CN220611364U - Bending performance detection device - Google Patents

Abstract

A bending performance detection device relates to the technical field of flexible glass. The bending performance detection device comprises a packaging mechanism, a performance detection mechanism and a recovery mechanism; the performance detection mechanism is located between the packaging mechanism and the recovery mechanism, the packaging mechanism is used for respectively coating the protective films on two opposite sides of the flexible glass to be detected and transmitting the protective films to the performance detection mechanism, the performance detection mechanism is used for detecting bending performance of the flexible glass to be detected and transmitting the bending performance to the recovery mechanism, and the recovery mechanism is used for collecting the flexible glass to be detected after the bending performance detection by the performance detection mechanism. The bending performance detection device has higher automation degree and can be applied to industrial mass production.

Description

Bending performance detection device

Technical Field

The utility model relates to the technical field of flexible glass, in particular to a bending performance detection device.

Background

With the increasing popularity of liquid crystal displays, smart phones and tablet computers, display products gradually develop towards the direction of light and thin, and electronic glass matched with the display products also needs to be light and thin, so that a flexible glass variety is developed. The flexible glass is ultrathin glass with the thickness less than or equal to 0.1 mm. The flexible glass not only has the hardness, transparency, heat resistance, insulativity and stable mechanical and chemical properties under the oxidation and illumination conditions of the glass, but also has the characteristics of being bendable, even foldable, light in weight, processable and the like. Currently, flexible glass has begun to be used in foldable cellular phones.

Although flexible glass has flexibility, the flexible glass still belongs to brittle materials, has lower mechanical strength and impact strength, and has difficult to detect damage, microcracks, edge breakage and the like in the production and processing processes. If the defective glass with flaws and defects flows to a downstream process, the defective glass is applied to terminal equipment for assembly and use, so that the terminal equipment is easy to malfunction and the use is affected. In particular, folding screens require repeated folding during use, and therefore minor imperfections in the flexible glass are more likely to accelerate damage to the folding screen during the continuous folding process. However, in the prior art, there is no better equipment for simulating the bending state of the product during use, so as to accurately and rapidly detect the defective products of the flexible glass, and most of the equipment adopts a spot check mode to detect the bending performance, and the used equipment is basically semi-automatic equipment, a large amount of labor is required to be input, and the efficiency is low. Therefore, how to provide a new flexible glass bending performance detection device with higher automation degree is urgent and significant.

Disclosure of Invention

The utility model aims to provide a bending performance detection device which has high automation degree and can be applied to industrial mass production.

Embodiments of the present utility model are implemented as follows:

in one aspect of the present utility model, there is provided a bending performance detecting apparatus including a packaging mechanism, a performance detecting mechanism, and a recovery mechanism; the performance detection mechanism is located between the packaging mechanism and the recovery mechanism, the packaging mechanism is used for respectively coating the protective films on two opposite sides of the flexible glass to be detected and transmitting the protective films to the performance detection mechanism, the performance detection mechanism is used for detecting bending performance of the flexible glass to be detected and transmitting the bending performance to the recovery mechanism, and the recovery mechanism is used for collecting the flexible glass to be detected after the bending performance detection by the performance detection mechanism. The bending performance detection device has higher automation degree and can be applied to industrial mass production.

Optionally, the packaging mechanism comprises a fixed table, a first roller, a second roller, a collecting roller, a first motor for driving the collecting roller to rotate and a trimming assembly; one end of the first protective film is wound on the first roller, and the other end of the first protective film bypasses the fixed table and is wound on the collecting roller; one end of the second protective film is wound on the second roller, and the other end of the second protective film winds on the collecting roller after bypassing the fixing table; the first roller and the collecting roller are positioned on the same side of the fixed table, and the first roller is positioned on one side of the fixed table, which is away from the second roller; the trimming assembly is located above the fixed table and is used for trimming the flexible glass to be detected.

Optionally, the packaging mechanism further comprises a third roller, the third roller is located on one side, away from the first roller, of the fixing table and located between the first roller and the second roller, one end of the second protective film is wound on the second roller, and the other end of the second protective film is wound on the collecting roller through the third roller.

