CN210911286U - Numerical control machining die with telescopic mechanism - Google Patents

Abstract

The utility model discloses a numerical control mold processing with telescopic machanism, including second bearing board, third bearing board and fourth bearing board, the intermediate position department level on the inside top of third bearing board is provided with the spout, spout internally mounted have with the first slider of spout assorted, the equal vertical first spring of being connected on first slider top of installing in both ends on the inside top of kelly, the top horizontal mounting of first bracing piece has the fourth bearing board, there is the second bearing board top on the top in the second bracing piece outside through bearing horizontal mounting, the equal vertical second sleeve of installing in fourth bearing board top of second bracing piece both sides, the vertical second connecting rod of running through on second sleeve top and with first draw-in groove assorted of installing in second spring top. This numerical control mold processing with telescopic machanism drives the mould body through third spring and fourth spring and reciprocates to be convenient for realize the flexible of mould body.

Description

Numerical control machining die with telescopic mechanism

Technical Field

The utility model relates to a mould processing technology field specifically is a numerical control mold processing with telescopic machanism.

Background

The numerical control machining die is a special die applied to numerical control machining and has an important function in the numerical control machining.

However, most of the numerical control processing molds in the current market are inconvenient to use due to the fact that the telescopic mechanism is not arranged, and most of the numerical control processing molds in the current market are inconvenient to adjust the angle and the horizontal position, so that the numerical control processing mold with the telescopic mechanism is provided for solving the problems.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a numerical control mold processing with telescopic machanism to solve the problem of proposing among the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: a numerical control machining die with a telescopic mechanism comprises a second bearing plate, a third bearing plate and a fourth bearing plate, wherein a sliding groove is horizontally arranged at the middle position of the top end in the third bearing plate, a second clamping groove is uniformly formed in the bottom end of the sliding groove, a first sliding block matched with the sliding groove is arranged in the sliding groove, clamping rods matched with the second clamping groove are arranged at two ends of the top end of the first sliding block, first springs connected with the top end of the first sliding block are vertically arranged at two ends of the top end in the clamping rods, a first supporting rod is vertically arranged at the middle position of the top end of the first sliding block, a fourth bearing plate is horizontally arranged at the top end of the first supporting rod, a second supporting plate is vertically arranged at the middle position of the top end of the fourth bearing plate, a second bearing plate is horizontally arranged at the top end of the outer side of the second supporting rod through a bearing, and a first clamping groove is uniformly formed in the bottom end in the second bearing, a second sleeve is vertically arranged at the top end of a fourth bearing plate at two sides of the second support rod, a second spring is vertically arranged in the second sleeve, a second connecting rod which penetrates through the top end of the second sleeve and is matched with the first clamping groove is vertically arranged at the top end of the second spring, slide rails are vertically arranged at two ends of the top end of the second bearing plate, a second slide block which is matched with the slide rails is arranged in the slide rails, a fourth connecting rod is horizontally arranged at one side, away from the slide rails, of the second slide block, a fourth spring is horizontally arranged at one end, close to the second slide block, of the outer side of the fourth connecting rod at one side of the fourth spring, a third sleeve is arranged at the outer side of the fourth connecting rod, the outer side wall of the third sleeve is hinged with a third connecting rod through a hinged shaft, the top end of the third connecting rod is hinged with a first bearing plate through a hinged shaft, the die is characterized in that a third spring is vertically arranged inside the first sleeve, a first connecting rod penetrating through the top end of the first sleeve is vertically arranged at the top end of the third spring, a fifth bearing plate is horizontally arranged at the top end of the first connecting rod, and a die body is arranged at the central position of the top end of the fifth bearing plate.

Preferably, the first support rod is connected with the sliding groove in a sliding manner through a first sliding block to form a sliding mechanism.

Preferably, the clamping rod is connected with the first sliding block through a first spring to form a telescopic mechanism, and the clamping rod is connected with the second clamping groove in a clamping mode to form a clamping mechanism.

Preferably, the second connecting rod is connected with the second sleeve through a second spring to form a telescopic mechanism, and the second connecting rod is connected with the first clamping groove in a clamping manner to form a clamping mechanism.

