CN210942885U - Biconvex optical lens storage disc - Google Patents

Abstract

The utility model discloses a biconvex optical lens storage disc, which relates to the technical field of biconvex optical lens storage, and comprises a biconvex optical lens storage plate and a storage plate auxiliary plate matched with the biconvex optical lens storage plate; the first groove is embedded in the lower surface of the double-convex optical lens containing plate and is located below the double-convex optical lens containing box. The utility model provides an inverted round platform form biconvex optical lens receiver can accomodate biconvex optical lens and carry out fixing to a certain extent, biconvex optical lens's convex surface can not contact the bottom of biconvex optical lens receiver moreover, the wearing and tearing that have avoided biconvex optical lens's convex surface probably to receive, and simultaneously, to biconvex optical lens's the easy operation of accomodating, need not great work load, after single storage disc accomodates more biconvex optical lens, still conveniently shift to biconvex optical lens in batches.

Description

Biconvex optical lens storage disc

Technical Field

The utility model relates to a biconvex optical lens stores technical field, especially relates to a biconvex optical lens storage disc.

Background

After the production biconvex optical lens, need put to biconvex optical lens and store or shift, place single biconvex optical lens in independent box usually at present, when putting a large amount of biconvex optical lens, the operation is comparatively loaded down with trivial details, needs great amount of labour, is also inconvenient to carry out in batches to a large amount of boxes that have been equipped with biconvex optical lens moreover and shifts.

SUMMERY OF THE UTILITY MODEL

The utility model mainly aims at providing a biconvex optical lens storage disc makes single storage disc can accomodate more biconvex optical lens, and further convenience is put and is shifted more biconvex optical lens.

The purpose of the utility model can be achieved by adopting the following technical scheme:

a biconvex optical lens storage disk comprises

A lenticular optical lens housing plate and a housing plate sub-plate used in cooperation with the lenticular optical lens housing plate;

the double-convex optical lens storage box is wide in upper part and narrow in lower part and is in a hollow circular truncated cone shape, the double-convex optical lens storage box is embedded on the upper surface of the double-convex optical lens storage plate, and the double-convex optical lens storage box is used for placing double-convex optical lenses;

the first groove is embedded in the lower surface of the double-convex optical lens containing plate and is positioned below the double-convex optical lens containing box;

the first ejector rod sequentially penetrates through the bottom of the double-convex optical lens storage box and the top of the first groove from top to bottom, the first ejector rod is used for ejecting the double-convex optical lens, and a first spring support plate is fixed at the bottom end of the first ejector rod;

the two ends of the first spring are fixedly connected with the top of the inner side of the first groove and the top side of the first spring supporting plate respectively;

the third groove is embedded in the lower surface of the storage plate auxiliary plate;

the second ejector rod sequentially penetrates through the upper surface of the storage plate auxiliary plate and the top of the third groove from top to bottom, and is used for jacking up the first ejector rod;

the second spring supporting plate is fixed at the bottom end of the second ejector rod;

a second spring disposed between the second spring support plate and an inside top of the third groove.

Preferably, the lenticular optical lens storage case is provided in plurality, and they are in a rectangular array on an upper surface of the lenticular optical lens storage plate.

Preferably, the biconvex optical lens receiver is a truncated cone structure with an open top and a cavity.

Preferably, the left and right bottom sides of the biconvex optical lens storage plate are both provided with second grooves.

Preferably, the number of the first springs is two, and the two springs are respectively positioned at two sides of the first top rod.

Preferably, the first lift pin penetrates through the bottom of the double-convex optical lens storage case at a middle position.

Preferably, the lower surface of biconvex optical lens storage plate still inlays there is the box, the last fixed surface of storage plate subplate has the pin thread, the pin thread with the box cooperation is used for the laminating the storage plate subplate with biconvex optical lens storage plate.

Preferably, the double-convex optical lens storage box protrudes from the upper surface of the double-convex optical lens storage plate, and the side wall of the double-convex optical lens storage box is a rubber curved plate.

Preferably, the first groove and the second top rod are both of a cylindrical structure, and the section diameter of the second top rod is smaller than that of the first groove.

Preferably, the number and the position of the second push rods correspond to those of the double-convex optical lens storage box one by one.

