CN117060832A - Component mounting structure and assembly method thereof - Google Patents

Abstract

The application discloses a component mounting structure and an assembly method thereof, wherein the component mounting structure comprises a frame, the frame comprises a first frame, at least one connecting piece is connected to the first frame, the first frame comprises a clamping groove and a cavity connected with the clamping groove, the cavity is positioned below the clamping groove, and the cavity corresponding to a pressing block is connected with a bracket through the connecting piece; the connecting piece includes the base and the riser that is connected with the base, constitutes the mounting groove between base and the riser, and the die cavity is located the mounting groove, adopts this scheme, through mutual cooperation between connecting piece and the die cavity, corresponds the die cavity installation connecting piece of briquetting department, and the die cavity of non-corresponding briquetting department need not to install the connecting piece to reduce the shielding of subassembly back to light as far as possible, in order to promote the double-sided rate of subassembly, and then promote the generating efficiency of subassembly.

Description

Component mounting structure and assembly method thereof

Technical Field

The present application relates to the field of photovoltaics, and more particularly, to a component mounting structure and an assembly method thereof.

Background

Compared with the traditional fossil fuel, the solar energy is an emerging energy source and has the advantages of inexhaustible, clean and environment-friendly aspects and the like. At present, a main solar energy utilization mode is to convert received light energy into electric energy to be output through a photovoltaic module, wherein the photovoltaic double-glass module has higher reliability and PID (potential induced degradation) resistance, so that the performance and reliability of a product are verified and promoted, and more photovoltaic power stations and distributed power generation use the double-glass module.

The double glass assembly can absorb ground reflected light at the back of the assembly, so that the output power of the assembly is improved, but part of reflected light can be shielded by the extending plate of the bottom wall in the frame, so that the reflected light cannot be reflected to the battery piece, and the double-sided rate of the double glass assembly is reduced due to shielding of the extending plate of the bottom wall in the frame, so that the double glass assembly is a technical problem to be solved in the art.

Disclosure of Invention

In view of the above, the present application provides a component mounting structure, which solves the problem of how to reduce the shielding of the extension plate of the bottom wall in the frame.

In a first aspect, the application provides a component mounting structure, which comprises a frame, wherein the frame comprises a first frame, at least one connecting piece is connected to the first frame, the first frame comprises a clamping groove and a cavity connected with the clamping groove, the cavity is positioned below the clamping groove, and the cavity corresponding to a pressing block is connected with a bracket through the connecting piece;

the connecting piece comprises a base and a vertical plate connected with the base, a mounting groove is formed between the base and the vertical plate, and the cavity is located in the mounting groove.

Optionally, the cavity comprises a bottom wall; the base includes the diaphragm, the riser is located the diaphragm is kept away from support one side, the tip of diaphragm is provided with the joint spare, joint spare is close to support one side and is provided with to keeping away from the sunken first joint groove of riser, the riser is close to support one side is provided with to keeping away from the sunken second joint groove of joint spare, peg graft respectively to first joint portion and second joint portion in the both ends of diapire.

Optionally, the length of the first clamping groove along the first direction is greater than the length of the second clamping groove along the first direction, the second direction is the direction from the clamping groove to the cavity, and the first direction intersects with the second direction.

Optionally, the cross section shape of the clamping piece along the second direction is T-shaped, and the vertical plate and the transverse plate form an inverted T-shaped structure.

Optionally, the diapire includes relative first joint portion and the second joint portion that sets up, first joint portion with first joint groove cooperatees, second joint portion with the second joint groove cooperatees, first joint portion joint to first joint groove, second joint portion joint to the second joint groove.

Optionally, the length of the transverse plate along the third direction is smaller than the length of the first frame along the third direction, and the third direction is the extending direction of the first frame.

Optionally, at least one boss is disposed on a side of the cross plate away from the bracket, and the boss contacts with the bottom wall.

Optionally, the cavity further comprises a side wall connected with the bottom wall, and the side wall is connected with the riser through a fastener.

Optionally, the width of the cavity along the first direction ranges from 5mm to 6mm, the second direction is the direction from the clamping groove to the cavity, and the first direction intersects with the second direction.

Optionally, a mounting hole penetrating along a second direction is formed in one side, away from the cavity, of the transverse plate, and the second direction is a direction from the clamping groove to the cavity.

