CN210268031U

CN210268031U - Drying apparatus for a turbine rotor

Info

Publication number: CN210268031U
Application number: CN201920639463.0U
Authority: CN
Inventors: 汪晓伍; 裴腊妹; 刘庆祥; 唐云冰
Original assignee: Changzhou E&e Turbo Power Co ltd
Current assignee: Changzhou E&e Turbo Power Co ltd
Priority date: 2019-05-07
Filing date: 2019-05-07
Publication date: 2020-04-07
Anticipated expiration: 2029-05-07

Abstract

The utility model discloses a drying equipment for turbine rotor, include: the rotary driving mechanism comprises a first support, a first rotary driver and a first propping part, the first rotary driver is arranged on the first support, one end of the first propping part is connected with the output end of the first rotary driver, and the other end of the first propping part is a free end which props against one end of the turbine rotor; one end of the abutting mechanism abuts against the other end of the turbine rotor so that the turbine rotor is clamped between the rotary driving mechanism and the abutting mechanism; and a reciprocating purge mechanism provided on one side of the rotary drive mechanism, the reciprocating purge mechanism reciprocating in the axial direction of the turbine rotor and purging the turbine rotor driven by the rotary drive mechanism. The utility model has the advantages of the realization is dry to the surface cutting fluid of turbine.

Description

Drying apparatus for a turbine rotor

Technical Field

The utility model relates to the technical field of engines, in particular to a drying equipment for turbine rotor.

Background

In the process of the automatic processing production line of the turbine, optical detection needs to be carried out on the turbine, but the cutting fluid attached to the whole surface of the turbine processing can influence the detection precision, the prior art basically cleans turbine workpieces through manual work, then the manual work carries out the upper and lower workpieces, so that the efficiency of the automatic processing line can be greatly reduced, the labor cost is increased, and great potential safety hazards exist.

Disclosure of Invention

An object of the utility model is to provide a drying equipment for turbine rotor.

The technical scheme for solving the technical problems is as follows:

drying apparatus for a turbine rotor, comprising:

the rotary driving mechanism comprises a first support, a first rotary driver and a first propping part, the first rotary driver is arranged on the first support, one end of the first propping part is connected with the output end of the first rotary driver, and the other end of the first propping part is a free end which props against one end of the turbine rotor;

one end of the abutting mechanism abuts against the other end of the turbine rotor so that the turbine rotor is clamped between the rotary driving mechanism and the abutting mechanism;

and a reciprocating purge mechanism provided on one side of the rotary drive mechanism, the reciprocating purge mechanism reciprocating in the axial direction of the turbine rotor and purging the turbine rotor driven by the rotary drive mechanism.

Further, the first rotary drive is a hydraulic motor or an electric motor.

Furthermore, the abutting mechanism comprises a second support, a linear driver and a second abutting part, the linear driver is arranged on the second support, one end of the second abutting part is connected with the linear driver, and the other end of the second abutting part is a free end abutting against the other end of the turbine rotor.

Further, the linear actuator is an air cylinder, or a hydraulic cylinder, or a linear air cylinder, or a linear motor.

Further, the first abutting part and the second abutting part are both apexes.

Further, the reciprocating blowing mechanism comprises a reciprocating linear driver and an air injection assembly, and the air injection assembly is connected with the reciprocating linear driver.

Further, the device also comprises a blowing chamber and a mist absorber for absorbing the blown mist cutting fluid, wherein the rotary driving mechanism, the abutting mechanism and the reciprocating blowing mechanism are all positioned in the blowing chamber, a first opening is formed in the side wall of the blowing chamber, and one end of the mist absorber is arranged at the first opening on the blowing chamber.

Further, the device also comprises a liquid storage tank, and the liquid storage tank is connected with the mist absorber.

Furthermore, the mist absorber comprises a pipeline, a filtering part and an air extracting part, wherein the pipeline is connected with one end of the filtering part, and the other end of the filtering part is connected with the air extracting part.

Further, the device also comprises a skylight and a driver for driving the skylight to move, wherein a second opening is formed in the blowing chamber, the skylight is located at the second opening, and the skylight is connected with the driver.

Compared with the prior art, the invention has the beneficial effects that:

1. the reciprocating purging mechanism moves and drives the turbine rotor to rotate, so that the surface cutting fluid of the turbine is dried. Compared with the action of manually blowing the turbine, the method greatly improves the working efficiency and provides a solution for automation of a factory processing line.

2. Through the closed processing environment and the mist absorber, the water mist can be prevented from being diffused into a workshop, and the workshop environment is favorably improved.

3. The whole process of mechanical automatic operation is realized in the working process without manual operation, so that the cleaning of the workpiece is facilitated and the workpiece is prevented from being corroded.

4. The automatic clamping of the turbine is realized by the truss manipulator on the automatic processing line, and the continuity and the efficiency of the automatic processing line are ensured. By utilizing the door opening device for the upper and lower workpieces on the top, the truss manipulator can convey the turbine to the turbine clamping mechanism to realize automatic clamping, so that the whole automatic processing line is not interrupted due to manual purging.

