CN220498768U - Pipe fitting clamping and rotating device and pipe fitting cutting equipment - Google Patents

Abstract

The utility model discloses a pipe fitting clamping and rotating device and pipe fitting cutting equipment, wherein the pipe fitting clamping and rotating device comprises a fixed seat, a rotating sleeve, a clamping structure and a driving ring, wherein the rotating sleeve is rotationally arranged on the fixed seat along an axis in the left-right direction, and is provided with a containing cavity which is penetrated left and right, and the containing cavity is used for containing a pipe fitting in the left-right direction; the clamping structure comprises a plurality of propping parts, wherein the propping parts are arranged in the accommodating cavity and distributed along the circumferential direction of the accommodating cavity and are movably arranged along the radial direction towards the center of the accommodating cavity so as to have a first position for simultaneously propping against the pipe fitting and a second position for separating from the pipe fitting; the driving ring is sleeved on the rotating sleeve and is arranged along the axis in the left-right direction in a rotating way, the driving ring is provided with a first rotating stroke section and a second rotating stroke section on the rotating stroke, the driving ring drives the plurality of propping parts to synchronously move to a first position on the first rotating stroke section, and the driving ring drives the rotating sleeve to rotate on the second rotating stroke. Thereby realizing that the diameter of the cutting wheel is not limited.

Description

Pipe fitting clamping and rotating device and pipe fitting cutting equipment

Technical Field

The utility model relates to the technical field of pipe cutting, in particular to a pipe clamping and rotating device and pipe cutting equipment.

Background

When the existing grinding wheel cutting machine is used for cutting pipe fittings, the common practice is to completely fix the pipe fittings on a cutting machine base, and then press the grinding wheel downwards to cut the pipe fittings, but the mode of completely fixing the pipe fittings has certain limitation, the pipe fittings can be cut off only by completely covering the grinding wheel in the radial direction, namely the outer diameter of the pipe fittings to be cut cannot be larger than the diameter of the grinding wheel, and the pipe fittings with larger outer diameters can be cut only by replacing the grinding wheel with larger sizes.

Disclosure of Invention

The utility model mainly aims to provide a pipe fitting clamping and rotating device and pipe fitting cutting equipment, and aims to solve the problem that an existing grinding wheel cutting machine is difficult to cut a pipe fitting with an enlarged outer diameter.

In order to achieve the above object, the present utility model provides a pipe clamping and rotating device for pipe cutting equipment, comprising:

a fixing seat;

the rotary sleeve is rotationally arranged on the fixed seat along an axis in the left-right direction, a containing cavity which is penetrated left and right is formed in the rotary sleeve, and the containing cavity is used for containing a pipe fitting in the left-right direction;

the clamping structure comprises a plurality of propping parts, wherein the propping parts are arranged in the accommodating cavity and distributed along the circumferential direction of the accommodating cavity and are movably arranged along the radial direction towards the center of the accommodating cavity so as to have a first position for simultaneously propping against the pipe fitting and a second position for separating from the pipe fitting; the method comprises the steps of,

the driving ring is sleeved on the rotating sleeve and is arranged along the axis in the left-right direction in a rotating mode, the driving ring is provided with a first rotating stroke section and a second rotating stroke section on the rotating stroke, the driving ring drives the plurality of jacking parts to synchronously move to the first position on the first rotating stroke section, and the driving ring drives the rotating sleeve to rotate on the second rotating stroke.

Optionally, a plurality of mounting holes are formed on the peripheral side of the rotary sleeve;

the pipe fitting clamping and rotating device further comprises a first transmission structure, wherein the first transmission structure comprises:

the plurality of driving screws penetrate through the corresponding mounting holes, and the plurality of jacking parts are respectively arranged on the corresponding driving screws;

the bevel gears are arranged on the rotating sleeve corresponding to the mounting holes and are rotatably arranged along the axis along the radial direction facing the center of the accommodating cavity, threaded holes communicated with the mounting holes are formed in the bevel gears, and the transmission screw extends into the threaded holes; the method comprises the steps of,

the bevel gear ring is coaxially arranged on the driving ring and is respectively meshed with the bevel gears.

