Patent Description:
The curling display, as a new flexible display application form, has attracted extensive attention. The curling action can be achieved by means of a continuously applied tension and a rotatable shaft. The display screen that can be used for a curling display generally require a support structure to assist in the curling and unfolding actions, and the design of the support structure has a great impact on the curling implementation and reliability of the curling display. The patent document <CIT> discloses a flexible display device. A flexible display device according to an embodiment of the present invention is configured to include a body, a moving plate, a flexible display, and a driving module. The driving module is configured to include a bracket, a sliding plate including a rack, a driving motor, and a driving gear. The driving module is coupled to a body and a moving plate after assembling the driving module so that it is possible to prevent a sliding plate which slidably moves together with a flexible display after assembling the flexible display device from being loosen and also prevent the idle operation of the driving gear. The patent document <CIT> discloses a flexible display device. The flexible display device comprises a flexible screen and a storage device, the storage device comprises a shell structure, a roller structure, a fixed shaft and a driving mechanism; a first opening allowing the flexible screen to extend out is formed in the side wall of the shell structure; the roller structure is located in the shell structure, and a flexible screen storage cavity is formed by the roller structure and the shell structure; the fixed shaft is arranged in the roller structure and is coaxial with the roller structure, and the two ends of the fixed shaft are fixedly connected with the shell structure; the roller structure is rotatably connected with the fixed shaft, and the driving mechanism is used for driving the roller structure to rotate, so that the flexible screen is contracted in the flexible screen storage cavity under the rotation of the roller structure and is wound on the roller structure. According to the embodiment of the invention, the problem that the flexible screen is easily damaged due to overlarge curling degree of the flexible screen in the existing flexible display device is solved, and the flexible screen has a relatively large curvature radius during curling and storage, so that the internal structure of the flexible screen is prevented from being damaged by over-bending.

The present application discloses a flexible display apparatus and a support assembly, to improve the structure of the curling display and increase the reliability of the curling and unfolding actions of the curling display.

In a first aspect, an embodiment of the present application provides a flexible display apparatus, including:.

Optionally, the flexible display apparatus further includes a first adhesive layer between the traction part and the first support member, where the traction part and the first support member are bonded by the first adhesive layer.

Optionally, an edge of the first support member close to the first end exceeds an edge of the flexible display screen close to the first end, and the traction part is connected to a part of the first support member beyond the flexible display screen.

Optionally, the traction part is bonded to a surface of the first support member facing the flexible display screen.

Optionally, the traction part includes a double-layer structure, and the double-layer structure is respectively bonded to two surfaces of the first support member.

Optionally, an edge of the first support member close to the first end is substantially aligned with an edge of the flexible display screen close to the first end, and the traction part is bonded to a surface of the first support member away from the flexible display screen.

Optionally, the first support member is provided with a first opening in a thickness direction of the first support member, the traction part is provided with a second opening, the first support member is connected to the traction part through connectors inserted into the first opening and the second opening, and the connectors are made of polymer material.

Optionally, the first opening is a half-through hole not penetrating the first support member or a through hole penetrating the first support member; and the second opening is a through hole penetrating the traction part.

Optionally, the flexible display apparatus further includes a casing in which the roller shaft and the tension applying component are arranged;
where the first end of the support assembly is in the casing, and the second end of the support assembly bypasses the roller shaft and protrudes out of the casing.

Optionally, the first support member is provided with a hollow opening in the rolling and sliding area.

Optionally, the first support member is provided with hollow openings in both the rolling and sliding area and the plane area.

Optionally, the hollow opening includes at least two rows of through holes, each row of through holes is arranged in an extending direction of the roller shaft, the through holes in odd-numbered rows and the through holes in even-numbered rows are at least partly staggered; and the through holes are strip-shaped holes extending in the extending direction of the roller shaft.

Optionally, the second support member is in the rolling and sliding area.

Optionally, the support assembly further includes a reinforcement structure arranged on a side of the first support member away from the flexible display screen and arranged in the plane area.

Optionally, the reinforcement structure is made of a same material as the first support member or the second support member.

Optionally, a thickness of the reinforcement structure is substantially same as a thickness of the second support member in a direction perpendicular to the first support member.

Optionally, the flexible display apparatus further includes a second adhesive layer between the second support member and the first support member, where the second support member and the first support member are bonded through the second adhesive layer; and
the second adhesive layer includes a base material layer and adhesive layers on both sides of the base material layer, and the base material layer is made of polymer material.

Optionally, the first support member includes metal or alloy material, and a thickness of the first support member is <NUM>-<NUM>.

Optionally, the second support member includes metal, alloy or metal oxide material, a width of each of the support bars in the second support member is <NUM>. <NUM>-<NUM>, and a thickness of each of the support bars in a direction perpendicular to the first support member is <NUM>-<NUM>.

Optionally, at least some of the plurality of support bars are provided with limiting parts, and positions between the at least some of the plurality of support bars and adjacent support bars thereof are limited relative to the limiting parts.

Optionally, the limiting part includes at least one of a protrusion structure and a groove structure; the protrusion structure includes an arc protrusion, a square protrusion, a trapezoidal protrusion and a concave protrusion; and the groove structure includes an arc groove, a square groove and a trapezoidal groove.