Optionally, the briquetting includes the butt spare with die cavity looks butt, joint spare is kept away from support one side is provided with to keeping away from the sunken third joint groove of riser, the bottom butt of butt spare extremely third joint groove.

A second aspect of the assembly method of any one of the above component mounting structures, wherein the first frame is put into the connecting member in an inclined manner, the first clamping portion is clamped into the first clamping groove, and when the first clamping portion is completely clamped into the first clamping groove, the first frame is put flat to make the bottom wall contact with the base; and then the second clamping part is clamped into the second clamping groove, and when the second clamping part is clamped into the second clamping groove completely, the side wall and the vertical plate are connected together through the fastener.

Compared with the prior art, the assembly mounting structure and the assembly method thereof provided by the application have the advantages that at least the following effects are realized:

the application provides a component mounting structure and an assembly method thereof, wherein the component mounting structure comprises a frame, the frame comprises a first frame, at least one connecting piece is connected to the first frame, the first frame comprises a clamping groove and a cavity connected with the clamping groove, the cavity is positioned below the clamping groove, and the cavity corresponding to a pressing block is connected with a bracket through the connecting piece; the connecting piece includes the base and the riser that is connected with the base, constitutes the mounting groove between base and the riser, and the die cavity is located the mounting groove, adopts this scheme, through mutual cooperation between connecting piece and the die cavity, corresponds the die cavity installation connecting piece of briquetting department, and the die cavity of non-corresponding briquetting department need not to install the connecting piece to reduce the shielding of subassembly back to light as far as possible, in order to promote the double-sided rate of subassembly, and then promote the generating efficiency of subassembly.

Of course, it is not necessary for any one product embodying the application to achieve all of the technical effects described above at the same time.

Other features of the present application and its advantages will become apparent from the following detailed description of exemplary embodiments of the application, which proceeds with reference to the accompanying drawings.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the application and together with the description, serve to explain the principles of the application.

FIG. 1 is a schematic view of a prior art component mounting structure;

FIG. 2 is a schematic view of a component mounting structure according to the present application;

FIG. 3 is a schematic cross-sectional view of F-F' of FIG. 2;

FIG. 4 is a schematic view of a structure of the first frame and the connecting member before the first frame and the connecting member are assembled;

FIG. 5 is a schematic view of a first frame according to the present application;

FIG. 6 is a schematic view of a connector according to the present application;

FIG. 7 is a partial enlarged view at D in FIG. 2;

FIG. 8 is a flow chart of an assembly method of a component mounting structure according to the present application;

fig. 9 is a schematic diagram of an assembly flow between a first frame and a connecting member according to the present application.

Detailed Description

Various exemplary embodiments of the present application will now be described in detail with reference to the accompanying drawings. It should be noted that: the relative arrangement of the components and steps, numerical expressions and numerical values set forth in these embodiments do not limit the scope of the present application unless it is specifically stated otherwise.

The following description of at least one exemplary embodiment is merely exemplary in nature and is in no way intended to limit the application, its application, or uses.

Techniques, methods, and apparatus known to one of ordinary skill in the relevant art may not be discussed in detail, but are intended to be part of the specification where appropriate.

In all examples shown and discussed herein, any specific values should be construed as merely illustrative, and not a limitation. Thus, other examples of exemplary embodiments may have different values.

It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further discussion thereof is necessary in subsequent figures.

FIG. 1 is a schematic view of a prior art component mounting structure; at present, the frame is provided with an A surface, a B1 surface, a B2 surface, a C surface and a D surface, wherein a clamping groove 2' for bearing the photovoltaic laminated piece 1' is formed between the A surface and the D surface, and a cavity 3' is formed between the B1 surface, the B2 surface, the C surface and the D surface; the C1 surface is positioned at the bottom of the cavity 3', the C1 surface extends inwards to form the C2 surface, and when the C surface is used for installing a component, the C surface is a contact surface contacted with the bracket, and the light of the component is blocked due to the existence of the C2 surface and cannot absorb the reflected light of the ground, so that the output power is reduced.

