CN214641749U - Connecting structure of machine tool beam and machining assembly and door type machining center - Google Patents

Abstract

The utility model discloses a connecting structure of a machine tool beam and a processing assembly, wherein a first slide rail is arranged on the upper part of the front side of the machine tool beam along the length direction of the machine tool beam, a second slide rail is arranged on the lower part of the front side of the machine tool beam along the length direction of the machine tool beam, an accommodating part is arranged on the front side of the machine tool beam along the length direction of the machine tool beam, the first slide rail is parallel to the second slide rail, and the accommodating part ensures that the first slide rail is positioned above the rear side of the second slide rail; the machining assembly is arranged on the front side of the supporting plate, a sliding block A matched with the first sliding rail and the second sliding rail is arranged on the rear side of the supporting plate, and the supporting plate is matched with the accommodating part to enable the machining assembly to be close to the cross beam of the machine tool. The utility model also discloses a gate-type machining center with this connection structure, the utility model discloses gate-type machining center makes the processing subassembly that sets up on the layer board be close to the lathe crossbeam more, can avoid producing great moment to the lathe crossbeam and the lathe crossbeam vibration appears and influence the processingquality of work piece.

Description

Connecting structure of machine tool beam and machining assembly and door type machining center

Technical Field

The utility model relates to a digit control machine tool field, in particular to connection structure of lathe crossbeam and processing subassembly and have this connection structure's gate-type machining center.

Background

The portal type machining center is a milling machine with structures such as a portal frame, a machine body, a workbench, a machine tool upright post, a machine tool cross beam, a numerical control system and the like; the gantry machining center is generally provided with a tool magazine, has an automatic tool changing function, can machine different workpieces, can control a machine tool to select tools, change the tools, automatically set the tools, automatically change the rotating speed and the feeding amount of an electric main shaft and the like according to different procedures after the workpieces are clamped, can continuously complete various procedures such as drilling, boring, milling, tapping and the like, and has good economic benefits for parts which are complex in machining shape, high in precision requirement and frequent in variety change.

Gate-type machining center that appears in the existing market, mainly install on the lathe crossbeam through the X axle layer board, the headstock is installed on the X axle layer board, drive unit (being the motor) because of the headstock (lead screw etc.) need install on the X axle layer board, this just makes the whole thickness increase of X axle layer board, the lathe crossbeam line rail installation face is also kept away from along with it to the line rail installation face on the X axle layer board, lead to the headstock to keep away from the lathe crossbeam, the moment that produces the lathe crossbeam also strengthens, the lathe crossbeam does not have fine support to electric main shaft, this can make electric main shaft (setting on the headstock) add man-hour rigidity not enough, lead to the high-speed man-hour work piece not to reach the effect of highlight.

Therefore, the structural design between the machine tool beam and the X-axis supporting plate of the door type machining center in the prior art is unreasonable. In the cutting process, the beam generates large moment, so that the rigidity of the beam is insufficient, cutting vibration is generated, and the machining precision is influenced. To above problem, the utility model provides a gate-type machining center and lathe crossbeam and processing subassembly's on it connection structure, the problem that appears more than the solution that can be fine.

Disclosure of Invention

The utility model aims at providing a machine tool crossbeam and connection structure who processes subassembly, aim at realizing reducing the distance of headstock and electric main shaft and machine tool crossbeam, carry out redesign through the structure to the machine tool crossbeam and the structure of layer board, make the moment that headstock and electric main shaft act on the machine tool crossbeam reduce, and then make the machine tool crossbeam have fine supporting role to electric main shaft, thereby make the electric main shaft can not influence the machining precision because of the insufficient production vibration of rigidity of machine tool crossbeam when processing the work piece.