Optionally, a plurality of rotation stopping holes are further formed on the peripheral side of the rotary sleeve corresponding to the plurality of mounting holes;

each propping-up part is provided with a rotation stopping rod which is parallel to the corresponding mounting hole and is adapted to extend into the corresponding rotation stopping hole.

Optionally, the rotating sleeve, the clamping structure and the driving ring form a rotating clamping group in one-to-one correspondence, and the rotating clamping groups are arranged in two groups and are oppositely arranged along the left-right direction;

the pipe fitting clamping and rotating device comprises a driving structure which is used for synchronously driving the driving rings in the two rotating clamping groups to rotate.

Optionally, the driving structure includes:

the synchronous rotating shaft is rotationally arranged on the fixed seat along the axis in the left-right direction and is provided with synchronous shaft sections corresponding to the two driving rings, and each synchronous shaft section is respectively in transmission connection with the corresponding driving ring; the method comprises the steps of,

and the driving motor is used for driving the synchronous rotating shaft to rotate.

Optionally, the pipe fitting clamping and rotating device further includes a second transmission structure corresponding to the two rotating clamping groups, and the second transmission structure includes:

the synchronous gears are coaxially arranged on the corresponding synchronous shaft sections; the method comprises the steps of,

the driven gear ring is coaxially arranged on the corresponding driving ring and is meshed with the synchronous gear.

Optionally, the driving motor is provided with an output rotating shaft which is rotatably arranged along an axis in the left-right direction, a driving gear is arranged on the output rotating shaft, and the driving gear is meshed with one of the synchronous gears.

Optionally, the pipe fitting clamping and rotating device further comprises a damping wheel, wherein the damping wheel is rotatably arranged on the fixing seat along an axis in the left-right direction, and the side end of the damping wheel is in rolling connection with the rotating sleeve;

and on the second rotating stroke section, the driving ring can drive the damping wheel to rotate.

In order to achieve the above object, the pipe cutting device according to the present utility model includes the pipe clamping and rotating device and the cutting device, where the cutting device is disposed on the fixing seat and is used for cutting a pipe.

Optionally, the cutting device comprises a grinding wheel cutting head or a laser cutting head.

According to the technical scheme provided by the utility model, the plurality of jacking parts can move along the radial direction towards the center of the accommodating cavity, under the rotation synchronous driving of the driving ring, the plurality of jacking parts can move to the first position for propping against the pipe fitting, so that the pipe fitting is clamped, after that, the rotation of the driving ring cannot be continuously converted into the telescopic movement of the jacking parts as the jacking parts move to the limit, under the continuous rotation driving of the driving ring, the plurality of jacking parts, the rotating sleeve and the pipe fitting are driven to integrally rotate, the external cutting device only needs to cut the pipe fitting at fixed points, the pipe fitting can be cut off under the self-rotation of the pipe fitting without pressing or circumferential movement, and the requirement on the size of a grinding wheel piece of the cutting device is greatly reduced, namely, the effective cutting depth is larger than the pipe diameter of the pipe fitting, and the effective cutting depth is not larger than the outer diameter of the pipe fitting; after the pipe fitting is cut, the plurality of propping parts can be driven to loosen and clamp the pipe fitting at the first time only by driving the driving ring to rotate reversely.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and other drawings may be obtained according to the structures shown in these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic view of an embodiment of a pipe clamping and rotating device according to the present utility model;

FIG. 2 is a schematic side view of the tubular clamping and rotating device (drive motor not shown) of FIG. 1;

FIG. 3 is a schematic view of the assembly of the top tightening part, the drive screw and the stopper rod of FIG. 1.

Reference numerals illustrate:

the achievement of the objects, functional features and advantages of the present utility model will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

In the case where a directional instruction is involved in the embodiment of the present utility model, the directional instruction is merely used to explain the relative positional relationship, movement condition, etc. between the components in a specific posture, and if the specific posture is changed, the directional instruction is changed accordingly.