Optionally, the plurality of support bars include a first support bar located at one end; among the plurality of support bars, one sides of remaining support bars other than the first support bar facing the first support bar each are provided with the limiting part, and the limiting part is the protrusion structure.

Optionally, the plurality of support bars include two end support bars at two ends and middle support bars between the two end support bars; two sides of each middle support bar facing the two end support bars are provided with the limiting part, one side of each end support bar facing the middle support bars is provided with the limiting part, and the limiting part is the protrusion structure.

Optionally, a first side of each support bar is provided with a first-type limiting part, and a second side of the each support bar is provided with a second-type limiting part, and shapes of the first-type limiting part and the second-type limiting part are complementary; and the first-type limiting part and the second-type limiting part of two adjacent support bars are complementary and coordinate.

Optionally, the plurality of support bars are provided with at least two rows of limiting parts, and each row of limiting parts are aligned in an arrangement direction of the support bars.

Optionally, limiting parts in adjacent rows are arranged alternately.

Optionally, each support bar includes two or more sections of bars, sections of bars of the plurality of support bars are arranged side by side, and each row of bars is provided with at least one row of limiting parts.

The technical solutions in the embodiments of the present application will be described clearly and completely below in combination with the accompanying drawings in the embodiments of the present application. Obviously the described embodiments are only a part of the embodiments of the present application but not all the embodiments. Based upon the embodiments of the present application, all of other embodiments obtained within the limits defined by the appended claims by those ordinary skilled in the art without creative work pertain to the protection scope of the present application.

It should be understood that the terms used herein to describe the embodiments of the present invention are not intended to limit and/or define the scope of the present invention. For example, unless otherwise defined, the technical or scientific terms used in the invention shall have the general meanings understood by those ordinary skilled in the art. The "first", "second" and similar words used in the invention do not represent any order, number or importance, and are only used to distinguish different components. Unless otherwise indicated clearly in the context, the singular "a", "one", "the" or the like does not denote a limitation of number but rather the existence of at least one.

As shown in <FIG> and <FIG>, an embodiment of the present application provides a flexible display apparatus, which includes:.

The 'rolling and sliding area' is an area where the flexible module passes through the roller shaft during the curling and unfolding actions, and can also be called the curling part; and correspondingly, the 'plane area' is an area where the flexible module does not pass through the roller shaft during the curling and unfolding actions, and can also be called a non-curling part.

The flexible module <NUM> includes a flexible display screen <NUM> and a support assembly <NUM>; the support assembly <NUM> is arranged on a surface of the flexible display screen <NUM> facing the roller shaft <NUM>, and includes a first support member <NUM> and a second support member <NUM>; the first support member <NUM> is a bendable plate-like structure, and the second support member <NUM> is arranged on a side of the first support member <NUM> away from the flexible display screen <NUM> and includes a plurality of support bars <NUM> arranged in a moving direction of the flexible module <NUM> (such as the direction indicated by the double-headed arrow in <FIG>, that is, the direction in which the flexible module <NUM> moves back and forth around the roller shaft <NUM>), and each support bar <NUM> has a same extending direction as the roller shaft <NUM> and is fixed on the first support member <NUM>.

In the flexible display apparatus provided by the embodiment of the present application, the support assembly <NUM> is used to support the flexible display screen <NUM>, and the support assembly <NUM> moves around the roller shaft <NUM> and can drive the flexible display screen <NUM> to realize unfolding and folding; and a continuous tension is applied to the support assembly <NUM> and the support assembly <NUM> is supported by the roller shaft <NUM>, to keep the support assembly <NUM> in the tensioned flat state and thereby ensure the reliability of the unfolding and folding actions of the flexible module <NUM>.

Specifically, in the support assembly <NUM>, the first support member <NUM> is a plate-like structure and is close to the back of the flexible display screen <NUM>, and has the main function of fixing the size and shape of the flexible display screen <NUM> and enhancing the support and dynamic curling reliability of the flexible module <NUM>; and optionally, the second support member <NUM> may be a plurality of mutually independent support bars <NUM>, which are not physically connected to each other. These support bars <NUM> are arranged close to the surface of the roller shaft <NUM>, are parallel to each other and have the same extending direction as the roller shaft <NUM>. During the process in which the flexible module <NUM> curls and moves around the roller shaft <NUM>, the design of the independent support bars <NUM> can reduce the stress influence on the flexible module <NUM> as much as possible to improve the curling reliability of the flexible module <NUM>, and can also reduce the overall resilience force of the flexible module <NUM>, and reduce the difficulty of assembling the complete flexible display apparatus and the difficulty of realizing the curling action; and furthermore, while providing the support performance, the support bars <NUM> can also strengthen the friction between the flexible module <NUM> and the roller shaft <NUM>, thereby improving the stability and reliability of the flexible module <NUM> moving and folding/unfolding around the roller shaft <NUM>.

To sum up, through the two-layer support structure with the first support member <NUM> and the second support member <NUM>, the flat state of the flexible display screen <NUM> can be maintained while enhancing the curling reliability of the flexible module <NUM>, and the movement of the flexible module <NUM> around the roller shaft <NUM> is improved to realize the reliability of the unfolding and folding actions, thereby improving the assembly yield and service life of the flexible display apparatus.

