CN212552807U - Horizontal milling compound machine - Google Patents

Abstract

The utility model relates to a compound machine crouches and mills, include: the device comprises a rack, a material ejecting mechanism, a horizontal numerical control machine tool, a bearing mechanism and a movement mechanism; the moving mechanism comprises a first driver and a guide rail, the guide rail is arranged on the rack, the first driver is in driving connection with the bearing mechanism, the bearing mechanism is arranged on the guide rail in a sliding mode, the horizontal numerical control machine tool is arranged on one side of the guide rail, the ejection mechanism is arranged on the other side of the horizontal numerical control machine tool, the ejection mechanism and the horizontal numerical control machine tool are arranged oppositely, and the ejection mechanism is used for abutting against the other side of the processed mold when the horizontal numerical control machine tool processes one side of the processed mold. When the bearing mechanism bears the processed die and moves to a position between the horizontal numerical control machine tool and the material ejecting mechanism, the horizontal numerical control machine tool processes one side of the processed die, the material ejecting mechanism abuts against the other side of the processed die, and the processed die can be supported by the material ejecting mechanism when being processed by the horizontal numerical control machine tool, so that the processing effect of the processed die of the horizontal numerical control machine tool is better.

Description

Horizontal milling compound machine

Technical Field

The utility model relates to a mill technical field, especially relate to a compound machine mills for sleeping in.

Background

The die machining needs to be conducted through cutting of the double-head cutter disc and milling of the milling equipment, the existing double-head cutter disc and the milling equipment are two independent devices, after the die is cut through the double-head cutter disc, a worker needs to manually place the die into the milling equipment for milling, more time needs to be consumed in the process, labor needs to be consumed, and the production efficiency is low.

Through the three milling integrated processing equipment of improvement, with double-end blade disc and horizontal digit control machine tool integration in a frame, the mould that is processed moves between double-end blade disc and horizontal digit control machine tool along the guide rail to realize the mould that is processed and mill the processing of horizontal digit control machine tool through double-end blade disc in proper order on three milling integrated processing equipment. However, when the existing machined die is machined by a horizontal numerical control machine, the machined die is difficult to fix due to the large force of the tool bit of the horizontal numerical control machine, and the machined die is easy to displace in the machining process, so that the machined die is poor in machining effect by the horizontal numerical control machine.

SUMMERY OF THE UTILITY MODEL

Based on this, it is necessary to provide a horizontal milling compound machine.

A horizontal milling compound machine comprising: the device comprises a rack, a material ejecting mechanism, a horizontal numerical control machine tool, a bearing mechanism and a movement mechanism;

the horizontal numerical control machine tool and the material ejecting mechanism are respectively arranged on the rack;

the moving mechanism comprises a first driver and a guide rail, the guide rail is arranged on the rack, the first driver is in driving connection with the bearing mechanism, the bearing mechanism is arranged on the guide rail in a sliding mode, the bearing mechanism is used for bearing a processed die, the horizontal numerical control machine is arranged on one side of the guide rail, the ejection mechanism is arranged on the other side of the horizontal numerical control machine, the ejection mechanism and the horizontal numerical control machine are arranged oppositely, and the ejection mechanism is used for abutting against the other side of the processed die when the horizontal numerical control machine processes one side of the processed die so that the processed die is clamped and fixed.

In one embodiment, the material ejecting mechanism includes a fixing seat, a driving component and a roller component, the fixing seat is fixedly connected with the rack, the fixing seat is disposed on one side of the guide rail, the driving component is disposed on the fixing seat, the driving component is in driving connection with the roller component, and the driving component is used for driving the roller component to abut against the processed mold.

In one embodiment, the roller assembly comprises a support and a roller, the support is slidably disposed on the fixing seat, the roller is rotatably disposed on the support, and the roller is configured to rotatably abut against the processed mold.

In one embodiment, the roller assembly further includes two clamping blocks, the two clamping blocks are oppositely disposed and fixedly disposed on one side of the support near the guide rail, each clamping block is provided with a supporting hole, one end of the roller is rotatably disposed in one of the supporting holes, and the other end of the roller is rotatably disposed in the other supporting hole.

In one embodiment, the driving assembly comprises an ejection driving motor and an ejection driving screw rod, and the ejection driving motor is in driving connection with the support through the ejection driving screw rod.

