CN219162631U - Memory bank mounting structure and electronic equipment - Google Patents

Abstract

The application discloses memory bank mounting structure and electronic equipment, this memory bank mounting structure includes mainboard, plug seat and mounting, and the mainboard has the loading surface, and the plug seat sets up in the loading surface, and the plug seat has the slot that supplies memory bank male, and the mounting rotates with the mainboard to be connected, and when the mounting rotated to the region that memory bank is located, the mounting compresses tightly the memory bank, and when the mounting rotated to avoiding the memory bank, the mounting breaks away from with the memory bank. The design can effectively ensure the stability of the memory bank installed in the plug-in socket.

Description

Memory bank mounting structure and electronic equipment

Technical Field

The application relates to the technical field of electronic equipment, in particular to a memory bank mounting structure and electronic equipment.

Background

Electronic devices, such as a host computer, have a risk of loosening the memory bank along with long-time vibration of the machine, thereby affecting normal operation of the machine, and therefore, how to ensure the stability of the memory bank fixed in the slot has become a problem to be solved.

Disclosure of Invention

The embodiment of the application provides a memory bar mounting structure and electronic equipment, which can effectively solve the problem that a memory bar in the related art is loosened due to vibration.

In a first aspect, an embodiment of the present application provides a memory bank mounting structure; the memory bank mounting structure comprises a main board, a plug seat and a fixing piece, wherein the main board is provided with a bearing surface, the plug seat is arranged on the bearing surface, the plug seat is provided with a slot for the memory bank to be inserted, the fixing piece is rotationally connected with the main board, when the fixing piece rotates to an area where the memory bank is located, the fixing piece compresses the memory bank, and when the fixing piece rotates to avoid the memory bank, the fixing piece is separated from the memory bank.

Based on the memory bank mounting structure, the fixing piece is rotated to the region where the memory bank is located, so that the fixing piece presses the memory bank, and the relative fixing of the position between the memory bank and the socket is realized, so that the stability of the memory bank fixed in the socket is ensured; the fixing piece is rotated to other areas where the memory bar is not located, so that the fixing piece is separated from the memory bar, the disassembly between the memory bar and the socket is realized, the disassembly can be realized without using other external tools, and the operation is simple and quick.

In a second aspect, an embodiment of the present application provides an electronic device, where the electronic device includes a memory bank, a housing, and the memory bank mounting structure described above, the housing has an accommodating space, the memory bank mounting structure is disposed in the accommodating space, and the memory bank passes through a socket of the socket and is at least partially located in the socket.

Based on the electronic equipment in this application embodiment, the electronic equipment that has above-mentioned memory bank mounting structure is convenient for realize the installation and dismantle between memory bank and the socket, and the memory bank can peg graft in the slot of socket steadily to guarantee electronic equipment's normal operating.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a partially exploded view of a memory chip mounting structure according to one embodiment of the present application;

FIG. 2 is a schematic structural view of a fixing member according to an embodiment of the present application;

FIG. 3 is a schematic structural view of a fixing member inserted into a fixing hole of a motherboard according to an embodiment of the present application;

FIG. 4 is a schematic diagram illustrating a structure in which a memory bank is inserted into a slot of a socket according to an embodiment of the present disclosure;

fig. 5 is a schematic structural diagram of a fixing member rotated to a region where a memory bank is located to compress the memory bank according to an embodiment of the present application.

Reference numerals: 1. a memory bank mounting structure; 10. a main board; 11. a bearing surface; 12. a fixing hole; 20. a socket; 201. a slot; 21. a first socket; 211. a first slot; 22. a second socket; 221. a second slot; 30. a fixing member; 31. a main body portion; 311. a clamping end; 312. a free end; 313. a peripheral side surface; 32. a rotating shaft portion; 33. a clamping part; 331. a clamping block; 332. a guide surface; 34. an abutting portion; 341. an abutment block; 342. a first abutment block; 3421. a first compression surface; 343. a second abutment block; 3431. a second compression surface; 35. an elastic connection part; 36. a pressing part; 361. a pressing surface; 40. a memory bank; 41. a first memory bank; 42. and a second memory bank.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application will be further described in detail with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the present application.

Referring to fig. 1-2, a first aspect of the present application proposes a memory bank mounting structure 1, which can effectively ensure the stability of the memory bank 40 mounted in the socket 20.

