CN213714402U - A environmental monitoring device for DLP photocuring 3D printer - Google Patents

Abstract

The utility model discloses an environment monitoring device for DLP photocuring 3D printer, including bottom plate, display screen, detector and detection case, the top of bottom plate is installed the elevation structure, the display screen is installed on the top of elevation structure, heat radiation structure is installed to the one end of display screen outer wall, the both sides of the inside top of installation piece all install the fixed orifices, the top of dismantling the structure is installed the detector; the utility model discloses a be provided with the dismantlement structure, when the device is at the in-process that uses, need install the detector on the detection case, at this moment, can be directly with the installation piece card on the dead lever, according to the effect of spring force for the installation piece drives the snubber block and compresses downwards, then rotatory installation piece to 90, makes the dead lever card in the inside of fixed orifices, thereby has realized the fixed effect of installation, and the reverse operation of the same reason, thereby the convenient effect of changing is carried out the detector of different models.

Description

A environmental monitoring device for DLP photocuring 3D printer

Technical Field

The utility model relates to a detection device technical field specifically is an environment monitoring device for DLP photocuring 3D printer.

Background

With the development of the society at present, the living standard of people improves, and the 3D printer appears in people's field of vision gradually, and wherein photocuring 3D printer is one of them most commonly used, and in order to make its product quality of printing better in the 3D printing process, can set up the environmental detection device on the 3D printer, detect the content of dust in the air around the 3D printer, but this kind of device of current still has certain problem and defect.

A detector that is used for environment monitoring device of DLP photocuring 3D printer on the in-process detection device that uses is not convenient for dismantle to it is very inconvenient at the in-process that uses to make, so need make a neotype detection device, with the solution above-mentioned problem.

Disclosure of Invention

An object of the utility model is to provide an environmental monitoring device for DLP photocuring 3D printer to provide the problem of being not convenient for dismantle in solving above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: an environment monitoring device for a DLP photocuring 3D printer comprises a bottom plate, a display screen, a detector and a detection box, wherein a lifting structure is installed at the top end of the bottom plate, the display screen is installed at the top end of the lifting structure, a heat dissipation structure is installed at one end of the outer wall of the display screen, the detection box is installed at the top end of the display screen, a door body is installed at one end of the outer wall of the detection box, a handle is installed at one side of the outer wall of the door body, a top plate is installed at the top end of the detection box, a disassembly structure is installed at one side of the top end of the top plate and comprises a damping block, an installation block, a fixing hole, a fixing rod, a disassembly groove and a spring, the disassembly groove is installed at one side of the top end of the top plate, the spring is installed at the bottom end inside, the utility model discloses a detector, including the structure of dismantling, the installation piece is installed on the top of dead lever, the mounting block is installed on the top of dead lever, the fixed orifices is all installed to the both sides on the inside top of installation piece, dismantle the top of structure and install the detector.

Preferably, the lifting structure comprises a telescopic rod, a plug, a jack and a fixed column, the fixed column is installed at the top end of the bottom plate, the telescopic rod is installed inside the fixed column, the jack penetrates through the inside of the telescopic rod, and the plug penetrates through the inside of the jack.

Preferably, the inner diameter of the insertion hole is larger than the outer diameter of the plug, and a clamping structure is formed between the plug and the insertion hole.

Preferably, the fixed orifices are provided with two groups, and the fixed orifices are distributed annularly at the top end inside the mounting block.

Preferably, the heat radiation structure comprises a heat radiation groove, heat radiation fins and a heat radiation plate, the heat radiation groove is installed at one end of the outer wall of the display screen, the heat radiation plate is installed inside the heat radiation groove, and the heat radiation fins are installed on the outer surface of the heat radiation plate.

Preferably, the plurality of radiating fins are arranged and distributed at equal intervals.

Compared with the prior art, the beneficial effects of the utility model are that: the environment monitoring device for the DLP photocuring 3D printer not only realizes convenient disassembly, but also realizes good lifting effect and convenient heat dissipation;

(1) by arranging the dismounting structure, when the device is used, the detector is required to be installed on the detection box, at the moment, the installation block can be directly clamped on the fixed rod, the installation block drives the damping block to compress downwards under the action of the elastic force of the spring, and then the installation block is rotated to 90 degrees, so that the fixed rod is clamped in the fixed hole, the installation and fixation effects are realized, and the reverse operation is carried out similarly, so that the detectors of different models can be conveniently replaced;

(2) through the lifting structure, in order to enable the detector to detect dust in air with different heights, the plug can be pulled out to be separated from the jack, then the telescopic rod is lifted to a specified position, and the plug is inserted into the jack again to be fixed, so that the lifting effect of the device is facilitated;

(3) through being provided with heat radiation structure, when the data after detecting transmitted to the display screen through the detection case on, the display screen can produce the heat in the work is done, this moment. The display screen can be provided with the radiating groove, and when heat is led out through the radiating plate, the radiating groove is provided with the plurality of radiating fins, so that the contact area with air is increased, and the phenomenon that the display screen is damaged due to long-time use in a high-temperature environment is prevented.

