Backlight module and display device

The present application provides a backlight module and a display device. The backlight module includes a first backlight assembly and a second backlight assembly. The second backlight assembly is provided with a backlight hole, and at least a portion of the first backlight assembly is accommodated in the backlight hole. The first backlight assembly includes a first light source and a light guide element. The light guide element is used to guide a light beam from the first light source, which enters the light guide element, out of the backlight hole, so that the light is evenly distributed in the backlight hole, and a full-screen display design of the display device is realized.

FIELD OF DISCLOSURE

The present application relates to display technology and in particular, to a backlight module and a display device.

DESCRIPTION OF RELATED ART

As consumers have increasingly higher expectations of display devices, there has been a trend to improve a screen ratio of display devices. A backlight hole design in a backlight module can not only satisfy photosensitive requirements of a functional assembly such as an optical assembly, but also realize a full screen design of the display device, so the backlight hole design has attracted much attention.

The backlight hole of the backlight module of the conventional display device is only used as a channel for receiving ambient light. When an optical assembly does not need to satisfy photosensitive requirements, a display panel of the display device cannot display normally in an area corresponding to the backlight hole, thus failing to provide full-screen displays.

Therefore, there is an urgent need for a backlight module and a display device which can solve the above technical problems.

SUMMARY

The present application provides a backlight module and a display device for solving the following problem: a display panel of a conventional display device cannot display normally in an area corresponding to a backlight hole of a backlight module of the conventional display device because the backlight hole cannot provide backlight, thus failing to achieve a full-screen display.

The present application provides a backlight module, comprising:

a first backlight assembly and a second backlight assembly;

wherein a backlight hole is defined in the second backlight assembly, and at least a portion of the first backlight assembly is accommodated in the backlight hole;

wherein the first backlight assembly comprises a first light source and a light guide element for guiding a light beam of the first light source, which enters the light guide element, out of the backlight hole.

In the backlight module of the present application, the light guide element is filled at least in the backlight hole, and the first light source surrounds the light guide element;

wherein the light guide element comprises a first light-incident surface adjacent to the first light source, and the first light-incident surface is disposed at one side of the first light source adjacent to the backlight hole;

wherein an angle between the first light-incident surface of the light guide element and one side of the light guide element away from the backlight hole is greater than or equal to 90 degrees.

In the backlight module of the present application, the light guide element comprises a first recess surrounding the backlight hole, the first light source is disposed in the first recess, and the first light-incident surface is arranged between the first light source and the backlight hole.

In the backlight module of the present application, the first light source comprises a first light emitting surface, and the first light emitting surface is located on one side of the light source adjacent to the first light-incident surface.

In the backlight module of the present application, the first backlight assembly further comprises a plurality of diffusion units arranged on the first light-incident surface, and the diffusion units are configured to cause light emitted from the first light source to have an increased range of angles of refraction at the first light-incident surface.

In the backlight module of the present application, the diffusion units are a plurality of prisms and/or a plurality of protrusions of the light guide element protruding towards the first light source.

In the backlight module of the present application, the first backlight assembly further comprises a first lens disposed between the first light source and the light guide element; and

the first lens is disposed corresponding to the first light source, and the first lens is configured to converge light from the first light source, so that light from the first light source enters the light guide element through the first light-incident surface.

In the backlight module of the present application, the backlight module further comprises a reflective layer, and the reflective layer is disposed between the first backlight assembly and the second backlight assembly.

In the backlight module of the present application, the reflective layer comprises a first sub-light-reflective layer and a first sub-light-absorbent layer, and the first sub-light-absorbent layer is arranged on one side of the first sub-light-reflective layer away from the first backlight assembly.

In the backlight module of the present application, a material of the light guide element is a colorless transparent material.

The present application further provides a display device, comprising:

a display panel and a backlight module arranged at one side of the display panel;

wherein a backlight hole of the backlight module comprises a first side at one side close to the display panel, and a light guide element of the backlight module comprises a first light-emergent surface close to the first side and a second light-emergent surface away from the first side; and

the first light-emergent surface is parallel to the first side, and/or the second light-emergent surface is parallel to the first side.

In the display device of the present application, the light guide element further comprises a plurality of light converging units located on the first light-emergent surface and/or the second light-emergent surface; and

the light converging units are configured to increase brightness of light emitted from the first light-emergent surface to the display panel.

