A decentralized cross-type intelligent internet of things home integration circuit arrangement device
By using a distributed cross-type smart IoT home integrated wiring device, the problems of large space occupation and difficult maintenance in smart home wiring are solved by using combined mounting brackets and cross locking components, achieving efficient space utilization and signal line maintenance.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- 深圳中堃物联网科技有限公司
- Filing Date
- 2023-03-27
- Publication Date
- 2026-06-19
AI Technical Summary
Existing smart home wiring methods take up a lot of space, have low space utilization, and the tangled and intertwined wires shorten the lifespan of signal cables and make maintenance difficult.
The distributed cross-type smart IoT home integrated wiring device utilizes a combination of mounting brackets, connection locking structures, movable wiring structures, and retractable cross-locking components to achieve distributed lead-out and cross-fixing of signal lines, reducing space occupation and improving space utilization.
It effectively reduces signal cable tangling, improves space utilization, avoids shortened lifespan due to cross-squeezing and pulling of signal cables, and facilitates identification and maintenance by maintenance personnel.
Smart Images

Figure CN116093861B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of wiring layout device technology, and specifically to a distributed cross-type smart IoT home integrated wiring layout device. Background Technology
[0002] Most smart home products on the market are combinations of various individual device technologies to form a smart home product. During installation, smart home products require wiring. There are many types of smart home wiring, and various signal lines are interconnected but operate independently. The integrated controller is set in a certain location, and multiple wiring terminals are set together. The other end of the signal line extends to the device user end. The various lines are messy, the installation and wiring are complicated, and the cost is high.
[0003] To organize the wiring at the integrated terminal, current methods typically integrate the ends of multiple signal lines together, then branch each signal line out from different wiring devices, and attach unique signal labels to the ends of the signal lines. This facilitates quick identification of the wiring by maintenance personnel and avoids the problems of messy and complex wiring at the integrated terminal. However, the current technology of integrating the ends of multiple signal lines together and branching them out through multiple wiring devices takes up a lot of space, which is not conducive to the overall layout and installation. Furthermore, due to the position and direction of the signal line ends, two or more signal lines are prone to crossing. The cross-shaped and tangled signal lines at the integrated terminal further expand the space occupied by the integrated terminal, making it difficult for maintenance personnel to identify the type of signal line outside the signal line ends in a timely manner. Moreover, the signal lines at the crossing points are prone to shortening their lifespan due to prolonged compression and pulling.
[0004] Therefore, the existing method of integrating multiple signal line ends together and splitting them through multiple wiring devices occupies a lot of space, with the lines crossing, twisting and overlapping in one place, resulting in low space utilization. It is also inconvenient for maintenance personnel to identify the type of signal line outside the signal line ends in a timely manner, and the signal lines at the crossing points are prone to shortening their lifespan due to long-term compression and pulling. Summary of the Invention
[0005] To address these issues, the present invention provides a distributed cross-type smart IoT home integrated wiring arrangement device, which effectively solves the problems of large space occupation, low space utilization, inconvenience for maintenance personnel to promptly identify the type of signal line outside the signal line end, and the fact that long-term compression and pulling of signal lines at the cross-section can shorten the service life of the signal lines.
[0006] To solve the above-mentioned technical problems, the present invention specifically provides the following technical solution: a distributed cross-type smart IoT home integrated wiring device, installed in an installation compartment inside a wall, comprising:
[0007] A modular mounting bracket is installed inside the mounting compartment. The modular mounting bracket includes an exit support frame and an inlet support frame. The inlet support frame is used to insert the incoming signal line, and the exit support frame is used to insert the equipment signal return line.
[0008] A connecting locking structure is provided between the exit support frame and the inlet support frame. The exit support frame is rotatably mounted on the inlet support frame through the connecting locking structure. The connecting locking structure is used to adjust the connection state between the exit support frame and the inlet support frame, as well as to adjust the distance between the exit support frame and the inlet support frame.
[0009] A movable cabling structure is rotatably mounted on the outgoing support frame and the incoming support frame. The movable cabling structure is used to fix the ends of the incoming signal line and the equipment signal return line and lead them out or in in a dispersed manner, and to pull the incoming signal line and the equipment signal return line into a straight state.
[0010] A retractable cross locking member is provided on the exit support frame and the inlet support frame. The retractable cross locking member forms a cross arrangement area on the exit support frame and the inlet support frame. The retractable cross locking member fixes the incoming signal line and the equipment signal return line that cross during the lead-out or lead-in process in pairs in the cross arrangement area.