The memory bank mounting structure 1 comprises a main board 10, a socket 20 and a fixing piece 30, wherein the main board 10 is provided with a bearing surface 11, the socket 20 is arranged on the bearing surface 11, the socket 20 is provided with a slot 201 for inserting a memory bank 40, the fixing piece 30 is rotationally connected with the main board 10, when the fixing piece 30 rotates to an area where the memory bank 40 is located, the fixing piece 30 compresses the memory bank 40, and when the fixing piece 30 rotates to avoid the memory bank 40, the fixing piece 30 is separated from the memory bank 40.

The following describes the specific structure of the memory bank mounting structure 1 in an expanded manner with reference to fig. 1 to 5.

As shown in fig. 1-2, the memory bank mounting structure 1 includes a motherboard 10, a socket 20, and a fixing member 30.

The main board 10 is used as a carrier of the memory bank mounting structure 1, the main board 10 has good rigidity strength, and is not easy to fail (such as bending deformation or fracture) under the action of external force, the specific shape of the main board 10 is not equivalent, and a designer can reasonably design according to actual needs. It can be understood that the main board 10 may be a common board without any function, and the main board 10 has a simple bearing function, and of course, the main board 10 may also be a circuit board integrated with electronic components such as a capacitor, an inductor, and a resistor, and the main board 10 has a circuit control function in addition to the bearing function.

The main board 10 has a carrying surface 11, where the carrying surface 11 is a surface of the main board 10 for carrying other components, and the carrying surface 11 may be a plane, or a curved surface, or a combination of a plane and a curved surface.

The socket 20 serves as a structural member for mounting the memory bank 40 in the memory bank mounting structure 1. When the motherboard 10 is a circuit board, the socket 20 is electrically connected with the circuit board, and the memory bank 40 is electrically connected with the circuit board through the socket 20 after the memory bank 40 is inserted into the socket 20, so that the circuit board is ensured to read the data in the memory bank 40.

The socket 20 is disposed on the carrying surface 11, that is, the socket 20 is mounted on a side of the carrying surface 11 of the motherboard 10. Wherein, the socket 20 may be detachably connected with the motherboard 10, or may be non-detachably connected, when the socket 20 is detachably connected with the motherboard 10, the socket 20 may be connected with the motherboard 10 by screwing, clamping or a combination of both, and when the socket 20 is non-detachably connected with the motherboard 10, the socket 20 may be connected with the motherboard 10 by bonding. The specific connection manner between the socket 20 and the motherboard 10 is not limited, and a designer can perform reasonable design according to actual needs.

The socket 20 has a slot 201 into which the memory bank 40 is inserted, that is, the memory bank 40 extends from the socket of the slot 201 at least partially into the slot 201 to be in plug-in fit with the socket 20.

The fixing piece 30 is used as a structural member for pressing the memory bar 40, when the memory bar 40 is inserted into the socket 20, no interaction force exists between the memory bar 40 and the socket 20, and at the moment, the memory bar 40 is pressed by the fixing piece 30 to realize the relative fixing of the position between the memory bar 40 and the socket 20; of course, when the memory bank 40 is inserted into the socket 20, the socket 20 may also apply a pre-compression force to the memory bank 40, and the fixing member 30 is used to strengthen the connection stability between the memory bank 40 and the socket 20. The specific structure of the fixing member 30 will be described below.

The fixing member 30 is rotatably connected to the main board 10, that is, the fixing member 30 is connected to the main board 10 and is rotatable relative to the main board 10, and a specific connection manner between the fixing member 30 and the main board 10 will be described below.

When the fixing member 30 rotates to the area where the memory bank 40 is located, the fixing member 30 presses the memory bank 40, and when the fixing member 30 rotates to avoid the memory bank 40, the fixing member 30 is separated from the memory bank 40. That is, the fixing member 30 compresses and releases the memory bank 40 in a rotating manner to mount and dismount the memory bank 40 and the socket 20. When the memory bar 40 rotates to a preset angle, the fixing member 30 abuts against the memory bar 40 to position the memory bar 40 on the socket 20, and when the fixing member 30 rotates to other angles different from the preset angle, the fixing member 30 is separated from the memory bar 40 to enable the memory bar 40 to be separated from the socket 20, wherein the preset angle is an angle to which the memory bar 40 is pressed by the fixing member 30 and needs to rotate.