In order to achieve the above object, the present invention provides a connecting structure of a machine tool beam and a processing assembly, wherein a first slide rail is arranged on the upper portion of the front side of the machine tool beam along the length direction of the machine tool beam, a second slide rail is arranged on the lower portion of the front side of the machine tool beam along the length direction of the machine tool beam, an accommodating portion is arranged on the front side of the machine tool beam along the length direction of the machine tool beam, the first slide rail is parallel to the second slide rail, and the accommodating portion enables the first slide rail to be located above the rear side of the second slide rail; the machining assembly is arranged on the front side of the supporting plate, a sliding block A matched with the first sliding rail and the second sliding rail is arranged on the rear side of the supporting plate, and the supporting plate is matched with the accommodating part to enable the machining assembly to be close to the cross beam of the machine tool.

The utility model relates to a machine tool crossbeam is one of them preferred scheme with the connection structure of processing subassembly does: the middle part of the supporting plate in the height direction at the front side is concavely provided with a mounting groove; the machining assembly is characterized by further comprising a first driving assembly used for driving the machining assembly to move up and down, and the first driving assembly is arranged on the mounting groove.

The utility model relates to a machine tool crossbeam is one of them preferred scheme with the connection structure of processing subassembly does: the processing assembly comprises a spindle box and an electric spindle, and the electric spindle is arranged on the spindle box.

The utility model relates to a machine tool crossbeam is one of them preferred scheme with the connection structure of processing subassembly does: and a third slide rail and a fourth slide rail are respectively arranged in the height directions of the supporting plate on the two sides of the front part of the supporting plate, and a slide block B matched with the third slide rail and the fourth slide rail is arranged on the rear side of the spindle box.

The utility model relates to a machine tool crossbeam is one of them preferred scheme with the connection structure of processing subassembly does: the first driving assembly comprises a first servo motor and a first lead screw, the first servo motor is arranged on the upper portion of the mounting groove, the first lead screw is parallel to the third sliding rail, the first servo motor is connected with the first lead screw through a coupler A, and the first lead screw is connected with the spindle box through a first lead screw nut.

The utility model relates to a machine tool crossbeam is one of them preferred scheme with the connection structure of processing subassembly does: the machine tool beam machining device is characterized by further comprising a second driving assembly used for driving the machining assembly to move left and right, and the second driving assembly is arranged on the machine tool beam.

The utility model relates to a machine tool crossbeam is one of them preferred scheme with the connection structure of processing subassembly does: the second driving assembly comprises a second servo motor and a second lead screw, the second servo motor is connected with the second lead screw through a coupler B, the second lead screw is parallel to the first slide rail, and the second lead screw is connected with the back of the supporting plate through a second lead screw nut.

The utility model relates to a machine tool crossbeam is one of them preferred scheme with the connection structure of processing subassembly does: the motor mounting seat used for mounting the second servo motor is arranged at one end of the accommodating part, and the bearing mounting seat is arranged at the other end of the accommodating part.

The utility model relates to a machine tool crossbeam is one of them preferred scheme with the connection structure of processing subassembly does: the lower end face of the accommodating part is an inclined mounting surface A, and the lower part of the supporting plate is provided with an inclined mounting surface B matched with the inclined mounting surface.

The utility model also discloses a door type machining center with the connecting structure of the machine tool beam and the machining assembly; through the connecting structure of the machine tool beam and the machining assembly, the moment applied to the machine tool beam of the door type machining center is reduced, the condition that the machine tool beam vibrates when a workpiece is machined is effectively avoided, and the machining precision of the door type machining center is improved.