In some embodiments, the flexible display screen <NUM> and the first support member <NUM> may be fixed by bonding, and the first support member <NUM> and the second support member <NUM> may also be fixed by bonding; or the first support member <NUM> may also be integrally formed with the second support member <NUM>.

Exemplarily, as shown in <FIG>, the flexible display screen <NUM> may include a flexible display <NUM> and a cover plate <NUM>, where the cover plate <NUM> is located on the side of the flexible display <NUM> away from the support assembly <NUM> and can support and protect the display surface of the flexible display <NUM>.

In some embodiments, the flexible display apparatus provided by the embodiments of the present application may further include a tension applying component (such as a traction part <NUM>, a steering shaft component <NUM> and a fixing part <NUM> in <FIG>). Referring to <FIG>, the support assembly <NUM> includes a first end and a second end oppositely arranged; the support assembly <NUM> bypasses the roller shaft <NUM> along the direction from the first end to the second end, and the first end of the support assembly <NUM> is connected to the tension applying component.

Specifically, the first end of the support assembly <NUM> is connected to the tension applying component, and the fixing and curling actions of the flexible module <NUM> can be realized through the tension applied by the tension applying component and the support of the roller shaft <NUM>.

As shown in <FIG>, the tension applying component includes a traction part <NUM>, a steering shaft component <NUM> and a fixing part <NUM>. The traction part <NUM> includes a third end and a fourth end, the third end is connected to the first support member <NUM> of the support assembly <NUM>, and the fourth end bypasses the steering shaft component <NUM> and is connected to the fixing part <NUM>; and the roller shaft <NUM> can move relative to the fixing part <NUM>, to drive the flexible module <NUM> to move and unfold around the roller shaft <NUM>.

Exemplarily, the traction part <NUM> may be a flexible strip or a flexible rope.

The steering shaft component <NUM> includes a moving shaft <NUM> and a fixed shaft <NUM>; the traction part <NUM> bypasses the fixed shaft <NUM> and the moving shaft <NUM> in turn so that the extending direction of the traction part <NUM> is reversed twice; where the position of the shaft center of the fixed shaft <NUM> is fixed relative to the fixing part <NUM>, for example, the fixed shaft <NUM> and the fixing part <NUM> can be connected on the casing of the same part so that their relative positions are fixed; and the position of the shaft center of the moving shaft <NUM> is fixed relative to the shaft center of the roller shaft <NUM>, for example, the central axis of the moving shaft <NUM> and the central axis of the roller shaft <NUM> can be connected through a connecting rod to ensure that the relative positions thereof remain unchanged. The moving shaft <NUM> and the roller shaft <NUM> can move synchronously to drive the flexible module <NUM> to move and unfold around the roller shaft <NUM>.

Exemplarily, the fixed shaft <NUM> can be either a rollable shaft or a non-rollable cylindrical pin; and similarly, the moving shaft <NUM> can be either a rollable shaft or a non-rollable cylindrical pin. Optionally, the fixed shaft <NUM> is a cylindrical pin, and the moving shaft <NUM> is a rollable shaft.

Exemplarily, the roller shaft <NUM> is a rollable shaft, and the flexible module <NUM> and the roller shaft <NUM> are in damping contact and can drive each other. When the flexible module <NUM> moves around the roller shaft <NUM>, the roller shaft <NUM> rolls synchronously.

Specifically, during the two reversals, the extending direction of the traction part <NUM> after each reversal is parallel to the extending direction before the reversal, so that the traction part <NUM> can generally extend in one dimensional direction, that is, extend between the roller shaft <NUM> and the fixing part <NUM>. Then, on the one hand, the space volume occupied by the roller shaft <NUM>, the traction part <NUM>, the steering shaft component <NUM> and the fixing part <NUM> can be reduced to facilitate them to be accommodated in the module casing <NUM>; and on the one hand, the synchronous movement of the moving shaft <NUM> and the roller shaft <NUM> away from the fixing part <NUM> and the rolling of the roller shaft <NUM> can drive the flexible module <NUM> to move around the roller shaft <NUM>, which is beneficial for the flexible module <NUM> to realize the unfolding action.

Exemplarily, the traction part <NUM> can maintain a certain stretching tension, through which the flexible module <NUM>, the moving shaft <NUM> and the roller shaft <NUM> can be pulled toward the fixing part <NUM>, so that the flexible module <NUM> realizes folding.

Exemplarily, as shown in <FIG>, the flexible display apparatus further includes a casing <NUM> in which the roller shaft <NUM> and the tension applying assembly are both located; the first end of the support assembly <NUM> is located in the casing <NUM> and is connected to the tension applying assembly, and the second end of the support assembly <NUM> bypasses the roller shaft <NUM> and protrudes out of the casing <NUM>, that is, one end of the flexible module <NUM> is located in the casing <NUM>, and the other end bypasses the roller shaft <NUM> and protrudes out of the casing <NUM>.

Exemplarily, the casing <NUM> may include two parts that can move relative to each other, where the position of the first part is fixed relative to the roller shaft <NUM> and the moving shaft <NUM>, and the position of the second part is fixed relative to the fixing part <NUM> and the fixed shaft <NUM>; when the roller shaft <NUM> and the moving shaft <NUM> move relative to the fixing part <NUM>, the first part and the second part of the casing <NUM> can move relative to each other.

