CN220902678U - Mobile numerical control machining equipment - Google Patents

Abstract

The utility model discloses mobile numerical control machining equipment which comprises a fixed base, a machining table, a machining main shaft and a protective cover, wherein the machining table is in sliding connection with the fixed base through an X-axis sliding rail assembly; the protective cover is arranged on the processing table and is driven by the processing table to slide and displace; the protective cover is provided with two door plates which are opened and closed relatively, and the door plates are connected with the installation convex edge of the processing table in a sliding manner. The protective cover is arranged on the processing table, can slide and displace along with the processing table, and can provide enough processing space, and simultaneously effectively reduce the use of metal plates, thereby reducing the manufacturing cost of the protective cover, reducing the difficulty and cost of equipment in the transportation process and solving the technical problems in the prior art.

Description

Mobile numerical control machining equipment

Technical Field

The utility model relates to the field of numerical control machining center equipment, in particular to mobile numerical control machining equipment.

Background

The utility model discloses a numerical control lathe hidden centralized oil supply device as disclosed in China patent grant publication No. CN218856354U, wherein the numerical control lathe that shows has complete safety cover, the safety cover encloses into a processing space with the base of lathe, and the work piece carries out orderly processing operation as required in the processing space, obviously, the safety cover is fixed connection with the base of lathe, in other words, is relatively fixed relation of connection between safety cover and the base.

When the numerical control machining center equipment is designed according to the disclosed technology, the base of the large enough wrapping machining center equipment is needed for the protective cover, and the base structure outside the machining table is wrapped or covered, so that the sheet metal cost of the equipment in the manufacturing and production processes is greatly improved, and the larger protective cover also provides higher requirements for equipment transportation, and meanwhile, the transportation cost of the equipment is also improved.

Therefore, how to effectively reduce the sheet metal production and processing costs and ensure a space enough for the workpiece processing to be safe is one of the technical problems that the skilled in the art needs to solve.

Disclosure of utility model

In order to solve the technical problems in the prior art, the utility model aims to provide mobile numerical control machining equipment.

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

the utility model provides a portable numerical control machining equipment, includes unable adjustment base, processing platform, processing main shaft and safety cover, wherein:

The processing table is in sliding connection with the fixed base through an X-axis sliding rail assembly;

The protective cover is arranged on the processing table and is driven by the processing table to slide and displace;

the protective cover is provided with two door plates which are opened and closed relatively, and the door plates are connected with the installation convex edge of the processing table in a sliding manner.

Further preferred is: the protective cover is U-shaped, and the opening surface of the protective cover faces the processing main shaft;

The installation convex edge is the edge of one side of the processing table far away from the processing main shaft.

Further preferred is: the protective cover is provided with a front shell plate, and the front shell plate consists of a single shell plate and the door plate;

The single shell plate is fixed on the processing table;

The door plate is arranged between the single shell plate and the installation convex edge.

Further preferred is: the door plate is provided with a door plate sliding rail at one side of the installation convex edge, which faces to the single shell plate, and a door plate sliding block is arranged on the door plate;

the door plate sliding block is connected with the door plate sliding rail in a sliding way;

The door plate sliding rail and the X-axis sliding rail component are arranged in the same direction.

Further preferred is: the door plant is provided with the installation position of cooperation door plant slider assembly, the installation position is provided with the gasket.

Further preferred is: the gasket is provided with a mounting hole, and the mounting hole is a waist-shaped hole;

Four mounting holes are distributed in a matrix.

Further preferred is: the door plate sliding blocks are distributed at intervals along the direction of the door plate sliding rail.

Further preferred is: the door plate is provided with a limiting convex edge;

The limiting convex edge is L-shaped and abuts against the edge of the single shell plate to limit the displacement travel of the door plate.

After the technical scheme is adopted, compared with the background technology, the utility model has the following advantages:

The protective cover is arranged on the processing table, can slide and displace along with the processing table, and can provide enough processing space, and simultaneously effectively reduce the use of metal plates, thereby reducing the manufacturing cost of the protective cover, reducing the difficulty and cost of equipment in the transportation process and solving the technical problems in the prior art.

Drawings

Fig. 1 is a schematic perspective view of a structure of a mobile numerical control machining device according to an embodiment of the present utility model;

Fig. 2 is a front view of the structure shown in fig. 1;

FIG. 3 is a side view of the structure shown in FIG. 2;

FIG. 4 is an enlarged view of a portion of the structure of FIG. 1 taken along the X-axis;

FIG. 5 is an enlarged view of a portion of the structure of FIG. 1 in a Z-axis cross-section;

Fig. 6 is a schematic view of a door panel according to an embodiment of the present utility model.

