CN219564155U - Effectual 3D of shock attenuation prints protective housing - Google Patents

Abstract

The utility model discloses a 3D printing protective housing with a good shock absorption effect, which comprises a 3D printer body, wherein a protective box is arranged at the bottom of the 3D printer body, the 3D printer body is positioned in the protective box, two sides of the protective box are fixedly connected with placing plates, and the rear sides of two sides of the protective box are fixedly connected with connecting plates. According to the utility model, the first air bag is compressed by downward movement of the 3D printer body, the first air bag discharges air into the second air bag through the air outlet pipe, then a user starts the motor, the motor rotates to drive the cam to rotate, the cam rotates to drive the square to move downward, the square moves downward to drive the limiting rod to move downward, the limiting rod moves downward to drive the rectangular plate to move downward, the rectangular plate moves downward to compress the second air bag, and when the second air bag receives the pressure of the rectangular plate, the second air bag discharges the air in the second air bag into the first air bag through the air outlet pipe, so that the advantage of good damping effect of the protective shell of the 3D printer is achieved.

Description

Effectual 3D of shock attenuation prints protective housing

Technical Field

The utility model relates to the technical field of 3D printing protection shells, in particular to a 3D printing protection shell with a good damping effect.

Background

The 3D printer is a process for rapid forming, a three-dimensional model is manufactured in a layering mode, the operation process of the three-dimensional printer is similar to that of a traditional printer, the traditional printer is used for printing ink on paper to form a two-dimensional plane drawing, the 3D printer is used for realizing layering and stacking of materials such as liquid photosensitive resin materials, molten plastic wires, gypsum powder and the like by spraying adhesives or extruding and the like to form a three-dimensional object, the 3D printing is a rapid forming technology, namely additive manufacturing, which is a technology for constructing an object by using a bondable material such as powdery metal or plastic and the like on the basis of a digital model file in a layering printing mode, the 3D printing is usually realized by using a digital technology material printer, and is generally used for manufacturing models in the fields such as mould manufacturing, industrial design and the like, and then the three-dimensional printer is gradually used for directly manufacturing some products, and parts printed by the technology are applied to the fields such as jewelry, footwear, industrial design, construction, engineering and construction, automobiles, aerospace, dental and medical industry, geographical information systems, civil engineering and other fields.

The 3D printer is inside the carriage in the transportation all is directly placed, and the 3D printer stacks owing to all being many, and the transport vechicle can make the inside 3D printer in carriage appear rocking when jolting the highway section, and current 3D printer is protected although having the protecting crust, but under violent rocking, the damage also can appear in 3D printer protecting crust, and 3D printer protecting crust does not possess the absorbing function yet, and the condition that the damage also can appear in 3D printer long-term and protecting crust collision.

Therefore, the 3D printer protecting shell needs to be designed and modified, the existing 3D printer is effectively prevented from being protected although the protecting shell is arranged, the protecting shell of the 3D printer is damaged under severe shaking, the protecting shell of the 3D printer also does not have the function of shock absorption, and the protecting shell of the 3D printer is damaged after long-term collision with the protecting shell.

Disclosure of Invention

In order to solve the problems in the prior art, the utility model aims to provide the 3D printing protective shell with good damping effect, which has the advantage of good damping effect of the protective shell of the 3D printer, and solves the problems that the protective shell of the 3D printer is damaged under severe shaking and the protective shell of the 3D printer does not have the damping function and the 3D printer is damaged after long-term collision with the protective shell.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a effectual 3D of shock attenuation prints protective housing, includes the 3D printer body, the bottom of 3D printer body is provided with the protection box, the 3D printer body is located the inside of protection box, the equal fixedly connected with of both sides of protection box places the board, the equal fixedly connected with connecting plate of rear side of protection box both sides, the bottom of connecting plate and the top fixed connection of placing the board, the inner wall of protection box is provided with damper.

As the preferred utility model, the damping component comprises two first air bags, the bottom of the first air bags and two sides of the bottom of the inner wall of the protection box are fixedly connected, the outer side of the first air bags is communicated with an air outlet pipe, and the outer side of the air outlet pipe penetrates to the outer side of the protection box.

As the preferable mode of the utility model, the bottom of the outer side of the protection box is fixedly connected with the support plate, the top of the support plate is fixedly connected with the second air bag, the top of the air outlet pipe sequentially penetrates through the support plate and the second air bag, the top of the air outlet pipe penetrates into the second air bag, and the second air bag is communicated with the air outlet pipe.