FIG. 2 is a schematic view of a component mounting structure according to the present application; FIG. 3 is a schematic cross-sectional view of F-F' of FIG. 2; FIG. 4 is a schematic view of a structure of the first frame and the connecting member before the first frame and the connecting member are assembled; FIG. 5 is a schematic view of a first frame according to the present application; FIG. 6 is a schematic view of a connector according to the present application; referring to fig. 2-6, the assembly mounting structure provided in this embodiment includes a frame 1, where the frame 1 includes a first frame 11, at least one connecting member 2 is connected to the first frame 11, the first frame 11 includes a clamping groove 110 and a cavity 120 connected to the clamping groove 110, the cavity 120 is located below the clamping groove 110, and the cavity 120 corresponding to the pressing block 4 is connected to the bracket 3 through the connecting member 2; the connecting piece 2 comprises a base 20 and a vertical plate 21 connected with the base 20, a mounting groove 22 is formed between the base 20 and the vertical plate 21, and a cavity 120 is positioned in the mounting groove 22.

In particular, as shown in connection with fig. 2 and 3, the assembly mounting structure comprises a frame 1, which frame 1 may be a photovoltaic frame, for mounting at the edge of a laminate (not shown in the figures). The frame 1 comprises a first frame 11, wherein the first frame 11 can be a long frame of a photovoltaic frame, the first frame 11 is provided with an A face, a B1 face, a B2 face, a C face and a D face, and the A face is the front face of the first frame 11, so that the surface requirements are very strict, and defects such as a lighting line, a black point, chromatic aberration and the like cannot be caused; the B1 surface and the B2 surface may be the outer side surface and the inner side surface of the first frame 11, which belong to decoration surfaces, a clamping groove 110 for bearing a laminated piece (not shown in the figure) is formed between the a surface and the D surface, and a cavity 120 is formed between the B1 surface, the B2 surface, the C surface and the D surface, and the first frame 11 has no C2 surface, that is, the bottom wall 1201 of the cavity 120 in the first frame 11 has no extension plate. In order to realize the fixed connection between the cavity 120 and the bracket 3, the connecting piece 2 may be installed on the first frame 11, and the connecting piece 2 may adopt a buckle structure.

The plurality of connecting pieces 2 are arranged and installed along the extending direction of the first frame 11, the number of the connecting pieces 2 can be one, two, three or four, of course, the installation number of the connecting pieces 2 is selected according to actual conditions, as long as the first frame 11 can be ensured to be fixed on the bracket 3, and the following needs to be described: as long as the cavity 120 is stably connected with the bracket 3, the connecting pieces 2 are not required to be designed in a large number, and the shielding of the connecting pieces 2 to the light reflected from the lower part is avoided as much as possible.

As shown in fig. 3, fig. 5 and fig. 6, the first frame 11 includes a clamping groove 110 and a cavity 120, the cavity 120 is located below the clamping groove 110, the clamping groove 110 is used for clamping the laminated piece 5, the laminated piece 5 includes a first packaging panel 51, a front packaging adhesive film 52, a battery string 53, a back packaging adhesive film 54 and a second packaging panel 55 which are stacked, the first packaging panel 51 and the second packaging panel 55 may be all glass, or the first packaging panel 51 is glass, the second packaging panel 55 is a back plate, in this embodiment, only the first packaging panel 51 and the second packaging panel 55 may be all glass for illustration, so as to improve the double-sided rate of the assembly; the die cavity 120 is used for inserting angle codes, and the die cavity 120 corresponding to the pressing block 4 is fixedly connected to the bracket 3 through the connecting piece 2 so as to ensure that the bracket 3 is stably connected with the die cavity 120. It can be understood that: except for the die cavity 120 corresponding to the pressing block 4, the rest of the die cavities 120 are provided with the first frame 11, the connecting piece 2 is not required to be installed, the shielding of the C2 surface of the photovoltaic frame in the prior art is reduced as much as possible, more reflected light on the ground is absorbed, so that the double-sided rate of the assembly is improved, and the power generation efficiency is improved.

As shown in fig. 4 and 6, the connecting piece 2 includes a base 20 and a riser 21, where the base 20 and the riser 21 are fixedly connected, alternatively, the base 20 and the riser 21 may be in an integral structure, so as to improve stability between the base 20 and the riser 21, although the base 20 and the riser 21 may also be in a split structure according to practical situations, and the base 20 and the riser 21 may form a mounting groove 22 without limitation, and the cavity 120 is directly mounted in the mounting groove 22, and opposite sides of the mounting groove 22 on the base 20 along the first direction X may replace the C2 surface in the existing frame, and use the position fixing bracket 3 on opposite sides of the mounting groove 22 on the base 20.

