CN220534186U - Large-capacity blade access device for numerical control blade management equipment - Google Patents

Abstract

The utility model relates to a high-capacity blade storing and taking device for numerical control blade management equipment, which comprises a blade storing mechanism, wherein the blade storing mechanism comprises a plurality of blade storing boxes which are stacked according to the height, a plurality of rows of corresponding blade storing grooves are arranged on the bottom surfaces of the blade storing boxes side by side, corresponding numerical control blades are respectively stored in the blade storing grooves, the numerical control blades in the blade storing grooves of the upper blade storing box are supported by the next blade storing box, and the blade storing grooves of the blade storing boxes positioned at the bottom end are sealed by corresponding sealing mechanisms; the blade output mechanism comprises a blocking pushing piece used for pushing the sealing mechanism and a driving mechanism used for driving the blocking pushing piece to move back and forth, at least one blanking notch is arranged on one side of the outer end of the blocking pushing piece, and the number of the blanking notches is smaller than the number of rows of the cutter storage grooves. The utility model can effectively and greatly improve the storage capacity of the numerical control blade and reduce the mechanical abrasion during the output of the numerical control blade.

Description

Large-capacity blade access device for numerical control blade management equipment

Technical Field

The utility model relates to the technical field of numerical control blade warehouse management equipment, in particular to a high-capacity blade access device for numerical control blade management equipment.

Background

The general size of the numerical control blade is smaller, most of numerical control blades used in a traditional processing plant are stored through corresponding blade storage cabinets, and processing staff can select the numerical control blade required by the processing staff in the blade storage cabinets according to use requirements, so that management is disordered.

In order to improve the warehouse management effect of the numerical control blade, intelligent warehouse management equipment of the intelligent numerical control blade is put into use. The blade storing and taking device is one of the most main components of the numerical control blade management equipment, stores the numerical control blades by hands, takes out the blades under the drive of the corresponding blade taking mechanism, and conveys the numerical control blades after taking out the blades to the corresponding designated positions through the corresponding conveying mechanism, so that the numerical control blades are convenient for workers to take. The storage capacity of the numerical control blade of the blade storing and taking device for the existing numerical control blade management equipment is relatively less, the supplementing times of the blade are more frequent in the use process, and the blade is easy to mechanically abrade the numerical control blade by the blade taking mechanism in the blade taking process, so that the quality of the numerical control blade is influenced.

Therefore, the design of the large-capacity blade storing and taking device for the numerical control blade management equipment, which can effectively and obviously improve the storage capacity of the numerical control blade, thereby reducing the number of blade replenishment times and reducing the mechanical abrasion of the numerical control blade in the blade taking process, is a research aim of the utility model.

Disclosure of Invention

The present utility model is directed to a large-capacity blade access device for a nc blade management device, which can effectively solve the technical problems of the prior art.

The technical scheme of the utility model is as follows:

a large-capacity blade access device for a numerical control blade management device comprises

The cutter blade storage mechanism comprises a plurality of cutter storage boxes which are stacked according to the height, wherein the upper cutter storage box and the lower cutter storage box can move in an internal and external direction, a plurality of rows of corresponding cutter storage grooves are formed in the bottom surface of each cutter storage box side by side, corresponding numerical control blades are respectively stored in the cutter storage grooves, the numerical control blades in the cutter storage grooves of the upper cutter storage box are supported by the next cutter storage box, the cutter storage grooves of the cutter storage boxes at the bottom end are closed by corresponding closing mechanisms, and the closing mechanisms and the cutter storage boxes at the bottom end can move in an internal and external direction;

the blade output mechanism comprises a blocking pushing piece used for pushing the sealing mechanism and a driving mechanism used for driving the blocking pushing piece to move back and forth, at least one blanking notch is arranged on one side of the outer end of the blocking pushing piece, and the number of the blanking notches is smaller than the number of rows of the cutter storage grooves.

Two rows of corresponding cutter storage grooves are arranged on the bottom surface of the cutter storage box side by side, and a blanking notch is formed in one side of the outer end of the blocking pushing piece.

The blade containing mechanism is fixedly arranged in the corresponding containing cavity, and communication holes for the blocking pushing piece and the sealing mechanism to pass through are respectively formed in the inner side and the outer side of the bottom of the containing cavity.