As the preferable one of the utility model, the top of the placing plate is provided with the limit rod, the bottom of the limit rod penetrates to the bottom of the placing plate, the bottom of the limit rod is fixedly connected with the rectangular plate, the bottom of the rectangular plate is contacted with the top of the second air bag, and the limit rod is in sliding connection with the placing plate.

As the preferable mode of the utility model, the back of the connecting plate is fixedly connected with a supporting block, the top of the supporting block is fixedly connected with a motor, the output end of the motor penetrates through the front side of the connecting plate, the output end of the motor is fixedly connected with a cam, and the surface of the cam is contacted with the top of the limiting rod.

As the preferable mode of the utility model, the top of the limiting rod is fixedly connected with a square block, the top of the square block is contacted with the surface of the cam, the surface of the limiting rod is sleeved with a spring, the top of the spring is fixedly connected with the bottom of the square block, and the bottom of the spring is fixedly connected with the top of the placing plate.

As the preferable mode of the utility model, the two sides of the inner wall of the protection box are respectively provided with a moving groove, the two sides of the 3D printer body are respectively fixedly connected with a moving block, the outer sides of the moving blocks extend into the moving grooves, and the moving blocks are in sliding connection with the moving grooves.

Compared with the prior art, the utility model has the following beneficial effects:

1. according to the utility model, the first air bag is compressed by downward movement of the 3D printer body, the first air bag discharges air into the second air bag through the air outlet pipe, then a user starts the motor, the motor rotates to drive the cam to rotate, the cam rotates to drive the square to move downward, the square moves downward to drive the limiting rod to move downward, the limiting rod moves downward to drive the rectangular plate to move downward, the rectangular plate moves downward to compress the second air bag, and when the second air bag receives the pressure of the rectangular plate, the second air bag discharges the air in the second air bag into the first air bag through the air outlet pipe, so that the advantage of good damping effect of the protective shell of the 3D printer is achieved.

2. According to the utility model, through the mutual matching of the first air bag and the air outlet pipe, the 3D printer body can move downwards when being rocked, the 3D printer body moves downwards to compress the first air bag, and the first air bag discharges air to the outer side of the protection box through the air outlet pipe, so that the advantage of shock absorption of the 3D printer body is achieved, and the situation that the 3D printer body is damaged is prevented.

3. According to the utility model, through the mutual matching of the support plate and the second air bag, the 3D printer body can move downwards when being rocked, the 3D printer body moves downwards to compress the first air bag, and the first air bag discharges air into the second air bag through the air outlet pipe, so that the air in the first air bag can be recycled, and the waste of the air in the first air bag is avoided.

4. According to the utility model, through the mutual matching of the limiting rod and the rectangular plate, the rectangular plate can be driven to move downwards when being pressed downwards, the rectangular plate moves downwards to compress the second air bag, the second air bag compresses to enable the air in the second air bag to be discharged into the first air bag through the air outlet pipe, the first air bag is inflated to expand, and the 3D printer body is reset immediately due to the fact that the air in the first air bag expands.

5. According to the utility model, through the mutual matching of the supporting block, the motor and the cam, the cam can be driven to rotate when the motor is started, the cam rotates to drive the limiting rod to move downwards, the limiting rod moves downwards to drive the rectangular plate to move downwards, and the rectangular plate moves downwards to compress the second air bag, so that the problem that the labor force is required to be used for compressing the second air bag is avoided, and the working strength of a user is increased.

Drawings

FIG. 1 is a front view of a structural shield case of the present utility model;

FIG. 2 is a cross-sectional view of the shield can of FIG. 1 according to the present utility model;

fig. 3 is an enlarged view of fig. 2 a in accordance with the present utility model.

In the figure: 1. a 3D printer body; 2. a protective case; 3. placing a plate; 4. a connecting plate; 5. a shock absorbing assembly; 501. a first air bag; 502. an air outlet pipe; 503. a support plate; 504. a second air bag; 505. a limit rod; 506. a rectangular plate; 507. a support block; 508. a motor; 509. a cam; 510. a square block; 511. a spring; 512. a moving groove; 513. and (5) moving the block.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1 to 3, the 3D printing protective housing with good shock absorption effect provided by the utility model comprises a 3D printer body 1, wherein a protection box 2 is arranged at the bottom of the 3D printer body 1, the 3D printer body 1 is positioned in the protection box 2, two sides of the protection box 2 are fixedly connected with a placing plate 3, the rear sides of two sides of the protection box 2 are fixedly connected with a connecting plate 4, the bottom of the connecting plate 4 is fixedly connected with the top of the placing plate 3, and a shock absorption component 5 is arranged on the inner wall of the protection box 2.