In one embodiment, the fixing base is provided with at least one sliding rail, the support is provided with at least one sliding block, and each sliding block is slidably disposed on one sliding rail.

In one embodiment, the automatic cutting device further comprises two cutter disc mechanisms, the two cutter disc mechanisms are respectively and fixedly connected with the rack, each cutter disc mechanism comprises a cutter disc, the two cutter discs are oppositely arranged, and the two cutter discs are respectively arranged on two sides of the guide rail.

In one embodiment, the horizontal numerically-controlled machine tool comprises a milling cutter head, a cutter head support, a sliding seat, a base, a transverse driver and a vertical driver, wherein the base is fixedly connected with a rack and arranged on one side of the guide rail, the sliding seat is provided with a transverse rail, the sliding seat is slidably arranged on the transverse rail, the transverse rail is perpendicular to the guide rail, the transverse driver is in driving connection with the sliding seat, the sliding seat is provided with a vertical rail, the cutter head support is slidably arranged on the vertical rail, the vertical rail is perpendicular to the guide rail and perpendicular to the transverse rail, the vertical driver is in driving connection with the cutter head support, and the milling cutter head is detachably arranged on the cutter head support.

In one embodiment, the bearing mechanism comprises a sliding seat, a rotating seat, a second driver and a pressing assembly, the first driver is in driving connection with the sliding seat, the sliding seat is slidably disposed on the guide rail, the second driver is disposed on the sliding seat, the second driver rotates with the rotating seat, the rotating seat is rotatably disposed on the sliding seat, the pressing assembly is movably disposed on the sliding seat, and the pressing assembly is used for pressing the mold onto the rotating seat.

In one embodiment, the pressing assembly comprises a supporting frame and a pressing driver, the supporting frame is arranged on the sliding seat, the pressing driver is arranged on the supporting frame, and a power output end of the pressing driver is used for pressing the die on the rotating seat.

The utility model has the advantages that: when bearing mechanism bears and is moved to horizontal digit control machine tool and liftout mechanism by the mold processing between, horizontal digit control machine tool is processed one side by the mold processing, liftout mechanism supports and holds in the opposite side by the mold processing, horizontal digit control machine tool and the common centre gripping of liftout mechanism are by the both sides of mold processing for by the mold processing when being added man-hour by horizontal digit control machine tool, can obtain the support of liftout mechanism on bearing mechanism, make by the mold processing remain stable in the course of working, and then make horizontal digit control machine tool better by the mold processing's machining effect.

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 drawings without inventive exercise.

Fig. 1 is a schematic view of a directional structure of a horizontal milling compound machine according to an embodiment;

fig. 2 is a schematic view of another direction structure of the horizontal milling compound machine according to the embodiment.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

As shown in fig. 1 to fig. 2, a horizontal milling compound machine 10 according to an embodiment of the present invention includes: the device comprises a frame 10, a material ejecting mechanism 700, a horizontal numerical control machine 300, a bearing mechanism 400 and a moving mechanism 500; the horizontal numerical control machine 300 and the material ejecting mechanism 700 are respectively arranged on the frame 10; the moving mechanism 500 includes a first driver and a guide rail 510, the guide rail 510 is disposed on the frame 10, the first driver is in driving connection with the bearing mechanism 400, the bearing mechanism 400 is slidably disposed on the guide rail 510, the bearing mechanism 400 is used for bearing a processed mold, the horizontal numerical control machine 300 is disposed on one side of the guide rail 510, the ejection mechanism 700 is disposed on the other side of the horizontal numerical control machine 300, the ejection mechanism 700 is disposed opposite to the horizontal numerical control machine 300, and the ejection mechanism 700 is used for abutting against the other side of the processed mold when the horizontal numerical control machine 300 processes one side of the processed mold, so that the processed mold is clamped and fixed.

Specifically, the carrying mechanism 400 is used for carrying and fixing the processed die in the vertical direction, the carrying mechanism 400 slides along the guide rail 510 under the driving of the first driver, and the ejecting mechanism 700 is used for abutting against one side of the processed die, which faces away from the horizontal numerical control machine 300, and supporting the processed die. When the bearing mechanism 400 slides to align the horizontal numerical control machine 300, the horizontal numerical control machine 300 processes one side of the processed die, the material ejecting mechanism 700 abuts against the other side of the processed die, the horizontal numerical control machine 300 and the material ejecting mechanism 700 clamp the two sides of the processed die together, so that the processed die can be supported by the material ejecting mechanism 700 on the bearing mechanism 400 when being processed by the horizontal numerical control machine 300, the processed die is kept stable in the processing process, and the processing effect of the processed die of the horizontal numerical control machine 300 is better.

