KR200494386Y1 - 3D printer storage closet - Google Patents

Abstract

The present invention relates to a 3D printer cabinet with a new structure that can prevent the surroundings from being polluted by fine dust and other substances harmful to the human body generated by the 3D printer.
The 3D printer cabinet according to the present invention has a long body (A) capable of accommodating the 3D printer (1) therein, and is connected to the long body (A) to remove dust contained in the air inside the long body (A). It consists of a dust collector (B) that removes dust and removes pollutants contained in the air inside the main body (A). There is an advantage in that this contamination can be prevented.

Description

3D printer storage closet

The present invention relates to a 3D printer cabinet with a new structure that can prevent the surroundings from being polluted by fine dust and other substances harmful to the human body generated by the 3D printer.

In general, a 3D printer is provided with a printer module inside a case, so that a three-dimensional product can be manufactured by repeatedly laminating synthetic resins or other materials as raw materials.

However, these 3D printers have a problem of contaminating the surroundings by discharging fine dust and other substances harmful to the human body during operation.

Therefore, although it is important to separate the space where the 3D printer is installed from the space where people are, there is a problem in that it is not easy to provide such conditions in reality.

In particular, in the case of a place that operates several 3D printers at once, this problem has become more serious.

Therefore, there is a need for a new method to solve these problems.

Public Utility Model No. 20-1999-004258,

The purpose of the present invention is to solve the above problems, and to provide a 3D printer cabinet with a new structure to prevent contamination of the surroundings by fine dust and other substances harmful to the human body generated by the 3D printer. There is this.

The present invention for achieving the above object is connected to the long body (A) and the long body (A) to accommodate the 3D printer (1) therein, or provided on one side of the inside of the long body (A) There is provided a 3D printer cabinet, characterized in that it comprises a dust collector (B) to remove the dust contained in the air inside the main body (A).

According to another feature of the present invention, the long body (A) includes a pedestal 10 and a plurality of storage cases 20 provided inside the pedestal 10 and capable of accommodating the 3D printer 1 therein. ), a plurality of storage cases 20 are configured to be disposed so as to be in close contact with the upper portion of the pedestal 10 in the vertical or lateral direction, and the storage case 20 has a main body 21 having an opening in its front surface. ), and a 3D printer cabinet is provided, which is provided in the opening and comprises a door 22 for opening and closing the opening.

According to another feature of the present invention, an exhaust hole 21c and an air supply hole 21d are formed to be vertically spaced apart from each other on the rear side of the storage case 20, and the storage case 20 is extended in the lateral direction. ) is provided on the rear side of the exhaust pipe 25 and connected to the exhaust hole 21c, and is provided on the rear side of the storage case 20 so as to extend in the lateral direction and is connected to the air supply hole 21d. (26) is further included, wherein the dust collector (B) is connected to the exhaust pipe 25 and the air supply pipe 26 to suck and purify the air inside the storage case 20 through the exhaust pipe 25, and then A 3D printer cabinet is provided, characterized in that it is discharged into the interior of the storage case 20 through the air supply pipe 26 .

According to another feature of the present invention, a 3D printer cabinet is provided, characterized in that a pull-out shelf 23 for placing the 3D printer 1 on the upper surface is provided on the lower inner side of the main body 21 . .

According to another feature of the present invention, an opening/closing detection means 31 provided in the main body 21 of the storage case 20 and sensing that the door 22 is closed, and provided inside the storage case 20 and a printer detection means 32 for detecting the 3D printer 1 accommodated in the storage case 20, and the exhaust hole 21c and the air supply hole 21d provided in the body 21 It further includes an opening/closing damper 34 for opening and closing, and a control unit 50 for receiving a signal from the opening/closing detection unit 31 and controlling the operation of the opening/closing damper 34, wherein the control unit 50 includes the Upon receiving the signal from the opening/closing detection means 31 and the opening/closing damper 34, the door 22 is opened or the storage case 20 in which the 3D printer 1 is not accommodated is detected, the storage case 20 ) by controlling the opening/closing damper 34 provided in the 3D printer cabinet, characterized in that to close the exhaust hole (21c) and the air supply hole (21d) is provided.