Referring to fig. 1 and 2, the shock absorbing assembly 5 includes a first air bag 501, the number of the first air bags 501 is two, both sides of the bottom of the first air bag 501 and the bottom of the inner wall of the protection box 2 are fixedly connected, an air outlet pipe 502 is communicated with the outer side of the first air bag 501, and the outer side of the air outlet pipe 502 penetrates to the outer side of the protection box 2.

As a technical optimization scheme of the utility model, through the mutual matching of the first air bag 501 and the air outlet pipe 502, the 3D printer body 1 can move downwards when being rocked, the 3D printer body 1 moves downwards to compress the first air bag 501, and the first air bag 501 discharges air to the outer side of the protection box 2 through the air outlet pipe 502, so that the advantage of shock absorption of the 3D printer body 1 is achieved, and the situation that the 3D printer body 1 is damaged is prevented.

Referring to fig. 2, the bottom outside the protection box 2 is fixedly connected with a support plate 503, the top of the support plate 503 is fixedly connected with a second air bag 504, the top of an air outlet pipe 502 sequentially penetrates through the support plate 503 and the second air bag 504, the top of the air outlet pipe 502 penetrates into the second air bag 504, and the second air bag 504 is communicated with the air outlet pipe 502.

As a technical optimization scheme of the utility model, through the mutual matching of the support plate 503 and the second air bag 504, the 3D printer body 1 can move downwards when being rocked, the 3D printer body 1 moves downwards to compress the first air bag 501, and the first air bag 501 discharges air into the second air bag 504 through the air outlet pipe 502, so that the air in the first air bag 501 can be recycled, and the air in the first air bag 501 is not wasted.

Referring to fig. 2, the top of the placement plate 3 is provided with a limit rod 505, the bottom of the limit rod 505 penetrates to the bottom of the placement plate 3, the bottom of the limit rod 505 is fixedly connected with a rectangular plate 506, the bottom of the rectangular plate 506 is in contact with the top of the second airbag 504, and the limit rod 505 is in sliding connection with the placement plate 3.

As a technical optimization scheme of the utility model, through the mutual matching of the limiting rod 505 and the rectangular plate 506, the rectangular plate 506 can be driven to move downwards when the limiting rod 505 is pressed downwards, the rectangular plate 506 moves downwards to compress the second air bag 504, the second air bag 504 is compressed to enable the air in the second air bag 504 to be discharged into the first air bag 501 through the air outlet pipe 502, the first air bag 501 is inflated to expand, and the weight of the 3D printer body 1 and the half air of the first air bag 501 are balanced, so that the 3D printer body 1 is reset immediately due to the fact that the air in the first air bag 501 is inflated.

Referring to fig. 3, a supporting block 507 is fixedly connected to the back surface of the connecting plate 4, a motor 508 is fixedly connected to the top of the supporting block 507, the output end of the motor 508 penetrates to the front side of the connecting plate 4, a cam 509 is fixedly connected to the output end of the motor 508, and the surface of the cam 509 is in contact with the top of the limit rod 505.

As a technical optimization scheme of the utility model, through the mutual matching of the supporting blocks 507, the motor 508 and the cam 509, the cam 509 can be driven to rotate when the motor 508 is started, the cam 509 rotates to drive the limiting rod 505 to move downwards, the limiting rod 505 moves downwards to drive the rectangular plate 506 to move downwards, and the rectangular plate 506 moves downwards to compress the second air bag 504, so that the problem that the labor force is needed when the second air bag 504 is compressed is avoided, and the working strength of a user is increased.

Referring to fig. 3, a square 510 is fixedly connected to the top of the limit bar 505, the top of the square 510 is in contact with the surface of the cam 509, a spring 511 is sleeved on the surface of the limit bar 505, the top of the spring 511 is fixedly connected to the bottom of the square 510, and the bottom of the spring 511 is fixedly connected to the top of the placement plate 3.

As a technical optimization scheme of the utility model, through the mutual matching of the block 510 and the spring 511, the square block 510 can always bear the elastic force of the spring 511, so that the limit rod 505 and the rectangular plate 506 are indirectly borne by the elastic force of the spring 511, and when the cam 509 is not contacted with the block 510, the block 510 can upwards move the limit rod 505 and the rectangular plate 506 to restore the state due to the elastic force of the spring 511, and the working strength of a user is reduced.

Referring to fig. 2, moving grooves 512 are formed in both sides of the inner wall of the protection box 2, moving blocks 513 are fixedly connected to both sides of the 3d printer body 1, the outer sides of the moving blocks 513 extend into the moving grooves 512, and the moving blocks 513 are slidably connected with the moving grooves 512.

