CN217983988U - Assembly structure of module and electronic equipment - Google Patents

Abstract

The utility model discloses an assembly structure of a module and electronic equipment, wherein a shell of the electronic equipment is provided with a mounting groove for mounting the module; the shell of the module is connected with at least two hanging lugs, and the hanging lugs are abutted against the outer surface of the shell in the state that the module is inserted into the mounting groove; the locking component is connected to the shell and can rotate relative to the shell to switch between a locking state and an unlocking state, the locking component presses the hanging lug on the outer surface in the locking state, and the locking component releases pressing force on the hanging lug in the unlocking state. The assembly structure is optimized in structure, the module and the electronic equipment can be quickly assembled or disassembled without external tools, and the assembly and disassembly are not limited by the size of a space.

Description

Assembly structure of module and electronic equipment

Technical Field

The utility model relates to an electronic equipment technical field especially relates to an assembly structure of module and electronic equipment.

Background

At present, it is a trend to externally connect a module to an electronic device to improve the performance of the electronic device or expand the application mode of the electronic device.

Taking an all-in-one machine and an OPS module as examples, a plurality of all-in-one machines adopt android systems, most of the existing applications are developed based on Windows systems, the all-in-one machines are compatible with Windows operating systems in design, and the OPS module is directly inserted into one machine in a frequently adopted mode, so that the all-in-one machine system can be switched to the Windows system; in practical application, the OPS module needs to be repaired or upgraded and replaced, and therefore the OPS module needs to be disassembled and installed on the all-in-one machine.

The all-in-one is the installation of hanging the wall usually in practical application, and the OPS module is located between all-in-one and the wall, and the space between all-in-one back and the wall is little, and the space of leaving for the dismouting of OPS module is little, and maintenance personal's operating space is little, and the dismouting is many to have inconveniently.

Besides the all-in-one machine and the OPS module, other electronic equipment and the external module are also disassembled and assembled to have similar problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a module and electronic equipment's assembly structure, through configuration optimization, need not to assemble module and electronic equipment fast or dismantle with the help of external tool, and install and remove and not be restricted to the space size.

In order to solve the above technical problem, the present invention provides an assembly structure of a module and an electronic device, wherein a housing of the electronic device has a mounting groove for mounting the module; the shell of the module is connected with at least two hanging lugs, and the hanging lugs are abutted against the outer surface of the shell in the state that the module is inserted into the mounting groove; the locking assembly is connected to the shell and can rotate relative to the shell to switch between a locking state and an unlocking state, the locking assembly presses the hanging lug on the outer surface in the locking state, and the locking assembly releases pressing force on the hanging lug in the unlocking state.

The utility model provides an assembly structure, which is characterized in that a mounting groove for mounting a module is arranged on a shell of an electronic device, after the module is inserted into the mounting groove, a hanging lug of a module shell is abutted against the shell so as to limit the mounting position of the module; the locking assembly is connected to a shell of the electronic equipment and can rotate relative to the shell to switch between a locking state and an unlocking state, the locking assembly tightly presses the hanging lug on the outer surface of the shell to lock the module and the electronic equipment in the locking state, and the locking assembly can release the pressing force on the hanging lug, namely, the locking of the unlocking module and the electronic equipment in the unlocking state, so that the module is convenient to detach from the electronic equipment; therefore, when the module is installed, the module is inserted into the installation groove and then is pressed against the hanging lug of the module through the rotating locking assembly, so that the locking with the electronic equipment is realized, when the module is disassembled, the pressing force on the hanging lug is relieved through the rotating locking assembly, the module is conveniently taken down, the assembling structure is not limited by installation space, and the module is conveniently disassembled or installed on the electronic equipment.

The assembly structure of the module and the electronic device comprises a locking main body, a shaft part and an elastic part; the locking body is sleeved on the shaft part and can rotate around the shaft part; the shaft part is fixedly connected with the shell; under the locking state, the locking body presses the hanging lug against the outer surface under the elastic force action of the elastic piece.

According to the assembly structure of the module and the electronic equipment, the locking main body comprises a rotating body and a pressing part, the pressing part is fixedly connected with the rotating body, and the rotating body is sleeved on the shaft part; and in the locking state, the pressing part presses against the hanging lug.