According to another feature of the present invention, the storage case 20 is provided on one side of the main body 21 to detect the vibration generated in the 3D printer 1 and transmitted to the storage case 20, the vibration sensor 33 and a vibration damping means 40 provided on the inner upper surface of the storage case 20 and attenuating the vibration of the storage case 20 by generating a vibration of a phase opposite to the vibration sensed by the vibration sensor 33 . ), wherein the vibration damping means 40 is slidable laterally on the guide rail 41 provided to extend laterally on the inner upper surface of the storage case 20, and the guide rail 41 The slide plate 42 coupled to each other, the drive motor 43 coupled to the slide plate 42 so that the drive shaft 43a faces forward, and a bracket provided on the drive shaft 43a of the drive motor 43 A pivot arm 44 rotatably coupled to the vertical direction and having a weight 44a at the distal end thereof, and the drive shaft 43a slide in the front-rear direction so as to be positioned in front of the bracket 43b A slide tube body (45) coupled operably, a link member (46) hinged at both ends to the slide tube body (45) and a pivot arm (44), and rotatably coupled to the outside of the slide tube body (45) The sleeve 47 is provided on the slide plate 42, is connected to the sleeve 47, and is operated and controlled by the control means 50 to position the sleeve 47 and the slide tube body 45 in the forward and backward directions. and a position adjusting mechanism 48 for controlling A 3D printer cabinet is provided, characterized in that the sleeve 47 is slid in the front-rear direction by controlling the position adjusting mechanism 48 to adjust and correspond to the amplitude of the measured vibration.

The 3D printer cabinet according to the present invention has a long body (A) capable of accommodating the 3D printer (1) therein, and is connected to the long body (A) to remove dust contained in the air inside the long body (A). It consists of a dust collector (B) that removes dust and removes pollutants contained in the air inside the main body (A). There is an advantage in that this contamination can be prevented.

1 is a front view showing a 3D printer cabinet according to the present invention;
2 is a front cross-sectional view of a 3D printer cabinet according to the present invention;
3 is a cross-sectional side view of a 3D printer cabinet according to the present invention;
4 is a side cross-sectional view showing a modified example of a 3D printer cabinet according to the present invention;
5 is a side cross-sectional view showing a second embodiment of the 3D printer cabinet according to the present invention;
6 is an enlarged side cross-sectional view of the main part of the second embodiment of the 3D printer cabinet according to the present invention;
7 is a front sectional view showing a second embodiment of the 3D printer cabinet according to the present invention;
8 is a circuit configuration diagram of a second embodiment of a 3D printer cabinet according to the present invention;
9 and 10 are reference views showing the operation of the second embodiment of the 3D printer cabinet according to the present invention.

Hereinafter, the present invention will be described in detail based on the accompanying illustrative drawings.

1 to 3 show a 3D printer storage cabinet according to the present invention, and a long body (A) capable of accommodating the 3D printer (1) therein, and the long body (A) connected to the long body (A) A) It consists of a dust collector (B) that removes dust contained in the air inside.

To explain this in detail, the long body (A) is composed of a pedestal 10 and a plurality of storage cases 20 provided inside the pedestal 10 and capable of accommodating the 3D printer 1 therein. do.

The pedestal 10 is configured in the shape of a box having a flat top surface.

The storage case 20 is composed of a main body 21 having an opening in the front thereof, and a door 22 provided in the opening to open and close the opening.

At this time, the periphery of the opening is provided with a packing in close contact with the rear surface of the door 22, so that when the door 22 is closed, the opening is hermetically sealed.

The door 22 is provided with a hinge on the right side, the right end is coupled to the storage case 20, and the left end has a handle, so that the opening can be opened and closed by pulling or pushing the handle.

In addition, the main body 21 and the door 22 are provided with locking devices to prevent the door 22 from being unintentionally opened in a closed state.

At this time, an exhaust hole 21c and an air supply hole 21d are formed on the rear side of the main body 21 of the storage case 20 to be vertically spaced apart from each other.

In addition, an exhaust pipe 25 and an air supply pipe 26 connected to the exhaust hole 21c and the air supply hole 21d are provided on the rear side of the main body 21 .