In order to support the mold, in an embodiment, the ejector mechanism 700 includes a fixing base 710, a driving component (not shown) and a roller component 730, the fixing base 710 is fixedly connected to the frame 10, the fixing base 710 is disposed at one side of the guide rail 510, the driving component is disposed on the fixing base 710, the driving component is drivingly connected to the roller component 730, and the driving component is configured to drive the roller component 730 to abut against the mold to be processed.

Specifically, the roller assembly 730 can rotate to abut against the processed mold, and it should be understood that when the horizontal numerical control machine 300 processes the processed mold, the bearing mechanism 400 drives the processed mold to slide along the guide rail 510, so that different positions of the processed mold in the transverse direction can be milled by the horizontal numerical control machine 300. The roller assembly 730 can rotate, so that the roller assembly 730 rotates relative to the surface of the processed mold during the sliding process of the processed mold along the guide rail 510, the processed mold is prevented from being clamped, and the processed mold is prevented from being scratched. The fixing seat 710 is used for supporting a driving assembly and a roller assembly 730, the driving assembly is used for driving the roller assembly 730 to approach to the processed mold on the bearing mechanism 400, so that the roller assembly 730 can be tightly abutted against the processed mold, and when the processed mold is processed and slides along the guide rail 510, the roller assembly 730 is driven by the driving assembly to move in a direction away from the bearing mechanism 400, and is separated from the processed mold, so that the processed mold can slide along the guide rail 510 along with the bearing mechanism 400.

In order to realize the rotation of the roller assembly 730, in one embodiment, referring to fig. 1 and fig. 2, the roller assembly 730 includes a support 740 and a roller 750, the support 740 is slidably disposed on the fixing base 710, the roller 750 is rotatably disposed on the support 740, and the roller 750 is configured to rotatably abut against the processed mold. In this embodiment, the roller 750 is a bearing roller 750, and the bearing roller 750 has the characteristics of flexible rotation and smoothness, so that the roller 750 can rotate and abut against the surface of the processed mold when the processed mold moves along the guide rail 510, the roller 750 can rotate and abut against the processed mold, the scratch of the processed mold is avoided, and the processed mold is enabled to move more stably.

In one embodiment, as shown in fig. 1 and fig. 2, the roller assembly 730 further includes two clamping blocks 731, the two clamping blocks 731 are oppositely disposed and fixedly disposed on one side of the support 740 near the guide rail 510, a supporting hole is formed on each clamping block 731, one end of the roller 750 is rotatably disposed in one of the supporting holes, and the other end of the roller 750 is rotatably disposed in the other supporting hole.

Specifically, the clamping blocks 731 are used for supporting the roller 750, two clamping blocks 731 are fixed on the supporting base 740 through screws, and the roller 750 is rotatably disposed in the supporting holes, so that the roller 750 can rotate on the clamping blocks 731. The two clamping blocks 731 are provided to facilitate installation of the roller 750 and to adjust the tightness of the roller 750 and the position of the roller 750 on the support 740, for example, two back-facing surfaces of the support 740 are respectively provided with a kidney-shaped hole, each clamping block 731 corresponds to a kidney-shaped hole, and the clamping blocks 731 are screwed to the side walls of the kidney-shaped holes through screws, so that the positions of the screws in the kidney-shaped holes can be adjusted to adjust the positions of the clamping blocks 731, thereby adjusting the position of the roller 750.

To effect actuation of the support 740, in one embodiment, the actuation assembly includes an ejection actuator motor and an ejection actuator screw, the ejection actuator motor being drivingly coupled to the support 740 via the ejection actuator screw. In this embodiment, the material ejecting driving motor drives the driving screw rod to rotate, the support 740 is provided with a driving hole, the driving screw rod penetrates through the driving hole, and the driving screw rod is in threaded connection with the side wall of the driving hole, so that the driving screw rod rotates, circular motion is converted into linear motion through the threaded connection with the side wall of the driving hole, the support 740 is driven to move, and the support 740 moves on the fixing seat 710 along the linear motion.

