CN114583630A - Wiring groove assembling structure - Google Patents

Abstract

The invention discloses a wiring groove assembling structure which comprises a wall surface wiring groove, a transition wiring groove, an overhead wiring groove and supporting legs, wherein each supporting leg comprises an adjusting rod and a supporting plate arranged on the adjusting rod, one side edge of the top of the wall surface wiring groove is bent to form a first positioning step, one side edge of the top of the transition wiring groove is bent to form a second positioning step, the first positioning step and the second positioning step are both supported on the front side edge of the supporting plate, a transition wiring port is formed in the middle of the second positioning step, the end part of the overhead wiring groove is communicated to the transition wiring port, and the edge of the second positioning step is attached to the front side edge of a clamping plate. The lines in the wall wiring grooves are generally parallel to the wall, the lines in the overhead wiring grooves are generally perpendicular to the wall, and the wall wiring grooves and the overhead wiring grooves are communicated through transition wiring grooves so as to achieve reversing of the lines.

Description

Wiring groove assembling structure

Technical Field

The invention relates to a wiring groove assembling structure, and belongs to the field of wiring groove installation.

Background

The wiring groove of installing in the office area, based on corresponding standard requirement, need form overhead structure, overhead structure's realization form generally divide into two kinds, and one kind is installed the wiring groove on the wall, and another kind is supported the wiring groove through the supporting legs. In order to communicate with other wiring channels, the wiring channel side walls of the wall have to be drilled on site, which results in a heavy work on the finishing site.

Disclosure of Invention

The present invention provides a wiring duct assembly structure to overcome the disadvantages of the prior art.

The technical scheme adopted by the invention is as follows:

a wiring groove assembling structure comprises a wall wiring groove, a transition wiring groove, an overhead wiring groove and supporting legs, wherein the supporting legs comprise an adjusting rod and a supporting plate arranged on the adjusting rod, one side edge of the top of the wall wiring groove is bent to form a first positioning step, one side edge of the top of the transition wiring groove is bent to form a second positioning step, the first positioning step and the second positioning step are both supported on the front side edge of the supporting plate, the first positioning step and the second positioning step are spliced to enable the end part of the wall wiring groove to be communicated with the end part of the transition wiring groove, a transition wiring opening is formed in the middle of the second positioning step, the top edge of the overhead wiring groove is bent to form a clamping groove, the right side edge of the supporting plate extends upwards to form a clamping plate, a gap is reserved between the front side edge of the clamping plate and the front side edge of the supporting plate, the top of the clamping plate is clamped in the clamping groove to enable the end part of the overhead wiring groove to be communicated with the transition wiring opening, the edge of the second positioning step is attached to the front edge of the clamping plate.

The invention has the beneficial effects that:

the line in the wall wiring groove is generally parallel to the wall, the line in the overhead wiring groove is generally perpendicular to the wall, and the wall wiring groove and the overhead wiring groove are communicated through the transition wiring groove to realize the reversing of the line, so that an opening is not needed on the side wall of the wall wiring groove independently, and the workload of a decoration site is reduced. The backup pad supports wall trough and transition trough simultaneously through first location step and second location step, has promoted the stability of wall trough and transition trough on the wall, has also stabilized the concatenation stability of first location step and second location step simultaneously. The overhead wiring duct obtains the support of backup pad through the cardboard top under the action of gravity, and the second location step obtains the location in the backup pad through the bottom edge of cardboard, has formed between simultaneously and the draw-in groove and has dodged to avoid overhead wiring duct to influence the support effect that transition wiring duct obtained in the backup pad.

The invention also comprises a bending plate, wherein the bending plate is used for being fixed on a wall, the edge of the other side of the top of the wall wiring groove is bent to form a third positioning step, the edge of the other side of the top of the transition wiring groove is bent to form a fourth positioning step, the third positioning step and the fourth positioning step are both supported on the bending plate, and the edge of the bending plate is simultaneously attached to the third positioning step and the fourth positioning step.

The left side edge of the supporting plate extends upwards to form a positioning plate, and the front side edge of the positioning plate is propped against the edge of the first positioning step.