In the display device of the present application, the light converging unit is symmetrically arranged with respect to a first symmetry axis of the display panel along a first direction and/or a second symmetry axis of the display panel in a second direction; and

wherein the first direction is parallel to an extension direction of a scan line of the display device, and the second direction is parallel to an extension direction of a data line of the display device.

In the display device of the present application, the light converging unit is a dot microstructure.

In the display device of the present application, a diameter of the dot microstructure ranges from 16 micrometers to 120 micrometers, and a depth of the dot microstructure ranges from 0.8 micrometers to 12 micrometers.

In the display device of the present application, the display device further comprises an outer frame located on one side of the first backlight assembly of the backlight module away from the display panel, and the outer frame is configured to fix the first backlight assembly in the backlight hole.

In the display device of the present application, the display device further comprises a functional assembly arranged at one side of the first backlight assembly of the backlight module away from the display panel, and a signal receiving end of the functional assembly is arranged corresponding to the backlight hole;

the display device further comprises a control component electrically connected to the functional assembly and the first light source;

when the functional assembly is in operation, the control component controls the first light source to be in an off state, and the backlight hole serves as a signal receiving channel of the functional assembly; and

when the functional assembly is not in operation, the control component controls the first light source to turn on, and the light guide element is configured to uniformly distribute light from the first light source in the backlight hole.

In the display device of the present application, the display device comprises a lighting region and a non-lighting region surrounding the lighting region, and the backlight hole is defined in the lighting region; and

the display panel comprises a color filter layer, and a distribution density of color resists of the color filter layer in the lighting region is less than a distribution density of color resists of the color filter layer in the non-lighting region.

In the display device of the present application, a gap between metal traces of the display panel in the lighting region is greater than a gap between metal traces of the display panel in the non-lighting region.

In the display device of the present application, a number of thin film transistors of the display panel in the lighting region is less than a number of thin film transistors of the display panel in the non-lighting region.

Through the arrangement of the first light source and the light guide element, the light guide element is used to uniformly distribute the light from the first light source in the backlight hole when the signal receiving end of the optical assembly does not need to receive ambient light signals, so that the display panel can display normally in an area corresponding to the backlight hole, and full-screen display operations of the display device are realized.

DETAILED DESCRIPTION OF EMBODIMENTS

In order to make the purpose, technical solutions and effects of the present application clearer, the following description is provided with reference to the accompanying drawings and in conjunction with specific embodiments. It should be understood that the specific embodiments described herein are only used to explain the present application, and not used to limit the present application.

A backlight hole in a backlight module of a conventional display device is only used as a channel for receiving ambient light and cannot provide backlight for the display panel in a corresponding area, thus leading to a problem that the display device cannot achieve full-screen displays. In order to solve this problem, the present application provides a backlight module and a display device.

Referring toFIGS.1to6, a backlight module102comprises: a first backlight assembly104and a second backlight assembly.

A backlight hole103is defined in the second backlight assembly, and at least a portion of the first backlight assembly104is accommodated in the backlight hole103.

The first backlight assembly104comprises a first light source105and a light guide element106for guiding a light beam of the first light source105, which enters the light guide element106, out of the backlight hole103.

In the present embodiment, when the backlight module102is used in a display device100, the light guide element106is used to guide the light beam entering the light guide element106to an area of the display panel101corresponding to the backlight hole103.

In the present embodiment, the display device100further comprises a functional assembly arranged at one side of the first backlight assembly104away from the display panel101, and a signal receiving end of the functional assembly is arranged corresponding to the backlight hole103. The functional assembly can be an optical assembly.

In the present embodiment, the display device100includes a lighting region and a non-lighting region surrounding the lighting region. The backlight hole103and the signal receiving end of the functional assembly are located in the lighting region.

The display device100further comprises a control component electrically connected to the functional assembly and the first light source105.

When the functional assembly is in operation, the control component controls the first light source105to be in an off state, and the backlight hole103serves as a signal receiving channel of the functional assembly. When the functional assembly is not in operation, the control component controls the first light source105to turn on, and the light guide element106is configured to uniformly distribute light from the first light source105in the backlight hole103. The display panel101displays normally in the lighting region, and the display device100achieves a full-screen display.

In the present embodiment, the light guide element106is made of a colorless and transparent material, and a material of the light guide element106can be polycarbonate, polymethyl methacrylate, tempered glass, or other colorless and transparent materials.

