CN210652470U - Totally-enclosed small-sized desktop type engraving machine - Google Patents

Abstract

The utility model discloses a totally-enclosed small-sized desktop type engraving machine, which comprises a box body, a bench vice, an engraving motor, a transmission mechanism arranged in the box body and an operation panel arranged on the outer surface of the box body; the transmission mechanism comprises an X-axis translation mechanism, a Y-axis translation mechanism and a Z-axis translation mechanism, the X-axis translation mechanism, the Y-axis translation mechanism and the Z-axis translation mechanism are respectively connected in the box body in a sliding manner along an X axis, a Y axis and a Z axis in a three-dimensional coordinate system, and the Y-axis translation mechanism is in transmission connection with the Z-axis translation mechanism; the engraving motor is arranged on the Y-axis translation mechanism and moves in a Y-Z plane through the compound motion of the Z-axis translation mechanism and the Y-axis translation mechanism; the bench vice is arranged on the X-axis translation mechanism, and the bench vice moves along the X axis through the movement of the X-axis translation mechanism; the lateral wall of box is equipped with the door frame and the door frame is equipped with the isolation door that can open to the side. The utility model discloses strengthened the centralized processing to dust and piece, be favorable to the popularization of engraver.

Description

Totally-enclosed small-sized desktop type engraving machine

Technical Field

The utility model relates to an engraver technical field, concretely relates to totally closed small-size desktop formula engraver.

Background

The conventional numerical control engraving machine mainly comprises 4 basic parts, namely an engraving machine tool, an electric control cabinet, a control computer and engraving control software. The working principle is that the design and typesetting are carried out by the special engraving software arranged in the computer, the information of the design and the typesetting is transmitted to the engraving machine controller by the computer, and then the controller converts the information into pulse signals which can drive a stepping motor or a servo motor, and the three-axis engraving feed positioning of X, Y, Z on the engraving machine main body is controlled. Meanwhile, the controller starts the frequency converter to drive the engraving head of the spindle motor to rotate at a high speed, and the processing material fixed on the worktable of the host machine is cut, drilled and milled, so that various planar or three-dimensional embossed patterns and characters designed in the computer can be engraved, the engraving automation operation is realized, and different special configuration cutters can be matched according to different processing materials and process requirements.

Although the use of the numerical control engraving machine is very widespread, many engraving enthusiasts do not purchase the engraving machine as a household appliance because the conventional engraving machine has an open structure and generates a large amount of dust and debris during processing. The defects of the existing numerical control engraving machine are overcome.

SUMMERY OF THE UTILITY MODEL

To the defect among the prior art, the utility model provides a totally closed small-size desktop formula engraver to strengthen the centralized processing to dust and piece, be favorable to the popularization of engraver.

The utility model provides a totally enclosed small-sized desktop type engraving machine, which comprises a box body, a bench vice, an engraving motor, a transmission mechanism arranged in the box body and an operation panel arranged on the outer surface of the box body;

the transmission mechanism comprises an X-axis translation mechanism, a Y-axis translation mechanism and a Z-axis translation mechanism, the X-axis translation mechanism, the Y-axis translation mechanism and the Z-axis translation mechanism are respectively connected in the box body in a sliding manner along an X axis, a Y axis and a Z axis in a three-dimensional coordinate system, and the Y-axis translation mechanism is in transmission connection with the Z-axis translation mechanism; the engraving motor is arranged on the Y-axis translation mechanism and moves in a Y-Z plane through the compound motion of the Z-axis translation mechanism and the Y-axis translation mechanism; the bench vice is arranged on the X-axis translation mechanism, and the bench vice moves along the X axis through the movement of the X-axis translation mechanism;

the lateral wall of box is equipped with the door frame and the door frame is equipped with the isolation door that can open to the side.

The beneficial effects of the utility model are embodied in:

and fixing the workpiece to be processed through the bench vice, and closing the isolation door to perform engraving. Because the box has formed sealed process chamber, dust and piece that the course of working produced all can be intercepted in the box, have avoided the dust to fly upward in the air and pollute surrounding air. After the carving is finished, the isolating door is opened, and the workpiece to be machined is taken out and then the dust and the scraps in the box body are processed in a centralized mode. The equipment does not fly dust in the using process, can be used indoors, and meets the use requirements of carving enthusiasts or individuals.