The reference numerals in the above description are as follows:

10. A fixed base; 20. a processing table; 21. mounting the edge; 22. a door panel slide rail; 30. a portal frame; 40. machining a main shaft;

100. A protective cover; 110. a single shell plate; 120. a door panel; 121. a limit edge; 122. a door panel slide block; 123. a base portion; 124. a boss; 130. a side shell plate;

200. a gasket; 210. and (5) mounting holes.

Detailed Description

The protective cover is fixedly connected with the base relatively, the processing table for processing is slidably mounted on the base and is arranged in a processing space enclosed between the protective cover and the base, the protective cover needs a base of a large enough package processing center device, the package or the cover is provided with a base structure outside the processing table, the sheet metal cost of the device in the manufacturing and production processes is greatly improved, and the larger protective cover also provides higher requirements for the transportation of the device, and meanwhile the transportation cost of the device is also improved.

The inventor aims at the technical problems, and through the analysis of reasons, the inventor finds a mobile numerical control machining device which comprises a fixed base, a machining table, a machining main shaft and a protective cover, wherein:

The processing table is in sliding connection with the fixed base through an X-axis sliding rail assembly;

The protective cover is arranged on the processing table and is driven by the processing table to slide and displace;

the protective cover is provided with two door plates which are opened and closed relatively, and the door plates are connected with the installation convex edge of the processing table in a sliding manner.

Among the above-mentioned technical scheme, install the safety cover on the processing platform to can carry out sliding displacement along with the processing platform, when providing sufficient processing space, the effectual use that reduces the panel beating, thereby reduce the manufacturing cost of safety cover, also reduced the degree of difficulty and the cost of equipment in the transportation, solved the technical problem that exists among the prior art.

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

It should be noted that, in the present utility model, terms "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are all based on the orientation or positional relationship shown in the drawings, and are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the apparatus or element of the present utility model must have a specific orientation, and thus should not be construed as limiting the present utility model.

Examples

As shown in fig. 1, a mobile numerical control machining apparatus is a full-hood type numerical control machining apparatus, that is: the periphery of the processing area is provided with a shell, the shell is assembled into a protective cover 100 which can be opened or closed according to requirements, and the protective cover 100 can ensure the safety of peripheral equipment and personnel in the process of processing workpieces, and is suitable for processing scraps or workpieces with high risks; in this scheme, the safety cover 100 can carry out sliding displacement according to the setting of specific processing product, can also adjust according to the requirement of work piece when adapting to the course of working of cutter.

Referring to fig. 1 to 3, the mobile numerical control machining apparatus includes a fixed base 10, a machining table 20, an adjusting base, a gantry 30, a tool rest, a machining spindle 40, a tool magazine, and a control box. The fixed base 10 is internally provided with an X-axis sliding rail component, the processing table 20 is in sliding connection with the X-axis sliding rail component and can be used for adjusting the sliding displacement of the X-axis sliding rail component in the direction, the fixed base 10 is connected with a gantry seat, a Y-axis sliding rail component is arranged in the gantry seat, the gantry 30 is connected with the Y-axis sliding rail component, the gantry is used for adjusting the sliding displacement of the gantry seat in the direction, the gantry seat is provided with a Z-axis sliding rail component, the tool rest is in sliding connection with the Z-axis sliding rail component and can be used for adjusting the sliding displacement of the Z-axis sliding rail component in the direction, and lifting adjustment is realized. The processing main shaft 40 is installed on the knife rest, and the tool magazine is close to the planer-type seat sets up and cooperates with the processing main shaft 40 through the tool changing wall, realizes the required cutter change operation of operation process, the control box with the tool magazine sets up relatively, namely: is arranged on the other side of the gantry seat.

Referring to fig. 1 to 3, the fixing base 10 is vertically distributed with the gantry base and is in a T shape, the fixing base 10 has an upper opening, the X-axis sliding rail assembly is disposed along the X-axis direction, the X-axis sliding rail assembly includes a screw rod and a sliding rail that are disposed along the X-axis direction, the screw rod is driven by a motor, a screw rod sleeve and a sliding block are disposed at the bottom of the processing table 20, the screw rod sleeve is connected with the screw rod and is driven by the screw rod to displace along the setting direction of the screw rod, and the sliding block is slidably connected with the sliding rail, so that the processing table 20 can slidably displace along the X-axis direction; the top surface of portal seat has along Y axial installation lead screw and slide rail, the lead screw is driven by the motor, the bottom of portal frame 30 sets up screw sleeve and slider, screw sleeve is connected with the lead screw, and by the lead screw drive is followed the setting direction displacement of lead screw, the slider with slide rail sliding connection, then processing platform 20 can carry out sliding displacement along the Y axial. Also described are: the portal frame 30 is a U-shaped frame with an opening facing the portal seat, and the screw rod sleeve and the sliding block are arranged at the opening end of the portal frame 30; the Z axial slide rail assembly is two slide rails that set up relatively, the one end that the portal frame 30 kept away from the portal seat is fixed with the actuating cylinder, the output shaft of actuating cylinder passes portal frame 30 is connected with the knife rest, the output shaft of actuating cylinder sets up along the Z axial, namely: the driving oil cylinder drives the arrival station to perform lifting displacement adjustment in the portal frame 30 along the z-axis.