In the present embodiment, the first light source105can be a mini-light-emitting diode or a micro-light-emitting diode.

In the present embodiment, the first light source105is arranged at one side of the backlight hole103away from the display panel101, and the first light source105can be arranged in the lighting region or the non-lighting region; however, the present application is not limited in this regard.

In the present embodiment, the backlight module102further comprises a second backlight assembly. The second backlight assembly comprises a second light source and an optical film set. The optical film set comprises, along a direction toward the display panel101, a first optical film, a second optical film, a third optical film, and a fourth optical film which are arranged in sequence. The first optical film, the second optical film, the third optical film, and the fourth optical film are used for reflecting, guiding, and diffusing the light emitted by the second light source, and enhancing brightness.

When the first light source105is arranged in the non-lighting region, the first light source105can be located on one side of the first optical film away from the display panel101. When the first light source105is arranged in the lighting region, the first light source105and the second light source105can be arranged in the same layer.

In the present embodiment, the display panel101can comprise a color filter layer. The color filter layer includes a red color resist, a green color resist, and a blue color resist. A distribution density of the color resists of the color filter layer in the lighting region is less than a distribution density of the color resists of the color filter layer in the non-lighting region, so as to improve transmittance of ambient light in the lighting region.

Alternatively, the color filter layer is not provided with any color resist in the lighting region, so as to increase the transmittance of ambient light in the lighting region. Under this condition, the first light source105can be composed of a first red sub-light source, a first green sub-light source, and a first blue sub-light source. When the first light source105adopts an RGB three-color arrangement, a driving frequency of the display panel101in the lighting region can be increased, and a color display in the lighting region can be performed in a manner like that of a field sequential color liquid crystal display. The field sequential color liquid crystal display refers to using an inverter to drive a RGB backlight source to illuminate in sequence, and the same pixel provides three color lights (R, G, and B) in sequence, so that eye's persistence of vision causes mixing of the three colors, as if the pixel is continuously illuminated, so as to achieve a full-color display.

In the present application, by having the first light source105and the light guide element106, when the signal receiving end of the optical assembly does not need to receive ambient light signals, the light guide element106is used to uniformly distribute the light from the first light source105in the backlight hole103, so that an area of the display panel101corresponding to the backlight hole103can display normally, and thereby a full-screen display of the display device100is realized.

The technical solution of the present application is described in conjunction with specific embodiments.

First Embodiment

Referring toFIG.2, the light guide element106is filled at least in the backlight hole103, and the first light source105surrounds the light guide element106.

The light guide element106comprises a first light-incident surface107adjacent to the first light source105, and the first light-incident surface107is disposed at one side of the first light source105adjacent to the backlight hole103.

An angle between the first light-incident surface107of the light guide element106and one side of the light guide element106away from the backlight hole106is greater than or equal to 90 degrees.

In the present embodiment, the light guide element106comprises a first recess115surrounding the backlight hole103, the first light source105is disposed in the first recess115, and the first light-incident surface107is arranged between the first light source105and the backlight hole103.

In the present embodiment, when the first light source105is located in the non-lighting region, the first light source105is located at one side of the first optical film away from the display panel101, so the light emitted by the first light source105needs to be guided into the light guide element106through the first light-incident surface107of the light guide element106to achieve uniform distribution in the backlight hole103, and then emits uniformly from one side of the backlight hole103close to the display panel101, so that the display panel101in the lighting region displays normally.

When the angle between the first light-incident surface107and one side of the backlight hole103away from the display panel101is greater than 90 degrees, a total amount of light emitted by the first light source105and entering the light guide element106from the first light-incident surface107is increased. Due to the included angle greater than 90 degrees between the first light-incident surface107and the side of the backlight hole103away from the display panel101, the light of the first light source105has an increased range of angles of refraction at the first light-incident surface107, which is conducive to the uniform distribution of the light of the first light source105in the backlight hole103when the signal receiving end of the optical assembly does not need to receive the ambient light signal, so that the display panel101in the lighting region is supplied with uniform backlight with sufficient brightness, the display panel101in the lighting region can display normally, and a full-screen display of the display device100is realized.

In the present embodiment, the first backlight assembly104further comprises a plurality of diffusion units108arranged on the first light-incident surface107, and the diffusion units108are configured to cause light from the first light source105to have an increased range of angles of refraction at the first light-incident surface.

