Digital product silica gel protective sleeve for touch display screen

By embedding a C-shaped skeleton inside the silicone sleeve and setting crisscrossing recessed patterns, the problems of insufficient rigidity and poor heat dissipation of the silicone protective sleeve are solved, achieving stable protection and heat dissipation for the equipment.

CN224329499UActive Publication Date: 2026-06-05深圳市精利盛实业有限公司

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
深圳市精利盛实业有限公司
Filing Date
2025-08-11
Publication Date
2026-06-05

AI Technical Summary

Technical Problem

Existing silicone protective sleeves lack a rigid internal support structure, which can cause the equipment to loosen and fall off or be damaged by squeezing the frame. In addition, poor heat dissipation can lead to overheating and frequency reduction of the equipment.

Method used

A C-shaped skeleton is embedded in the side wall of the silicone sleeve and extends to the bottom to form a clamping structure. The interior is decorated with crisscrossing recessed patterns and functional holes to maintain the integrity of the device's functions.

Benefits of technology

The silicone sleeve enhances the deformation resistance, preventing the device from detaching and the frame from being damaged. At the same time, the heat dissipation channel reduces the risk of overheating and ensures the normal operation of the device.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224329499U_ABST
    Figure CN224329499U_ABST
Patent Text Reader

Abstract

The utility model relates to the technical field of silica gel protective sleeve, specifically to a digital product silica gel protective sleeve of touch display screen, aims at solving traditional protective sleeve weak impact resistance, poor heat dissipation and function shielding problem, in this technique, in silica gel cover length and width direction side wall inlay C type skeleton and extend to the bottom surface and form the clamping structure, inside bottom surface is equipped with longitudinal and transverse interlaced recessed lines, bottom surface extension groove is embedded lens groove and adjacent lamp groove, width side wall sets up first microphone hole, second microphone hole, charging hole and loudspeaker hole, length side wall sets up concave switch pad and volume pad, and opposite side installs the bump with double wear guide hole, the obvious advantage realized from this is: C type skeleton clamping structure enhances lateral impact resistance, prevents equipment drop and reduces screen fragmentation risk at the same time, recessed lines promote backboard heat flow to flow and dissipate and absorb impact energy through continuous channel, and cooperate with full function opening system to keep equipment operation original function complete, and comprehensive optimization protection ability and use experience.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This utility model relates to the field of silicone protective case technology, specifically a silicone protective case for digital products with touch screen displays. Background Technology

[0002] Silicone protective cases for touchscreen digital products are external accessories made of flexible silicone material, designed to fit snugly to the shape of electronic devices with touchscreens such as mobile phones and tablets. The core purpose of these cases is to provide basic physical protection for the device: wrapping the entire device to cushion impacts from everyday drops and collisions, preventing damage to the screen and body from scratches or impacts, while retaining access to essential components such as cameras and charging ports, ensuring a balance between protection and functionality.

[0003] However, existing silicone protective cases often lack a rigid internal support structure and have weak resistance to deformation of the side walls. Under external impact, the device is prone to loosening and falling off or the frame is squeezed, causing screen damage. In addition, traditional silicone cases are designed to be highly sealed and have no heat dissipation channels. The heat from the device's back panel cannot flow effectively, resulting in poor heat dissipation. Long-term use can easily lead to overheating, frequency reduction, or performance degradation of the device. Utility Model Content

[0004] The purpose of this invention is to provide a silicone protective case for digital products with touch screen displays, so as to solve the problems mentioned in the background art.

[0005] To achieve the above objectives, this utility model provides the following technical solution:

[0006] A silicone protective case for a digital product with a touch screen includes a silicone case, wherein C-shaped skeletons are embedded in the sidewalls of the silicone case in both the length and width directions, one end of the C-shaped skeleton extends into the bottom surface of the silicone case to form a clamping structure for the sidewalls of the silicone case, and the bottom surface of the silicone case has crisscrossing recessed patterns.

[0007] Preferably, the bottom surface of the silicone sleeve extends downward to form a groove, and a through-type lens groove begins on the bottom surface of the groove. A through-type lamp groove is formed at the location where the bottom surface of the groove is adjacent to the lens groove.

[0008] Preferably, a through-hole first microphone hole is formed on one sidewall of the silicone sleeve in the width direction, and a through-hole second microphone hole is formed on the other sidewall of the silicone sleeve in the width direction.

[0009] Preferably, a through-hole is provided on the side wall of the silicone sleeve in the width direction, adjacent to the second microphone, and a through-hole is provided on the side wall of the silicone sleeve in the width direction, adjacent to the charging hole.

[0010] Preferably, a switch pad is formed by an inward recess on one of the sidewalls along the length of the silicone sleeve, and a volume pad is formed by an inward recess on the sidewall along the length of the silicone sleeve adjacent to the switch pad.

[0011] Preferably, a protrusion is fixedly installed on the outer side of the other sidewall along the length direction of the silicone sleeve, and two through holes are formed on the protrusion.

