CN218518270U - Main shaft bearing lubricating structure and main shaft - Google Patents

Abstract

The utility model relates to a main shaft bearing lubricating structure and main shaft relates to the lubricated technical field of lathe main shaft, is used for solving the utility model discloses a comparatively complicated problem of bearing frame structural design of main shaft. The main shaft bearing lubricating structure includes: the spindle bearing is arranged on the periphery of the spindle core, and a first flow passage is arranged in the spindle core; and the pull rod assembly is arranged in the shaft core in a sliding mode along the first direction, a second flow passage is arranged in the pull rod assembly, and the second flow passage is communicated with the first flow passage. The technical scheme of the utility model under the condition that does not influence the original function of pull rod assembly, with the integrated setting of oil-gas lubrication passageway part in axle core and pull rod assembly, pull rod assembly has compatibly carried the function of lubricated liquid, and lubricated liquid can lubricate main shaft bearing through the inside bearing installation cavity that flows in of pull rod assembly, need not like this at bearing frame design lubrication channel to the problem that the bearing frame structural design of main shaft is complicated among the correlation technique has been avoided.

Description

Main shaft bearing lubricating structure and main shaft

Technical Field

The utility model relates to a lubricated technical field of lathe main shaft relates to a main shaft bearing lubricating structure and main shaft very much.

Background

The oil-gas lubrication technology has been widely applied to a main shaft of a loose broach of a machine tool, in the prior art, an oil-gas lubrication channel of a main shaft bearing lubrication structure is usually partially arranged in a bearing seat, a plurality of communication holes are processed inside the bearing seat for conveying lubricating liquid, and the specific structure can be referred to chinese patent CN113145873A. Therefore, the structural design of the bearing seat is complex, the processing difficulty of the bearing seat is high, and the processing cost of the main shaft bearing lubricating structure is increased.

In other words, the bearing seat of the spindle in the related art has a problem of complicated structural design.

SUMMERY OF THE UTILITY MODEL

The utility model provides a main shaft bearing lubricating structure and main shaft for solve the comparatively complicated problem of bearing frame structural design of main shaft.

The utility model provides a main shaft bearing lubricating structure, include: the spindle bearing is arranged on the periphery of the spindle core, and a first flow passage is arranged in the spindle core; the pull rod assembly is arranged in the shaft core in a sliding mode along the first direction, a second flow passage is arranged in the pull rod assembly, and the second flow passage is communicated with the first flow passage; the liquid inlet end of the first flow channel is communicated with a bearing installation cavity for installing the main shaft bearing, and lubricating liquid can flow into the bearing installation cavity through the second flow channel and the first flow channel in sequence and lubricate the main shaft bearing when the pull rod assembly is used for loosening or pulling a cutter.

In one embodiment, a tie rod assembly includes: the pull rod is arranged in the shaft core in a sliding mode along the first direction; and the pull rod inner rod is arranged in the pull rod, an annular channel is arranged between the pull rod inner rod and the pull rod, and the second flow channel comprises an annular channel.

In one embodiment, a first communication hole and a second communication hole are formed in the outer circumference of the pull rod and spaced apart from the first communication hole in the first direction, the first and second communication holes are both communicated with the annular channel, the second communication hole is communicated with the first flow channel, and the second flow channel further includes the first and second communication holes.

In one embodiment, the tie rod assembly further comprises a tie rod sleeve, the tie rod sleeve is arranged between the tie rod assembly and the shaft core, and a third flow passage is arranged in the tie rod sleeve and is used for communicating the first flow passage with the second flow passage.

In one embodiment, the liquid inlet end of the third flow channel is provided with a groove, and the liquid outlet end of the second flow channel always slides in the groove in the process of loosening or pulling the pull rod assembly.

In one embodiment, a seal is provided at the communication of the third flow passage with the first flow passage, and/or a seal is provided at the communication of the third flow passage with the second flow passage.

In one embodiment, the number of the spindle bearings is multiple, the spindle bearing lubricating structure further includes a spacer ring assembly, the spacer ring assembly is disposed between two adjacent spindle bearings and used for axially limiting the spindle bearings, a fourth flow passage is disposed in the spacer ring assembly and is communicated with the first flow passage, and lubricating fluid flows out of the fourth flow passage to lubricate the spindle bearings.

In one embodiment, a spacer ring assembly comprises: the inner spacer is arranged on the periphery of the shaft core, a flow channel is arranged in the inner spacer, and the flow channel is communicated with the first flow channel; and the outer spacer ring is positioned on the outer side of the inner spacer ring, a radial gap communicated with the flow channel is formed between the outer spacer ring and the inner spacer ring, and the fourth flow channel comprises the flow channel and the radial gap.