Optionally, as shown in fig. 2, the frame 1 may further include a second frame 12 opposite to the first frame 11, where the second frame 12 and the first frame 11 are long frames, the second frame 12 may also be provided with connectors 2, the connectors 2 on the second frame 12 are mirror symmetrical to the connectors 2 on the first frame 11, and the number of the connectors is the same, on the basis of installing the connectors 2 on the first frame 11, the connectors 2 are also installed at the second frame 12, and the connectors 2 installed on the second frame 11 are identical to the connectors 2 installed on the first frame 11 in structure, so that shielding of the back of the assembly against light can be effectively reduced, and the double-sided rate of the assembly is improved, thereby improving the power generation efficiency of the assembly.

As can be seen from the foregoing embodiments, the component mounting structure provided in this embodiment at least achieves the following beneficial effects:

the component mounting structure provided by the embodiment comprises a frame 1, wherein the frame 1 comprises a first frame 11, at least one connecting piece 2 is connected to the first frame 11, the first frame 11 comprises a clamping groove 110 and a cavity 120 connected with the clamping groove 110, the cavity 120 is positioned below the clamping groove 110, and the cavity 120 corresponding to a pressing block 4 is connected with a bracket 3 through the connecting piece 2; the connecting piece 2 includes base 20 and riser 21 that is connected with base 20, constitutes mounting groove 22 between base 20 and the riser 21, and die cavity 120 is located mounting groove 22, adopts this scheme, through mutual cooperation between connecting piece 2 and the die cavity 120, corresponds die cavity 120 installation connecting piece 2 of briquetting 4 department, and die cavity 120 of non-briquetting 4 department need not to install connecting piece 2 to reduce the shielding of subassembly back to light as far as possible, in order to promote subassembly double face rate, and then promote the generating efficiency of subassembly.

In an alternative embodiment, cavity 120 includes a bottom wall 1201; the base 20 includes diaphragm 201, and riser 21 is located diaphragm 201 and keeps away from support 3 one side, and the tip of diaphragm 201 is provided with joint spare 202, and joint spare 202 is close to support 3 one side and is provided with to keeping away from the sunken first joint groove 202a of riser 21, and riser 21 is close to support 3 one side and is provided with to keeping away from the sunken second joint groove 210 of joint spare 202, and peg graft respectively to first joint portion 1201a and second joint portion 1201b in the both ends of diapire 1201.

Specifically, as shown in fig. 3-6, the cavity 120 includes a bottom wall 1201, the bottom wall 1201 is located at the bottom of the cavity 120, the base 20 includes a transverse plate 201, the transverse plate 201 may be rectangular in shape, the vertical plate 21 is located at one side of the transverse plate 201 far away from the bracket 3, the vertical plate 21 may be rectangular in shape, an inverted T-shaped structure is formed between the vertical plate 21 and the transverse plate 201, a mounting groove 22 is formed along one side in the first direction X, opposite sides of the mounting groove 22 form a C-plane, so that the transverse plate 201 and the bracket 3 are fixedly connected together, a clamping piece 202 is disposed at an end of the transverse plate 201, an orthographic projection of the clamping piece 202 along the second direction Y is located in an orthographic projection of the pressing block 4 along the second direction Y, a first clamping groove 202a recessed toward a side far away from the vertical plate 21 is disposed at one side of the bracket 3, a second clamping groove 210 recessed toward a side far away from the vertical plate 21 is disposed at a side of the vertical plate 21, the first clamping groove 202a and the second clamping groove 210 is matched with the second clamping groove 210 along the first direction X, so that two ends of the bottom wall 202 are respectively clamped into the first clamping groove 1201 and the second clamping groove 210 and the first clamping groove 210 are directly connected to the first side frame 11 a and the first side frame 11, and the second clamping groove is directly connected to the first side frame 11 and the first side frame 210, and the frame is conveniently assembled. The cross-sectional shape of the clamping member 202 along the second direction Y may be T-shaped, which is advantageous for plugging the bottom wall 1201 of the cavity 120.

