CN211082693U

CN211082693U - Electrically-driven vibration damper for electric control machining

Info

Publication number: CN211082693U
Application number: CN201922337881.7U
Authority: CN
Inventors: 梁运; 李润东
Original assignee: Shenzhen Chuang Rui Core Electronics Co ltd
Current assignee: Shenzhen Chuang Rui Core Electronics Co ltd
Priority date: 2019-12-23
Filing date: 2019-12-23
Publication date: 2020-07-24
Anticipated expiration: 2029-12-23

Abstract

The utility model discloses a damping device for electrically-driven electrically-controlled machining, which comprises a base and a damping plate, wherein sliding plates are fixedly connected to both sides of the damping plate, a connecting plate is welded at the center of the bottom of the damping plate, ten second springs are welded at the bottom of the connecting plate, the bottom ends of the second springs are welded at the inner bottom of the base, and two first T-shaped chutes which are symmetrical by taking the bottom center point of the base as a symmetry center are arranged at the inner bottom of the base; the work piece is placed and is processed on the shock attenuation board, and the vibrations power that produces in the course of working passes through slide and traveller transmission to first spring, transmits vibrations power to first arc steel sheet and second arc steel sheet through even board simultaneously, and the first spring of deformation, first arc steel sheet and second arc steel sheet can be turned into elastic potential energy with the vibrations, slow down the vibrations power, protect the work piece, and simultaneously, fore-and-aft vibrations power is transmitted to the cross spring through the bull stick, further slows down the vibrations power.

Description

Electrically-driven vibration damper for electric control machining

Technical Field

The utility model relates to an electricity drives automatically controlled processing technology field, specifically is an electricity drives automatically controlled vibration damper for processing.

Background

The electric drive is a component playing a key role and a pivot role in the process that the motor realizes the mutual conversion of mechanical energy and electric energy. For a generator, it is a component that generates an electromotive force, such as a rotor in a dc generator, a stator in an ac generator; in the case of an electric motor, it is the component that generates the electromagnetic force, such as the rotor in a dc motor. An electric drive is a component of an electric motor that incorporates wires that rotate within a magnetic field induced in the wires by relative movement of the wires through the magnetic field between the pole pieces or induced by current passing through the wires. The electric control means an electric control device. The semi-finished product of the electric-drive electric-control production and processing process needs to be supported by a workbench.

At present, the supporting table structure of the general electric drive electric control finished product processing process is simpler, the damping effect is poorer, the electric drive electric control equipment is more precise generally, and the product is easy to damage due to the rigid processing collision in the process. Therefore, the damping device for electrically-driven and electrically-controlled machining is provided.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an electricity drives automatically controlled damping device for processing to solve the problem that proposes among the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: the damping device for electrically-driven electrically-controlled machining comprises a base and a damping plate, wherein sliding plates are fixedly connected to two sides of the damping plate, a connecting plate is welded at the center of the bottom of the damping plate, ten second springs are welded at the bottom of the connecting plate, the bottom end of each second spring is welded at the bottom of the inner side of the base, two first T-shaped sliding grooves which are symmetrical by taking the bottom central point of the base as a symmetrical center are formed in the bottom of the inner side of the base, first arc-shaped steel plates are fixedly connected to two sides of the connecting plate, first T-shaped sliding blocks are welded at one ends, away from the connecting plate, of the first arc-shaped steel plates and are connected to the inside of the first T-shaped sliding grooves in a sliding manner, second arc-shaped steel plates are fixedly connected to two sides of the connecting plate and are connected to the bottom of the first arc-shaped steel plates in a sliding manner, and second T-shaped sliding blocks are welded at one ends, away, the base is provided with two second T-shaped sliding grooves which are symmetrical by taking the bottom center point of the base as a symmetry center at the bottom of the inner side of the base, and the second T-shaped sliding blocks are connected to the inner parts of the second T-shaped sliding grooves in a sliding mode.

As further preferable in the present technical solution: the utility model discloses a sliding plate, including base, sliding column, sliding plate, spout, sliding plate, sliding connection, the inside of base is seted up quantity and is two the spout that uses the central point of base as the symmetry center symmetry, the inside sliding connection of spout has first spring, the top welding of first spring has the traveller, traveller sliding connection is in the inside of spout, one side of traveller welds in one side of slide, slide sliding connection is in the inside of spout.

As further preferable in the present technical solution: the welding of the bottom of shock attenuation board has the quantity to be two the set-square that uses the central point of shock attenuation board as the symmetry center symmetry, the slide bar that quantity is ten evenly distributed is all welded to one side of set-square and slide, the lateral wall cover of slide bar is equipped with horizontal spring, the welding of the one end of horizontal spring has the lantern ring, the lateral wall of slide bar is located to the inside wall cover of the lantern ring.

As further preferable in the present technical solution: the draw-in groove has been seted up at the top of base, the equal sliding connection in the inside of draw-in groove in both sides of shock attenuation board.