The utility model also provides a main shaft, it includes: the main shaft bearing lubricating structure; the shaft sleeve assembly is arranged on the periphery of the main shaft bearing lubricating structure; the oil cylinder is arranged at one end of the shaft sleeve assembly; the elastic assembly is arranged between the pull rod assembly and the shaft core; the bearing installation cavity is defined by the shaft sleeve assembly and the shaft core, the oil cylinder can drive the pull rod assembly to slide so as to achieve the cutter loosening function, and the elastic assembly can drive the pull rod assembly to reversely slide so as to achieve the cutter pulling function.

In one embodiment, the spindle bearing assembly further comprises a connecting disc assembly, the connecting disc assembly is arranged at one end, away from the spindle bearing, of the spindle core, a sealing cavity is defined among the connecting disc assembly, the spindle sleeve assembly and the oil cylinder, a liquid injection flow channel is arranged on the oil cylinder, and the liquid injection flow channel and the second flow channel are communicated with the sealing cavity.

In one embodiment, the sensing disc is arranged at one end of the pull rod assembly far away from the main shaft bearing, and the oil cylinder drives the pull rod assembly to slide by pushing the sensing disc.

In one embodiment, a flushing channel which is not communicated with the second flow channel is arranged in the pull rod assembly, and the spindle further comprises a pipe joint which is arranged on the oil cylinder in a penetrating mode and is communicated with the flushing channel.

In one embodiment, a liquid drainage flow passage is arranged in the shaft sleeve assembly, the liquid drainage flow passage is communicated with the bearing installation cavity, and lubricating liquid in the bearing installation cavity is discharged out of the main shaft through the liquid drainage flow passage.

In one embodiment, a spring installation cavity is formed between the shaft core and the pull rod assembly, the elastic assembly comprises at least one compression spring, the at least one compression spring is arranged in the spring installation cavity, and the at least one compression spring drives the pull rod assembly to slide reversely under the action of restoring force so as to realize broaching.

In one embodiment, when the elastic member includes a plurality of compression springs, a spacer is disposed between adjacent two of the compression springs.

Compared with the prior art, the utility model has the advantages of, under the condition that does not influence the original function of pull rod assembly (pine broach function), with the integrated setting of oil-gas lubrication passageway part in axle core and pull rod assembly, pull rod assembly has compatibly carried the function of lubricated liquid, lubricated liquid can lubricate main shaft bearing through the inside bearing installation cavity that flows in of pull rod assembly, need not like this at the lubricated passageway of bearing frame design to the problem that the bearing frame structural design of main shaft is complicated among the correlation technique has been avoided, has reduceed its processing degree of difficulty. And further, the processing cost of the main shaft bearing lubricating structure is reduced.

Drawings

The present invention will be described in more detail hereinafter based on embodiments and with reference to the accompanying drawings.

Fig. 1 is a schematic sectional structure view of the spindle bearing lubrication structure of the present invention (showing its assembling relationship with other parts of the spindle);

FIG. 2 shows another cross-sectional view of the spindle bearing lubrication structure of FIG. 1 (showing oil and gas lubrication passages);

FIG. 3 is a schematic cross-sectional view of the drawbar assembly in FIG. 1;

FIG. 4 is a schematic cross-sectional view of the pull rod cover of FIG. 1;

fig. 5 shows a schematic cross-sectional structure of the inner spacer in fig. 1.

Reference numerals:

10. a shaft core; 11. a first flow passage; 20. a drawbar assembly; 21. a second flow passage; 211. an annular channel; 212. a first communication hole; 213. a second communication hole; 22. an inner rod of the pull rod; 23. a pull rod; 24. flushing the channel; 30. a pull rod sleeve; 31. a third flow path; 311. a groove; 40. a seal member; 50. a spacer ring assembly; 51. a fourth flow channel; 52. an inner spacer ring; 521. a flow channel; 5211. a radial channel; 5212. an axial channel; 53. an outer space ring; 531. a radial gap; 100. a main shaft bearing lubricating structure; 200. a main shaft bearing; 300. a bushing assembly; 301. a liquid discharge flow channel; 302. a front end flange; 303. locking the nut; 304. a shaft sleeve; 305. a positioning sleeve; 306. a bearing seat; 400. an oil cylinder; 401. a liquid injection runner; 402. a cylinder body; 4021. a cavity; 403. a cylinder head body; 4031. pressing the channel; 404. a piston assembly; 4041. a piston; 4042. a piston seal; 500. an elastic component; 501. a compression spring; 502. a spacer; 600. a connecting disc assembly; 601. a connecting disc; 602. a composite seal; 700. an induction disc; 800. a pipe joint; 900. a sleeve.