In addition, if there is a description of "first", "second", etc. in the embodiments of the present utility model, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed in the present utility model.

When the existing grinding wheel cutting machine is used for cutting pipe fittings, the common practice is to completely fix the pipe fittings on a cutting machine base, and then press the grinding wheel downwards to cut the pipe fittings, but the mode of completely fixing the pipe fittings has certain limitation, the pipe fittings can be cut off only by completely covering the grinding wheel in the radial direction, namely the outer diameter of the pipe fittings to be cut cannot be larger than the diameter of the grinding wheel, and the pipe fittings with larger outer diameters can be cut only by replacing the grinding wheel with larger sizes.

In view of the above, the present utility model provides a pipe clamping and rotating device and a pipe cutting apparatus, which aim to solve the problem that the existing grinding wheel cutting machine is difficult to cut a pipe with an enlarged outer diameter, wherein fig. 1 to 3 are schematic structural diagrams of an embodiment of the pipe clamping and rotating device provided by the present utility model.

Referring to fig. 1 to 3, the pipe clamping and rotating device 100 is used for pipe cutting equipment, and includes a fixing base 1, a rotating sleeve 2, a clamping structure 3 and a driving ring 4: the rotary sleeve 2 is rotatably arranged on the fixed seat 1 along an axis in the left-right direction, and the rotary sleeve 2 is provided with a left-right through accommodating cavity which is used for accommodating a pipe fitting in the left-right direction; the clamping structure 3 comprises a plurality of propping parts 31, wherein the propping parts 31 are arranged in the accommodating cavity and distributed along the circumferential direction of the accommodating cavity, and are movably arranged along the radial direction towards the center of the accommodating cavity so as to have a first position for simultaneously propping against the pipe fitting 200 and a second position for separating from the pipe fitting 200; and the driving ring 4 is sleeved on the rotating sleeve 2 and is rotatably arranged along an axis in the left-right direction, the driving ring 4 is provided with a first rotating stroke section and a second rotating stroke section on the rotating stroke, the driving ring 4 drives a plurality of jacking parts 31 to synchronously move to the first position on the first rotating stroke section, and the driving ring 4 drives the rotating sleeve 2 to rotate on the second rotating stroke.

In the technical scheme provided by the utility model, the plurality of propping parts 31 can move along the radial direction towards the center of the accommodating cavity, under the rotation synchronous driving of the driving ring 4, the plurality of propping parts 31 can move to a first position for propping against the pipe fitting 200 so as to clamp the pipe fitting, after that, as the propping parts 31 move to the limit, the rotation of the driving ring 4 cannot be continuously converted into the telescopic movement of the propping parts 31, under the continuous rotation driving of the driving ring 4, the plurality of propping parts 31, the rotating sleeve 2 and the pipe fitting can be driven to integrally rotate, the external cutting device only needs to cut the pipe fitting at fixed points, and can cut the pipe fitting under the self-rotation without pressing or circumferential movement, and the requirement on the size of a grinding wheel piece of the cutting device is greatly reduced, namely, the effective cutting depth is larger than the pipe diameter of the pipe fitting without being larger than the outer diameter of the pipe fitting; after the pipe is cut, the plurality of tightening parts 31 can be driven to return to the second position at the first time only by driving the driving ring 4 to rotate reversely, so as to release and clamp the pipe.