In summary, as shown in fig. 1 to 3, the processing table 20 is slidably connected to the fixed base 10 through an X-axis sliding rail assembly, so as to implement a reciprocating sliding displacement along the X-axis, so as to adapt to the processing requirement of the workpiece. It should be noted that: the processing table 20 is a platform capable of performing sliding displacement adjustment along the X axis, on which the protective cover 100 is mounted, and the protective cover 100 performs synchronous displacement along with the displacement of the processing table 20, so that the safety of the processing process is ensured while the sliding adjustment is ensured.

As shown in fig. 1 to 6, the protection cover 100 includes a front shell plate and two side shell plates 130, wherein the front shell plate has a J shape, and the left and right sides of the front shell plate are respectively connected with the two side shell plates 130. The specific method is as follows: the processing table 20 is rectangular, one long side is close to the portal frame 30, the other long side is a mounting side, the mounting side 21Z extends axially to obtain a mounting side 21, the mounting side 21 protrudes out of the processing table 20, and the front shell plate is fixed on the processing table 20 and is close to the mounting side 21; in more detail: the front shell plate comprises a single shell plate 110 and a door plate 120, the single shell plate 110 is fixed on the processing table 20, a gap exists between the single shell plate 110 and the installation edge 21, and the door plate 120 is arranged between the installation edge 21 and the single shell plate 110 and is in sliding connection with the installation edge 21 to realize the opening and closing of the door plate 120; it should be noted that: the number of the single-shell plates 110 is two, and further the number of the door plates 120 is two, the two single-shell plates 110 are symmetrically distributed and have a space, and the size of the space satisfies the opening and closing of the two door plates 120.

Referring to fig. 1 to 6, a door slide block 122 is fixed to the bottom edge of each door 120, the mounting edge 21 is provided with a door slide rail 22, the door slide rail 22 is disposed along the X axis, and the door slide block 122 is slidably connected with the door slide rail 22, so as to drive the door 120 to reciprocate along the direction of the door slide rail 22; the specific method is as follows: the door plate sliding rail 22 is disposed at one side of the mounting edge 21 facing the gantry, the number of the door plate sliding blocks 122 is plural, and the plurality of door plate sliding blocks 122 are disposed at intervals, so as to ensure stable sliding displacement of the door plate 120; also to be described is: the door plates 120 are provided with limiting convex edges, the limiting convex edges are L-shaped convex edges formed by bending the door plates 120 towards the direction of the single shell, the limiting convex edges are matched with the single shell to be propped against, the limiting of sliding displacement of the door plates 120 is achieved, and the maximum opening and closing degree of the two door plates 120 are determined.

Referring to fig. 1 to 6, the door panel 120 is a integrally cast plate body, that is: the door panel 120 includes a base portion 123 and a protruding portion 124 that are integrally connected, the protruding portion 124 protrudes toward the mounting edge 21, one side of the base portion 123, which is close to the processing table 20, is disposed in a gap between the single-shell plate 110 and the mounting edge 21, the protruding portion 124 is disposed on the mounting edge 21, a height difference exists between a surface of the protruding portion 124 and a surface of the base portion 123, and a thickness of the slider is smaller than the height difference, so that the slider meets a requirement that the slider can be assembled on the base portion 123. The base 123 is provided with a mounting position for a slider on one side close to the processing table 20, and the mounting position is provided with one slider.

Preferably: as shown in fig. 6, in order to ensure the stability of sliding of the slider and the stability of the mounting structure, an L-shaped spacer 200 is added to the mounting position, two portions of the spacer 200 that are vertically distributed are respectively connected to the base portion 123 and the protruding portion 124, the spacer 200 is a metal spacer 200, and a mounting hole 210 is formed through the spacer 200 and the base portion 123, and the mounting hole 210 is matched with the assembly of the slider; the mounting holes 210 are kidney-shaped holes, which satisfy a micro-adjustment in a certain range, thereby ensuring an adjustable mounting of the slider. Four mounting holes 210 are formed in each sliding block, and the four mounting holes 210 are distributed in a matrix.