Optionally, the packaging mechanism further comprises an air source, wherein a plurality of evenly distributed air holes are formed in one end, close to the performance detection mechanism, of the fixing table, the air source is used for supplying air to the air holes, the air holes face to the first protection film to jet air, and the first protection film and the second protection film are used for being separated from the coated flexible glass to be detected respectively.

Optionally, the performance detection mechanism comprises a first conveyor belt, two clamping plates and a driving mechanism, wherein the first conveyor belt is in butt joint with the packaging mechanism, the two clamping plates are positioned above the first conveyor belt, and the driving mechanism is used for driving the two clamping plates to move; the driving mechanism drives the two clamping plates to move towards the direction close to the first conveyor belt, so that the two clamping plates are respectively clamped at the two opposite ends of the flexible glass to be detected; when the two clamping plates are respectively clamped at the two opposite ends of the flexible glass to be detected, the driving mechanism drives the two clamping plates to move in opposite directions, and the two clamping plates are used for driving the flexible glass to be detected to fold.

Optionally, the driving mechanism includes a first driving mechanism and a second driving mechanism, the first driving mechanism is used for driving the two clamping plates to approach or separate from the first conveyor belt, and the second driving mechanism is used for driving the two clamping plates to approach or separate from each other.

Optionally, the performance detection mechanism further comprises a spacer plate located between the two clamping plates.

Optionally, when the two clamping plates are respectively clamped at two opposite ends of the flexible glass to be detected, the two clamping plates are respectively adsorbed with two opposite ends of the flexible glass to be detected in vacuum.

Optionally, the recovery mechanism includes yields recovery unit and waste product recovery unit, yields recovery unit be used for collecting through performance detection mechanism after bending performance detects qualified wait to detect flexible glass, waste product recovery unit be used for collecting through performance detection mechanism after bending performance detects unqualified wait to detect flexible glass.

Optionally, the recycling mechanism further comprises a rotating plate, a second conveying belt and a second motor, wherein one end of the rotating plate is in butt joint with the first conveying belt, the second conveying belt is positioned on one side, away from the performance detection mechanism, of the rotating plate, and the second motor is used for driving the rotating plate to rotate; one end of the second conveyor belt, which is far away from the rotating plate, is in butt joint with the good product recovery part; when the flexible glass to be detected is waste, the second motor is used for driving the rotating plate to rotate, so that the first conveyor belt is in butt joint with the waste recovery part through the rotating plate; when the flexible glass to be detected is good, the second motor is used for driving the rotating plate to rotate, so that the first conveyor belt is in butt joint with the second conveyor belt through the rotating plate;

and/or the recovery mechanism further comprises a detector, wherein the detector is used for detecting the flexible glass to be detected after the performance detection mechanism is used for detecting the flexible glass to be detected, and determining whether the flexible glass to be detected is good or waste.

The beneficial effects of the utility model include:

the bending performance detection device comprises a packaging mechanism, a performance detection mechanism and a recovery mechanism; the performance detection mechanism is located between the packaging mechanism and the recovery mechanism, the packaging mechanism is used for respectively coating the protective films on two opposite sides of the flexible glass to be detected and transmitting the protective films to the performance detection mechanism, the performance detection mechanism is used for detecting bending performance of the flexible glass to be detected and transmitting the bending performance to the recovery mechanism, and the recovery mechanism is used for collecting the flexible glass to be detected after the bending performance detection by the performance detection mechanism. According to the method, the flexible glass to be detected is coated by the packaging mechanism, so that after the flexible glass to be detected is detected by the performance detection mechanism, the protective film can protect the flexible glass to be detected, and fragments after the flexible glass to be detected is broken affect the working procedure; the performance detection mechanism is respectively in butt joint with the packaging mechanism and the recovery mechanism, so that the whole detection process is in a full-automatic state, and the automation degree and the detection efficiency of the flexible glass to be detected can be improved; through setting up recovery mechanism, can retrieve the flexible glass that waits to detect through bending property detection. The bending performance detection device provided by the application is higher in automation degree, can enable flexible glass to be detected to be applied to industrial mass production, can improve detection efficiency, and has higher practical value.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed in the embodiments will be briefly described below, it being understood that the following drawings only illustrate some embodiments of the present utility model and therefore should not be considered as limiting the scope, and other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of a bending performance detecting device according to an embodiment of the present utility model;

