CN220701852U - Glass running assembly - Google Patents

Abstract

The application relates to a glass running assembly, comprising: the side plate structure comprises a first side plate structure and a second side plate structure, the first side plate structure comprises a first long hole and a second long hole, and the second side plate structure is provided with a third long hole and a fourth long hole; the first end of the lower support rod structure is connected with the first side plate structure, and the second end of the lower support rod structure is connected with the second side plate structure; the upper supporting rod structure comprises a first upper supporting rod structure and a second upper supporting rod structure, the first end of the first upper supporting rod structure is movably penetrated in the first long hole, and the second end of the first upper supporting rod structure is movably penetrated in the third long hole. The technical scheme of the application effectively solves the problems of complicated frame adjustment mode and lower operation efficiency when different types of ultrathin glass are operated in the prior art.

Description

Glass running assembly

Technical Field

The application relates to the technical field of glass operation, in particular to a glass operation assembly.

Background

The ultrathin flexible glass is required to be placed in operation after processing, an operation frame is usually used for placing in operation, the glass operation frame in the prior art generally comprises a rectangular underframe, a plurality of inclined supporting frames are arranged on one side of the underframe, limiting pieces are arranged on the inclined supporting frames, a plurality of pieces of glass (for example, 202320185927.1; a glass storage operation frame) can be placed on each operation device, but the distance between the inclined supporting frames of the operation frame is not adjustable, and a supporting structure is added according to the ultrathin glass of a finished product when the ultrathin glass of different types is operated, so that the frame adjustment mode is complicated and the operation efficiency is lower.

Disclosure of Invention

The application provides a glass operation subassembly to adjust frame mode loaded down with trivial details, the lower problem of operating efficiency when solving among the prior art to the ultra-thin glass operation of different models.

According to the present application there is provided a glass run assembly comprising: the side plate structure comprises a first side plate structure and a second side plate structure, the first side plate structure comprises a first long hole and a second long hole, the second side plate structure is provided with a third long hole and a fourth long hole, the first long hole is opposite to the third long hole, the second long hole is opposite to the fourth long hole, and the first long hole, the second long hole, the third long hole and the fourth long hole extend along a first direction; the first end of the lower support rod structure is connected with the first side plate structure, and the second end of the lower support rod structure is connected with the second side plate structure; the upper support rod structure comprises a first upper support rod structure and a second upper support rod structure, a first end of the first upper support rod structure is movably penetrated in the first long hole, and a second end of the first upper support rod structure is movably penetrated in the third long hole; the first end of the second upper support rod structure is movably penetrated in the second long hole, and the second end of the second upper support rod structure is movably penetrated in the fourth long hole.

In some embodiments, the first slot is located in an upper left corner of the first side panel structure and the third slot is located in an upper left corner of the second side panel structure, the length of the first slot being the same as the length of the third slot.

In some embodiments, the second slot is located at an upper right corner of the first side plate structure and the fourth slot is located at an upper right corner of the second side plate structure, the length of the second slot being the same as the length of the fourth slot.

In some embodiments, the first upper support rod structure includes a first upper support rod, a first upper anti-slip sleeve and two first nuts, two ends of the first upper support rod are respectively provided with threads matched with the two first nuts, the two first nuts are respectively installed at two ends of the first upper support rod and are abutted to the first side plate structure and the second side plate structure, the first upper anti-slip sleeve is sleeved on the first upper support rod, and the first upper anti-slip sleeve is located between the first side plate structure and the second side plate structure.

In some embodiments, the outer sidewall of the first upper anti-skid sleeve has a plurality of first grooves, each of which has an opening that gradually increases in a direction from approaching the first upper support rod to separating from the first upper support rod.

In some embodiments, the second upper support rod structure includes a second upper support rod, a second upper anti-slip sleeve and two second nuts, two ends of the second upper support rod are respectively provided with threads matched with the two second nuts, the two second nuts are respectively installed at two ends of the second upper support rod and are abutted with the first side plate structure and the second side plate structure, the second anti-slip sleeve is sleeved on the second upper support rod, and the second upper anti-slip sleeve is located between the first side plate structure and the second side plate structure.