As shown in fig. 1 to 6, the single-shell plate 110 is integrally connected to the side-shell plate 130 and has an L-shape, and is fixed to the processing table 20. The specific method is as follows: each of the single-shell plates 110 is a metal plate formed by casting and forming a side shell plate 130 corresponding to a side surface, which is L-shaped and corresponds to a short side of the rectangular processing table 20, and then two symmetrically distributed technical plates are formed on the processing table 20 to enclose the side edge of the processing table 20 away from the gantry, so as to form a full-cover protection structure of the processing table 20.

It should be noted that: as shown in fig. 1 to 6, a side surface of the processing table 20 near the gantry is an opening surface of the protection cover 100, and the opening surface is used to match the processing spindle 40 and provide enough processing space for the processing spindle 40, that is: because the processing table 20 is above the function of being able to slide in the X-axis direction, in order to adapt to the sliding processing table 20, an opening surface is further provided on the side surface of the processing table 20 corresponding to the processing spindle 40, so as to ensure the normal operation of the processing process.

As shown in fig. 1 to 3, a protection plate is arranged between the fixed base 10 and the gantry base, the protection plate is L-shaped, and is respectively connected with the fixed base 10 and the gantry base, and the two protection plates are symmetrically distributed; the protection board is in fixing base and planer-type seat cooperation have constituted a space separation, and then have constituted two symmetrical distribution's region at unable adjustment base 10 and planer-type seat, are equipped with in one region control box and operation ladder, the operation ladder is fixed in the control box below to make things convenient for the staff to operate the control box, another region is the accessory region, is equipped with chip removal mechanism and tool magazine therein.

Referring to fig. 1 to 3, the chip removing mechanism includes a double-screw chip guiding groove and a chip removing machine, the double-screw chip guiding groove is composed of two independent chip guiding grooves, a chip guiding screw is installed in each chip guiding groove, chip discharging ports of the chip guiding grooves are communicated with the chip removing machine, the two chip guiding grooves penetrate through the fixing base 10 and are symmetrically distributed on two sides of the gantry, the chip removing machine is arranged in the accessory area, and the tool magazine is tightly attached to the gantry.

And in combination with the figures 1 to 3, the edge of the accessory area is provided with a protective baffle, the protective baffle is connected with the protective plate, and the protective baffle is vertically arranged on the ground through adjustable supporting legs, so that a tool magazine and a chip removal mechanism are isolated, and the use safety of the equipment in the running process is further improved.

The present utility model is not limited to the above-mentioned embodiments, and any changes or substitutions that can be easily understood by those skilled in the art within the technical scope of the present utility model are intended to be included in the scope of the present utility model. Therefore, the protection scope of the present utility model should be subject to the protection scope of the claims.

Claims (8)

1. Mobile numerical control machining equipment, its characterized in that: including unable adjustment base, processing platform, processing main shaft and safety cover, wherein:

The processing table is in sliding connection with the fixed base through an X-axis sliding rail assembly;

The protective cover is arranged on the processing table and is driven by the processing table to slide and displace;

the protective cover is provided with two door plates which are opened and closed relatively, and the door plates are connected with the installation convex edge of the processing table in a sliding manner.

2. The mobile numerically controlled machining apparatus according to claim 1, wherein: the protective cover is U-shaped, and the opening surface of the protective cover faces the processing main shaft;

The installation convex edge is the edge of one side of the processing table far away from the processing main shaft.

3. The mobile numerically controlled machining apparatus according to claim 1, wherein: the protective cover is provided with a front shell plate, and the front shell plate consists of a single shell plate and the door plate;

The single shell plate is fixed on the processing table;

The door plate is arranged between the single shell plate and the installation convex edge.

4. A mobile numerically controlled machining apparatus as in claim 3, wherein: the door plate is provided with a door plate sliding rail at one side of the installation convex edge, which faces to the single shell plate, and a door plate sliding block is arranged on the door plate;

the door plate sliding block is connected with the door plate sliding rail in a sliding way;

The door plate sliding rail and the X-axis sliding rail component are arranged in the same direction.

5. The mobile numerically controlled machining apparatus according to claim 4, wherein: the door plant is provided with the installation position of cooperation door plant slider assembly, the installation position is provided with the gasket.

6. The mobile numerically controlled machining apparatus according to claim 5, wherein: the gasket is provided with a mounting hole, and the mounting hole is a waist-shaped hole;

Four mounting holes are distributed in a matrix.

7. The mobile numerically controlled machining apparatus according to claim 4, wherein: the door plate sliding blocks are distributed at intervals along the direction of the door plate sliding rail.

8. A mobile numerically controlled machining apparatus as in claim 3, wherein: the door plate is provided with a limiting convex edge;

The limiting convex edge is L-shaped and abuts against the edge of the single shell plate to limit the displacement travel of the door plate.