Gaps are reserved between the rear side edge of the positioning plate and the rear side edge of the clamping plate and the rear side edge of the supporting plate.

The wall surface wiring groove, the transition wiring groove and the overhead wiring groove are all provided with cover plates, the edges of the cover plates extend downwards to form expansion plates, the cover plates and the expansion plates are enclosed to form expansion grooves, the bottom edges of the expansion plates extend towards the middle of the cover plates to form bottom plates, the bottom plates on the wall surface wiring groove are pressed on the first positioning steps, the bottom plates on the transition wiring groove are pressed on the second positioning steps, and the bottom plates on the overhead wiring groove are pressed on the supporting plates.

The side wall of the expansion groove above the transition wiring groove is provided with an avoiding port, and the avoiding port is communicated to the end part of the expansion groove above the overhead wiring groove.

The edge of the cover plate above the transition wiring duct extends towards the cover plate above the overhead wiring duct to form a baffle plate, and the baffle plate is spliced with the end part of the cover plate above the overhead wiring duct.

The bottom plate is provided with an adjusting groove, the adjusting groove extends along the axial direction of the cover plate, the support plate is provided with four screw holes, the four screw holes are arranged in a rectangular array mode, the adjusting groove is communicated with the corresponding screw holes, and the adjusting groove is provided with a locking screw.

The top angle of the cover plate is provided with a dismounting notch, and the dismounting notch is opposite to the adjusting groove in the direction vertical to the cover plate.

The invention also comprises an overhead plate, wherein the edge of the bottom of the overhead plate is provided with a positioning rod, the positioning rod is pressed on the supporting plate and is attached to the positioning plate, and the supporting plate supports the overhead plate through the positioning rod.

Other features and advantages of the present invention will be disclosed in more detail in the following detailed description of the invention and the accompanying drawings.

Drawings

The invention is further described below with reference to the accompanying drawings:

FIG. 1 is a schematic perspective view of a wiring duct assembly according to an embodiment of the present invention;

FIG. 2 is a schematic view of a partial three-dimensional structure of a wall-surface wiring duct in the embodiment of the present invention;

FIG. 3 is a schematic perspective view of a transition routing groove according to an embodiment of the present invention;

FIG. 4 is a schematic partial perspective view of an overhead raceway in an embodiment of the invention;

FIG. 5 is a schematic perspective view of the wall surface raceway and a cover plate above the overhead raceway in an embodiment of the present invention;

FIG. 6 is a schematic perspective view of a cover plate above a transition routing groove according to an embodiment of the present invention;

FIG. 7 is a schematic perspective view of the wiring duct assembly structure according to the embodiment of the present invention (with the overhead plate hidden);

FIG. 8 is an enlarged view of the structure at A in FIG. 7;

FIG. 9 is an enlarged view of the structure at B in FIG. 7;

FIG. 10 is a schematic perspective view of FIG. 9 with a portion of the cover plate removed;

fig. 11 is a schematic perspective view of a support leg according to an embodiment of the present invention.

Detailed Description

The technical solutions of the embodiments of the present invention are explained and illustrated below with reference to the drawings of the embodiments of the present invention, but the following embodiments are only preferred embodiments of the present invention, and not all embodiments. Based on the embodiments in the implementation, other embodiments obtained by those skilled in the art without any creative effort belong to the protection scope of the present invention.

In the following description, the appearances of the indicating orientation or positional relationship such as the terms "inner", "outer", "upper", "lower", "left", "right", etc. are only for convenience in describing the embodiments and for simplicity in description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and are not to be construed as limiting the present invention.

Example (b):

referring to fig. 1-11, the present embodiment provides a cabling trough assembly structure, including a bending plate 7, an overhead plate 5, a wall cabling trough 1, a transition cabling trough 2, an overhead cabling trough 3, and a supporting leg 4.

The bending plate 7 is fixed on the wall 6.

One side edge of the top of the wall wiring groove 1 is bent to form a first positioning step 11, and the other side edge of the top of the wall wiring groove 1 is bent to form a third positioning step 12.

