CN211947094U - Cutting equipment and adsorption mechanism thereof - Google Patents

Abstract

The utility model provides a cutting device and an adsorption mechanism thereof, the adsorption mechanism comprises a bottom frame, a workbench, a shunt pipe, a connecting pipe, a rotary joint and an air blower, the shunt pipe is arranged on a driving component in a penetrating way, a connecting platform is arranged on the shunt pipe, the branch pipe facing to an adsorption station is arranged on the shunt pipe, the connecting pipe is connected with the branch pipe and the corresponding adsorption station, the rotary joint is provided with an input end and an output end which rotate relatively, the input end is arranged outside the shunt pipe, the output end is arranged in the shunt pipe, the corresponding opening and closing mechanism is connected through an air pipe, the air blower is rotatably connected with one end of the shunt pipe away from the rotary joint, therefore, the shunt pipe is rotatably connected with the air blower and the rotary joint and rotates along with the rotation of the platform, the output end and the opening and closing mechanism of the rotary joint, thereby improving the reliability of the adsorption mechanism.

Description

Cutting equipment and adsorption mechanism thereof

Technical Field

The utility model relates to a cutting equipment technical field, in particular to cutting equipment and adsorption apparatus thereof.

Background

Cutting equipment can carry out corresponding cutting to the cladding according to specific shape, is used widely by each enterprise, wherein, is equipped with adsorption apparatus on the cutting equipment, and this adsorption apparatus adsorbs the cladding under negative pressure state.

In the correlation technique, be equipped with a plurality of stations on the cutting equipment, adsorption apparatus rotates in a plurality of stations to drive the trachea of connecting adsorption apparatus and rotate, lead to the trachea to twine easily at the rotation in-process, reduce adsorption apparatus's reliability.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a cutting equipment and adsorption apparatus constructs thereof to improve adsorption apparatus constructs's reliability.

In order to solve the technical problem, the utility model adopts the following technical scheme:

according to an aspect of the utility model, the utility model provides an adsorption device, include: a chassis; the workbench is arranged on one side of the underframe; the workbench comprises a driving assembly and a platform; the driving assembly is arranged on the bottom frame and connected with and drives the platform to rotate; a plurality of adsorption stations are arranged on the platform; the shunt pipe penetrates through the driving assembly and is connected with the platform; the branch pipe part facing the adsorption station is arranged on the flow dividing pipe; the connecting pipe is connected with the branch pipe part and the corresponding adsorption station; an opening and closing mechanism for opening and closing is arranged in the connecting pipe; the rotary joint is provided with an input end and an output end which rotate relatively; the input end is arranged outside the shunt pipe, and the output end is arranged in the shunt pipe and is connected with the corresponding opening and closing mechanism through an air pipe; and the blower is rotatably connected with one end of the shunt pipe, which is far away from the rotary joint.

Optionally, an output port is arranged on an end face, facing the shunt tube, of the output end of the rotary joint; the shunt tubes are provided with through holes which are arranged corresponding to the output ports and communicated with the output ports.

Optionally, a rotating part is arranged between the blower and the flow dividing pipe, and the rotating part comprises a rotating part and a fixing part which rotate relatively; the rotating part is connected with one end of the shunt pipe, which is far away from the rotary joint; the fixed part pipeline is connected with the air blower.

Optionally, the driving assembly includes a driving motor and a rotating table, and the driving motor is connected to and drives the rotating table to rotate; the rotating platform is provided with a through hole for the shunt pipe to penetrate through; the output end of the rotating platform is fixedly connected with the workbench.

Optionally, the adsorption mechanism further comprises a containing pipe, and the containing pipe is arranged on the input end of the rotary joint; the containing pipe is provided with an inner cavity and an opening communicated with the inner cavity, and the opening is arranged at one end, close to the rotary joint, of the containing pipe.

Optionally, the opening and closing mechanism comprises an air cylinder and a blocking head connected with the output end of the air cylinder; the sealing plug is hermetically attached to the inner wall of the connecting pipe along with the extension of the output end of the air cylinder; the blocking head is far away from the inner wall of the connecting pipe along with the retraction of the output end of the air cylinder.