The utility model provides a lathe crossbeam and processing subassembly's connection structure's beneficial effect as follows: the upper part and the lower part of the front side of the machine tool beam are respectively provided with a first slide rail and a second slide rail, the machine tool beam is provided with an accommodating part, the accommodating part enables the first slide rail to be positioned above the rear side of the second slide rail, the accommodating part is matched with the supporting plate and is used for accommodating the supporting plate thickened due to the installation of other components, a machining assembly arranged on the supporting plate is enabled to be closer to the machine tool beam, the moment generated on the machine tool beam is reduced, and further the problem that the machining assembly generates larger moment on the machine tool beam in the machining process to avoid the vibration of the machine tool beam to influence the machining precision of a workpiece is solved; the utility model also discloses a gate-type machining center with above-mentioned connection structure, thereby the connection structure of lathe crossbeam and processing subassembly on the gate-type machining center makes the electric main shaft can not influence gate-type machining center's machining precision because of the insufficient production vibration of the rigidity of lathe crossbeam when processing the work piece.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

Fig. 1 is a schematic structural view of an embodiment of a connection structure of a machine tool beam and a machining assembly according to the present invention;

FIG. 2 is a schematic front side perspective view of an embodiment of the gate-type machining center of the present invention;

FIG. 3 is a schematic view of a rear side three-dimensional structure of an embodiment of the gate-type machining center of the present invention;

FIG. 4 is a schematic view of a pallet structure of an embodiment of the gate-type machining center of the present invention;

the reference numbers illustrate:

100-a lathe bed, 101-a machine tool column, 102-a processing table, 103-a folding protective cover, 104-a diversion trench and 105-a liquid outlet;

200-a machine tool cross beam, 201-a first slide rail, 202-a second slide rail, 203-a containing part, 204-a motor mounting seat, 205-a bearing mounting seat;

300-a supporting plate, 301-a mounting groove, 302-a first servo motor;

400-machining component, 401-headstock, 402-electric spindle;

501-tool magazine body, 502-tool holder, 503-driving device, 504-fixing frame, 505-oil receiving disc.

Detailed Description

The technical solution of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein, as those skilled in the art will be able to make similar modifications without departing from the spirit and scope of the present invention.

It will be understood that when an element is referred to as being "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. When an element is referred to as being "mounted to" another element, it can be directly mounted to the other element or intervening elements may also be present.

Furthermore, it should be understood that all directional indicators (such as upper, lower, left, right, middle … …) in the embodiments are only used to explain the relative position relationship between the components, the movement situation, etc. in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indicator is changed correspondingly; the terms "first," "second," and the like are used herein to distinguish one structural element from another. These terms are merely for convenience of description and simplicity of description, and are not to be construed as limiting the present invention.

Examples

The embodiment discloses a machine tool crossbeam and processing subassembly's connection structure and have this connection structure's gate-type machining center, aim at realizing reducing the gate-type machining center and go up the distance of headstock and electric main shaft and machine tool crossbeam, carry out redesign through the structure to the machine tool crossbeam and the structure of layer board, make headstock and electric main shaft act on the moment on the crossbeam reduce, and then make the machine tool crossbeam have fine supporting role to electric main shaft, thereby make electric main shaft can not influence gate-type machining center's machining precision because of the insufficient production vibration of the rigidity of machine tool crossbeam when processing the work piece.

The gantry machining center of the embodiment, referring to fig. 1 to 4, includes a machine tool 100, wherein a gantry is arranged on the machine tool 100, the gantry includes a machine tool beam 200 and a machine tool column 101, and the machine tool beam 200 is arranged on the upper portion of the machine tool column 101; specifically, the machine tool column 101 is arranged on two sides of the machine tool 100, the lower end of the machine tool beam 200 is fixedly arranged on the upper portion of the machine tool column 101, in order to reduce the overall weight of the machining center, the machine tool beam 200 and the machine tool column 101 in this embodiment are preferably of a cavity structure, and reinforcing ribs or reinforcing plate structures are arranged in the cavity structure, and the machine tool 100, the machine tool beam 200 and the machine tool column 101 in this embodiment are made of gray cast iron or other alloy materials.