[0012] Compared with the prior art, the beneficial effects of this utility model are:

[0013] 1. A silicone protective case for digital products with touch screen displays, which, through a C-shaped skeleton embedded in the side wall and a clamping structure extending to the bottom surface, tightly fastens the edge of the device and suppresses silicone deformation, prevents the device from falling out of the protective case and resists frame deformation caused by lateral impact, thereby reducing the risk of touch screen edge breakage.

[0014] 2. This silicone protective case for digital products with touch screen displays forms heat dissipation channels and elastic buffer layers through the crisscrossing recessed textures on the inner bottom surface, guiding the flow of heat from the back of the device to dissipate and avoid stuffiness, while absorbing the impact energy transferred to the back panel to reduce the probability of damage to internal electronic components. Attached Figure Description

[0015] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0016] Figure 2 This is a schematic diagram of the internal structure of the present invention;

[0017] Figure 3 This is a schematic diagram of the planar structure of the silicone sleeve of this utility model;

[0018] Figure 4 This utility model Figure 2 Enlarged diagram of point A in the middle.

[0019] In the diagram: 101, silicone sleeve; 102, C-shaped frame; 103, recessed texture; 104, groove; 105, lens slot; 106, light slot; 107, first microphone hole; 108, second microphone hole; 109, charging hole; 110, speaker hole; 111, switch pad; 112, volume pad; 113, protrusion; 114, through hole. Detailed Implementation

[0020] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0021] Please see Figures 1-4 As shown, this utility model provides a technical solution:

[0022] A silicone protective case for a digital product with a touch screen includes a silicone case 101. C-shaped skeletons 102 are embedded in the sidewalls of the silicone case 101 in both the length and width directions. One end of the C-shaped skeleton 102 extends into the bottom surface of the silicone case 101 to form a clamping structure for the sidewall of the silicone case 101. The bottom surface inside the silicone case 101 has crisscrossing recessed textures 103.

[0023] The above solution achieves basic protection by wrapping the device body with a silicone sleeve. The C-shaped skeleton embedded in the side wall in the length and width directions forms a side wall clamping structure. One end of the C-shaped skeleton extends into the bottom surface of the silicone sleeve to enhance the side wall's resistance to deformation. The crisscrossing grooves on the bottom surface of the silicone sleeve improve the friction and impact buffering capacity of the device's back.

[0024] In this embodiment, preferably, the bottom surface of the silicone sleeve 101 extends downward to form a groove 104, and a through-shaped lens groove 105 is formed at the bottom surface of the groove 104. A through-shaped lamp groove 106 is formed at the bottom surface of the groove 104 adjacent to the lens groove 105.

[0025] The above solution creates clearance space for protruding components of the device by creating a groove extending downwards on one side of the bottom surface of the silicone sleeve, ensures unobstructed optical operation of the device lens by creating a through-type lens slot on the bottom surface of the groove, and maintains the purity of the flash output by creating a through-type lamp slot adjacent to the lens slot on the bottom surface of the groove.

[0026] In this embodiment, preferably, a through-hole first microphone hole 107 is formed on one side wall of the silicone sleeve 101 in the width direction, and a through-hole second microphone hole 108 is formed on the other side wall of the silicone sleeve 101 in the width direction.

[0027] The above solution ensures the clarity of sound acquisition by the main microphone through a through-hole in one sidewall of the silicone sleeve in the width direction, and enables the noise-canceling microphone to capture ambient noise through a through-hole in the other sidewall in the width direction.

[0028] In this embodiment, preferably, a through-hole 109 is provided on the side wall of the silicone sleeve 101 in the width direction adjacent to the second microphone, and a through-hole 110 is provided on the side wall of the silicone sleeve 101 in the width direction adjacent to the charging hole 109.

[0029] The above solution maintains the physical connectivity of the charging interface through a through-hole on the side wall of the silicone sleeve adjacent to the second microphone hole, and allows for attenuated transmission of external audio through a through-hole on the side wall of the sleeve adjacent to the charging hole.

[0030] In this embodiment, preferably, a switch pad 111 is formed by an inward recess on one of the sidewalls along the length of the silicone sleeve 101, and a volume pad 112 is formed by an inward recess on the sidewall along the length of the silicone sleeve 101 adjacent to the switch pad 111.

[0031] The above solution triggers the physical response of the device's power button by a switch pad formed by an inward indentation on one of the sidewalls along the length of the silicone sleeve, and controls the execution of the device's volume button function by a volume pad formed by an inward indentation on the sidewall adjacent to the switch pad along the length of the sleeve.

[0032] In this embodiment, preferably, a protrusion 113 is fixedly installed on the outer side of the other sidewall in the length direction of the silicone sleeve 101, and two through holes 114 are formed on the protrusion 113.

[0033] The above scheme establishes an external mounting connection point by fixing a protrusion to the outer side of the other side wall along the length of the silicone sleeve, and achieves bidirectional threading and fixing of the hanging rope through two interconnected through holes on the protrusion.