Drawings

Fig. 1 is a schematic perspective view of the present invention;

fig. 2 is a schematic perspective view of the present invention in another direction;

1 is a first support, 2 is a first rotary driver, 3 is a first propping part, 4 is a second support, 5 is a linear driver, 6 is a second propping part, 7 is a reciprocating linear driver, 8 is an air injection assembly, 9 is a purging chamber, 10 is a mist absorber, 11 is a first opening, 12 is a liquid storage tank, 13 is a skylight, 14 is a driver, and 15 is a sliding seat.

Detailed Description

As shown in fig. 1 and 2, the drying apparatus for a turbine rotor of the present invention includes: the rotating driving mechanism, the abutting mechanism and the reciprocating purging mechanism are explained in detail as follows:

the rotary driving mechanism comprises a first support 1, a first rotary driver 2 and a first propping part 3, the first rotary driver 2 is arranged on the first support 1, one end of the first propping part 3 is connected with the output end of the first rotary driver 2, and the other end of the first propping part 3 is a free end which props against one end of the turbine rotor.

As shown in fig. 1 and 2, the first rotary actuator 2 is a hydraulic motor or an electric motor, the first rotary actuator 2 preferably adopts an electric motor, the first support 1 is provided with a first through hole, one end of the first propping member 3 passes through the first through hole and then is connected with the first rotary actuator 2, and the first propping member 3 preferably adopts an apex.

As shown in fig. 1 and fig. 2, one end of the abutting mechanism abuts against the other end of the turbine rotor so that the turbine rotor is clamped between the rotary driving mechanism and the abutting mechanism; the abutting mechanism comprises a second support 4, a linear driver 5 and a second abutting part 6, the linear driver 5 is arranged on the second support, one end of the second abutting part is connected with the linear driver, and the other end of the second abutting part is a free end abutting against the other end of the turbine rotor.

As shown in fig. 1 and 2, the second support 4 is provided with a second through hole, the second propping member 6 passes through the second through hole, the second propping member 6 is in clearance fit with the second through hole, the second propping member 6 can move along the axial direction of the second through hole, and the second propping member 6 is preferably an apex. The linear driver 5 is connected with the second propping part 6, the linear driver 5 drives the second propping part 6 to move linearly, so that the second propping part 6 moves along the axial direction of the second through hole, and then propping is formed on the other end of the turbine rotor, and the second propping part 6 preferably adopts a tip. The linear actuator 5 is an air cylinder, or a hydraulic cylinder, or a linear air cylinder, or a linear motor, and in this embodiment, the air cylinder is preferably used as the linear actuator 5.

As shown in fig. 1 and 2, a reciprocating purge mechanism is provided on one side of the rotary drive mechanism, and reciprocates in the axial direction of the turbine rotor to purge the turbine rotor driven by the rotary drive mechanism. The reciprocating purging mechanism comprises a reciprocating linear driver 7 and an air injection assembly 8, wherein the air injection assembly 8 is connected with the reciprocating linear driver 7, and the reciprocating linear driver 7 drives the air injection assembly 8 to reciprocate along the axial direction of the turbine rotor. The gas ejected from the jet module 8 purges the turbine rotor. The gas injection assembly 8 includes a gas injection tube and a gas source for providing gas to the gas injection tube, which may be implemented by a component such as an air pump.

As shown in fig. 1 and 2, the cutting fluid cleaning device further comprises a purging chamber 9 and a mist absorber 10 for absorbing the purged mist-like cutting fluid, the rotary driving mechanism, the abutting mechanism and the reciprocating purging mechanism are all located in the purging chamber 9, a first opening 11 is formed in the side wall of the purging chamber 9, and one end of the mist absorber 10 is arranged at the first opening on the purging chamber. The cutting fluid storage tank is characterized by further comprising a liquid storage tank 12, the liquid storage tank 12 is connected with the mist absorber 10, and the mist absorber 10 conveys the absorbed cutting fluid into the liquid storage tank 12 for storage.

As shown in fig. 1 and 2, when the gas ejected from the gas ejection unit 8 purges the turbine rotor, the cutting fluid on the turbine rotor is separated from the turbine rotor, the separated cutting fluid floats in the form of mist in the purge chamber 9, and the mist 10 absorbs the floating cutting fluid under the negative pressure force generated by the mist absorber 10, so that the mist 10 prevents the mist of cutting fluid from reattaching to the turbine rotor.

As shown in fig. 1 and 2, the mist absorber 10 includes a pipe, a filter member, and an air extracting member, the pipe is connected to one end of the filter member, and the other end of the filter member is connected to the air extracting member. Since some of the cut metal is adhered to the turbine rotor in addition to the cutting fluid, the negative pressure force generated by the mist absorber 10 absorbs the purged cutting fluid together with the fine metal, and the metal is filtered by the filter member.

