A multi-axis cam turret machining machine and method of use thereof

Abstract

The application discloses a multi-axis cam rotary table processing machine tool and a use method thereof, which comprises a first function mechanism, the first function mechanism comprising a base and a rotating part, the top of the base being fixedly connected with a mounting seat, the outer surfaces of the two sides of the mounting seat being rotatably connected with synchronous frames, and the rotating part being arranged on the base. In the application, when in use, the equipment is stably arranged at a specified use position through the base, and the first function mechanism and the second function mechanism are conveniently installed and dismounted, so that the equipment is conveniently maintained, the to-be-processed articles are fixed on the top of the rotary table body, and then according to the actual processing requirements of the to-be-processed articles, if the processing modes of the to-be-processed articles are the same, the driving motor is controlled to be started, so that the driving motor can effectively drive the driving gear to rotate through the rotating worm and the rotating worm wheel, and then the driving gear can effectively drive the rotating gear ring to rotate.

Description

Technical Field

[0001] This invention belongs to the field of machine tool equipment technology, specifically a multi-axis cam rotary table machining machine tool and its usage method. Background Technology

[0002] Cam-type machine tools are automatic machine tools that use cams to control the machining program. They are widely used in automated machining tools and are characterized by high machining speed, high machining accuracy, automatic feeding, automatic shutdown when the material is used up, and one person can operate multiple machine tools.

[0003] However, in the existing technology, the actual structure of the existing cam rotary table machine tool is fixed, which means that it can only process a single item at most. This results in low actual efficiency of the existing cam rotary table machine tool. At the same time, the fixed structure makes the existing cam rotary table machine tool difficult to maintain and can easily cause the processing process to stop, which in turn affects the overall processing efficiency and results in poor actual performance of the existing cam rotary table machine tool. Summary of the Invention

[0004] The purpose of this invention is to provide a multi-axis cam rotary table machine tool and its usage method that can conveniently adjust its own structure according to actual usage conditions, thereby enabling the equipment to process multiple items simultaneously, while also facilitating equipment inspection and maintenance, and ensuring that item processing can continue during maintenance, thus ensuring actual processing efficiency.

[0005] The technical solution adopted in this invention is as follows: A multi-axis cam rotary table machining center includes: a first functional mechanism, the first functional mechanism including a base and a rotating component, a mounting seat fixedly connected to the top of the base, synchronization frames rotatably connected to both outer surfaces of the mounting seat, a linkage gear ring fixedly connected inside each synchronization frame, and the rotating component disposed on the base; and

[0006] The second functional mechanism comprises two sets, each including a mounting frame. A base column is rotatably connected to the bottom surface of the mounting frame. Multiple slots are equidistantly provided on the outer surface of the base column. A first linkage ring is slidably fitted onto the outer surface of the base column through the slots, and a second linkage ring is slidably fitted onto the outer surface of the base column. An automatic linkage rod is rotatably connected between the inner walls of the two sides of the mounting frame, and the automatic linkage rod engages with the second linkage ring. A synchronous linkage rod is rotatably connected to the inner wall of one side of the mounting frame, and the synchronous linkage rod engages with the first linkage ring. A turntable body is fixedly connected to the top of the base column.

[0007] The rotating component includes a connecting frame, two outer surfaces of the connecting frame and two synchronization frames, which are fixedly connected. The connecting frame is rotatably connected between the inner walls of the mounting base on both sides. A synchronization gear ring is sleeved on the outer surface of the connecting frame. A support shaft is rotatably connected between the inner walls of the mounting base on both sides. A synchronization gear and a synchronization worm gear are sleeved on the outer surface of the support shaft.

[0008] The mounting base has a synchronous worm gear rotatably connected to one inner wall, which meshes with a synchronous worm wheel. A synchronous motor is fixedly connected to the other inner wall, and the output end of the synchronous motor is fixedly connected to one end of the synchronous worm gear.

[0009] The rotating components are provided in two sets. Each set of rotating components includes a support frame, which is fixedly connected to the top of the base. An installation shaft is rotatably connected to the inner wall of one side of the support frame, and a rotating worm gear and a drive gear are sleeved on the outer surface of the installation shaft.