The utility model has the advantages of:

1. the utility model provides an inverted round platform form biconvex optical lens receiver can accomodate biconvex optical lens and carry out fixing to a certain extent, biconvex optical lens's convex surface can not contact the bottom of biconvex optical lens receiver moreover, the wearing and tearing that have avoided biconvex optical lens's convex surface probably to receive, and simultaneously, to biconvex optical lens's the easy operation of accomodating, need not great work load, after single storage disc accomodates more biconvex optical lens, still conveniently shift to biconvex optical lens in batches.

2. The utility model provides a cooperation of second ejector pin and first ejector pin is used can be in batches take out biconvex optical lens, also can the exclusive use second ejector pin 3 take out single biconvex optical lens in addition to this adapts to different service environment.

Drawings

Fig. 1 is a schematic perspective view of a lenticular optical lens receiving plate according to an embodiment of the present invention;

fig. 2 is a schematic cross-sectional view of a lenticular optical lens receiving plate and a lenticular optical lens receiving case according to an embodiment of the present invention;

fig. 3 is a schematic diagram of a cross-sectional structure of a first groove according to an embodiment of the present invention.

In the figure: 1-biconvex optical lens storage plate, 2-biconvex optical lens storage box, 3-first ejector rod, 4-first groove, 5-first spring, 6-first spring support plate, 7-second groove, 8-storage plate auxiliary plate, 9-male buckle, 10-female buckle, 11-third groove, 12-second spring support plate, 13-second spring, and 14-second ejector rod.

Detailed Description

In order to make the technical solutions of the present invention clearer and clearer for those skilled in the art, the present invention will be described in further detail with reference to the following embodiments and the accompanying drawings, but the embodiments of the present invention are not limited thereto.

As shown in fig. 1 to 3, the present embodiment provides a lenticular optical lens receiving disc including

The double-convex optical lens storage plate 1 and the storage plate auxiliary plate 8 matched with the double-convex optical lens storage plate 1 are used, and in the process of using the double-convex optical lens storage plate 1, the storage plate auxiliary plate 8 can be attached to the bottom of the double-convex optical lens storage plate 1 or can be randomly placed;

the biconvex optical lens storage box 2 is wide at the top and narrow at the bottom, is in a hollow circular truncated cone shape, the biconvex optical lens storage box 2 can be divided into an upper part, a middle part and a lower part, the diameters of the upper part and the middle part of the biconvex optical lens storage box 2 are larger than those of the biconvex optical lens, and the diameter of the lower part of the biconvex optical lens storage box 2 is smaller than that of the biconvex optical lens, so that the biconvex optical lens can smoothly enter the biconvex optical lens storage box 2 and can be clamped into the lower part of the biconvex optical lens storage box 2 without contacting with the bottom of the biconvex optical lens storage box 2, the biconvex optical lens storage box 2 is embedded on the upper surface of the bicon;

the first groove 4 is embedded in the lower surface of the biconvex optical lens storage plate 1, and the first groove 4 is positioned right below the biconvex optical lens storage box 2, so that the first ejector rod 3 is conveniently controlled;

the first ejector rod 3, the first ejector rod 3 penetrates the bottom of the double-convex optical lens storage box 2 and the top of the first groove 4 from top to bottom in sequence, the first ejector rod 3 is used for jacking the double-convex optical lens, the first spring 5, and two ends of the first spring 5 are fixedly connected with the top of the inner side of the first groove 4 and the top side of the first spring support plate 6 respectively; when the first spring 5 is in a natural state, the top end portion of the first push rod 3 is positioned inside the lenticular optical lens housing case 2, but does not touch the lenticular optical lenses inside the lenticular optical lens housing case 2, and the bottom end of the first push rod 3 is fixed with the first spring support plate 6, and in addition, when the first spring 5 is in a natural state, the bottom end surface of the first spring support plate 6 is flush with the bottom side surface of the lenticular optical lens housing case 1;

the third groove 11 is embedded in the lower surface of the storage plate auxiliary plate 8, and the third groove 11 is a large independent groove and is used for storing a second spring support plate 12 and a second ejector rod 14;

the second ejector rod 14, the second ejector rod 14 penetrates the upper surface of the storage plate auxiliary plate 8 and the top of the third groove 11 from top to bottom in sequence, the second ejector rod 14 is used for jacking up the first ejector rod 3; the second spring supporting plate 12, the second spring supporting plate 12 is fixed on the bottom end of the second knockout pin 14; and the second spring 13, the second spring 13 is arranged between the second spring support plate 12 and the top of the inner side of the third groove 11, when the second spring 13 is in a natural state, the bottom surface of the second spring support plate 12 is flush with the bottom surface of the storage plate sub-plate 8, and the top surface of the second ejector rod 14 is flush with the top surface of the storage plate sub-plate 8, so as to ensure the stability of the storage plate sub-plate 8 when placed on a plane, and ensure that the second ejector rod 14 does not affect the first ejector rod 3 when the storage plate sub-plate 8 is attached to the biconvex optical lens storage plate 1.