FIG. 2 is a second schematic diagram of a bending performance detecting device according to an embodiment of the present utility model;

fig. 3 is a schematic structural view of a packaging mechanism according to an embodiment of the present utility model;

FIG. 4 is a schematic structural diagram of a performance detecting mechanism according to an embodiment of the present utility model;

FIG. 5 is a schematic structural view of a recycling mechanism according to an embodiment of the present utility model;

fig. 6 is a schematic diagram of two clamping plates for clamping flexible glass to be tested according to an embodiment of the present utility model.

Icon: 10-a packaging mechanism; 11-a fixed table; 111-gas injection holes; 112-a guide post; 12-a first roller; 13-a second roller; 14-collecting roller; 15-a first motor; 16-edge cutting assembly; 17-a third roller; 18-air source; 20-a performance detection mechanism; 21-a first conveyor belt; 22-clamping plates; 23-a first drive mechanism; 24-a second drive mechanism; 25-a separator; 26-a guide rail; 30-a recovery mechanism; 31-a good product recovery part; 32-a waste recovery section; 33-a rotating plate; 34-a second conveyor belt; 35-a second motor; 36-a detector; 37-counter; 100-a first protective film; 200-a second protective film; 300-flexible glass to be tested.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments of the present utility model. The components of the embodiments of the present utility model generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the utility model, as presented in the figures, is not intended to limit the scope of the utility model, as claimed, but is merely representative of selected embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures.

In the description of the present utility model, it should be noted that, directions or positional relationships indicated by terms such as "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., are directions or positional relationships based on those shown in the drawings, or are directions or positional relationships conventionally put in use of the inventive product, are merely for convenience of describing the present utility model and simplifying the description, and are not indicative or implying that the apparatus or element to be referred to must have a specific direction, be constructed and operated in a specific direction, and thus should not be construed as limiting the present utility model. Furthermore, the terms "first," "second," "third," and the like are used merely to distinguish between descriptions and should not be construed as indicating or implying relative importance.

Furthermore, the terms "horizontal," "vertical," and the like do not denote a requirement that the component be absolutely horizontal or overhang, but rather may be slightly inclined. As "horizontal" merely means that its direction is more horizontal than "vertical", and does not mean that the structure must be perfectly horizontal, but may be slightly inclined.

In the description of the present utility model, it should also be noted that, unless explicitly specified and limited otherwise, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

Referring to fig. 1 and 2, the present embodiment provides a bending performance detecting apparatus, which includes a packaging mechanism 10, a performance detecting mechanism 20 and a recycling mechanism 30; the performance detection mechanism 20 is located between the packaging mechanism 10 and the recovery mechanism 30, the packaging mechanism 10 is used for respectively coating protective films on two opposite sides of the flexible glass 300 to be detected and transmitting the protective films to the performance detection mechanism 20, the performance detection mechanism 20 is used for detecting bending performance of the flexible glass 300 to be detected and transmitting the bending performance to the recovery mechanism 30, and the recovery mechanism 30 is used for collecting the flexible glass 300 to be detected after the bending performance detection by the performance detection mechanism 20. The bending performance detection device has higher automation degree and can be applied to industrial mass production.

It should be noted that, the bending performance detection device provided in the present application is used for automatically detecting the bending performance of the flexible glass 300 to be detected. The bending performance detecting apparatus includes a packaging mechanism 10, a performance detecting mechanism 20, and a recovering mechanism 30. Wherein the performance detection mechanism 20 is located between the retrieval mechanism 30 and the packaging mechanism 10.

The above-mentioned packaging mechanism 10 is used for packaging the flexible glass 300 to be detected, so that the outer surface of the flexible glass 300 to be detected is coated with a protective film, and the packaging mechanism 10 is in butt joint with the performance detecting mechanism 20, so that the flexible glass 300 to be detected coated with the protective film can be conveyed to the performance detecting mechanism 20.