[0010] Each of the support frames has a rotating worm gear rotatably connected to one outer surface, and each rotating worm gear meshes with a rotating worm wheel. Each of the support frames has a drive motor fixedly connected to one inner wall, and the output end of each drive motor is fixedly connected to one end of the corresponding rotating worm gear.

[0011] Each of the mounting frames has a rotating frame fixedly connected to both outer surfaces, and each rotating frame has multiple mounting slots equidistantly spaced on its outer surface.

[0012] Each of the mounting slots has a support wheel rotatably connected to one side of its inner surface wall. Two of the rotating frames have a rotating gear ring fixedly connected to one side of their outer surface. The two rotating gear rings and their corresponding rotating frames extend into the interior of their respective support frames. Each rotating gear ring meshes with its corresponding drive gear. The other two rotating frames extend into the interior of their respective synchronization frames at one end.

[0013] Each of the automatic linkage rods has a first bevel gear fitted on its outer surface, an automatic motor is fixedly connected to the bottom surface inside each mounting frame, a second bevel gear is fitted at the output end of each automatic motor, each second bevel gear meshes with a corresponding first bevel gear, multiple reset frames are fixedly connected at equal intervals on the outer surface of each second linkage ring, a locking rod slides through one side of the outer surface of each reset frame, one end of each locking rod extends into the corresponding slot, a reset spring is slidably fitted on the outer surface of each locking rod, and a stop piece is fitted on the outer surface of each locking rod.

[0014] Each mounting frame has a stop rod rotatably connected to the inner wall of the other side. One end of each stop rod slides through the inner wall of the corresponding rotating frame. A connecting gear is sleeved on the outer surface of each stop rod. Each connecting gear meshes with the corresponding linkage gear ring. A support spring and a stop tube are slidably sleeved on the outer surface of each stop rod. One side of the inner wall of each stop tube is engaged with one end of the corresponding synchronous linkage rod.

[0015] A method of using a multi-axis cam rotary table machining center includes the following steps:

[0016] S1. Synchronous Processing: The base securely positions the equipment in the designated location, facilitating the installation and disassembly of both the first and second functional mechanisms, thus simplifying equipment maintenance. The item to be processed is fixed to the top of the turntable. Based on the actual processing requirements, if the processing methods for the items are the same, the drive motor is activated. This drives the drive gear via a rotating worm and worm wheel, which in turn rotates the rotating gear ring. The rotating gear ring, in turn, rotates the corresponding mounting frame, ensuring the item on top of the turntable is in a suitable processing state. Then, the synchronous motor is activated, driving the synchronous worm gear... The rod and the worm gear drive the synchronizing gear to rotate. The rotating synchronizing gear, in conjunction with the synchronizing gear ring, drives the connecting frame to rotate, which in turn drives the corresponding synchronizing frame to rotate. The rotating synchronizing frame drives the connecting gear ring to rotate, which in turn drives the corresponding abutment rod to rotate through the connecting gear. Supported by the support spring, the abutment rod drives the synchronizing linkage rod to rotate through the abutment tube, which in turn drives the two synchronizing linkage rods to rotate synchronously. The synchronizing linkage rods then drive the two first linkage rings to rotate synchronously, which in turn drive the base column to rotate synchronously. The base column then drives the corresponding turntable body to rotate, allowing the workpiece to be processed to be processed synchronously.

[0017] S2. Independent Processing: If the actual processing methods of the items to be processed are different, the synchronous linkage rod can be removed, and the automatic motor can be started by controlling the start of the automatic motor. The automatic motor can drive the corresponding automatic linkage rod to rotate through the second bevel gear and the first bevel gear. In turn, the automatic linkage rod can drive the second linkage ring to rotate. The second linkage ring can drive the bottom column to rotate through the locking rod and the locking groove. In turn, the bottom column can drive the corresponding turntable body to rotate. Thus, the equipment can process different items to be processed at the same time.