[0034] In this embodiment, a silicone protective case for a touchscreen digital product provides physical protection by wrapping the device body with the silicone case 101. A C-shaped frame 102, embedded within the sidewalls of the silicone case 101 in both its length and width directions, forms a clamping structure at its end extending to the bottom surface, ensuring the protective case tightly fits the device's edge. When external impacts are applied to the sidewalls of the protective case, the rigid support of the C-shaped frame 102 effectively suppresses silicone deformation, preventing the device from detaching from the case and resisting lateral impact forces from squeezing the device's frame, thus avoiding the risk of touchscreen edge breakage due to frame deformation.

[0035] The crisscrossing grooves 103 on the inner bottom surface of the silicone sleeve 101 adhere to the non-display area of ​​the device's back panel. These grooves increase friction on the contact surface, preventing device displacement. Simultaneously, the continuous channels formed by the grooves guide the heat generated on the back of the device during operation along a predetermined path for dissipation, breaking the traditional sealed state of the silicone sleeve 101 and significantly reducing the risk of overheating. The grooved cavity structure further forms an elastic buffer layer between the device's back panel and the protective sleeve, absorbing the instantaneous impact energy transmitted to the device's back shell during a fall, reducing the probability of internal electronic components being damaged by vibration.

[0036] All functional openings support customized design: When applied to mobile phones, the bottom surface of the silicone case 101 forms a camera component clearance space through a downward-extending groove 104. The through-type lens slot 105 within the groove 104 precisely exposes the camera optical window to ensure distortion-free imaging, while the adjacent light slot 106 prevents the silicone material from obstructing the flash light path. If adapted to non-mobile phone devices such as tablets and game consoles, the layout of the groove 104 and functional openings can be reconstructed according to the specific shape of the device to achieve universal protection compatibility.

[0037] The side wall opening system is precisely matched to the device's functional components: the through-hole first microphone hole 107 and second microphone hole 108 on both sides in the width direction ensure unobstructed sound acquisition path; the charging hole 109 maintains smooth cable insertion and removal; and the speaker hole 110 eliminates audio output obstruction. The inwardly recessed switch pad 111 and volume pad 112 on the side wall in the length direction form a thin-walled elastic deformation zone, allowing the user to precisely trigger the device's physical buttons through localized silicone deformation when pressed. The through hole 114 of the protrusion 113 on the end side wall provides a lanyard fixing point, which, combined with the anti-torsion characteristics of the C-shaped frame 102, prevents the device from shaking and colliding with hard objects while suspended.

[0038] Ultimately, the comprehensive protective performance is enhanced through a triple synergistic mechanism: the clamping and bending structure of the C-shaped frame 102 resists lateral impacts; the recessed texture 103 simultaneously achieves heat dissipation and buffering of the back plate; and the reconfigurable opening system preserves the original functional integrity of the equipment, allowing the silicone protective cover to provide high-strength protection while maintaining the free operation of the equipment in full functionality.

[0039] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. Those skilled in the art should understand that this utility model is not limited to the above embodiments. The embodiments and descriptions in the specification are merely preferred examples and are not intended to limit the utility model. Various changes and modifications can be made to this utility model without departing from its spirit and scope, and all such changes and modifications fall within the scope of the claimed utility model. The scope of protection of this utility model is defined by the appended claims and their equivalents.

Claims

1. A silicone protective case for a digital product with a touch screen, comprising a silicone sleeve (101), characterized in that: C-shaped skeletons (102) are embedded in the sidewalls of the silicone sleeve (101) in both the length and width directions. One end of the C-shaped skeleton (102) extends into the bottom surface of the silicone sleeve (101) to form a clamping structure for the sidewall of the silicone sleeve (101). The bottom surface inside the silicone sleeve (101) is provided with crisscrossing recessed patterns (103).

2. The silicone protective case for a digital product with a touch screen display according to claim 1, characterized in that: The silicone sleeve (101) extends downward on one side of the bottom surface to form a groove (104). A through-type lens groove (105) is formed at the bottom surface of the groove (104). A through-type lamp groove (106) is formed at the bottom surface of the groove (104) adjacent to the lens groove (105).

3. The silicone protective case for a digital product with a touch screen display according to claim 2, characterized in that: The silicone sleeve (101) has a through-hole (107) on one side wall in the width direction and a through-hole (108) on the other side wall in the width direction.

4. The silicone protective case for a digital product with a touch screen display according to claim 3, characterized in that: A through-hole (109) is provided on the side wall of the silicone sleeve (101) in the width direction, adjacent to the second microphone. A through-hole (110) is provided on the side wall of the silicone sleeve (101) in the width direction, adjacent to the charging hole (109).

5. A silicone protective case for a digital product with a touch screen display according to claim 4, characterized in that: A switch pad (111) is formed by an inward recess on one of the sidewalls along the length of the silicone sleeve (101), and a volume pad (112) is formed by an inward recess on the sidewall along the length of the silicone sleeve (101) adjacent to the switch pad (111).

6. A silicone protective case for a digital product with a touch screen display according to claim 5, characterized in that: A protrusion (113) is fixedly installed on the outer side of the other sidewall along the length direction of the silicone sleeve (101), and two through holes (114) are provided on the protrusion (113).