Specifically, for example, the fixing part <NUM> can be a connecting part of the second part in the casing <NUM>; one end of the flexible module <NUM> is connected to the fixing part <NUM> by the tension applying component, and the other end of the flexible module <NUM> bypasses the roller shaft <NUM> and protrudes out of the casing <NUM>. Referring to <FIG>, when the moving shaft <NUM> and the roller shaft <NUM> move away from the fixing part <NUM>, the rolling of the roller shaft <NUM> can drive the flexible module <NUM> to protrude out of the casing <NUM> and unfold; and referring to <FIG> and <FIG>, the flexible module <NUM> can move toward the fixing part <NUM> under the pulling of the traction part <NUM>, so as to retract the flexible module <NUM> into the casing <NUM>.

Of course, the curling movement of the flexible display apparatus provided by the embodiments of the present application is not limited to the driving mode described above, and can be adjusted according to actual requirements. For example, the relative positions of the fixing part <NUM> and the roller shaft <NUM> may be fixed, and the moving shaft <NUM> moves back and forth relative to the roller shaft <NUM>, to drive the traction part <NUM> to drive the flexible module <NUM> to move.

In some embodiments, as shown in <FIG>, <FIG>, the flexible display apparatus provided by the embodiments of the present application may further include a first adhesive layer <NUM> between the traction part <NUM> and the first support member <NUM>, where the traction part <NUM> and the first support member <NUM> are bonded by the first adhesive layer <NUM>.

Exemplarily, the edge of the first support member <NUM> close to the first end exceeds the edge of the flexible display screen <NUM> close to the first end, and the traction part <NUM> is connected to a part of the first support member <NUM> beyond the flexible display screen <NUM>. In other words, the length of the first support member <NUM> is greater than the length of the flexible display screen <NUM>, and the part of the first support member <NUM> beyond the flexible display screen <NUM> along the length direction is used to connect with the tension applying component, and the tension applying component applies a tension to the first support member <NUM> so that the entire flexible module <NUM> remains flat and achieves the curling action.

Exemplarily, as shown in <FIG>, the traction part <NUM> is bonded to a side surface of the first support member <NUM> facing the flexible display screen <NUM>. That is, the bonding part of the traction part <NUM> and the flexible display screen <NUM> are located on the same side of the first support member <NUM>.

Alternatively, as shown in <FIG>, the traction part <NUM> includes a double-layer structure, which is respectively bonded to two surfaces of the first support member <NUM>. That is, the traction part <NUM> is adhesively connected to two surfaces of the first support member <NUM>.

Of course, the edge of the first support member <NUM> close to the first end may also be substantially aligned with the edge of the flexible display screen <NUM> close to the first end; and at this time, the traction part <NUM> is bonded to a side surface of the first support member <NUM> away from the flexible display screen <NUM>. Specifically, 'substantially aligned' means that the distance between two edges is very small and within a set range, for example, the distance between two edges is within the range of ±<NUM>.

In some embodiments, as shown in <FIG>, the first support member <NUM> is provided with a first opening in the thickness direction of the first support member <NUM>, the traction part <NUM> is provided with a second opening, and the first support member <NUM> is connected to the traction part <NUM> through one or more connectors <NUM> inserted into the first opening and the second opening, so that the bonding strength between the first support member <NUM> and the traction part <NUM> can be increased, thereby reducing the width of the bonding area.

Specifically, the connector may be made of polymer material. For example, the connector may include polymer materials with a certain viscosity, such as resin, rubber, plastic and paint, and may specifically be formed by coating, filling and then curing. In this way, the material of the connector can be placed in the first opening and the second opening by the hole-dispensing process, and the first support member and the traction part can be tightly connected after the material of the connector is cured. Specifically, the material of the connector may be silicone rubber, epoxy resin, acrylic resin, polyethylene resin, or the like.

Exemplarily, the first opening may be a half-through hole not penetrating the first support member <NUM> or a through hole penetrating the first support member <NUM>; and the second opening may be a through hole penetrating the traction part <NUM>.

In some embodiments, as shown in <FIG>, the flexible module <NUM> further includes a second adhesive layer <NUM> located between the second support member <NUM> and the first support member <NUM>, where the second support member <NUM> and the first The supports <NUM> are bonded by the second adhesive layer <NUM>.

Exemplarily, the second adhesive layer may include a base material layer and adhesive layers on both sides of the base material layer, and the base material layer is made of polymer material. In other words, the second adhesive layer may adopt a double-sided adhesive structure.

Of course, the second adhesive layer is not limited to the double-sided adhesive tape, and may also adopt adhesive materials such as glue; and furthermore, the first adhesive layer may be made of the same material as the second adhesive layer, to facilitate the unified bonding process.

In some embodiments, the first support member is provided with a hollow opening in the rolling and sliding area; as shown in <FIG>, the first support member <NUM> may include a rolling and sliding part <NUM> located in the rolling and sliding area and a plane part located in the plane area <NUM>, where the rolling and sliding part <NUM> is configured to move around the roller shaft; and the rolling and sliding part <NUM> is provided with a hollow opening.