The sealing mechanism is a cutter storage box which is used for not receiving the numerical control blade in the cutter storage groove.

The bottom both sides of storing up the sword box are provided with corresponding spout respectively indent, store up the top both sides of sword box respectively upwards be provided with the reverse L shape draw-in groove of spout looks adaptation, between two upper and lower storing up sword boxes, the spout of last storing up sword box is movable to insert on the reverse L shape draw-in groove of next storing up sword box.

The reverse L-shaped clamping grooves of the cutter storage boxes are respectively and integrally formed and outwards provided with corresponding gear convex edges, the gear convex edges extend to the outer sides of the cutter storage boxes, and the outer sides of the bottom ends of the upper cutter storage box and the lower cutter storage box are abutted to the gear convex edges of the next cutter storage box.

The top of the inverted L-shaped clamping groove of the cutter storage box is internally provided with a plurality of abutting blocks which are arranged at intervals in an integrated mode, and the abutting blocks on the inverted L-shaped clamping groove are abutted to the sliding groove in an interference fit mode.

The inner side of the top of the inverted L-shaped clamping groove of the cutter storage box is respectively and outwards provided with a corresponding abdication chamfer, and a chute of the upper cutter storage box is movably inserted into the inverted L-shaped clamping groove of the next cutter storage box through the abdication chamfer between the upper cutter storage box and the lower cutter storage box.

The driving mechanism adopts an electric push rod, a corresponding installation seat is arranged on the position of the blocking push rod corresponding to the electric push rod, the push rod end of the electric push rod is fixedly connected to the installation seat, the blocking push rod is internally fixedly connected with a corresponding grating ruler, and one side of the grating ruler is provided with a transmission type grating sensor corresponding to the grating ruler.

The utility model has the advantages that:

1) The blade storage mechanism comprises a plurality of blade storage boxes which are stacked according to the height, wherein the bottom surfaces of the blade storage boxes are provided with a plurality of rows of corresponding blade storage grooves side by side, and in the use process, numerical control blades can be stored in the blade storage grooves of the blade storage boxes, so that the storage quantity of the numerical control blades can be effectively and obviously improved, and the number of blade replenishment times is reduced.

After the cutter storage groove of the cutter storage box is used for storing the digital blades, the cutter output mechanism is further adaptively designed, and comprises a blocking and pushing piece used for pushing the sealing mechanism of the cutter storage mechanism and a driving mechanism used for driving the blocking and pushing piece to move back and forth, wherein one side of the outer end of the blocking and pushing piece is provided with at least one blanking notch, and the number of the blanking notches is smaller than the row number of the cutter storage groove. In the cutter discharging process: the blocking pushing piece is driven to move outwards through the driving mechanism, so that the sealing mechanism is pushed outwards by the blocking pushing piece, and the numerical control blade in the cutter storage groove corresponding to the blanking notch of the blocking pushing piece is output by the cutter storage box at the bottom end through the blanking notch of the blocking pushing piece; after the closing mechanism is pushed to leave the cutter storage box at the bottom end, all the numerical control blades in the cutter storage groove corresponding to the blanking notch are output, and the numerical control blades in the cutter storage groove not corresponding to the blanking notch are blocked by the blocking pushing piece; and then, the driving mechanism drives the blocking pushing piece to move inwards, the rest numerical control blades in the cutter storage groove of the cutter storage box at the bottom end are output through the outer side of the blocking pushing piece, and after the blocking pushing piece leaves the bottom of the cutter storage box, the cutter storage box at the bottom descends by the thickness of one cutter storage box and is used as a sealing mechanism. Therefore, the utility model can effectively maintain the accurate control of the output of the blade on the basis of greatly improving the storage capacity of the blade.

2) In the cutter discharging process, the cutter is discharged: the blocking pushing piece is mainly used for driving the sealing mechanism (the cutter storage box without the numerical control blades) outwards, so that the numerical control blades in the cutter storage grooves corresponding to the blanking gaps can be output, and then the blocking pushing piece is used for blocking the numerical control blades in the cutter storage grooves in the other row; and in the resetting process of the blocking pushing piece, the blocking of the numerical control blades can be gradually released, so that the numerical control blades in the cutter storage groove which do not correspond to the blanking notch can be output one by one. The whole numerical control blade output process is that the numerical control blade is not subjected to obvious mechanical friction, so that the mechanical abrasion to the numerical control blade is reduced, and the quality of the numerical control blade after output is effectively ensured while the storage capacity of the numerical control blade is greatly improved and the high-precision quantitative output of the numerical control blade is realized.

