TWI808361B - Improvement of lateral load steel cables in the process of panels - Google Patents

Abstract

An improvement of a steel cable that withstands side loads during a panel manufacturing process, comprising: a steel cable, which is coated with resin to form an outer layer, and the two ends of the steel cable are reserved with connecting sections that are not coated with resin, and a non-slip ring is sleeved on the connecting section and fixed. The diameter of the non-slip ring is larger than the outer layer of the steel cable; at least one set of fixing parts. The steel cable is integrated with the fixing part; wherein: the axial sectional surface of the steel cable presents a polygonal shape, and the steel cable forms a shape along the outer corner of the polygon along the axial direction. When in use, the fixing part is rotated to make the steel cable rotate in conjunction, so that a plane carrying the glass panel is formed between every two adjacent outer corners of the aforementioned axial sectional surface, and the aforementioned plane is used to increase the contact area between the steel cable and the glass panel to achieve the effects of anti-slip and stable transportation.

Description

Improvement of lateral load steel cables in the process of panels

The present invention relates to steel cables that bear lateral loads in the manufacturing process for panels, and in particular refers to a polygonal contact surface on the steel cables that bear lateral loads in the panel manufacturing process or a spiral contact surface on the surface of the steel cables, using the aforementioned contact surface to carry the glass panel to increase the contact area and prevent the sliding of the glass panel.

As disclosed in the Republic of China Invention Patent No. I251573 "Linear Substrate Supporting Member for Substrate Storage Rack for Transportation", the supporting member used for substrate transportation mainly consists of rectangular frames formed by connecting a pair of upright columns with crossbeams.

In addition, between the above-mentioned pair of upright columns of each rectangular frame, a plurality of linear substrate support members are arranged at intervals in the height direction, and in the above-mentioned adjacent rectangular frames, the above-mentioned linear substrate support members formed so as to face each other are stretched to the same height and level, and the feature is: a linear body that is coated with resin on the outer periphery of a stainless steel wire formed by twisting a plurality of stainless steel wires by extrusion; and a pair of installation hardware fixed at both ends of the above-mentioned linear body. a stainless steel wire exposed outside the linear body after the resin at both ends of the linear body is removed; and a resin end adjacent to the exposed stainless steel wire.

But the problem of the foregoing structure is as follows: due to the stainless steel wire and the glass panel There is point contact or line contact between them, and the contact area is not much, so it is easy to be shaken by the uneven floor during transportation, and then the glass panel will slide down, making the production operation not smooth and increasing the cost of the industry.

How to improve the shortcomings of the conventional structure is a topic that relevant industry players actively solve.

The main purpose of the present invention is to provide an improved side load-bearing steel cable in the panel manufacturing process. The improvement is mainly carried out on a panel bearing steel cable. The shape of the axial sectional surface of the aforementioned steel cable is polygonal or petal-shaped, and the axial shape of the steel cable can be implemented in a straight or spiral shape. Because the sectional surface allows the steel cable to produce multiple regions to carry the glass panel in the form of surface contact, avoiding the sliding of the glass panel and the stability of the glass panel handling.

Therefore, the structure of the present invention includes: a steel cable, which is coated with resin to form an outer layer, and the two ends of the steel cable are reserved with connecting sections that are not coated with resin, and a non-slip ring is sleeved on the connecting section and fixed. Combined into one; it is characterized in that: the axial sectional surface of the steel cable presents the shape of petals arranged continuously with multiple arc angles, and the steel cable forms a straight shape along the axial direction. When in use, the fixing part is rotated to make the steel cable rotate in conjunction, so that a support surface formed between each two adjacent circular arcs of the aforementioned axial sectional surface is one high and one low. effect.

In an embodiment of the present invention, wherein every 5-20 degrees of rotation of the fixing member, a support surface for carrying the glass substrate can be formed between every two adjacent arc angles.

Through the above description, the characteristics and functions of the present invention are briefly described as follows: the structure of the present invention constructs a support structure for supporting the glass panel through adjacent outer corners or adjacent arc corners. Compared with the conventional structure, the steel cable of the present invention increases the contact area to achieve the effects of anti-slip and stable transportation of the glass panel.

first embodiment

100: Improvement of side load bearing steel cables in panel manufacturing process

10: Cable

11: outer layer

12: Connection section

13: Anti-slip ring

14: Axial truncated surface

15: Outer corner

16: Plane

20:Fixer

21: external thread segment

22: Locking section

second embodiment

200: Improvement of side load bearing steel cables in panel manufacturing process

30: Cable

31: outer layer

32: Connection section

33: Anti-slip ring

34: Axial truncated surface

35: arc angle

36: Support surface

40:Fixer

41: external thread segment

42: Locking section

Fig. 1 is a structural diagram of the first embodiment of the present invention.

FIG. 2 is an exploded view of the structure of FIG. 1 .

Fig. 3 is a cross-sectional structure diagram along line A-A of Fig. 1 .

Fig. 4 is a use state diagram of Fig. 1 .

Figure 5 is a side view of the cable.

Fig. 6 is a structural diagram of the second embodiment of the present invention.

Fig. 7 is a B-B sectional structure diagram of Fig. 5 .

Fig. 8 is a side view of the second embodiment of the cable.

FIG. 9 is a diagram of the use state of FIG. 5 .

Fig. 10 is a side view of a bidirectional helical cable in the second embodiment.