Detailed Description

The present invention will be further explained with reference to the accompanying drawings.

It should be noted that the spindle in the present application is a main spindle of a broaching machine tool, the main spindle of the broaching machine tool is a core functional component of a numerical control machine tool, and a pull rod assembly 20 is driven by an oil cylinder 400 at the rear end of the main spindle to slide so as to realize a broaching action, thereby facilitating a tool holder replacement of the numerical control machine tool. After the tool handle is replaced, the pull rod assembly 20 is driven to slide reversely under the action of the elastic assembly 500, so that the broaching action can be realized, and the current tool handle is locked.

The first direction in the present application refers to the axial direction of the shaft core 10.

As shown in fig. 1 and 2, the present invention provides a main shaft bearing lubricating structure 100, which includes a shaft core 10 and a pull rod assembly 20. The spindle bearing 200 is arranged on the periphery of the shaft core 10, a first flow passage 11 is arranged in the shaft core 10, the pull rod assembly 20 is arranged in the shaft core 10 in a sliding manner along a first direction, a second flow passage 21 is arranged in the pull rod assembly 20, and the second flow passage 21 is communicated with the first flow passage 11; the liquid inlet end of the first flow passage 11 is communicated with a bearing installation cavity for installing the main shaft bearing 200, and in the process that the draw bar assembly 20 slides during the cutter beating, lubricating liquid can flow into the bearing installation cavity through the second flow passage 21 and the first flow passage 11 in sequence and lubricate the main shaft bearing 200.

In the above arrangement, under the condition that the original function of the pull rod assembly 20 is not affected (the function of the broaching tool is loosened), the oil-gas lubrication channel is partially integrated and arranged in the shaft core 10 and the pull rod assembly 20, the pull rod assembly 20 is compatible with the function of conveying lubricating liquid, the lubricating liquid can lubricate the main shaft bearing 200 by flowing into the bearing installation cavity through the inside of the pull rod assembly 20, so that the lubricating channel is not required to be designed on the bearing seat, the problem that the structural design of the bearing seat of the main shaft in the related art is complex is solved, and the processing difficulty is reduced. And further reduces the processing cost of the main shaft bearing lubricating structure 100.

Specifically, as shown in fig. 1-3, in one embodiment, the tie rod assembly 20 includes a tie rod 23 and a tie rod inner rod 22. Wherein, the pull rod 23 is arranged in the shaft core 10 in a sliding way along the first direction; and the pull rod inner rod 22 is arranged in the pull rod 23, an annular channel 211 is arranged between the pull rod inner rod 22 and the pull rod 23, and the second flow passage 21 comprises the annular channel 211.

In the above arrangement, the pull rod inner rod 22 is additionally arranged in the pull rod 23, and the annular channel 211 formed between the pull rod inner rod 22 and the pull rod 23 is used as a part of the oil-gas lubrication channel. This avoids deep-hole machining on the tie rod 23, and also eliminates the need to machine a deep hole in the sleeve as in the related art. Thereby having optimized the inner structure of main shaft and the structural design of oil-gas lubrication passageway, reduced the processing degree of difficulty and the cost of pull rod assembly 20 simultaneously.

Specifically, as shown in fig. 1 to 3, in one embodiment, a first communication hole 212 and a second communication hole 213 spaced apart from the first communication hole 212 in the first direction are provided on an outer circumference of the tie rod 23, the first communication hole 212 and the second communication hole 213 are both communicated with the annular channel 211, the second communication hole 213 is communicated with the first flow channel 11, wherein the second flow channel 21 further includes the first communication hole 212 and the second communication hole 213.

In the above arrangement, the lubricating liquid can flow into the first flow channel 11 sequentially through the first communication hole 212, the annular channel 211, and the second communication hole 213, thereby ensuring that the lubricating liquid can subsequently lubricate the spindle bearing 200.

Specifically, as shown in fig. 1 to 3, in one embodiment, the first communication hole 212 and the second communication hole 213 are both radial through holes, i.e., the central axes of the first communication hole 212 and the second communication hole 213 are perpendicular to the central axis of the annular channel 211.

Specifically, as shown in fig. 1 and 2, in one embodiment, the main shaft bearing lubricating structure 100 further includes a tie rod sleeve 30, the tie rod sleeve 30 is disposed between the tie rod assembly 20 and the shaft core 10, and a third flow passage 31 is disposed in the tie rod sleeve 30, and the third flow passage 31 is used for communicating the first flow passage 11 with the second flow passage 21.

