CN210970485U - Imprinting device for computer hardware development - Google Patents

Abstract

The utility model discloses an engraving device for computer hardware development, the on-line screen storage device comprises a base, the common horizontal welded fastening in one side that the support is relative has the backup pad, the welding of backup pad upside has the motor, welded fastening has first half gear on the output shaft of motor, sliding connection has the conveyer belt on the output shaft of motor, conveyer belt sliding connection has the axis of rotation, axis of rotation other end welded fastening has second half gear, first half gear has the double faced tooth with the common meshing of second half gear. The utility model discloses two half gears drive the up-and-down motion is made to the double faced rack, and deflection motion about the telescopic link is made to make seal seat up-and-down motion carry out seal work to the computer hardware body, and because double faced rack up-and-down motion distance keeps unanimous, thereby seal seat keeps unanimous to the pressure of computer hardware body, prevents to cause the damage because manual operation pressure is too big to the computer hardware body.

Description

Imprinting device for computer hardware development

Technical Field

The utility model relates to an imprinting technical field especially relates to a computer hardware development is with imprinting device.

Background

Computer hardware refers to a general term for various physical devices composed of electronic, mechanical and optoelectronic components in a computer system, and in small-scale production of computer hardware development, it is often necessary to perform imprinting work on computer hardware development workpieces.

Traditional computer hardware development work piece is all artifical manual work and carries out the seal work of carving, but artifical manual seal of carving wastes time and energy, and can't keep unanimous to the pressure of calculation and hardware body during the manual seal of staff, has influenced the precision and the effect of seal, and the manual pressure of exerting still need keep computer hardware body to keep fixed simultaneously, has increaseed the staff and has operated the degree of difficulty for production efficiency is low, has reduced the quality of seal.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the problems that the manual engraving is time-consuming and labor-consuming and the engraving is not accurate in the prior art, and providing an engraving device for developing computer hardware.

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

an engraving device for developing computer hardware comprises a base, wherein the upper side of the base is symmetrically welded and fixed with a bracket, a supporting plate is horizontally welded and fixed on one side of the bracket, a fixing block is welded and fixed on the upper side of the supporting plate, a motor is welded and fixed on the upper side of the fixed block, a first half gear is welded and fixed on an output shaft of the motor, the output shaft of the motor is connected with a conveyor belt in a sliding way, one end of the conveyor belt far away from the motor is connected with a rotating shaft in a sliding way, one end of the rotating shaft is rotatably connected with the adjacent bracket through a bearing, the other end of the rotating shaft is fixedly welded with a second half gear, the first half gear and the second half gear are meshed with a double-sided rack together at one side adjacent to each other, the lower end of the double-sided rack penetrates through the supporting plate and is fixedly welded with the linkage mechanism, and the pushing mechanism is fixedly welded at one side, far away from the motor, of the double-sided rack.

Preferably, the linkage mechanism comprises a guide rod welded and fixed at the lower end of the double-sided rack, the lower end of the guide rod is symmetrically and rotatably connected with two slide rods, one end, far away from the guide rod, of each slide rod is rotatably connected with a slide block, two first grooves and two second grooves are symmetrically formed in the upper side of the base, and the two slide blocks slide in the corresponding first grooves respectively.

Preferably, every equal sliding connection has a ejector pad in the second recess, every the equal welded fastening of ejector pad upside has the baffle, the symmetry is opened in the base has two spouts, every the spout communicates with first recess, the second recess that corresponds, every equal sliding connection has the trace in the spout, trace both ends respectively with slider, ejector pad welded fastening.

Preferably, pushing mechanism includes the telescopic link of welded fastening in two-sided rack one side, it is connected with dead lever and catch bar to rotate on the telescopic link, the one end of dead lever telescopic link is kept away from with backup pad upside welded fastening, the one end that the telescopic link was kept away from to the catch bar runs through backup pad and welded fastening and has the seal seat.