[0011] Furthermore, the movable cabling structure includes a mounting plate rotatably disposed on the side of the outgoing support frame and the incoming support frame, a mounting slot disposed on the mounting plate, a positioning slot slidably disposed on the mounting slot, a slider disposed at the bottom of the positioning slot, and a sliding groove disposed in the mounting slot.
[0012] The angle between the mounting slot and the center line of the mounting plate gradually increases as the distance from the center of the mounting plate increases. The slider is slidably disposed in the sliding groove. A connecting spring is provided at the end of the slider. The end of the connecting spring away from the slider is connected to the sliding groove.
[0013] Furthermore, a positioning bottom buckle is provided on the positioning slot seat, and a positioning top buckle is rotatably provided on the positioning bottom buckle. The incoming signal line and the equipment signal return line are fixed between the positioning bottom buckle and the positioning top buckle.
[0014] A first torsion spring is provided at the rotatable connection between the positioning bottom buckle and the positioning top buckle. A lock buckle is provided at the end of the positioning top buckle, and a buckle groove is provided at the end of the positioning bottom buckle. A pressing seat is movably provided in the buckle groove. The pressing seat is connected to the inside of the buckle groove through the first spring. A locking groove is provided inside the pressing seat, and the lock buckle is engaged in the locking groove.
[0015] Both the bottom positioning buckle and the top positioning buckle are provided with a friction inner layer, which is in contact with the incoming signal line and the equipment signal return line.
[0016] Furthermore, the retractable cross locking member includes a first locking cylinder disposed on the mounting plate and a second locking cylinder movably mounted on the first locking cylinder;
[0017] The bottom of the first locking cylinder is provided with a mounting plate, and the mounting plate is mounted on the mounting plate by a first bolt. The incoming signal line and the equipment signal return line pass through the first locking cylinder and the second locking cylinder.
[0018] Furthermore, a first adjusting disc is provided at the top of the first locking cylinder, and a second adjusting disc is provided at the bottom of the second locking cylinder;
[0019] The first adjusting disc has a circular groove, and the second adjusting disc is rotatably disposed in the circular groove. The first adjusting disc is provided with a positioning bolt, and the second adjusting disc has threaded holes arranged at equal intervals along a circular trajectory. The positioning bolt is connected to the threaded holes.
[0020] Furthermore, a connecting notch is provided on the second locking cylinder near the second adjusting disc, a first folding shaft is rotatably disposed within the connecting notch, a second folding shaft is rotatably disposed on the first folding shaft, and the end of the second folding shaft is rotatably mounted on the second adjusting disc;
[0021] A second torsion spring is provided at the rotatable connection between the first folding shaft and the second folding shaft, and a folding groove is provided inside the first folding shaft for folding and storing the second folding shaft.
[0022] Furthermore, a connecting frame is provided at the bottom of the first adjusting disc, and an adjusting bolt is rotatably provided on the connecting frame. A first connecting cylinder is threadedly connected to the adjusting bolt. A connecting groove is provided on the first adjusting disc and the second adjusting disc along the circular track. The first connecting cylinder passes through the connecting groove, and a second connecting cylinder is provided through the remaining connecting grooves. The first connecting cylinder and the second connecting cylinder are connected by a connecting ring.
[0023] The first connecting cylinder or one of the second connecting cylinders abuts against the second folding shaft.
[0024] Furthermore, both the outgoing support frame and the incoming support frame are provided with integrated holes for the incoming signal line and the equipment signal return line to pass through.
[0025] Furthermore, the connection locking structure includes a first connecting frame disposed on the in-mount support frame, a second connecting frame disposed on the out-mount support frame, and a third connecting frame movably connected to the end of the second connecting frame;
[0026] The first connecting frame and the third connecting frame are rotatably connected.
[0027] Furthermore, a telescopic shaft is provided between the third connecting frame and the second connecting frame, a movable groove is provided at the top of the third connecting frame, a threaded cylinder is provided in the movable groove, and a rotating screw is provided at the bottom of the second connecting frame, with the end of the rotating screw threadedly connected to the threaded cylinder.
[0028] The rotating screw is mounted through the second connecting frame, and an adjustment knob is provided at the end of the rotating screw.
[0029] Compared with the prior art, the present invention has the following advantages:
[0030] This invention uses a movable wiring structure to fix the ends of the incoming signal line and the equipment signal return line, and leads them out or in in a dispersed manner. Pulling the incoming signal line and the equipment signal return line straightens them, reducing the space occupied by the incoming signal line and the equipment signal return line during the introduction and introduction process. Furthermore, a retractable cross locking component is used to fix the incoming signal line and the equipment signal return line that cross during the introduction or introduction process in pairs within the cross arrangement area, avoiding multiple line crossings, dispersing the crossing positions, further reducing the space occupied, improving space utilization, and avoiding the situation where long-term compression and pulling of signal lines at multiple crossing points can shorten the service life of the signal lines. Attached Figure Description
[0031] To more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are merely exemplary, and those skilled in the art can derive other embodiments based on the provided drawings without creative effort.
