CN209775561U - Micro-nano biomedical 3D printing apparatus with objective table - Google Patents

Abstract

The utility model belongs to the field of 3D printing, in particular to a micro-nano biomedical 3D printing device with an object stage, aiming at the problems that the existing micro-nano biomedical 3D printing device has poor damping performance, can generate vibration with larger amplitude during the operation process, and can affect the service life of internal parts due to long-term large-amplitude vibration, the utility model provides a proposal which comprises a base, two symmetrical fixed blocks are welded at the top of the base, a horizontally arranged first mounting seat is connected on the top wall of the base in a sliding way, the two fixed blocks are respectively positioned at the two sides of the first mounting seat, a first spring is respectively connected with the two fixed blocks and the first mounting seat, a limiting hole is arranged on the first mounting seat, a horizontally arranged limiting rod is movably sleeved in the limiting hole, the limiting rod penetrates through the first mounting seat, fixed plates which are vertically arranged are welded at the two ends of the limiting rod, and the two fixed plates are both connected with the first mounting seat, the utility model discloses the damping performance is good, and life is longer.

Description

Micro-nano biomedical 3D printing apparatus with objective table

Technical Field

The utility model relates to a 3D prints technical field, especially relates to a micro-nano biomedical 3D printing apparatus with objective table.

background

3D printing is typically achieved using digital technology material printers. Often be used for making the model in fields such as mould manufacturing, industrial design, be used for the direct manufacturing of some products gradually afterwards, have used the spare part that this kind of technique printed, often can use 3D printing apparatus in the micro-nano biomedicine, for the place of convenient mould, generally can install the objective table on 3D printing apparatus.

The existing micro-nano biomedical 3D printing equipment is generally directly placed on the ground, the damping performance is poor, the micro-nano biomedical 3D printing equipment can generate vibration of a large amplitude in the operation process, the long-term vibration of the large amplitude can influence the service life of internal parts, and therefore the micro-nano biomedical 3D printing equipment with the object stage is provided.

SUMMERY OF THE UTILITY MODEL

The utility model provides a pair of micro-nano biomedical 3D printing apparatus with objective table has solved the general directness of current micro-nano biomedical 3D printing apparatus and has placed subaerially, and the damping performance is relatively poor, and micro-nano biomedical 3D printing apparatus can produce vibrations by a relatively large margin at the operation in-process, and long-term vibrations by a wide margin can influence the life's of internals problem.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

A micro-nano biomedical 3D printing device with an object stage comprises a base, wherein two symmetrical fixed blocks are welded at the top of the base, a horizontally arranged first mounting seat is connected to the top wall of the base in a sliding manner, the two fixed blocks are respectively positioned at two sides of the first mounting seat, a first spring is connected with the two fixed blocks and the first mounting seat, a limiting hole is formed in the first mounting seat, a horizontally arranged limiting rod is movably sleeved in the limiting hole and penetrates through the first mounting seat, two vertically arranged fixed plates are welded at two ends of the limiting rod, a second spring is connected with the first mounting seat and sleeved on the outer ring of the limiting rod, a horizontally arranged second mounting seat is welded at the top ends of the two fixed plates, the second mounting seat is positioned at the top end of the first mounting seat, a rectangular box body is installed right above the second mounting seat, the shock tube that all welds the perpendicular setting on the lateral wall of two symmetries of box, the shock tube's inner circle activity has cup jointed the shock absorber post of perpendicular setting, the top welding of shock tube has the backup pad, be connected with the third spring between shock absorber post and the backup pad, the inner circle at the shock tube is established to the third spring housing, the bottom of shock absorber post extends to the below of box and welds on the roof of second mount pad.

Preferably, install the printing apparatus main part on the interior roof of box, the welding has two output electric putter up of symmetry on the interior diapire of box, two electric putter's output welding has the objective table that the level set up, the printing apparatus main part is located the objective table directly over.

Preferably, the limiting rod is perpendicular to the first mounting seat.