The exhaust pipe 25 and the air supply pipe 26 are configured in a tubular shape extending in the lateral direction and are fixed to the rear surface of the main body 21 so as to extend in the lateral direction, and the exhaust hole 21c and A plurality of connecting portions (25a, 26a) connected to the air supply hole (21d) is formed.

The dust collector (B) is provided with a dust collecting filter and a circulation fan therein, is provided on one side of the inner side of the pedestal 10, is connected to the exhaust pipe 25 and the air supply pipe 26, and is operated in FIGS. 2 and FIG. 3, the air inside the storage case 20 is sucked through the exhaust pipe 25, and dust contained in the air is collected and purified using a dust collection filter, and then the air supply pipe ( 26) is configured to be supplied to the inside of the storage case 20 .

Accordingly, a plurality of storage cases 20 are stacked on the upper surface of the pedestal 10 or arranged to be in close contact with each other in the lateral direction, and the exhaust pipe 25 and the air supply pipe 26 are disposed on the rear side of the storage case 20 . ), by connecting the dust collector (B) to the exhaust pipe 25 and the air supply pipe 26, the 3D printer cabinet can be assembled.

The 3D printer cabinet configured as described above has a long body (A) that can accommodate the 3D printer (1) therein, and is connected to the long body (A) to remove dust contained in the air inside the long body (A). It is composed of a dust collector (B) that collects and removes contaminants contained in the air inside the main body (A). It has the advantage of preventing contamination.

And, the long body (A) is composed of a pedestal 10 and a plurality of storage cases 20 provided inside the pedestal 10 and capable of accommodating the 3D printer 1 therein, By stacking a plurality of storage cases 20 on the upper surface of the pedestal 10 in the vertical direction or in close contact with the lateral direction, there is an advantage that can be assembled in various forms.

In particular, the exhaust hole 21c and the air supply hole 21d are formed to be vertically spaced apart from each other on the rear side of the storage case 20, and are provided on the rear side of the storage case 20 so as to extend laterally. An exhaust pipe 25 connected to the exhaust hole 21c, and an air supply pipe 26 provided on the rear side of the storage case 20 so as to extend laterally and connected to the air supply hole 21d are further provided. , the dust collector (B) is connected to the exhaust pipe (25) and the air supply pipe (26) to suck and purify the air inside the storage case (20) through the exhaust pipe (25), and then through the air supply pipe (26) It is configured to discharge into the interior of the storage case (20).

Therefore, there is an advantage that can effectively purify the air inside the storage case 20 .

In this embodiment, the dust collector (B) is illustrated as being provided on one side of the inner side of the pedestal 10, but the dust collector (B) may be separately provided on the outside of the long main body (A).

In addition, although the dust collector (B) is exemplified as being connected to the storage case 20 through the exhaust pipe 25 and the air supply pipe 26 , the dust collector (B) is provided on one inner side of the storage case 20 , respectively. can be

In addition, although the exhaust pipe 25 and the air supply pipe 26 are provided on the rear side of the storage case 20 to extend laterally, the arrangement and shape of the exhaust pipe 25 and the air supply pipe 26 are can be variously changed.

In addition, as shown in FIG. 4 , a pull-out shelf 23 capable of placing the 3D printer 1 on the upper surface of the inner lower side of the main body 21 may be provided.

The pull-out shelf 23 is slidable to the front of the main body 21 by a slide guide. ) can be easily maintained, and the product manufactured by the 3D printer 1 can be easily taken out.

5 to 10 show another embodiment according to the present invention, provided in the storage case 20, the main body 21, the opening and closing detection means 31 for detecting that the door 22 is closed, the A printer detection means 32 provided inside the storage case 20 to detect the 3D printer 1 accommodated in the storage case 20, and provided on one side of the storage case 20 body 21 A vibration sensor 33 for detecting vibration generated by the 3D printer 1 and transmitted to the storage case 20, and provided inside the main body 21, the exhaust hole 21c and the air supply hole 21d ), an opening/closing damper 34 for opening and closing, a vibration damping means 40 provided on the inner upper surface of the storage case 20, the opening/closing detection means 31, a printer detection means 32, and a vibration detection sensor ( 33) and a control means 50 for controlling the operation of the opening/closing damper 34 and the vibration damping means 40 is further provided.

