CN107524902B - Supporting structure for optical communication equipment and optical communication equipment - Google Patents

Abstract

The invention discloses a support structure for optical communication equipment and optical communication equipment comprising the same, wherein the support structure comprises a rear shell and a support structure, and the support structure comprises a support plate and a support plate; the support plate is connected with the rear shell through a first connecting shaft on the support plate, and two opposite side edges of the support plate are respectively connected with the support plate and the rear shell; the first connecting shaft and the support plate are integrally arranged; the rear shell, the support plate and the support plate form a stable triangular support structure. The invention can solve the defect of unstable support of the existing optical time domain reflectometer and provides the support structure for the optical time domain reflectometer and the optical time domain reflectometer, which have the advantages of low cost, stable structure and automatic opening and support. The bracket structure adopted by the invention is stable in support, is not easy to damage in the using process and can resist external force impact with considerable strength. And the operation structure is simple, the processing cost is low, and the aim of reducing the product cost is effectively fulfilled.

Description

Supporting structure for optical communication equipment and optical communication equipment

Technical Field

The invention relates to the field of optical cable construction and maintenance equipment, in particular to a support structure for optical communication equipment and the optical communication equipment comprising the same.

Background

With the development of optical fiber communication technology, optical communication equipment is applied more and more widely, and in order to adapt to operations in various conditions such as high altitude, on the ground and the like, the optical communication equipment is often provided with a support structure. The support structure can facilitate better data observation of operators during specific operation, and accords with the principle of human engineering.

The support structure of the existing common optical communication equipment is mostly supported by a supporting point, namely, a plate which can be pulled open is arranged on the rear shell. The mode has high requirement on the strength of the fulcrum and unstable support, and the fulcrum is broken due to severe working environment in the actual use process, so that the adverse effect is generated on the whole use.

Disclosure of Invention

The present invention is to solve the problem of making up the above-mentioned defects in the prior art, and provides a bracket structure for optical communication equipment, which has low cost and a stable structure, and optical communication equipment using the bracket structure.

The technical problem of the invention can be solved by the following technical scheme:

a supporting structure for optical communication equipment comprises a rear shell and a supporting structure, wherein the supporting structure comprises a supporting plate and a supporting plate; the support plate is connected with the rear shell through a first connecting shaft on the support plate, and two opposite side edges of the support plate are respectively connected with the support plate and the rear shell.

The first connecting shaft and the support plate are integrally arranged; the rear shell, the support plate and the support plate form a stable triangular support structure.

Further, the support plate comprises a support plate accommodating part which is slightly lower than the inner surface of the support plate, and the side edge of the support plate accommodating part comprises a support plate accommodating groove; the support plate comprises a second connecting shaft connected with the support plate, and the second connecting shaft slides in the support plate accommodating groove.

Further, the rear housing includes a bracket cover plate disposed at an inner side of the rear housing, the bracket cover plate including a support plate connection hole; the support plate comprises a fourth connecting shaft connected with the support plate connecting hole.

Further, the support structure comprises a spring; the spring includes a first spring support portion, a second spring support portion, and a spring connecting portion.

The support cover plate comprises a first spring accommodating part for accommodating the first spring supporting part, the support plate comprises a second spring accommodating part for accommodating the second spring supporting part, the support plate comprises a third connecting shaft connected with the spring connecting part, and the spring enables the support plate to generate a force far away from the support cover plate.

Further, the bracket cover plate includes an inclined portion groove, the rear case includes an inclined recessed portion, a first gap is formed between the inclined portion groove and the inclined recessed portion, and the first connecting shaft slides in the first gap.

Further, the inclined part groove comprises an inclined part and a buckling part; the buckling part comprises a buckling bulge and a buckling connecting part, and a buckling gap is arranged between the buckling part and the inclined part.

Further, the bracket cover plate comprises a raised line, and the rear shell comprises a side step matched and connected with the raised line; the sand grip with form the second space between the buckle arch, the width in second space with the diameter adaptation of first connecting axle, will when external force first connecting axle presses to the second space, first connecting axle is spacing.