[0032] Figure 1 This is a schematic diagram of a distributed cross-type smart IoT home integrated wiring layout device provided in an embodiment of the present invention;
[0033] Figure 2 This is a top view of the embedded support frame in an embodiment of the present invention.
[0034] Figure 3 This is a schematic diagram of the side portion structure of the embedded support frame in an embodiment of the present invention;
[0035] Figure 4 This is a schematic diagram of the mounting slot in an embodiment of the present invention;
[0036] Figure 5 This is a schematic diagram of the positioning bottom buckle and the positioning bottom buckle fastening state in an embodiment of the present invention;
[0037] Figure 6 This is a schematic diagram of the positioning bottom buckle and the positioning bottom buckle in the open state in an embodiment of the present invention;
[0038] Figure 7 This is a schematic diagram of the positioning bottom buckle and the rotating connection of the positioning bottom buckle in an embodiment of the present invention;
[0039] Figure 8 This is a top view of the retractable cross locking member in an embodiment of the present invention;
[0040] Figure 9 This is a schematic diagram of the folded state of the retractable cross locking member in an embodiment of the present invention;
[0041] Figure 10 This is a structural schematic diagram of the retractable cross locking member in the unfolded state in an embodiment of the present invention;
[0042] Figure 11 This is a schematic diagram of the rotatable connection between the first folding shaft and the second folding shaft in an embodiment of the present invention;
[0043] Figure 12 This is a schematic diagram of the bottom structure of the first adjusting disk in an embodiment of the present invention;
[0044] Figure 13 This is a schematic diagram of the top structure of the second adjusting disk in an embodiment of the present invention.
[0045] The labels in the diagram represent the following:
[0046] 1-Modular mounting bracket; 2-Connection locking structure; 3-Modible wiring structure; 4-Retractable cross locking element; 5-Mounting compartment; 6-Incoming signal line; 7-Equipment signal return line; 8-Cross-layout area;
[0047] 11-Outward support frame; 12-Inward support frame; 13-Integrated hole;
[0048] 21-First connecting frame; 22-Second connecting frame; 23-Third connecting frame; 24-Telescopic shaft; 25-Modible groove; 26-Threaded cylinder rod; 27-Rotating screw; 28-Adjusting knob;
[0049] 31-Mounting plate; 32-Mounting slot; 33-Positioning slot; 34-Slider; 35-Sliding groove; 36-Connecting spring; 37-Positioning bottom buckle; 38-Positioning top buckle; 39-First torsion spring; 310-Lock; 311-Snap groove; 312-Pressing seat; 313-First spring; 314-Locking groove;
[0050] 41-First locking cylinder; 42-Second locking cylinder; 43-Mounting plate; 44-First bolt; 45-First adjusting disc; 46-Second adjusting disc; 47-Circular groove; 48-Positioning bolt; 49-Threaded hole; 410-Connecting notch; 411-First folding shaft; 412-Second folding shaft; 413-Second torsion spring; 414-Folding groove; 415-Connecting bracket; 416-Adjusting bolt; 417-First connecting cylinder; 418-Connecting groove; 419-Second connecting cylinder; 420-Connecting ring. Detailed Implementation
[0051] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.
[0052] like Figure 1 and Figure 2 As shown, the present invention provides a distributed cross-type smart IoT home integrated wiring device, which is installed in an installation compartment inside the wall and mainly includes a combined installation bracket 1, a connection locking structure 2, a movable wiring structure 3, and a retractable cross locking component 4.
[0053] The modular mounting bracket 1 is installed inside the mounting compartment 5. The modular mounting bracket 1 has an outward support frame 11 and an inward support frame 12. The inward support frame 11 is used to insert the incoming signal line 6, and the outward support frame 12 is used to insert the equipment signal return line 7.
[0054] The connecting locking structure 2 is disposed between the exit support frame 11 and the inlet support frame 12. The exit support frame 11 is rotatably mounted on the inlet support frame 12 through the connecting locking structure 2. The connecting locking structure 2 is used to adjust the connection state between the exit support frame 11 and the inlet support frame 12, as well as to adjust the distance between the exit support frame 11 and the inlet support frame 12.
[0055] The movable cabling structure 3 is rotatably mounted on the outgoing support frame 11 and the incoming support frame 12. The movable cabling structure 3 is used to fix the ends of the incoming signal line 6 and the equipment signal return line 7 and lead them out or in in a dispersed manner, as well as to pull the incoming signal line 6 and the equipment signal return line 7 into a straight state.