Preferably, the third connecting rod is rotatably connected with the third sleeve through a hinge shaft to form a rotating mechanism, the third sleeve is connected with the fourth connecting rod through a fourth spring to form a telescopic mechanism, and the fourth connecting rod is slidably connected with the sliding rail through a second sliding block to form a sliding mechanism.

Preferably, the first connecting rod is connected with the first sleeve through a third spring to form a telescopic mechanism.

Compared with the prior art, the beneficial effects of the utility model are that:

(1) by installing the clamping rod, the second clamping groove, the fourth bearing plate, the first supporting rod, the first sliding block, the sliding groove, the first spring and the die body, when the horizontal position of the numerical control machining die with the telescopic mechanism needs to be adjusted, the clamping rod is firstly pulled upwards to separate the clamping rod from the second clamping groove, then the fourth bearing plate and the first supporting rod are pulled to slide to a proper position in the sliding groove through the first sliding block, and then the clamping rod is loosened to drive the clamping rod to be clamped with the second clamping grooves at different positions again under the elastic force action of the first spring, so that the horizontal position of the die body can be adjusted conveniently;

(2) meanwhile, the device is provided with a die body, a second connecting rod, a first clamping groove and a second bearing plate, when the angle of the die body needs to be adjusted, the second connecting rod is firstly pulled downwards to enable the second connecting rod to be separated from the first clamping groove, then the second bearing plate is rotated to a proper position and then the second connecting rod is loosened, and the second connecting rod is driven to be clamped with the first clamping grooves at different positions again under the elastic action of a second spring, so that the angle of the die body can be adjusted conveniently;

(3) the device is through installing the mould body simultaneously, the head rod, the first sleeve, first cushion cap board, the third sleeve, the third connecting rod, third spring and fourth spring, when mould body atress needs to stretch out and draw back, the mould body will do all can and transmit for head rod and first sleeve, the first sleeve will do all can and transmit for first cushion cap board, third sleeve and third connecting rod, thereby drive the mould body and reciprocate under the spring action of third spring and fourth spring, thereby be convenient for realize the flexible of mould body.

Drawings

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

FIG. 2 is a left side view of the structure of the present invention;

fig. 3 is a schematic bottom view of the second support plate of the present invention;

fig. 4 is an enlarged schematic view of a portion a of fig. 1 according to the present invention.

In the figure: 1. a first connecting rod; 2. a first sleeve; 3. a first deck plate; 4. a second deck plate; 5. a first card slot; 6. a second sleeve; 7. a second card slot; 8. a chute; 9. a third deck plate; 10. a clamping rod; 11. a first support bar; 12. a first slider; 13. a first spring; 14. a fourth deck plate; 15. a second spring; 16. a second connecting rod; 17. a second support bar; 18. a third sleeve; 19. a third connecting rod; 20. a third spring; 21. a mold body; 22. a fifth deck plate; 23. a second slider; 24. a slide rail; 25. a fourth connecting rod; 26. and a fourth 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.