In this embodiment, a first slide rail 201 is disposed on the upper portion of the front side of the machine tool cross beam 200 along the length direction thereof, a second slide rail 202 is disposed on the lower portion of the front side of the machine tool cross beam 200 along the length direction thereof, an accommodating portion 203 is disposed on the front side of the machine tool cross beam 200 along the length direction thereof, the first slide rail 201 is parallel to the second slide rail 202, and the accommodating portion 203 enables the first slide rail 201 to be located above the rear side of the second slide rail 202, that is, the first slide rail 201 is fixedly disposed on the upper end of the front side of the machine tool cross beam 200, the second slide rail 202 is fixedly disposed on the lower end of the front side of the machine tool cross beam 200, the first slide rail 201 can be regarded as being disposed on the upper side of the accommodating portion 203, and the accommodating portion 203 enables the first slide rail 201 to be located above the rear side of the second slide rail 202; the processing device further comprises a supporting plate 300 and a processing assembly 400, wherein the processing assembly 400 is arranged on the front side of the supporting plate 300, a sliding block A matched with the first sliding rail 201 and the second sliding rail 202 is arranged on the rear side of the supporting plate 300, and it should be understood that the sliding blocks A are arranged on the upper portion and the lower portion of the rear side of the supporting plate 300 and are respectively matched with the first sliding rail 201 and the second sliding rail 202;

in the present embodiment, it is within the protection scope of the present patent that the receiving portion 203 is matched with the supporting plate 300 so that the processing assembly 400 is close to the machine tool beam 200, and it is worth to be noted that the shape of the receiving portion 203 is matched with the supporting plate 300 so that the whole supporting plate 300 and the members arranged thereon can be closer to the machine tool beam 200; it can be approximately understood that the upper middle portion of the front side of the machine tool cross beam 200 is recessed to the rear side to form the accommodating portion, and the longitudinal section of the accommodating portion may be an arc surface, and in this embodiment, specifically, with reference to the drawings (the drawings in the present application are only for reference, and do not limit the protection scope of the patent), the lower end surface of the accommodating portion is an inclined mounting surface a, and the upper end surface is a vertical mounting surface vertically arranged to the machine tool bed 100; further, the lower portion of the rear side of the supporting plate 300 is provided with an oblique mounting surface B matched with the oblique mounting surface a, the accommodating portion 203 is matched with the supporting plate 300, the accommodating portion 203 is used for accommodating the supporting plate 300 thickened due to the fact that other components are mounted, the machining assembly 400 arranged on the supporting plate 300 is closer to the machine tool cross beam 200, the moment generated by the machine tool cross beam 200 is reduced, and therefore the machining assembly 400 can avoid the problem that the machining accuracy of workpieces is affected due to vibration of the machine tool cross beam 200 caused by large moment generated on the machine tool cross beam 200 in the machining process.

One of the preferred schemes in this embodiment is: the middle part of the supporting plate 300 in the height direction is concavely provided with a mounting groove 301 at the front side; the machining device further comprises a first driving assembly for driving the machining assembly 400 to move up and down, and the first driving assembly is arranged on the mounting groove 301; in this embodiment, the supporting plate 300 is provided with a mounting groove 301 for mounting the first driving assembly, so that the overall thickness of the supporting plate 300 can be increased, and the weight can also be increased, but due to the structural cooperation between the supporting plate 300 and the accommodating portion, the first driving assembly is substantially located right above the accommodating portion, and therefore, the first driving assembly is closer to the machine tool cross beam 200, and the moment that the machine tool cross beam 200 needs to bear is reduced.

One of the preferred schemes in this embodiment is: the machining assembly 400 comprises a spindle box 401 and an electric spindle 402, wherein the electric spindle 402 is arranged on the spindle box 401; a third slide rail and a fourth slide rail are respectively arranged on the two sides of the front part of the supporting plate 300 in the height direction of the supporting plate 300, and a slide block B matched with the third slide rail and the fourth slide rail is arranged on the rear side of the spindle box 401, namely, the left side and the right side of the rear side of the spindle box 401 are respectively provided with slide blocks B matched with the third slide rail and the fourth slide rail; the present embodiment drives the electric spindle 402 to move up and down by the first driving assembly, so as to machine a workpiece placed on the machining center.