In this embodiment, the specific structure of the packaging mechanism 10 is not limited, as long as the packaging mechanism 10 can cover the outer surface of the flexible glass 300 to be tested with a protective film, and can transfer the flexible glass 300 to be tested to the next process (i.e. the performance detecting mechanism 20) after the protective film is covered.

It should be noted that, the packaging mechanism 10 is provided to cover the flexible glass 300 to be detected by using the protective film, so that after the bending performance of the performance detecting mechanism 20 is detected, if the flexible glass 300 to be detected is a defective product, the flexible glass 300 to be detected can be covered by the protective film, so that the problem that the flexible glass 300 to be detected is inconvenient to collect after being broken can be solved (the properties of the flexible glass and the toughened glass are similar, the flexible glass and the toughened glass are not broken into two pieces but are broken into pieces after being broken, particularly, the central bending area is broken into powder).

The performance detecting mechanism 20 is used between the packaging mechanism 10 and the recycling mechanism 30 for detecting bending performance of the flexible glass 300 to be detected, which is coated with the protective film. The specific structure for detecting the bending performance is not limited in the application, and a person skilled in the art can design the bending performance according to actual requirements.

The recovery mechanism 30 is located at a side of the performance detection mechanism 20 away from the packaging mechanism 10, and is configured to recover the flexible glass 300 to be detected according to the state of the flexible glass 300 to be detected (i.e. according to whether the flexible glass 300 to be detected is good or defective) after the flexible glass 300 to be detected is subjected to bending performance detection.

It should be noted that, the present application may perform performance detection on the flexible glass 300 to be detected with a size within 400mm×300m and a thickness between 20 μm and 100 μm, and the bending radius of the flexible glass 300 to be detected may be between 0.5mm and 10 mm.

In summary, the bending performance detecting apparatus provided in the present application includes a packaging mechanism 10, a performance detecting mechanism 20, and a recovering mechanism 30; the performance detection mechanism 20 is located between the packaging mechanism 10 and the recovery mechanism 30, the packaging mechanism 10 is used for respectively coating protective films on two opposite sides of the flexible glass 300 to be detected and transmitting the protective films to the performance detection mechanism 20, the performance detection mechanism 20 is used for detecting bending performance of the flexible glass 300 to be detected and transmitting the bending performance to the recovery mechanism 30, and the recovery mechanism 30 is used for collecting the flexible glass 300 to be detected after the bending performance detection by the performance detection mechanism 20. According to the method, the flexible glass 300 to be detected is coated by the packaging mechanism 10, so that after the flexible glass 300 to be detected is detected by the performance detection mechanism 20, the protective film can protect the flexible glass 300 to be detected, and fragments after the flexible glass 300 to be detected is broken affect the working procedure; by respectively butting the performance detection mechanism 20 with the packaging mechanism 10 and the recovery mechanism 30, the whole detection process can be in a full-automatic state, and the degree of automation and the detection efficiency of the flexible glass 300 to be detected can be improved; by providing the recovery mechanism 30, the flexible glass 300 to be detected, which is subjected to bending performance detection, can be recovered. The bending performance detection device provided by the application is higher in automation degree, can enable the flexible glass 300 to be detected to be applied to industrial mass production, can improve detection efficiency, and has higher practical value.

Referring to fig. 3 in combination, optionally, the packaging mechanism 10 includes a fixing table 11, a first roller 12, a second roller 13, a collecting roller 14, a first motor 15 for driving the collecting roller 14 to rotate, and a trimming assembly 16; one end of the first protective film 100 is wound on the first roller 12, and the other end is wound around the fixing table 11 and is wound on the collecting roller 14; one end of the second protective film 200 is wound on the second roller 13, and the other end is wound on the collecting roller 14 after bypassing the fixing table 11; the first roller 12 and the collecting roller 14 are positioned on the same side of the fixed table 11, and the first roller 12 is positioned on the side of the fixed table 11 away from the second roller 13; the edge cutting assembly 16 is located above the fixing table 11 and is used for cutting edges of the flexible glass 300 to be detected.