[0056] The retractable cross locking member 4 is installed on the exit support frame 11 and the inlet support frame 12. The retractable cross locking member 4 forms a cross arrangement area 8 on the exit support frame 11 and the inlet support frame 12. The retractable cross locking member 4 fixes the incoming signal line 6 and the equipment signal return line 7 that cross during the lead-out or lead-in process in pairs in the cross arrangement area 8.
[0057] In this embodiment of the invention, the ends of the incoming signal line 6 and the equipment signal return line 7 are fixed by the movable wiring structure 3 and led out or introduced in a dispersed manner. Pulling the incoming signal line 6 and the equipment signal return line 7 straightens them, reducing the space occupied by the incoming signal line 6 and the equipment signal return line 7 during the introduction and introduction process. The retractable cross locking member 4 fixes the incoming signal line 6 and the equipment signal return line 7 that cross during the introduction or introduction process in pairs within the cross arrangement area 8, avoiding multiple line crossings, dispersing the crossing positions, further reducing the space occupied, improving space utilization, and avoiding the situation where the signal lines at multiple crossing points are easily shortened by long-term compression and pulling.
[0058] The movable cabling structure 3 of the present invention fixes the ends of the incoming signal line 6 and the equipment signal return line 7 and leads them out or in in a dispersed manner, and pulls the incoming signal line 6 and the equipment signal return line 7 to a straight state. The movable cabling structure 3 of the present invention adopts the following preferred embodiments, such as... Figure 1 , Figure 2 , Figure 3 and Figure 4 As shown, the movable wiring structure 3 includes a mounting plate 31 rotatably disposed on the side of the exit support frame 11 and the inlet support frame 12, a mounting slot 32 disposed on the mounting plate 31, a positioning slot 33 slidably disposed on the mounting slot 32, a slider 34 disposed at the bottom of the positioning slot 33, and a sliding groove 35 disposed in the mounting slot 32; the angle between the mounting slot 32, which is away from the middle position on the mounting plate 31, and the center line of the mounting plate 31 gradually increases; the slider 34 is slidably disposed in the sliding groove 35; a connecting spring 36 is provided at the end of the slider 34; the end of the connecting spring 36 away from the slider 34 is connected to the sliding groove 35.
[0059] In the above embodiment, the mounting plate 31 is rotatable and adjustable. During the initial line installation process, the mounting plate 31 can be adjusted to a vertical state. After the line installation is completed, the mounting plate 31 can be adjusted to a horizontal state. Since the angle between the mounting slot 32, which is far from the middle position on the mounting plate 31, and the center line of the mounting plate 31 gradually increases, different lines are distributed outward in a divergent manner after passing through the mounting slot 32 and the positioning slot 33, which further avoids the crossing and misalignment between the lines.
[0060] To secure the incoming signal line 6 and the equipment signal return line 7, the present invention also includes the following design features, such as... Figure 5 , Figure 6 and Figure 7 As shown, a positioning bottom buckle 37 is provided on the positioning slot seat 33, and a positioning top buckle 38 is rotatably provided on the positioning bottom buckle 37. The incoming signal line 6 and the equipment signal return line 7 are fixed between the positioning bottom buckle 37 and the positioning top buckle 38. A first torsion spring 39 is provided at the rotatable connection between the positioning bottom buckle 37 and the positioning top buckle 38. A latch 310 is provided at the end of the positioning top buckle 38. A latch groove 311 is provided at the end of the positioning bottom buckle 37. A pressing seat 312 is movably provided in the latch groove 311. The pressing seat 312 is connected to the inside of the latch groove 311 through the first spring 313. A locking groove 314 is provided inside the pressing seat 312, and the latch 310 is engaged in the locking groove 314. A friction inner layer is provided inside both the positioning bottom buckle 37 and the positioning top buckle 38. The friction inner layer is in contact with the incoming signal line 6 and the equipment signal return line 7.
[0061] In the above embodiment, the positioning bottom buckle 37 and positioning top buckle 38 are initially in the open state. The incoming signal line 6 or the equipment signal return line 7 is placed in the positioning bottom buckle 37, and the positioning top buckle 38 is snapped inward. Under the action of the locking buckle 310, the pressing seat 312 gradually moves inward, squeezing the first spring 313. The locking buckle 310 then engages in the locking groove 314, thus fixing the incoming signal line 6 or the equipment signal return line 7. To remove the incoming signal line 6 and the equipment signal return line 7, the pressing seat 312 needs to be pressed inward. At this time, the locking buckle 310 is not engaged by the locking groove 314. Under the action of the first torsion spring 39, the positioning top buckle 38 is subjected to an upward force. Under the upward force, the locking buckle 310 disengages from the locking groove 314, and the positioning top buckle 38 returns to its initial position.