One of the preferred schemes in this embodiment is: the first driving assembly comprises a first servo motor 302 and a first screw rod, the first servo motor 302 is fixedly arranged at the upper part of the mounting groove 301, the first screw rod is parallel to the third slide rail, namely the first screw rod is parallel to the third slide rail and the fourth slide rail and is arranged in the vertical direction, and the first screw rod is arranged between the third slide rail and the fourth slide rail; the first servo motor 302 is connected with one end of the first screw rod through a coupler A, the other end of the first screw rod is arranged on a bearing seat corresponding to the first screw rod, the first screw rod is connected with the spindle box 401 through a first screw nut, namely, a first screw nut mounting seat is arranged on the rear side of the spindle box 401, so that the spindle box 401 is connected with the first screw rod through the first screw nut, and the spindle box 401 and the electric spindle 402 are driven to move up and down through rotation of the first screw rod.

One of the preferred schemes in this embodiment is: the second driving assembly is used for driving the machining assembly 400 to move left and right and is arranged on the machine tool cross beam 200; the second driving assembly comprises a second servo motor and a second lead screw, the second servo motor is connected with the second lead screw through a coupler B, the second lead screw is parallel to the first slide rail 201, namely the second lead screw is transversely arranged on the cross beam 200 of the machine tool, the second lead screw is parallel to the first slide rail 201 and the second slide rail 202, the second lead screw is arranged between the first slide rail 201 and the second slide rail 202, and the second lead screw is connected with the back of the supporting plate 300 through a second lead screw nut. One preferable scheme of the gate-type machining center of this embodiment is that one end of the accommodating portion 203 is provided with a motor mounting seat 204 for mounting a second servo motor, the other end of the accommodating portion 203 is provided with a bearing mounting seat 205, the second servo motor of this embodiment is fixedly arranged on the motor mounting seat 204, the second servo motor is connected with one end of a second lead screw through a coupling B, and the other end of the second lead screw is arranged on the bearing mounting seat 205; the second lead screw of this embodiment pass through the second lead screw nut with layer board 300 is connected, and layer board 300 rear side is equipped with the second lead screw nut mount pad promptly to layer board 300 is connected with the second lead screw through the second lead screw nut, thereby rotates through the second lead screw and drives the processing subassembly 400 that sets up in layer board 300 front side and remove.

One of the preferred schemes in this embodiment is: a processing table 102 is arranged on the lathe bed 100, and the processing table 102 is arranged below the processing assembly 400; the machining center is characterized by further comprising a third driving assembly for driving the machining table 102 to move back and forth, the third driving assembly is arranged on the machine body 100, a fifth slide rail and a sixth slide rail which are parallel to each other are arranged on the machine body 100 along the front-back direction of the machine body, a slide block C matched with the fifth slide rail and the sixth slide rail is arranged at the lower part of the machining table 102, namely, the slide blocks C matched with the fifth slide rail and the sixth slide rail are respectively arranged at the lower part of the machining table 102, and the slide blocks and the slide rails are arranged in pairs, so that related structural components can move more stably, and the machining stability of the machining center is improved.

In this embodiment, the third driving assembly includes a third servo motor and a third lead screw, the third servo motor is connected to one end of the third lead screw through a coupling C, and the other end of the third lead screw is disposed on a bearing seat corresponding to the third lead screw; further, the third screw rod is parallel to the fifth slide rail, that is, the third screw rod is also arranged along the front-back direction of the bed 100 and is arranged between the fifth slide rail and the sixth slide rail; the third screw rod is connected with the lower part of the processing table 102 through a third screw nut, namely, a third screw nut mounting seat is arranged at the lower part of the processing table 102, so that the processing table 102 is connected with the third screw rod through the third screw nut, and the third screw rod rotates to drive the processing table 102 to move back and forth, so that a workpiece fixedly arranged on the processing table 102 moves back and forth; in this embodiment, the first driving unit drives the processing unit 400 to move up and down, the second driving unit drives the processing unit 400 to move left and right, and the third driving unit drives the processing table 102 to move along the front and rear directions of the bed 100, wherein the moving directions are the Z-axis direction, the Y-axis direction, and the X-axis direction of the gantry machining center, and each component moves in a predetermined direction, so that the processing unit 400 can process a workpiece placed on the processing table 102.