As shown in Fig. 1 to Fig. 5, the improvement 100 of the side load-bearing steel cable in the panel manufacturing process according to the first embodiment of the present invention includes: a steel cable 10, which is covered with resin to form an outer layer 11, and the two ends of the steel cable 10 are reserved with connecting sections 12 not coated with resin, and in the connecting section 12 An anti-slip ring 13 is sleeved on the upper shaft and fixed, the diameter of the anti-slip ring 13 is larger than the outer layer 11 of the steel cable 10; two sets of fixing parts 20, the outer edge of the fixing part 20 is provided with an external thread section 21 and a locking section 22, one side of the locking section 22 is used to combine the aforementioned anti-slip ring 13 on the steel cable, so that the aforementioned steel cable 10 is integrated with the fixing part 20.

As shown in Fig. 3 and Fig. 5, the axial sectional surface 14 of the steel cable 10 presents a polygonal shape, and the steel cable 10 forms a shape along the axial direction along the polygonal outer corner 15. During use, the fixing member 20 is rotated to make the steel cable 10 rotate in conjunction, so that a plane 16 for carrying a glass panel is formed between every two adjacent outer corners 15 of the aforementioned axial sectional surface 14. Through the soft and slightly deformable characteristics of the aforementioned outer layer 11, the aforementioned flat surface 16 is also used. The contact area between the steel cable 10 and the glass panel is increased to achieve the effects of anti-slip and stable transportation. Wherein, every time the fixing member 20 is rotated by 5-20 degrees, a plane 16 for carrying the glass substrate can be formed between every two adjacent outer corners 15 .

As shown in Fig. 6 to Fig. 9, the second embodiment of the improvement 200 of the side load-bearing steel cable in the panel manufacturing process of the present invention is basically as follows: a steel cable 30 is coated on the steel cable 30 through resin to form an outer layer 31, and the two sides of the steel cable 30 are reserved with connecting sections 32 not covered with resin, and a non-slip ring 33 is sleeved on the connecting section 32 and fixed. The diameter of the anti-slip ring 33 is larger than the outer layer 31 of the steel cable 30; 0, the outer edge of the fixing member 40 is provided with an external thread section 41 and a locking section 42, one side of the locking section 42 is used to combine with the anti-slip ring 33 on the aforementioned steel cable, so that the aforementioned steel cable 30 is integrated with the fixing member 40.

As shown in FIGS. 6 to 9 , the axial sectional surface 34 of the steel cable 30 presents a petal shape in which multiple arc angles 35 are continuously arranged, and the steel cable 30 forms a set of straight double helix shapes along the axial direction. When in use, the fixing member 40 is rotated to make the steel cable 30 rotate in conjunction, so that a shape formed between every two adjacent arc angles 35 of the aforementioned axial sectional surface 34 is one high and one low for carrying the glass panel. The support surface 36, through the soft and slightly deformable characteristics of the aforementioned outer layer 31, utilizes the aforementioned support surface 36 to increase the contact area between the steel cable 30 and the glass panel to achieve the effects of anti-slip and stable transportation. Wherein, every time the fixing member 40 is rotated by 5-20 degrees, a supporting surface 36 for carrying the glass substrate can be formed between every two adjacent arc angles 35 .

In addition to the above two embodiments, according to the idea of the present invention, the following methods can also be implemented: 1. Combining the shape of the polygonal outer corner 15 of the first embodiment with the shape feature of the double helix of the steel cable 30 of the second embodiment, so that two adjacent outer corners 15 constitute a supporting surface for carrying the glass substrate, and the contact area between the steel cable and the glass substrate is increased through the aforementioned supporting surface; 5. Form a support surface for carrying the glass substrate, and increase the contact area between the steel cable and the glass substrate through the aforementioned support surface; 3. In addition to the single-directional double helix shape of the steel cable 30 as shown in FIG.

To sum up, the structure of the present invention has never been seen in any books or periodicals or publicly used, and it truly meets the requirements for an invention patent application. I sincerely hope that the bureau will grant a patent as soon as possible, and I will pray for it.

It should be stated that the above descriptions are the specific embodiments of the present invention and the technical principles used. If changes are made according to the conception of the present invention, and the functions produced by it still do not exceed the spirit covered by the description and drawings, they should be stated within the scope of the present invention.

31: outer layer

34: Axial truncated surface

35: arc angle

Claims (2)

An improvement of a steel cable that withstands side loads during a panel manufacturing process, comprising: a steel cable, which is coated with resin to form an outer layer, and the two ends of the steel cable are reserved with connecting sections that are not coated with resin, and a non-slip ring is sleeved on the connecting section and fixed. The diameter of the non-slip ring is larger than the outer layer of the steel cable; at least one set of fixing parts. The steel cable is integrated with the fixing part; the axial sectional surface of the steel cable is in the shape of petals arranged continuously with multiple circular arc angles, and the steel cable forms a set of straight double helix shapes along the axial direction. When in use, the fixing part is rotated to make the steel cable rotate in conjunction, so that a supporting surface for carrying the glass panel formed between every two adjacent circular arcs of the aforementioned axial sectional surface can be slightly deformed through the aforementioned soft outer layer, and the aforementioned supporting surface is used to increase the contact area between the steel cable and the glass panel to achieve anti-slip and stable transportation effect. The improvement of the side load-bearing steel cable in the panel manufacturing process as described in claim 1, wherein the steel cable has a double helix structure in a clockwise direction and a counterclockwise direction such as a twist.

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