As shown in FIG. 5, the opening/closing detection means 31 is provided to be embedded in the front surface of the case body and uses a push switch equipped with a push button 31a in the front, and when the door 22 is closed, It is configured to detect that the push button 31a is pressed and the door 22 is closed.

The printer detecting means 32 uses an ultrasonic sensor provided on the rear side of the case body to face forward. When the 3D printer 1 is accommodated in the case body, the ultrasonic sensor detects it and signals is configured to output

Such an ultrasonic sensor is designed to detect an object within a preset distance using ultrasonic waves, and various types have been developed and used, and detailed description thereof will be omitted.

The vibration sensor 33 is provided on the bottom surface of the case body and is configured to detect vibrations generated while the 3D printer 1 accommodated in the case body is operated.

As shown in FIG. 7 , the opening/closing damper 34 is a damper plate slidably coupled to the inner rear surface of the case body in the lateral direction so as to be positioned at one side of the exhaust hole 21c and the air supply hole 21d. (34a) and an actuator (34b) connected to the damper plate (34a) and sliding the damper plate (34a) laterally according to a control signal from the control means (50).

The damper plate 34a is located on the right side of the exhaust hole 21c and the air supply hole 21d, and as shown in FIG. 8, when it is slid to the left by the actuator 34b, the exhaust hole 21c It is configured to block the inner end of the supercharged air hole (21d).

The actuator 34b uses a solenoid mechanism operated by an electric signal.

The vibration damping means 40 includes a guide rail 41 provided to extend laterally on the inner upper surface of the storage case 20, and the guide rail 41 as shown in FIGS. 5 to 7 . A slide plate 42 slidably coupled in the lateral direction, a drive motor 43 coupled to the slide plate 42 so that the drive shaft 43a faces forward, and a drive shaft 43a of the drive motor 43 ) is rotatably coupled to the bracket 43b provided in the vertical direction and is provided with a weight 44a at the distal end thereof, and the driving shaft 43a is positioned in front of the bracket 43b. a slide tube body 45 slidably coupled in the front-rear direction, a link member 46 hinged at both ends to the slide tube body 45 and the pivot arm 44, respectively, and the outer side of the slide tube body 45 The sleeve 47 is rotatably coupled to a sleeve 47, is provided on the slide plate 42, is connected to the sleeve 47, and is controlled by the control means 50 to operate the sleeve 47 and the slide tube body 45 ) using the position adjustment mechanism 48 for adjusting the front-back direction position.

The slide tube body 45 is configured to rotate together with the drive shaft 43a when the drive shaft 43a is rotated while being slid on the drive shaft 43a in the longitudinal direction of the drive shaft 43a.

To this end, the driving shaft 43a is configured to have a rectangular cross-sectional shape.

The position adjusting mechanism 48 uses an electric cylinder mechanism that is expanded and contracted by a motor provided therein, and the front end is fixed to the slide tube body 45 and the piston rod 48a extending rearwardly is the sleeve 47 . It is connected to and is configured to adjust the position of the sleeve 47 and the slide tube body 45 in the front-rear direction according to the expansion and contraction.

The operation of the 3D printer cabinet configured in this way will be described as follows.

First, the dust collector (B) is continuously operated, and the exhaust hole (21c), the air supply hole (21d), and the air supply hole (21d) are maintained in an open state, so that the air inside each storage case 20 is After being sucked into the dust collector B through the exhaust hole 21c and the exhaust pipe 25 and purified, it is supplied to the inside of the storage case 20 through the air supply pipe 26 and the air supply hole 21d.

At this time, the control means 50 receives the signal of the open/close detection means 31 and the printer detection means 32, and the door 22 of the storage case 20 on one side is open or the storage case 20 on the one side. ), when it is detected that the 3D printer 1 is not accommodated in the interior, as shown by the arrow in FIG. By sealing the supercharger hole 21d, the air inside the storage case 20 is sucked into the dust collector B, or the air purified by the dust collector B is not supplied to the storage case 20.

That is, in the case of the storage case 20 in which the door 22 is opened, even if the air inside is purified, the outside contaminated air is continuously supplied to the inside of the storage case 20 through the opening.