In the assembly structure of the module and the electronic device, the locking body has a step surface facing away from the housing, the shaft portion has a limiting surface facing the housing, the elastic member is sleeved on the shaft portion, and two ends of the elastic member respectively abut against the step surface and the limiting surface.

The assembly structure of the module and the electronic equipment comprises a locking main body, a rotating body and a pressing part, wherein the locking main body is fixedly connected with the rotating body, and the pressing part is arranged on two sides of the rotating body.

According to the assembly structure of the module and the electronic device, a limiting structure is arranged between the locking component and the shell and used for limiting the relative positions of the locking component and the shell in the locking state and the unlocking state.

The assembly structure of the module and the electronic device as described above, the limiting structure includes a limiting post and a limiting groove, one of the limiting post and the limiting groove is disposed on the locking assembly, the other is disposed on the housing, the limiting post is inserted into the limiting groove and can slide along the limiting groove, the limiting post abuts against a first groove wall of the limiting groove in the locking state, and the limiting post abuts against a second groove wall of the limiting groove in the unlocking state.

In the assembly structure of the module and the electronic device, one of the groove wall of the mounting groove and the housing is provided with the guide rail, and the other is provided with the guide groove in sliding fit with the guide rail.

In the assembly structure of the module and the electronic device, the mounting groove is provided with the first connecting part, the housing is provided with the second connecting part, and the first connecting part and the second connecting part are electrically connected with each other when the module is inserted into the mounting groove; one of the first connecting part and the second connecting part is a male socket, and the other one is a female socket.

According to the assembly structure of the module and the electronic equipment, the module is an OPS module, and the electronic equipment is an all-in-one machine.

Drawings

FIG. 1 is a schematic structural diagram of an OPS module and a kiosk in an assembled state in an exemplary embodiment;

FIG. 2 is a partial enlarged view of portion A of FIG. 1;

FIG. 3 is a partial enlarged view of the portion B in FIG. 2;

FIG. 4 is a schematic view of a portion of the configuration of the kiosk of FIG. 1;

FIG. 5 is a partial enlarged view of the location of the internal threaded hole and the limiting groove of the integrated machine of FIG. 4;

FIG. 6 is a front view of the OPS module of FIG. 1;

FIG. 7 is a bottom view of FIG. 6;

FIG. 8 is a side view of FIG. 6;

FIG. 9 is an exploded view of the locking assembly of FIG. 1;

FIG. 10 is a cross-sectional view of the locking assembly of FIG. 1;

FIG. 11 is a partial side view of the kiosk and OPS module with the locking assembly in an unlocked state in an exemplary embodiment.

Description of reference numerals:

the electronic device 10, the rear shell 11, the mounting groove 111, the first connecting part 112, the internal thread hole 113, the limiting groove 114 and the guide rail 115;

the OPS module 20, the hanging lug 21, the second connecting part 22, the guide groove 23 and the handle 24;

the locking assembly 30, the locking body 31, the rotating body 311, the first hole 3111, the second hole 3112, the stepped surface 3113, the pressing part 312, the handle 313, the shaft 32, the head 321, the first rod 322, the second rod 323, the elastic member 33, and the limit post 34.

Detailed Description

The utility model provides an assembly structure of module and electronic equipment, the generality is not lost, and the module is used to the below as the OPS module, and electronic equipment explains for the example of all-in-one, can understand, under other applied scenes, the module can be other external modules, for example storage module or stereo set equipment etc. also do not confine electronic equipment to the all-in-one, for example can be computing equipment or server etc. also.

Referring to fig. 1 to 3, fig. 1 is a schematic structural diagram of an OPS module and an all-in-one machine in an assembled state in an embodiment; FIG. 2 is a partial enlarged view of portion A of FIG. 1; fig. 3 is a partially enlarged view of a portion B in fig. 2.

The assembly structure provided by the present embodiment is used to assemble the OPS module 20 to the all-in-one machine 10 or disassemble the OPS module 20 from the all-in-one machine 10.

Among them, the OPS (Open plug Specification) is a standardized digital signage interface Specification established by INTEL and display manufacturers. The internal component of the OPS is a mini PC with an X86 architecture, and the open type pluggable specification technology is adopted. Generally, the OPS module 20 has a standard shape and size, and is provided with a hanging lug 21 on its housing for easy assembly with electronic devices such as the all-in-one machine 10.