In an alternative embodiment, as shown in fig. 4 and 6, the length of the first clamping groove 202a along the first direction X is greater than the length of the second clamping groove 210 along the first direction X, the second direction Y is the direction from the clamping groove 110 to the cavity 120, the first direction X intersects with the second direction Y, alternatively, the first direction X is perpendicular to the second direction Y, because the size of the first clamping groove 202a is greater than the size of the second clamping groove 210, when the first frame 11 is obliquely placed into the base 20, the end of the bottom wall 1201 close to the first clamping groove 202a is clamped to the first clamping groove 202a, after adjusting the position of the first frame 11, the end of the bottom wall 1201 close to the second clamping groove 210 is clamped to the second clamping groove 210, which is convenient and fast to assemble.

In an alternative embodiment, as shown in fig. 3-5, the bottom wall 1201 includes a first clamping portion 1201a and a second clamping portion 1201B that are disposed opposite to each other along the first direction X, where the first clamping portion 1201a and the second clamping portion 1201B are not disposed inside the cavity 120, such as an L-shaped structure formed between the B1 surface and the first clamping portion 1201a, an L-shaped structure formed between the B2 surface and the second clamping portion 1201B, and a mirror symmetry may be formed between the L-shaped structure formed between the B1 surface and the first clamping portion 1201a and an L-shaped structure formed between the B2 surface and the second clamping portion 1201B. The first clamping portion 1201a is matched with the first clamping groove 202a, the second clamping portion 1201b is matched with the second clamping groove 210, and since the first clamping portion 1201a is matched with the first clamping groove 202a and the second clamping portion 1201b is matched with the second clamping groove 210, the length of the first clamping portion 1201a along the first direction X can be greater than the length of the second clamping portion 1201b along the first direction X, so that the first clamping portion 1201a is clamped to the first clamping groove 202a, and the second clamping portion 1201b is clamped to the second clamping groove 210.

In an alternative embodiment, with continued reference to fig. 2, the length of the transverse plate 201 may extend along the extending direction of the first frame 11, and in order to reduce the shielding of the light by the back surface of the assembly, the length of the transverse plate 201 along the third direction Z is smaller than the length of the first frame 11 along the third direction Z, where the third direction Z may be the extending direction of the first frame 11, and may be understood as: the orthographic projection of the transverse plate 201 along the second direction Y may cover the orthographic projection of the bracket 3 along the second direction Y, so long as the fixed installation between the frame 1 and the bracket 3 can be realized.

In an alternative embodiment, as shown in fig. 3 and fig. 4, at least one boss 203 is disposed on a side of the transverse plate 201 away from the bracket 3, the boss 203 protrudes toward a side away from the bracket 3, a cross-sectional shape of the boss 203 along the second direction Y may be trapezoid, a side of the boss 203 away from the bracket 3 and a side of the bottom wall 1201 close to the bracket 3 may be flat, the number of the bosses 203 may be 2, and the 2 bosses 203 may be arranged along the first direction X, such as one boss 203 is close to the first clamping groove 202a, so as to clamp the first clamping portion 1201a into the first clamping groove 202a between the bottom wall 1201, the boss 203 and the clamping member 202, and the other boss 203 is close to the second clamping groove 210, so as to clamp the second clamping portion 1201b into the second clamping groove 210 between the bottom wall 1201, the boss 203 and the vertical plate 21, and after the first clamping portion 1201a is clamped into the first clamping groove 202a, the second clamping portion 1201b is prevented from being separated from the first clamping portion 1201a and the second clamping groove 210.

It should be noted that: referring to fig. 6, the riser 21, the transverse plate 201, the clamping member 202 and the boss 203 may be integrally formed, and the riser 21, the transverse plate 201, the clamping member 202 and the boss 203 may be integrally formed, so that the stability of the clamping between the connecting member 2 and the first frame 11 can be improved, and the assembly cost can be saved.

In an alternative embodiment, referring to FIG. 3, cavity 120 further includes side walls 1202 connected to bottom wall 1201, side walls 1202 being connected to riser 21 by fasteners 23; the side wall 1202 may be an inner wall of the cavity 120, the inner wall of the cavity 120 is fixedly connected with one side of the riser 21, which is close to the cavity 120, by a fastener 23, the fastener 23 may be a rivet, such as a self-plugging rivet, and the inner wall of the cavity 120 is fixedly connected with the riser 21 by the rivet, which is convenient and fast, and is beneficial to improving the assembly efficiency between the cavity 120 and the riser 21.