Further, the support plate includes a bent portion, and the bent portion is connected to the second connecting shaft; the support plate comprises a baffle plate, and a third gap for the second connecting shaft to slide into the support plate accommodating groove is formed between the baffle plate and the support plate accommodating groove.

Further, the support plate also includes a support plate void.

Furthermore, be provided with the gliding slope arch of a plurality of mounting panel of being convenient for on the slope.

Further, the backshell includes the arch, the mounting panel includes the shrinkage pool, the arch with the shrinkage pool adaptation, when the mounting panel lock is in the time, protruding card is gone into in the shrinkage pool, the supporting structure is spacing.

Further, the length of the support plate is smaller than that of the accommodating position of the support cover plate, and when the support structure is closed, a fourth gap is formed between the support plate and the rear shell.

The invention also provides optical communication equipment which is provided with the support structure.

The invention achieves the following beneficial effects:

1. the bracket structure adopted by the invention is stable in support, is not easy to damage in the using process, and can resist external force impact with considerable strength.

2. The bracket structure adopted by the invention adopts a quick opening mode, is convenient and simple to use and is simple to operate.

3. The invention has simple structure and low processing cost, and effectively realizes the aim of reducing the product cost.

Drawings

Fig. 1 is an exploded view of the overall structure of a mounting structure for optical communication equipment according to the present invention;

FIG. 2 is a schematic view of a rear housing of the mounting structure for optical communication equipment according to the present invention;

FIG. 3 is a schematic structural diagram of a bracket cover plate of the bracket structure for an optical communication apparatus according to the present invention;

FIG. 4 is a schematic structural view of a mounting plate of the mounting structure for optical communication equipment according to the present invention;

FIG. 5 is a schematic structural view of a support plate of the mounting structure for optical communication equipment according to the present invention;

FIG. 6 is a schematic structural view of a spring of the supporting structure for optical communication equipment according to the present invention;

FIG. 7 is a schematic view of a supporting state of a supporting structure for an optical communication apparatus according to the present invention;

FIG. 8 is an enlarged, fragmentary view of the structure shown in FIG. 7;

FIG. 9 is a schematic view illustrating a supporting state of the supporting plate of the supporting structure for optical communication apparatus according to the present invention when the supporting plate is not opened;

fig. 10 is a schematic view illustrating a supporting state when the cradling plate of the optical communication apparatus of the present invention is opened;

FIG. 11 is a schematic structural view of the optical communication apparatus of the present invention when the mounting plate is closed;

fig. 12 is a schematic structural view of the optical communication device when the mounting plate is closed;

fig. 13 is a schematic view illustrating the connection between the rear housing and the cover plate of the optical communication apparatus according to the present invention.

The reference numbers in the figures:

1 rear shell 11 shelf cover receiving 111 first side 14 inclined side 15 side step 16 abutting surface 17 first connecting axle receiving groove 2 shelf cover 21 inclined groove 211 inclined protrusion 212 inclined portion 22 snap fit protrusion 222 snap fit connection 223 snap fit clearance 23 protrusion 24 first spring receiving 25 support plate connection 26 second side 3 shelf plate 31 first connecting axle 32 baffle 33 receiving 331 support plate receiving 34 recess 35 limit rib 36 second step portion 4 support plate 41 second connecting axle 42 bend 43 second spring receiving 44 support plate clearance 45 third connecting axle 46 fourth connecting axle 5 spring connecting 52 first spring receiving 53 second spring receiving

6 first gap 7 second gap 8 third gap 9 fourth gap.

Detailed Description

The present invention will be further described below based on preferred embodiments with reference to the accompanying drawings.

Referring to fig. 1, a supporting structure for an optical communication apparatus includes a rear case 1, a supporting plate 3, a supporting plate 4, and a spring 5. Preferably, the rear case 1 further includes a detachable bracket cover 2. The bracket cover 2 and the rear case 1 may also be integrally formed, and are not limited herein.