In this embodiment, the all-in-one machine 10 includes a rear case 11, and the ops module 20 is specifically mounted on the rear case 11. The front of the all-in-one machine 10 is usually a display screen, and the all-in-one machine 20 is usually hung on a wall surface such as a wall when in use, so that the OPS module 20 is installed on the rear shell 11 thereof to avoid influence on display of the display screen, and the OPS module 20 can be hidden between the all-in-one machine 10 and the wall.

Of course, in other embodiments, if the electronic device for mounting the module does not require a display or a mounted appearance, the module may be mounted in a convenient area of the housing of the electronic device, and is not limited to the rear case, for example, the module may be located at a side portion, a bottom portion, a top portion, or the like of the housing.

Referring to fig. 4 to 8 together, fig. 4 is a partial structural schematic diagram of the all-in-one machine of fig. 1; FIG. 5 is a partial enlarged view of the location of the internal threaded hole and the limiting groove of the integrated machine of FIG. 4; FIG. 6 is a front view of the OPS module of FIG. 1; FIG. 7 is a bottom view of FIG. 6; fig. 8 is a side view of fig. 6.

In this embodiment, the rear case 11 of the all-in-one machine 10 has a mounting groove 111 for mounting the OPS module 20; referring to fig. 2 and 4, the mounting groove 111 of the rear housing 11 penetrates through a side wall and a bottom wall of the rear housing 11, in practical applications, the mounting groove 111 may be disposed as needed, and is not limited to that shown in the drawings, for example, the mounting groove 111 may penetrate through only the bottom wall of the rear housing 11, or through the bottom wall and the top wall of the rear housing 11.

After the OPS module 20 is inserted into the mounting groove 111, the engaging lug 21 connected to the housing can contact with the outer surface of the rear housing 11, and in the drawing, the engaging lug 21 contacts with the housing sidewall of the rear housing 11, and in the orientation of fig. 2 and 3, the engaging lug 21 specifically contacts with the housing sidewall on the right side of the rear housing 11.

A locking assembly 30 is connected to the rear housing 11, the locking assembly 30 being rotatable relative to the rear housing 11 to switch between a locked state in which, as shown in fig. 2 and 3, the locking assembly 30 presses the lugs 21 of the OPS module 20 against the outer surface of the rear housing 11 to lock the relative positions of the OPS module 20 and the kiosk 10, and an unlocked state in which the locking assembly 30 is disengaged from the lugs 21 by rotation to release the pressing force against the lugs 21 so that the OPS module 20 can be removed from the kiosk 10.

After the installation, the OPS module 20 is inserted into the installation groove 111 during installation, the locking assembly 30 is rotated to tightly press the hanging lug 21 of the OPS module 20, so that the locking with the all-in-one machine 10 is realized, during disassembly, the locking assembly 30 is rotated to release the pressing force on the hanging lug 21, so that the OPS module 20 is conveniently taken down, in the disassembly and assembly process, only the locking assembly 30 needs to be manually rotated, no external tool is needed, the assembly structure is not limited by the installation space, and the OPS module 20 is convenient to disassemble or install on the all-in-one machine.

The OPS module 20 is used as a standard component, and during processing, a screw hole can be further formed in the hanging lug 21, so that the OPS module 20 can be conveniently assembled with the electronic device to be installed according to application requirements, that is, under the condition that the installation space between the OPS module 20 and the electronic device to be installed is enough, a screw can be used to pass through the screw hole of the hanging lug 21 and be fixed to the rear shell 11 of the all-in-one machine 10.

In order to ensure the firmness of the assembled OPS module 20 and the all-in-one machine 10, at least two lugs 21 are arranged on the shell of the OPS module 20, correspondingly, at least two locking assemblies 30 are connected to the rear shell 11 of the all-in-one machine 10, and the locking assemblies 30 correspond to the lugs 21 one to one, so that at least two locking points of the OPS module 20 and the all-in-one machine 10 are ensured.

Referring to fig. 6, two lugs 21 of the OPS module 20 are disposed on two opposite walls of the housing, and the OPS module 20 shown in fig. 6 is inserted into the mounting groove 111 of the rear housing 11 shown in fig. 4 in a state of being rotated by 90 degrees, so that the two lugs 21 are vertically arranged, and when the two lugs 21 are inserted, the lugs 21 abut against the outer surface of the rear housing 11 to insert the OPS module 20 in place, and at this time, the locking assembly 30 can be rotated to a locking state, so as to lock the OPS module 20 and the all-in-one machine 10.