In the present embodiment, the diffusion units108can be continuously distributed on the first light-incident surface107over its entire surface.

In the present embodiment, the diffusion units108can be integrally formed with the light guide element106.

In the present embodiment, the adjacent diffusion units108are arranged parallel to each other.

In the present embodiment, the diffusion units108are prisms and/or protrusions of the light guide element106, which protrude toward the first light source105.

When the diffusion unit108is a prism, the prism can be a triangular prism or other polygonal prism which functions to cause the light from the first light source105to have an increased range of angles of refractions at the first light-incident surface107.

When the prism is a triangular prism, any side of the prism is located on the first light-incident surface107.

The arrangement of the diffusion units108causes the light from the first light source105to have an increased range of angles of refraction at the first light-incident surface107. Therefore, when the signal receiving end of the optical assembly does not need to receive ambient light signals, the light of the first light source105is uniformly distributed in the backlight hole103to provide sufficient and uniform backlight to the display panel101in the lighting region, and as a result, the display panel101in the lighting region can display normally to realize a full-screen display of the display device100.

In the present embodiment, the first light source105can have multiple first light-emitting surfaces, or can have only one first light-emitting surface. When the first light source105has only one first light-emitting surface, the first light-emitting surface is located on one side close to the first light-incident surface107.

In the present embodiment, the first backlight assembly104further comprises a first lens disposed between the first light source105and the light guide element106.

The first lens is arranged corresponding to the first light source105, and the first lens is used to converge the light of the first light source105, so that the light of the first light source105enters the light guide element106through the first light-incident surface107.

Since the light emitted by the first light source105diverges in all directions, the converging function of the first lens can increase a total amount of light entering the light guide element106through the first light-incident surface107, so as to provide a backlight with sufficient and uniform brightness to the display panel101in the lighting region.

In the present embodiment, the light of the first light source105is guided into the light guide element106through the first light-incident surface107of the light guide element106. When the signal receiving end of the optical assembly does not need to receive the ambient light signals, the light guide element106is used to uniformly distribute the light from the first light source105in the backlight hole103, so that the display panel101can display normally in an area corresponding to the backlight hole103, and a full-screen display of the display device100is realized.

Second Embodiment

Referring toFIG.3, the second embodiment is the same or similar to the first embodiment, and the difference lies in that: the backlight module102further comprises a reflective layer113, and the reflective layer113is disposed between the first backlight assembly104and the second backlight assembly.

In the present embodiment, the reflective layer113can include a first sub-light-reflective layer. A material of the first sub-reflective layer can be a silver reflective material, such as silver, or other material capable of reflecting light.

The first sub-light-reflective layer is arranged, so that when the signal receiving end of the optical assembly does not need to receive ambient light signals, the light that is guided out of the light guide element106to one side of the backlight hole103near the second backlight assembly in the non-lighting region is reflected back to the light guide element106or directly reflected to one side of the backlight hole103near the display panel101, thus providing sufficient light to the display panel101in the lighting region to realize normal display operations of the display panel101in the lighting region and also reducing a loss of the light from the first light source105in the light guide element106and the backlight hole103to improve a utilization rate of the light from the first light source105and reduce energy consumption. At the same time, the first sub-light-reflective layer can also reflect light from the second light source located in the non-lighting region, so as to avoid interference from the second light source when the signal receiving end of the optical assembly needs to receive ambient light signals.

Alternatively, in the present embodiment, the reflective layer113can further include a first sub-light-absorbent layer arranged on one side of the first sub-light-reflective layer away from the light guide element106. A material of the first sub-light-absorbent layer can be a gray or black light-absorbing material, which is used to absorb light from the second light source located in the non-lighting region to prevent the light of the second light source from causing interference to the reception of ambient light by the signal receiving end of the optical assembly when the signal receiving end of the optical assembly needs to receive ambient light signals, thus avoiding affecting the product quality of the display device100.

In the present embodiment, the arrangement of the reflective layer113reduces the loss of the light from the first light source105in the light guide element106and the backlight hole103, and improves a utilization rate of the light of the first light source105. At the same time, the arrangement of the reflective layer113prevents the second light source located in the non-lighting region from interfering with the reception of the ambient light by the signal receiving end of the optical assembly, thereby improving the product quality of the display device100.