3) Corresponding sliding grooves are respectively concavely formed in two sides of the bottom of the cutter storage box, inverted L-shaped clamping grooves matched with the sliding grooves are respectively formed in two sides of the top of the cutter storage box, the sliding groove of the upper cutter storage box is movably inserted into the inverted L-shaped clamping groove of the next cutter storage box, and the outer side of the bottom end of the upper cutter storage box is abutted to the gear convex edge of the next cutter storage box. Therefore, on the premise of not affecting the pushing driving of the cutter storage box, more stable stacking assembly can be formed on the cutter storage box, so that the numerical control cutter can be quickly and stably stored, and the cutter storage box after stacking assembly can be quickly and stably arranged in the corresponding accommodating cavity, so that the practical effect of the numerical control cutter is further improved.

4) The top of the inverted L-shaped clamping groove of the cutter storage box is respectively and integrally formed and inwards provided with a plurality of abutting blocks which are arranged at intervals, and the abutting blocks on the inverted L-shaped clamping groove are respectively abutted to the corresponding sliding grooves of the cutter storage box in an interference fit mode. Under the propping of the propping blocks which are arranged at intervals, the movement quantity of the propping blocks is effectively prevented from being larger than the pushing quantity of the blocking pushing piece due to the self inertia force of the knife storage box; and the abutting blocks are staggered, so that excessive abrasion between the abutting blocks and the sliding grooves of the cutter storage box caused by excessive friction force is prevented.

5) The inner sides of the tops of the inverted L-shaped clamping grooves of the cutter storage boxes are respectively provided with corresponding abdication chamfers outwards, and a chute of the upper cutter storage box is movably inserted into the inverted L-shaped clamping groove of the next cutter storage box through the abdication chamfers between the upper cutter storage box and the lower cutter storage box. The setting of the abdication chamfer is used for preventing the overlarge assembly difficulty between two adjacent cutter storage boxes caused by the setting of the propping block, so that the practical effect of the cutter storage box is effectively and greatly improved.

6) The driving mechanism of the utility model adopts an electric push rod, the blocking push piece is provided with an installation seat at a position corresponding to the electric push rod, the push rod end of the electric push rod is fixedly connected to the installation seat, the blocking push piece is fixedly connected with a grating ruler inwards, and one side of the grating ruler is provided with a transmission type grating sensor corresponding to the grating ruler. The position of the grating ruler is detected by the transmission type grating sensor, so that the displacement of the electric push rod is effectively and accurately controlled in real time, and the practical effect of the utility model is further ensured.

Drawings

Fig. 1 is a schematic structural view of the present utility model.

Fig. 2 is a schematic structural view of the magazine.

Fig. 3 is a schematic view of the bottom side structure of the magazine.

Fig. 4 is a schematic structural view of the blade output mechanism.

Fig. 5 is a use state diagram of the present utility model.

Fig. 6 is a partial enlarged view of fig. 5.

Detailed Description

For the convenience of understanding by those skilled in the art, the structure of the present utility model will now be described in further detail with reference to the accompanying drawings:

referring to FIGS. 1-6, a large-capacity blade access device for a CNC blade management apparatus includes

The cutter blade storage mechanism comprises a plurality of cutter storage boxes 1 which are stacked according to the height, wherein the upper cutter storage box 1 and the lower cutter storage box 1 can move in an internal and external direction, two rows of corresponding cutter storage grooves 101 are arranged on the bottom surface of the cutter storage boxes 1 side by side, corresponding numerical control blades are respectively stored in the cutter storage grooves 101, the numerical control blades in the cutter storage grooves 101 of the upper cutter storage box 1 are supported by the next cutter storage box 1, the cutter storage 101 grooves of the cutter storage boxes 1 positioned at the bottom end are closed by corresponding closing mechanisms, and the closing mechanisms and the cutter storage boxes 1 positioned at the bottom end can move in an internal and external direction;

the blade output mechanism comprises a blocking pushing piece 2 used for pushing the sealing mechanism and a driving mechanism 3 used for driving the blocking pushing piece 2 to move back and forth, a blanking notch 201 is arranged on one side of the outer end of the blocking pushing piece 2, and the number of the blanking notches 201 is smaller than the number of rows of the cutter storage grooves 101.