In an embodiment, referring to fig. 1 and fig. 2 again, the fixing base 710 is provided with at least one sliding rail 711, the support 740 is provided with at least one sliding block 741, and each sliding block 741 is slidably disposed on one sliding rail 711. In this embodiment, the number of the sliding rails 711 is two, the number of the sliding blocks 741 arranged on the support 740 is two, each of the sliding blocks 741 is slidably disposed on one of the sliding rails 711, in one embodiment, the number of the sliding blocks 741 is four, two sliding blocks 741 are slidably disposed on each of the sliding rails 771, and two sliding blocks 741 are respectively disposed on two sides of the support 740, so that the support 740 can slide more stably. In this way, the support 740 can move along the sliding rail 711 on the fixed seat 710 by the driving of the driving screw rod, so that the roller 750 on the support 740 can approach or depart from the processed mold on the bearing mechanism 400.

In an embodiment, please refer to fig. 1 and fig. 2, the horizontal milling compound machine further includes two cutter head mechanisms 200, the two cutter head mechanisms 200 are respectively and fixedly connected to the frame 10, each cutter head mechanism 200 includes a cutter head 210, the two cutter heads 210 are arranged oppositely, and the two cutter heads 210 are respectively arranged at two sides of the guide rail.

Specifically, the cutter disc mechanism 200 and the horizontal numerically-controlled machine tool 300 are fixed by the frame 100, the guide rail 510 extends along the cutter disc mechanism 200 in the direction toward the horizontal numerically-controlled machine tool 300, the bearing mechanism 400 is used for bearing a mold to be machined, and the bearing mechanism 400 slides on the guide rail 510, so that the mold on the bearing mechanism 400 can be conveyed from the cutter disc mechanism 200 to the horizontal numerically-controlled machine tool 300. The first driver drives the carriage 400 to move linearly on the guide rail 510.

A cutter head mechanism 200 is arranged on one side of the guide rail 510, and another cutter head mechanism 200 is arranged on the other side of the guide rail 510, so that two cutter heads 210 can be arranged at intervals and are positioned on two sides of the guide rail 510, and the cutter heads 210 are used for cutting the mold on the bearing mechanism 400, so that the mold can be cut by the two cutter heads 210 when positioned between the two cutter heads 210. The horizontal numerical control machine 300 is provided with a cutter facing the die on the bearing mechanism 400, the cutter on the horizontal numerical control machine 300 is used for milling the die on the bearing mechanism 400, and after the die is cut by the cutter disc 210, the die moves to the horizontal numerical control machine 300 along with the bearing mechanism 400, so that the horizontal numerical control machine 300 can mill the die.

In this application, two blade disc mechanisms 200 mill the mould through two blade discs 210 for the mould is milled and is required shape, and horizontal digit control machine tool 300 carries out processing such as accurate drilling, milling, chamfer to the mould, makes the mould obtain accurate processing. The two cutter head mechanisms and the horizontal numerical control machine 300 are respectively provided with cutters, which is equivalent to three cutters for processing the mold, so that three heads in the horizontal milling compound machine are respectively two cutter heads and one cutter of the horizontal numerical control machine 300. In one embodiment, the horizontal milling compound machine can also be called a cutting and milling integrated processing device.

In one embodiment, each of the cutter head mechanisms 200 further includes a third driver 230, the third driver 230 is in driving connection with one of the cutter heads 210, and the third driver 230 is configured to drive the cutter head 210 to rotate. In this embodiment, the third driver 230 is a servo motor, and the driving of the motor enables the cutter head 210 to rotate at a high speed, so that the cutter head 210 can cut the mold. Regarding the connection structure of motor and blade disc, can adopt prior art to realize, for example, the motor passes through the gear train and is connected with the blade disc drive, like this, can make the blade disc can high-speed rotation, realizes the cutting.

In one embodiment, referring to fig. 1 and 2, the horizontal numerical control machine 300 includes a milling cutter head 310, a cutter head support 320, a sliding seat 330, a base 340, a traverse driver and a vertical driver, the base 340 is fixedly connected to the machine frame and is disposed on one side of the guide rail, a traverse rail 341 is disposed on the base 340, the sliding seat 330 is slidably disposed on the traverse rail 341, the traverse rail 341 is perpendicular to the guide rail, the traverse driver is drivingly connected to the sliding seat 330, a vertical rail 331 is disposed on the sliding seat 330, the cutter head support 320 is slidably disposed on the vertical rail 331, the vertical rail 331 is perpendicular to the guide rail and perpendicular to the traverse rail 341, the vertical driver is drivingly connected to the cutter head support 320, and the milling cutter head 310 is detachably mounted on the cutter head support 320.