[0062] In addition, when the mounting plate 31 is adjusted to the vertical position, the incoming signal line 6 and the equipment signal return line 7 are fixed. During the process of rotating the mounting plate 31 to the horizontal position, the fixed positions of the incoming signal line 6 and the equipment signal return line 7 are adjustable. The distance between the incoming signal line 6 and the equipment signal return line 7 from the starting end to the fixed end gradually increases. Under the action of the connecting spring 36, the incoming signal line 6 and the equipment signal return line 7 are gradually pulled, so that the incoming signal line 6 and the equipment signal return line 7 are straightened. During the above process, the slider 34 slides in the sliding groove 35, and the connecting spring 36 is stretched. When the mounting plate 31 is adjusted to the vertical position, under the action of the connecting spring 36, the slider 34 can be reset, driving the positioning groove seat 33, the incoming signal line 6 and the equipment signal return line 7 to reset to the initial state, from the straightened state to the relaxed state.
[0063] In this invention, the retractable cross-locking component 4 secures the incoming signal line 6 and the equipment signal return line 7, which cross during the lead-out or lead-in process, in pairs within the cross-arrangement area 8. The retractable cross-locking component 4 of this invention adopts the following preferred embodiments, such as... Figure 8 , Figure 9 and Figure 10 As shown, the retractable cross locking member 4 includes a first locking cylinder 41 disposed on the mounting plate 31 and a second locking cylinder 42 movably mounted on the first locking cylinder 41; a mounting plate 43 is disposed at the bottom of the first locking cylinder 41, and the mounting plate 43 is mounted on the mounting plate 31 by a first bolt 44, and the incoming signal line 6 and the equipment signal return line 7 pass through the first locking cylinder 41 and the second locking cylinder 42.
[0064] There are two intersecting incoming signal lines 6, one of which passes through the first locking cylinder 41 and the other passes through the second locking cylinder 42. The equipment signal return line 7 is the same as the incoming signal line 6.
[0065] The first bolt 44 is used to fix the first locking cylinder 41. In addition, to adjust and fix the intersection angle between the first locking cylinder 41 and the second locking cylinder 42, the present invention also includes the following design: Figure 8 , Figure 9 and Figure 12 As shown, a first adjusting disc 45 is provided at the top of the first locking cylinder 41, and a second adjusting disc 46 is provided at the bottom of the second locking cylinder 42; a circular groove 47 is provided inside the first adjusting disc 45, and the second adjusting disc 46 is rotatably disposed in the circular groove 47; a positioning bolt 48 is provided on the first adjusting disc 45, and threaded holes 49 are provided at equal intervals along a circular trajectory inside the second adjusting disc 46, and the positioning bolt 48 is correspondingly connected to the threaded holes 49.
[0066] In the above embodiment, the second adjusting disc 46 is rotated to select a suitable threaded hole 49, and the positioning bolt 48 is installed into the threaded hole 49 to realize the installation of the positioning bolt 48 and the fixation between the first adjusting disc 45 and the second adjusting disc 46.
[0067] Since not every pair of incoming signal lines 6 and every pair of equipment signal return lines 7 intersect, the incoming signal lines 6 and equipment signal return lines 7 that do not intersect do not need to be fixed during their outward extension. To avoid the corresponding second locking cylinder 42 occupying more space, the present invention also incorporates the following design, such as... Figure 9 , Figure 10 and Figure 11 As shown, a connecting notch 410 is provided on the second locking cylinder 42 near the second adjusting disc 46. A first folding shaft 411 is rotatably disposed within the connecting notch 410. A second folding shaft 412 is rotatably disposed on the first folding shaft 411. The end of the second folding shaft 412 is rotatably mounted on the second adjusting disc 46. A second torsion spring 413 is provided at the rotatable connection between the first folding shaft 411 and the second folding shaft 412. A folding groove 414 is provided inside the first folding shaft 411 for folding and storing the second folding shaft 412.
[0068] In the above embodiment, the first folding shaft 411 and the second folding shaft 412 are rotatable. When the first folding shaft 411 and the second folding shaft 412 are folded, the second locking cylinder 42 moves down, so that the first locking cylinder 41 is directly opposite the connecting notch 410. At this time, the horizontal position of the second locking cylinder 42 coincides with the first locking cylinder 41, reducing the corresponding space occupied.