The driving ring 4 rotates along the axis of the left-right direction, and converts the circumferential rotation of the driving ring 4 into radial movement of the propping part 31, and the transmission mode can be in various forms, for example, the transmission mode can be realized through a cam transmission mechanism, the driving ring 4 acts on a cam shaft to drive the cam to rotate through the cam shaft, and then the cam is lifted up to act with the propping part 31 through the cam so as to convert the rotation into radial translation, but the lifting stroke of the cam transmission mechanism is smaller, and is difficult to provide enough movement for the propping part 31, and in this embodiment, a plurality of mounting holes 21 are arranged on the periphery side of the rotating sleeve 2; the pipe fitting clamping and rotating device 100 further comprises a first transmission structure 5, wherein the first transmission structure 5 comprises a plurality of transmission screws 51, a plurality of bevel gears 52 and bevel gears 53, the plurality of transmission screws 51 penetrate through the corresponding mounting holes 21, and the plurality of tightening parts 31 are respectively arranged on the corresponding transmission screws 51; the bevel gears 52 are arranged on the rotary sleeve 2 corresponding to the mounting holes 21 and are rotatably arranged along the axis along the radial direction facing the center of the accommodating cavity, threaded holes communicated with the mounting holes 21 are formed in the bevel gears 52, and the transmission screw 51 extends into the threaded holes; and the bevel gear ring 53 is coaxially disposed on the drive ring 4 and is engaged with the bevel gears 52. The bevel gears 52 can be synchronously driven to rotate by the driving of the bevel gears 53 on the driving ring 4, so that the bevel gears 52 drive the driving screw 51 to perform circumferential expansion and contraction under the driving action of the screw pair, that is, the tightening part 31 is driven to movably adjust along the radial direction towards the center of the accommodating cavity, and the combination mode of gear transmission and screw transmission can provide a larger movement amount for the tightening part 31, and meanwhile, the structure is compact.

Since the forces act mutually, the bevel gear 52 drives the drive screw 51 to axially move, and the bevel gear 52 itself is subject to the same axial force, that is, the bevel gear 52 needs to be mounted to the rotating sleeve 2 through an axial limiting structure, which is not limited by the embodiment of the present utility model.

It should be noted that, the tightening portion 31 only performs radial movement toward the center of the accommodating cavity, so that the driving screw 51 should perform axial movement of rotation stopping, and in this embodiment, a plurality of rotation stopping holes are further provided on the circumferential side of the rotating sleeve 2 corresponding to the plurality of mounting holes 21; each tightening portion 31 is provided with a rotation stopping rod 6, and the rotation stopping rod 6 and the corresponding mounting hole 21 are arranged in parallel and are adapted to extend into the corresponding rotation stopping hole. By the cooperation of the rotation stop lever 6 and the rotation stop hole, the rotation freedom degree of the drive screw 51 can be limited, and it can be understood that the rotation stop lever 6 is disposed at the lateral side of the drive screw 51 in the left-right direction and keeps consistent with the extending direction of the drive screw 51.

Through the combination of the rotating sleeve 2, the clamping structure 3 and the driving ring 4, the pipe fitting can be effectively driven to perform rotary clamping movement, so that the cutting device is convenient for cutting, but in order to further improve the axial rotation precision of the pipe fitting, in the embodiment, the rotating sleeve 2, the clamping structure 3 and the driving ring 4 form rotary clamping groups in a one-to-one correspondence manner, and the two rotary clamping groups are arranged and are oppositely arranged along the left-right direction; the pipe clamping and rotating device 100 comprises a driving structure 7 for synchronously driving the driving rings 4 in the two rotating clamping groups to rotate. Two driving rings 4 in the two rotary clamping groups are synchronously driven to rotate through the driving structure 7, so that the pipe fitting can be clamped from the two axial ends of the pipe fitting to perform rotary motion, the pipe fitting is clamped more stably, and the cutting precision is higher.

The driving structure 7 can synchronously drive the two driving rings 4 to rotate, and has various structural forms, for example, the two driving rings 4 can be synchronously controlled and driven by two motors to rotate, but the production cost of the mode is higher, and in view of the fact, the driving structure 7 comprises a synchronous rotating shaft 71 and a driving motor, the synchronous rotating shaft 71 is rotationally arranged on the fixing seat 1 along the axis of the left and right directions, the synchronous rotating shaft is provided with synchronous shaft sections corresponding to the two driving rings 4, and each synchronous shaft section is respectively in transmission connection with the corresponding driving ring 4; and the driving motor is used for driving the synchronous rotating shaft 71 to rotate. The synchronization of the two driving rings 4 can be simply and effectively realized through the synchronization rotating shaft 71, and the synchronous rotation of the two driving rings 4 can be realized through the action of the driving motor on the synchronization rotating shaft 71.