Preferably, the isolation door is connected with the door frame in a swinging mode through a hinge.

Preferably, a 24V dc power transformer, a controller and a motor driver are arranged inside the base of the box body, and the controller is electrically connected with the 24V dc power transformer and the motor driver respectively.

Preferably, the operation panel is provided with a power switch, a carving starting button, a carving speed regulating knob, a power indicator, an electronic display screen, a data interface, a forward/backward knob, an X-axis selecting button, a Y-axis selecting button and a Z-axis selecting button which are electrically connected with the controller.

The specific model of controller chooses for use PCL6045B, and the motor drive chooses for use DM542, and the motor drive is used for enlargeing the digital signal for the signal of drive step motor to control X axle translation mechanism, Y axle translation mechanism and Z axle translation mechanism and carry out the action according to the procedure requirement. And the electronic display screen is used for displaying the processing information.

Preferably, the X-axis translation mechanism includes an X-lead screw, an X-step motor, an X-guide rod and an X-slider, the X-lead screw and the X-guide rod are parallel, the X-lead screw is rotatably mounted in the box body along the X-axis, the X-guide rod is fixedly mounted in the box body along the X-axis, the X-step motor is in transmission connection with the X-lead screw, the X-slider is sleeved on the X-lead screw and the X-guide rod, the X-slider is rotatably connected with the X-lead screw and slidably connected with the X-slider, and the X-slider is further driven to translate along the X-axis by the rotation of the.

Preferably, the bench vice is fixedly mounted on the X slider.

The X stepping motor is electrically connected with the controller, and the controller controls the positive and negative rotation of the X stepping motor, so that the specific position of the bench vice is controlled.

Preferably, the Z-axis translation mechanism comprises a Z lead screw, a Z stepping motor, a Z guide rod and a Z slider, the Z lead screw and the Z guide rod are parallel, the Z lead screw is rotatably mounted in the box body along the Z axis, the Z guide rod is fixedly mounted in the box body along the Z axis, the Z stepping motor is in transmission connection with the Z lead screw, the Z slider is sleeved on the Z lead screw and the Z guide rod, the Z slider is rotatably connected with the Z lead screw and slidably connected with the Z slider, and the Z slider is rotated by the Z stepping motor to be driven to translate along the Z axis.

Preferably, the Y-axis translation mechanism comprises a Y-lead screw, a Y-stepping motor, a Y-guide rod and a Y-slide block; the Y lead screw is parallel to the Y guide rod, the Y lead screw is rotatably mounted on the Z sliding block along a Y axis, the Y guide rod is fixedly mounted on the Z sliding block along the Y axis, the Y stepping motor is in transmission connection with the Y lead screw, the Y sliding block is sleeved on the Y lead screw and the Y guide rod, the Y sliding block is rotatably connected with the Y lead screw and is in sliding connection with the Y guide rod, and the Y sliding block is driven to translate along the Y axis through the rotation of the Y stepping motor.

Preferably, the engraving motor is fixedly installed at the Y slider with a cutter of the engraving motor facing downward.

The Z stepping motor is electrically connected with the controller, and the controller controls the Z stepping motor to rotate forwards and backwards so as to control the Y-axis translation mechanism to move along the Y axis. The Y stepping motor is electrically connected with the controller, and the controller controls the positive and negative rotation of the Y stepping motor, so that the translation mechanism of the carving motor shaft is controlled to move along the Y axis.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the technical solutions in the prior art will be briefly described below. Throughout the drawings, like elements or portions are generally identified by like reference numerals. In the drawings, elements or portions are not necessarily drawn to scale.

FIG. 1 is a schematic structural diagram of the present embodiment;

fig. 2 is a left side view of fig. 1.