[0069] Under the action of the second torsion spring 413, the first folding shaft 411 and the second folding shaft 412 are normally in a folded state. In order to adjust the first folding shaft 411 and the second folding shaft 412 to an extended state when the second locking cylinder 42 is in use, the present invention also makes the following design, such as... Figure 9 , Figure 10 , Figure 12 and Figure 13 As shown, a connecting frame 415 is provided at the bottom of the first adjusting disc 45, and an adjusting bolt 416 is rotatably provided on the connecting frame 415. A first connecting cylinder 417 is threadedly connected to the adjusting bolt 416. A connecting groove 418 is provided on the first adjusting disc 45 and the second adjusting disc 46 along the circular track. The first connecting cylinder 417 passes through the connecting groove 418, and a second connecting cylinder 419 is provided through the remaining connecting grooves 418. The first connecting cylinder 417 and the second connecting cylinder 419 are connected by a connecting ring 420. The first connecting cylinder 417 or one of the second connecting cylinders 419 abuts against the second folding shaft 412.
[0070] The adjustment process for the folding state of the first locking cylinder 41 and the second locking cylinder 42 is as follows: Rotate the adjusting bolt 416. Under the rotation of the adjusting bolt 416, the first connecting cylinder 417 gradually moves upward, and drives the second connecting cylinder 419 to move upward together through the connecting ring 420. Since the first connecting cylinder 417 or one of the second connecting cylinders 419 can definitely abut against the second folding shaft 412 after the rotation adjustment between the first adjusting disc 45 and the second adjusting disc 46, the first connecting cylinder 417 and the second connecting cylinder 419 drive the second folding shaft 412 to rotate during the upward movement. Gradually, the second folding shaft 412 and the first folding shaft 411 rotate to a vertical state. During this process, the second locking cylinder 42 is driven to move upward to a certain height, and the first locking cylinder 41 disengages from the connecting notch 410. The incoming signal line 6 and the equipment signal return line 7 can pass through the second locking cylinder 42.
[0071] In addition, the incoming signal line 6 and the equipment signal return line 7 are usually bundled in multiple strands at the integration end. In order to facilitate subsequent distributed lead-out, both the outgoing support frame 11 and the incoming support frame 12 are provided with integration holes 13 for the incoming signal line 6 and the equipment signal return line 7 to pass through.
[0072] In this invention, the connecting locking structure 2 adjusts the connection state between the exit support frame 11 and the inlet support frame 12, and adjusts the distance between the exit support frame 11 and the inlet support frame 12, such as... Figure 1 As shown, the connection locking structure 2 includes a first connecting frame 21 disposed on the inlet support frame 12, a second connecting frame 22 disposed on the outlet support frame 11, and a third connecting frame 23 movably connected to the end of the second connecting frame 22; the first connecting frame 21 and the third connecting frame 23 are rotatably connected.
[0073] In the above embodiments, the third connecting frame 23 is movably connected, and the corresponding outward support frame 11 and inward support frame 12 are rotatably connected and parallel to each other, so that the distance between them can be adjusted to reduce the corresponding space occupied. In addition, in order to avoid blocking the mounting plate 31, the rotatable connection of the first connecting frame 21 and the third connecting frame 23 is on the side of the rotatable connection of the mounting plate 31.
[0074] To adjust the distance between the outgoing support frame 11 and the incoming support frame 12, the present invention also includes the following design: a telescopic shaft 24 is provided between the third connecting frame 23 and the second connecting frame 22; a movable groove 25 is provided at the top of the third connecting frame 23; a threaded cylindrical rod 26 is provided in the movable groove 25; a rotating screw 27 is provided at the bottom of the second connecting frame 22; the end of the rotating screw 27 is threadedly connected to the threaded cylindrical rod 26; the rotating screw 27 is provided through the second connecting frame 22; and an adjusting knob 28 is provided at the end of the rotating screw 27.
[0075] In the above embodiment, rotating the adjustment knob 28 drives the rotating screw 27 to rotate. Under the rotation of the rotating screw 27, the threaded cylinder 26 gradually approaches the rotating screw 27. Since the threaded cylinder 26 is fixed during the adjustment process, the rotating screw 27 will gradually move down and approach the threaded cylinder 26, causing the second connecting frame 22 to gradually approach the third connecting frame 23, so that the outgoing support frame 11 descends and the distance between the outgoing support frame 11 and the incoming support frame 12 becomes smaller.
[0076] In summary, the main implementation process of this invention is as follows:
[0077] Insert the incoming signal line 6 into the integrated hole 13, adjust the mounting plate 31 to a vertical position, and place it in the positioning bottom buckle 37 in sequence from different directions. Then, snap the positioning top buckle 38 inward. Under the action of the latch 310, the pressing seat 312 gradually moves inward, squeezing the first spring 313. The latch 310 then engages in the locking groove 314, thus fixing the incoming signal line 6.