Wherein, the fixing table 11 is used for providing support for the first protective film 100, the flexible glass 300 to be tested and the second protective film 200. Opposite ends of the fixing table 11 may be provided in an arc shape, or guide posts 112 may be provided at the opposite ends of the fixing table 11, respectively, as shown in fig. 3. In this way, the opposite end portions of the fixing base 11 can guide the movement of the first protective film 100, and damage to the first protective film 100 by the end portions of the fixing base 11 can be avoided.

The first roller 12 is located at one side of the fixed table 11, and the second roller 13 is located at the other side of the fixed table 11. Wherein, the first roller 12 is used for winding one end of the first protective film 100, the second roller 13 is used for winding one end of the second protective film 200, and the other ends of the first protective film 100 and the second protective film 200 are wound on the collecting roller 14, as shown in fig. 3. The flexible glass 300 to be detected is arranged on the first protective film 100, the first motor 15 drives the collecting roller 14 to rotate, and the collecting roller 14 can drive the first roller 12 and the second roller 13 to rotate, so that the first protective film 100 and the second protective film 200 are coated on two opposite sides of the flexible glass 300 to be detected.

The trimming assembly 16 is located above the fixing table 11 and is used for trimming the to-be-detected flexible glass 300 coated with the first protective film 100 and the second protective film 200, so that the to-be-detected flexible glass 300 coated with the first protective film 100 and the second protective film 200 is cut, and the to-be-detected flexible glass 300 coated with the first protective film 100 and the second protective film 200 is separated from the winding of the first protective film 100 and the second protective film 200 respectively, so that redundant first protective film 100 and second protective film 200 around the to-be-detected flexible glass 300 are cut off.

The specific structure of the edge cutting assembly 16 is not limited in this application, and the edge cutting assembly 16 may include a motor and a guillotine assembly electrically connected to the motor, where the motor is used to drive the guillotine assembly to move toward a direction close to the fixed table 11, and the guillotine assembly is used to cut edges of the flexible glass 300 to be detected. The guillotine group is matched with the outer contour of the flexible glass 300 to be detected, and is used for cutting off the redundant first protective film 100 and second protective film 200 at the edge of the flexible glass 300 to be detected. It should be noted that, the front projection of the cutting edge of the guillotine set on the fixed table 11 should be larger than the area of the flexible glass 300 to be detected, and the flexible glass 300 to be detected should be located at the center of the front projection of the cutting edge of the guillotine set on the fixed table 11, so that the periphery of the flexible glass 300 to be detected is provided with a protective film for wrapping.

Also, in this embodiment, the packaging mechanism 10 further includes a third roller 17, where the third roller 17 is located on a side of the fixed table 11 facing away from the first roller 12 and between the first roller 12 and the second roller 13, and one end of the second protective film 200 is wound on the second roller 13, and the other end is wound on the collecting roller 14 through the third roller 17, as shown in fig. 3.

As shown in fig. 3, a motor for driving the third roller 17 to rotate may be connected to the third roller 17. It should be noted that, one end of each of the first protective film 100 and the second protective film 200 may be wound around the collection roller 14 after being wound around one end of the fixing table 11 near the performance detecting mechanism 20, so that one collection roller 14 may collect the waste films of the first protective film 100 and the second protective film 200 at the same time.

Optionally, the packaging mechanism 10 further includes an air source 18, and one end of the fixing table 11 near the performance detecting mechanism 20 is provided with a plurality of evenly distributed air injection holes 111, where the air source 18 is used for supplying air to the air injection holes 111, and the air injection holes 111 inject air toward the first protective film 100, so as to separate the first protective film 100 and the second protective film 200 from the coated flexible glass 300 to be detected respectively. The application is through setting up air supply 18 and fumarole 111, like this, the cladding has the flexible glass 300 of waiting to detect of first protection film 100 and second protection film 200 to be cut the back, can make the useless membrane of first protection film 100 and second protection film 200 separate with the flexible glass 300 of waiting to detect of cladding with first protection film 100 and second protection film 200 through fumarole 111, like this, be favorable to the cladding to have the flexible glass 300 of waiting to detect of first protection film 100 and second protection film 200 to get into next process (i.e. performance detection mechanism 20), and the useless membrane of first protection film 100 and second protection film 200 is collected by collection roller 14.