In the drawing, a box body 1, a bench vice 2, a carving motor 3, an operation panel 4, a door frame 5, an isolation door 6, a hinge 7, a base 8, a 24V direct-current power transformer 9, a controller 10, a motor driver 11, a power switch 12, a carving starting button 13, a carving speed regulating knob 14, a power indicator lamp 15, an electronic display screen 16, a data interface 17, a screwing in/out button 18, an X-axis selecting button 19, a Y-axis selecting button 20, a Z-axis selecting button 21, an X-lead screw 22, an X-step motor 23, an X-guide rod 24, an X-slide block 25, a Y-lead screw 26, a Y-step motor 27, a Y-guide rod 28, a Y-slide block 29, a Z-lead screw 30, a Z-step motor 31, a Z-guide rod 32, a Z-slide block 33 and a.

Detailed Description

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings. The following examples are only for illustrating the technical solutions of the present invention more clearly, and therefore are only examples, and the protection scope of the present invention is not limited thereby.

It is to be noted that unless otherwise specified, technical or scientific terms used herein shall have the ordinary meaning as understood by those skilled in the art to which the present invention belongs.

As shown in fig. 1, the present embodiment provides a fully enclosed small table top type carving machine, which comprises a box body 1, a bench vice 2, a carving motor 3, a transmission mechanism installed inside the box body 1, and an operation panel 4 installed on the outer surface of the box body 1. Specifically, the box body 1 is provided with a base 8, and the operation panel 4 is installed on the front surface of the base 8. And the side wall of the box body 1 is provided with a door frame 5, and the door frame 5 is provided with an isolation door 6 capable of being opened laterally, specifically, the isolation door 6 is connected with the door frame 5 in a swinging mode through a hinge 7. The hinge 7 is connected between the isolation door 6 and the door frame 5, and facilitates the opening and closing of the isolation door 6.

And putting the workpiece to be processed into the box body 1, and closing the isolating door 6 to perform carving processing. Because box 1 has formed sealed process chamber, dust and piece that produce in the course of working all can be intercepted in box 1, have avoided the dust to fly upward in the air and pollute the surrounding air. After the carving is finished, the isolation door 6 is opened, and the workpiece to be machined is taken out and then the dust and the scraps in the box body 1 are processed in a centralized mode. The equipment does not fly dust in the using process, can be used indoors, and meets the use requirements of carving enthusiasts or individuals.

As shown in fig. 1 and 2, the transmission mechanism in the present embodiment includes an X-axis translation mechanism, a Y-axis translation mechanism, and a Z-axis translation mechanism, the X-axis translation mechanism, the Y-axis translation mechanism, and the Z-axis translation mechanism are respectively connected in the box 1 in a sliding manner along the X-axis, the Y-axis, and the Z-axis in the three-dimensional coordinate system, and the Y-axis translation mechanism is in transmission connection with the Z-axis translation mechanism; the engraving motor 3 is arranged on the Y-axis translation mechanism, and the engraving motor 3 moves in a Y-Z plane through the compound motion of the Z-axis translation mechanism and the Y-axis translation mechanism; the bench vice 2 is arranged on an X-axis translation mechanism, and the bench vice 2 moves along the X axis through the movement of the X-axis translation mechanism.

The X-axis translation mechanism has the following specific structure:

the X-axis translation mechanism comprises an X lead screw 22, an X stepping motor 23, an X guide rod 24 and an X slide block 25, the X lead screw 22 is parallel to the X guide rod 24, the X lead screw 22 is rotatably installed in the box body 1 along the X axis, the X guide rod 24 is fixedly installed in the box body 1 along the X axis, the X stepping motor 23 is in transmission connection with the X lead screw 22, the X slide block 25 is sleeved on the X lead screw 22 and the X guide rod 24, the X slide block 25 is rotatably connected with the X lead screw 22, the X slide block 25 is in sliding connection with the X guide rod 24, and the X slide block 25 is driven to translate along the X axis by the rotation of the X stepping motor 23. The bench vice 2 is fixedly mounted on the X slider 25.