In the above arrangement, the pull rod sleeve 30 has a switching communication function, i.e. the second flow passage 21 and the first flow passage 11 can be switched and communicated. Thereby ensuring that the lubricating fluid can flow from the second flow passage 21 into the first flow passage 11 to subsequently lubricate the main shaft bearing 200.

In addition, the pull rod cover 30 is separately provided, and the pull rod cover 30 and the shaft core 10 are not provided as an integrated structure. Therefore, the design of the shaft core 10 can be simplified, the processing difficulty is reduced, and the design and manufacturing cost of the main shaft is saved. And the separate arrangement of the pull rod sleeve 30 enables the position of the pull rod sleeve and the shaft core 10 to be adjustable, so that the pull rod sleeve is ensured to be installed at a proper position for communicating the second flow passage 21 with the first flow passage 11. Further, the problem that the second flow passage 21 and the first flow passage 11 cannot be communicated in a switching manner due to the fact that the position of the pull rod sleeve 30 is fixed and cannot be adjusted because the pull rod sleeve 30 and the shaft core 10 are arranged into an integrated structure is solved.

Note that, if the pull rod cover 30 is provided as an integral structure with the shaft core 10, the second communication hole 213 may not communicate with the first flow passage 11 due to machining errors.

Specifically, as shown in fig. 1 and fig. 2, in one embodiment, the liquid inlet end of the third flow channel 31 is provided as a groove 311, and the liquid outlet end of the second flow channel 21 always slides in the groove 311 during the sliding process of the draw bar assembly 20.

In the above arrangement, since the liquid outlet end of the second flow passage 21 always slides in the groove 311 during the broaching, the pull rod assembly 20 slides from the broaching position to the broaching position, or from the broaching position to the broaching position. The liquid outlet end of the second flow passage 21 is always communicated with the groove 311. This ensures that the oil and gas lubrication passage can continuously supply the lubricating fluid to the main shaft bearing 200 without interruption due to the action of releasing the draw bar assembly 20 from the draw bar. Thereby realizing the continuous lubrication function of the main shaft bearing 200 by the main shaft bearing lubrication structure 100.

Specifically, as shown in fig. 1, 2 and 4, in one embodiment, the liquid outlet end of the third flow channel 31 is provided as a groove 311. The notch of the recess 311 has a size larger than the caliber of the inlet end of the first flow path 11. Even if the third flow channel 31 and the first flow channel 11 have a positional machining error, the third flow channel 31 can be surely communicated with the first flow channel 11 by providing the recess 311.

Specifically, in one embodiment, the recess 311 is an annular groove.

Specifically, as shown in fig. 1, fig. 2 and fig. 4, in one embodiment, the size of the liquid outlet end groove of the third flow channel 31 is smaller than that of the liquid inlet end groove of the third flow channel 31.

Of course, the two grooves 311 may be equally sized according to actual conditions. Alternatively, the outlet-side groove of the third flow channel 31 is sized larger than the inlet-side groove thereof.

Specifically, as shown in fig. 1 and 2, in one embodiment, a seal 40 is provided at a communication of the third flow passage 31 and the first flow passage 11. The sealing member 40 is used to seal the communication between the third flow passage 31 and the first flow passage 11 to prevent leakage of the lubricating liquid.

Specifically, as shown in fig. 1 and 2, in one embodiment, a sealing member 40 is disposed at a communication portion of the second flow passage 21 and the third flow passage 31. The sealing member 40 is used to seal the communication between the second flow passage 21 and the third flow passage 31 to prevent the lubricating liquid from leaking.

Specifically, as shown in fig. 1 and fig. 2, in one embodiment, the number of the spindle bearings 200 is two, the spindle bearing lubricating structure 100 further includes a spacer ring assembly 50, the spacer ring assembly 50 is disposed between two adjacent spindle bearings 200 for axially limiting the spindle bearings 200, wherein a fourth flow passage 51 is disposed in the spacer ring assembly 50, the fourth flow passage 51 is communicated with the first flow passage 11, and the lubricating fluid flows out of the fourth flow passage 51 to lubricate the spindle bearings 200.

In the above arrangement, the fourth flow passage 51 can rapidly lead the lubricating liquid in the first flow passage 11 to the spindle bearing 200, which can enhance the lubricating effect of the spindle bearing lubricating structure 100. Thereby improving the lubrication efficiency of the main shaft bearing 200 by the main shaft bearing lubrication structure 100.

Specifically, as shown in fig. 1 and 2, in one embodiment, the liquid outlet end of the fourth flow passage 51 is located at an annular gap between the bearing outer ring and the bearing inner ring of the spindle bearing 200.