Referring to fig. 4 in combination, the performance detecting mechanism 20 includes a first conveyor belt 21 abutting against the packaging mechanism 10, two clamping plates 22 located above the first conveyor belt 21, and a driving mechanism for driving the two clamping plates 22 to move; the driving mechanism drives the two clamping plates 22 to move towards the direction approaching the first conveyor belt 21, so that the two clamping plates 22 are respectively clamped at the opposite ends of the flexible glass 300 to be detected; when the two clamping plates 22 are respectively clamped at the two opposite ends of the flexible glass 300 to be tested, the driving mechanism drives the two clamping plates 22 to move in opposite directions, and the two clamping plates 22 are used for driving the flexible glass 300 to be tested to fold.

The driving mechanism is used for driving the two clamping plates 22 to move towards or away from the fixed table 11, and is used for driving the two clamping plates 22 to move towards or away from each other.

Alternatively, the driving mechanism includes a first driving mechanism 23 and a second driving mechanism 24, the first driving mechanism 23 is used for driving the two clamping plates 22 to approach or separate from the first conveyor belt 21, and the second driving mechanism 24 is used for driving the two clamping plates 22 to approach or separate from each other.

Also, the first driving mechanism 23 and the second driving mechanism 24 may include two driving mechanisms, respectively, so that the two first driving mechanisms 23 may be used to drive the two clamping plates 22 to approach or separate from the first conveyor belt 21 at the same time; the two second driving mechanisms 24 may be used to drive the two clamping plates 22 toward each other or away from each other, respectively.

It should be noted that, the first driving mechanism 23 drives the clamping plates 22 to move toward the direction approaching the fixing table 11, so that the two clamping plates 22 can respectively clamp the opposite ends of the flexible glass 300 to be tested, as shown in fig. 4; when the two clamping plates 22 are respectively clamped at two opposite ends of the flexible glass 300 to be tested, the driving mechanism drives the two clamping plates 22 to move in opposite directions, and the two clamping plates 22 are used for driving the flexible glass 300 to be tested to fold, as shown in fig. 6, so that the clamping plates 22 can drive the flexible glass 300 to be tested to bend.

Optionally, the performance inspection mechanism 20 of the present application may also include a spacer plate 25 positioned between the two clamping plates 22. In this way, the two clamping plates 22 are driven to move in opposite directions, and when the two clamping plates 22 move in opposite directions to the limit position, the two clamping plates 22 are respectively attached to two opposite sides of the partition plate 25, so that the bending radius of the flexible glass 300 to be detected can be limited by the partition plate 25. Thus, the folding diameter of the flexible glass 300 to be detected can be controlled by changing the partition plates 25 with different thicknesses, and the folding diameter is the thickness of the partition plates 25.

In addition, in order to make the clamping of the two clamping plates 22 more stable and reliable when clamping the opposite ends of the flexible ratio to be detected, alternatively, when the two clamping plates 22 are respectively clamped at the opposite ends of the flexible glass 300 to be detected, the two clamping plates 22 are respectively vacuum-absorbed with the opposite ends of the flexible glass 300 to be detected.

In this embodiment, the performance detecting mechanism 20 may further include a guide rail 26, and the two clamping plates 22 are slidably connected to the guide rail 26, respectively, and the two clamping plates 22 can slide on the guide rail 26 along the driving direction of the first conveyor belt 21. In the present embodiment, the movement of the two clamp plates 22 in the driving direction of the first driving mechanism 23 is limited (i.e., the two clamp plates 22 can move in the transverse direction of the orientation shown in fig. 4, but cannot move longitudinally).

Of course, two guide rails 26 may be provided, and as shown in fig. 4, both guide rails 26 are provided side by side.