[0078] Rotate the mounting plate 31 to a horizontal position, and the fixed position of the incoming signal line 6 will be gradually pulled, so that the incoming signal line 6 is straightened. Then, pass the incoming signal line 6 through the first locking cylinder 41 and extend it outward.
[0079] Find the incoming signal line 6 that intersects with the corresponding incoming signal line 6. Assuming that one exists, rotate the corresponding second locking cylinder 42 to a suitable angle, select a suitable threaded hole 49, and install the positioning bolt 48 into the threaded hole 49 to achieve the installation of the positioning bolt 48 and the fixation between the first adjusting disc 45 and the second adjusting disc 46. Rotate the adjusting bolt 416. Under the rotation of the adjusting bolt 416, the first connecting cylinder 417 and the second connecting cylinder 419 move upward together. During the upward movement of the first connecting cylinder 417 and the second connecting cylinder 419, the second folding shaft 412 is driven to rotate, and the second folding shaft 412 and the first folding shaft 411 are gradually driven to rotate to a vertical state. During this process, the second locking cylinder 42 is driven to move upward to a certain height, and the first locking cylinder 41 disengages from the connecting notch 410. Another incoming signal line 6 that intersects with the first locking cylinder 42 passes through the second locking cylinder 42 to fix the intersection position of the two incoming signal lines 6, and then extends out for arrangement.
[0080] Afterwards, the equipment signal return line 7 uses the same return integrated hole 13. During the arrangement of the equipment signal return line 7, the output support frame 11 and the input support frame 12 are almost 180° apart. After the line arrangement is completed, rotate the output support frame 11 to be parallel to the input support frame 12.
[0081] Rotating the adjustment knob 28 causes the rotating screw 27 to rotate, and the threaded cylinder 26 gradually approaches the rotating screw 27, causing the second connecting frame 22 to gradually approach the third connecting frame 23, which causes the exit support frame 11 to descend, and the distance between the exit support frame 11 and the inlet support frame 12 to decrease, thereby reducing the distance between the exit support frame 11 and the inlet support frame 12 and the space occupied.
[0082] The above embodiments are merely exemplary embodiments of this application and are not intended to limit this application. The scope of protection of this application is defined by the claims. Those skilled in the art can make various modifications or equivalent substitutions to this application within its substance and scope of protection, and such modifications or equivalent substitutions should also be considered to fall within the scope of protection of this application.
Claims
1. A distributed cross-type smart internet of things home integrated wiring arrangement device installed in a mounting cabin in a wall, characterized in that, have: A modular mounting bracket (1) is installed inside the mounting compartment (5). The modular mounting bracket (1) has an outward support frame (11) and an inward support frame (12). The inward support frame (11) is used to insert the incoming signal line (6), and the outward support frame (12) is used to insert the equipment signal return line (7). A connecting locking structure (2) is provided between the exit support frame (11) and the inlet support frame (12). The exit support frame (11) is rotatably mounted on the inlet support frame (12) through the connecting locking structure (2). The connecting locking structure (2) is used to adjust the connection state between the exit support frame (11) and the inlet support frame (12), and to adjust the distance between the exit support frame (11) and the inlet support frame (12). The movable wiring structure (3) is rotatably mounted on the outgoing support frame (11) and the incoming support frame (12). The movable wiring structure (3) is used to fix the ends of the incoming signal line (6) and the equipment signal return line (7) and lead them out or in in a dispersed manner, and to pull the incoming signal line (6) and the equipment signal return line (7) into a straight state. A retractable cross locking member (4) is provided on the exit support frame (11) and the inlet support frame (12). The retractable cross locking member (4) forms a cross arrangement area (8) on the exit support frame (11) and the inlet support frame (12). The retractable cross locking member (4) fixes the incoming signal line (6) and the equipment signal return line (7) that cross during the lead-out or lead-in process in pairs in the cross arrangement area (8).
2. The device as claimed in claim 1, wherein the device is a decentralized cross-type intelligent Internet of Things (IoT) home integration circuit arrangement device. The movable wiring structure (3) includes a mounting plate (31) rotatably disposed on the side of the outgoing support frame (11) and the incoming support frame (12), a mounting slot (32) disposed on the mounting plate (31), a positioning slot (33) slidably disposed on the mounting slot (32), a slider (34) disposed at the bottom of the positioning slot (33), and a sliding groove (35) disposed in the mounting slot (32); The angle between the mounting slot (32) located away from the center position on the mounting plate (31) and the center line of the mounting plate (31) gradually increases. The slider (34) is slidably disposed in the sliding groove (35). A connecting spring (36) is provided at the end of the slider (34). The end of the connecting spring (36) away from the slider (34) is connected to the sliding groove (35).