In some embodiments, the outer side wall of the second upper anti-skid sleeve has a plurality of second grooves, each of which has an opening gradually increasing in a direction from approaching the second upper support rod to separating from the second upper support rod, and the plurality of first grooves and the plurality of second grooves are disposed in one-to-one correspondence.

In some embodiments, the lower support bar structure includes a first lower support bar structure and a second lower support bar structure, each movably disposed on the first side plate structure and the second side plate structure.

In some embodiments, the side panel structure is provided with a distance indicator.

In some embodiments, the distance indicator is a scale size indicator.

Through above-mentioned technical scheme, the glass operation subassembly that this application provided includes curb plate structure, lower part bracing piece structure and upper portion bracing piece structure. The side plate structure includes first side plate structure and second side plate structure, and first side plate structure includes first slot hole and second slot hole, and first slot hole and second slot hole are as the removal passageway, and upper portion bracing piece structure of being convenient for removes thereupon, and the second side plate structure has third slot hole and fourth slot hole, and third slot hole and fourth slot hole are as the removal passageway, and upper portion bracing piece structure of being convenient for removes thereupon, and first slot hole sets up with the third slot hole relatively simultaneously, and second slot hole sets up with the fourth slot hole relatively so that upper portion bracing piece structure all extends along the second direction (Y direction). The first long hole, the second long hole, the third long hole, and the fourth long hole each extend in the first direction (X direction) so as to move in the first direction. The first end of lower part bracing piece structure links to each other with first curb plate structure, and the second end of lower part bracing piece structure links to each other with the second curb plate structure, and first curb plate structure and second curb plate structure play the effect of supporting to lower part bracing piece structure. The upper support rod structure comprises a first upper support rod structure and a second upper support rod structure, wherein the first end of the first upper support rod structure is movably penetrated in the first long hole, the second end of the first upper support rod structure is movably penetrated in the third long hole, the first upper support rod structure can move between the first long hole and the third long hole along the extending direction (X direction) of the first long hole and the third long hole, the first end of the second upper support rod structure is movably penetrated in the second long hole, the second end of the second upper support rod structure is movably penetrated in the fourth long hole, the second upper support rod structure can move between the second long hole and the fourth long hole along the extending direction (X direction) of the second long hole, and the distance between the first upper support rod structure and the second upper support rod structure can be adjusted, so that the frame adjusting mode is simplified when different types of ultrathin glass are operated. The technical scheme of the application effectively solves the problems of complicated frame adjustment mode and lower operation efficiency in the operation of different types of ultrathin glass in the prior art.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the application and together with the description, serve to explain the principles of the application.

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings that are required to be used in the description of the embodiments or the prior art will be briefly described below, and it will be obvious to those skilled in the art that other drawings can be obtained from these drawings without inventive effort.

FIG. 1 is a schematic view showing the overall structure of a glass running assembly according to a first embodiment of the present application;

fig. 2 is a schematic view showing partial fitting of the first upper support rod and the third long hole according to the first embodiment of the present application;

fig. 3 shows a schematic structural view of a first groove according to a first embodiment of the present application;

FIG. 4 is a schematic view showing the structure of a cleat according to a second embodiment of the present application;

fig. 5 shows a schematic front view of a glass run assembly according to a third embodiment of the present application.

Wherein the above figures include the following reference numerals:

10. a side plate structure; 11. a first side plate structure; 111. a first long hole; 112. a second long hole; 12. a second side panel structure; 121. a third long hole; 122. a fourth long hole; 20. a lower support bar structure; 21. a first lower support bar structure; 22. a second lower support bar structure; 30. an upper support bar structure; 31. a first upper support bar structure; 311. a first upper support bar; 312. a first upper anti-skid sleeve; 3121. a first groove; 313. a first nut; 32. a second upper support bar structure; 321. a second upper support bar; 322. a second upper anti-skid sleeve; 323. and a second nut.

Detailed Description

It should be noted that, in the case of no conflict, the embodiments and features in the embodiments may be combined with each other. The present application will be described in detail below with reference to the accompanying drawings in conjunction with embodiments.

It should be noted that the following detailed description is illustrative and is intended to provide further explanation of the present application. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs.