[0018] In summary, due to the adoption of the above technical solution, the beneficial effects of the present invention are:

[0019] In this invention, during use, the device is securely positioned in the designated location using a base, facilitating the installation and disassembly of the first and second functional mechanisms, thereby simplifying equipment maintenance. The item to be processed is fixed to the top of the turntable body. Based on the actual processing requirements of the item, if the processing methods are the same, the drive motor is activated, enabling it to effectively rotate the drive gear via a rotating worm and worm wheel. This drive gear then effectively rotates the rotating gear ring, which in turn, in conjunction with the corresponding rotating frame, effectively rotates the corresponding mounting frame. This ensures the item to be processed on the top of the turntable body is in a suitable processing state. Furthermore, the synchronous motor is activated, enabling it to effectively rotate the synchronous gear via a synchronous worm and worm wheel. The rotating synchronous gear, in conjunction with the synchronous gear ring, effectively rotates the connecting frame, which in turn rotates the corresponding synchronous frame. The rotating synchronous frame then effectively rotates the connecting gear ring, which, through the connecting gear, effectively rotates the corresponding abutment rod, thus supporting the spring... Supported by the spring, the stop rod can effectively drive the synchronous linkage rod to rotate through the stop tube, thereby enabling the two synchronous linkage rods to rotate synchronously. This, in turn, allows the two first linkage rings to rotate synchronously, which in turn drives the base column to rotate synchronously. The base column then drives the corresponding turntable body to rotate, allowing the workpieces to be processed synchronously. If the actual processing methods for the workpieces differ, the synchronous linkage rod can be removed, and the automatic motor can be started. The automatic motor, through the second and first bevel gears, can effectively drive the corresponding automatic linkage rod to rotate. This, in turn, allows the automatic linkage rod to rotate the second linkage ring, which, through the locking rod and slot, effectively drives the base column to rotate. The base column then drives the corresponding turntable body to rotate, enabling the equipment to process different workpieces simultaneously. This significantly improves the equipment's performance and allows processing to continue even if a secondary functional mechanism malfunctions, ensuring the equipment efficiently performs its intended functions. Attached Figure Description

[0020] Figure 1 This is a frontal perspective view of the present invention;

[0021] Figure 2 This is a rear perspective view of the present invention;

[0022] Figure 3 This is a frontal sectional perspective view of the present invention;

[0023] Figure 4 This is a frontal sectional view of the first functional mechanism of the present invention.

[0024] Figure 5 For the present invention Figure 4 Enlarged view of section A in the middle;

[0025] Figure 6 This is a frontal sectional view of the second functional mechanism of the present invention.

[0026] Figure 7 For the present invention Figure 6 Enlarged view of section B;

[0027] Figure 8 For the present invention Figure 6 Enlarged view of section C;

[0028] Figure 9 This is a rear sectional view of the second functional mechanism of the present invention.

[0029] In the diagram, the markings are as follows: 1. First functional mechanism; 101. Base; 102. Support frame; 103. Rotating worm gear; 104. Drive motor; 105. Drive gear; 106. Mounting base; 107. Connecting frame; 108. Synchronous gear ring; 109. Synchronous gear; 110. Synchronous worm gear; 111. Synchronous frame; 112. Linking gear ring; 113. Synchronous motor; 2. Second functional mechanism; 201. Mounting frame; 2 02. Turning frame; 203. Support wheel; 204. Rotating gear ring; 205. Support rod; 206. Support spring; 207. Support tube; 208. Synchronous linkage rod; 209. First linkage ring; 210. Base column; 211. Second linkage ring; 212. Reset frame; 213. Locking rod; 214. Reset spring; 215. Automatic linkage rod; 216. Automatic motor; 217. Connecting gear; 218. Turntable body. Detailed Implementation

[0030] To make the objectives, technical solutions, and advantages of this invention clearer, the invention will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative and not intended to limit the invention.