As a technical optimization scheme of the utility model, the stability of the 3D printer body 1 during up-and-down movement can be improved through the mutual matching of the moving groove 512 and the moving block 513, and the condition that the 3D printer body 1 shakes when moving in the protective box 2 is avoided, so that the 3D printer body 1 is collided with the protective box 2, and the protective box 2 or the 3D printer body 1 is damaged.

The working principle and the using flow of the utility model are as follows: when the three-dimensional printer is used, a user places the 3D printer body 1 inside the protection box 2, when the moving block 513 enters the moving groove 512, then the user places the protection box 2 inside a carriage, when the car is jolt, the 3D printer body 1 moves downwards to compress the first air bag 501, the first air bag 501 discharges air into the second air bag 504 through the air outlet pipe 502, then the user starts the motor 508, the motor 508 rotates to drive the cam 509 to rotate, the cam 509 rotates to drive the block 510 to move downwards, the block 510 moves downwards to drive the limit rod 505 to move downwards, the limit rod 505 moves downwards to drive the rectangular plate 506 to move downwards, the rectangular plate 506 moves downwards to compress the second air bag 504, and when the second air bag 504 is pressed by the rectangular plate 506, the second air bag 504 discharges air in the second air bag to the inside of the first air bag 501 through the air outlet pipe 502, so that the advantage of damping the 3D printer body 1 is achieved.

To sum up: this effectual 3D of shock attenuation prints protective housing, through setting up 3D printer body 1, protection box 2, place the board 3, connecting plate 4, damper 5, first gasbag 501, outlet duct 502, extension board 503, second gasbag 504, gag lever post 505, rectangular plate 506, supporting shoe 507, motor 508, cam 509, square 510, spring 511, remove groove 512 and remove the cooperation of piece 513 and use, the protection shell is protected although having to current 3D printer has been solved, but under violent rocking, the damage also can appear in 3D printer protection shell, and 3D printer protection shell does not possess the absorbing function yet, the problem that damage also can appear in 3D printer long-term and protection shell collision.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. Effectual 3D of shock attenuation prints protective housing, including 3D printer body (1), its characterized in that: the bottom of 3D printer body (1) is provided with protection box (2), 3D printer body (1) is located the inside of protection box (2), equal fixedly connected with in both sides of protection box (2) places board (3), the equal fixedly connected with connecting plate (4) of rear side of protection box (2) both sides, the bottom of connecting plate (4) and the top fixed connection of placing board (3), the inner wall of protection box (2) is provided with damper (5).

2. The effectual 3D print protective housing of claim 1, wherein: the damping component (5) comprises first air bags (501), the number of the first air bags (501) is two, the bottom of the first air bags (501) and the two sides of the bottom of the inner wall of the protection box (2) are fixedly connected, an air outlet pipe (502) is communicated with the outer side of the first air bags (501), and the outer side of the air outlet pipe (502) penetrates through the outer side of the protection box (2).

3. The effectual 3D print protective housing of claim 2, wherein: the bottom in protection box (2) outside is all fixedly connected with extension board (503), the top fixedly connected with second gasbag (504) of extension board (503), extension board (503) and second gasbag (504) are run through in proper order at the top of outlet duct (502), the top of outlet duct (502) runs through to the inside of second gasbag (504), second gasbag (504) and outlet duct (502) intercommunication.

4. The effectual 3D print protective housing of claim 1, wherein: the top of placing board (3) is provided with gag lever post (505), the bottom of gag lever post (505) runs through to the bottom of placing board (3), the bottom fixedly connected with rectangular plate (506) of gag lever post (505), the bottom of rectangular plate (506) and the top contact of second gasbag (504), gag lever post (505) and place board (3) sliding connection.

5. The effectual 3D print protective housing of claim 1, wherein: the back fixedly connected with supporting shoe (507) of connecting plate (4), the top fixedly connected with motor (508) of supporting shoe (507), the output of motor (508) runs through to the front side of connecting plate (4), the output fixedly connected with cam (509) of motor (508), the surface of cam (509) and the top contact of gag lever post (505).

6. The effectual 3D print protective housing of claim 4, wherein: the top fixedly connected with square (510) of gag lever post (505), the top of square (510) and the surface contact of cam (509), the surface cover of gag lever post (505) is equipped with spring (511), the top of spring (511) and the bottom fixed connection of square (510), the bottom of spring (511) and the top fixed connection of placing board (3).

7. The effectual 3D print protective housing of claim 1, wherein: the protection box is characterized in that moving grooves (512) are formed in two sides of the inner wall of the protection box (2), moving blocks (513) are fixedly connected to two sides of the 3D printer body (1), the outer sides of the moving blocks (513) extend to the inner parts of the moving grooves (512), and the moving blocks (513) are in sliding connection with the moving grooves (512).