One side edge of the top of the transition wiring groove 2 is bent to form a second positioning step 21, a transition wiring opening 211 is formed in the middle of the second positioning step 21, and the other side edge of the top of the transition wiring groove 2 is bent to form a fourth positioning step 22.

The edges of two sides of the top of the overhead wiring duct 3 are bent to form clamping grooves 31, and the openings of the clamping grooves 31 face downwards.

The supporting foot 4 comprises an adjusting rod 41 and a supporting plate 42 installed on the adjusting rod 41, the adjusting rod 41 is vertically arranged, the supporting plate 42 is horizontally arranged, and the supporting plate 42 can axially move along the adjusting rod 41 to adjust the vertical height of the supporting plate 42. The right side edge of the supporting plate 42 extends upwards to form a clamping plate 421, the left side edge of the supporting plate 42 extends upwards to form a positioning plate 422, and the clamping plate 421 and the positioning plate 422 are parallel to each other and are both vertical to the supporting plate 42.

Third location step 12 supports on board 7 of bending, leaves the space between the front side reason of cardboard 421 and the front side reason of locating plate 422 all and the front side reason of backup pad 42, so first location step 11 can dodge cardboard 421 and locating plate 422 and support in the front side reason of backup pad 42. The bending plate 7 and the supporting plate 42 are respectively in surface contact with the wall wiring grooves 1 through the third positioning step 12 and the first positioning step 11, so that the wall wiring grooves 1 are supported from two sides of the wall wiring grooves 1 respectively, the wall wiring grooves 1 are kept parallel to the wall 6, and therefore lines in the wall wiring grooves 1 are parallel to the wall 6 on the whole. Because the vertical height of the supporting plate 42 is adjustable, the height of the supporting plate 42 can be matched with the bending plate 7, so that the wall wiring groove 1 is in a horizontal state and forms an overhead structure relative to the ground.

Preferably, the front side edge of the positioning plate 422 abuts against the edge of the first positioning step 11, and the positioning plate 422 positions the first positioning step 11, so as to ensure that the supporting plate 42 has a sufficient supporting area for the first positioning step 11. Meanwhile, the positioning plate 422 also prevents the first positioning step 11 from occupying too much area of the surface of the supporting plate 42, so that the supporting plate 42 still has enough area to support the overhead plate 5 after supporting the first positioning step 11.

Similarly, the fourth positioning step 22 is supported on the bending plate 7, and the second positioning step 21 is also supported on the front side edge of the supporting plate 42, so that the transition wiring groove 2 is kept at the same vertical height with the wall wiring groove 1 under the supporting action of the bending plate 7 and the supporting plate 42, the end of the transition wiring groove 2 and the end of the wall wiring groove 1 can be aligned and communicated, and therefore the line of the wall wiring groove 1 can enter the transition wiring groove 2.

Likewise, the second positioning step 21 may be pressed against the front side edge of the card 421 to position the second positioning step 21 by the card 421.

In order to ensure the communication effect between the wall surface wiring groove 1 and the transition wiring groove 2, the first positioning step 11 is spliced with the second positioning step 21, and the third positioning step 12 is spliced with the fourth positioning step 22, so that the generation of gaps between the wall surface wiring groove 1 and the transition wiring groove 2 is effectively reduced. In addition, the edge of the bending plate 7 is simultaneously attached to the third positioning step 12 and the fourth positioning step 22 in the embodiment, the wall wiring groove 1 and the transition wiring groove 2 are positioned through the bending plate 7, and the splicing effect between the wall wiring groove 1 and the transition wiring groove 2 is ensured.