In all the above embodiments, by means of the arrangement of the first light source105and the light guide element106, the light guide element106is used to uniformly distribute the light from the first light source105in the backlight hole103when the signal receiving end of the optical assembly does not need to receive the ambient light signal, so that the display panel101can display normally in an area corresponding to the backlight hole103to realize a full-screen display of the display device100.

Referring toFIGS.1to6, the present application also provides a display device. The display device comprises a display panel and a backlight module located on one side of the display panel.

Referring toFIG.4, in the present embodiment, the backlight hole103of the backlight module102comprises a first side109near the display panel101, and the light guide element106of the backlight module102comprises a first light-emergent surface110close to the first side109and a second light-emergent surface111close to the first side109.

The first light-emergent surface110is parallel to the first side109, and/or the second light-emergent surface111is parallel to the first side109.

In the present embodiment, the first light-emergent surface110and the first side109can have a first overlapping portion.

The first light-emergent surface110and the first side109can overlay.

When the first light-emergent surface110and the first side109overlay each other, the light guide element106can fill a space of the backlight hole103, which facilitates uniform distribution of the light from the first light source105in the backlight hole103.

In the present embodiment, the first light-emergent surface110and/or the second light-emergent surface111can be a smooth surface. When the first light-emergent surface110and the second light-emergent surface111are smooth surfaces, the present application can avoid a condition that when the signal receiving end of the optical assembly needs to receive ambient light signals, the ambient light is scattered from the first light-emergent surface110or the second light-emergent surface111, which results in distortion of the ambient light signals received by the signal receiving end of the optical assembly, leads to unclear shooting pictures when the optical assembly is used for shooting or camera functions, and hence affects the product quality of the display device100.

By arranging the first light-emergent surface110, the second light-emergent surface111, and the first side109parallel to each other, the present application avoids a condition that when the signal receiving end of the optical assembly needs to receive the ambient light signals, the ambient light deflects after passing through the light guide element106and the deflection of light causes distortion of the ambient light signals received by the signal receiving end of the optical assembly, which affects the product quality of the display device100.

In the display device100of the present application, by means of the arrangement of the first light source105and the light guide element106, the light guide element106is used to make the light from the first light source105to be uniformly distributed in the backlight hole103when the signal receiving end of the optical assembly does not need to receive the ambient light signals, so that the display panel101can display normally in an area corresponding to the backlight hole103to realize a full-screen display of the display device100.

The technical solution of the present application is described in conjunction with specific embodiments.

Third Embodiment

Referring toFIG.5, the present embodiment is the same as or similar to the foregoing embodiment, except that:

In the third embodiment, the light guide element106further comprises a plurality of light converging units112located on the first light-emergent surface110and/or the second light-emergent surface111.

The light converging units112are configured to increase brightness of light emitted from the first light-emergent surface110to the display panel101.

In the present embodiment, the light converging units112are preferably arranged on the first light-emergent surface110.

In the present embodiment, the light converging unit112is a dot microstructure.

A diameter of the dot microstructure can range from 16 to 120 microns, preferably from 20 to 100 microns. When the diameter of the dot microstructure is less than 16 microns, it is difficult to enhance the brightness of the light emitted from the first light-emergent surface110to the display panel101. When the diameter of the dot microstructure is greater than 120 microns, the diameter of the dot microstructure is too large and affects surface smoothness of the first light-emergent surface110and/or the second light-emergent surface111, resulting in distortion of the ambient light signals received by the signal receiving end of the optical assembly when the signal receiving end of the optical component needs to receive ambient light signals, which affects the product quality of the display device100. When the diameter of the dot microstructure ranges from 20 to 100 microns, the diameter of the dot microstructure is not too small to enhance the brightness of the light emitted from the first light-emergent surface110to the display panel101, and the diameter of the dot microstructure is not large enough to affect the surface smoothness of the first light-emergent surface110and/or the second light-emergent surface111.

The depth of the dot microstructure ranges from 0.8 to 12 microns, preferably from 1 to 10 microns. When the depth of the dot microstructure is less than 0.8 μm, the depth of the dot microstructure is too small to well enhance the brightness of the light emitted from the first light-emergent surface110to the display panel101; when the depth of the dot microstructure is greater than 12 microns, the depth of the dot microstructure is too large, and therefore, when the signal receiving end of the optical assembly needs to receive ambient light signals, the ambient light is significantly refracted or scattered in the dot microstructure, resulting in distortion of the ambient light signals received by the signal receiving end of the optical assembly, which affects the product quality of the display device100. When the depth of the dot microstructure ranges from 1 to 10 microns, the depth of the dot microstructure is not too small to enhance the brightness of the light emitted from the first light-emergent surface110to the display panel101, and the depth of the dot microstructure is not large enough to cause distortion of the ambient light signals received by the signal receiving end of the optical assembly.