Specifically, as shown in fig. 1, 2, and 5, in one embodiment, the spacer ring assembly 50 includes an inner spacer ring 52 and an outer spacer ring 53. Wherein, the inner ring spacer 52 is arranged on the periphery of the shaft core 10, a flow channel 521 is arranged in the inner ring spacer 52, and the flow channel 521 is communicated with the first flow channel 11; and the outer spacer 53 is located outside the inner spacer 52, the outer spacer 53 and the inner spacer 52 have a radial gap 531 communicating with the flow passage 521, and the fourth flow passage 51 includes the flow passage 521 and the radial gap 531.

In the above arrangement, the distance between the two main shaft bearings 200 can be adjusted by the spacer ring assembly 50, and the spacer ring assembly 50 is provided in a split structure, so that the processing difficulty of the spacer ring assembly 50 can be reduced. Thereby saving the design and manufacturing costs of the main shaft bearing lubricating structure 100.

Meanwhile, a radial gap 531 between the inner spacer ring 52 and the outer spacer ring 53 can be used as a part of the fourth flow passage 51, so that the structural design of the oil-gas lubrication passage is optimized.

Specifically, as shown in fig. 1, 2, and 5, in one embodiment, the flow channel 521 includes a radial channel 5211 and two axial channels 5212. One end of the radial passage 5211 communicates with the first flow passage 11, and the other end of the radial passage 5211 communicates with the two axial passages 5212.

Specifically, as shown in fig. 5, in one embodiment, the axial passage 5212 is obliquely angled relative to the central axis of the spacer ring assembly 50, which may enable the lubricating fluid to precisely reach the bearing inner race raceway of the spindle bearing 200, thereby enhancing the lubricating effect of the lubricating fluid.

As shown in fig. 1 and fig. 2, the present invention further provides a spindle, which includes the spindle bearing lubrication structure 100, the sleeve assembly 300, the cylinder 400, and the elastic assembly 500. Wherein the boss assembly 300 is disposed on the outer circumference of the main shaft bearing lubrication structure 100, and the oil cylinder 400 is disposed at one end of the boss assembly 300. The resilient assembly 500 is disposed between the drawbar assembly 20 and the spindle 10. The sleeve assembly 300 and the mandrel 10 define a bearing installation cavity, the oil cylinder 400 can drive the pull rod assembly 20 to slide to realize a cutter loosening function, and the elastic assembly 500 can drive the pull rod assembly 20 to slide reversely to realize a cutter pulling function.

Specifically, as shown in fig. 1 and fig. 2, in one embodiment, the spindle further includes a connecting disc assembly 600, the connecting disc assembly 600 is disposed at an end of the spindle core 10 away from the spindle bearing 200, a sealed cavity is defined among the connecting disc assembly 600, the oil cylinder 400 and the sleeve assembly 300, the oil cylinder 400 is provided with an injection flow channel 401, and the injection flow channel and the second flow channel 21 are both communicated with the sealed cavity.

In the above arrangement, the arrangement of the land assembly 600 enables the land assembly and the oil cylinder 400 to define a sealed cavity, so as to ensure that the lubricating liquid can flow into the second flow channel 21 through the liquid injection flow channel, and further ensure that the lubricating liquid can flow to the spindle bearing 200 to lubricate the spindle bearing.

Specifically, as shown in fig. 1 and 2, in one embodiment, a land assembly 600 includes a land 601 and a composite seal 602 disposed at an outer periphery thereof. The composite seal 602 is used to seal the gap between the coupling plate 601 and the boss assembly 300.

Specifically, as shown in fig. 1 and 2, in one embodiment, the main shaft further includes a sensing plate 700, the sensing plate 700 is disposed on an end of the drawbar assembly 20 away from the main shaft bearing 200, and the cylinder 400 drives the drawbar assembly 20 to slide by pushing the sensing plate 700.

Specifically, as shown in fig. 1 and 2, in one embodiment, a flushing passage 24 is disposed in the drawbar assembly 20 and is not communicated with the second flow passage 21, and the spindle further includes a pipe joint 800, and the pipe joint 800 is disposed on the oil cylinder 400 and is communicated with the flushing passage 24.

In the above arrangement, the pipe joint 800 can be filled with high-pressure gas, and the high-pressure gas can then flow through the flushing passage 24, so as to flush dust at the end of the main shaft.

It should be noted that dust generated during the machining of the numerical control machine tool is very easily adsorbed on the tool holder and the spindle, and if the tool holder is replaced (replaced), the dust is not cleaned, so that the connection precision of the spindle and the tool holder is affected, the problems that the spindle vibrates excessively during rotation, the machining precision of a workpiece is poor and the like are caused, and once the dust enters the spindle, the service life of the spindle is affected. The provision of the flushing channel 24 thus enables a high pressure flushing of the dust to be carried out in order to avoid the problems described above.

