block 432 can be adjusted to adapt to electrical components 5 with different thicknesses at both ends within a certain size. The mounting frame 431 can be adjusted to adapt to electrical components 5 with different heights within a certain range by compressing the second spring 437 and sliding. When the size of the electrical component 5 exceeds the adaptation range, the fixing adjustment mechanism 4 can be replaced. At the same time, the limiting component 43 can also be set to any other structure that can achieve the same effect.
[0053] In this embodiment, the first adjustment component 44 includes a first driving component 441 slidably connected to the mounting component 41, a transmission gear 442 tractively connected to one end of the first driving component 441, a slide rod 443 tractively connected to the outer bottom of the transmission gear 442, and a transmission component 445 with an elastic element in the middle, a slide plate 444 slidably connected to the end of the slide rod 443 away from the transmission gear 442, a first gear set 446 tractively connected to the end of the transmission component 445 away from the transmission gear 442, and two sets of L-shaped sliding top rods 447 tractively connected to the outer upper end of the first gear set 446.
[0054] Specifically, such as Figure 12 and Figure 15 - Figure 17 As shown, the end of the first driving member 441 away from the transmission gear 442 protrudes to the outside of the mounting member 41. The transmission gear 442 and the first gear set 446 are rotatably mounted inside the mounting member 41. The transmission member 445, the slide rod 443, and the sliding plate 444 are slidably mounted inside the mounting member 41. The first gear set 446 includes upper and lower gears and a rotating shaft inside the gears. The upper gear is connected to the sliding push rod 447, and the lower gear is connected to the transmission member 445. When disassembling a larger electrical component 5, the first driving member 441, in conjunction with the transmission gear 442, drives the slide rod 443 and the transmission member 445 to slide inside the mounting member 41. At this time, the distance that the slide rod 443 needs to move is greater than that of the sliding push rod 445. The sliding rod 447 can no longer move when it pushes out and pushes the bottom of the electrical component 5 back inward. When the transmission gear 442 continues to rotate, the elastic element in the middle of the transmission component 445 can elastically contract, thus preventing the power from being transmitted to the first gear set 446. After the limiting component 43 moves to the appropriate position to remove the electrical component 5, the elastic element inside the transmission component 445 resets. The elastic element can be set as a spring telescopic rod. The reset of the limiting component 43 can drive the sliding rod 447 to reset, and at the same time drive the slide rod 443, the slide plate 444 and the first driving component 441 to reset. At the same time, the first adjusting component 44 and the elastic element can also be set as any other structure that can achieve the same effect.
[0055] In this embodiment, the second adjustment component 48 includes a second sliding member 481 slidably installed inside one side of the mounting member 41. A third fixing rod 482 is symmetrically arranged inside the second sliding member 481. A third spring 483 is sleeved on the outside of the third fixing rod 482. A second driving member 484 is fixedly connected to one side of the second sliding member 481. A buckle 485 is symmetrically arranged inside the second driving member 484. The second driving member 484 is slidably connected inside the mounting member 41. One end of the second driving member 484 protrudes to the outside of the mounting member 41. The third spring 483 is disposed on the third fixing rod 482 on both sides of the second sliding member 481. The two ends of the third spring 483 are fixedly connected to the second sliding member 481 and the mounting member 41, respectively.
[0056] Specifically, such as Figure 18 - Figure 21 The mounting component 41 includes a limiting block 411 slidably connected to the second driving component 484 and a third sliding component 412 slidably mounted inside the sliding groove 22. The limiting block 411 is used to cooperate with the buckle 485 to limit the second sliding component 481, so that the second locking block 47 engages with the sliding mounting component 3 to fix the fixing adjustment mechanism 4. The third sliding component 412 is used to cooperate with the buckle 485 to reset the second sliding component 481, so that when the fixing adjustment mechanism 4 is disassembled, the second sliding component 481 drives the second locking block 47 to reset. The second adjustment component 48 can also be set to any other structure that can achieve the same effect.