The Z-axis translation mechanism has the following specific structure:

the Z-axis translation mechanism comprises a Z lead screw 30, a Z stepping motor 31, a Z guide rod 32 and a Z slider 33, the Z lead screw 30 is parallel to the Z guide rod 32, the Z lead screw 30 is rotatably installed in the box body 1 along the Z axis, the Z guide rod 32 is fixedly installed in the box body 1 along the Z axis, the Z stepping motor 31 is in transmission connection with the Z lead screw 30, the Z slider 33 is sleeved on the Z lead screw 30 and the Z guide rod 32, the Z slider 33 is rotatably connected with the Z lead screw 30 and slidably connected with the Z guide rod 32, and the Z slider 33 is driven to translate along the Z axis by the rotation of the Z stepping motor 31.

The specific structure of the Y-axis translation mechanism is as follows:

the Y-axis translation mechanism comprises a Y-lead screw 26, a Y-stepping motor 27, a Y-guide rod 28 and a Y-slide block 29; the Y-shaped screw 26 is parallel to the Y-shaped guide rod 28, the Y-shaped screw 26 is rotatably mounted on the Z-shaped slide block 33 along the Y axis, the Y-shaped guide rod 28 is fixedly mounted on the Z-shaped slide block 33 along the Y axis, the Y-shaped stepping motor 27 is in transmission connection with the Y-shaped screw 26, the Y-shaped slide block 29 is sleeved on the Y-shaped screw 26 and the Y-shaped guide rod 28, the Y-shaped slide block 29 is rotatably connected with the Y-shaped screw 26 and the Y-shaped slide block 29 is in sliding connection with the Y-shaped guide rod 28, and the Y-shaped slide block 29 is driven to. The engraving motor 3 is fixedly mounted to the Y slider 29 and the cutter of the engraving motor 3 faces downward.

In this embodiment, a 24V dc power transformer 9, a controller 10 and a motor driver 11 are disposed inside the base 8 of the box 1, and the controller 10 is electrically connected to the 24V dc power transformer 9 and the motor driver 11, respectively. And the motor driver 11 is electrically connected to the engraving motor 3, the X stepping motor 23, the Y stepping motor 27 and the Z stepping motor 31, respectively. Wherein the engraving motor 3 is also a stepping motor. The base 8 is provided with a 220V power interface 34 electrically connected with a 24V DC power transformer 9. The operation panel 4 is provided with a power switch 12, an engraving start button 13, an engraving speed regulation knob 14, a power indicator lamp 15, an electronic display screen 16, a data interface 17, a forward/backward rotation button 18, an X-axis selection button 19, a Y-axis selection button 20 and a Z-axis selection button 21 which are electrically connected with the controller 10.

The specific model of the controller 10 selects PCL6045B, the motor driver 11 selects DM542, and the motor driver 11 is configured to amplify a digital signal into a signal for driving the stepping motor, so as to control the X-axis translation mechanism, the Y-axis translation mechanism, and the Z-axis translation mechanism to act according to a program requirement. While the electronic display 16 is used to display process information. The working flow of the equipment is as follows:

s1: and fixing the workpiece to be processed on the bench vice 2, locking and closing the isolation door 6.

S2: the X-axis selection button 19, the Y-axis selection button 20, and the Z-axis selection button 21 are pressed, and the advance/retreat rotation button 18 is rotated, respectively, so that the workpiece to be machined is located in the machining region. The machining area is the middle area of the base 8, which is beneficial for the workpiece to be machined to move in an X-Y plane.

S3: the engraving speed knob 14 is rotated to select the optimum rotation speed. The rotation speed is selected according to the material of the workpiece to be processed. Then, the engraving start button 13 is pressed, and the engraving motor 3 and the transmission mechanism work under the instruction of the controller 10 to complete the engraving of the workpiece to be processed.

S4: the isolation door 6 is opened, the workpiece to be processed is taken out, and a dust collector or other dust removing equipment is used for cleaning dust and debris in the box body 1.

Wherein the signal in S3 is passed as follows: the data interface 17 receives the processing program information from the computer software, processes the signal into a digital signal through the controller 10, and then the stepping motor driver 11 amplifies the digital signal into a signal for driving the stepping motor, thereby controlling the engraving motor 3 and the transmission mechanism to act according to the program requirement, and simultaneously the electronic display screen 16 displays the processing information.

The cutter of the engraving motor 3 in this embodiment can be manually replaced according to actual conditions.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not substantially depart from the scope of the embodiments of the present invention, and are intended to be covered by the claims and the specification.