Referring to fig. 1-4, the present invention provides an embodiment: a numerical control processing die with a telescopic mechanism comprises a second bearing plate 4, a third bearing plate 9 and a fourth bearing plate 14, wherein a sliding groove 8 is horizontally arranged at the middle position of the top end in the third bearing plate 9, a second clamping groove 7 is uniformly arranged at the bottom end of the sliding groove 8, a first sliding block 12 matched with the sliding groove 8 is arranged in the sliding groove 8, clamping rods 10 matched with the second clamping groove 7 are respectively arranged at two ends of the top end of the first sliding block 12, the clamping rods 10 are connected with the first sliding block 12 through first springs 13 to form the telescopic mechanism, the clamping rods 10 are connected with the second clamping groove 7 in a clamping mode to form a clamping mechanism, the horizontal position is convenient to adjust, first springs 13 connected with the top end of the first sliding block 12 are vertically arranged at two ends of the top end in the clamping rods 10, a first supporting rod 11 is vertically arranged at the middle position of the top end of the first sliding block 12, the first supporting rod 11 is connected with the sliding groove 8 through the first sliding block 12 to form, the horizontal position is convenient to adjust, a fourth bearing plate 14 is horizontally arranged at the top end of the first supporting rod 11, a second supporting rod 17 is vertically arranged at the middle position of the top end of the fourth bearing plate 14, a second bearing plate 4 is horizontally arranged at the top end of the outer side of the second supporting rod 17 through a bearing, first clamping grooves 5 are uniformly formed in the bottom end of the inner part of the second bearing plate 4, second sleeves 6 are vertically arranged at the top ends of the fourth bearing plates 14 at two sides of the second supporting rod 17, second springs 15 are vertically arranged in the second sleeves 6, second connecting rods 16 penetrating through the top ends of the second sleeves 6 and matched with the first clamping grooves 5 are vertically arranged at the top ends of the second springs 15, the second connecting rods 16 are connected with the second sleeves 6 through the second springs 15 to form a telescopic mechanism, the second connecting rods 16 are connected with the first clamping grooves 5 in a clamping manner to form a clamping mechanism, the angle is convenient to adjust, sliding rails 24 are vertically arranged at two ends of, a second sliding block 23 matched with the sliding rail 24 is arranged in the sliding rail 24, a fourth connecting rod 25 is horizontally arranged on one side of the second sliding block 23 far away from the sliding rail 24, a fourth spring 26 is horizontally arranged on one end of the outer side of the fourth connecting rod 25 close to the second sliding block 23, a third sleeve 18 is arranged on the outer side of the fourth connecting rod 25 on one side of the fourth spring 26, the outer side wall of the third sleeve 18 is hinged with a third connecting rod 19 through a hinged shaft, the third connecting rod 19 is rotatably connected with the third sleeve 18 through the hinged shaft to form a rotating mechanism, the third sleeve 18 is connected with the fourth connecting rod 25 through the fourth spring 26 to form a telescopic mechanism, the fourth connecting rod 25 is slidably connected with the sliding rail 24 through the second sliding block 23 to form a sliding mechanism, the telescopic mechanism is convenient to stretch, the top end of the third connecting rod 19 is hinged with a first bearing plate 3 through the hinged shaft, and the top end, the third spring 20 is vertically installed in the first sleeve 2, the top end of the third spring 20 is vertically installed with a first connecting rod 1 penetrating through the top end of the first sleeve 2, the first connecting rod 1 is connected with the first sleeve 2 through the third spring 20 to form a telescopic mechanism, the telescopic mechanism is convenient to stretch, a fifth bearing plate 22 is horizontally installed at the top end of the first connecting rod 1, and a mold body 21 is installed at the central position of the top end of the fifth bearing plate 22.

The working principle is as follows: when the numerical control machining die with the telescopic mechanism is used, when the horizontal position of the numerical control machining die with the telescopic mechanism needs to be adjusted, the clamping rod 10 is pulled upwards to separate the clamping rod 10 from the second clamping groove 7, then the fourth supporting platform plate 14 and the first supporting rod 11 are pulled to slide to a proper position in the sliding groove 8 through the first sliding block 12, then the clamping rod 10 is loosened to drive the clamping rod 10 to be re-clamped with the second clamping grooves 7 at different positions under the action of the elastic force of the first spring 13, so that the horizontal position of the die body 21 is convenient to adjust, when the angle of the die body 21 needs to be adjusted, the second connecting rod 16 is pulled downwards to separate the second connecting rod 16 from the first clamping groove 5, then the second supporting platform plate 4 is rotated to a proper position, the second connecting rod 16 is loosened, the second connecting rod 16 is driven to be re-clamped with the first clamping grooves 5 at different positions under the action of the elastic force of the second spring 15, thereby be convenient for adjust the angle of mould body 21, when mould body 21 atress needs stretch out and draw back, mould body 21 will do all can and transmit for head rod 1 and first sleeve 2, and first sleeve 2 will do all can and transmit for first bearing board 3, third sleeve 18 and third connecting rod 19 to drive mould body 21 and reciprocate under the spring action of third spring 20 and fourth spring 26, thereby be convenient for realize the flexible of mould body 21, do above the utility model discloses a whole theory of operation.