Optionally, the input end of the cylinder is located in the connecting pipe, and is connected with the output end of the rotary joint through the shunt pipe.

Optionally, the inner wall of the connecting pipe is connected with a guiding mechanism, and the guiding mechanism is connected with one end of the plugging head, which faces away from the output end of the air cylinder.

According to another aspect of the utility model, the utility model provides a cutting equipment, including foretell adsorption apparatus structure.

According to the above technical scheme, the embodiment of the utility model provides an at least have following advantage and positive effect:

the utility model discloses in cutting equipment and adsorption apparatus constructs thereof, the drive assembly is worn to locate by the shunt tubes, connection platform, be equipped with the branch pipe portion of adsorbing the station towards on the shunt tubes, branch pipe portion and the absorption station that corresponds are connected to the connecting pipe, be equipped with relative pivoted input and output on the rotary joint, the input sets up outside the shunt tubes, the output is installed in the shunt tubes, the hoist or lower mechanism that corresponds is connected to the trachea, the one end that rotary joint was kept away from to the shunt tubes is rotationally connected to the air-blower, consequently, shunt tubes and air-blower and rotary joint rotatable coupling, and rotatory along with the rotation of platform, and rotary joint's output and hoist or lower mechanism are connected through the trachea in the shunt tubes, make each trachea can rotate along with the rotation of shunt tubes, thereby avoid each trachea intertwin.

Drawings

Fig. 1 is an oblique view of an adsorption mechanism according to an embodiment of the present invention.

Fig. 2 is a plan view of an adsorption mechanism according to an embodiment of the present invention.

Fig. 3 is a sectional view taken along the direction a of fig. 2.

Fig. 4 is a partial enlarged view taken along B of fig. 3.

Fig. 5 is a partial enlarged view taken along C of fig. 4.

The reference numerals are explained below:

1. an adsorption mechanism; 11. a chassis; 12. a work table; 121. a drive assembly; 1211. a drive motor; 1212. a rotating table; 1212a, a via hole; 122. a platform; 122a, an adsorption station; 13. a shunt tube; 131. a main body portion; 132. a branch pipe portion; 132a, a through hole; 14. a connecting pipe; 141. an opening and closing mechanism; 1411. A cylinder; 1412. plugging a plug; 142. a guide mechanism; 1421. a fixing plate; 1422. a guide shaft; 15. A rotary joint; 151. an input end; 152. an output end; 1521. an output port; 16. a blower; 17. A rotating member; 171. a rotating part; 172. a fixed part; 18. a receiving tube; 181. an inner cavity; 182. and (4) opening.

Detailed Description

Exemplary embodiments that embody features and advantages of the present invention will be described in detail in the following description. It is to be understood that the invention is capable of other and different embodiments and its several details are capable of modification without departing from the scope of the invention, and that the description and drawings are to be regarded as illustrative in nature and not as restrictive.

The utility model provides a cutting equipment, cutting equipment can carry out corresponding cutting to the cladding according to specific shape, by each enterprise's wide use, wherein, is equipped with adsorption apparatus on the cutting equipment, and this adsorption apparatus adsorbs the cladding under negative pressure state.

In the correlation technique, be equipped with a plurality of stations on the cutting equipment, adsorption apparatus rotates in a plurality of stations to drive the trachea of connecting adsorption apparatus and rotate, lead to the trachea to twine easily at the rotation in-process, reduce adsorption apparatus's reliability.

Referring to fig. 1 to 4, the utility model provides a cutting equipment includes adsorption apparatus 1, and this adsorption apparatus 1 is used for adsorbing and fixed cladding for the cladding is guaranteed stably under the removal of each station.

The adsorption mechanism 1 includes a base frame 11, a table 12, a shunt tube 13, a connection tube 14, a rotary joint 15, and a blower 16.

The base frame 11 serves as a support member of the suction mechanism 1 and is connected to the table 12. Optionally, the underframe 11 is formed by connecting a cross beam and a vertical beam.