Preferably, a sliding groove is formed in the top wall of the base, two sliding blocks are arranged in the sliding groove in a sliding mode, the sliding groove extends out of the top end of each sliding block, and the first mounting seat is welded to the top ends of the two sliding blocks.

Preferably, the shape of the limiting hole on the first mounting seat is matched with the shape of the limiting rod.

Compared with the prior art, the method has the beneficial effects that:

The utility model discloses in, through the mating reaction of first spring, second spring, third spring, first mount pad, second mount pad, fixed block, fixed plate, shock attenuation post, shock attenuation pipe and backup pad, can produce vibrations to micro-nano biomedical 3D printing apparatus at the operation in-process and cushion to reduce the range of vibrations, prevent that micro-nano biomedical 3D printing apparatus's internals from damaging because of long-term vibrations by a wide margin.

The utility model discloses the damping performance is good, and life is longer.

Drawings

Fig. 1 is a schematic structural diagram of a micro-nano biomedical 3D printing apparatus with an object stage according to the present invention;

Fig. 2 is the utility model provides a micro-nano biomedical 3D printing apparatus's with objective table side view of first mount pad.

reference numbers in the figures: 1. the printing device comprises a base, a sliding groove 2, a first mounting seat 3, a fixing plate 4, a sliding block 5, a first spring 6, a fixing block 7, a second mounting seat 8, a damping column 9, a damping tube 10, a second spring 11, a supporting plate 12, a printing device main body 13, an objective table 14, an electric push rod 15, a limiting rod 16, a third spring 17 and a box 18.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

In the embodiment, referring to fig. 1-2, a micro-nano biomedical 3D printing device with an object stage comprises a base 1, wherein two symmetrical fixing blocks 7 are welded at the top of the base 1, a horizontally arranged first mounting seat 3 is slidably connected on the top wall of the base 1, the two fixing blocks 7 are respectively positioned at two sides of the first mounting seat 3, the two fixing blocks 7 are respectively connected with the first mounting seat 3 through a first spring 6, a limiting hole is formed in the first mounting seat 3, a horizontally arranged limiting rod 16 is movably sleeved in the limiting hole, the limiting rod 16 penetrates through the first mounting seat 3, two vertically arranged fixing plates 4 are welded at two ends of the limiting rod 16, a second spring 11 is connected with the first mounting seat 3 through the two fixing plates 4, the second spring 11 is sleeved on the outer ring of the limiting rod 16, a horizontally arranged second mounting seat 8 is welded at the top ends of the two fixing plates 4, second mount pad 8 is located the top of first mount pad 3, install the box 18 of rectangle directly over second mount pad 8, all weld on the lateral wall of two symmetries of box 18 has shock tube 10 of perpendicular setting, shock tube 10's inner circle activity has cup jointed the shock absorber post 9 of perpendicular setting, shock tube 10's top welding has backup pad 12, be connected with third spring 17 between shock absorber post 9 and the backup pad 12, the inner circle at shock tube 10 is established to third spring 17 cover, shock absorber post 9's bottom extends to box 18's below and welds on the roof of second mount pad 8.

Install printing apparatus main part 13 on the interior roof of box 18, the welding has two output electric putter 15 up of symmetry on the interior diapire of box 18, the objective table 14 that the output welding of two electric putter 15 has the level to set up, printing apparatus main part 13 is located objective table 14 directly over, the first mount pad 3 of gag lever post 16 perpendicular to, spout 2 has been seted up on base 1's the roof, it is provided with two sliders 5 to slide in spout 2, spout 2 extends on slider 5's top, the welding of first mount pad 3 is on two sliders 5's top, the shape in the spacing hole on first mount pad 3 and gag lever post 16's shape looks adaptation.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and to simplify the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