The blade receiving mechanism is fixedly arranged in the corresponding receiving cavity 12, and communication holes for the blocking push piece 2 and the sealing mechanism to pass through are respectively arranged on the inner side and the outer side of the bottom of the receiving cavity 12.

The sealing mechanism is a cutter storage box 1 which is used for storing the numerical control cutter in the cutter storage groove 101.

The blade storage mechanism comprises a plurality of blade storage boxes 1 which are stacked according to the height, wherein a plurality of rows of corresponding blade storage grooves 101 are arranged on the bottom surface of each blade storage box 1 side by side, and in the use process, numerical control blades can be stored in the blade storage grooves 101 of each blade storage box 1, so that the storage quantity of the numerical control blades can be effectively and obviously improved, and the number of blade replenishment times can be reduced.

In the cutter discharging process: the blocking pushing piece 2 is driven to move outwards through the driving mechanism 3, so that the closing mechanism is pushed outwards by the blocking pushing piece 2, and the numerical control blade in the cutter storage groove 101 corresponding to the blanking notch 201 of the blocking pushing piece 2 is output by the cutter storage box 1 at the bottom end through the blanking notch 201 of the blocking pushing piece 2; after the closing mechanism is pushed to leave the cutter storage box 1 at the bottom end, all the numerical control blades in the cutter storage groove 101 corresponding to the blanking notch 201 are output, and the numerical control blades in the cutter storage groove 101 not corresponding to the blanking notch 201 are blocked by the blocking pushing piece 2; then, the driving mechanism 3 drives the blocking pushing piece 2 to move inwards, the rest numerical control blades in the cutter storage groove 101 of the cutter storage box 1 at the bottom end are output through the outer side of the blocking pushing piece 2, and after the blocking pushing piece 2 leaves the bottom of the cutter storage box 1, the cutter storage box 1 at the bottom descends by one thickness of the cutter storage box 1 and is used as a sealing mechanism. Therefore, the utility model can effectively maintain the accurate control of the output of the blade on the basis of greatly improving the storage capacity of the blade.

In the cutter discharging process, the cutter is discharged: the blocking pushing piece 2 is mainly used for driving the sealing mechanism (a cutter storage box without numerical control blades) outwards, so that the numerical control blades in the cutter storage groove 101 corresponding to the blanking notch 201 can be output, and then the blocking pushing piece 2 is used for blocking the numerical control blades in the cutter storage groove 101 of the other row; in the resetting process of the blocking push piece 2, the blocking of the numerical control blades can be gradually released, so that the numerical control blades in the cutter storage groove 101 which do not correspond to the blanking notch 201 can be output one by one. The whole numerical control blade output process is that the numerical control blade is not subjected to obvious mechanical friction, so that the mechanical abrasion to the numerical control blade is reduced, and the quality of the numerical control blade after output is effectively ensured while the storage capacity of the numerical control blade is greatly improved and the high-precision quantitative output of the numerical control blade is realized.

The bottom both sides of storing up sword box 1 indent respectively are provided with corresponding spout 4, store up the top both sides of sword box 1 respectively upwards be provided with the reverse L shape draw-in groove 5 of spout 4 looks adaptation, between two upper and lower storing up sword box 1, the spout 4 of last storing up sword box 1 is movable to insert on the reverse L shape draw-in groove 5 of next storing up sword box 1.

The cutter storage box comprises a cutter storage box body 1, a cutter storage box body 1 and a cutter storage box body, wherein corresponding gear convex edges 6 are outwards arranged between inverted L-shaped clamping grooves 5 of the cutter storage box body 1 in an integrated mode, the gear convex edges 6 extend to the outer sides of the cutter storage box bodies 1, between an upper cutter storage box body 1 and a lower cutter storage box body 1, the outer sides of the bottom ends of the upper cutter storage box body 1 are abutted to the gear convex edges 6 of the next cutter storage box body 1.

