CN215880949U - Cutter support for vertical numerical control machining center - Google Patents

Abstract

The utility model relates to the technical field of cutter supports of numerical control machining centers, and discloses a cutter support for a vertical numerical control machining center, which comprises a base, a bearing plate and a placing cavity, wherein the bearing plate is movably connected with the base through a cleaning mechanism, the cleaning mechanism comprises an air inlet hole, a rotating plate, a pushing plate, a vertical shaft, a connecting plate and balls, the air inlet hole is a hollow cylinder with a closed bottom, the air inlet hole is formed in the circumferential surface of the base, the balls are rotatably connected with the connecting plate, the connecting plate is fixedly connected with the rotating plate, the balls are in rolling connection with the inner bottom surface of the base, when a cutter is selected, the bearing plate is pushed to drive the connecting plate on the bottom surface of the rotating plate to rotate, the balls roll on the bottom surface of the base, the pushing plate is driven to rotate the pushing plate through the rotating plate to push the air in the cavity of the base upwards, the air in the base is pushed upwards to blow towards the cutter placed on the bearing plate, and metal chips and cutting fluid adhered to the used cutter are blown away from the cutter, the cleaning effect of the used cutter is improved.

Description

Cutter support for vertical numerical control machining center

Technical Field

The utility model relates to the technical field of vertical numerical control machining center cutter supports, in particular to a cutter support for a vertical numerical control machining center.

Background

The prior art discloses a cutter placing device (CN201920316823.3) of a numerical control machining center, which comprises a fixed support, wherein one end of the bottom end of a supporting table, which is far away from a first moving wheel, is fixedly provided with a second moving wheel, the left side of the top end of the supporting table is fixedly connected with a first supporting column, one end of the top end of the supporting table, which is far away from the first supporting column, is fixedly connected with a second supporting column, one ends of the first supporting column and the second supporting column, which are far away from the supporting table, are fixedly connected with a rotary placing table, one end of the rotary placing table, which is far away from the first cutter placing seat, is fixedly connected with a second cutter placing seat, the rotary placing table, the first cutter placing seat and the second cutter placing seat are all provided with cutter placing grooves, the device can rotate, an operator can place cutters conveniently, and the rotary placing table is provided with the first cutter placing seat and the second cutter placing seat can classify the cutters, the cutter support is simple and convenient to use, metal chips and cutting fluid can be adhered to the surface of the cutter after the cutter is machined, and the chips and the cutting fluid on the surface of the cutter cannot be cleaned in time and are accumulated in the placing cavity, so that the cutter support is not beneficial to next use, and the cutter support for the vertical numerical control machining center is needed to be provided.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

Aiming at the defects of the prior art, the utility model provides a cutter bracket for a vertical numerical control machining center.

(II) technical scheme

In order to achieve the purpose, the utility model provides the following technical scheme: the utility model provides a vertical cutter support for numerical control machining center, includes base, loading board and places the chamber, and the top surface of loading board is seted up and is placed the chamber, loading board and base swing joint, the loading board passes through clearance mechanism and base swing joint, clearance mechanism includes inlet port, rotor plate, slurcam, vertical axis, connecting plate and ball, the inlet port is bottom confined hollow cylinder, and the inlet port is seted up to the periphery of base, the ball rotates with the connecting plate to be connected and connecting plate and rotor plate fixed connection, the interior bottom surface roll connection of ball and base, slurcam and vertical axis fixed connection just slurcam and rotor plate fixed connection, the top surface fixed connection of loading board and rotor plate.

Preferably, the rotor plate is the annular board of circle and rotor plate and base adaptation, the slurcam is the slope setting of rectangular plate and slurcam, and the quantity of slurcam is four and four slurcams equidistant setting in the interior circumference of rotor plate.

Preferably, the connecting plate is an arc-shaped plate and is fixedly connected with the bottom surface of the rotating plate, the arc surface of the connecting plate is flush with the outer circumferential surface of the rotating plate, and the number of the connecting plates is two, and the two connecting plates are symmetrically arranged.

Preferably, the cleaning mechanism further comprises a collecting groove, a first permanent magnet, a spring, an air guide groove and a second permanent magnet, the collecting groove is formed in the top surface of the bearing plate, the air guide groove is formed in the bottom surface of the bearing plate, the first permanent magnet is located in the placing cavity, one end of the spring is fixedly connected with the first permanent magnet, the other end of the spring is fixedly connected with the bearing plate, and the second permanent magnet is fixedly connected with the bearing plate.

Preferably, the bottom surface of the placing cavity is obliquely arranged, the air guide groove is communicated with the collecting groove through the placing cavity, the second permanent magnet is an annular magnet and is located in the collecting groove, and the second permanent magnet is fixedly connected with the inner wall surface of the bearing plate.