[0057] In this embodiment, the sliding mounting assembly 3 includes a sliding mounting bracket 31 for engaging and fixing the adjustment mechanism 4, a slide rail 32 on one side of the sliding mounting bracket 31, adjustment grooves 33 inside both ends of the sliding mounting bracket 31, a fixing member 34 rotatably mounted inside the adjustment groove 33, and a fixing mechanism 2 slidably connected to the side of the sliding mounting assembly 3 with the slider. The fixing mechanism 2 includes a fixing frame 21 fixedly connected to the cabinet 1, a slide groove 22 inside the fixing frame 21, and evenly distributed fixing holes 23 inside the slide groove 22.
[0058] Specifically, such as Figure 3 - Figure 6As shown, the sliding mounting bracket 31 is slidably connected to the inside of the slide groove 22 at both ends by sliders. The end of the fixing member 34 protruding to the outside of the slider is engaged with the fixing hole 23 to fix the sliding mounting assembly 3. The sliding mounting bracket 31 has sliders at both ends on the side away from the slide rail 32. One end of the fixing member 34 protrudes to the outside of the slider. One end of the fixing member 34 is provided with an elastic element that connects to the inner wall of the adjustment groove 33. The other end of the fixing member 34 protrudes to the outside of the sliding mounting bracket 31 and is used to fix and release the sliding adjustment assembly for longitudinal adjustment. The sliding mounting assembly 3 is engaged with the fixing adjustment mechanism 4 through the slide rail 32. The elastic element at one end of the fixing member 34 and the friction between the sliders at both ends of the sliding mounting bracket 31 and the slide groove 22 are sufficient to fix the sliding mounting assembly 3 on the fixing bracket 21.
[0059] Working principle: The sliders on both sides of the sliding mounting bracket 31 are inserted into the sliding grooves 22 inside the fixed bracket 21, and the sliding mounting component 3 is fixed on the fixed bracket 21 by the cooperation of the fixing member 34 and the fixing hole 23. The elastic element set at one end of the fixing member 34 and the friction between the sliders at both ends of the sliding mounting bracket 31 and the sliding groove 22 are sufficient to fix the sliding mounting component 3 on the fixed bracket 21.
[0060] Then, by pulling the second drive member 484, it causes the second sliding member 481 to drive the second locking block 47 to slide. Then, the fixing adjustment mechanism 4 can be placed on the slide rail 32 of the sliding mounting assembly 3. Then, by releasing the second drive member 484, the second locking block 47 is reset under the action of the third spring 483, and the fixing adjustment mechanism 4 is locked onto the sliding mounting assembly 3 in conjunction with the first locking block 45.
[0061] Next, by pulling a set of limiting components 43 to slide it, the electrical component 5 with a buckle at the bottom can be aligned with the snap-fit block 42 so that the bottom slot of the electrical component 5 is snapped into the snap-fit block 42 and the snap-fit block 42 is secured to achieve initial fixation. The buckle at the bottom of the electrical component 5 is existing technology and will not be described in detail. Then, the limiting components 43 are released to allow it to automatically reset and cooperate with another limiting component 43 to clamp and fix the electrical component 5. At the same time, the adjusting block 432 inside the limiting components 43 can be adjusted according to the thickness of both sides of the electrical component 5. By pulling the adjusting block 432 to slide it inside the mounting frame 431, when the required height of the electrical component 5 is reached, the adjusting block 432 can be released. Under the action of the first spring 434, the adjusting block 432 is driven to reset to limit and further clamp and fix the electrical component 5.