Under the action of the gear convex edge 6, the utility model can form more stable stacking assembly for the cutter storage box 1 on the premise of not influencing the pushing and driving of the cutter storage box 1, so that the numerical control cutter can be quickly and stably stored, and the cutter storage box 1 after stacking assembly can be quickly and stably arranged in the corresponding accommodating cavity 12.

The top of the reverse L-shaped clamping groove 5 of the cutter storage box 1 is internally provided with a plurality of abutting blocks 7 which are arranged at intervals in an integrated mode, and the abutting blocks 7 on the reverse L-shaped clamping groove 5 are abutted to the sliding groove 4 in an interference fit mode.

Under the propping of the propping blocks 7 which are arranged at intervals, the movement quantity of the cutter storage box 1 caused by the self inertia force of the cutter storage box is effectively prevented from being larger than the pushing quantity of the blocking pushing piece 2; and the abutting blocks 7 are staggered, so that excessive abrasion between the abutting blocks 7 and the sliding groove 4 of the cutter storage box 1 caused by excessive friction force is prevented.

The inner sides of the tops of the inverted L-shaped clamping grooves 5 of the cutter storage boxes 1 are respectively and outwards provided with corresponding abdication chamfers 8, and a chute 4 of the upper cutter storage box 1 is movably inserted into the inverted L-shaped clamping groove 5 of the next cutter storage box 1 through the abdication chamfers 8 between the upper cutter storage box 1 and the lower cutter storage box 1.

The setting of the abdication chamfer 8 is used for preventing the overlarge assembly difficulty between two adjacent cutter storage boxes 1 caused by the setting of the abutting blocks 7, so that the practical effect of the cutter storage box is effectively and greatly improved.

The driving mechanism 3 adopts an electric push rod, the blocking push piece 2 is provided with a corresponding mounting seat 9 at a position corresponding to the electric push rod, the push rod end of the electric push rod is fixedly connected to the mounting seat 9, the blocking push piece 2 is internally fixedly connected with a corresponding grating ruler 10, and one side of the grating ruler is provided with a transmission type grating sensor 11 corresponding to the grating ruler.

The position of the grating ruler 10 is detected by the transmission type grating sensor 11, so that the displacement of the electric push rod is effectively and accurately controlled in real time, and the practical effect of the utility model is further ensured.

The specific use method of the utility model comprises the following specific steps:

s1, purchasing various types of numerical control blades required by machining according to machining requirements of machining parts, inverting the cutter storage boxes 1, storing the various types of numerical control blades in cutter storage grooves 101 of the cutter storage boxes 1 in a classified mode, and then movably buckling the corresponding cutter storage boxes 1 together through the inverted L-shaped clamping grooves 5 to be stacked and installed through matching with corresponding sliding grooves 4, wherein the cutter storage box 1 at the uppermost part is not provided with the numerical control blades to be used as a sealing mechanism;

s2, turning over the stacked and mounted knife storing boxes 1, and fixedly stacking the knife storing boxes in the accommodating cavity 12;

s4, starting the driving mechanism 3 to drive the blocking pushing piece 2 to move the length of one cutter storage groove 101, so that the numerical control cutter in the corresponding cutter storage groove 101 is output along the blanking notch 201;

s5, as the blocking pushing piece 2 moves outwards, the sealing mechanism is pushed outwards by the blocking pushing piece 2, and after all the numerical control blades in the row of cutter storage grooves 101 corresponding to the blanking notch 201 of the blocking pushing piece 2 are output, the cutter storage box 1 at the bottom end is pushed to leave the accommodating cavity 12;

s6, after the closing mechanism is pushed to leave the accommodating cavity 12, the blocking pushing piece 2 moves inwards, the numerical control blades accommodated in the other row of cutter storage grooves 101 are output one by one, and after the blocking pushing piece 2 leaves the bottom of the cutter storage box 1, the cutter storage box 1 positioned at the bottom descends by the thickness of one cutter storage box 1 and is used as the closing mechanism.

The foregoing is merely a preferred embodiment of the present utility model and it should be noted that modifications and adaptations to those skilled in the art may be made without departing from the principles of the present utility model, which are intended to be comprehended within the scope of the present utility model.