Based on the memory bank mounting structure 1 in the embodiment of the application, the fixing piece 30 is rotated to the area where the memory bank 40 is located, so that the fixing piece 30 compresses the memory bank 40, and the relative fixing of the position between the memory bank 40 and the socket 20 is realized, thereby improving the stability of fixing the memory bank 40 in the socket 20; the fixing piece 30 is rotated to other areas where the memory bar 40 is not located, so that the fixing piece 30 is separated from the memory bar 40, the disassembly between the memory bar 40 and the socket 20 is realized, and the operation is simple and quick without using other external tools.

Further, as shown in fig. 1-3, it is contemplated that the fixing member 30 may be connected to the main board 10 in a plurality of manners capable of rotating relative to the main board 10, for example, the fixing member 30 may be rotatably connected to the main board 10 through an intermediate connection structure such as a bearing. To facilitate the mounting and dismounting between the fixing member 30 and the motherboard 10, the fixing member 30 is designed to be engaged with the motherboard 10 in some embodiments. That is, the fixing member 30 can be engaged with the main plate 10 and rotated relative to the main plate 10. By the design, the fixing piece 30 and the main board 10 can be mounted and dismounted without using other external tools, and the portability of the fixing piece 30 and the main board 10 in mounting and dismounting is improved.

Further, as shown in fig. 1-3, considering that the fixing member 30 is connected to the main board 10 and can rotate relative to the main board 10 by means of a locking manner, in order to make the fixing member 30 have a corresponding function, the bearing surface 11 is designed, in some embodiments, to have a fixing hole 12 penetrating through the main board 10, and the fixing member 30 includes a main body portion 31, a rotating shaft portion 32, and a locking portion 33. The main body 31 is located on the side of the bearing surface 11 of the main board 10, the main body 31 comprises a clamping end 311 and a free end 312 which are far away from each other, and the clamping end 311 is closer to the bearing surface 11 than the free end 312; the rotating shaft part 32 is connected with the clamping end 311 and penetrates through the fixed hole 12, and the rotating shaft part 32 can rotate around the hole axis of the fixed hole 12; the clamping portion 33 is fixedly connected to one end of the rotating shaft portion 32 away from the clamping end 311 in a cantilever manner, and the free end of the clamping portion 33 and the clamping end 311 jointly clamp the motherboard 10. That is, the engaging end 311 of the main body 31 abuts against the carrying surface 11 of the main board 10, and the free end of the engaging portion 33 abuts against the surface of the main board 10 opposite to the carrying surface 11, so that the main body 31 and the engaging portion 33 clamp the main board 10 from two sides of the main board 10, respectively, to position the fixing member 30 on the main board 10. The clamping portion 33 is fixedly connected with the rotating shaft portion 32 in a cantilever shape, which means that a free end of the clamping portion 33, which is far away from the rotating shaft portion 32, can deform along a hole axis of the fixing hole 12 under the action of an external force, so that the clamping portion 33 can pass through the fixing hole 12. The main body 31, the shaft 32 and the clamping portion 33 may be formed as an integral structure by injection molding or 3D printing.

In the design, the clamping part 33 is fixedly connected with the rotating shaft part 32 in a cantilever shape, in the process that the clamping part 33 penetrates through the fixing hole 12, the hole wall of the fixing hole 12 presses the clamping part 33, so that the free end of the clamping part 33 is deformed along the hole axis of the fixing hole 12 towards the direction close to the main body part 31, the free end of the clamping part 33 is gradually folded towards the hole axis direction of the fixing hole 12, after the clamping part 33 penetrates through the fixing hole 12, the free end of the clamping part 33 is deformed along the hole axis direction of the fixing hole 12 towards the direction close to the main body part 31, the free end of the clamping part 33 is gradually relaxed to resume deformation along the hole axis direction of the fixing hole 12, at the moment, the free end of the clamping part 33 is in contact with one side opposite to the bearing surface 11 of the main board 10, the clamping end 311 of the main body part 31 is in contact with the bearing surface 11 of the main board 10, and the free end of the clamping part 33 and the clamping end 311 of the main body part 31 are clamped to the main board 10 from two sides of the main board 10, so that the clamping connection between the fixing piece 30 and the main board 10 is realized; the main body 31 is fixedly connected with the clamping part 33 through the rotating shaft part 32, the rotating shaft part 32 can rotate relative to the hole axis of the fixing hole 12, so that the main body 31 and the clamping part 33 can also rotate along with the rotating shaft part 32, and the relative rotation between the main boards 10 of the fixing piece 30 is realized.