In the present embodiment, as shown in fig. 1, the lenticular lens accommodating case 2 is provided in a plurality of rectangular arrays on the upper surface of the lenticular lens accommodating plate 1, so as to facilitate the placement of the lenticular lenses.

In this embodiment, as shown in fig. 1, the double-convex optical lens storage box 2 is a circular truncated cone structure with an open top and a hollow cavity, and the side wall of the double-convex optical lens storage box 2 is a rubber curved plate, because the rubber plate has certain elasticity and hardness, and can generate large friction with the edge of the double-convex optical lens, the surface of the double-convex optical lens cannot be damaged, the double-convex optical lens can be fixed, and the double-convex optical lens cannot slide out easily.

In the present embodiment, as shown in fig. 1, the lenticular optical lens housing plate 1 is formed with second grooves 7 on the bottom sides of the left and right ends, and the cross section of the second grooves 7 is inverted "L", which is for facilitating the lifting of the lenticular optical lens housing plate 1.

In the present embodiment, as shown in fig. 2, two first springs 5 are provided and are respectively disposed at both sides of the first lift pin 3, i.e., inside each first recess 4, and two first springs 5 are provided in order that the first lift pin 3 may be vertically lifted up.

In the present embodiment, as shown in fig. 2, the first lift pins 3 penetrate through the bottom of the lenticular optical lens accommodating case 2 at the middle position, so that the lenticular optical lens can be smoothly ejected in order to ensure that the lenticular optical lens can be pushed up to the middle position.

In this embodiment, as shown in fig. 2, a female buckle 10 is further embedded on the lower surface of the lenticular optical lens storage plate 1, a male buckle 9 is fixed on the upper surface of the storage plate sub-plate 8, the male buckle 9 and the female buckle 10 are used in cooperation for attaching the storage plate sub-plate 8 and the lenticular optical lens storage plate 1, the male buckle 9 and the female buckle 10 are inserted into each other, the storage plate sub-plate 8 and the lenticular optical lens storage plate 1 can be fixed, and the lenticular optical lenses on the lenticular optical lens storage plate 1 can be conveniently taken out in batches.

In the present embodiment, as shown in fig. 1, the biconvex optical lens storage case 2 protrudes from the upper surface of the biconvex optical lens storage plate 1, in order to increase the depth of the cavity of the biconvex optical lens storage case 2, so that the biconvex optical lenses are less likely to fall out of the biconvex optical lens storage case 2 inside the biconvex optical lens storage case 2.

In this embodiment, as shown in fig. 2, the first groove 4 and the second pin 14 are both cylindrical structures, and the cross-sectional diameter of the second pin 14 is smaller than that of the first groove 4, so that the second pin 14 can be smoothly inserted into the first groove 4 to jack up the first pin 3.

In the present embodiment, as shown in fig. 1 and 2, the number and positions of the second lift pins 14 and the lenticular optical lens housing case 2 are each in one-to-one correspondence, in order to make it possible to take out the lenticular optical lenses in batch.

As shown in fig. 1 to fig. 3, the usage flow of the biconvex optical lens storage disc provided in this embodiment is as follows:

keep flat the inboard at biconvex optical lens receiver 2 with biconvex optical lens correspondence, and compress tightly biconvex optical lens downwards slightly, make biconvex optical lens receiver 2's lateral wall compress tightly slightly biconvex optical lens's outer edge, after putting a large amount of biconvex optical lenses, only need to shift biconvex optical lens receiver plate 1 can, if need use biconvex optical lens, we can directly upwards press second spring support plate 12, make second ejector pin 14 push up first spring support plate 6, push up first ejector pin 3 by the way, make the top of first ejector pin 3 push up biconvex optical lens, just so can take out biconvex optical lens in batches.