The working principle is as follows: the two ends of the first spring 6 are respectively welded on the mutually close side walls of the fixed block 7 and the first mounting seat 3, the two ends of the second spring 11 are respectively welded on the mutually close side walls of the fixed plate 4 and the first mounting seat 3, the top end of the third spring 17 is welded on the bottom wall of the supporting plate 12, the bottom end of the third spring 17 is welded on the top end of the shock absorption column 9, the bottom of the printing equipment main body 13 is provided with a spray head, when the printing equipment main body 13 runs, vibration with larger amplitude can be generated, the first mounting seat 3 can drive the printing equipment main body 13 to horizontally displace along the sliding chute 2 through the elastic potential energy action of the first spring 6, the second mounting seat 8 can drive the printing equipment main body 13 to horizontally displace along the length direction of the limiting rod 16 through the elastic potential energy action of the second spring 11, the vibration of the printing equipment main body 13 in the horizontal direction can be buffered, so as to reduce the amplitude of, through the elastic potential energy effect of third spring 17, can make box 18 drive printing apparatus main part 13 displacement from top to bottom, can cushion printing apparatus main part 13 vertical direction's vibrations to reduce the range of vertical direction's vibrations, through reducing the range of printing apparatus main part 13 vibrations, can prevent that its inside part from damaging because of long-term vibrations by a wide margin, the utility model discloses the damping performance is good, and life is longer.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (5)

1. The micro-nano biomedical 3D printing equipment with the object stage comprises a base (1) and is characterized in that two symmetrical fixed blocks (7) are welded at the top of the base (1), a first mounting seat (3) horizontally arranged is connected on the top wall of the base (1) in a sliding mode, the two fixed blocks (7) are respectively located on two sides of the first mounting seat (3), the two fixed blocks (7) are both connected with the first mounting seat (3) through first springs (6), a limiting hole is formed in the first mounting seat (3), a limiting rod (16) horizontally arranged is movably sleeved in the limiting hole, the limiting rod (16) penetrates through the first mounting seat (3), fixing plates (4) vertically arranged are welded at two ends of the limiting rod (16), and a second spring (11) is connected between each fixing plate (4) and the first mounting seat (3), the second spring (11) is sleeved on the outer ring of the limiting rod (16), the top ends of the two fixing plates (4) are welded with a second mounting seat (8) which is horizontally arranged, the second mounting seat (8) is positioned at the top end of the first mounting seat (3), a rectangular box body (18) is arranged right above the second mounting seat (8), two symmetrical outer side walls of the box body (18) are respectively welded with a damping tube (10) which is vertically arranged, the inner ring of the damping tube (10) is movably sleeved with a damping column (9) which is vertically arranged, a supporting plate (12) is welded at the top end of the damping tube (10), a third spring (17) is connected between the damping column (9) and the supporting plate (12), the third spring (17) is sleeved on the inner ring of the damping tube (10), the bottom end of the shock absorption column (9) extends to the lower part of the box body (18) and is welded on the top wall of the second mounting seat (8).

2. The micro-nano biomedical 3D printing device with the object stage according to claim 1, wherein a printing device main body (13) is installed on an inner top wall of the box body (18), two symmetrical electric push rods (15) with upward output ends are welded on an inner bottom wall of the box body (18), the object stage (14) horizontally arranged is welded on output ends of the two electric push rods (15), and the printing device main body (13) is located right above the object stage (14).

3. The micro-nano biomedical 3D printing apparatus with an object stage according to claim 1, wherein the limiting rod (16) is perpendicular to the first mounting seat (3).

4. The micro-nano biomedical 3D printing equipment with an object stage according to claim 1, wherein a sliding groove (2) is formed in the top wall of the base (1), two sliding blocks (5) are arranged in the sliding groove (2) in a sliding manner, the sliding groove (2) extends out of the top end of each sliding block (5), and the first mounting seat (3) is welded to the top ends of the two sliding blocks (5).

5. The micro-nano biomedical 3D printing equipment with an object stage according to claim 1, wherein the shape of the limiting hole on the first mounting seat (3) is matched with the shape of the limiting rod (16).