Spatially relative terms, such as "above … …," "above … …," "upper surface at … …," "above," and the like, may be used herein for ease of description to describe one device or feature's spatial location relative to another device or feature as illustrated in the figures. It will be understood that the spatially relative terms are intended to encompass different orientations in use or operation in addition to the orientation depicted in the figures. For example, if the device in the figures is turned over, elements described as "above" or "over" other devices or structures would then be oriented "below" or "beneath" the other devices or structures. Thus, the exemplary term "above … …" may include both orientations of "above … …" and "below … …". The device may also be oriented 90 degrees or at other orientations and the spatially relative descriptors used herein interpreted accordingly.

As shown in fig. 1, a glass run module according to a first embodiment includes: a side panel structure 10, a lower support bar structure 20 and an upper support bar structure 30. The side plate structure 10 includes a first side plate structure 11 and a second side plate structure 12, the first side plate structure 11 includes a first long hole 111 and a second long hole 112, the second side plate structure 12 has a third long hole 121 and a fourth long hole 122, the first long hole 111 is disposed opposite to the third long hole 121, the second long hole 112 is disposed opposite to the fourth long hole 122, and the first long hole 111, the second long hole 112, the third long hole 121 and the fourth long hole 122 all extend in the first direction. The first end of the lower support bar construction 20 is connected to the first side plate construction 11 and the second end of the lower support bar construction 20 is connected to the second side plate construction 12. The upper support rod structure 30 includes a first upper support rod structure 31 and a second upper support rod structure 32, a first end of the first upper support rod structure 31 is movably inserted into the first long hole 111, and a second end of the first upper support rod structure 31 is movably inserted into the third long hole 121; the first end of the second upper support bar structure 32 is movably disposed within the second elongated aperture 112 and the second end of the second upper support bar structure 32 is movably disposed within the fourth elongated aperture 122.

In the first embodiment, the glass running assembly provided in this embodiment includes a side plate structure 10, a lower support rod structure 20, and an upper support rod structure 30. The side plate structure 10 includes a first side plate structure 11 and a second side plate structure 12, the first side plate structure 11 includes a first long hole 111 and a second long hole 112, the first long hole 111 and the second long hole 112 serve as a moving passage, the upper support rod structure 30 is facilitated to move thereon, the second side plate structure 12 has a third long hole 121 and a fourth long hole 122, the third long hole 121 and the fourth long hole 122 serve as a moving passage, the upper support rod structure 30 is facilitated to move thereon, while the first long hole 111 is disposed opposite to the third long hole 121, and the second long hole 112 is disposed opposite to the fourth long hole 122 such that the upper support rod structure 30 extends in the second direction (Y direction). The first long hole 111, the second long hole 112, the third long hole 121, and the fourth long hole 122 each extend in the first direction (X direction) so as to move in the first direction. The first end of the lower support bar construction 20 is connected to the first side bar construction 11 and the second end of the lower support bar construction 20 is connected to the second side bar construction 12, the first side bar construction 11 and the second side bar construction 12 acting as supports for the lower support bar construction 20. The first end of the first upper support rod structure 31 is movably inserted into the first long hole 111, the second end of the first upper support rod structure 31 is movably inserted into the third long hole 121, the first upper support rod structure 31 can move between the first long hole 111 and the third long hole 121 along the extending direction (X direction) of the first long hole 111 and the third long hole 121, the first end of the second upper support rod structure 32 is movably inserted into the second long hole 112, the second end of the second upper support rod structure 32 is movably inserted into the fourth long hole 122, the second upper support rod structure 32 can move between the second long hole 112 and the fourth long hole 122 along the extending direction (X direction) of the second long hole 112 and the fourth long hole 122, and the distance between the first upper support rod structure 31 and the second upper support rod structure 32 can be adjusted, so that the frame adjusting mode when different types of ultra-thin glass (UTG) are operated is simplified. The technical scheme of the embodiment effectively solves the problems of complicated frame adjustment mode and lower operation efficiency in the operation of different types of ultrathin glass in the prior art.