The 'rolling and sliding part' is an area where the first support member passes through the roller shaft during the curling and unfolding actions, and can also be called the curling part; and correspondingly, the 'plane part' is an area where the first support member does not pass through the roller shaft during the curling and unfolding actions, and can also be called the non-curling part.

The rolling and sliding part of the first support member is provided with a hollow opening, thus improving the flexibility of this part and improving the curling reliability.

Alternatively, the first support member may also be provided with hollow openings in both the rolling and sliding area and the plane area, that is, both the rolling and sliding part <NUM> and the plane part <NUM> of the first support member may be patterned.

Exemplarily, as shown in <FIG>, the hollow opening includes at least two rows of through holes <NUM>, each row of through holes <NUM> is arranged in an extending direction of the roller shaft, the through holes <NUM> in odd-numbered rows and the through holes <NUM> in even-numbered rows are at least partly staggered; and the through holes are strip-shaped holes extending in the extending direction of the roller shaft.

In some embodiments, as shown in <FIG>, the second support member <NUM> is located in the rolling and sliding area, that is, the second support member <NUM> is disposed on the rolling and sliding part <NUM> of the first support member <NUM>. Alternatively, the second support member <NUM> is disposed on the part of the flexible module that curls and moves around the roller shaft.

Specifically, the second support member <NUM> includes at least three support bars <NUM>.

Specifically, since the second support member <NUM> is an independent strip arranged side by side, the contact between the second support member <NUM> and the roller shaft can not only improve the support of the flexible display screen in the rolling and sliding area <NUM>, but also enhance the friction between the flexible module and the roller shaft, to improve the stability and reliability of the flexible module moving and folding around the roller shaft.

In some embodiments, as shown in <FIG>, the support assembly may further include a reinforcement structure <NUM> arranged on the side of the first support member <NUM> away from the flexible display screen and located in the plane area, that is, on the plane part <NUM> of the first support member <NUM>.

Exemplarily, the reinforcement structure <NUM> is made of a same material as the first support member <NUM> or the second support member <NUM>. For example, the reinforcement structure <NUM> may be made of stainless steel (SUS).

Exemplarily, the reinforcement structure <NUM> and the first support member <NUM> may be bonded and fixed by a third adhesive layer <NUM>. The third adhesive layer <NUM> is made of the same material as the second adhesive layer <NUM>.

In some embodiments, the thickness of the reinforcement structure <NUM> is roughly the same as the thickness of the second support member <NUM> in the direction perpendicular to the first support member <NUM>, where "roughly the same" means that the thicknesses of them is the same or the thickness difference is less than <NUM>%.

In some embodiments, the first support member includes metal or alloy material, which may be metal or alloy material with a high relative Young's modulus, such as stainless steel, structural steel, titanium alloy, etc., or may be metal with a low relative Young's modulus, such as copper and copper alloy, aluminum alloy, magnesium alloy, etc..

For example, the thickness of the first support member is <NUM>-<NUM>, and for example, may specifically be <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM>.

Alternatively, the first support member may also be a polymer film layer or an inorganic non-metallic layer that has a certain mechanical strength and can meet the requirements of flexibility and reliability, and for example, may be made of organic polymer material such as polyimide film or polyurethane foam, or inorganic non-metallic material such as glass or ceramics.

In some embodiments, the second support member includes metal, alloy or metal oxide material, and for example, may be specifically stainless steel, copper alloy, titanium alloy, etc., or a metal oxide such as ferrite, nickel oxide, etc. Exemplarily, the width of each support bar in the second support member is <NUM>-<NUM>, and the thickness of each support bar in the direction perpendicular to the first support member is <NUM>-<NUM>.

Specifically, when the support bar includes a structure such as limiting part or protrusion part, the 'width of each support bar' refers to the width of the main part of the support bar (other than the limiting part or protrusion part).

In some embodiments, as shown in <FIG>, at least some of the plurality of support bars <NUM> in the second support member are provided with limiting parts <NUM>, and relative positions between the at least some of the plurality of support bars <NUM> and adjacent support bars <NUM> thereof are limited by the limiting parts <NUM>.

Exemplarily, the limiting part <NUM> is a part of the support bar <NUM> and can be integrated with the main body of the support bar in the production process.

Specifically, the support bars <NUM> in the present application are fine structures and arranged independently of each other. Then, in the actual arrangement process, it is difficult to ensure the position of each support bar <NUM> and the spacing between support bars. In an embodiment of the present application, the limiting parts <NUM> are arranged on the support bars <NUM>, and the relative positions of adjacent support bars are defined by the limiting parts <NUM>, so that the positions of adjacent support bars <NUM> can be easily determined and the spacing can be maintained. In the actual process, the difficulty of arranging and fixing the positions of independent support bars <NUM> can be reduced.

Exemplarily, the limiting part <NUM> may include at least one of a protrusion structure and a groove structure.

For example, the limiting part <NUM> in <FIG> is a protrusion structure, and the limiting part <NUM> in <FIG> includes both a protruding structure and a groove structure.