In addition, in the case of the storage case 20 in which the 3D printer 1 is not accommodated therein, there is no need to purify the air inside.

Accordingly, in the case of the storage case 20 in which it is sensed that the door 22 is opened or that the 3D printer 1 is not accommodated, the control means 50 includes an opening/closing damper 34 provided in the storage case 20 . to seal the exhaust hole 21c and the air supply hole 21d using ), so that the dust collector (B) is focused on purifying the air inside the remaining storage case 20, the efficiency of using the dust collector (B) to purify the air inside the storage case 20 is improved. be able to do

In addition, the control means 50 receives the signal of the vibration detection sensor 33, detects the frequency and amplitude of vibration generated while the 3D printer 1 operates, and controls the vibration damping means 40 to The vibration generated while the 3D printer 1 is operated is reduced.

That is, when vibration is sensed by the vibration sensor 33, the control means 50 drives the drive motor 43 to rotate the weight 44a, as shown in FIG. Vibration is applied to the drive motor 43 and the slide plate 42 .

However, since the slide plate 42 is slidably coupled to the guide rail 41 in the lateral direction, when vibration is generated while the weight 44a is rotated, as shown by solid and dotted lines in FIG. 7 , As the slide plate 42 freely slides in the lateral direction to absorb the lateral component force, only the vertical component force is transmitted to the storage case 20, and the storage case 20 vibrates in the vertical direction. .

At this time, the control means 50 adjusts the number of rotations of the driving motor 43 to correspond to the frequency and the direction of vibration measured by the vibration sensor 33 , and attaches the 3D printer to the storage case 20 . Make sure that the vibration generated in (1) and the opposite phase are applied.

In addition, the control means 50 controls the position adjusting mechanism 48 to adjust the amplitude generated while the weight 44a is rotated.

That is, as shown in FIG. 6 by adjusting the position adjusting mechanism 48, when the sleeve 47 and the slide tube body 45 are pushed backward, the pivot arm 44 is operated by the link member 46. ) is rotated to the outside, the weight 44a is spaced apart from the drive shaft 43a, and the magnitude of the vibration generated by the weight 44a increases, and accordingly, the vibration applied to the storage case 20 will increase in amplitude.

Conversely, as shown in FIG. 10 , when the sleeve 47 and the slide tube body 45 are slid forward, the rotation arm 44 is rotated toward the drive shaft 43a and the vibration generated by the weight 44a and the amplitude of the vibration applied to the storage case 20 are reduced.

In this way, the control means 50 adjusts the amplitude of the vibration generated by the vibration damping means 40 so as to correspond to the amplitude of the vibration measured by the vibration detection sensor 33, thereby generating in the 3D printer 1 . to dampen the vibration.

The 3D printer storage cabinet configured as described above is provided in the main body 21 of the storage case 20 and includes an opening/closing detection means 31 that detects that the door 22 is closed, and is provided in the storage case 20 for storage. A printer detection means 32 for detecting the 3D printer 1 accommodated in the case 20, and provided inside the main body 21 to open and close the exhaust hole 21c and the air supply hole 21d An opening/closing damper 34 and a control unit 50 for receiving a signal from the opening/closing detection unit 31 and controlling the operation of the opening/closing damper 34 are provided, so that the door 22 is opened or the 3D printer ( 1) By controlling the opening/closing damper 34 of the storage case 20 in which it is not accommodated, and sealing the exhaust hole 21c and the air supply hole 21d of the storage case 20, the efficiency of the dust collector B There are advantages to improving

In addition, a vibration sensor 33 provided on one side of the storage case 20 body 21 to detect vibration generated by the 3D printer 1 and transmitted to the storage case 20, and the storage case 20 ) is provided on the inner upper surface of the vibration sensor 33 and generates a vibration of the opposite phase to the vibration detected by the vibration sensor 33 to attenuate the vibration of the storage case 20, the vibration damping means 40 is further provided, When vibration is generated when the 3D printer 1 is operated, the vibration damping means 40 is controlled to cancel the vibration by generating a vibration having the same frequency as the vibration generated in the 3D printer 1 but having a reverse phase. .