Referring to fig. 5, optionally, the recovery mechanism 30 includes a good product recovery portion 31 and a waste product recovery portion 32, the good product recovery portion 31 is configured to collect the qualified flexible glass 300 to be detected after the performance detection mechanism 20 performs the bending performance detection, and the waste product recovery portion 32 is configured to collect the unqualified flexible glass 300 to be detected after the performance detection mechanism 20 performs the bending performance detection. The present application is through setting up yields recovery unit 31 and waste recovery unit 32, like this, can make wait to detect flexible glass 300 after performance detection mechanism 20 detects and classify and collect.

In this embodiment, the recycling mechanism 30 further includes a detector 36, where the detector 36 is configured to detect the flexible glass 300 to be detected after the performance detecting mechanism 20 tests, and determine whether the flexible glass 300 to be detected is good or defective.

The properties of the flexible glass 300 to be tested and the tempered glass are somewhat similar, and after breaking, the flexible glass 300 is broken into pieces instead of two pieces, particularly, the central bending area is broken into powder, so that a clear white mark is also formed in the central area in a film-covered state, and therefore, the detector 36 can distinguish whether the flexible glass 300 to be tested is bad or bad (i.e. waste) according to the way of detecting the white mark. When the detector 36 detects that the flexible glass 300 to be detected is good, the recovery mechanism 30 recovers the flexible glass 300 to be detected to a good collecting part; when the detector 36 detects that the flexible glass 300 to be detected is a defective product, the recovery mechanism 30 recovers the flexible glass 300 to be detected to the waste recovery portion 32.

Alternatively, the recovery mechanism 30 may further include a rotating plate 33 having one end abutting against the first conveyor belt 21, a second conveyor belt 34 located on a side of the rotating plate 33 away from the performance detecting mechanism 20, and a second motor 35 for driving the rotating plate 33 to rotate; one end of the second conveyor belt 34, which is far away from the rotating plate 33, is in butt joint with the good product recovery part 31; when the flexible glass 300 to be inspected is a waste, the second motor 35 is used for driving the rotating plate 33 to rotate, so that the first conveyor belt 21 is in butt joint with the waste recovery part 32 through the rotating plate 33; when the flexible glass 300 to be inspected is good, the second motor 35 is used for driving the rotating plate 33 to rotate, so that the first conveyor belt 21 is in butt joint with the second conveyor belt 34 through the rotating plate 33.

It should be noted that, when the flexible glass 300 to be detected is good, the second motor 35 is used to drive the rotating plate 33 to rotate, so that the end of the rotating plate 33 away from the performance detecting mechanism 20 is in butt joint with the second conveyor 34, and thus the flexible glass 300 to be detected can sequentially pass through the rotating plate 33 and the second conveyor 34 and then enter the good recovery portion 31 located at the end of the second conveyor 34; when the flexible glass 300 to be detected is a defective product, the second motor 35 is used for driving the rotating plate 33 to rotate, so that the end of the rotating plate 33 away from the performance detecting mechanism 20 is disconnected from the second conveyor 34, and the end of the rotating plate 33 away from the performance detecting mechanism 20 is abutted against the waste recycling portion 32, so that the flexible glass 300 to be detected can enter the waste recycling portion 32 after passing through the rotating plate 33 in sequence.

In addition, in the present embodiment, the recovery mechanism 30 further includes a counter 37, and the counter 37 is located above the second conveyor 34 or at the good recovery portion 31 for counting the number of good products.

The above description is only of alternative embodiments of the present utility model and is not intended to limit the present utility model, and various modifications and variations will be apparent to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

In addition, the specific features described in the above embodiments may be combined in any suitable manner, and in order to avoid unnecessary repetition, various possible combinations are not described further.

Claims (10)

1. The bending performance detection device is characterized by comprising a packaging mechanism, a performance detection mechanism and a recovery mechanism; the performance detection mechanism is located between the packaging mechanism and the recovery mechanism, the packaging mechanism is used for respectively coating protective films on two opposite sides of the flexible glass to be detected and transmitting the protective films to the performance detection mechanism, the performance detection mechanism is used for detecting bending performance of the flexible glass to be detected and transmitting the bending performance to the recovery mechanism, and the recovery mechanism is used for collecting the flexible glass to be detected after the bending performance detection of the performance detection mechanism.