In the illustrated embodiment, after assembly, the lugs 21 of the OPS module 20 abut against the housing side walls of the rear housing 11; in other embodiments, depending on the installation position and the extending direction of the hanging lug 21, it may be abutted against the case bottom wall of the rear case 11 after assembly.

Referring to fig. 9 and 10 together, fig. 9 is an exploded view of the locking assembly of fig. 1; fig. 10 is a cross-sectional view of the locking assembly of fig. 1.

In this embodiment, the locking assembly 30 includes a locking body 31, a shaft 32 and an elastic member 33, wherein the locking body 31 is sleeved on the shaft 32 and can rotate around the shaft 32, the shaft 32 is fixedly connected with the rear shell 11, and in the locking state, the locking body 31 presses the hanging lug 21 against the outer surface of the rear shell 11 under the elastic force of the elastic member 33.

Specifically, the shaft portion 32 includes a head portion 321, a first rod portion 322 and a second rod portion 323 which are fixedly connected in sequence, wherein the second rod portion 323 has an external thread portion, the locking body 31 is sleeved on the first rod portion 322 and can rotate around the first rod portion 322, and the elastic member 33 is located between the head portion 321 and the locking body 31; the rear shell 11 is provided with an internal threaded hole 113, and the second rod part 323 of the shaft part 32 is in threaded connection with the internal threaded hole 113; thus, the locking body 31 is fixed relative to the rear case 11 by the second lever portion 323 of the shaft portion 32, and at the same time, the locking body 31 can also rotate around the first lever portion 322 to switch between the locked state and the unlocked state, and when the locking body 31 rotates to the locked state, the locking body 31 presses the hanging lug 21 against the outer surface of the rear case 11 by the elastic force of the elastic member 33, as shown in fig. 3. It is apparent that, when the locking assembly 30 is assembled with the rear case 11, the elastic member 33 is in a charged state having an elastic force pressing the locking body 31 toward the rear case 11.

Wherein, the outer diameter of the second rod part 323 of the shaft part 32 can be smaller than the outer diameter of the first rod part 322, so that a stepped surface is formed at the joint of the two, after the shaft part 32 passes through the locking body 31 and is screwed into the internal thread hole 113 of the rear shell 11, the stepped surface at the joint of the first rod part 322 and the second rod part 323 is abutted against the outer surface of the rear shell 11, so as to limit the depth of the shaft part 32 inserted into the internal thread hole 113, and the operation and the control are convenient. The shaft portion 32 may take the form of a stepped screw.

In a specific embodiment, the locking body 31 includes a rotating body 311 and a pressing portion 312, which are fixedly connected to each other, the rotating body 311 is specifically sleeved on the first rod portion 322 of the shaft portion 31, and in a locked state, specifically, the pressing portion 312 is in contact with the hanging lug 21 to press against the hanging lug 21.

The rotating body 311 may be a cylinder, and the pressing portion 312 may extend from the outer circumference of the rotating body 311 in the radial direction, so that along with the rotation of the rotating body 311, the pressing portion 312 may be in a position of pressing against the hanging lug 21 or in a position of being separated from the hanging lug 21, thereby facilitating switching between the locking state and the unlocking state.

Further, a handle 313 may be fixedly connected to the rotating body 311 to facilitate rotation of the locking body 31, and during operation, an operator may hold the handle 313 to apply a force to the locking body 31 to rotate the locking body 31. Specifically, the rotating body 311, the pressing portion 312, and the handle 313 are integrally formed. The handle 313 and the pressing part 312 may be particularly positioned at opposite sides of the rotating body 311 to facilitate the operation.