One of the preferred schemes in this embodiment is: the front side and the rear side of the processing table 102 are respectively provided with a folding protective cover 103 for protecting the third driving assembly, one end of the folding protective cover 103 is fixedly connected with the bed 100, and the other end of the folding protective cover 103 is fixedly connected with the processing table 102, the folding protective cover 103 of the embodiment is similar to an organ protective cover, can be folded, can be used for preventing relevant components arranged on the bed 100 from being protected from chips generated by a processing center in the process of processing workpieces, and particularly can effectively protect the structure of the third driving assembly through the folding protective cover 103, so that the normal operation of the third driving assembly is ensured.

In this embodiment, not shown in the drawings, a spray head for spraying cutting fluid is further connected to the processing assembly 400; the spray head can spray cutting fluid outwards, the cutting fluid can take away heat generated during the processing of a workpiece, the abrasion of a processing cutter is reduced, the friction can be reduced, the smooth cutting is ensured, the cuttings on the surface of the glass plate are taken away, and the machined plate is prevented from being scratched by the cuttings; in this embodiment, the processing table 102 is located in the middle of the bed 100, the bed 100 is provided with guide grooves 104 on both sides of the processing table 102, and the front side end of the machine tool is provided with a liquid outlet 105, so that the cutting fluid and the waste chips can be guided to the outside through the guide grooves 104 and the liquid outlet 105.

One of the preferred schemes in this embodiment is: the tool magazine assembly is arranged on the lathe bed 100 and comprises a tool magazine body 501, the tool magazine body 501 comprises a chain arranged on the side edge of the upper part of the tool magazine body 501, tool shank seats 502 are arranged on the chain at intervals, a machining tool is arranged on the tool shank seat 502, and a driving motor for driving the chain to rotate is arranged on the tool magazine body 501; the tool magazine further comprises a driving device 503, which is used for driving the tool magazine body 501 to move back and forth; in the embodiment, referring to the drawings, the machining table 102 is arranged on the front side of the bed 100, and the tool magazine assembly can be understood as being arranged on the rear side of the bed 100, but the tool magazine assembly can be driven to move back and forth by the driving device 503, so that the tool magazine body 501 is positioned below the machining assembly 400, namely below the electric spindle 402, and the machining table 102 is positioned below the tool magazine body 501; the working mode of the electric spindle 402 can be understood that when a certain type of machining tool needs to be mounted on the electric spindle 402, the machining tool can drive a chain on the side edge of the upper part of the tool magazine body 501 to rotate through a driving motor and further be positioned right below the electric spindle 402, and a tool mounting and changing assembly is arranged on the lower side of the electric spindle 402, so that the tool can be fixed on the electric spindle 402 to machine a workpiece; when the tool needs to be changed, the machining tool on the electric spindle 402 is firstly placed back to the corresponding tool holder 502 or other tool holders 502 without machining tools, and then the chain on the side edge of the upper part of the tool magazine body 501 is driven to rotate by the driving motor, so that the machining tool needing to be installed on the electric spindle 402 is positioned right below the electric spindle 402, and the tool changing of the electric spindle 402 is realized.