[0062] When it is necessary to disassemble the electrical component 5, the first driving member 441 is pulled and the transmission gear 442 drives the slide rod 443 to move. The slide rod 443 pushes the slide plate 444 towards the first sliding member 435 of the limiting component 43 so that it contacts the first sliding member 435. As the slide plate 444 moves, the first sliding member 435 moves, thereby causing the limiting component 43 to contact and clamp the electrical component 5. At the same time, as the transmission gear 442 rotates, the rotating member 46 drives the first gear set 446 to rotate. The first gear set 446 drives the two sets of sliding top rods 447 to move. The sliding top rods 447 move and press the bottom buckle of the electrical component 5 to retract into the electrical component 5, contacting the buckle connection of the electrical component 5 to the snap-fit block 42. Then the electrical component 5 can be removed for further processing.
[0063] When the position of electrical component 5 needs to be adjusted, the second drive member 484 can be slightly pulled to disengage the second locking block 47 from the slide rail 32. Then, the rotating member 46 inside the first locking block 45 and the second locking block 47 will fit against the corner of the slide rail 32 under the action of the torsion spring. Then, the lateral position of electrical component 5 can be adjusted by moving the fixed adjustment mechanism 4. Then, when the longitudinal position of electrical component 5 needs to be adjusted, the fixed members 34 protruding at both ends of the sliding mounting bracket 31 can be turned to make it rotate. As the fixed members 34 rotate, they will disengage from the fixed holes 23. Then, the longitudinal position of the sliding mounting bracket 31 can be adjusted.
[0064] When the fixed adjustment mechanism 4 needs to be disassembled and replaced, the second drive component 484 is pulled to make it cooperate with the second sliding component 481 to drive the second locking block 47 to disengage from the slide rail 32. Then the fixed adjustment mechanism 4 can be removed for replacement and subsequent processing. The operation is simple, time-saving, labor-saving and easy to disassemble.
[0065] The foregoing has shown and described the basic principles, main features, and advantages of the present invention. Those skilled in the art should understand that the present invention is not limited to the above embodiments. The embodiments and descriptions in the specification are merely illustrative of the principles of the invention. Various changes and modifications can be made to the invention without departing from its spirit and scope, and all such changes and modifications fall within the scope of protection claimed by the present invention. The scope of protection of the present invention is defined by the appended claims and their equivalents.
Claims
1. A power storage control device, comprising a cabinet, characterized in that: The cabinet is equipped with a sliding installation assembly. Several sets of fixed adjustment mechanisms are slidably connected to one side of the sliding installation assembly. The fixed adjustment mechanism includes a mounting part with a protrusion on one side, a clamping part on the side of the mounting part with the protrusion, and a slidingly adjustable buckle part on the other side of the mounting part. The fixing and adjusting mechanism also includes a latching block protruding on one side of the mounting component. The latching assembly includes a first latching block and a second latching block symmetrically arranged on the side of the mounting component away from the latching block, and rotating components symmetrically arranged inside the first latching block and the second latching block. The limiting component is slidably connected to the mounting component, the first latching block is fixedly connected to the mounting component, the second latching block is fixedly connected to the second adjusting component, one end of the rotating component located inside the first latching block is rotatably connected to the mounting component, and one end of the rotating component located inside the second latching block is rotatably connected to the second adjusting component. The clamping part includes two sets of symmetrically arranged limiting components and a first adjusting component disposed at the bottom of the limiting components. The limiting components are used to limit the position of electrical components installed on the mounting part, and the first adjusting component is used to adjust the limiting components to release the limiting of the electrical components. The buckle part includes symmetrically arranged buckle components and a second adjustment component arranged at the bottom of the buckle components. The buckle components are used to snap the fixed adjustment mechanism onto the sliding mounting component. The second adjustment component is used to drive one side of the buckle to disengage from the mounting component, so that the fixed adjustment mechanism can be adjusted laterally along the sliding mounting component and can be disassembled and replaced. The second adjustment component includes a second sliding member slidably installed inside one side of the mounting component. A third fixed rod is symmetrically arranged inside the second sliding member. A third spring is sleeved on the outside of the third fixed rod. A second driving member is fixedly connected to one side of the second sliding member. A buckle is symmetrically arranged inside the second driving member. The second driving member is slidably connected inside the mounting component. One end of the second driving member protrudes to the outside of the mounting component. The third spring is arranged on the third fixed rod on both sides of the second sliding member. The two ends of the third spring are fixedly connected to the second sliding member and the mounting component, respectively.