Drawings

Fig. 1 is a schematic front view of a cross-sectional structure of the present invention;

fig. 2 is a schematic rear view of the present invention;

fig. 3 is a schematic view of a front cross-sectional structure of the lifting structure of the present invention;

fig. 4 is a schematic view of the front view section structure of the detachment structure of the present invention.

In the figure: 1. a base plate; 2. a lifting structure; 201. a telescopic rod; 202. plugging; 203. a jack; 204. fixing a column; 3. a display screen; 4. a door body; 5. a handle; 6. a top plate; 7. disassembling the structure; 701. a damper block; 702. mounting blocks; 703. a fixing hole; 704. fixing the rod; 705. disassembling the groove; 706. a spring; 8. a detector; 9. a detection box; 10. a heat dissipation structure; 1001. a heat sink; 1002. heat dissipation fins; 1003. a heat sink.

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. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides an embodiment: the utility model provides an environment monitoring device for DLP photocuring 3D printer, comprising a base plate 1, a display screen 3, detector 8 and detection case 9, elevation structure 2 is installed on the top of bottom plate 1, elevation structure 2 includes telescopic link 201, plug 202, jack 203 and fixed column 204, fixed column 204 is installed on the top of bottom plate 1, telescopic link 201 is installed to the inside of fixed column 204, jack 203 has all been run through to the inside of telescopic link 201, plug 202 has been run through to the inside of jack 203, the internal diameter of jack 203 is greater than the external diameter of plug 202, and constitute the block structure between plug 202 and the jack 203;

specifically, as shown in fig. 1 and 3, when the mechanism is used, firstly, in order to enable the detector 8 to detect dust in air with different heights, the plug 202 can be pulled out, so that the plug 202 is separated from the jack 203, then the telescopic rod 201 is lifted to a specified position, and the plug 202 is inserted into the jack 203 again for fixing, thereby further facilitating the effect of lifting the device;

the display screen 3 is installed at the top end of the lifting structure 2, the heat dissipation structure 10 is installed at one end of the outer wall of the display screen 3, the heat dissipation structure 10 comprises a heat dissipation groove 1001, heat dissipation fins 1002 and a heat dissipation plate 1003, the heat dissipation groove 1001 is installed at one end of the outer wall of the display screen 3, the heat dissipation plates 1003 are installed inside the heat dissipation groove 1001, the heat dissipation fins 1002 are installed on the outer surface of the heat dissipation plate 1003, the heat dissipation fins 1002 are arranged on the heat dissipation fins 1002, and the heat dissipation fins 1002 are distributed at equal intervals;

specifically, as shown in fig. 1 and 2, when this mechanism is used, first, when the detected data is transmitted to the display screen 3 through the detection box 9, the display screen 3 generates heat during operation. The heat dissipation groove 1001 can be arranged on the display screen 3, and when heat is led out through the heat dissipation plate 1003, the heat dissipation groove 1001 is provided with the plurality of heat dissipation fins 1002, so that the contact area with air is increased, and the phenomenon that the display screen 3 is damaged due to long-time use in a high-temperature environment is prevented;

the top end of the display screen 3 is provided with a detection box 9, one end of the outer wall of the detection box 9 is provided with a door body 4, one side of the outer wall of the door body 4 is provided with a handle 5, the top end of the detection box 9 is provided with a top plate 6, one side of the top end of the top plate 6 is provided with a dismounting structure 7, the dismounting structure 7 comprises a shock absorption block 701, an installation block 702, fixing holes 703, fixing rods 704, a dismounting groove 705 and a spring 706, the dismounting groove 705 is installed at one side of the top end of the top plate 6, the spring 706 is installed at the bottom end inside the dismounting groove 705, the shock absorption block 701 is installed at the top end of the spring 706, the fixing rods 704 are installed at the top ends of the shock absorption block 701, the installation block 702 is, the top ends of the fixing holes 703 in the mounting block 702 are distributed annularly, and the top end of the dismounting structure 7 is provided with a detector 8;

specifically, as shown in fig. 1 and 4, when the mechanism is used, firstly, when the device is used, the detector 8 needs to be installed on the detection box 9, at this time, the installation block 702 can be directly clamped on the fixing rod 704, the installation block 702 drives the damping block 701 to compress downwards under the action of the elastic force of the spring 706, then the installation block 702 is rotated to 90 degrees, the fixing rod 704 is clamped inside the fixing hole 703, the effect of installation and fixation is realized, the reverse operation is performed similarly, and the effect of replacing the detectors 8 of different models is facilitated.