As shown in fig. 1, in the solution of the first embodiment, the first long hole 111 is located at the upper left corner of the first side plate structure 11, the third long hole 121 is located at the upper left corner of the second side plate structure 12, and the length of the first long hole 111 is the same as the length of the third long hole 121. The first long hole 111 is located at the upper left corner of the first side plate structure 11, the third long hole 121 is located at the upper left corner of the second side plate structure 12, the first long hole 111 and the third long hole 121 play roles in supporting and limiting the moving track of the first upper supporting rod structure 31, and the same length of the first long hole 111 and the third long hole 121 can reduce the angular deflection of the upper supporting rod structure 30 during moving and further reduce the influence on the ultra-thin glass during fixing. The glass run component of this embodiment is an ultra-thin glass run component.

As shown in fig. 1, in the solution of the first embodiment, the second long hole 112 is located at the upper right corner of the first side plate structure 11, the fourth long hole 122 is located at the upper right corner of the second side plate structure 12, and the length of the second long hole 112 is the same as that of the fourth long hole 122. The second long hole 112 is located at the upper right corner of the first side plate structure 11, the fourth long hole 122 is located at the upper right corner of the second side plate structure 12, the second long hole 112 and the fourth long hole 122 play roles in supporting and limiting the moving track of the second upper supporting rod structure 32, and the same length of the second long hole 112 and the fourth long hole 122 can reduce the angular deflection of the second upper supporting rod structure 32 during moving and further reduce the influence on the fixing of the ultra-thin glass.

As shown in fig. 1 and 2, in the first technical solution of the first embodiment, the first upper supporting rod structure 31 includes a first upper supporting rod 311, a first upper anti-slip sleeve 312 and two first nuts 313, two ends of the first upper supporting rod 311 are respectively provided with threads matching with the two first nuts 313, the two first nuts 313 are respectively installed at two ends of the first upper supporting rod 311 and are abutted with the first side plate structure 11 and the second side plate structure 12, the first upper anti-slip sleeve 312 is sleeved on the first upper supporting rod 311, and the first upper anti-slip sleeve 312 is located between the first side plate structure 11 and the second side plate structure 12. The two ends of the first upper supporting rod 311 are respectively provided with threads matched with the two first nuts 313, the first upper supporting rod 311 is adjusted to a proper position according to the size of the running ultra-thin glass, the two first nuts 313 are fastened, the two first nuts 313 are respectively arranged at the two ends of the first upper supporting rod 311 and are abutted against the first side plate structure 11 and the second side plate structure 12 to limit the movement of the first upper supporting rod 311, the first upper anti-slip sleeve 312 is sleeved on the first upper supporting rod 311 and is positioned between the first side plate structure 11 and the second side plate structure 12, the first upper anti-slip sleeve 312 can increase the fixing effect on the ultra-thin glass by adopting materials such as silica gel or rubber to increase the friction force between the ultra-thin glass, and meanwhile, the materials such as the silica gel or the rubber have certain softness and impact resistance and can prevent scratches or cracks on the surface of the ultra-thin glass during running.

As shown in fig. 1 and 3, in the technical solution of the first embodiment, the outer side wall of the first upper anti-slip cover 312 has a plurality of first grooves 3121, and each first groove 3121 gradually increases in opening in a direction from approaching the first upper support bar 311 to separating from the first upper support bar 311. The outer side wall of the first upper anti-slip sleeve 312 has a plurality of first grooves 3121, which can fix a plurality of ultra-thin glass with the same size, thereby greatly improving the operation efficiency, and the opening of each first groove 3121 along the direction from the first upper support rod 311 to the direction far from the first upper support rod 311 is gradually increased, so that the ultra-thin glass is convenient to be matched with each first groove 3121.

It should be noted that, the first upper anti-slip sleeve 312 and the plurality of first grooves 3121 are integrated, and the first upper anti-slip sleeve 312 and the plurality of first grooves 3121 can rotate along with the ultra-thin glass when the ultra-thin glass is moved in and out along the first grooves 3121, so that scratches of the ultra-thin glass are effectively reduced when the ultra-thin glass is placed and taken.