2. The bending performance detection device according to claim 1, wherein the packaging mechanism comprises a fixed table, a first roller, a second roller, a collecting roller, a first motor for driving the collecting roller to rotate, and a trimming assembly; one end of the first protective film is wound on the first roller, and the other end of the first protective film bypasses the fixed table and is wound on the collecting roller; one end of the second protective film is wound on the second roller, and the other end of the second protective film is wound on the collecting roller after bypassing the fixed table; the first roller and the collecting roller are positioned on the same side of the fixed table, and the first roller is positioned on one side of the fixed table, which is away from the second roller; the edge cutting assembly is located above the fixed table and used for cutting edges of the flexible glass to be detected.

3. The bending property detection device according to claim 2, wherein the packaging mechanism further comprises a third roller, the third roller is located at one side of the fixed table away from the first roller and located between the first roller and the second roller, one end of the second protective film is wound on the second roller, and the other end of the second protective film is wound on the collecting roller through the third roller.

4. The bending performance detection device according to claim 2, wherein the packaging mechanism further comprises an air source, a plurality of evenly distributed air injection holes are formed in one end of the fixing table, which is close to the performance detection mechanism, the air source is used for supplying air to the air injection holes, the air injection holes are used for injecting air towards the first protective film, and the first protective film and the second protective film are respectively separated from the coated flexible glass to be detected.

5. The bending performance testing apparatus according to any one of claims 1 to 4, wherein said performance testing mechanism comprises a first conveyor belt abutting said packaging mechanism, two clamping plates positioned above said first conveyor belt, and a driving mechanism for driving movement of both said clamping plates; the driving mechanism drives the two clamping plates to move towards the direction close to the first conveyor belt, so that the two clamping plates are respectively clamped at the two opposite ends of the flexible glass to be detected; when the two clamping plates are respectively clamped at the two opposite ends of the flexible glass to be detected, the driving mechanism drives the two clamping plates to move in opposite directions, and the two clamping plates are used for driving the flexible glass to be detected to fold.

6. The bending performance testing apparatus according to claim 5, wherein the driving mechanism comprises a first driving mechanism for driving the two clamping plates toward or away from the first conveyor belt, and a second driving mechanism for driving the two clamping plates toward or away from each other.

7. The bending property detection apparatus according to claim 5, wherein the property detection mechanism further comprises a spacer plate located between the two clamping plates.

8. The bending performance testing apparatus according to claim 5, wherein when the two clamping plates are respectively clamped at opposite ends of the flexible glass to be tested, the two clamping plates are respectively vacuum-adsorbed to the opposite ends of the flexible glass to be tested.

9. The bending performance testing device according to claim 5, wherein the recovery mechanism comprises a good recovery portion and a waste recovery portion, the good recovery portion is used for collecting the flexible glass to be tested which is qualified after the bending performance testing by the performance testing mechanism, and the waste recovery portion is used for collecting the flexible glass to be tested which is unqualified after the bending performance testing by the performance testing mechanism.

10. The bending property detection apparatus according to claim 9, wherein the recovery mechanism further comprises a rotating plate having one end abutting against the first conveyor belt, a second conveyor belt located on a side of the rotating plate remote from the property detection mechanism, and a second motor for driving the rotating plate to rotate; one end of the second conveyor belt, which is far away from the rotating plate, is in butt joint with the good product recovery part; when the flexible glass to be detected is waste, the second motor is used for driving the rotating plate to rotate, so that the first conveyor belt is in butt joint with the waste recovery part through the rotating plate; when the flexible glass to be detected is good, the second motor is used for driving the rotating plate to rotate, so that the first conveyor belt is in butt joint with the second conveyor belt through the rotating plate;

and/or the recovery mechanism further comprises a detector, wherein the detector is used for detecting the flexible glass to be detected after the performance detection mechanism tests and determining whether the flexible glass to be detected is good or waste.