In an alternative embodiment, the width of the cavity 120 in the first direction X ranges from 5mm to 6mm, and the second direction Y is the direction from the card slot 110 to the cavity 120, the first direction X intersecting the second direction Y.

Specifically, as shown in fig. 3 to 4, on the one hand, if the width of the cavity 120 along the first direction X is less than 5mm, it is not beneficial to insert a corner connector (not shown in the drawings); on the other hand, if the width of the cavity 120 along the first direction X is greater than 6mm, when the bottom wall 1201 includes the first clamping portion 1201a and the second clamping portion 1201b that are disposed opposite to each other along the first direction X, the requirement that the first clamping portion 1201a is clamped to the first clamping groove 202a and the second clamping portion 1201b is clamped to the second clamping groove 210 cannot be met, as shown in fig. 2, and meanwhile, because the width of the cavity 120 along the first direction X is too wide, the manufacturing cost of the first frame 11 is increased; therefore, the width range of the cavity 120 along the first direction X is designed to be 5mm-6mm, which is not only beneficial to inserting the corner code, but also can meet the requirement that the first clamping portion 1201a is clamped to the first clamping groove 202a, and the second clamping portion 1201b is clamped to the second clamping groove 210, and simultaneously reduce the manufacturing cost of the first frame 11.

In an alternative embodiment, FIG. 7 is a partial enlarged view at D in FIG. 2; as shown in fig. 3 and 7, a mounting hole 202 penetrating along a second direction Y is formed on a side, away from the cavity 120, of the cross plate 201, and the mounting hole 202 may be circular or elliptical, or may take other shapes according to actual needs, which are not limited thereto, and the cross plate 201 and the bracket 3 are assembled by the mounting hole 202 and screws to complete the fixed connection between the first frame 11 and the bracket 3, and the second direction Y is a direction from the clamping groove 110 to the cavity 120.

In an alternative embodiment, as shown in fig. 3 and 4, the pressing block 4 includes an abutment member 41 abutted against the cavity 120, the cross-sectional shape of the abutment member 41 along the second direction Y may be q-shaped, a third clamping groove 202b recessed away from the riser 21 is provided on the side of the clamping member 202 away from the bracket 3, the bottom of the abutment member 41 abuts against the third clamping groove 202b, and the abutment member 41 directly abuts against the third clamping groove 202b of the clamping member 202, so that the cavity 120 can be fixed more firmly.

FIG. 8 is a flow chart of an assembly method of a component mounting structure according to the present application; referring to fig. 9, which is a schematic diagram illustrating an assembling process between a first frame and a connecting member, and referring to fig. 8 and 9, the present embodiment provides an assembling method of a component mounting structure, in which a first frame 11 is obliquely placed into a connecting member 2, a first clamping portion 1201a is first clamped into a first clamping groove 202a, and when the first clamping portion 1201a is completely clamped into the first clamping groove 202a, the first frame 11 is placed flat to make the bottom wall 1201 contact with a base 20; and then the second clamping part 1201b is clamped into the second clamping groove 210, and when the second clamping part 1201b is clamped into the second clamping groove 210 completely, the side wall 1202 and the riser 21 are connected together by the fastener 23.

Specifically, as shown in connection with fig. 8 and 9, the assembly method of the component mounting structure includes the steps of: the first side frame 11 is obliquely placed into the base 20 of the connecting piece 2 at a designated position, the first side frame 11 is rotated by 30-40 degrees anticlockwise to clamp the first clamping part 1201a into the first clamping groove 202a, the first side frame 11 clamps the first clamping part 1201a into the first clamping groove 202a to the outer side of the cavity 120, the first side frame 11 is flattened, the bottom surface of the first side frame 11 is flatly attached to the boss 203 on the base 20, the second clamping part 1201b is clamped into the second clamping groove 210 to the inner side of the cavity 120, the fastening piece 23 (such as a blind rivet) is placed into holes which are sequentially inserted into the riser 21 and the side wall 1202, and then the riveting between the side wall 1202 and the riser 21 is pulled out.