Specifically, the traverse drivers and the vertical drivers can both adopt the structures of a motor and a screw rod to respectively drive the sliding seat 330 and the tool bit support 320 to move in the horizontal direction and the vertical direction, and as the traverse rail 341 is perpendicular to the guide rail, the sliding seat 330 can be close to the guide rail or far away from the guide rail, so that the distance between the milling tool bit 310 and a mold on the bearing mechanism can be adjusted, and in addition, the vertical rail 331 is perpendicular to the guide rail, so that the tool bit support 320 can move in the vertical direction, further the milling tool bit 310 can process different height positions on the surface of the mold, and the bearing mechanism is matched to move on the guide rail, so that different positions on the surface of the mold can be processed by the milling tool bit 310.

In an embodiment, please refer to fig. 1 and fig. 2, the bearing mechanism 400 includes a sliding seat 410, a rotating seat 420, a second driver (not shown), and a pressing assembly 430, the first driver is connected to the sliding seat 410 in a driving manner, the sliding seat 410 is slidably disposed on the guide rail, the second driver is disposed on the sliding seat 410, the second driver and the rotating seat 420 rotate, the rotating seat is rotatably disposed on the sliding seat 410, the pressing assembly 430 is movably disposed on the sliding seat 410, and the pressing assembly 430 is configured to press the mold onto the rotating seat.

In this embodiment, the sliding seat 410 is configured to slide on the guide rail 510, the sliding seat 410 drives the rotating seat 420 to move, and the rotating seat 420 is configured to carry a mold, so that the sliding seat 410 slides along the guide rail 510, so that the mold can move to the milling assembly 310 from between the two cutter discs 210, and the second driver is configured to drive the rotating seat 420 to rotate, so that when the mold is placed on the rotating seat 420, the mold can rotate along with the rotating seat 420, so that different surfaces of the mold can face the milling assembly 310, and the milling assembly 310 can mill different surfaces of the mold respectively. The pressing assembly 430 is used for pressing the die onto the rotating base 420, so that when the die is used for cutting and milling, the die can be fixed on the rotating base 420, the die is prevented from moving in machining, the machining precision of the die is higher, and the effect is better.

In one embodiment, the pressing assembly 430 includes a support frame 431 and a pressing driver 432, the support frame 431 is disposed on the sliding seat 410, the pressing driver 432 is disposed on the support frame 431, and a power output end of the pressing driver 432 is used for pressing the mold onto the rotating seat.

In this embodiment, the supporting frame 431 is used to be fixed on the sliding seat 410 to provide support for the pressing driver 432, for example, the pressing driver 432 is a hydraulic cylinder, for example, the pressing driver 432 is an auxiliary pressing cylinder, when the pressing driver 432 works, a power output end of the pressing driver 432 abuts against the mold, and the mold is pressed against the rotating seat 420 by the power of the pressing driver 432, so that the mold is pressed, and the mold to be processed is fixed on the bearing mechanism. In the horizontal numerically-controlled machine tool to the mould course of working by, cylinder 750 of liftout mechanism 700 is supported to the butt of mould by the processing, can further avoid by the mould of working produce the displacement by horizontal numerically-controlled machine tool course of working for it is more accurate to process.

In order to drive the carrying mechanism 400 to move on the guide rail 510, in one embodiment, the first driver includes a first motor 520 and a first lead screw (not shown), the first motor 520 is in driving connection with the first lead screw, the carrying mechanism 400 has a screw hole, the first lead screw is inserted into the screw hole, and the first lead screw is in threaded connection with a side wall of the screw hole.