[0031] Example 1

[0032] Reference Figures 1-9A multi-axis cam rotary table machining center includes a first functional mechanism 1 and a second functional mechanism 2. The first functional mechanism 1 includes a base 101 and a rotating component. The base 101 provides a mounting foundation for other functional components of the machine, allowing the machine to be stably installed in a designated position. A mounting seat 106 is fixedly connected to the top of the base 101, facilitating the installation of other functional components. Synchronization frames 111 are rotatably connected to both outer surfaces of the mounting seat 106, enabling the synchronization frames to coordinate with... The connecting frame 107 rotates synchronously. Each synchronous frame 111 has a fixed connecting gear ring 112 inside. The connecting gear ring 112, in conjunction with the connecting gear 217, can synchronously drive the push rod 205 to rotate. The rotating component is set on the base 101. There are two sets of second functional mechanisms 2. Each set of second functional mechanisms 2 includes a mounting frame 201. The mounting frame 201 facilitates the installation of other functional components of the equipment. The bottom surface inside the mounting frame 201 is rotatably connected to a bottom column 210. The bottom column 210 is conveniently set up. For the installation and setup of other functional components of the equipment, multiple slots are equidistantly provided on the outer surface of the base column 210. These slots effectively restrict the positions of the first linkage ring 209 and the locking rod 213. The first linkage ring 209 is slidably fitted onto the outer surface of the base column 210 through the slots. The first linkage ring 209, in conjunction with the synchronous linkage rod 208, effectively drives the base column 210 to rotate. A second linkage ring 211 is slidably fitted onto the outer surface of the base column 210. The second linkage ring 211, in conjunction with the locking rod 213 and the slots, effectively drives the base column... 210 rotates, and an automatic linkage 215 is rotatably connected between the inner surfaces of the two sides of the mounting frame 201. The automatic linkage 215 can effectively drive the second linkage ring 211 to rotate. The automatic linkage 215 and the second linkage ring 211 mesh. A synchronous linkage 208 is rotatably connected to the inner surface of one side of the mounting frame 201. The synchronous linkage 208 meshes with the first linkage ring 209. A turntable body 218 is fixedly connected to the top of the bottom column 210. The turntable body 218 facilitates the placement and fixing of the items to be processed.

[0033] Reference Figures 3-9The rotating component includes a connecting frame 107, which facilitates the installation of other functional components of the equipment. The outer surfaces of both sides of the connecting frame 107 and two synchronization frames 111 are fixedly connected. The connecting frame 107 is rotatably connected between the inner walls of both sides of the mounting base 106. A synchronization gear ring 108 is fitted onto the outer surface of the connecting frame 107. The synchronization gear ring 108, in conjunction with the synchronization gear 109, synchronization worm gear 110, and synchronization worm, enables the synchronous motor 113 to effectively drive the synchronization gear ring 108 to rotate. A support shaft is rotatably connected between the inner walls of both sides of the mounting base 106. The outer surface of the support shaft is fitted with the synchronization gear 109 and synchronization worm gear 110. A synchronization worm is rotatably connected to one inner wall of the mounting base 106. A synchronous worm gear and a synchronous worm wheel 110 mesh. A synchronous motor 113 is fixedly connected to the inner wall of the other side of the mounting base 106. The output end of the synchronous motor 113 is fixedly connected to one end of the synchronous worm gear. There are two sets of rotating components. Each set of rotating components includes a support frame 102. The support frame 102 facilitates the installation of other functional components of the equipment. The support frame 102 is fixedly connected to the top of the base 101. A mounting shaft is rotatably connected to the inner wall of one side of the support frame 102. A rotating worm wheel 103 and a drive gear 105 are sleeved on the outer surface of the mounting shaft. A rotating worm gear is rotatably connected to the outer surface of one side of each support frame 102. The rotating worm gear, in conjunction with the rotating worm wheel 103, can effectively drive the drive gear 105 to rotate. Each rotating worm gear and the rotating worm wheel 105... All worm gears 103 are engaged. A drive motor 104 is fixedly connected to the inner wall of one side of each support frame 102. The output end of each drive motor 104 is fixedly connected to one end of the corresponding rotating worm. A rotating frame 202 is fixedly connected to the outer surfaces of both sides of each mounting frame 201. The rotating frame 202 facilitates the installation of other functional components of the equipment. Multiple mounting slots are equidistantly provided on the outer surface of each rotating frame 202. These mounting slots facilitate the installation of support wheels 203. A support wheel 203 is rotatably connected to the inner wall of one side of each mounting slot. The support wheels 203 enable the synchronization frame 111 to rotate effectively. Rotating gear rings 204 are fixedly connected to the outer surface of one side of two rotating frames 202. The two rotating gear rings 204 and... Each rotating frame 202 extends into the interior of its corresponding support frame 102. Each rotating gear ring 204 meshes with its corresponding drive gear 105. Two other rotating frames 202 extend one end into their respective synchronization frames 111. A first bevel gear is fitted onto the outer surface of each automatic linkage rod 215. An automatic motor 216 is fixedly connected to the bottom surface of each mounting frame 201. The automatic motor 216 provides the automatic linkage rod 215 with the ability to rotate. A second bevel gear is fitted onto the output end of each automatic motor 216. Each second bevel gear meshes with its corresponding first bevel gear. Multiple reset frames 212 are equidistantly fixed to the outer surface of each second linkage ring 211. The reset frames 212 facilitate the installation and setup of other functional components of the equipment.Each reset frame 212 has a locking rod 213 slidingly extending through one side of its outer surface. One end of each locking rod 213 extends into a corresponding slot. A reset spring 214 is slidably fitted onto the outer surface of each locking rod 213. The reset spring 214, together with the abutment, effectively restricts the position of the locking rod 213. A abutment is fitted onto the outer surface of each locking rod 213. A stop rod 205 is rotatably connected to the inner wall of the other side of each mounting frame 201. The installation of the stop rod 205 facilitates the installation of other functional components of the equipment. The configuration includes a design where one end of each abutment 205 slides through the inner wall of the corresponding rotating frame 202. A connecting gear 217 is fitted onto the outer surface of each abutment 205. The connecting gear 217 enables the linkage gear ring 112 to effectively drive the abutment 205 to rotate. Each connecting gear 217 meshes with its corresponding linkage gear ring 112. A support spring 206 and an abutment tube 207 are slidably fitted onto the outer surface of each abutment 205. One inner wall of each abutment tube 207 engages with one end of the corresponding synchronous linkage rod 208.