The working principle is as follows: the utility model discloses when using, at first, when the device is at the in-process that uses, need install detector 8 on detection case 9, at this moment, can be directly with installation piece 702 card on dead lever 704, according to the effect of spring 706 elasticity, make installation piece 702 drive snubber block 701 downward compression, then rotatory installation piece 702 to 90, make dead lever 704 card in the inside of fixed orifices 703, thereby realized the fixed effect of installation, the same reason reverse operation, thereby the convenient effect of changing is carried out detector 8 to different models.

Afterwards, in order to enable the detector 8 to detect dust in air with different heights, the plug 202 can be pulled out, so that the plug 202 is separated from the jack 203, then the telescopic rod 201 is lifted to a specified position, and the plug 202 is inserted into the jack 203 again for fixing, thereby further facilitating the lifting effect of the device.

Finally, when the detected data are transmitted to the display screen 3 through the detection box 9, the display screen 3 generates heat during working, and at the moment. The heat dissipation groove 1001 can be installed on the display screen 3, and when heat is conducted out through the heat dissipation plate 1003, the heat dissipation groove 1001 is provided with the plurality of heat dissipation fins 1002, so that the contact area with air is increased, and the phenomenon that the display screen 3 is damaged due to long-time use in a high-temperature environment is prevented.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (6)

1. The utility model provides an environment monitoring device for DLP photocuring 3D printer, includes bottom plate (1), display screen (3), detector (8) and detection case (9), its characterized in that: lifting structure (2) is installed on the top of bottom plate (1), display screen (3) is installed on the top of lifting structure (2), heat radiation structure (10) is installed to the one end of display screen (3) outer wall, detection case (9) is installed on the top of display screen (3), the door body (4) is installed to the one end of detection case (9) outer wall, handle (5) is installed to one side of door body (4) outer wall, roof (6) is installed on the top of detection case (9), dismantlement structure (7) is installed to one side of roof (6) top, dismantlement structure (7) includes snubber block (701), installation piece (702), fixed orifices (703), dead lever (704), dismantlement groove (705) and spring (706), dismantlement groove (705) is installed in one side on roof (6) top, spring (706) is installed to the inside bottom of dismantlement groove (705), snubber block (701) are installed on the top of spring (706), dead lever (704) are all installed on the top of snubber block (701), installation piece (702) is installed on the top of dead lever (704), fixed orifices (703) are all installed to the both sides on the inside top of installation piece (702), detector (8) are installed on the top of dismantlement structure (7).

2. The environment monitoring device for the DLP photocuring 3D printer according to claim 1, wherein: the lifting structure (2) comprises a telescopic rod (201), a plug (202), a jack (203) and a fixed column (204), the fixed column (204) is installed at the top end of the bottom plate (1), the telescopic rod (201) is installed inside the fixed column (204), the jack (203) penetrates through the inside of the telescopic rod (201), and the plug (202) penetrates through the inside of the jack (203).

3. The environment monitoring device for the DLP photocuring 3D printer according to claim 2, wherein: the inner diameter of the insertion hole (203) is larger than the outer diameter of the plug (202), and a clamping structure is formed between the plug (202) and the insertion hole (203).

4. The environment monitoring device for the DLP photocuring 3D printer according to claim 1, wherein: two groups of fixing holes (703) are arranged, and the fixing holes (703) are distributed annularly at the top end inside the mounting block (702).

5. The environment monitoring device for the DLP photocuring 3D printer according to claim 1, wherein: the heat dissipation structure (10) comprises a heat dissipation groove (1001), heat dissipation fins (1002) and a heat dissipation plate (1003), wherein the heat dissipation groove (1001) is installed at one end of the outer wall of the display screen (3), the heat dissipation plate (1003) is installed inside the heat dissipation groove (1001), and the heat dissipation fins (1002) are installed on the outer surface of the heat dissipation plate (1003).

6. The environment monitoring device for the DLP photocuring 3D printer of claim 5, wherein: the number of the radiating fins (1002) is equal, and the radiating fins (1002) are distributed at equal intervals.

Images