According to the embodiment, the assembly mounting structure and the assembly method thereof provided by the application have the following beneficial effects:

the application provides a component mounting structure and an assembly method thereof, wherein the component mounting structure comprises a frame, the frame comprises a first frame, at least one connecting piece is connected to the first frame, the first frame comprises a clamping groove and a cavity connected with the clamping groove, the cavity is positioned below the clamping groove, and the cavity corresponding to a pressing block is connected with a bracket through the connecting piece; the connecting piece includes the base and the riser that is connected with the base, constitutes the mounting groove between base and the riser, and the die cavity is located the mounting groove, adopts this scheme, through mutual cooperation between connecting piece and the die cavity, corresponds the die cavity installation connecting piece of briquetting department, and the die cavity of non-corresponding briquetting department need not to install the connecting piece to reduce the shielding of subassembly back to light as far as possible, in order to promote the double-sided rate of subassembly, and then promote the generating efficiency of subassembly.

While certain specific embodiments of the application have been described in detail by way of example, it will be appreciated by those skilled in the art that the above examples are for illustration only and are not intended to limit the scope of the application. It will be appreciated by those skilled in the art that modifications may be made to the above embodiments without departing from the scope and spirit of the application. The scope of the application is defined by the appended claims.

Claims (12)

1. The component mounting structure is characterized by comprising a frame, wherein the frame comprises a first frame, at least one connecting piece is connected to the first frame, the first frame comprises a clamping groove and a cavity connected with the clamping groove, the cavity is positioned below the clamping groove, and the cavity corresponding to a pressing block is connected with a bracket through the connecting piece;

the connecting piece comprises a base and a vertical plate connected with the base, a mounting groove is formed between the base and the vertical plate, and the cavity is located in the mounting groove.

2. The component mounting arrangement of claim 1, wherein the cavity includes a bottom wall; the base includes the diaphragm, the riser is located the diaphragm is kept away from support one side, the tip of diaphragm is provided with the joint spare, joint spare is close to support one side and is provided with to keeping away from the sunken first joint groove of riser, the riser is close to support one side is provided with to keeping away from the sunken second joint groove of joint spare, peg graft respectively to first joint portion and second joint portion in the both ends of diapire.

3. The component mounting structure of claim 2, wherein a length of the first clamping groove in a first direction is greater than a length of the second clamping groove in the first direction, the second direction being a direction from the clamping groove toward the cavity, the first direction intersecting the second direction.

4. A component mounting arrangement as claimed in claim 3, wherein the cross-sectional shape of the clip along the second direction is T-shaped, the riser and cross-plate forming an inverted T-shaped arrangement.

5. The component mounting structure of claim 2, wherein the bottom wall includes a first clamping portion and a second clamping portion disposed opposite to each other, the first clamping portion being mated with the first clamping groove, the second clamping portion being mated with the second clamping groove, the first clamping portion being clamped to the first clamping groove, the second clamping portion being clamped to the second clamping groove.

6. The component mounting structure of claim 2, wherein a length of the cross plate in a third direction is less than a length of the first rim in a third direction, the third direction being an extension direction of the first rim.

7. The component mounting structure according to claim 2, wherein the side of the cross plate away from the bracket is provided with at least one boss that contacts the bottom wall.

8. The assembly mounting structure of claim 2 wherein the cavity further comprises a side wall connected to the bottom wall, the side wall being connected to the riser by a fastener.

9. The component mounting structure of claim 2, wherein the width of the cavity in a first direction is in the range of 5mm to 6mm, and the second direction is a direction directed toward the cavity by the card slot, the first direction intersecting the second direction.

10. The component mounting structure according to claim 2, wherein a mounting hole penetrating in a second direction is provided on a side of the cross plate away from the cavity, the second direction being a direction directed toward the cavity by the clamping groove.

11. The component mounting structure according to claim 2, wherein the pressing block includes an abutting piece abutting against the cavity, a third clamping groove recessed toward and away from the riser is provided on a side of the clamping piece away from the bracket, and a bottom of the abutting piece abuts against the third clamping groove.

12. A method of assembling a component mounting structure according to any one of claims 1 to 11, wherein the first frame is put obliquely into the connecting member, the first clamping portion is clamped into the first clamping groove, and when the first clamping portion is completely clamped into the first clamping groove, the first frame is put flat so that the bottom wall is in contact with the base; and then the second clamping part is clamped into the second clamping groove, and when the second clamping part is clamped into the second clamping groove completely, the side wall and the vertical plate are connected together through the fastener.