[0034] The following provides a detailed description of the method of using a multi-axis cam rotary table machining center provided by an embodiment of the present invention. The method of use includes the following steps:

[0035] Step 1, Synchronous Processing: The equipment is securely positioned in the designated location using the base 101, facilitating the installation and disassembly of the first functional mechanism 1 and the second functional mechanism 2, thereby simplifying equipment maintenance. The item to be processed is fixed on the top of the turntable body 218. Based on the actual processing requirements of the item, if the processing method is the same, the drive motor 104 is activated. The drive motor 104 effectively drives the drive gear 105 to rotate via the rotating worm and rotating worm wheel 103. The drive gear 105 then effectively drives the rotating gear ring 204 to rotate, which in turn, in conjunction with the corresponding rotating frame 202, effectively drives the corresponding mounting frame 201 to rotate. This ensures the item to be processed on the top of the turntable body 218 is in a suitable processing state. Then, the synchronous motor 113 is activated, enabling it to effectively drive the synchronous worm and synchronous worm wheel 110. The gear 109 rotates, and the rotating synchronous gear 109, in conjunction with the synchronous gear ring 108, can effectively drive the connecting frame 107 to rotate. In turn, the connecting frame 107 can effectively drive the corresponding synchronous frame 111 to rotate. The rotating synchronous frame 111 can effectively drive the linkage gear ring 112 to rotate. In turn, the linkage gear ring 112, through the connecting gear 217, can effectively drive the corresponding abutment rod 205 to rotate. Under the support of the support spring 206, the abutment rod 205 can effectively drive the synchronous linkage rod 208 to rotate through the abutment tube 207. In turn, the two synchronous linkage rods 208 can rotate synchronously. In turn, the synchronous linkage rods 208 can synchronously drive the two first linkage rings 209 to rotate synchronously. In turn, the first linkage rings 209 can synchronously drive the base column 210 to rotate synchronously. In turn, the base column 210 can drive the corresponding turntable body 218 to rotate, so that the workpiece to be processed can be processed synchronously.