Claims (9)

1. The utility model provides a totally closed small-size desktop formula engraver which characterized in that: comprises a box body, a bench vice, a carving motor, a transmission mechanism arranged in the box body and an operation panel arranged on the outer surface of the box body;

the transmission mechanism comprises an X-axis translation mechanism, a Y-axis translation mechanism and a Z-axis translation mechanism, the X-axis translation mechanism, the Y-axis translation mechanism and the Z-axis translation mechanism are respectively connected in the box body in a sliding manner along an X axis, a Y axis and a Z axis in a three-dimensional coordinate system, and the Y-axis translation mechanism is in transmission connection with the Z-axis translation mechanism; the engraving motor is arranged on the Y-axis translation mechanism and moves in a Y-Z plane through the compound motion of the Z-axis translation mechanism and the Y-axis translation mechanism; the bench vice is arranged on the X-axis translation mechanism, and the bench vice moves along the X axis through the movement of the X-axis translation mechanism;

the lateral wall of box is equipped with the door frame and the door frame is equipped with the isolation door that can open to the side.

2. The totally enclosed tabletop engraver of claim 1, wherein: the isolating door is connected with the door frame in a swinging mode through a hinge.

3. The totally enclosed tabletop engraver of claim 1, wherein: the interior of the base of the box body is provided with a 24V direct-current power supply transformer, a controller and a motor driver, and the controller is electrically connected with the 24V direct-current power supply transformer and the motor driver respectively.

4. A totally enclosed tabletop engraver as claimed in claim 3 wherein: the operation panel is provided with a power switch, a carving starting button, a carving speed regulating knob, a power indicator lamp, an electronic display screen, a data interface, a forward/backward knob, an X-axis selecting button, a Y-axis selecting button and a Z-axis selecting button which are electrically connected with the controller.

5. The totally enclosed tabletop engraver of claim 1, wherein: the X-axis translation mechanism comprises an X lead screw, an X stepping motor, an X guide rod and an X sliding block, the X lead screw is parallel to the X guide rod, the X lead screw is rotatably installed in the box body along an X axis, the X guide rod is fixedly installed in the box body along the X axis, the X stepping motor is in transmission connection with the X lead screw, the X sliding block is sleeved on the X lead screw and the X guide rod, the X sliding block is rotatably connected with the X lead screw, the X sliding block is in sliding connection with the X guide rod, and the X sliding block is further driven to translate along the X axis through the rotation of the X stepping motor.

6. The totally enclosed tabletop engraver of claim 5, wherein: the bench vice is fixedly arranged on the X sliding block.

7. The totally enclosed tabletop engraver of claim 1, wherein: the Z-axis translation mechanism comprises a Z lead screw, a Z stepping motor, a Z guide rod and a Z sliding block, the Z lead screw is parallel to the Z guide rod, the Z lead screw is rotatably installed in the box body along the Z axis, the Z guide rod is fixedly installed in the box body along the Z axis, the Z stepping motor is in transmission connection with the Z lead screw, the Z sliding block is sleeved on the Z lead screw and the Z guide rod, the Z sliding block is rotatably connected with the Z lead screw and is in sliding connection with the Z guide rod, and the Z sliding block is driven to translate along the Z axis by the rotation of the Z stepping motor.

8. The totally enclosed tabletop engraver of claim 7, wherein: the Y-axis translation mechanism comprises a Y lead screw, a Y stepping motor, a Y guide rod and a Y sliding block; the Y lead screw is parallel to the Y guide rod, the Y lead screw is rotatably mounted on the Z sliding block along a Y axis, the Y guide rod is fixedly mounted on the Z sliding block along the Y axis, the Y stepping motor is in transmission connection with the Y lead screw, the Y sliding block is sleeved on the Y lead screw and the Y guide rod, the Y sliding block is rotatably connected with the Y lead screw and is in sliding connection with the Y guide rod, and the Y sliding block is driven to translate along the Y axis through the rotation of the Y stepping motor.

9. The totally enclosed tabletop engraver of claim 8, wherein: the engraving motor is fixedly arranged on the Y sliding block, and a cutter of the engraving motor faces downwards.

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