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

Claims (6)

1. The utility model provides a numerical control mold processing with telescopic machanism, includes second cushion board (4), third cushion board (9) and fourth cushion board (14), its characterized in that: a sliding groove (8) is horizontally arranged at the middle position of the top end in the third bearing plate (9), second clamping grooves (7) are uniformly formed in the bottom end of the sliding groove (8), a first sliding block (12) matched with the sliding groove (8) is installed in the sliding groove (8), clamping rods (10) matched with the second clamping grooves (7) are installed at two ends of the top end of the first sliding block (12), first springs (13) connected with the top end of the first sliding block (12) are vertically installed at two ends of the top end in the clamping rods (10), a first supporting rod (11) is vertically installed at the center position of the top end of the first sliding block (12), a fourth bearing plate (14) is horizontally installed at the top end of the first supporting rod (11), a second supporting rod (17) is vertically installed at the middle position of the top end of the fourth bearing plate (14), a second bearing plate (4) is horizontally installed at the top end of the outer side of the second supporting rod (17) through a bearing, a first clamping groove (5) is uniformly formed in the bottom end inside the second bearing plate (4), second sleeves (6) are vertically arranged at the top ends of fourth bearing plates (14) on two sides of the second supporting rod (17), second springs (15) are vertically arranged inside the second sleeves (6), second connecting rods (16) penetrating through the top ends of the second sleeves (6) and matched with the first clamping grooves (5) are vertically arranged at the top ends of the second springs (15), slide rails (24) are vertically arranged at two ends of the top end of the second bearing plate (4), second slide blocks (23) matched with the slide rails (24) are arranged inside the slide rails (24), fourth connecting rods (25) are horizontally arranged on one sides, far away from the slide rails (24), of the second slide blocks (23) and fourth springs (26) are horizontally arranged at one ends, close to the second slide blocks (23), of the outer sides of the fourth connecting rods (25), the die is characterized in that a third sleeve (18) is installed on the outer side of a fourth connecting rod (25) on one side of a fourth spring (26), the outer side wall of the third sleeve (18) is hinged to a third connecting rod (19) through a hinged shaft, the top end of the third connecting rod (19) is hinged to a first bearing plate (3) through a hinged shaft, a first sleeve (2) is evenly and vertically installed on the top end of the first bearing plate (3), a third spring (20) is vertically installed inside the first sleeve (2), a first connecting rod (1) penetrating through the top end of the first sleeve (2) is vertically installed on the top end of the third spring (20), a fifth bearing plate (22) is horizontally installed on the top end of the first connecting rod (1), and a die body (21) is installed at the central position of the top end of the fifth bearing plate (22).

2. The numerical control machining die with the telescopic mechanism as claimed in claim 1, wherein: the first supporting rod (11) is connected with the sliding groove (8) in a sliding mode through a first sliding block (12) to form a sliding mechanism.

3. The numerical control machining die with the telescopic mechanism as claimed in claim 1, wherein: the clamping rod (10) is connected with the first sliding block (12) through the first spring (13) to form a telescopic mechanism, and the clamping rod (10) is connected with the second clamping groove (7) in a clamping mode to form a clamping mechanism.

4. The numerical control machining die with the telescopic mechanism as claimed in claim 1, wherein: the second connecting rod (16) is connected with the second sleeve (6) through a second spring (15) to form a telescopic mechanism, and the second connecting rod (16) is connected with the first clamping groove (5) in a clamping mode to form a clamping mechanism.

5. The numerical control machining die with the telescopic mechanism as claimed in claim 1, wherein: the third connecting rod (19) is rotatably connected with the third sleeve (18) through a hinge shaft to form a rotating mechanism, the third sleeve (18) is connected with the fourth connecting rod (25) through a fourth spring (26) to form a telescopic mechanism, and the fourth connecting rod (25) is slidably connected with the sliding rail (24) through a second sliding block (23) to form a sliding mechanism.

6. The numerical control machining die with the telescopic mechanism as claimed in claim 1, wherein: the first connecting rod (1) is connected with the first sleeve (2) through a third spring (20) to form a telescopic mechanism.

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