Referring to fig. 2, a bracket cover plate accommodating portion 11 for accommodating the bracket cover plate 2, a first side 13, an inclined side 14 having a width smaller than that of the first side 13, a step-shaped side step 15 located between the inclined side 14 and the first side 13, a protrusion 12 protruding from the first side 13, and an inclined concave portion, which is a recessed groove recessed in the inner surface of the rear housing 1 and having an inclination angle, preferably, a first connecting shaft accommodating groove 17 for accommodating the bracket plate 3 is provided in this embodiment. Preferably, the rear housing 1 further includes an abutting surface 16, the abutting surface 16 is lower than the surface 111 of the receiving place of the bracket cover plate, the abutting surface 16 is used for matching with the bracket plate 3, and when the bracket plate is closed, external dust is prevented from directly entering the inside of the bracket structure.

Referring to fig. 3, the bracket cover plate 2 is provided with an inclined portion groove 21 recessed in the bracket cover plate 2 and having an inclined bottom surface, fastening portions 22 at both sides in the inclined portion groove 21 protruding from a protruding strip 23 at the bottom surface of the bracket cover plate 2 for accommodating a first spring accommodating portion 24 of the spring 5, a support plate connecting hole 25 connected to the support plate 4, a second side 26, and a second gap 7 between the protruding strip 23 and the fastening protrusion 221.

The inclined portion groove 21 is provided with an inclined portion 212 and an inclined protrusion 211 protruding from the inclined portion 212. A fastening gap 223 is provided between the fastening portion 22 and the inclined portion 212, and the fastening portion 22 further includes a fastening protrusion 221 protruding from the bottom surface of the fastening portion 22 and having a curved surface, and a fastening connection portion 222 connecting the fastening protrusion 221 and the inclined portion groove 21.

Referring to fig. 4, the support plate 3 is provided with a first connecting shaft 31 integrally disposed with the support plate 3, a baffle 32, a support plate receiving portion 33 slightly lower than the inner surface of the support plate 3, a concave hole 34 engaged with the protrusion 12, a second step portion 36, a third gap 8 between the baffle 32 and the support plate receiving portion 33, and support plate receiving grooves 331 for receiving the support plate 4 and limiting ribs 35 for limiting the sliding distance of the second connecting shaft 41 in the support plate receiving grooves 331 are disposed at two sides of the support plate receiving portion 33. The length of the support plate 3 is less than that of the support cover plate accommodating part 11.

Referring to fig. 5, the supporting plate 4 is provided with a second connecting shaft 41 extending into the supporting plate receiving groove 331 to slide, a bent portion 42, a second spring receiving portion 43 for receiving the spring 5, a supporting plate gap 44, a third connecting shaft 45 for connecting the spring 5, and a fourth connecting shaft 46 connected to the supporting plate connecting hole 25.

Referring to fig. 6, the spring 5 is provided with a spring connecting portion 51 connected to the third connecting shaft 45, a first spring supporting portion 52 contacting the supporting plate 4, and a second spring supporting portion 53 connected to the bracket cover 2.

Referring to fig. 1 to 6 and 13, when the support structure is assembled, the first connecting shaft 31 of the support plate 3 is disposed in the first connecting shaft receiving groove 17, and the first connecting shaft receiving groove 17 is a groove recessed inside the rear housing 1, and has a length matching with the first connecting shaft 31. The support cover plate 2 is connected with the rear shell 1, in the embodiment, the connection mode is not limited, and modes such as clamping, buckling and the like can be adopted. At this time, both ends of the protruding strip 23 on the bracket cover plate 2 are clamped on the side step 15 of the rear shell 1, and a first gap 6 for the movement of the first connecting shaft 31 is formed between the inclined portion groove 21 of the bracket cover plate 2 and the inclined recessed portion, i.e., the first connecting shaft accommodating groove 17, of the rear shell 1.

Preferably, the width of the inclined side 14 is smaller than the width of the groove wall of the inclined groove 21, so that the first connecting shaft 31 is stably accommodated in the first gap 6 without jumping out.

Preferably, the connection mode of the spring 5 and the support plate 4 is as follows: the spring connecting portion 51 is connected to the third connecting shaft 45, the first spring supporting portion 52 is received in the first spring receiving portion 24, the second spring supporting portion 53 is received in the second spring receiving portion 43, and the spring 5 causes the supporting plate 4 to generate a force away from the bracket cover plate 2.