[0036] Step 2, Independent Processing: If the actual processing methods of the items to be processed are different, the synchronous linkage 208 is removed, and the automatic motor 216 is started by controlling it. The automatic motor 216 can effectively drive the corresponding automatic linkage 215 to rotate through the second bevel gear and the first bevel gear. The automatic linkage 215 can then effectively drive the second linkage ring 211 to rotate. The second linkage ring 211 can then effectively drive the bottom column 210 to rotate through the locking rod 213 and the locking groove. The bottom column 210 can then effectively drive the corresponding turntable body 218 to rotate. This allows the equipment to process different items to be processed simultaneously, thereby improving the actual use effect of the equipment. At the same time, even if a certain second functional mechanism 2 fails, the processing of items can continue, enabling the equipment to efficiently realize its intended functions.

[0037] The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention. Any modifications, equivalent substitutions, and improvements made within the spirit and principles of the present invention should be included within the protection scope of the present invention.

Claims

1. A multi-axis cam rotary table machining center, characterized in that, include: A first functional mechanism (1) includes a base (101) and a rotating component. A mounting base (106) is fixedly connected to the top of the base (101). Synchronization frames (111) are rotatably connected to both outer surfaces of the mounting base (106). A linkage gear ring (112) is fixedly connected inside each synchronization frame (111). The rotating component is mounted on the base (101). The second functional mechanism (2) is provided in two sets. Each set of the second functional mechanism (2) includes a mounting frame (201). The bottom surface of the mounting frame (201) is rotatably connected to a bottom column (210). The outer surface of the bottom column (210) is provided with multiple slots at equal intervals. The outer surface of the bottom column (210) is slidably fitted with a first linkage ring (209) through the slots. The outer surface of the bottom column (210) is slidably fitted with a second linkage ring (211). The inner surface walls on both sides of the mounting frame (201) are rotatably connected to an automatic linkage rod (215). The automatic linkage rod (215) meshes with the second linkage ring (211). The inner surface wall on one side of the mounting frame (201) is rotatably connected to a synchronous linkage rod (208). The synchronous linkage rod (208) meshes with the first linkage ring (209). The top of the bottom column (210) is fixedly connected to a turntable body (218). The rotating component includes two sets of support frames (102). The support frames (102) are fixedly connected to the top of the base (101). An installation shaft is rotatably connected to the inner wall of one side of the support frame (102). A rotating worm gear (103) and a drive gear (105) are sleeved on the outer surface of the installation shaft. Each of the support frames (102) has a rotating worm gear rotatably connected to one side of its outer surface. Each of the rotating worm gears meshes with a rotating worm wheel (103). Each of the support frames (102) has a drive motor (104) fixedly connected to one side of its inner wall. The output end of each drive motor (104) is fixedly connected to one end of the corresponding rotating worm gear. Each of the mounting frames (201) has a rotating frame (202) fixedly connected to its outer surfaces on both sides, and each of the rotating frames (202) has multiple mounting slots equidistantly provided on its outer surface; Each of the mounting slots has a support wheel (203) rotatably connected to the inner wall of one side. Two of the rotating frames (202) have a rotating gear ring (204) fixedly connected to the outer surface of one side. The two rotating gear rings (204) and the corresponding rotating frames (202) extend into the interior of the corresponding support frame (102). Each rotating gear ring (204) meshes with the corresponding drive gear (105). One end of the other two rotating frames (202) extends into the interior of the corresponding synchronization frame (111).

2. The multi-axis cam rotary table machining tool as described in claim 1, characterized in that: The rotating component also includes a connecting frame (107), the outer surfaces of the two sides of the connecting frame (107) and two synchronization frames (111) are fixedly connected respectively, the connecting frame (107) is rotatably connected between the inner walls of the two sides of the mounting base (106), the outer surface of the connecting frame (107) is fitted with a synchronization gear ring (108), the two sides of the mounting base (106) are rotatably connected between the inner walls of the two sides, and the outer surface of the support shaft is fitted with a synchronization gear (109) and a synchronization worm gear (110).

3. The multi-axis cam rotary table machining tool as described in claim 2, characterized in that: A synchronous worm gear is rotatably connected to the inner wall of one side of the mounting base (106), and the synchronous worm gear meshes with the synchronous worm wheel (110). A synchronous motor (113) is fixedly connected to the inner wall of the other side of the mounting base (106), and the output end of the synchronous motor (113) is fixedly connected to one end of the synchronous worm gear.