(III) advantageous effects

Compared with the prior art, the utility model provides a cutter support for a vertical numerical control machining center, which has the following beneficial effects:

1. this vertical cutter support for numerical control machining center, through when selecting the cutter, it is rotatory to promote the connecting plate that the loading board drove the rotor plate bottom surface, and the ball rolls in the base bottom surface, drives the gaseous upwards promotion of slurcam rotation in with the base intracavity through the rotor plate, blows the cutter of placing on the loading board through upwards promoting the gaseous in the base, blows off the cutter with the metal piece and the cutting fluid of adhesion on the cutter after will using, improves the cleaning performance to the cutter after using.

2. This vertical cutter support for numerical control machining center, when choosing the cutter through promoting the loading board is rotatory, gaseous promotion in with the base to the catch bar on the rotor plate is in the entering of air guide groove and is placed the intracavity, a permanent magnet adsorbs cutter and downward compression spring, through from air guide groove get into place the intracavity gas with the metal and the cutting fluid of adhesion on the cutter blow off the cutter and fall into and place the intracavity, metal piece is adsorbed by permanent magnet one and permanent magnet two, the cutting fluid is collected in the collecting vat, the separation effect to piece and cutting fluid is improved.

3. This vertical cutter support for numerical control machining center through setting up permanent magnet one, spring and permanent magnet two, in time blows the piece away from the cutter, avoids cutter and loading board to form rigid connection, better protection cutter, reduces the unnecessary fish tail.

Drawings

FIG. 1 is an exploded view of the present invention;

FIG. 2 is a schematic perspective view of the connecting plate and the rotating plate according to the present invention;

FIG. 3 is a schematic cross-sectional view of a carrier plate according to the present invention.

In the figure: 10. a base; 11. an air inlet; 12. a rotating plate; 13. a push plate; 14. a vertical axis; 15. A connecting plate; 16. a ball bearing; 17. a carrier plate; 18. a placement chamber; 19. collecting tank; 20. a first permanent magnet; 21. a spring; 22. a gas guide groove; 23. and a second permanent magnet.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-3, a cutter holder for a vertical numerical control machining center comprises a base 10, a bearing plate 17 and a placing cavity 18, wherein the placing cavity 18 is formed on the top surface of the bearing plate 17, the bearing plate 17 is movably connected with the base 10 through a cleaning mechanism, the cleaning mechanism comprises an air inlet hole 11, a rotating plate 12, a pushing plate 13, a vertical shaft 14, a connecting plate 15 and balls 16, the air inlet hole 11 is a hollow cylinder with a closed bottom, the circumferential surface of the base 10 is provided with an air inlet hole 11, the balls 16 are rotatably connected with the connecting plate 15, the connecting plate 15 is fixedly connected with the rotating plate 12, the balls 16 are in rolling connection with the inner bottom surface of the base 10, the pushing plate 13 is fixedly connected with the vertical shaft 14, the pushing plate 13 is fixedly connected with the rotating plate 12, the bearing plate 17 is fixedly connected with the top surface of the rotating plate 12, when a cutter is selected, the bearing plate 17 is pushed to drive the connecting plate 15 on the bottom surface of the rotating plate 12 to rotate, the ball 16 rolls on the bottom surface of the base 10, the rotating plate 12 drives the pushing plate 13 to rotate to push the gas in the cavity of the base 10 upwards, the gas in the base 10 is pushed upwards to blow the cutter placed on the bearing plate 17, metal chips and cutting fluid adhered to the used cutter are blown away from the cutter, and the cleaning effect on the used cutter is improved.

The rotating plate 12 is a circular ring-shaped plate, the rotating plate 12 is matched with the base 10, the pushing plates 13 are rectangular plates, the pushing plates 13 are obliquely arranged, the number of the pushing plates 13 is four, four pushing plates 13 are arranged on the inner circumferential surface of the rotating plate 12 at equal intervals, the connecting plates 15 are arc-shaped plates, the connecting plates 15 are fixedly connected with the bottom surface of the rotating plate 12, the arc surfaces of the connecting plates 15 are flush with the outer circumferential surface of the rotating plate 12, the number of the connecting plates 15 is two, two connecting plates 15 are symmetrically arranged, the cleaning mechanism further comprises a collecting groove 19, a first permanent magnet 20, a spring 21, an air guide groove 22 and a second permanent magnet 23, the collecting groove 19 is formed in the top surface of the bearing plate 17, an air guide groove 22 is formed in the bottom surface of the bearing plate 17, the first permanent magnet 20 is positioned in the placing cavity 18, one end of the spring 21 is fixedly connected with the first permanent magnet 20, the other end of the spring 21 is fixedly connected with the bearing plate 17, and the second permanent magnet 23 is fixedly connected with the bearing plate 17, place the bottom surface slope setting of chamber 18, air guide groove 22 is through placing chamber 18 and collecting vat 19 intercommunication, two 23 of permanent magnet are annular magnet and two 23 of permanent magnet are located the collecting vat 19, two 23 of permanent magnet and 17 internal face fixed connection of loading board, when choosing the cutter through promoting the rotatory choosing of loading board 17, gaseous promotion in base 10 of the last slurcam 13 of rotor plate 12 is to air guide groove 22 in getting into and place chamber 18, first 20 of permanent magnet adsorbs the cutter and compresses spring 21 downwards, through getting into from air guide groove 22 and placing the interior gas of chamber 18 and blow off the cutter with metal and the cutting fluid of adhesion on the cutter and fall into and place the chamber 18, metal piece is adsorbed by first 20 of permanent magnet and second 23 of permanent magnet, the cutting fluid is collected in collecting vat 19, improve the separation effect to piece and cutting fluid.