Overhead trough 3 level setting and keep perpendicular with wall 6, wherein the top joint of cardboard 421 is in draw-in groove 31, because the opening of draw-in groove 31 is down, consequently the top edge of cardboard 421 can support overhead trough 3 steadily under the action of gravity, even the thickness of cardboard 421 slightly is less than draw-in groove 31 width, can not influence the supporting effect of cardboard 421 to overhead trough 3 yet. The supporting plate 42 supports the overhead cabling channel 3 through the clamping plate 421, so that an overhead structure is formed between the overhead cabling channel 3 and the ground. Because transition trough 2 and overhead trough 3 all obtain the support through backup pad 42, consequently transition trough 2 and overhead trough 3 can be at same height to make transition wire walking mouth 211 can communicate to the tip of overhead trough 3, the interior circuit that is parallel with wall 6 of transition trough 2 can buckle and get into overhead trough 3 via transition wire walking mouth 211, realizes the switching-over of circuit and walks the line.

In order to ensure the supporting effect of the overhead cabling channel 3, a plurality of supporting feet 4 can be respectively arranged on two sides of the overhead cabling channel 3, so that the stability of the overhead cabling channel 3 supported by the supporting feet can be improved.

In the embodiment, the reversing wiring under the overhead structure is realized through the transition wiring groove 2, the side wall of the wall wiring groove 1 is prevented from being perforated in a decoration site, and the working strength of the decoration site is reduced.

In addition, it can be known through the foregoing, second location step 21 is because keeping the laminating state with backup pad 42, consequently second location step 21 is located cardboard 421 bottoms with the contact position of cardboard 421 front side edge, and draw-in groove 31 is located the top position of cardboard 421, so there is the effect of dodging each other between draw-in groove 31 and the second location step 21, the supporting role that overhead trough 3 and transition trough 2 received on backup pad 42 can not influence each other, so overhead trough 3 and the installation order of transition trough 2 on backup pad 42 do not have the restriction, consequently overhead trough 3 and the flexibility of transition trough 2 at the on-the-spot assembly are higher.

Preferably, a gap is left between the rear side edge of the positioning plate 422 and the rear side edge of the clamping plate 421 and the rear side edge of the supporting plate 42, so that the material cost of the supporting foot 4 is reduced, and in addition, the structural symmetry of the supporting foot 4 is also increased. For example, in this embodiment, the supporting leg 4 is horizontally rotated by 180 °, so that the overhead wiring duct 3 can be supported by the positioning plate 422 and the second positioning step 21 can be positioned, and the first positioning step 11 can be positioned by the clamping plate 421. It can be seen that the mounting flexibility of the support foot 4 is increased and the assembly error rate is correspondingly reduced.

After the installation of the wall surface wiring groove 1, the transition wiring groove 2 and the overhead wiring groove 3 on the supporting legs 4 is completed, a cover plate 8 needs to be arranged above the wall surface wiring groove 1, the transition wiring groove 2 and the overhead wiring groove 3 for shielding.

The both sides edge of apron 8 all extends downwards and forms flash board 81, and apron 8 and flash board 81 enclose and form the dilatation groove, and the bottom edge of flash board 81 extends towards the centre of apron 8 and forms bottom plate 82. For the cover plate 8 on the wall wiring duct 1, the two bottom plates 82 are respectively pressed on the first positioning step 11 and the third positioning step 12. For the cover plate 8 on the transition cabling channel 2, the two bottom plates 82 press on the fourth positioning step 22 and the second positioning step 21, respectively. The base plate 82 presses against the support plate 42 for the cover plate 8 on the overhead cabling channel 3. Because the height of the cover plate 8 is raised by the expansion plate 81, the wall surface wiring groove 1, the transition wiring groove 2 and the overhead wiring groove 3 can be communicated with the corresponding expansion grooves, so that the wiring space is increased. All of the cover plates 8 are correspondingly supported by the bottom plate 82, so that a veneer can be subsequently installed above the cover plates 8, and the veneer is supported by the cover plates 8.

In particular, the side wall of the expansion slot above the transition routing slot 2 is provided with an avoiding opening 811, and the avoiding opening 811 is communicated to the end part of the expansion slot above the overhead routing slot 3, so that the line in the expansion slot above the transition routing slot 2 can also enter the expansion slot above the overhead routing slot 3, and the routing amount entering the overhead routing slot 3 is prevented from being limited.