The table 12 is used for supporting leather. The table 12 is mounted on the base frame 11 and is provided on one side of the base frame 11. Alternatively, the table 12 is provided on the upper side of the base frame 11.

The table 12 includes a driving assembly 121 and a platform 122, the driving assembly 121 being connected to and driving the platform 122 to rotate.

The driving unit 121 is mounted on the base frame 11 and serves as a driving source of the table 12 to provide a driving force. The driving assembly 121 includes a driving motor 1211 and a rotation stage 1212.

The driving motor 1211 is connected to and drives the rotation stage 1212 to rotate, and optionally, the driving motor 1211 is a servo motor, a synchronous motor or a synchronous motor.

The input end of the rotary table 1212 is connected to the output shaft of the driving motor 1211, and the output end of the rotary table 1212 is fixedly connected to the working table 12. The output end of the rotary stage 1212 rotates with the rotation of the output shaft of the driving motor 1211, and drives the table 12 to rotate.

The rotary stage 1212 is provided with a through hole 1212a for the shunt tube 13 to pass through, and the through hole 1212a is optionally located at the middle of the rotary stage 1212, and is in clearance fit with the shunt tube 13.

The platform 122 is connected to the output end of the rotation stage 1212 and rotates with the rotation of the rotation stage 1212.

Be equipped with a plurality of adsorption station 122a on the platform 122, have the adsorption plate on this adsorption station 122a, have a plurality of absorption holes on this adsorption plate, realize the adsorption plate to the absorption location of cladding through the negative pressure to a plurality of absorption holes.

The shunt 13 is disposed through the driving assembly 121, connected to the platform 122, and rotates along with the rotation of the platform 122, so as to keep the shunt 13 and the platform 122 relatively stationary.

The shunt tube 13 includes a body 131 and branch tubes 132, and the branch tubes 132 are provided on the periphery of the body 131.

The body 131 is optionally a cylinder and is disposed through the via 1212 a. One end of the main body 131 is connected with an output end pipeline of the blower 16, so that the main body 131 realizes air collection under the negative pressure action of the blower 16.

A rotor 17 is provided between the main body 131 and the blower 16, and the rotor 17 includes a rotor 171 and a stator 172 that rotate relative to each other.

The rotating part 171 is connected to one end of the main body part 131, that is, the rotating part 171 is connected to one end of the shunt tube 13 away from the rotary joint 15, and the fixing part 172 is connected to the blower 16, so that the rotation of the main body part 131 does not drive the blower 16, thereby ensuring the fixation and stable output of the blower 16.

The branch pipe portion 132 has a plurality of one-to-one correspondence with the adsorption stations 122 a. Alternatively, the branch pipe portions 132 may have three, and the three branch pipe portions 132 may be circumferentially distributed along the circumferential side of the main body portion 131.

The branch pipe portion 132 is disposed at the lower side of the platform 122 and is fixedly connected to the platform 122, so that the branch pipe 13 is fixedly connected to the platform 122.

The branch pipe portion 132 communicates with the main body portion 131, and extends from the peripheral side of the main body portion 131 toward the corresponding adsorption station 122 a.

The branch pipe portion 132 is provided with a through hole 132a, and the through hole 132a is optionally arranged with respect to the main body portion 131.

Referring to fig. 4 and 5, the connection pipe 14 connects the branch pipe portion 132 and the corresponding adsorption station 122 a. An opening and closing mechanism 141 for opening and closing is arranged in the connecting pipe 14, the opening and closing of the branch pipe part 132 and the corresponding adsorption station 122a is realized through the opening and closing mechanism 141, and the opening and closing mechanism 141 realizes independent control for the corresponding adsorption station 122a, so that the independence of each adsorption station 122a is ensured.

The opening and closing mechanism 141 comprises a cylinder 1411 and a sealing head 1412 connected with the output end of the cylinder 1411.

The input end of the cylinder 1411 is positioned in the connecting pipe 14 and is connected with the output end of the rotary joint 15 through the shunt pipe 13, so that the cylinder 1411 and the rotary joint 15 correspond to the adsorption station 122a, and the cylinder 1411 and the rotary joint 15 are positioned in the same channel.