Claims (9)

1. A large-capacity blade access device for numerical control blade management equipment is characterized in that: comprising

The cutter blade storage mechanism comprises a plurality of cutter storage boxes (1) which are stacked according to the height, wherein the cutter storage boxes (1) at the bottom and the cutter storage boxes (1) can move in an internal and external direction, a plurality of rows of corresponding cutter storage grooves (101) are arranged on the bottom surface of the cutter storage boxes (1) side by side, corresponding numerical control blades are respectively stored in the cutter storage grooves (101), the numerical control blades in the cutter storage grooves (101) of the cutter storage box (1) at the top are supported by the cutter storage box (1) at the bottom, the cutter storage grooves (101) of the cutter storage boxes (1) at the bottom are closed by corresponding closing mechanisms, and the cutter storage boxes (1) at the bottom can move in the internal and external directions;

the blade output mechanism comprises a blocking pushing piece (2) used for pushing the sealing mechanism and a driving mechanism (3) used for driving the blocking pushing piece (2) to move back and forth, at least one blanking notch (201) is arranged on one side of the outer end of the blocking pushing piece (2), and the number of the blanking notches (201) is smaller than the number of rows of the cutter storage grooves (101).

2. The large-capacity blade access device for a numerical control blade management apparatus according to claim 1, wherein: two rows of corresponding cutter storage grooves (101) are formed in the bottom surface of the cutter storage box (1) side by side, and a blanking notch (201) is formed in one side of the outer end of the blocking pushing piece (2).

3. The large-capacity blade access device for a numerical control blade management apparatus according to claim 1, wherein: the blade containing mechanism is fixedly arranged in a corresponding containing cavity (12), and communication holes for the blocking pushing piece (2) and the closing mechanism to pass through are respectively formed in the inner side and the outer side of the bottom of the containing cavity (12).

4. The large-capacity blade access device for a numerical control blade management apparatus according to claim 1, wherein: the sealing mechanism is a cutter storage box (1) which is used for storing the numerical control cutter in the cutter storage groove (101).

5. The large-capacity blade access device for a numerical control blade management apparatus according to claim 1, wherein: the utility model discloses a knife storing device, including knife storing box (1), upper and lower two knife storing box (1), bottom both sides indent respectively are provided with corresponding spout (4), and the top both sides of knife storing box (1) upwards be provided with respectively with the reverse L shape draw-in groove (5) of spout (4) looks adaptation, between two knife storing box (1) about, but the spout (4) movable plug-in connection of last knife storing box (1) is to on the reverse L shape draw-in groove (5) of next knife storing box (1).

6. The large-capacity blade access device for a digital blade management apparatus according to claim 5, wherein: the novel knife storing device is characterized in that corresponding gear convex edges (6) are outwards arranged between the inverted L-shaped clamping grooves (5) of the knife storing boxes (1) in an integrated mode, the gear convex edges (6) extend to the outer sides of the knife storing boxes (1), and the outer sides of the bottom ends of the upper knife storing box (1) are abutted to the gear convex edges (6) of the lower knife storing box (1) between the upper knife storing box and the lower knife storing box (1).

7. The large-capacity blade access device for a digital blade management apparatus according to claim 6, wherein: the top of the inverted L-shaped clamping groove (5) of the cutter storage box (1) is internally provided with a plurality of abutting blocks (7) which are arranged at intervals in an integrated mode, and the abutting blocks (7) on the inverted L-shaped clamping groove (5) are abutted to the sliding groove (4) in an interference fit mode.

8. The large-capacity blade access device for a digital blade management apparatus according to claim 7, wherein: the inner side of the top of the inverted L-shaped clamping groove (5) of the cutter storage box (1) is respectively and outwards provided with a corresponding abdication chamfer (8), and a chute (4) of the upper cutter storage box (1) is movably inserted into the inverted L-shaped clamping groove (5) of the next cutter storage box (1) through the abdication chamfer (8) between the upper cutter storage box and the lower cutter storage box (1).

9. The large-capacity blade access device for a numerical control blade management apparatus according to claim 1, wherein: the driving mechanism (3) adopts an electric push rod, the blocking push piece (2) is provided with a corresponding mounting seat (9) at a position corresponding to the electric push rod, the push rod end of the electric push rod is fixedly connected to the mounting seat (9), the blocking push piece (2) is internally fixedly connected with a corresponding grating ruler (10), and one side of the grating ruler is provided with a transmission type grating sensor (11) corresponding to the grating ruler.