Preferably, the engraving seat is arranged right above the computer hardware body, the fixing rod is arranged between the push rod and the double-sided rack, the telescopic rod comprises a connecting rod and a loop bar, the connecting rod is sleeved at the two ends of the loop bar, the connecting rod is close to the engraving seat and is rotatably connected with the push rod, and the connecting rod is close to the motor and is rotatably connected with the double-sided rack.

Preferably, the first half gear and the second half gear have the same cross-sectional radius, and the smooth surfaces of the first half gear and the second half gear are in the same direction.

Compared with the prior art, the utility model has the advantages of:

1. the motor drives the double-sided rack to do up-and-down reciprocating motion on a vertical plane through two half gears, the double-sided rack drives the telescopic link to do up-and-down deflection motion by taking the fixed rod as the center, thereby enabling the push rod to drive the engraving seat to do up-and-down motion to engrave a computer hardware body, and the up-and-down motion distance of the double-sided rack is kept consistent, thereby keeping the distance of the engraving seat to do down-motion consistent, thereby keeping the pressure of the engraving seat to the computer hardware body consistent, realizing automatic engraving work, ensuring the engraving precision, and preventing the computer hardware body from being damaged due to overlarge manual operation pressure.

2. The guide rod is driven to move up and down when the double-sided rack reciprocates up and down, so that the slider does reciprocating motion in the first groove, the double-sided rack moves up and drives the two sliders to be close to each other, the sliders drive the two baffles on the push block to be close to each other through the linkage rod to clamp the computer hardware body, at the moment, the engraving seat moves down to perform engraving work on the hardware body, the engraving work is guaranteed, the device clamps the computer hardware body, the automatic engraving clamping work is realized, thereby the computer hardware body is prevented from moving to influence the processing precision, and the efficiency is improved.

Drawings

Fig. 1 is a front cross-sectional view of an imprinting apparatus for developing computer hardware according to the present invention.

Fig. 2 is a left side sectional view of the imprinting apparatus for developing computer hardware according to the present invention.

Fig. 3 is a right side sectional view of the imprinting apparatus for developing computer hardware according to the present invention.

Fig. 4 is a cross-sectional view of a base of an imprinting apparatus for developing computer hardware according to the present invention.

Fig. 5 is an enlarged view of a portion a of fig. 1.

In the figure: the device comprises a base 1, a support 2, a support plate 3, a motor 4, a first half gear 5, a conveyor belt 6, a rotating shaft 7, a second half gear 8, a double-sided rack 9, a telescopic rod 10, a connecting rod 101, a sleeve rod 102, a fixed rod 11, a push rod 12, an engraving seat 13, a guide rod 14, a slide rod 15, a first groove 16, a second groove 17, a sliding groove 18, a sliding block 19, a push block 20, a linkage rod 21 and a baffle 22.

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.

Referring to fig. 1-5, an engraving device for computer hardware development comprises a base 1, wherein a support 2 is symmetrically welded and fixed on the upper side of the base 1, a support plate 3 is horizontally welded and fixed on one side of the support 2 opposite to the support plate, a fixing block is welded and fixed on the upper side of the support plate 3, a motor 4 is welded and fixed on the upper side of the fixing block, a first half gear 5 is welded and fixed on an output shaft of the motor 4, a conveyor belt 6 is connected on the output shaft of the motor 4 in a sliding mode, one end, far away from the motor 4, of the conveyor belt 6 is connected with a rotating shaft 7 in a sliding mode, one end of the rotating shaft 7 is connected with the adjacent support 2 in a rotating mode through a bearing, a second half gear 8 is welded and fixed on the other end of the rotating shaft 7, a double-sided rack 9 is meshed with one side, adjacent to the first half gear 5 and the second.

The linkage mechanism comprises a guide rod 14 fixed at the lower end of the double-sided rack 9 in a welding mode, two slide rods 15 are symmetrically and rotatably connected to the lower end of the guide rod 14, one end, far away from the guide rod 14, of each slide rod 15 is rotatably connected with a slide block 19, two first grooves 16 and two second grooves 17 are symmetrically formed in the upper side of the base 1, and the two slide blocks 19 respectively slide in the corresponding first grooves 16.