As shown in fig. 10, in this embodiment, the rotating body 311 has a first hole 3111 and a second hole 3112 communicating with each other, a step surface 3113 facing away from the rear case 11 is formed at a connection portion of the first hole 3111 and the second hole 3112, the locking assembly 30 is connected to the rear case 11 in an orientation shown in fig. 10, a right side surface of the rotating body 311 shown in fig. 10 abuts against the rear case 11, the step surface 3113 is designed to face away from the rear case 11, a portion of the first rod portion 322 of the shaft portion 32 is located in the second hole 3312, at least a portion of the elastic member 33 is located in the first hole 3111, and both ends of the elastic member 33 abut against the step surface 3113 and the head portion 321 of the shaft portion 32, specifically, the head portion 321 has a position-limiting surface facing the rear case 11, and the elastic member 33 is limited between the step surface 3113 and the position-limiting surface. The above-mentioned structure of the rotating body 311 facilitates the arrangement and the position limitation of the elastic member 33, and prevents the elastic member 33 from being separated from the rotating body 311.

In practice, the elastic member 33 may be a spring, which is sleeved on the first rod 322.

In the embodiment shown in fig. 10, the head portion 321 of the shaft portion 32 is also located in the first hole portion 3111, and in this case, a cross-shaped groove structure for facilitating the operation of a tool may be provided on an end surface of the head portion 321, as shown in fig. 3, to facilitate the screwing of the shaft portion 32 into the female screw hole 113 of the rear housing 11 by the tool. It will be appreciated that it is also possible to arrange the head 321 of the shaft 32 to extend beyond the rotor 311, so long as the resilient member 33 is in the stored energy state after assembly.

In a specific scheme, a limiting structure is further arranged between the locking main body 31 and the rear shell 11 to limit the relative positions of the locking main body 31 and the rear shell 11 in a locking state and an unlocking state, and particularly, an operator can conveniently know whether the locking main body 31 rotates in place through the limiting structure.

As shown in fig. 4, 5, 9 and 10, in the present embodiment, the limiting structure includes a limiting post 34 disposed on the locking body 31 and a limiting groove 114 disposed on the rear shell 11, when the locking body 31 is connected to the rear shell 11 through the shaft portion 32, the limiting post 34 thereon can be inserted into the limiting groove 114, when the locking body 31 is rotated, the limiting post 34 can slide in the limiting groove 114, in the locked state shown in fig. 3, the limiting post 34 abuts against a first groove wall of the limiting groove 114, at this time, if the locking body 31 is continuously rotated in the locking direction, the limiting post is limited by the first groove wall of the limiting groove 114, the locking body 31 cannot continuously rotate, in the unlocked state shown in fig. 11, the limiting post 34 abuts against a second groove wall of the limiting groove 114, at this time, if the locking body 31 is continuously rotated in the unlocking direction, the limiting groove 114 is limited by the second groove wall of the limiting groove 114, and the locking body 31 cannot continuously rotate.

In the illustrated embodiment, the limiting column 34 is specifically disposed on the rotating body 311, it can be understood that the limiting groove 114 is actually an arc-shaped groove taking the rotation center of the rotating body 311 as a circle center, and in the illustrated embodiment, the limiting groove 114 is specifically an arc-shaped groove with a 90-degree circle center angle; as shown in fig. 11, the locking body 31 is in an unlocked state, and is in a horizontal state, the limiting post 34 of the locking assembly 30 located below abuts against the upper groove wall of the corresponding limiting groove 114, the limiting post 34 of the locking assembly 30 located above abuts against the lower groove wall of the corresponding limiting groove 114, after the OPS module 20 is inserted, the locking body 31 located below is rotated 90 degrees counterclockwise to achieve the locking state shown in fig. 2, and the locking body 31 located above is rotated 90 degrees clockwise to achieve the locking state shown in fig. 2, at this time, the upper and lower locking bodies 31 are both in a vertical state, and the pressing portions 312 of the locking bodies 31 respectively press against the lugs 21 at corresponding positions.

It is understood that in other embodiments, the angle for rotating the locking body 31 is not limited to 90 degrees as described above according to the structural configuration of the pressing portion locking body 31, and may be designed adaptively according to the shape of the pressing portion 312, the locking requirement, and the like.

In other embodiments, if the structure allows, the aforementioned limiting column 34 may be disposed on the rear shell 11, and the locking body 31 may be provided with a limiting groove 114 that is matched with the limiting column 34.

In this embodiment, a guide rail 115 is further disposed on a wall of the mounting groove 111 of the rear housing 11, correspondingly, a guide groove 23 is disposed on the OPS module 20, and when the OPS module 20 is inserted into the mounting groove 11, the guide groove 23 is slidably engaged with the guide rail 115 to guide the assembly of the OPS module 20. The guide grooves 23 and the guide rails 115 that are engaged with each other may be provided in one or more sets as necessary.