The sealing head 1412 is sealingly attached to the inner wall of the connecting tube 14 as the output end of the cylinder 1411 is extended. The blocking head 1412 moves away from the inner wall of the connecting tube 14 as the output end of the cylinder 1411 retracts. Optionally, the blocking head 1412 is made of an elastic material to improve the airtightness of the inner wall of the connection pipe 14.

The inner wall of the connecting pipe 14 is connected with a guiding mechanism 142, and the guiding mechanism 142 is connected with one end of the sealing head 1412 facing away from the output end of the air cylinder 1411, so that the movement stability of the sealing head 1412 is ensured.

Specifically, the guide mechanism 142 includes a fixing plate 1421 and a guide shaft 1422 penetrating the fixing plate 1421, and the guide shaft 1422 moves along the thickness direction of the fixing plate 1421, wherein the axis of the guide shaft 1422 is parallel to the axis of the cylinder 1411.

Referring to fig. 1 to 4, the rotary joint 15 is specifically a pneumatic rotary joint. The rotary joint 15 is provided with an input end 151 and an output end 152 which rotate relatively, and the output end 152 is arranged below the input end 151.

The input end 151 of the rotary union 15 is disposed outside the shunt tube 13 as a fixing portion of the rotary union 15. The input 151 of the rotary joint 15 is connected to an air pipe joint and is connected to an air source through the air pipe joint.

The output end 152 of the rotary joint 15 is used as a rotating part of the rotary joint 15, is installed in the shunt pipe 13, and is connected with the corresponding opening and closing mechanism 141 through an air pipe, specifically, the output end 152 of the rotary joint 15 is communicated with the air cylinder 1411.

The air tube is accommodated in the branch tube 132 of the branch tube 13, rotates with the rotation of the branch tube 132, and is stationary relative to the branch tube 132.

An output port 1521 is provided on the end surface of the output end 152 of the rotary joint 15 facing the shunt tube 13, and the output port 1521 is communicated with the through hole 132a of the branch tube part 132 so as to be communicated with the connecting tube 14.

The air pipes connecting the opening and closing mechanism 141 and the rotary joint 15 are distributed in the corresponding branch pipe parts 132 and protected by the outer layers of the branch pipe parts 132, and the branch pipe parts 132 are mutually independent, so that the relative independence of the air pipes is ensured, and the mutual winding of the air pipes is avoided.

In addition, the blower 16 is rotatably connected with the main body 131, that is, the blower 16 is rotatably connected with one end of the shunt pipe 13 far away from the rotary joint 15, the shunt pipe 13 is rotatably connected with the blower 16 and the rotary joint 15 and rotates along with the rotation of the platform 122, and the output end 152 of the rotary joint 15 and the opening and closing mechanism 141 are connected in the shunt pipe 13 through the air pipes, so that the air pipes can rotate along with the rotation of the shunt pipe 13, the air pipes are prevented from being intertwined with each other, and the reliability of the adsorption mechanism 1 is improved.

The suction mechanism 1 further comprises a receiving tube 18, the receiving tube 18 being arranged on the input end 151 of the rotary joint 15. The accommodating tube 18 is provided with a lumen 181 and an opening 182 communicating with the lumen 181.

The opening 182 is disposed at one end of the accommodating tube 18 close to the rotary joint 15, so as to facilitate convergence of the air tubes connected to the air source, wherein the accommodating tube 18 is relatively fixed to the input end 151 of the rotary joint 15, and is stationary along with the rotation of the platform 122, thereby ensuring stability of the air tubes connected to the air source and achieving outer protection of the air tubes connected to the air source.