4. The multi-axis cam rotary table machining tool as described in claim 3, characterized in that: Each of the automatic linkage rods (215) has a first bevel gear fitted on its outer surface. Each of the mounting frames (201) has an automatic motor (216) fixedly connected to its inner bottom surface. Each of the automatic motors (216) has a second bevel gear fitted at its output end. Each second bevel gear meshes with the corresponding first bevel gear. Each of the second linkage rings (211) has multiple reset frames (212) fixedly connected at equal intervals on its outer surface. Each of the reset frames (212) has a locking rod (213) slidingly passing through one side of its outer surface. One end of each locking rod (213) extends into the corresponding slot. Each locking rod (213) has a reset spring (214) slidably fitted on its outer surface. Each locking rod (213) has a stop piece fitted on its outer surface.

5. The multi-axis cam rotary table machining tool as described in claim 4, characterized in that: Each mounting frame (201) has a stop rod (205) rotatably connected to the inner wall of the other side. One end of each stop rod (205) slides through the inner wall of the corresponding rotating frame (202). A connecting gear (217) is sleeved on the outer surface of each stop rod (205). Each connecting gear (217) meshes with the corresponding linkage gear ring (112). A support spring (206) and a stop tube (207) are slidably sleeved on the outer surface of each stop rod (205). The inner wall of one side of each stop tube (207) is engaged with one end of the corresponding synchronous linkage rod (208).

6. A method of using a multi-axis cam rotary table machining center, characterized in that, When applied to a multi-axis cam rotary table machining center as described in claim 5, the method includes the following steps: S1. Synchronous processing: The equipment is securely set in the designated position by the base (101), which facilitates the installation and disassembly of the first functional mechanism (1) and the second functional mechanism (2), and facilitates the maintenance of the equipment. The item to be processed is fixed on the top of the turntable body (218). Then, according to the actual processing requirements of the item to be processed, if the processing methods of the items to be processed are the same, the drive motor (104) is started by controlling the start of the drive motor (104), so that the drive motor (104) can drive the drive gear (105) to rotate through the rotating worm and rotating worm wheel (103), so that the drive gear (105) can drive the rotating gear ring (204) to rotate, so that the rotating gear ring (204) cooperates with the corresponding rotating frame (202) to drive the corresponding mounting frame (201) to rotate, so that the item to be processed on the top of the turntable body (218) can be in a suitable processing state. Then, the synchronous motor (113) is started by controlling the start of the synchronous motor (113), so that the synchronous motor (113) can drive the synchronous gear through the synchronous worm and synchronous worm wheel (110). (109) rotates, and the rotating synchronous gear (109) in conjunction with the synchronous gear ring (108) can drive the connecting frame (107) to rotate, thereby enabling the connecting frame (107) to drive the corresponding synchronous frame (111) to rotate. The rotating synchronous frame (111) can drive the connecting gear ring (112) to rotate, thereby enabling the connecting gear ring (112) to drive the corresponding abutment (205) to rotate through the connecting gear (217). Then, under the support of the support spring (206), the abutment (205) rotates. 05) The synchronous linkage rod (208) can be rotated by the abutment tube (207), thereby enabling the two synchronous linkage rods (208) to rotate synchronously, thereby enabling the synchronous linkage rods (208) to drive the two first linkage rings (209) to rotate synchronously, thereby enabling the first linkage rings (209) to drive the bottom column (210) to rotate synchronously, thereby enabling the bottom column (210) to drive the corresponding turntable body (218) to rotate, thereby enabling the items to be processed to be processed synchronously; S2. Independent processing: If the actual processing methods of the items to be processed are different, the synchronous linkage rod (208) is removed, and the automatic motor (216) is started by controlling it. The automatic motor (216) can drive the corresponding automatic linkage rod (215) to rotate through the second bevel gear and the first bevel gear. The automatic linkage rod (215) can drive the second linkage ring (211) to rotate. The second linkage ring (211) can drive the bottom column (210) to rotate through the locking rod (213) and the locking groove. The bottom column (210) can drive the corresponding turntable body (218) to rotate. Thus, the equipment can process different items to be processed at the same time.

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