As further preferable in the present technical solution: one side of the lantern ring is rotated and is connected with the bull stick, one side that the lantern ring was kept away from to the bull stick rotates and is connected with the plate body, the top welding of plate body has the perpendicular spring that quantity is ten, the top of erecting the spring welds in the bottom of shock attenuation board.

As further preferable in the present technical solution: the bottom welding of plate body has the reference column that quantity is ten, the bottom welding of reference column has the third spring, the bottom fixed connection of third spring is in the inboard bottom of base, the lateral wall cover of reference column is equipped with the holding ring, the bottom of holding ring welds in the inboard bottom of base, the inside wall of holding ring is located to the third spring housing.

Compared with the prior art, the beneficial effects of the utility model are that: the work piece is placed and is processed on the shock attenuation board, and the vibrations power that produces in the course of working passes through slide and traveller transmission to first spring, transmits vibrations power to first arc steel sheet and second arc steel sheet through even board simultaneously, and the first spring of deformation, first arc steel sheet and second arc steel sheet can be turned into elastic potential energy with the vibrations, slow down the vibrations power, protect the work piece, and simultaneously, fore-and-aft vibrations power is transmitted to the cross spring through the bull stick, further slows down the vibrations power.

Drawings

Fig. 1 is a schematic structural view of the present invention;

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

fig. 3 is a schematic structural view of a second T-shaped chute of the present invention.

In the figure: 1. a base; 2. a damper plate; 3. a slide plate; 4. a traveler; 5. a first spring; 6. a chute; 7. connecting plates; 8. a first arc-shaped steel plate; 9. a second arc-shaped steel plate; 10. a second spring; 11. a second T-shaped chute; 12. a second T-shaped slider; 13. a card slot; 15. a first T-shaped slider; 16. a first T-shaped chute; 17. a lateral spring; 18. a slide bar; 19. a collar; 20. a rotating rod; 21. a vertical spring; 22. a plate body; 23. a set square; 24. a positioning column; 25. a positioning ring; 26. and a third spring.

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.

Examples

Referring to fig. 1-3, the present invention provides a technical solution: a damping device for electrically-driven electrically-controlled machining comprises a base 1 and a damping plate 2, wherein sliding plates 3 are fixedly connected to two sides of the damping plate 2, a connecting plate 7 is welded to the center of the bottom of the damping plate 2, ten second springs 10 are welded to the bottom of the connecting plate 7, the bottom ends of the second springs 10 are welded to the bottom of the inner side of the base 1, two first T-shaped sliding grooves 16 which are symmetrical with the bottom center point of the base 1 serving as the symmetry center are formed in the bottom of the base 1, first arc-shaped steel plates 8 are fixedly connected to two sides of the connecting plate 7, first T-shaped sliding blocks 15 are welded to one ends, away from the connecting plate 7, of the first arc-shaped steel plates 8, the first T-shaped sliding blocks 15 are connected to the inside of the first T-shaped sliding grooves 16 in a sliding mode, second arc-shaped steel plates 9 are fixedly connected to two sides of the connecting plate 7, the second arc-shaped steel plates 9 are connected to the bottom of the first arc-shaped steel plates 8 in, the number of the inner bottom of the base 1 is two, the two second T-shaped sliding grooves 11 are symmetrical by taking the bottom center point of the base 1 as a symmetry center, and the second T-shaped sliding blocks 12 are connected inside the second T-shaped sliding grooves 11 in a sliding mode.

In this embodiment, specifically: base 1's inside is seted up quantity and is two spout 6 that uses base 1's central point as the symmetry center, the inside sliding connection of spout 6 has first spring 5, the top welding of first spring 5 has

traveller

4, 4 sliding connection in the inside of spout 6 of traveller, one side of traveller 4 welds in one side of

slide

3, 3 sliding connection in the inside of spout 6 of slide, through above setting up, the vibrations power that produces in the work piece course of working, through damper plate 2,

slide

3 and 4 transmission of traveller to first spring 5, extrude first spring 5, make first spring 5 produce deformation, slow down the vibrations power.

In this embodiment, specifically: the bottom welding of damper plate 2 has the quantity to be two the set-square 23 that uses damper plate 2's central point as the symmetry center symmetry, and the slide bar 18 that the evenly distributed of quantity is ten is all welded to one side of set-square 23 and slide 3, and the lateral wall cover of slide bar 18 is equipped with horizontal spring 17, and the one end welding of horizontal spring 17 has lantern ring 19, and slide bar 18's lateral wall is located to the inside wall cover of lantern ring 19, and lantern ring 19 can slide for slide bar 18.

In this embodiment, specifically: draw-in groove 13 has been seted up at base 1's top, and the equal sliding connection in the inside of draw-in groove 13 in both sides of shock attenuation board 2, the range of motion that can restrict shock attenuation board 2 is seted up to draw-in groove 13.

In this embodiment, specifically: one side of lantern ring 19 is rotated and is connected with bull stick 20, and one side that the lantern ring 19 was kept away from to bull stick 20 is rotated and is connected with plate body 22, and the top welding of plate body 22 has the vertical spring 21 that the quantity is ten, and the top of vertical spring 21 welds in the bottom of damper plate 2, and fore-and-aft vibrations power passes through plate body 22 and bull stick 20 and turns into horizontal effort, transmits to lantern ring 19 and horizontal spring 17.