In the present embodiment, the light converging units112are symmetrically arranged with respect to a first symmetry axis of the display panel101along a first direction and/or a second symmetry axis along a second direction.

The first direction is parallel to an extension direction of a scan line of the display device100, and the second direction is parallel to an extension direction of a data line of the display device100.

The arrangement of the light converging units112increases the amount of light emitted from the light converging units112to the display panel101, thereby enhancing the brightness of the light emitted from the first light-emergent surface110to the display panel101. Therefore, the symmetrical arrangement of the light converging units112about the first symmetry axis and/or the second symmetry axis is beneficial to provide light with sufficient and uniform brightness to the display device100in the lighting region. As a result, the display device100in the lighting region can uniformly display when the signal receiving end of the optical assembly does not need to receive the ambient light signal, which realizes the full-screen display operations of the display device100and improves display quality of the display device100.

In the present embodiment, through the arrangement of the light converging units112, the brightness of the light emitted from the first light-emergent surface110to the display panel101is enhanced, which is beneficial to realize the full-screen displays of the display device100and also improve the product quality of the display device100.

Fourth Embodiment

Referring toFIG.6, the fourth embodiment is the same as or similar to the foregoing embodiment, and the difference lies in that:

The display device100further includes an outer frame114located on one side of the backlight hole103away from the display panel101, and the outer frame114is used to fix the first backlight assembly104of the backlight module in the backlight hole103.

In the present embodiment, the outer frame114and the reflective layer113can have a first overlapping portion.

In the present embodiment, a material of the outer frame114can be a light-absorbent material or a light-reflective material. While the outer frame114fixes the first backlight assembly104, the light from the first light source105can be absorbed or reflected to prevent the light of the first light source105from leaking from one side of the first backlight assembly104away from the display panel101, thus improving the product quality of the display device100.

In the present embodiment, the outer frame114comprises a first opening corresponding to the signal receiving end of the functional assembly. When the signal receiving end of the optical assembly needs to receive the ambient light signals, the ambient light reaches the signal receiving end of the optical assembly through the first opening, thus preventing the outer frame114from absorbing or reflecting the ambient light, which improves the sensitivity of the optical assembly.

In the present embodiment, through the arrangement of the outer frame114, the first backlight assembly104is fixed in the backlight hole103to prevent the first backlight assembly104from loosening or detaching from the backlight hole103to affect the product quality of the display device100.

In the foregoing embodiment, a gap between metal traces of the display panel101in the lighting region can be greater than a gap between metal traces of the display panel101in the non-lighting region. Alternatively, a width of a black matrix of the display panel101in the lighting region can be less than a width of the black matrix of the display panel101in the non-lighting region. Alternatively, a number of thin film transistors (TFTs) of the display panel101in the lighting region can be less than a number of TFTs of the display panel101in the non-lighting region. The above configurations are all conducive to improving a transmittance of ambient light in the lighting region, increasing a total amount of ambient light that can reach the signal receiving end of the optical assembly, improving the sensitivity of the optical assembly, and improving the product quality of the display device100.

The present application provides a backlight module and a display device. The backlight module comprises a first backlight assembly and a second backlight assembly. The second backlight assembly is provided with a backlight hole, and at least a portion of the first backlight assembly is accommodated in the backlight hole. The first backlight assembly includes a first light source and a light guide element, and the light guide element is used for guiding a light beam from the first light source, which enters the light guide element, out of the backlight hole. Through the arrangement of the first light source and the light guide element, the light guide element uniformly distributes the light from the first light source in the backlight hole when the signal receiving end of the optical assembly does not need to receive ambient light signals, so that the display panel can display normally in an area corresponding to the backlight hole, thus realizing full-screen display operations of the display device.

It can be understood that those of ordinary skill in the art can make equivalent replacements or changes according to the technical solution and inventive concept of the present application, and all such changes or replacements should be deemed to fall within the protection scope defined by the appended claims of the present application.