The transmission connection manner of the synchronizing shaft section and the driving ring 4 is various, for example, may be realized by a transmission or chain transmission manner, specifically, in this embodiment, the pipe clamping and rotating device 100 further includes a second transmission structure 8 disposed corresponding to two rotation clamping groups, and the second transmission structure 8 includes a synchronizing gear 81 and a driven gear ring 82: the synchronizing gears 81 are coaxially arranged on the corresponding synchronizing shaft sections; and the driven ring gears 82 are coaxially disposed on the corresponding driving rings 4, and the driven ring gears 82 are meshed with the synchronizing gears 81. By means of the gear transmission form of the synchronizing gear 81 and the driven gear ring 82, a precise synchronous rotation effect can be obtained.

The driving motor and the synchronous rotating shaft 71 are connected in a transmission manner in a plurality of manners, specifically, the driving motor is provided with an output rotating shaft which is rotatably arranged along the axis in the left-right direction, a driving gear is arranged on the output rotating shaft, and the driving gear is meshed with one of the synchronous gears 81. By directly engaging the driving gear to one of the synchronizing gears 81, it is possible to avoid providing a plurality of gears on the synchronizing shaft 71, which is simpler in structure and lower in cost.

It can be understood that the driving ring 4 has a tandem relationship between driving the tightening part 31 and driving the rotating sleeve 2 to rotate, that is, a larger driving force is required to drive the rotating sleeve 2, the fixing base 1 provides a certain resistance to the rotating sleeve 2, so that the rotating sleeve 2 can keep stable on a first rotating stroke section and simultaneously rotate on a second stroke section, for example, a rubber pad can be arranged between the fixing base 1 and the rotating sleeve 2 to provide friction resistance, in this embodiment, the pipe clamping rotating device 100 further comprises a damping wheel 9, the damping wheel 9 is rotatably arranged on the fixing base 1 along an axis where the left and right directions are located, and a side end of the damping wheel 9 is connected to the rotating sleeve 2 in a rolling manner; in the second rotational path, the drive ring 4 can rotate the damping wheel 9. The damping wheel 9 has various structural forms, which are not described in detail in the utility model, and the damping wheel 9 can convert sliding friction into rolling friction on one hand, so that abrasion is avoided, and the damping force can be changed according to the requirement, so that the tightening force of the tightening part 31 on the pipe fitting can be controlled.

Specifically, the rotating sleeve 2 is rotatably disposed on the fixing base 1 in a plurality of modes, and can be fixed by abutting and fixing the rotating sleeve 2 on the peripheral side by a plurality of rollers, specifically, the damping wheels 9 are disposed in a plurality of modes and are respectively disposed on the peripheral side of the rotating sleeve 2, so that the limiting of the rotating sleeve 2 can be directly completed by the damping wheels 9.

In addition, in order to achieve the above object, the present utility model also provides a pipe cutting apparatus, which includes the pipe clamping and rotating device 100 according to the above technical solution. It should be noted that, the detailed structure of the pipe clamping and rotating device 100 of the pipe cutting apparatus may refer to the above-mentioned embodiment of the pipe clamping and rotating device 100, and will not be described herein again; because the pipe clamping and rotating device 100 is used in the pipe cutting apparatus of the present utility model, embodiments of the pipe cutting apparatus of the present utility model include all technical solutions of all embodiments of the pipe clamping and rotating device 100, and the achieved technical effects are identical, and are not described in detail herein.

The types of the cutting device are various, and in particular, the cutting device includes a grinding wheel cutting head or a laser cutting head.

The foregoing description is only of the preferred embodiments of the present utility model and is not intended to limit the scope of the utility model, and all equivalent structural changes made by the specification and drawings of the present utility model or direct/indirect application in other related technical fields are included in the scope of the present utility model.