In summary, in this embodiment, the inverted circular truncated cone-shaped lenticular lens accommodating box 2 provided in this embodiment can accommodate and fix the lenticular lens to a certain extent, and the convex surface of the lenticular lens does not contact the bottom of the lenticular lens accommodating box 2, so as to avoid the wear of the convex surface of the lenticular lens, and meanwhile, the accommodating operation of the lenticular lens is simple, a large amount of work is not required, and after a single accommodating disc 2 accommodates a large number of lenticular lenses, the batch of lenticular lenses are also conveniently displaced.

The second push rod 3 and the first push rod 14 provided by this embodiment are used in cooperation, so that the biconvex optical lenses can be taken out in batch, and in addition, the second push rod 3 can be used alone to take out a single biconvex optical lens, so as to adapt to different use environments.

The above description is only a further embodiment of the present invention, but the scope of protection of the present invention is not limited thereto, and any person skilled in the art can replace or change the technical solution and the concept of the present invention within the scope of the present invention.

Claims (9)

1. A biconvex optical lens storage disc, characterized in that: comprises that

A biconvex optical lens storage plate (1) and a storage plate sub-plate (8) used in cooperation with the biconvex optical lens storage plate (1);

the storage box (2) for the biconvex optical lenses is wide at the top and narrow at the bottom, is in a hollow circular truncated cone shape, a plurality of the biconvex optical lens storage boxes (2) are arranged and are embedded on the upper surface of the biconvex optical lens storage plate (1), and the biconvex optical lens storage box (2) is used for placing the biconvex optical lenses;

the first groove (4), the first groove (4) is embedded in the lower surface of the double-convex optical lens containing plate (1), and the first groove (4) is positioned below the double-convex optical lens containing box (2);

the first ejector rod (3), the first ejector rod (3) penetrates through the bottom of the double-convex optical lens storage box (2) and the top of the first groove (4) from top to bottom in sequence, the first ejector rod (3) is used for ejecting the double-convex optical lens, and a first spring support plate (6) is fixed at the bottom end of the first ejector rod (3);

the two ends of the first spring (5) are fixedly connected with the top of the inner side of the first groove (4) and the top side of the first spring supporting plate (6) respectively;

the third groove (11), the third groove (11) is inlaid in the lower surface of the storage plate auxiliary plate (8);

the second ejector rod (14), the second ejector rod (14) penetrates through the upper surface of the storage plate auxiliary plate (8) and the top of the third groove (11) from top to bottom in sequence, and the second ejector rod (14) is used for jacking the first ejector rod (3);

the second spring supporting plate (12), the second spring supporting plate (12) is fixed at the bottom end of the second ejector rod (14);

a second spring (13), the second spring (13) being disposed between the second spring support plate (12) and an inside top of the third groove (11).

2. The lenticular optical lens-receiving disc of claim 1, wherein: the double-convex optical lens storage boxes (2) are rectangular arrays and are arranged on the upper surfaces of the double-convex optical lens storage plates (1), and the second push rods (14) correspond to the double-convex optical lens storage boxes (2) in number and position one to one.

3. The lenticular optical lens-receiving disc of claim 1, wherein: the biconvex optical lens storage box (2) is of a round table structure with an open top and a cavity.

4. The lenticular optical lens-receiving disc of claim 1, wherein: and second grooves (7) are formed in the bottom sides of the left end and the right end of the biconvex optical lens storage plate (1).

5. The lenticular optical lens-receiving disc of claim 1, wherein: the number of the first springs (5) is two, and the first springs are respectively positioned on two sides of the first ejector rod (3).

6. The lenticular optical lens-receiving disc of claim 1, wherein: the first ejector rod (3) penetrates through the middle position of the bottom of the double-convex optical lens storage box (2).

7. The lenticular optical lens-receiving disc of claim 1, wherein: biconvex optical lens accomodates the lower surface of board (1) and still inlays box (10), the last fixed surface of accomodating board subplate (8) has pin thread (9), pin thread (9) with box (10) cooperation is used for the laminating accomodate board subplate (8) with biconvex optical lens accomodates board (1).

8. The lenticular optical lens-receiving disc of claim 1, wherein: the biconvex optical lens storage box (2) protrudes out of the upper surface of the biconvex optical lens storage plate (1), and the side wall of the biconvex optical lens storage box (2) is a rubber curved plate.

9. The lenticular optical lens-receiving disc of claim 1, wherein: the first groove (4) and the second ejector rod (14) are both of cylindrical structures, and the section diameter of the second ejector rod (14) is smaller than that of the first groove (4).

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