Through setting up permanent magnet one 20, spring 21 and permanent magnet two 23, in time blow away the cutter with the piece, avoid cutter and loading board 17 to form rigid connection, better protection cutter reduces unnecessary fish tail.

When the tool picking and selecting device is used, a tool is placed into the placing cavity 18, the first permanent magnet 20 adsorbs the tool and compresses the spring 21 downwards, when the bearing plate 17 is pushed to rotate to pick the tool, the bearing plate 17 drives the connecting plate 15 on the bottom surface of the rotating plate 12 to rotate, the balls 16 roll on the bottom surface of the base 10, the rotating plate 12 drives the pushing plate 13 to rotate to push gas in the cavity of the base 10 upwards, the gas pushes the gas into the gas guide groove 22 to enter the placing cavity 18, metal and cutting fluid adhered to the tool are blown away from the tool and fall into the placing cavity 18, metal debris is adsorbed by the first permanent magnet 20 and the second permanent magnet 23, and the cutting fluid is collected in the collecting groove 19.

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 utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. The utility model provides a vertical numerical control is cutter holder for machining center, includes base (10), loading board (17) and places chamber (18), and the top surface of loading board (17) is seted up and is placed chamber (18), loading board (17) and base (10) swing joint, its characterized in that: bearing board (17) are through clearance mechanism and base (10) swing joint, clearance mechanism includes inlet port (11), rotor plate (12), catch plate (13), vertical axis (14), connecting plate (15) and ball (16), inlet port (11) are the hollow cylinder of bottom confined, and inlet port (11) are seted up to the periphery of base (10), ball (16) rotate with connecting plate (15) and be connected and connecting plate (15) and rotor plate (12) fixed connection, ball (16) and the interior bottom surface roll connection of base (10), catch plate (13) and vertical axis (14) fixed connection and catch plate (13) and rotor plate (12) fixed connection, the top surface fixed connection of bearing board (17) and rotor plate (12).

2. The cutter holder for the vertical numerical control machining center according to claim 1, characterized in that: the rotating plate (12) is a circular ring-shaped plate, the rotating plate (12) is matched with the base (10), the pushing plate (13) is a rectangular plate and the pushing plate (13) is inclined, and the pushing plate (13) is arranged in the mode that the number of the pushing plate (13) is four and the four pushing plates (13) are arranged on the inner circumferential surface of the rotating plate (12) at equal intervals.

3. The cutter holder for the vertical numerical control machining center according to claim 2, characterized in that: the connecting plates (15) are arc-shaped plates, the connecting plates (15) are fixedly connected with the bottom surfaces of the rotating plates (12), the arc surfaces of the connecting plates (15) are flush with the outer circumferential surfaces of the rotating plates (12), the number of the connecting plates (15) is two, and the two connecting plates (15) are symmetrically arranged.

4. The cutter holder for the vertical numerical control machining center according to claim 3, characterized in that: the cleaning mechanism further comprises a collecting groove (19), a first permanent magnet (20), a spring (21), an air guide groove (22) and a second permanent magnet (23), wherein the collecting groove (19) is formed in the top surface of the bearing plate (17), the air guide groove (22) is formed in the bottom surface of the bearing plate (17), the first permanent magnet (20) is located in the placing cavity (18), one end of the spring (21) is fixedly connected with the first permanent magnet (20) and the other end of the spring (21) is fixedly connected with the bearing plate (17), and the second permanent magnet (23) is fixedly connected with the bearing plate (17).

5. The cutter holder for the vertical numerical control machining center according to claim 4, characterized in that: the bottom surface of the placing cavity (18) is obliquely arranged, the air guide groove (22) is communicated with the collecting groove (19) through the placing cavity (18), the second permanent magnet (23) is an annular magnet and is located in the collecting groove (19), and the second permanent magnet (23) is fixedly connected with the inner wall surface of the bearing plate (17).

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