Claims (10)

1. A pipe clamping and rotating device for pipe cutting equipment, comprising:

a fixing seat;

the rotary sleeve is rotationally arranged on the fixed seat along an axis in the left-right direction, a containing cavity which is penetrated left and right is formed in the rotary sleeve, and the containing cavity is used for containing a pipe fitting in the left-right direction;

the clamping structure comprises a plurality of propping parts, wherein the propping parts are arranged in the accommodating cavity and distributed along the circumferential direction of the accommodating cavity and are movably arranged along the radial direction towards the center of the accommodating cavity so as to have a first position for simultaneously propping against the pipe fitting and a second position for separating from the pipe fitting; the method comprises the steps of,

the driving ring is sleeved on the rotating sleeve and is arranged along the axis in the left-right direction in a rotating mode, the driving ring is provided with a first rotating stroke section and a second rotating stroke section on the rotating stroke, the driving ring drives the plurality of jacking parts to synchronously move to the first position on the first rotating stroke section, and the driving ring drives the rotating sleeve to rotate on the second rotating stroke.

2. The pipe clamping and rotating device according to claim 1, wherein a plurality of mounting holes are formed on the circumferential side of the rotating sleeve;

the pipe fitting clamping and rotating device further comprises a first transmission structure, wherein the first transmission structure comprises:

the plurality of driving screws penetrate through the corresponding mounting holes, and the plurality of jacking parts are respectively arranged on the corresponding driving screws;

the bevel gears are arranged on the rotating sleeve corresponding to the mounting holes and are rotatably arranged along the axis along the radial direction facing the center of the accommodating cavity, threaded holes communicated with the mounting holes are formed in the bevel gears, and the transmission screw extends into the threaded holes; the method comprises the steps of,

the bevel gear ring is coaxially arranged on the driving ring and is respectively meshed with the bevel gears.

3. The pipe fitting clamping and rotating device according to claim 2, wherein a plurality of rotation stopping holes are further formed in the circumferential side of the rotating sleeve corresponding to the plurality of mounting holes;

each propping-up part is provided with a rotation stopping rod which is parallel to the corresponding mounting hole and is adapted to extend into the corresponding rotation stopping hole.

4. The pipe fitting clamping and rotating device according to claim 1, wherein the rotating sleeve, the clamping structure and the driving ring form a rotating clamping group in a one-to-one correspondence manner, and the rotating clamping groups are arranged in two groups and are oppositely arranged along the left-right direction;

the pipe fitting clamping and rotating device comprises a driving structure which is used for synchronously driving the driving rings in the two rotating clamping groups to rotate.

5. The pipe clamping and rotating device as defined in claim 4, wherein said drive structure comprises:

the synchronous rotating shaft is rotationally arranged on the fixed seat along the axis in the left-right direction and is provided with synchronous shaft sections corresponding to the two driving rings, and each synchronous shaft section is respectively in transmission connection with the corresponding driving ring; the method comprises the steps of,

and the driving motor is used for driving the synchronous rotating shaft to rotate.

6. The pipe clamping and rotating device according to claim 5, further comprising a second transmission structure provided corresponding to two of the rotary clamping groups, the second transmission structure comprising:

the synchronous gears are coaxially arranged on the corresponding synchronous shaft sections; the method comprises the steps of,

the driven gear ring is coaxially arranged on the corresponding driving ring and is meshed with the synchronous gear.

7. The pipe clamping and rotating device according to claim 6, wherein the driving motor is provided with an output rotating shaft which is rotatably arranged along an axis in the left-right direction, and a driving gear is arranged on the output rotating shaft and is meshed with one of the synchronous gears.

8. The pipe clamping and rotating device according to claim 1, further comprising a damping wheel, wherein the damping wheel is rotatably arranged on the fixing seat along an axis in the left-right direction, and the side end of the damping wheel is in rolling connection with the rotating sleeve;

and on the second rotating stroke section, the driving ring can drive the damping wheel to rotate.

9. A pipe cutting apparatus comprising a pipe clamping and rotating device according to any one of claims 1 to 8 and a cutting device provided on the holder for cutting a pipe.

10. The pipe cutting apparatus of claim 9, wherein the cutting device comprises a grinding wheel cutting head or a laser cutting head.