The connection mode of the support plate 4 and the support cover plate 2 is as follows: the fourth connecting shaft 46 is connected to the support plate connecting hole 25, and the support plate gap 44 allows the fourth connecting shaft 46 to be deformed so as to protrude into the support plate connecting hole 25. Meanwhile, the first spring supporting part 52 is received in the second spring receiving part 43, and the second spring supporting part 53 is received in the first spring receiving part 24.

The connection mode of the support plate 4 and the support plate 3 is as follows: the second connecting shaft 41 slides into the supporting plate accommodating groove 331 through the third gap 8, the second connecting shaft 41 can slide in the supporting plate accommodating groove 331, and the sliding range of the second connecting shaft is limited by the limiting edge 35. The second connecting shaft 41 is under the tension of the spring 5, generating a force away from the bracket cover plate 2, and when the second connecting shaft 41 slides to the limiting edge 35, the whole bracket structure is in a supporting state.

Referring to fig. 7 to 12, when the supporting structure has two states, i.e., a supporting state and a closed state.

Referring to fig. 12, the supporting structure of the optical communication apparatus is in a closed state before use. As shown in the figure, the length of the support plate 3 is a, the length of the support cover plate accommodating part 11 is b, and since a < b, when the support structure is closed, the support plate 3 and the rear shell 1 form a fourth gap 9, which is convenient for an operator to open the support plate 3 to start the support structure.

Preferably, the rear housing 1 includes an abutting surface 16 lower than the surface 111 of the receiving place of the bracket cover, in this case, the abutting surface 16 is the bottom surface of the fourth gap 9, and the abutting surface 16 cooperates with the bracket plate 3 to make the side surface of the fourth gap 9 relatively closed, so as to prevent dust from entering.

Referring to fig. 7 and 8, when the optical communication device is in a supporting state, the first connecting shaft 31 of the supporting board 3 is located in the second gap 7, the width of the second gap 7 is adapted to the diameter of the first connecting shaft 31, preferably, the width of the second gap 7 is smaller than or equal to the width of the first connecting shaft 31, and when an external force presses the first connecting shaft 31 into the second gap 7, the first connecting shaft 31 is limited. The second connecting shaft 41 of the supporting plate 4 is located at the bottom of the supporting plate accommodating groove 331, and is in contact with the limiting edge 35 to be limited. The rear shell 1, the support plate 3 and the support plate 4 form a stable triangular support structure.

Referring to fig. 7 to 12, when the supporting structure is opened, the operator opens the supporting plate 3 through the fourth gap 9 by external force. The first connecting shaft 31 of the support plate 3 is located at the top of the first gap 6, and because the spring 5 generates a force separating the support plate 4 from the support cover plate 2, the spring 5 drives the support plate 4 to make an arc motion with the fourth connecting shaft 46 as an axis, that is, the second connecting shaft 41 starts to make a motion from top to bottom in the support plate accommodating groove 331, when the second connecting shaft 41 moves to the bottom of the support plate accommodating groove 331 and contacts the limiting edge 35, the motion of the second connecting shaft 41 in the support plate accommodating groove 331 is stopped, the positions of the support plate 4 and the support plate 3 are fixed, and at this time, the support plate 3 is opened.

In the opening process of the support structure, the support plate 3 moves from the top to the bottom in the first gap 6, the inclined protrusion 211 facilitates the movement of the support plate 3, when the first connecting shaft 31 moves to the upper side of the buckle protrusion 221, due to the blocking of the buckle protrusion 221, the space of the first gap 6 is reduced, at the moment, an operator presses the support plate 3 downwards with force, due to the buckle gap 223, the buckling part 22 is a deformation part, and under the action of external force, the first connecting shaft 31 falls into the second gap 7 and is limited, the support structure is supported stably, and therefore the opening operation of the support structure is completed.

When the support structure is closed, an operator presses the support plate 3 with external force, the first connecting shaft 31 is popped out from the second gap 7, the operator continues to press the support plate 3, the first connecting shaft 31 moves towards the top of the first connecting shaft accommodating groove 17, when the first connecting shaft 31 moves to the top of the first connecting shaft accommodating groove 17, the first connecting shaft 31 is fixed with the rear shell 1 and the support cover plate 2, and at the moment, the support plate 3 is still in an open state.