As shown in fig. 1, in the first embodiment, the second upper support rod structure 32 includes a second upper support rod 321, a second upper anti-slip sleeve 322 and two second nuts 323, two ends of the second upper support rod 321 are respectively provided with threads matched with the two second nuts 323, the two second nuts 323 are respectively installed at two ends of the second upper support rod 321 and are abutted against the first side plate structure 11 and the second side plate structure 12, the second upper anti-slip sleeve 322 is sleeved on the second upper support rod 321, and the second upper anti-slip sleeve 322 is located between the first side plate structure 11 and the second side plate structure 12. The two ends of the second upper supporting rod 321 are respectively provided with threads matched with two second nuts 323, the second upper supporting rod 321 is adjusted to a proper position according to the size of the running ultrathin glass, the two second nuts 323 are fastened, the two second nuts 323 are respectively arranged at the two ends of the second upper supporting rod 321 and are abutted against the first side plate structure 11 and the second side plate structure 12 to limit the movement of the second upper supporting rod 321, the second upper anti-slip sleeve 322 is sleeved on the second upper supporting rod 321 and is positioned between the first side plate structure 11 and the second side plate structure 12, the second upper anti-slip sleeve 322 can be made of materials such as silica gel or rubber, so that the friction between the second upper anti-slip sleeve and the ultrathin glass can be enhanced, and meanwhile, the materials such as silica gel or rubber have certain softness and impact resistance, so that scratches or cracks on the surface of the ultrathin glass can be prevented when the ultrathin glass runs.

In the first embodiment, the outer side wall of the second upper anti-slip cover 322 has a plurality of second grooves, each of which has an opening gradually increasing in a direction from the second upper support rod 321 to the second upper support rod 321, and the plurality of first grooves 3121 and the plurality of second grooves are disposed in one-to-one correspondence. The lateral wall of second upper portion antiskid cover 322 has a plurality of second recesses, can fix the effect to a plurality of same size ultra-thin glass, can improve operating efficiency by a wide margin, each second recess is along being close to the ascending opening of second upper portion bracing piece 321 to keeping away from the ascending cooperation of ultra-thin glass and second recess of being convenient for of second upper portion bracing piece 321, a plurality of first recesses 3121 and a plurality of second recesses set up the ultra-thin glass of having guaranteed to place along first direction in one-to-one, adjacent first recess 3121 and adjacent second recess all are provided with certain distance can prevent to take place adjacent ultra-thin glass collision's phenomenon when operating a plurality of ultra-thin glass, the damage rate has been reduced.

As shown in fig. 1, in the solution of the first embodiment, the lower support rod structure 20 includes a first lower support rod structure 21 and a second lower support rod structure 22, and the first lower support rod structure 21 and the second lower support rod structure 22 are movably disposed on the first side plate structure 11 and the second side plate structure 12. The lower support rod structure 20 comprises a first lower support rod structure 21 and a second lower support rod structure 22, the first lower support rod structure 21 and the second lower support rod structure 22 can be placed at two ends of the ultrathin glass to limit the displacement of the ultrathin glass and cooperate with the first upper support rod structure 31 and the second upper support rod structure 32 to fix the ultrathin glass together, the first lower support rod structure 21 and the second lower support rod structure 22 are movably arranged on the first side plate structure 11 and the second side plate structure 12, the distance between the ultrathin glass can be adjusted according to different sizes, the placement mode is more stable, and the ultrathin glass can be well fixed even if the ultrathin glass inclines in the operation process. The first lower support rod structure 21 and the second lower support rod structure 22 can also be placed at the bottom of the ultrathin glass for lifting, the first upper support rod structure 31 and the second upper support rod structure 32 are used for fixing the ultrathin glass, the arrangement mode is only suitable for short-distance operation without large deflection, the adjustment of the first lower support rod structure 21 and the second lower support rod structure 22 can be reduced, the operation efficiency is improved,