Exemplarily, the protrusion structure may include an arc protrusion, a square protrusion, a trapezoidal protrusion, a concave protrusion, etc.; for example, the limiting part <NUM> in <FIG> and <FIG> to <NUM> is an arc protrusion, the limiting part <NUM> in <FIG> is a rectangular protrusion, and the limiting part <NUM> in <FIG> is a trapezoidal protrusion; the limiting part <NUM> in <FIG> includes a concave protrusion <NUM>; and the limiting part <NUM> in <FIG> includes a concave protrusion <NUM>.

Exemplarily, the groove structure includes an arc groove, a square groove and a trapezoidal groove. For example, the limiting part <NUM> in <FIG> includes an arc groove <NUM>.

In some embodiments, as shown in <FIG>, the plurality of support bars <NUM> include a first support bar <NUM> located at one end; the limiting part <NUM> is provided on a side of each support bar <NUM> other than the first support bar <NUM> among the plurality of support bars <NUM> facing the first support bar <NUM>, and the limiting part <NUM> is a protrusion structure.

Specifically, "one end" refers to one end along the arrangement direction of the support bars, so the first support bar refers to one end support bar; in other words, in the embodiments of the present application, a limiting part is provided on the side of each support bar <NUM> other than the support bar on one end facing the end, thus ensuring that the relative position between every two adjacent support bars can be limited by the limiting part.

In other embodiments, as shown in <FIG> and <FIG>, the plurality of support bars <NUM> include two end support bars <NUM> located at two ends and middle support bars <NUM> located between the two end support bars <NUM>. Specifically, 'two ends' refer to two ends along the arrangement direction of the support bars, so the two end support bars refer to the support bars located at both ends.

Exemplarily, two sides of each middle support bar <NUM> facing the two end support bars <NUM> are provided with a limiting part <NUM> respectively, and a side of each support bar <NUM> facing the middle support bar <NUM> is provided with a limiting part <NUM>; and the limiting part <NUM> is a protrusion structure.

According to the above arrangement, two limiting parts <NUM> are arranged between every two adjacent support bars. Specifically, these two limiting parts <NUM> can limit the gap between two adjacent support bars, and the relative positional relationship of the two limiting parts <NUM> (for example, the two limiting parts <NUM> are aligned or staggered in the direction perpendicular to the support bars) is also beneficial to keep the two support bars aligned in the extending direction.

In some embodiments, a first side of each support bar is provided with a first-type limiting part, and a second side of the each support bar is provided with a second-type limiting part, and shapes of the first-type limiting part and the second-type limiting part are complementary; and the first-type limiting part and the second-type limiting part of two adjacent support bars are complementary and coordinate.

Specifically, through the complementary cooperation between the first-type limiting part and the second-type limiting part of two adjacent support bars, the two adjacent support bars can be mutually limited to thereby avoid the misalignment between the adjacent support bars, which is beneficial to reduce the arrangement difficulty of the support bars and simultaneously maintain the relative positional relationship between the support bars.

For example, in <FIG>, two sides of each support bar <NUM> are respectively provided with a first-type limiting part and a second-type limiting part, which are respectively an arc protrusion <NUM> and an arc groove <NUM>. The relative positional relationship between the support bars <NUM> can be maintained by the cooperation of the two complementary-shaped limiting parts <NUM> (i.e., the arc protrusion <NUM> and the arc groove <NUM>). In <FIG>, two sides of each support bar <NUM> are respectively provided with a first-type limiting part and a second-type limiting part, which are respectively an arc protrusion <NUM> and a concave protrusion <NUM>, where the groove part of the concave protrusion <NUM> is an arc groove. The relative positional relationship between the support bars <NUM> can be maintained by the cooperation of the two complementary-shaped limiting parts <NUM> (i.e., the arc protrusion <NUM> and the concave protrusion <NUM>). In <FIG>, two sides of each support bar <NUM> are respectively provided with a first-type limiting part and a second-type limiting part, which are respectively a trapezoidal protrusion <NUM> and a concave protrusion <NUM>, where the groove part of the concave protrusion <NUM> is a trapezoidal groove. The relative positional relationship between the support bars <NUM> can be maintained by the cooperation of the two complementary-shaped limiting parts <NUM> (i.e., the trapezoidal protrusion <NUM> and the concave protrusion <NUM>).

In some embodiments, as shown in <FIG>, a plurality of support bars <NUM> are provided with at least two rows of limiting parts <NUM> arranged in the extending direction of the support bars <NUM>, and each row of limiting parts <NUM> are aligned in the arrangement direction of the support bars <NUM>. For example, the plurality of support bars <NUM> in <FIG> are provided with two rows of limiting parts <NUM>; and the plurality of support bars <NUM> in <FIG> are provided with three rows of limiting parts <NUM>.

Specifically, the design of this embodiment can improve the stability and consistency of the distances between the support bars <NUM> in the extending direction of the support bars <NUM> through the multiple rows of limiting parts <NUM>.

In some embodiments, as shown in <FIG>, the limiting parts <NUM> in adjacent rows are arranged alternately. In other words, the limiting parts <NUM> of the support bars <NUM> can be staggered to form two or more rows of limiting parts <NUM>.