Of course, in other embodiments, the fixing member 30 may include the main body 31, the fixing hole 12 is disposed on the main body 31, the rotating shaft 32 is fixedly connected to the bearing surface 11 of the motherboard 10, the clamping portion 33 is fixedly connected to an end of the rotating shaft 32 away from the bearing surface 11 in a cantilever manner, and the rotating shaft 32 is disposed in the fixing hole 12 in a penetrating manner, so that the main body 31 is commonly clamped between the motherboard 10 and the free end of the clamping portion 33. The rotating shaft portion 32, the clamping portion 33, and the main board 10 may be integrally formed by injection molding or 3D printing.

In particular, the embodiments with respect to the clamping portion 33 may be, but are not limited to, one or more of the following embodiments.

As shown in fig. 2, in the first embodiment, the clamping portion 33 has a guiding surface 332 facing away from the bearing surface 11, and the guiding surface 332 is used for guiding the clamping portion 33 to pass through the fixing hole 12. Wherein, from the side far from the bearing surface 11 to the side near to the bearing surface 11, the distance between the guide surface 332 and the hole axis of the fixing hole 12 gradually increases, or the guide surface 332 gradually inclines in a direction deviating from the hole axis of the fixing hole 12. By designing the guiding surface 332 in the process of penetrating the fastening hole 12 through the fastening portion 33, the guiding surface 332 has guiding function, which is beneficial to guiding the fastening portion 33 to penetrate the fastening hole 12, thereby further improving the portability of the installation between the fixing member 30 and the main board 10.

As shown in fig. 2, in the second embodiment, the clamping portion 33 includes clamping blocks 331, the clamping blocks 331 are fixedly connected to one end of the rotating shaft portion 32 away from the clamping end 311 of the main body portion 31, the number of the clamping blocks 331 is plural (more than two), and all the clamping blocks 331 are distributed at intervals around the hole axis of the fixing hole 12. All the clamping blocks 331 may be equally spaced around the hole axis of the fixing hole 12 or may be non-equally spaced around the hole axis of the fixing hole 12. In this design, by designing the plurality of clamping blocks 331, all the clamping blocks 331 are fixedly connected with the rotating shaft portion 32 to form a clamping jaw-like structure, the free end 312 of each clamping block 331 far away from the rotating shaft portion 32 is abutted against the surface opposite to the bearing surface 11 of the main board 10, and the clamping end 311 of the main body portion 31 is abutted against the bearing surface 11 of the main board 10, so that the clamping portions 33 and the main body portion 31 clamp the main board 10 from two sides of the main board 10 respectively, and the fixing member 30 is positioned on the main board 10.

Of course, in other embodiments, the clamping portion 33 may also include one clamping block 331, where the one clamping block 331 is an annular clamping block 331, and an inner annular wall surface of the annular clamping block 331 is fixedly connected to an end of the rotating shaft portion 32 away from the clamping end 311 of the main body portion 31.

Further, as shown in fig. 1-3, in order to enable the fixing member 30 to rotate to the area where the memory bank 40 is located and compress the memory bank 40, to achieve the relative fixing of the position between the memory bank 40 and the socket 20, so as to reduce the possibility of loosening the memory bank 40, in some embodiments, the fixing member 30 further includes an abutting portion 34, where the abutting portion 34 is fixedly connected to the main body 31, and when the fixing member 30 rotates to the area where the memory bank 40 is located, the abutting portion 34 abuts against the memory bank 40. The abutting portion 34 may be formed integrally with the main body 31 by injection molding or 3D printing. So designed, when the fixing piece 30 rotates to the area where the memory strip 40 is located, the abutting part 34 can abut against the memory strip 40 to compress the memory strip 40, so that the relative fixing of the position between the memory strip 40 and the socket 20 is realized, and the possibility of loosening of the memory strip 40 is effectively reduced.