it should be noted that, the first side plate structure 11 further includes a fifth long hole and a sixth long hole, the second side plate structure 12 further includes a seventh long hole and an eighth long hole, the fifth long hole is disposed opposite to the seventh long hole, the fifth long hole is located at a lower left corner of the first side plate structure 11, the seventh long hole is located at a lower left corner of the second side plate structure 12, the lengths of the fifth long hole and the seventh long hole are the same, the sixth long hole and the eighth long hole are disposed opposite to each other, the sixth long hole is located at a lower right corner of the first side plate structure 11, the eighth long hole is located at a lower right corner of the second side plate structure 12, and the lengths of the sixth long hole and the eighth long hole are the same; the first end of the first lower support rod structure 21 is movably arranged in the fifth long hole in a penetrating way, the second end of the first lower support rod structure 21 is movably arranged in the seventh long hole in a penetrating way, the first end of the second lower support rod structure 22 is movably arranged in the sixth long hole in a penetrating way, and the second end of the second lower support rod structure 22 is movably arranged in the eighth long hole in a penetrating way; the first lower support bar structure 21 includes a first lower support bar, a first lower anti-slip sleeve, and two third nuts, and the second lower support bar structure 22 includes a second lower support bar, a second lower anti-slip sleeve, and two fourth nuts. The first lower support bar structure 21 and the second lower support bar structure 22 correspond to the first upper support bar structure 31 and the second upper support bar structure 32, and the operation process corresponds, and the effects are consistent and will not be described again.

In the first embodiment, the side plate structure 10 is provided with a distance mark. In operation, the lower support bar structure 20 and the upper support bar structure 30 are adjusted to the proper positions according to the size of the ultra-thin glass, so that repeated adjustment is reduced, and the operation efficiency is improved.

It should be noted that, the first side plate structure 11 and the second side plate structure 12 are both provided with hollow structures. The hollow structure can reduce the weight of the first side plate structure 11 and the second side plate structure 12, so that the operation is convenient, and the operation efficiency is improved.

In the technical solution of the first embodiment, the distance mark is a scale size mark. The laser engraving machine is adopted for engraving the size mark, so that the size mark has the advantage of durability and is not easy to fall off.

As shown in fig. 4, the second embodiment is different from the first embodiment in that a plurality of cleats are disposed on the outer sidewalls of the first upper anti-slip sleeve 312, the second upper anti-slip sleeve 322, the first lower anti-slip sleeve and the second lower anti-slip sleeve, and the sizes of the cleats gradually decrease along the direction from the first upper anti-slip sleeve 312, the second upper anti-slip sleeve 322, the first lower anti-slip sleeve and the second lower anti-slip sleeve to the direction away from the first upper anti-slip sleeve 312, the second upper anti-slip sleeve 322, the first lower anti-slip sleeve and the second lower anti-slip sleeve. The plurality of anti-slip protrusions can fix a plurality of ultra-thin glass with the same size, so that the running efficiency can be greatly improved, and the protruding sizes of the anti-slip protrusions in the directions close to the first upper anti-slip sleeve 312, the second upper anti-slip sleeve 322, the first lower anti-slip sleeve and the second lower anti-slip sleeve far away from the first upper anti-slip sleeve 312, the second upper anti-slip sleeve 322, the first lower anti-slip sleeve and the second lower anti-slip sleeve are gradually reduced so as to facilitate the matching of the ultra-thin glass and the anti-slip protrusions. The anti-skidding bulges are integrally connected with the first upper anti-skidding sleeve 312, the second upper anti-skidding sleeve 322, the first lower anti-skidding sleeve and the second lower anti-skidding sleeve, and the occurrence of scratches on the surface of the ultra-thin glass is effectively reduced along with the fact that the ultra-thin glass can be rotated when being placed and taken.

As shown in fig. 5, the difference between the technical solution of the third embodiment and the first embodiment is that universal wheels are added at four corner positions of the bottom of the glass running assembly, push-pull rods are installed between the first side plate structure 11 and the second side plate structure 12 near the lower edges of the left side and the right side of the first side plate structure 11 and the second side plate structure 12 along the second direction, and when the glass running assembly is operated, an operator can use the push-pull rods to run the glass running assembly, and can also lift the push-pull rods to lift the glass running assembly. The arrangement can enable the operation of operators to be more labor-saving and convenient.

It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of example embodiments in accordance with the present application. As used herein, the singular is also intended to include the plural unless the context clearly indicates otherwise, and furthermore, it is to be understood that the terms "comprises" and/or "comprising" when used in this specification are taken to specify the presence of stated features, steps, operations, devices, components, and/or combinations thereof.

It should be noted that the terms "first," "second," and the like in the description and claims of the present application and the above figures are used for distinguishing between similar objects and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used may be interchanged where appropriate such that embodiments of the present application described herein may be capable of being practiced otherwise than as specifically illustrated and described herein. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

The foregoing is merely a preferred embodiment of the present application and is not intended to limit the present application, and various modifications and variations may be made to the present application by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principles of the present application should be included in the protection scope of the present application.