The expansion groove end parts above the wall wiring groove 1 and the transition wiring groove 2 are opposite, so that the splicing of the end parts of the cover plates 8 above the wall wiring groove 1 and the transition wiring groove 2 can be better realized, the gap of the splicing part is smaller, and the shielding effect of the joint of the wall wiring groove 1 and the transition wiring groove 2 is better. However, since the end of the expansion slot above the overhead cabling slot 3 is not exactly opposite to the end of the expansion slot above the transition cabling slot 2, but is communicated with the avoidance port 811, and is affected by the expansion plate 81 above the transition cabling slot 2, the splicing effect of the cover plate 8 above the transition cabling slot 2 and the cover plate 8 above the overhead cabling slot 3 is not ideal, and the sealing performance of the spliced part needs to be improved. Therefore, the edge of the cover plate 8 above the transition wiring duct 2, which is located at the avoidance opening 811, extends toward the cover plate 8 above the overhead wiring duct 3 to form a shielding plate 812, and the shielding plate 812 crosses the expansion plate 81 above the transition wiring duct 2 and is spliced with the end of the cover plate 8 above the overhead wiring duct 3, so that the shielding effect above the splicing position of the transition wiring duct 2 and the overhead wiring duct 3 is improved.

Under some special conditions, a very tight splicing effect is not required between the wall surface wiring groove 1 and the cover plate 8 above the transition wiring groove 2, and between the transition wiring groove 2 and the cover plate 8 above the overhead wiring groove 3, but a certain gap can be reserved, so that the requirement on assembly precision is properly reduced.

Based on this, the bottom plate 82 is provided with an adjusting groove 821, the adjusting groove 821 extends along the axial direction of the cover plate 8, and a locking screw is arranged at the adjusting groove 821. Four screw holes 423 are formed in the supporting plate 42, and the four screw holes 423 are arranged in a rectangular array. The adjusting grooves 821 above the wall wiring groove 1 and the transition wiring groove 2 are located on the same horizontal straight line and communicated to two screw holes 423 respectively, the cover plate 8 above the wall wiring groove 1 and the transition wiring groove 2 is locked on the supporting plate 42 through locking screws, the wall wiring groove 1 and the transition wiring groove 2 are also locked on the supporting plate 42 together after the cover plate 8 is locked, the adjusting grooves 821 provide axial adjusting allowance for the cover plate 8 above the wall wiring groove 1 and the transition wiring groove 2, and the adjusting grooves 821 can be kept in a communicated state with the screw holes 423 in the axial moving process of the cover plate 8. The adjusting groove 821 at the overhead cabling groove 3 can be communicated to another screw hole 423, and the cover plate 8 above the overhead cabling groove 3 can be directly locked on the support plate 42 through a locking screw. Although the adjusting groove 821 at the overhead cabling groove 3 is perpendicular to the adjusting grooves 821 at the wall cabling groove 1 and the transition cabling groove 2, the cover plate 8 above the overhead cabling groove 3 can still be in a communication state with the corresponding screw hole 423 during the axial movement process. It follows that the effectiveness of the screw holes 423 in the support plate 42 does not decrease depending on the direction in which the adjustment groove 821 is provided. Meanwhile, the four screw holes 423 arranged in the rectangular array form have high symmetry, so that after the support plate 42 rotates 180 degrees, the cover plate 8 still has a moving margin which is adjusted along the self axial direction.

Preferably, the top corner of the cover plate 8 is opened with a dismounting notch 83, and the dismounting notch 83 is opposite to the adjusting groove 821 in the direction perpendicular to the cover plate 8, so that the locking screw at the corresponding adjusting groove 821 is controlled at the dismounting notch 83.

The bottom edge of overhead board 5 is provided with the locating lever, and the locating lever is pressed in backup pad 42 and is laminated with locating plate 422, fixes a position the locating lever through locating plate 422 to guarantee the mounted position of overhead board 5 in backup pad 42. The backup pad 42 supports the overhead board 5 through the locating lever, and the overhead board 5 has then lifted highly and dodges the locating plate 422 through the locating lever, can match the promotion of dilatation board 81 to 8 heights of apron after the high promotion of overhead board 5 to guarantee that 8 upper surfaces of apron and overhead board 5 upper surface can be in the coplanar, so that the installation of follow-up decorative board.