Further, as shown in fig. 1-3, in order to avoid damage to the memory bank 40 caused by excessive tightening force of the abutting portion 34 on the memory bank 40 when the fixing member 30 rotates to the area where the memory bank 40 is located, in some embodiments, the fixing member 30 further includes an elastic connecting portion 35, the elastic connecting portion 35 is fixedly connected with the main body portion 31, the elastic connecting portion 35 extends from the clamping end 311 of the main body portion 31 to the free end 312 of the main body portion 31, the abutting portion 34 is fixedly connected with a side of the elastic connecting portion 35 facing away from the main body portion 31, the elastic connecting portion 35 is adapted to drive the abutting portion 34 to compress the memory bank 40 under the self elastic force, and the elastic connecting portion 35 is further adapted to be elastically deformed under the external force so as to separate the abutting portion 34 from the memory bank 40. The abutting portion 34 is indirectly connected to the main body portion 31 via the elastic connection portion 35, and the main body portion 31, the elastic connection portion 35, and the abutting portion 34 may be formed as an integral structure by injection molding or 3D printing. In this design, through designing elastic connection portion 35, abutting portion 34 is connected with main part 31 indirectionally through elastic connection portion 35, and elastic connection portion 35 is applicable to and drives abutting portion 34 under self elasticity effect and compress tightly memory strip 40 for be flexible contact between abutting portion 34 and the memory strip 40, thereby effectively reduce the possibility that abutting portion 34 is too big and is led to memory strip 40 damage in the tight power of acting on memory strip 40.

Specifically, the main body 31 has a peripheral side 313 disposed around the hole axis of the fixing hole 12, the elastic connection portion 35 is fixedly connected with the peripheral side 313 of the main body 31 and extends in a direction opposite to the bearing surface 11, so as to form an elastic arm structure, the elastic connection portion 35 is adapted to elastically deform in a direction deviating from the hole axis of the fixing hole 12 under the action of self elastic force, so that the abutting portion 34 presses the memory bank 40, thereby realizing the relative fixing of the position between the memory bank 40 and the socket 20, and the elastic connection portion 35 is adapted to elastically deform in a direction deviating from the hole axis of the fixing hole 12 under the action of external force, so that the abutting portion 34 is separated from the memory bank 40, and the detachment between the memory bank 40 and the socket 20 can be realized without using an external tool.

Further, as shown in fig. 1-3, in order to facilitate the elastic connection portion 35 to elastically deform under the action of an external force so as to separate the abutting portion 34 from the memory bank 40, in some embodiments, the fixing member 30 further includes a pressing portion 36, where the pressing portion 36 is fixedly connected to a side of the elastic connection portion 35 facing away from the bearing surface 11, and the pressing portion 36 has a pressing surface 361 facing away from the main body 31, and a distance between the pressing surface 361 and a hole axis of the fixing hole 12 gradually increases from a side facing away from the bearing surface 11 to a side facing toward the bearing surface 11, that is, the pressing surface 361 gradually inclines in a direction deviating from the hole axis of the fixing hole 12. When the user presses the pressing portion 36 with a finger, the finger falls on the pressing surface 361 of the pressing portion 36, and the pressing surface 361 has a guiding function, so that the elastic connection portion 35 connected with the pressing portion 36 is guided to elastically deform in a direction biased toward the hole axis of the fixing hole 12, and the clamping portion 33 moves along with the elastic connection portion 35 in a direction biased toward the hole axis of the fixing hole 12 to be separated from the memory bank 40, so that the memory bank 40 and the socket 20 are detached.

Further, as shown in fig. 4-5, it is contemplated that the memory bank 40 may be mounted on the motherboard 10 by the socket 20 in a variety of ways. For example, in some embodiments, when the socket of the socket 201 of the socket 20 is oriented perpendicular to the carrying surface 11 of the motherboard 10, the memory bank 40 passes through the socket of the socket 201 and at least partially extends into the socket 201 of the socket 20, and the memory bank 40 is perpendicular to the carrying surface 11 of the motherboard 10, that is, the memory bank 40 is mounted vertically. Of course, in other embodiments, when the socket of the socket 201 of the socket 20 is parallel to the carrying surface 11 of the motherboard 10, the memory bank 40 passes through the socket of the socket 201 and at least partially extends into the socket 201 of the socket 20, and the memory bank 40 is parallel to the carrying surface 11 of the motherboard 10, that is, the memory bank 40 is mounted horizontally.