Additionally, in other embodiments, the guide rail 115 and guide slot 23 may be reversed in design, i.e., the guide slot 23 is disposed on the mounting slot 111 and the guide rail 115 is disposed on the OPS module 20.

A first connecting part 112 is arranged in the mounting groove 111, a second connecting part 22 is arranged on the OPS module 20, and after the OPS module 20 is inserted into the mounting groove 111, the second connecting part 22 is electrically connected with the first connecting part 112, so that the OPS module 20 is communicated with the all-in-one machine; for convenience, the second connecting portion 22 is a male socket and the first connecting portion 112 is a female socket, but the reverse arrangement is also possible.

In addition, a handle 24 can be further arranged on the OPS module 20, so that the OPS module 20 can be conveniently taken out during assembly or disassembly.

It is right above that the utility model provides an assembly structure of module and electronic equipment has carried out the detailed introduction. The principles and embodiments of the present invention have been explained herein using specific examples, and the above descriptions of the embodiments are only used to help understand the method and its core ideas of the present invention. It should be noted that, for those skilled in the art, without departing from the principle of the present invention, the present invention can be further modified and modified, and such modifications and modifications also fall within the protection scope of the appended claims.

Claims (10)

1. An assembly structure of a module and electronic equipment is characterized in that a shell of the electronic equipment is provided with a mounting groove for mounting the module; the shell of the module is connected with at least two hanging lugs, and the hanging lugs are abutted against the outer surface of the shell in the state that the module is inserted into the mounting groove; the locking assembly is connected to the shell and can rotate relative to the shell to switch between a locking state and an unlocking state, the locking assembly presses the hanging lug on the outer surface in the locking state, and the locking assembly releases pressing force on the hanging lug in the unlocking state.

2. A module and electronic device assembling structure according to claim 1, wherein said lock assembly comprises a lock main body, a shaft portion and an elastic member; the locking body is sleeved on the shaft part and can rotate around the shaft part; the shaft part is fixedly connected with the shell; under the locking state, the locking body presses the hanging lug against the outer surface under the elastic force action of the elastic piece.

3. An assembly structure of a module and an electronic device according to claim 2, wherein the locking body includes a rotor and a pressing portion, the pressing portion is fixedly connected to the rotor, and the rotor is externally fitted over the shaft portion; and in the locking state, the pressing part presses against the hanging lug.

4. An assembly structure of a module and an electronic device according to claim 2, wherein the locking body has a stepped surface facing away from the housing, the shaft portion has a position-limiting surface facing toward the housing, the elastic member is sleeved on the shaft portion, and two ends of the elastic member respectively abut against the stepped surface and the position-limiting surface.

5. An assembly structure of a module and an electronic apparatus according to claim 3, wherein said lock main body further comprises a handle fixedly attached to said rotor, and said handle and said pressing portion are respectively located on both sides of said rotor.

6. An assembly structure of a module and an electronic device according to claim 1, wherein a limiting structure is provided between the locking assembly and the housing, and the limiting structure is used for limiting the relative positions of the locking assembly and the housing in the locked state and the unlocked state.

7. An assembly structure of a module and an electronic device according to claim 6, wherein the limiting structure comprises a limiting post and a limiting groove, one of the limiting post and the limiting groove is provided in the locking component, the other is provided in the housing, the limiting post is inserted into the limiting groove and can slide along the limiting groove, the limiting post abuts against a first groove wall of the limiting groove in the locked state, and the limiting post abuts against a second groove wall of the limiting groove in the unlocked state.

8. A mounting structure of a module and an electronic device according to any one of claims 1 to 7, wherein one of a groove wall of said mounting groove and said housing is provided with a guide rail, and the other is provided with a guide groove slidably fitted with said guide rail.

9. An assembly structure of a module and an electronic device according to any one of claims 1 to 7, wherein the mounting groove is provided with a first connecting portion, the housing is provided with a second connecting portion, and the first connecting portion and the second connecting portion are electrically connected in a state where the module is inserted into the mounting groove; one of the first connecting part and the second connecting part is a male socket, and the other one is a female socket.

10. An assembly structure of a module and an electronic device according to any one of claims 1 to 7, wherein the module is an OPS module, and the electronic device is a unified device.

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