Specifically, as shown in fig. 1 and 2, in one embodiment, a drainage channel 301 is provided in the sleeve assembly 300, the drainage channel 301 is communicated with the bearing installation cavity, and the lubricating fluid in the bearing installation cavity is discharged out of the main shaft through the drainage channel 301.

In the above arrangement, the drainage channel 301 is arranged to drain the cleaned lubricating fluid in time, so as to ensure that the lubricating fluid entering the bearing mounting cavity can continuously clean the spindle bearing 200.

Specifically, as shown in fig. 1 and 2, in one embodiment, a spring installation cavity is formed between the shaft core 10 and the pull rod assembly 20, the elastic assembly 500 includes two compression springs 501, two compression springs 501 are disposed in the spring installation cavity, and a spacer 502 is disposed between two adjacent compression springs 501. The compression spring 501 drives the drawbar assembly 20 to slide reversely under the restoring force to realize the broaching.

It should be noted that, on the premise of ensuring that sufficient axial force is provided to the pull rod 23, if the elastic assembly 500 is provided as a single compression spring 501, the elastic assembly is easily scratched against the inner wall of the shaft core 10 in the compression process, which may reduce the service life of the elastic assembly 500, and the processing difficulty may be increased if the length is too long. Since the end surfaces of the compression springs 501 are not flat, the spacers 502 are correspondingly added when a plurality of compression springs 501 are provided, because the spacers 502 must be in transition between the plurality of compression springs 501.

Specifically, as shown in fig. 1 and 2, in one embodiment, a sleeve 900 is disposed between the compression spring 501 and the pull rod sleeve 30.

Specifically, as shown in fig. 1 and 2, in one embodiment, the bushing assembly 300 includes a front end flange 302, a lock nut 303, a bushing 304, a locating bushing 305, and a bearing seat 306. A bearing housing 306 is provided on the outer periphery of the shaft core 10, and a lock nut 303 is screwed with the end of the shaft core 10. The retaining nut 303 is capable of compressing the front end flange 302 against the bearing seat 306. The lock nut 303, the front end flange 302, the bearing seat 306 and the shaft core 10 define a bearing mounting cavity. The shaft sleeve 304 is arranged on the periphery of the bearing seat 306, the positioning sleeve 305 is arranged on the periphery of the connecting disc 601, one end of the shaft sleeve 304 is in contact with the bearing seat 306 in an abutting mode, one end of the positioning sleeve 305 is in contact with the oil cylinder 400 in an abutting mode, and the other end of the shaft sleeve 304 is in contact with the other end of the positioning sleeve 305 in an abutting mode.

Specifically, as shown in fig. 1 and 2, in one embodiment, the cylinder 400 includes a cylinder block 402, a cylinder head 403, and a piston assembly 404. The piston assembly 404 includes, among other things, a piston 4041 and a piston seal 4042 disposed about its periphery. The cylinder block 402 is disposed on the locating sleeve 305 and the piston 4041 slides within a cavity 4021 defined by the cylinder block 402 and the cylinder block 403. The cavity 4021 is divided into two pressing cavities by the piston 4041, a pressing channel 4031 is arranged on the cylinder cover body 403, the pressing channel 4031 is communicated with the pressing cavities, and the axial movement of the piston 4041 is realized by pressing the pressing cavities.

Specifically, as shown in fig. 1 and 2, in one embodiment, the seal 40 is also disposed between the coupling 800 and the cylinder head 403, and between the cylinder head 402 and the piston 4041, and between the rod inner 22 and the rod 23, and between the rod inner 22 and the coupling 800.

It should be noted that the first flow channel 11, the second flow channel 21, the third flow channel 31, the flow channel 521, the liquid discharge flow channel 301, the liquid injection flow channel 401 and the seal cavity in the present application constitute a complete oil-gas lubrication channel. Be provided with many oil-gas lubrication passageways in the main shaft bearing lubricating structure in this application, many oil-gas lubrication passageways can let in lubricated liquid to main shaft bearing 200 simultaneously and lubricate to increase lubricated effect.

Specifically, the number of the liquid injection flow channel 401, the first flow channel 11, the third flow channel 31, the liquid discharge flow channel 301, the flow channel 521, the first communication hole 212, and the second communication hole 213 is four, and the liquid injection flow channel, the first flow channel 11, the third flow channel 31, the liquid discharge flow channel 301, the flow channel 521, and the first communication hole 212 are arranged at regular intervals in the circumferential direction of the main shaft. Four oil-gas lubrication channels are arranged in the main shaft bearing lubrication structure, and share one annular channel 211 and one sealing cavity.