Equal sliding connection has a ejector pad 20 in every second recess 17, equal welded fastening of 20 upsides of every ejector pad has baffle 22, the symmetry is opened in base 1 has two spouts 18, every spout 18 and the first recess 16 that corresponds, second recess 17 intercommunication, equal sliding connection has trace 21 in every spout 18, trace 21 both ends respectively with slider 19, ejector pad 20 welded fastening, guide arm 14 upwards moves and drives two sliders 19 and be close to each other, slider 19 drives two trace 21 and is close to each other, make two ejector pads 20 be close to each other, two baffles 22 press from both sides the computer hardware body tightly, thereby prevent that the computer hardware body from taking place to remove when carrying out the seal work and influencing the machining precision.

Pushing mechanism includes telescopic link 10 of welded fastening in two-sided rack 9 one side, rotates on telescopic link 10 to be connected with dead lever 11 and catch bar 12, and the one end of dead lever 11 telescopic link 10 is kept away from with 3 upside welded fastening of backup pad, and the one end that telescopic link 10 was kept away from to catch bar 12 runs through backup pad 3 and welded fastening has seal carving seat 13.

The engraving seat 13 is arranged right above a computer hardware body, the fixed rod 11 is arranged between the pushing rod 12 and the double-sided rack 9, the radius of the cross section of the first half gear 5 is the same as that of the cross section of the second half gear 8, the smooth surface direction on the first half gear 5 and the second half gear 8 is the same, when the first half gear 5 drives the double-sided rack 9 to move upwards, the smooth surface of the second half gear 8 is close to the double-sided rack 9, when the second half gear 8 drives the double-sided rack 9 to move downwards, the smooth surface of the first half gear 5 is close to the double-sided rack 9.

The telescopic link 10 includes connecting rod 101 and loop bar 102, and the connecting rod 101 has all been cup jointed at loop bar 102 both ends, and the connecting rod 101 that is close to seal seat 13 rotates with catch bar 12 to be connected, and the connecting rod 101 that is close to motor 4 rotates with two-sided rack 9 to be connected, and the distance of two-sided rack 9 upward movement, downstream is always the same to make seal seat 13 keep unanimous to the pressure size of computer hardware body, guaranteed the device seal precision of carving.

In the utility model, the computer hardware body is placed at the designated position, the starting motor 4 drives the first half gear 5 to rotate, the first half gear 5 is meshed with the double-sided rack 9 to drive the double-sided rack 9 to move upwards, the guide rod 14 moves upwards and drives the two sliders 19 to slide in the first groove 16 through the slide rod 15 and approach each other, the sliders 19 approach each other to drive the two linkage rods 21 to slide in the sliding grooves 18 and approach each other, the sliders 19 enable the two push blocks 20 to slide in the second groove 17 through the linkage rods 21 and approach each other, the push blocks 20 drive the two baffle plates 22 to approach each other to clamp the computer hardware body, the computer hardware body is prevented from moving during the engraving work to influence the processing precision, the double-sided rack 9 moves upwards to drive the telescopic rod 10 to make deflection motion with the fixed rod 11 position center, one side of the telescopic rod 10 far away from the motor 4 rotates downwards, so that the pushing rod 12 drives the engraving seat 13 to move downwards to perform engraving work on the computer hardware body.

When the first half gear 5 is disengaged from the double-sided rack 9, the imprinting work is completed at this time, the second half gear 8 is engaged with the double-sided rack 9, thereby driving the double-sided rack 9 to move downwards, the guide rod 14 moves downwards and drives the two sliders 19 to slide in the first groove 16 through the slide rod 15 and to be away from each other, thereby the sliders 19 enable the two pushing blocks 20 to slide in the second groove 17 through the linkage rod 21 and to be away from each other, the pushing blocks 20 drive the two baffles 22 to be away from the computer hardware body, the downward movement of the double-sided rack 9 drives the telescopic rod 10 to make deflection motion with the fixed rod 11 position center, one side of the telescopic rod 10 away from the motor 4 rotates upwards, thereby the pushing rod 12 drives the imprinting seat 13 to move upwards and to be away from the.