According to the above technical scheme, the embodiment of the utility model provides an at least have following advantage and positive effect:

the shunt tube 13 is arranged through the driving component 121, the connecting platform 122 is arranged, a branch tube part 132 facing the adsorption station 122a is arranged on the shunt tube 13, the connecting tube 14 is connected with the branch tube part 132 and the corresponding adsorption station 122a, a rotary joint 15 is provided with an input end 151 and an output end 152 which rotate relatively, the input end 151 is arranged outside the shunt tube 13, the output end 152 is arranged in the shunt tube 13 and is connected with a corresponding opening and closing mechanism 141 through an air tube, the blower 16 is rotatably connected with one end of the shunt tube 13 far away from the rotary joint 15, the shunt tube 13, therefore, is rotatably coupled to the blower 16 and the rotary union 15, and rotates with the rotation of the platform 122, the output end 152 of the rotary joint 15 is connected with the opening and closing mechanism 141 in the shunt pipe 13 through the air pipe, each air pipe can rotate along with the rotation of the shunt pipe 13, so that the air pipes are prevented from being wound, and the reliability of the adsorption mechanism 1 is improved.

While the present invention has been described with reference to several exemplary embodiments, it is understood that the terminology used is intended to be in the nature of words of description and illustration, rather than of limitation. As the present invention may be embodied in several forms without departing from the spirit or essential characteristics thereof, it should also be understood that the above-described embodiments are not limited by any of the details of the foregoing description, but rather should be construed broadly within its spirit and scope as defined in the appended claims, and therefore all changes and modifications that fall within the meets and bounds of the claims, or equivalences of such meets and bounds are therefore intended to be embraced by the appended claims.

Claims (9)

1. An adsorption mechanism, comprising:

a chassis;

the workbench is arranged on one side of the underframe; the workbench comprises a driving assembly and a platform; the driving assembly is arranged on the bottom frame and connected with and drives the platform to rotate; a plurality of adsorption stations are arranged on the platform;

the shunt pipe penetrates through the driving assembly and is connected with the platform; the branch pipe part facing the adsorption station is arranged on the flow dividing pipe;

the connecting pipe is connected with the branch pipe part and the corresponding adsorption station; an opening and closing mechanism for opening and closing is arranged in the connecting pipe;

the rotary joint is provided with an input end and an output end which rotate relatively; the input end is arranged outside the shunt pipe, and the output end is arranged in the shunt pipe and is connected with the corresponding opening and closing mechanism through an air pipe; and

and the blower is rotatably connected with one end of the shunt pipe, which is far away from the rotary joint.

2. The suction mechanism as claimed in claim 1, wherein an output port is provided on an end surface of the output end of the rotary joint facing the shunt tube;

the shunt tubes are provided with through holes which are arranged corresponding to the output ports and communicated with the output ports.

3. The suction mechanism as recited in claim 1, wherein a rotating member is disposed between said blower and said manifold, said rotating member including a rotating portion and a stationary portion that rotate relative to each other;

the rotating part is connected with one end of the shunt pipe, which is far away from the rotary joint;

the fixed part pipeline is connected with the air blower.

4. The suction mechanism as recited in claim 1, wherein the drive assembly includes a drive motor and a turntable, the drive motor being coupled to and driving the turntable to rotate;

the rotating platform is provided with a through hole for the shunt pipe to penetrate through; the output end of the rotating platform is fixedly connected with the workbench.

5. The suction mechanism as recited in claim 1, further comprising a receiving tube disposed on the input end of the rotary union; the containing pipe is provided with an inner cavity and an opening communicated with the inner cavity, and the opening is arranged at one end, close to the rotary joint, of the containing pipe.

6. The adsorption mechanism of claim 1 wherein the opening and closing mechanism comprises a cylinder and a plug connected to an output end of the cylinder;

the sealing plug is hermetically attached to the inner wall of the connecting pipe along with the extension of the output end of the air cylinder; the blocking head is far away from the inner wall of the connecting pipe along with the retraction of the output end of the air cylinder.

7. The suction mechanism of claim 6 wherein the input end of said cylinder is located within said connecting tube and is connected to the output end of said rotary union via said shunt tube.

8. The suction mechanism as claimed in claim 6, wherein a guide mechanism is attached to the inner wall of the connecting tube and connects an end of the plugging head facing away from the output end of the cylinder.

9. A cutting apparatus, characterized by comprising the adsorption mechanism of any one of claims 1 to 8.

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