2. The power storage control device according to claim 1, characterized in that: The limiting component includes a mounting frame and an adjusting block slidably connected inside the mounting frame. A first fixing rod is provided inside the mounting frame, and a first spring is sleeved on the outside of the first fixing rod. A first sliding member is fixedly connected to the bottom of the mounting frame in a symmetrical manner. A second fixing rod is slidably connected inside the first sliding member, and a second spring is sleeved on the outside of the second fixing rod. The mounting frame is slidably connected to the mounting member through the first sliding member. Sliding blocks with an inverted T shape are provided on both sides of the adjusting block. The sliding blocks are slidably connected to the first fixing rod. The first fixing rod and the first spring are symmetrically arranged about the sliding blocks. The second fixing rod is fixedly connected to the mounting member.
3. The power storage control device according to claim 1, characterized in that: The first adjustment component includes a first driving component that is slidably connected to the mounting component. One end of the first driving component is connected to a transmission gear. The bottom outer side of the transmission gear is connected to a slide rod and a transmission component with an elastic element in the middle. The end of the slide rod away from the transmission gear is slidably connected to a slide plate. The end of the transmission component away from the transmission gear is connected to a first gear set. The upper outer side of the first gear set is connected to two sets of L-shaped sliding top rods.
4. The power storage control device according to claim 3, characterized in that: The end of the first driving member away from the transmission gear protrudes to the outside of the mounting member. The transmission gear and the first gear set are rotatably mounted inside the mounting member. The transmission member, the slide rod, and the slide plate are slidably mounted inside the mounting member. The first gear set includes two sets of gears, an upper set and a rotating shaft inside the gears. The upper gear is connected to the sliding push rod, and the lower gear is connected to the transmission member.
5. The power storage control device according to claim 4, characterized in that: The mounting component includes a limiting block inside the sliding groove that is slidably connected to the second drive component, and a third sliding component that is slidably installed inside the sliding groove. The limiting block is used to limit the second sliding component in conjunction with the buckle, so that the second buckle is engaged with the sliding mounting component to fix the fixing adjustment mechanism. The third sliding component is used to reset the second sliding component in conjunction with the buckle, so that when the fixing adjustment mechanism is disassembled, the second sliding component drives the second buckle to reset.
6. The power storage control device according to claim 5, characterized in that: The sliding mounting assembly includes a sliding mounting bracket for engaging and fixing the adjustment mechanism. A slide rail is provided on one side of the sliding mounting bracket, and adjustment grooves are opened inside both ends of the sliding mounting bracket. Fixing members are rotatably installed inside the adjustment grooves. Slider blocks are provided at both ends of the side of the sliding mounting bracket away from the slide rail. One end of the fixing member protrudes to the outside of the slider, and one end of the fixing member is provided with an elastic element that connects to the inner wall of the adjustment groove. The other end of the fixing member protrudes to the outside of the sliding mounting bracket. This is used to fix and release the sliding adjustment assembly for longitudinal adjustment. The sliding mounting assembly engages with the fixing adjustment mechanism through the slide rail.
7. The power storage control device according to claim 6, characterized in that: The sliding mounting assembly has a fixed mechanism slidably connected to one side of the slider. The fixed mechanism includes a fixed frame that is fixedly connected to the cabinet. The fixed frame has a groove inside and evenly distributed fixing holes inside the groove. Both ends of the sliding mounting frame are slidably connected to the groove through the slider. The end of the fixing member that protrudes to the outside of the slider engages with the fixing hole to fix the sliding mounting assembly.