In some embodiments, as shown in <FIG>, each support bar <NUM> may include two or more sections of bars <NUM>, all sections of bars <NUM> of the plurality of support bars <NUM> are arranged side by side, and at least one row of limiting parts <NUM> are provided on each row of bars <NUM>. In other words, a row of support bars <NUM> is divided into two or more rows of bars <NUM>, and the limiting parts <NUM> are provided on each row of bars <NUM>, to maintain the gap and/or relative position between the bars <NUM> in this row.

In the embodiment of the present application, due to the discontinuous design of the support bars <NUM>, the breaking problem of the support bars <NUM> during bending or other flexible movements can be avoided or eliminated, and the reliability of the bending movement of the support assembly <NUM> itself can be improved. Moreover, since each row of bars <NUM> is provided with at least one row of limiting parts <NUM>, the gap and/or relative position between the rows of bars <NUM> can be maintained.

Specifically, the flexible display apparatus provided by the above-mentioned embodiments of the present application can be applied to a flexible OLED, a flexible mini-LED, a flexible Micro-LED or a flexible QLED or other flexible display products, and can be specifically applied to a mobile phone, a tablet computer or a notebook or other products that can be used for curling display.

In another aspect, as shown in <FIG>, an embodiment of the present application further provides a support assembly <NUM>, configured to be arranged on a non-display surface of a flexible display screen, and including a first support member <NUM> and a second support member <NUM>; where the first support member <NUM> is a bendable plate-like structure, the second support member <NUM> is arranged on a side of the first support member <NUM> away from the flexible display screen and includes a plurality of support bars <NUM> arranged in a first direction, and the support bars <NUM> have a same extending direction and are fixed on the first support member <NUM>.

Specifically, in the support assembly <NUM> provided by the present application, the first support member <NUM> is a plate-like structure and is close to the back of the flexible display screen, and has the main function of fixing the size and shape of the flexible display screen and enhancing the support and dynamic curling reliability of the flexible module; and optionally, the second support member <NUM> may be a plurality of mutually independent support bars <NUM>, which are not physically connected to each other. These support bars <NUM> are parallel to each other and extend in the same direction. During the curling process of the flexible display screen, the design of the independent support bars <NUM> can reduce the stress influence on the flexible module as much as possible to improve the curling reliability of the flexible module, and can also reduce the overall resilience force of the flexible module, and reduce the difficulty of assembling the complete flexible display apparatus and the difficulty of realizing the curling action; and furthermore, while providing the support performance, the support bars <NUM> can also strengthen the friction between the flexible display screen and other structure (such as the curling roller shaft) on the back side, thereby improving the reliability and dependability of the curling action of the flexible module.

To sum up, through the two-layer support structure with the first support member <NUM> and the second support member <NUM>, the support assembly <NUM> provided by the present application can maintain the flat state of the flexible display screen, and at the same time, enhance the support and dynamic curling reliability of the flexible display screen, improve the reliability of the flexible curling action of the flexible display screen, and improve the assembly yield and service life of the curling display apparatus.

Exemplarily, in an embodiment of the present application, the first direction may be consistent with the extending direction of one edge of the flexible display screen; for example, the arrangement direction of the plurality of support bars <NUM> is consistent with the extending direction of one edge of the flexible display screen, and the extending direction of the support bars <NUM> is consistent with the extending direction of the other edge of the flexible display screen; the flexible display screen can be rolled or unfolded around an axis, and the extending direction of the support bars <NUM> is consistent with the extending direction of the axis.

In some embodiments, the first support member <NUM> is used to cover the back of the entire flexible display screen, that is, the first support member <NUM> and the flexible display screen can be approximately the same in shape and area; and on the side of the first support member <NUM> away from the flexible display screen, the second support member <NUM> may be evenly distributed on the entire first support member <NUM> or may be located only in a partial area of the first support member <NUM>, which may specifically be determined according to actual product requirements.

Exemplarily, the support assembly provided by the embodiment of the present application is configured to move around a roller shaft together with the flexible display screen to realize unfolding and folding of the flexible display screen; and as shown in <FIG>, in the support assembly provided by the embodiment of the present application, the first support member <NUM> may include a rolling and sliding part <NUM> and a plane part <NUM>, where the rolling and sliding part <NUM> is configured to move around the roller shaft; and the rolling and sliding part <NUM> is provided with a hollow opening.

The 'rolling and sliding part' is an area where the first support member passes through the roller shaft when performing the curling and unfolding actions together with the flexible display screen, and can also be called a curling part; and correspondingly, the 'plane part' is an area where the first support member does not pass through the roller shaft during the curling and unfolding actions, and can also be called a non-curling part.

The rolling and sliding part <NUM> is provided with a hollow opening, thus improving the flexibility of this part and improving the curling reliability.

Alternatively, both the rolling and sliding part <NUM> and the plane part <NUM> are provided with hollow openings, that is, the entire surface of the first support member <NUM> can be patterned.

Exemplarily, as shown in <FIG> and <FIG>, the second support member <NUM> is arranged on the rolling and sliding part <NUM> of the first support member <NUM>, that is, the second support member <NUM> is arranged on the part of the flexible module that curls and moves around the roller shaft.

In some embodiments, the flexible display screen and the first support member <NUM> may be fixed by bonding, and the first support member <NUM> and the second support member <NUM> may also be fixed by bonding.