When the memory bank 40 is vertically installed, the fixing member 30 rotates to the area where the memory bank 40 is located, and the abutting portion 34 abuts against the side surface of the memory bank 40 along the direction parallel to the bearing surface 11. When the memory bank 40 is horizontally mounted, the fixing member 30 rotates to the area where the memory bank 40 is located, and the abutting portion 34 abuts against the surface of the memory bank 40 opposite to the bearing surface 11 along the direction perpendicular to the bearing surface 11.

Considering that the fixing member 30 can independently compress and fix one memory bank 40, and can also compress and fix a plurality of memory banks 40 at the same time, so as to be suitable for different scene requirements.

When the memory banks 40 are horizontally mounted and the number of the memory banks 40 is plural, the socket 20 has plural slots 201 with the same orientation, the plural slots 201 are sequentially disposed in a direction perpendicular to the bearing surface 11, the abutting portion 34 includes plural abutting blocks 341 corresponding to the slots 201, the plural abutting blocks 341 are sequentially disposed in a direction perpendicular to the bearing surface 11, each abutting block 341 has a pressing surface facing the bearing surface 11, and the pressing surface is pressed against a surface of the corresponding memory bank 40 facing away from the bearing surface 11.

The plurality of slots 201 may be located on one socket 20 at the same time, or may be located on a plurality of sockets 20 respectively. Each slot 201 may correspond to one abutment block 341 or a plurality of abutment blocks 341, when each slot 201 corresponds to one abutment block 341, the memory bank 40 inserted in the slot 201 is pressed and fixed on the socket 20 by the one abutment block 341, and when each slot 201 corresponds to a plurality of abutment blocks 341, the memory bank 40 inserted in the slot 201 is pressed and fixed on the socket 20 by the plurality of abutment blocks 341. The pressing surface of the abutment block 341 and the surface of the memory bank 40 facing away from the bearing surface 11 of the motherboard 10 may form one of point contact, line contact or surface contact.

Specifically, as shown in fig. 1, 3, 4, and 5, the plurality of memory banks 40 includes a first memory bank 401 and a second memory bank 402. The socket 20 includes a first socket 21 and a second socket 22, where the first socket 21 is spaced from the second socket 22, and the first socket 21 is closer to the edge of the motherboard 10 than the second socket 22, the first socket 21 has a first slot 211 into which the first memory bank 401 is inserted, and the second socket 22 has a second slot 221 into which the second memory bank 402 is inserted, and in a direction perpendicular to the bearing surface 11 of the motherboard 10, the first slot of the first slot 211 is closer to the bearing surface 11 of the motherboard 10 than the second slot of the second slot 221.

The plurality of abutting blocks 341 include a first abutting block 342 and a second abutting block 343, the first abutting block 342 and the second abutting block 343 are fixedly connected with one side of the elastic connection portion 35 facing away from the main body portion 31, and the first abutting block 342 is closer to the bearing surface 11 of the motherboard 10 than the second abutting block 343. The first abutting block 342 has a first pressing surface 3421 facing the carrying surface 11 of the motherboard 10, and the first pressing surface 3421 is an arc surface protruding toward the carrying surface 11 of the motherboard 10, so that the first pressing surface 3421 forms a point contact with a surface of the first memory bank 401 facing away from the carrying surface 11 of the motherboard 10. The second abutment block 343 has a second pressing surface 3431 facing the carrying surface 11 of the main board 10, and the second pressing surface 3431 is planar, so that the second pressing surface 3431 makes surface contact with a surface of the second memory bank 402 facing away from the carrying surface 11 of the main board 10.

The second aspect of the present application proposes an electronic device (not shown in the drawings), which includes a memory bank 40, a housing (not shown in the drawings) and the memory bank mounting structure 1 described above, the housing has an accommodating space, the memory bank mounting structure 1 is disposed in the accommodating space, and the memory bank 40 passes through the socket of the socket 201 and is at least partially located in the socket 20. The electronic device may be, but is not limited to, a computer host or the like. In this design, the electronic device with the memory bank mounting structure 1 is convenient for realizing the mounting and dismounting between the memory bank 40 and the socket 20, and the memory bank 40 can be stably inserted into the slot 201 of the socket 20, thereby ensuring the normal operation of the electronic device.