The lubrication process of the lubricating fluid in the present application is described below:

in the application, lubricating liquid enters from the cylinder cover body 403, and enters the sealing cavity through a radial and axial lubricating channel (liquid injection flow channel 401) on the cylinder, and at the moment, under the actions of a combined sealing element 602 between the connecting disc 601 and the positioning sleeve 305, a sealing ring between the cylinder body 402 and the piston 4041, a piston sealing element 4042 between the piston 4041 and the cylinder cover body 403, a sealing ring (sealing element 40) between the pipe joint and the inner rod of the pull rod, a sealing ring (sealing element 40) between the pull rod 23 and the inner rod of the pull rod 22, a sealing ring (sealing element 40) between the cylinder cover body 403 and the pipe joint 800, and a sealing ring between the pull rod 23 and the shaft core 10, the lubricating liquid cannot leak to other positions, and enters a cavity (annular channel 211) between the pull rod 23 and the inner rod from the sealing cavity through a radial hole (first through hole 212) on the pull rod; the oil gas outlet (the liquid outlet end of the second communication hole 213) at the front end of the pull rod 23 is communicated with the groove 311 in the pull rod sleeve 30 in the axial moving process of the pull rod 23 from the radial hole (the second communication hole 213) at the front end of the pull rod to the pull rod sleeve 30; the groove 311 outside the pull rod sleeve 30 is communicated with the upper radial hole of the shaft core 10, and lubricating liquid reaches the upper groove of the shaft core 10 through the upper radial hole and the axial hole of the shaft core 10; meanwhile, a sealing ring is arranged between the pull rod sleeve 30 and the shaft core 10, and a sealing ring is arranged between the pull rod sleeve 30 and the pull rod 23, so that lubricating liquid is prevented from leaking to other places; the upper groove of the shaft core 10 is in contact with the upper groove of the inner spacer 52, and the lubricating fluid reaches the position of the bearing through a radial hole (a radial channel 5211) on the inner spacer 52 and a side hole (an axial channel 5212) which forms an angle with the axial direction, so that the bearing is lubricated. A liquid drainage channel 301 is arranged in the bearing seat 306 to drain the residual lubricating liquid, so that the oil-gas lubrication process of the main shaft bearing 200 is completed.

The working principle of the spindle in the present application is explained as follows:

by injecting hydraulic oil into the pressing channel 4031, the piston 4041 moves axially to push the pull rod 23 to move axially, at this time, the compression spring 501 is in a compressed state, the hydraulic oil is removed, and the pull rod 23 moves axially in the opposite direction under the action of the elastic force of the compression spring 501. Wherein, the axial movement of the pull rod 23 in the left-right direction is a necessary process for realizing the action of loosening or pulling the main shaft. After broaching, the shaft core 10 drives the tool holder to rotate to process parts.

During the working process of the spindle, the spindle core 10, the lock nut 303, the inner spacer 52, the bearing inner ring of the spindle bearing 200, the connecting disc 601, the pull rod 23, the pull rod sleeve 30, the sleeve 900, the compression spring 501, the spacer 502, the pull rod inner rod 22 and the induction disc 700 inside the spindle core rotate around the central axis of the spindle.

The size of the axial force applied to the pull rod 23 after the compression springs 501 rebound can be adjusted by adjusting the thickness of the spacer 502, so that the adjustment of the broach force of the main shaft is realized, and the spacer 502 ensures that the compression and rebound of the two compression springs 501 are normally performed. The main shaft bearing 200 is an essential component for realizing the rotation function of the shaft core 10 and the pull rod 23, and the outer ring of the bearing is in contact with the bearing seat 306, and the inner ring of the bearing is in contact with the shaft core 10, and the inner ring of the bearing clamps the shaft core 10 to rotate in the rotation process of the main shaft.

While the invention has been described with reference to a preferred embodiment, various modifications may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In particular, the technical features mentioned in the embodiments can be combined in any way as long as there is no structural conflict. The present invention is not limited to the particular embodiments disclosed herein, but encompasses all technical solutions falling within the scope of the claims.

Claims (15)

1. A main shaft bearing lubricating structure, characterized by comprising:

the spindle bearing is arranged on the periphery of the spindle core, and a first flow channel is arranged in the spindle core; and

the pull rod assembly is arranged in the shaft core in a sliding mode along a first direction, a second flow passage is arranged in the pull rod assembly, and the second flow passage is communicated with the first flow passage;

the liquid inlet end of the first flow channel is communicated with the bearing installation cavity of the spindle bearing, and lubricating liquid can sequentially flow through the second flow channel and the first flow channel to flow into the bearing installation cavity and lubricate the spindle bearing in the process of loosening or broaching the pull rod assembly.