Because the double-sided rack 9 moves up and down under the drive of the first half gear 5 and the second half gear 8, and the distances of upward movement and downward movement of the double-sided rack 9 are always the same, the pressure of the engraving seat 13 on the computer hardware body is kept consistent, the engraving precision of the device is ensured, the automatic processing is realized, and the damage to the computer hardware body caused by overlarge manual operation pressure is prevented.

It should be noted that the motor model used in the present invention is a 6RK200RGU-CF motor, and the use of the 6RK200RGU-CF motor is a well-known technical means for those skilled in the art, and will not be described herein.

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 (7)

1. The utility model provides an engraving device for computer hardware development, includes base (1), its characterized in that, base (1) upside symmetry welded fastening has support (2), the common level welded fastening in one side that support (2) are relative has backup pad (3), backup pad (3) upside welded fastening has the fixed block, fixed block upside welded fastening has motor (4), welded fastening has first semi-gear (5) on the output shaft of motor (4), sliding connection has conveyer belt (6) on the output shaft of motor (4), the one end sliding connection that motor (4) were kept away from in conveyer belt (6) has axis of rotation (7), axis of rotation (7) one end is connected through using the bearing rotation with adjacent support (2), axis of rotation (7) other end welded fastening has second semi-gear (8), first semi-gear (5) have two-sided rack (9) with the common meshing in one side that second semi-gear (8) are adjacent The lower end of the double-sided rack (9) penetrates through the supporting plate (3) and is fixedly welded with a linkage mechanism, and one side, far away from the motor (4), of the double-sided rack (9) is fixedly welded with a pushing mechanism.

2. The imprinting device for computer hardware development according to claim 1, wherein the linkage mechanism comprises a guide rod (14) welded and fixed at the lower end of the double-sided rack (9), the lower end of the guide rod (14) is symmetrically and rotatably connected with two slide rods (15), one end of each slide rod (15) far away from the guide rod (14) is rotatably connected with a slide block (19), the upper side of the base (1) is symmetrically provided with two first grooves (16) and two second grooves (17), and the two slide blocks (19) respectively slide in the corresponding first grooves (16).

3. The engraving device for developing computer hardware according to claim 2, wherein a pushing block (20) is slidably connected in each second groove (17), a baffle (22) is fixedly welded on the upper side of each pushing block (20), two sliding grooves (18) are symmetrically formed in the base (1), each sliding groove (18) is communicated with the corresponding first groove (16) and the corresponding second groove (17), a linkage rod (21) is slidably connected in each sliding groove (18), and two ends of the linkage rod (21) are respectively fixedly welded with the sliding block (19) and the pushing block (20).

4. The imprinting device for computer hardware development according to claim 1, wherein the pushing mechanism comprises a telescopic rod (10) fixed on one side of the double-sided rack (9) by welding, a fixed rod (11) and a pushing rod (12) are connected to the telescopic rod (10) in a rotating manner, one end of the telescopic rod (10) far away from the fixed rod (11) is fixed to the upper side of the supporting plate (3) by welding, and one end of the pushing rod (12) far away from the telescopic rod (10) penetrates through the supporting plate (3) and is fixed with the imprinting seat (13) by welding.

5. The computer hardware development imprinting device according to claim 4, wherein the imprinting base (13) is disposed right above the computer hardware body, and the fixing rod (11) is disposed between the pushing rod (12) and the double-sided rack (9).

6. An imprinting device for computer hardware development according to claim 1, characterized in that the first half-gear (5) and the second half-gear (8) have the same cross-sectional radius, and the smooth surfaces of the first half-gear (5) and the second half-gear (8) are oriented in the same direction.

7. The engraving device for computer hardware development according to claim 1, wherein the telescopic rod (10) comprises a connecting rod (101) and a sleeve rod (102), the connecting rod (101) is sleeved at both ends of the sleeve rod (102), the connecting rod (101) close to the engraving seat (13) is rotatably connected with the push rod (12), and the connecting rod (101) close to the motor (4) is rotatably connected with the double-sided rack (9).

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