As shown in fig. 1 and 2, the purging device further includes a louver 13 and a driver 14 for driving the louver 13 to move, a second opening is provided on the purging chamber 9, the louver 13 is located at the second opening, and the louver 13 is connected to the driver 14. After the actuator 14 drives the louver 13 to open, the robot arm puts the taken turbine rotor into the purge chamber 9 through the louver. Therefore, the utility model discloses cooperate with the manipulator for turbine rotor sweeps in sweeping the relative sealed space of room, has the characteristics that drying efficiency is high. The louver 13 is provided on the top of the purge chamber 9.

As shown in fig. 1 and 2, a transparent member is attached to the front surface of the purge chamber 9, and the operation state in the purge chamber 9 can be easily observed through the transparent member. In addition, the rotary driving mechanism and the abutting mechanism are installed on the same sliding seat 15, a sliding rail is arranged on the sliding seat 15, and the first support 1 and the second support 4 can slide along the sliding rail on the sliding seat 15 as required.

The working process of the utility model is as follows:

as shown in fig. 1 and 2, the truss manipulator for workpiece circulation in the automatic processing line of the turbine reaches the position of the top skylight 13 of the drying device, the driver 14 on the drying device drives the skylight 13 to move, the second opening is opened, the truss manipulator clamping the turbine rotor is used for placing the turbine rotor into the purging chamber 9, and the turbine rotor is positioned between the first butting part 3 and the second butting part 6. The robot is withdrawn from the purge chamber and the louvers 13 are driven by the drive 14 to close the second opening, so that the purge chamber 9 forms a relatively closed purge space.

The linear actuator 5 operates to push the second abutment member 6 to move, so that the turbine rotor is clamped by the second abutment member 6 and the first abutment member 3. The first rotary actuator 2 operates to rotate the first prop member 3.

The reciprocating linear driver 7 works to drive the gas injection assembly 8 to reciprocate, the gas injection assembly 8 injects gas and acts on the turbine rotor, and the cutting fluid on the surface of the turbine rotor is dried within set time. The blown cutting fluid is in a mist shape and is absorbed by the mist absorber 10, so that solid-liquid separation is realized, and the filtered fluid enters the liquid storage tank 12. The residual cutting fluid in the device also enters the filter part of the mist absorber 10 through the collection hole arranged on the blowing chamber 9, and the filtered fluid also enters the liquid storage tank 12.

The cutting fluid in the liquid storage tank can be recycled after being filtered, thereby reducing the inorganization discharge of the cutting fluid and avoiding the leakage of running, falling and dripping on site.

And after the turbine rotor is dried, the skylight 13 at the top of the equipment is opened, meanwhile, the truss mechanical arm grabs the turbine rotor, the turbine rotor clamping mechanism loosens the workpiece, and the truss mechanical arm takes out the workpiece to complete the whole set of working procedures.

The foregoing is merely a preferred embodiment of this invention, which is intended to be illustrative, and not limiting. It will be understood by those skilled in the art that various changes, modifications and equivalents may be made therein without departing from the spirit and scope of the invention as defined in the appended claims.

Claims

1. Drying apparatus for a turbine rotor, comprising:

2. Drying apparatus for a turbine rotor as claimed in claim 1, characterised in that the first rotary drive is a hydraulic motor or an electric motor.

3. Drying apparatus for a turbine rotor according to claim 1, wherein the abutment mechanism comprises a second abutment, a linear actuator and a second abutment member, the linear actuator being arranged on the second abutment, one end of the second abutment member being connected to the linear actuator, the other end of the second abutment member being a free end which abuts against the other end of the turbine rotor.

4. Drying apparatus for turbine rotors according to claim 3, characterised in that the linear drive is a pneumatic cylinder, or a hydraulic cylinder, or a linear pneumatic cylinder, or a linear motor.

5. Drying apparatus for a turbine rotor according to claim 3 in which the first and second abutments are both apexes.

6. The drying apparatus for turbine rotors according to claim 1, wherein the reciprocating purge mechanism comprises a reciprocating linear actuator, an air injection assembly, the air injection assembly being connected to the reciprocating linear actuator.

7. The drying apparatus for the turbine rotor according to any one of claims 1 to 6, further comprising a purging chamber and a mist absorber for absorbing the purged mist-like cutting fluid, wherein the rotary driving mechanism, the abutting mechanism and the reciprocating purging mechanism are located in the purging chamber, a first opening is formed in a side wall of the purging chamber, and one end of the mist absorber is disposed at the first opening of the purging chamber.

8. The drying apparatus for a turbine rotor as claimed in claim 7, further comprising a liquid reservoir connected to the mist absorber.

9. Drying apparatus for a turbine rotor as claimed in claim 7 in which the mist eliminator comprises a duct, a filter element, the extraction element, the duct being connected to one end of the filter element and the other end of the filter element being connected to the extraction element.

10. The drying apparatus for a turbine rotor according to claim 7, further comprising a louver and a driver for driving the louver to move, wherein the purge chamber is provided with a second opening, the louver is located at the second opening, and the louver is connected to the driver.