2. The spindle bearing lubrication structure of claim 1, wherein the tie rod assembly comprises:

the pull rod is arranged in the shaft core in a sliding mode along a first direction; and

the pull rod inner rod is arranged in the pull rod, an annular channel is formed between the pull rod inner rod and the pull rod, and the second flow channel comprises the annular channel.

3. The main shaft bearing lubricating structure according to claim 2, wherein a first communication hole and a second communication hole that is provided at an interval in a first direction from the first communication hole are provided on an outer periphery of the tie rod, the first communication hole and the second communication hole each communicate with the annular channel, the second communication hole communicates with the first flow passage, and the second flow passage further includes the first communication hole and the second communication hole.

4. The main shaft bearing lubricating structure according to any one of claims 1 to 3, further comprising a tie rod sleeve provided between the tie rod assembly and the spindle, wherein a third flow passage for communicating the first flow passage and the second flow passage is provided in the tie rod sleeve.

5. The main shaft bearing lubricating structure of claim 4, wherein the liquid inlet end of the third flow passage is provided with a groove, and the liquid outlet end of the second flow passage always slides in the groove during the process of loosening or pulling the cutter of the pull rod assembly.

6. The main shaft bearing lubricating structure according to claim 4, wherein a seal is provided at a communication of the third flow passage with the first flow passage, and/or a seal is provided at a communication of the third flow passage with the second flow passage.

7. The main shaft bearing lubricating structure according to any one of claims 1 to 3, wherein the number of the main shaft bearings is plural, and the main shaft bearing lubricating structure further comprises a spacer ring assembly disposed between two adjacent main shaft bearings for axially limiting the main shaft bearings, wherein a fourth flow passage is provided in the spacer ring assembly, the fourth flow passage is communicated with the first flow passage, and the lubricating liquid flows out from the fourth flow passage to lubricate the main shaft bearings.

8. The main shaft bearing lubrication structure of claim 7 wherein said spacer ring assembly comprises:

the inner ring spacer is arranged on the periphery of the shaft core, a flow channel is arranged in the inner ring spacer, and the flow channel is communicated with the first flow channel; and

and the outer spacer ring is positioned on the outer side of the inner spacer ring, a radial gap communicated with the flow channel is formed between the outer spacer ring and the inner spacer ring, and the fourth flow channel comprises the flow channel and the radial gap.

9. A spindle, comprising:

the main shaft bearing lubricating structure according to any one of claims 1 to 8; and

the shaft sleeve assembly is arranged on the periphery of the main shaft bearing lubricating structure; and

the oil cylinder is arranged at one end of the shaft sleeve assembly;

the elastic assembly is arranged between the pull rod assembly and the shaft core;

the bearing installation cavity is limited by the shaft sleeve assembly and the shaft core, the oil cylinder can drive the pull rod assembly to slide so as to achieve a cutter loosening function, and the elastic assembly can drive the pull rod assembly to slide reversely so as to achieve a cutter pulling function.

10. The spindle of claim 9, further comprising a connecting disc assembly, wherein the connecting disc assembly is disposed on an end of the spindle core away from the spindle bearing, a sealed cavity is defined between the connecting disc assembly, the sleeve assembly and the cylinder, a liquid injection flow passage is disposed on the cylinder, and the liquid injection flow passage and the second flow passage are both communicated with the sealed cavity.

11. The spindle of claim 9, further comprising a sensing disc disposed on an end of the drawbar assembly remote from the spindle bearing, wherein the cylinder drives the drawbar assembly to slide by pushing the sensing disc.

12. The spindle of claim 9, wherein a flushing passage is provided in the drawbar assembly that is not in communication with the second flow passage, the spindle further comprising a nipple that is disposed through the cylinder and is in communication with the flushing passage.

13. The spindle of claim 9, wherein a drain flow passage is provided in the sleeve assembly, the drain flow passage communicating with the bearing mounting cavity, the lubricating fluid in the bearing mounting cavity draining the spindle through the drain flow passage.

14. The spindle of claim 9, wherein a spring mounting cavity is formed between the spindle core and the drawbar assembly, and the resilient assembly comprises at least one compression spring disposed in the spring mounting cavity, and the at least one compression spring drives the drawbar assembly to slide in a reverse direction under a restoring force to realize a broaching tool.

15. The spindle of claim 14, wherein when the resilient assembly comprises a plurality of said compression springs, a spacer is disposed between two adjacent compression springs.

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