The operator continues to press the supporting plate 3, at this time, the second connecting shaft 41 starts to move from the limiting edge 35 to the baffle 32 in the supporting plate accommodating groove 331 due to the action of external force until the supporting plate 3 is closed in contact with the rear shell 1, the concave hole 34 in the supporting plate 3 is matched with the protrusion 12 in the rear shell 1 to limit the supporting plate 3, and the supporting structure is closed.

While the invention has been described in detail and with reference to specific embodiments thereof, it will be apparent to one skilled in the art that various changes and modifications can be made therein without departing from the spirit of the invention, and it is intended to claim all such changes and modifications as fall within the scope of the appended claims.

Claims (8)

1. The utility model provides a supporting structure for optical communication equipment, includes backshell and supporting structure, its characterized in that:

the support structure comprises a support plate and a support plate; the support plate is connected with the rear shell through a first connecting shaft on the support plate, and two opposite side edges of the support plate are respectively connected with the support plate and the rear shell; the first connecting shaft and the support plate are integrally arranged; the rear shell, the support plate and the support plate form a stable triangular support structure; the support plate comprises a support plate accommodating part which is slightly lower than the inner surface of the support plate, and the side edge of the support plate accommodating part comprises a support plate accommodating groove; the supporting plate comprises a second connecting shaft connected with the supporting plate, and the second connecting shaft slides in the supporting plate accommodating groove; the rear shell comprises a support cover plate arranged on the inner surface of the rear shell, and the support cover plate comprises a support plate connecting hole; the support plate comprises a fourth connecting shaft connected with the support plate connecting hole; the support structure comprises a spring; the spring comprises a first spring supporting part, a second spring supporting part and a spring connecting part; the support cover plate comprises a first spring accommodating part for accommodating a first spring supporting part, the support plate comprises a second spring accommodating part for accommodating a second spring supporting part, the support plate comprises a third connecting shaft connected with the spring connecting part, and the spring enables the support plate to generate a force far away from the support cover plate; the bracket cover plate comprises an inclined part groove, the rear shell comprises an inclined concave part, a first gap is formed between the inclined part groove and the inclined concave part, and the first connecting shaft slides in the first gap; the inclined part groove comprises an inclined part and a buckling part;

the buckling part comprises a buckling bulge and a buckling connecting part, and a buckling gap is arranged between the buckling part and the inclined part;

the rear shell further comprises a butting surface, and the butting surface is used for being matched with the support plate.

2. A mounting structure for optical communication equipment according to claim 1, wherein:

the bracket cover plate comprises a convex strip, and the rear shell comprises a side step which is matched and connected with the convex strip;

the sand grip with form the second space between the buckle arch, the width in second space with the diameter adaptation of first connecting axle, will when external force first connecting axle presses to the second space, first connecting axle is spacing.

3. A mounting structure for optical communication apparatus according to claim 2, wherein:

the support plate comprises a bent part which is connected with the second connecting shaft;

the support plate comprises a baffle plate, and a third gap for the second connecting shaft to slide into the support plate accommodating groove is formed between the baffle plate and the support plate accommodating groove.

4. A mounting structure for optical communication apparatus according to claim 3, wherein:

the support plate also includes a support plate void.

5. A mounting structure for optical communication equipment according to claim 4, wherein:

the inclined part is provided with a plurality of inclined bulges which are convenient for the support plate to slide.

6. A mounting structure for optical communication equipment according to claim 5, wherein:

the rear shell comprises a protrusion, the support plate comprises a concave hole, the protrusion is matched with the concave hole, when the support plate is buckled, the protrusion is clamped into the concave hole, and the support structure is limited.

7. A mounting structure for optical communication equipment according to claim 6, wherein:

the length of the support plate is smaller than that of the accommodating position of the support cover plate, and when the support structure is closed, a fourth gap is formed between the support plate and the rear shell.

8. An optical communication device, it is equipped with supporting structure, its characterized in that: the support structure for an optical communication apparatus according to any one of claims 1 to 7.

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