In this embodiment, a cavity is arranged in the sliding seat 410, the side wall of the cavity is connected with a screwing part, the screwing part is provided with the screw hole, the side walls at the two ends of the cavity are further provided with through holes for the screw rod to pass through, and the first screw rod is parallel to the guide rail 510, so that the first motor 520 works to drive the first screw rod to rotate, thereby driving the sliding seat 410 to move along the axial direction of the screw rod, and further enabling the sliding seat 410 to move along the guide rail 510.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. The utility model provides a crouch mills compounding machine which characterized in that includes: the device comprises a rack, a material ejecting mechanism, a horizontal numerical control machine tool, a bearing mechanism and a movement mechanism;

the horizontal numerical control machine tool and the material ejecting mechanism are respectively arranged on the rack;

the moving mechanism comprises a first driver and a guide rail, the guide rail is arranged on the rack, the first driver is in driving connection with the bearing mechanism, the bearing mechanism is arranged on the guide rail in a sliding mode, the bearing mechanism is used for bearing a processed die, the horizontal numerical control machine is arranged on one side of the guide rail, the ejection mechanism is arranged on the other side of the horizontal numerical control machine, the ejection mechanism and the horizontal numerical control machine are arranged oppositely, and the ejection mechanism is used for abutting against the other side of the processed die when the horizontal numerical control machine processes one side of the processed die so that the processed die is clamped and fixed.

2. The horizontal milling compound machine according to claim 1, wherein the material ejecting mechanism comprises a fixed seat, a driving component and a roller component, the fixed seat is fixedly connected with the frame, the fixed seat is arranged on one side of the guide rail, the driving component is arranged on the fixed seat, the driving component is in driving connection with the roller component, and the driving component is used for driving the roller component to abut against the processed die.

3. The horizontal milling compound machine as claimed in claim 2, wherein the roller assembly comprises a support and a roller, the support is slidably disposed on the fixing seat, the roller is rotatably disposed on the support, and the roller is configured to rotatably abut against the processed mold.

4. The horizontal milling compound machine as claimed in claim 3, wherein the roller assembly further comprises two clamping blocks, the two clamping blocks are oppositely arranged and fixedly arranged on one side of the support close to the guide rail, each clamping block is provided with a supporting hole, one end of the roller is rotatably arranged in one supporting hole, and the other end of the roller is rotatably arranged in the other supporting hole.

5. The horizontal milling compound machine as claimed in claim 3, wherein the driving assembly comprises an ejection driving motor and an ejection driving screw rod, and the ejection driving motor is in driving connection with the support through the ejection driving screw rod.

6. The horizontal milling compound machine as claimed in claim 3, wherein the fixing base is provided with at least one slide rail, the support is provided with at least one slide block, and each slide block is slidably disposed on one slide rail.

7. The horizontal milling compound machine according to claim 1, further comprising two cutter head mechanisms, wherein the two cutter head mechanisms are respectively and fixedly connected with the frame, each cutter head mechanism comprises a cutter head, the two cutter heads are oppositely arranged, and the two cutter heads are respectively arranged at two sides of the guide rail.

8. A horizontal milling compound machine as claimed in any one of claims 1 to 7, wherein the horizontal numerical control machine comprises a milling cutter head, a cutter head support, a sliding seat, a base, a traverse actuator and a vertical actuator, the base is fixedly connected with the frame and is arranged on one side of the guide rail, the base is provided with a traverse rail, the sliding seat is slidably arranged on the traverse rail, the traverse rail is perpendicular to the guide rail, the traverse actuator is in driving connection with the sliding seat, the sliding seat is provided with a vertical rail, the cutter head support is slidably arranged on the vertical rail, the vertical rail is perpendicular to the guide rail and is perpendicular to the traverse rail, the vertical actuator is in driving connection with the cutter head support, and the milling cutter head is detachably mounted on the cutter head support.

9. A horizontal milling compound machine as claimed in any one of claims 1 to 7, wherein the carrying mechanism includes a sliding seat, a rotating seat, a second driver and a pressing assembly, the first driver is drivingly connected with the sliding seat, the sliding seat is slidably disposed on the guide rail, the second driver is disposed on the sliding seat, the second driver is rotatably connected with the rotating seat, the rotating seat is rotatably disposed on the sliding seat, the pressing assembly is movably disposed on the sliding seat, and the pressing assembly is used for pressing the mold onto the rotating seat.

10. The horizontal milling compound machine as claimed in claim 9, wherein the press-down assembly comprises a support frame and a press-down driver, the support frame is arranged on the sliding seat, the press-down driver is arranged on the support frame, and a power output end of the press-down driver is used for pressing the die on the rotating seat.

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