Claims (10)

1. A glass run assembly, comprising:

a side plate structure (10), the side plate structure (10) comprising a first side plate structure (11) and a second side plate structure (12), the first side plate structure (11) comprising a first long hole (111) and a second long hole (112), the second side plate structure (12) having a third long hole (121) and a fourth long hole (122), the first long hole (111) being arranged opposite to the third long hole (121), the second long hole (112) being arranged opposite to the fourth long hole (122), the first long hole (111), the second long hole (112), the third long hole (121) and the fourth long hole (122) all extending in a first direction;

a lower support bar construction (20), a first end of the lower support bar construction (20) being connected to the first side plate construction (11), a second end of the lower support bar construction (20) being connected to the second side plate construction (12);

an upper support rod structure (30), wherein the upper support rod structure (30) comprises a first upper support rod structure (31) and a second upper support rod structure (32), a first end of the first upper support rod structure (31) is movably penetrated in the first long hole (111), and a second end of the first upper support rod structure (31) is movably penetrated in the third long hole (121); the first end of the second upper support rod structure (32) is movably arranged in the second long hole (112) in a penetrating mode, and the second end of the second upper support rod structure (32) is movably arranged in the fourth long hole (122) in a penetrating mode.

2. The glass run assembly according to claim 1, wherein the first elongated hole (111) is located at an upper left corner of the first side plate structure (11), the third elongated hole (121) is located at an upper left corner of the second side plate structure (12), and a length of the first elongated hole (111) is the same as a length of the third elongated hole (121).

3. The glass run assembly according to claim 2, wherein the second elongated hole (112) is located in an upper right corner of the first side plate structure (11), the fourth elongated hole (122) is located in an upper right corner of the second side plate structure (12), and a length of the second elongated hole (112) is the same as a length of the fourth elongated hole (122).

4. The glass running assembly according to claim 1, wherein the first upper support rod structure (31) comprises a first upper support rod (311), a first upper anti-slip sleeve (312) and two first nuts (313), two ends of the first upper support rod (311) are respectively provided with threads matched with the two first nuts (313), the two first nuts (313) are respectively installed at two ends of the first upper support rod (311) and are abutted against the first side plate structure (11) and the second side plate structure (12), the first upper anti-slip sleeve (312) is sleeved on the first upper support rod (311), and the first upper anti-slip sleeve (312) is located between the first side plate structure (11) and the second side plate structure (12).

5. The glass run assembly according to claim 4, wherein the outer side wall of the first upper anti-slip sleeve (312) has a plurality of first grooves (3121), each of the first grooves (3121) having an opening gradually increasing in a direction approaching the first upper support rod (311) to a direction away from the first upper support rod (311).

6. The glass running assembly according to claim 5, wherein the second upper support rod structure (32) comprises a second upper support rod (321), a second upper anti-slip sleeve (322) and two second nuts (323), two ends of the second upper support rod (321) are respectively provided with threads matched with the two second nuts (323), the two second nuts (323) are respectively installed at two ends of the second upper support rod (321) and are abutted against the first side plate structure (11) and the second side plate structure (12), the second upper anti-slip sleeve (322) is sleeved on the second upper support rod (321), and the second upper anti-slip sleeve (322) is located between the first side plate structure (11) and the second side plate structure (12).

7. The glass run assembly according to claim 6, wherein the outer side wall of the second upper anti-skid sleeve (322) has a plurality of second grooves, each of which is gradually increased in opening in a direction from approaching the second upper support rod (321) to separating from the second upper support rod (321), and the plurality of first grooves (3121) and the plurality of second grooves are provided in one-to-one correspondence.

8. The glass run assembly according to claim 1, wherein the lower support bar structure (20) comprises a first lower support bar structure (21) and a second lower support bar structure (22), the first lower support bar structure (21) and the second lower support bar structure (22) being both movably arranged on the first side plate structure (11) and the second side plate structure (12).

9. Glass run assembly according to any of claims 1 to 8, characterized in that the side panel structure (10) is provided with distance markings.

10. The glass run assembly according to claim 9, wherein the distance indicator is a scale size indicator.