The same or similar reference numerals in the drawings of the present embodiment correspond to the same or similar components; in the description of the present application, it should be understood that, if there is an azimuth or positional relationship indicated by terms such as "upper", "lower", "left", "right", etc., based on the azimuth or positional relationship shown in the drawings, this is for convenience of description and simplification of the description, but does not indicate or imply that the apparatus or element to be referred must have a specific azimuth, be constructed and operated in a specific azimuth, and thus terms describing the positional relationship in the drawings are merely used for illustration and are not to be construed as limitations of the present patent, and that the specific meaning of the terms described above may be understood by those of ordinary skill in the art according to the specific circumstances.

The foregoing description of the preferred embodiments of the present application is not intended to be limiting, but is intended to cover any and all modifications, equivalents, and alternatives falling within the spirit and principles of the present application.

Claims (10)

1. A memory bank mounting structure, comprising:

the main board is provided with a bearing surface;

the socket is arranged on the bearing surface and is provided with a slot for the insertion of the memory bank;

the fixing piece is rotationally connected with the main board, when the fixing piece rotates to the area where the memory bank is located, the fixing piece compresses the memory bank, and when the fixing piece rotates to avoid the memory bank, the fixing piece is separated from the memory bank.

2. The memory stick mounting structure of claim 1, wherein the fixing member is engaged with the motherboard.

3. The memory stick mounting structure of claim 2, wherein the bearing surface is provided with a fixing hole penetrating the main board, and the fixing member comprises:

the main body part is positioned on one side of the bearing surface of the main board and comprises a clamping end and a free end which are far away from each other, wherein the clamping end is closer to the bearing surface than the free end;

the rotating shaft part is connected with the clamping end and penetrates through the fixing hole, and can rotate around the hole axis of the fixing hole;

the clamping part is fixedly connected to one end, far away from the clamping end, of the rotating shaft part in a cantilever mode, and the free end of the clamping part and the clamping end jointly clamp the main board.

4. The memory bank mounting structure of claim 3, wherein,

the clamping part is provided with a guide surface facing away from the bearing surface, and the guide surface is used for guiding the clamping part to pass through the fixing hole; and/or

The clamping part comprises a plurality of clamping blocks fixedly connected with one end, away from the clamping end, of the rotating shaft part, and all the clamping blocks are distributed at intervals around the hole axis of the fixing hole.

5. The memory stick mounting structure of claim 3, wherein the fixing member further comprises:

and the abutting part is fixedly connected with the main body part, and when the fixing piece rotates to the area where the memory strip is located, the abutting part abuts against the memory strip.

6. The memory stick mounting structure of claim 5, wherein the fixing member further comprises:

an elastic connection part fixedly connected with the main body part, extending from the clamping end of the main body part to the free end of the main body part, and fixedly connected with one side of the elastic connection part, which is opposite to the main body part; the elastic connection part is suitable for driving the abutting part to compress the memory strip under the action of self elastic force, and is suitable for elastic deformation under the action of external force so that the abutting part is separated from the memory strip.

7. The memory stick mounting structure of claim 6, wherein the fastener further comprises:

and the pressing part is fixedly connected with one side of the elastic connecting part, which is opposite to the bearing surface, and is provided with a pressing surface opposite to the main body part, and the distance between the pressing surface and the hole axis of the fixing hole is gradually increased from one side away from the bearing surface to one side close to the bearing surface.

8. The memory chip mounting structure according to any one of claims 5 to 7, wherein,

the direction of the socket of the slot is parallel to the bearing surface, and when the fixing piece rotates to the area where the memory strip is located, the abutting part abuts against the surface of the memory strip, which is opposite to the bearing surface, along the direction perpendicular to the bearing surface.

9. The memory bank mounting structure of claim 8, wherein,

the socket is provided with a plurality of slots with the same orientation, the slots are sequentially arranged in the direction perpendicular to the bearing surface, the abutting parts comprise a plurality of abutting blocks corresponding to the slots, the abutting parts are sequentially arranged in the direction perpendicular to the bearing surface, each abutting block is provided with a pressing surface facing the bearing surface, and the pressing surface is pressed on the surface, opposite to the bearing surface, of the corresponding memory strip.

10. An electronic device, comprising:

a housing having an accommodation space;

the memory bank mounting structure according to any one of claims 1 to 9, the memory bank mounting structure being disposed in the accommodation space;

the memory bar passes through the socket of the slot and is at least partially positioned in the socket.

Images