In this embodiment, specifically: plate body 22's bottom welding has reference column 24 that quantity is ten, reference column 24's bottom welding has third spring 26, third spring 26's bottom fixed connection is in base 1's inboard bottom, reference column 24's lateral wall cover is equipped with holding ring 25, the bottom of holding ring 25 welds in base 1's inboard bottom, the inside wall of holding ring 25 is located to third spring 26 cover, holding ring 25 and reference column 24 combined action, make damping plate 2 can not produce the displacement of horizontal direction for base 1, damping plate 2 can be slowed down to base 1's impact force to the setting of third spring 26.

Theory of operation or structure, in use, the work piece is placed and is processed on damper plate 2, the shaking force that produces in the work piece course of working, through damper plate 2, slide 3 and traveller 4 transmit to first spring 5, extrude first spring 5, make first spring 5 produce deformation, slow down the shaking force, fore-and-aft shaking force passes through plate body 22 and bull stick 20 and turns into horizontal effort, transmit to lantern ring 19 and horizontal spring 17, lantern ring 19 extrudees horizontal spring 17, the horizontal spring 17 of deformation absorbs the shaking force, and simultaneously, the shaking force passes through even board 7 effect and first arc steel sheet 8 and second arc steel sheet 9, relative gliding first arc steel sheet 8 and second arc steel sheet 9 can effectual shaking force transform into the inside effort of steel sheet, slow down the shaking force, protect the work piece.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides an electricity drives automatically controlled damping device for processing, includes base (1) and shock attenuation board (2), its characterized in that: the shock absorption plate is characterized in that sliding plates (3) are fixedly connected to two sides of the shock absorption plate (2), a connecting plate (7) is welded to the center of the bottom of the shock absorption plate (2), ten second springs (10) are welded to the bottom of the connecting plate (7), the bottom end of each second spring (10) is welded to the bottom of the inner side of the base (1), two first T-shaped sliding grooves (16) which are symmetrical about the center of the bottom of the base (1) are formed in the bottom of the inner side of the base (1), first arc-shaped steel plates (8) are fixedly connected to two sides of the connecting plate (7), first T-shaped sliding blocks (15) are welded to one ends, far away from the connecting plate (7), of the first arc-shaped steel plates (8), the first T-shaped sliding blocks (15) are connected to the inside of the first T-shaped sliding grooves (16) in a sliding mode, second arc-shaped steel plates (9) are fixedly connected to two sides, second arc steel sheet (9) sliding connection is in the bottom of first arc steel sheet (8), second arc steel sheet (9) are kept away from the one end welding of even board (7) and are had second T type slider (12), the second T type spout (11) that the bottom central point that uses base (1) that quantity is two is symmetry center symmetry are seted up to the inboard bottom of base (1), second T type slider (12) sliding connection is in the inside of second T type spout (11).

2. The vibration damping device for electrically driven and controlled machining according to claim 1, wherein: the utility model discloses a sliding column, including base (1), the inside of base (1) is seted up quantity and is two spout (6) that use the central point of base (1) as the symmetry center symmetry, the inside sliding connection of spout (6) has first spring (5), the top welding of first spring (5) has traveller (4), traveller (4) sliding connection is in the inside of spout (6), one side of traveller (4) welds in one side of slide (3), slide (3) sliding connection is in the inside of spout (6).

3. The vibration damping device for electrically driven and controlled machining according to claim 1, wherein: the welding of the bottom of damper plate (2) has set square (23) that the central point that uses damper plate (2) that quantity is two is symmetry, one side of set square (23) and slide (3) all welds slide bar (18) that have the evenly distributed that quantity is ten, the lateral wall cover of slide bar (18) is equipped with horizontal spring (17), the one end welding of horizontal spring (17) has lantern ring (19), the lateral wall of slide bar (18) is located to the inside wall cover of the lantern ring (19).

4. The vibration damping device for electrically driven and controlled machining according to claim 1, wherein: draw-in groove (13) have been seted up at the top of base (1), the equal sliding connection in the inside of draw-in groove (13) in both sides of shock attenuation board (2).

5. The vibration damping device for electrically driven and controlled machining according to claim 3, wherein: one side of the lantern ring (19) is rotated and is connected with the bull stick (20), one side that the lantern ring (19) was kept away from in bull stick (20) is rotated and is connected with plate body (22), the top welding of plate body (22) has perpendicular spring (21) of ten in quantity, the top of perpendicular spring (21) welds in the bottom of shock attenuation board (2).

6. The vibration damping device for electrically driven and controlled machining according to claim 5, wherein: the welding of the bottom of plate body (22) has reference column (24) that quantity is ten, the welding of the bottom of reference column (24) has third spring (26), the bottom fixed connection of third spring (26) is in the inboard bottom of base (1), the lateral wall cover of reference column (24) is equipped with holding ring (25), the bottom of holding ring (25) welds in the inboard bottom of base (1), the inside wall of holding ring (25) is located to third spring (26) cover.