In some embodiments, as shown in <FIG>, the support assembly may further include a reinforcement structure <NUM> arranged on the side of the first support member <NUM> away from the flexible display screen and located on the plane part <NUM> of the first support member <NUM>.

Exemplarily, the first support member <NUM> and the second support member <NUM> are bonded and fixed by a second adhesive layer <NUM>, and the reinforcement structure <NUM> and the first support member <NUM> may be bonded and fixed by a third adhesive layer <NUM>. The third adhesive layer <NUM> can be made of the same material as the second adhesive layer <NUM>.

In some embodiments, the second support member includes metal, alloy or metal oxide material, and for example, may be specifically stainless steel, copper alloy, titanium alloy, etc., or a metal oxide such as ferrite, nickel oxide, etc..

Exemplarily, the width of each support bar in the second support member is <NUM>-<NUM>, and the thickness of each support bar in the direction perpendicular to the first support member is <NUM>-<NUM>.

In some embodiments, as shown in <FIG>, at least some of the plurality of support bars <NUM> in the second support member are provided with limiting parts <NUM>, and relative positions between the at least some support bars <NUM> and adjacent support bars <NUM> thereof are limited by the limiting parts <NUM>.

Specifically, "one end" refers to one end along the arrangement direction of the support bars, so the first support bar refers to one end support bar; in other words, a limiting part is provided on the side of each support bar <NUM> other than the support bar on one end facing the end, thus ensuring that the relative position between every two adjacent support bars can be limited by the limiting part.

In other embodiments, as shown in <FIG> and <FIG>, the plurality of support bars <NUM> include two end support bars <NUM> located at two ends and middle support bars <NUM> located between the two end support bars <NUM>; the limiting parts <NUM> are provided on both sides of each middle support bar <NUM> facing the two end support bars <NUM>, the limiting part <NUM> is provided on a side of each end support bar <NUM> facing the middle support bars <NUM>, and the limiting part <NUM> is a protrusion structure.

Specifically, 'two ends' refer to two ends along the arrangement direction of the support bars, so the two end support bars refer to the support bars located at both ends.

The above arrangement makes it possible to have two limiting parts <NUM> between every two adjacent support bars. Specifically, these two limiting parts <NUM> can limit the gap between two adjacent support bars, and the relative positional relationship of the two limiting parts <NUM> (for example, the two limiting parts <NUM> are aligned or staggered in the direction perpendicular to the support bars) is also beneficial to keep the two support bars aligned in the extending direction.

In some embodiments, a first side of each support bar is provided with a first-type limiting part, and a second side of each support bar is provided with a second-type limiting part, so shapes of the first-type limiting part and the second-type limiting part are complementary; and the first-type limiting part and the second-type limiting part of two adjacent support bars are complementary and coordinate.

Specifically, the support assembly provided by the embodiments of the present application can be applied to a flexible display, such as flexible OLED, flexible mini-LED, flexible Micro-LED or flexible QLED; and for example, can be specifically applied to a mobile phone, a tablet computer or a notebook or other products that can be used for curling display.

Claim 1:
A flexible display apparatus, comprising:
a roller shaft (<NUM>); and
a flexible module (<NUM>) comprising a rolling and sliding area and a plane area, wherein the rolling and sliding area is configured to move around the roller shaft (<NUM>) to realize unfolding and folding of the flexible module (<NUM>); the flexible module (<NUM>) comprises a flexible display screen (<NUM>) and a support assembly (<NUM>); the support assembly (<NUM>) is arranged on a surface of the flexible display screen (<NUM>) facing the roller shaft (<NUM>), and comprises a first support member (<NUM>) and a second support member (<NUM>); the first support member (<NUM>) is a bendable plate-like structure, and the second support member (<NUM>) is arranged on a side of the first support member (<NUM>) away from the flexible display screen (<NUM>) and comprises a plurality of support bars (<NUM>) arranged in a moving direction of the flexible module (<NUM>), and each support bar (<NUM>) has a same extending direction as the roller shaft (<NUM>) and is fixed on the first support member (<NUM>);
wherein the flexible display apparatus further comprises a tension applying component;
wherein the support assembly (<NUM>) comprises a first end and a second end oppositely arranged; the support assembly (<NUM>) bypasses the roller shaft (<NUM>) along a direction from the first end to the second end, and the first end is connected to the tension applying component;
wherein the tension applying component comprises a traction part (<NUM>), a steering shaft component (<NUM>) and a fixing part (<NUM>);
the traction part (<NUM>) comprises a third end and a fourth end, the third end is connected to the first support member (<NUM>), and the fourth end bypasses the steering shaft component (<NUM>) and is connected to the fixing part (<NUM>); and
the roller shaft (<NUM>) moves relative to the fixing part (<NUM>), to drive the flexible module (<NUM>) to move and unfold around the roller shaft (<NUM>);
characterized in that, the steering shaft component (<NUM>) comprises a moving shaft (<NUM>) and a fixed shaft (<NUM>); and the traction part (<NUM>) bypasses the fixed shaft (<NUM>) and the moving shaft (<NUM>) so that an extending direction reversed twice; and
a position of a shaft center of the fixed shaft (<NUM>) is fixed relative to the fixing part, and a position of a shaft center of the moving shaft (<NUM>) is fixed relative to a shaft center of the roller shaft (<NUM>).