While the invention has been described with reference to specific embodiments thereof, it will be understood by those skilled in the art that the invention is not limited thereto, and may be embodied in many different forms without departing from the spirit and scope of the invention as set forth in the following claims. Any modification which does not depart from the functional and structural principles of the present invention is intended to be included within the scope of the claims.

Claims (10)

1. A wiring groove assembling structure is characterized by comprising a wall wiring groove, a transition wiring groove, an overhead wiring groove and supporting legs, wherein the supporting legs comprise an adjusting rod and a supporting plate arranged on the adjusting rod, one side edge of the top of the wall wiring groove is bent to form a first positioning step, one side edge of the top of the transition wiring groove is bent to form a second positioning step, the first positioning step and the second positioning step are both supported on the front side edge of the supporting plate, the first positioning step and the second positioning step are spliced to enable the end part of the wall wiring groove to be communicated with the end part of the transition wiring groove, a transition wiring opening is formed in the middle of the second positioning step, the top edge of the overhead wiring groove is bent to form a clamping groove, the right side edge of the supporting plate extends upwards to form a clamping plate, a gap is reserved between the front side edge of the clamping plate and the front side edge of the supporting plate, and the top of the clamping plate is clamped in the clamping groove, so that the end part of the overhead wiring groove is communicated to the transitional wiring port, and the edge of the second positioning step is attached to the front edge of the clamping plate.

2. The wiring duct assembly structure of claim 1, further comprising a bending plate, wherein the bending plate is used for being fixed on a wall, the other side edge of the top of the wall surface wiring duct is bent to form a third positioning step, the other side edge of the top of the transition wiring duct is bent to form a fourth positioning step, the third positioning step and the fourth positioning step are both supported on the bending plate, and the edge of the bending plate is simultaneously attached to the third positioning step and the fourth positioning step.

3. The cabling trough assembly of claim 2, wherein the left side edge of the support plate extends upwardly to form a positioning plate, the front side edge of which abuts the edge of the first positioning step.

4. A raceway assembly according to claim 3, wherein a gap is provided between each of the rear side edges of the locating plate and the clamping plate and the rear side edge of the support plate.

5. A raceway assembly according to claim 3, wherein a cover plate is provided over each of the wall raceway, the transition raceway and the overhead raceway, the edge of the cover plate extends downward to form a capacity expansion plate, the cover plate and the capacity expansion plate enclose to form a capacity expansion groove, the bottom edge of the capacity expansion plate extends toward the middle of the cover plate to form a bottom plate, the bottom plate on the wall raceway presses against the first positioning step, the bottom plate on the transition raceway presses against the second positioning step, and the bottom plate on the overhead raceway presses against the support plate.

6. A raceway assembly structure according to claim 5, wherein the side wall of the expansion groove above the transition raceway groove is provided with an escape opening communicating with an end of the expansion groove above the overhead raceway groove.

7. A raceway assembly according to claim 6 wherein the edge of the cover above the transition raceway at the relief opening extends towards the cover above the overhead raceway to form a shield that is spliced to the end of the cover above the overhead raceway.

8. The assembly structure of wire chase of claim 6, wherein the bottom plate is provided with an adjusting groove extending along the axial direction of the cover plate, the support plate is provided with four screw holes, the four screw holes are arranged in a rectangular array, the adjusting groove is communicated to the corresponding screw hole, and the adjusting groove is provided with a locking screw.

9. The cabling trough assembly structure of claim 7, wherein a mounting and dismounting notch is formed at a top corner of the cover plate, and the mounting and dismounting notch is opposite to the adjusting groove in a direction perpendicular to the cover plate.

10. The cabling trough assembly structure of claim 5, further comprising an overhead plate, wherein the bottom edge of the overhead plate is provided with a positioning rod, the positioning rod is pressed on the support plate and attached to the positioning plate, and the support plate supports the overhead plate through the positioning rod.

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