Accordingly, there is an advantage in that it is possible to prevent the vibration from being transmitted to the 3D printer 1 provided in the other storage case 20 or from being generated by the vibration.

A. Long body 10. Stand
20. Storage case B. Dust collector

Claims (6)

A long body (A) that can accommodate the 3D printer (1) inside,
and a dust collector (B) connected to the long main body (A) to remove dust contained in the air inside the long main body (A),
The long body (A) is
a pedestal (10) and
It is provided in the interior of the pedestal 10 and includes a plurality of storage cases 20 capable of accommodating the 3D printer 1 therein,
It is configured so that a plurality of storage cases 20 can be disposed so as to be in close contact with the upper portion of the pedestal 10 in the vertical or lateral direction,
The storage case 20 is
A body 21 having an opening formed in the front thereof;
a door 22 provided in the opening to open and close the opening;
An exhaust hole 21c and an air supply hole 21d are formed on the rear side to be spaced apart from each other in the vertical direction,
an opening/closing detecting means 31 provided in the body 21 of the storage case 20 and detecting that the door 22 is closed;
a printer detecting means 32 provided in the storage case 20 to detect the 3D printer 1 accommodated in the storage case 20;
an opening/closing damper 34 provided inside the main body 21 and opening and closing the exhaust hole 21c and the air supply hole 21d;
Further comprising a control means (50) for receiving the signal of the opening/closing detection means (31) and controlling the operation of the opening/closing damper (34),
The control means 50 receives the signals of the opening/closing detection unit 31 and the opening/closing damper 34 so that the door 22 is open or the storage case 20 in which the 3D printer 1 is not accommodated is installed. When it is sensed, it is configured to close the exhaust hole 21c and the air supply hole 21d by controlling the opening/closing damper 34 provided in the corresponding storage case 20,
A vibration sensor 33 provided on one side of the storage case 20 body 21 to detect vibrations generated in the 3D printer 1 and transmitted to the storage case 20;
Vibration damping means 40 provided on the inner upper surface of the storage case 20 and attenuating the vibration of the storage case 20 by generating a vibration of a phase opposite to the vibration sensed by the vibration sensor 33 is provided. including more,
The vibration damping means 40 is
a guide rail 41 provided to extend laterally on the inner upper surface of the storage case 20;
a slide plate 42 slidably coupled to the guide rail 41 laterally;
a driving motor 43 coupled to the slide plate 42 so that the driving shaft 43a faces forward;
A rotating arm 44 rotatably coupled to the bracket 43b provided on the drive shaft 43a of the drive motor 43 in the vertical direction and provided with a weight 44a at the distal end thereof;
a slide tube body 45 slidably coupled to the drive shaft 43a in the front-rear direction so as to be positioned in front of the bracket 43b;
a link member 46 having both ends hinged to the slide tube body 45 and the pivot arm 44, respectively;
a sleeve 47 rotatably coupled to the outside of the slide tube body 45;
A positioning mechanism provided on the slide plate 42, connected to the sleeve 47, and controlled by the control means 50 to adjust the front and rear positions of the sleeve 47 and the slide tube body 45 ( 48);
The control means 50 receives the signal from the vibration sensor 33, adjusts the driving speed of the drive motor 43 to correspond to the frequency of the measured vibration, and adjusts the driving speed of the drive motor 43 to correspond to the measured amplitude of the vibration. 3D printer cabinet, characterized in that by controlling the adjustment mechanism (48) to slide the sleeve (47) in the front and rear direction.
delete The method of claim 1,
an exhaust pipe 25 provided on the rear side of the storage case 20 so as to extend laterally and connected to the exhaust hole 21c;
It is provided on the rear side of the storage case 20 so as to extend in the lateral direction and further includes an air supply pipe 26 connected to the air supply hole 21d,
The dust collector (B) is connected to the exhaust pipe (25) and the air supply pipe (26), sucks air inside the storage case (20) through the exhaust pipe (25) to purify it, and then receives it through the air supply pipe (26). 3D printer cabinet, characterized in that it is discharged to the inside of the case (20).
According to claim 1,
3D printer cabinet, characterized in that the drawer-type shelf (23) for placing the 3D printer (1) on the upper surface of the inner lower side of the main body (21) is provided.
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