One of the preferred schemes in this embodiment is: the tool magazine assembly further comprises a fixing frame 504 and a bottom plate, wherein an oil receiving disc 505 is arranged on the upper portion of the bottom plate, the oil receiving disc 505 can receive engine oil leaked downwards from the tool magazine body 501, the tool magazine body 501 is arranged on the upper portion of the fixing frame 504, the bottom plate is arranged on the lower portion of the fixing frame 504, namely the oil receiving disc 505 is arranged between the lower portion of the fixing frame 504 and the upper portion of the bottom plate, a guide rail is arranged on the machine body 100, and a guide slider matched with the guide rail is arranged on the lower portion of the bottom plate.

The above only be the preferred embodiment of the utility model discloses a not consequently restriction the utility model discloses a patent range, all are in the utility model discloses a conceive, utilize the equivalent structure transform of what the content was done in the description and the attached drawing, or direct/indirect application all is included in other relevant technical field the utility model discloses a patent protection within range.

Claims (10)

1. The utility model provides a connection structure of lathe crossbeam and processing subassembly which characterized in that: the upper part of the front side of the machine tool cross beam is provided with a first slide rail along the length direction, the lower part of the front side of the machine tool cross beam is provided with a second slide rail along the length direction, the front side of the machine tool cross beam is provided with an accommodating part along the length direction, and the first slide rail is parallel to the second slide rail and is positioned above the rear side of the second slide rail by the accommodating part; the machining assembly is arranged on the front side of the supporting plate, a sliding block A matched with the first sliding rail and the second sliding rail is arranged on the rear side of the supporting plate, and the supporting plate is matched with the accommodating part to enable the machining assembly to be close to the cross beam of the machine tool.

2. The machine tool beam and machining assembly connecting structure according to claim 1, wherein: the middle part of the supporting plate in the height direction at the front side is concavely provided with a mounting groove; the machining assembly is characterized by further comprising a first driving assembly used for driving the machining assembly to move up and down, and the first driving assembly is arranged on the mounting groove.

3. A machine tool beam and machining assembly connecting structure according to claim 2, wherein: the processing assembly comprises a spindle box and an electric spindle, and the electric spindle is arranged on the spindle box.

4. A machine tool beam and machining assembly connecting structure according to claim 3, wherein: and a third slide rail and a fourth slide rail are respectively arranged in the height directions of the supporting plate on the two sides of the front part of the supporting plate, and a slide block B matched with the third slide rail and the fourth slide rail is arranged on the rear side of the spindle box.

5. The machine tool beam and machining assembly connecting structure according to claim 4, wherein: the first driving assembly comprises a first servo motor and a first lead screw, the first servo motor is arranged on the upper portion of the mounting groove, the first lead screw is parallel to the third sliding rail, the first servo motor is connected with the first lead screw through a coupler A, and the first lead screw is connected with the spindle box through a first lead screw nut.

6. A machine tool beam and machining assembly connecting structure according to claim 2, wherein: the machine tool beam machining device is characterized by further comprising a second driving assembly used for driving the machining assembly to move left and right, and the second driving assembly is arranged on the machine tool beam.

7. The machine tool beam and machining assembly connecting structure according to claim 6, wherein: the second driving assembly comprises a second servo motor and a second lead screw, the second servo motor is connected with the second lead screw through a coupler B, the second lead screw is parallel to the first slide rail, and the second lead screw is connected with the back of the supporting plate through a second lead screw nut.

8. The machine tool beam and machining assembly connecting structure according to claim 7, wherein: the motor mounting seat used for mounting the second servo motor is arranged at one end of the accommodating part, and the bearing mounting seat is arranged at the other end of the accommodating part.

9. The machine tool beam and machining assembly connecting structure according to claim 1, wherein: the lower end face of the accommodating part is an inclined mounting surface A, and the lower part of the supporting plate is provided with an inclined mounting surface B matched with the inclined mounting surface.

10. The utility model provides a gate type machining center which characterized in that: a connecting structure comprising a machine tool beam and a machining module according to any one of claims 1 to 9.

Images