3. The device according to claim 2, wherein, The positioning slot (33) is provided with a positioning bottom buckle (37), and a positioning top buckle (38) is rotatably provided on the positioning bottom buckle (37). The incoming signal line (6) and the equipment signal return line (7) are fixed between the positioning bottom buckle (37) and the positioning top buckle (38). A first torsion spring (39) is provided at the rotatable connection between the positioning bottom buckle (37) and the positioning top buckle (38). A lock buckle (310) is provided at the end of the positioning top buckle (38). A buckle groove (311) is provided at the end of the positioning bottom buckle (37). A pressing seat (312) is movably provided in the buckle groove (311). The pressing seat (312) is connected to the inside of the buckle groove (311) through a first spring (313). A locking groove (314) is provided inside the pressing seat (312). The lock buckle (310) is engaged in the locking groove (314). Both the positioning bottom buckle (37) and the positioning top buckle (38) are provided with a friction inner layer, which is in contact with the incoming signal line (6) and the equipment signal return line (7).
4. The device according to claim 3, wherein, The retractable cross locking member (4) includes a first locking cylinder (41) disposed on the mounting plate (31) and a second locking cylinder (42) movably mounted on the first locking cylinder (41); The first locking cylinder (41) is provided with a mounting plate (43) at its bottom, and the mounting plate (43) is mounted on the mounting plate (31) by a first bolt (44). The incoming signal line (6) and the equipment signal return line (7) pass through the first locking cylinder (41) and the second locking cylinder (42).
5. The device according to claim 4, wherein, The first locking cylinder (41) is provided with a first adjusting disc (45) at its top, and the second locking cylinder (42) is provided with a second adjusting disc (46) at its bottom; The first adjusting disc (45) is provided with a circular groove (47), and the second adjusting disc (46) is rotatably disposed in the circular groove (47). The first adjusting disc (45) is provided with a positioning bolt (48), and the second adjusting disc (46) is provided with threaded holes (49) at equal intervals along a circular trajectory. The positioning bolt (48) is connected to the threaded hole (49).
6. The device according to claim 5, wherein, A connecting notch (410) is provided on the second locking cylinder (42) near the second adjusting disc (46). A first folding shaft (411) is rotatably disposed in the connecting notch (410). A second folding shaft (412) is rotatably disposed on the first folding shaft (411). The end of the second folding shaft (412) is rotatably mounted on the second adjusting disc (46). A second torsion spring (413) is provided at the rotatable connection between the first folding shaft (411) and the second folding shaft (412), and a folding groove (414) is provided in the first folding shaft (411) for the second folding shaft (412) to be folded and stored.
7. The device according to claim 6, wherein, The first adjusting disc (45) is provided with a connecting frame (415) at its bottom. An adjusting bolt (416) is rotatably provided on the connecting frame (415). A first connecting cylinder (417) is threadedly connected to the adjusting bolt (416). A connecting groove (418) is provided on the first adjusting disc (45) and the second adjusting disc (46) along a circular track. The first connecting cylinder (417) passes through the connecting groove (418). A second connecting cylinder (419) is provided through the remaining connecting grooves (418). The first connecting cylinder (417) and the second connecting cylinder (419) are connected by a connecting ring (420). The first connecting cylinder (417) or one of the second connecting cylinders (419) abuts against the second folding shaft (412).
8. The distributed cross-type smart IoT home integrated wiring layout device according to claim 7, characterized in that, Both the outgoing support frame (11) and the incoming support frame (12) are provided with integrated holes (13) for the incoming signal line (6) and the equipment signal return line (7) to pass through.
9. The device according to claim 8, wherein, The connection locking structure (2) includes a first connecting frame (21) disposed on the in-type support frame (12), a second connecting frame (22) disposed on the out-type support frame (11), and a third connecting frame (23) movably connected to the end of the second connecting frame (22); The first connecting frame (21) and the third connecting frame (23) are rotatably connected.
10. The device according to claim 9, wherein the device is a distributed cross-type intelligent Internet of Things (IoT) home integration circuit arrangement device. A telescopic shaft (24) is provided between the third connecting frame (23) and the second connecting frame (22). A movable groove (25) is provided at the top of the third connecting frame (23). A threaded cylinder rod (26) is provided in the movable groove (25). A rotating screw (27) is provided at the bottom of the second connecting frame (22). The end of the rotating screw (27) is threaded into the threaded cylinder rod (26). The rotating screw (27) is disposed through the second connecting frame (22), and an adjustment knob (28) is provided at the end of the rotating screw (27).