CN111014090A

CN111014090A - Nylon lamination cleaning cutter

Info

Publication number: CN111014090A
Application number: CN201911060055.0A
Authority: CN
Inventors: 赵章献; 董洪林; 席志成; 吴辉; 刘恪畅; 马闯; 曹天亮
Original assignee: Wuhan Marine Machinery Plant Co Ltd
Current assignee: Wuhan Marine Machinery Plant Co Ltd
Priority date: 2019-11-01
Filing date: 2019-11-01
Publication date: 2020-04-17
Anticipated expiration: 2039-11-01
Also published as: CN111014090B

Abstract

The utility model discloses a nylon lamination clearance cutter belongs to machining technical field. When the lamination on the bottom surface of the guide groove needs to be cleaned, the nylon lamination cleaning tool can be placed between the two guide grooves, and the position of the installation body is righted, so that the two first cleaning blades on the installation body are respectively abutted against the bottom surfaces of the two guide grooves. The driving element drives the installation body to move along the length direction of the guide groove, the first cleaning blade with the cutting edge completely attached to the bottom surface of the guide groove moves along the length direction of the guide groove along with the installation body, and the cutting edge on the first cleaning blade cleans the lamination on the bottom surface of the guide groove. The structure can not be influenced by a narrow space between the two guide grooves, the cutting edge of the first cleaning blade can also directly scrape the lamination on the bottom surface, and the removal efficiency of the lamination is greatly improved compared with the method of polishing the lamination by using sand paper in the traditional method.

Description

Nylon lamination cleaning cutter

Technical Field

The disclosure relates to the technical field of machining, in particular to a nylon lamination cleaning tool.

Background

There is a mechanical structure among sharp elevating gear, and the softer and wear-resisting material of material such as nylon is adopted at both ends as the guide, and the guide way adopts ordinary metal preparation. The mechanical structure comprises a sliding part and two guide grooves which are symmetrically arranged, wherein openings of the two guide grooves are opposite, the sliding part is abutted to the bottom surfaces of the two guide grooves, the sliding part slides along the length direction of the two guide grooves, and the bottom surfaces of the two guide grooves guide the sliding part.

Because the sliding part is made of soft materials such as lead nylon, a layer of lamination is left on the bottom surfaces of the two guide grooves after the sliding part slides between the guide grooves for too many times, the running track of the sliding part is affected by the lamination left on the bottom surfaces of the two guide grooves, and if the lamination is accumulated too much, the sliding part is difficult to pass between the two guide grooves, so that the lamination on the bottom surfaces of the guide grooves needs to be cleaned regularly to ensure that the sliding part can slide normally.

At present, the bottom surfaces of the guide grooves are usually polished through abrasive paper to remove the lamination, but because the space between the two guide grooves is small, the artificial polishing of the lamination is inconvenient, and the efficiency of removing the lamination by manually polishing the abrasive paper is slow.

Disclosure of Invention

The embodiment of the disclosure provides a nylon lamination cleaning tool, which can improve the removal efficiency of a lamination on the bottom surface of a guide groove. The technical scheme is as follows:

the embodiment of the disclosure provides a nylon lamination cleaning tool, which is suitable for two guide grooves which are symmetrically arranged and have opposite openings, and comprises two first cleaning blades, an installation body and a driving element,

the two first cleaning blades are respectively connected with two ends of the mounting body, the driving element is used for driving the mounting body to move along the guide groove,

two first clearance blade symmetries set up the both sides of the plane of symmetry of guide way, the cutting edge of first clearance blade with the bottom surface of guide way is laminated completely.

Optionally, each first cleaning blade comprises a connecting surface, a rake surface, two side surfaces, two spaced-apart rake surfaces, a back surface and a secondary rake surface, the connecting surface is parallel to the symmetry plane, the rake surface is opposite to the back surface, the two side surfaces are opposite, the connecting surface is opposite to the secondary rake surface, the connecting surface simultaneously intersects the rake surface, the two side surfaces and the back surface, each of the rake surfaces intersects the rake surface, one of the side surfaces, the secondary rake surface and the back surface,

the cutting edge does the rake face with the intersection line of vice back knife face, every all opened a chip groove on the side, the chip groove by the rake face extends to the sword back.

Optionally, on a plane perpendicular to the symmetry plane and located between the two side faces, the projection of the rake face is a line convex toward the back face.

Optionally, the lines include consecutive first slash, circular arc and second slash, first slash with the second slash respectively with the both ends of circular arc are tangent, are perpendicular the plane of symmetry just is located on the plane between two sides, the chip groove with the projection of the intersect of rake face is located on the first slash.

Optionally, an included angle between the first oblique line and the symmetric plane is 120 ° to 150 °.

Optionally, the first cleaning insert has a cross-sectional area that gradually decreases in a direction from the rake face to the back face.

Optionally, an included angle between the flank face and the connecting face is 7 ° to 15 °.

Optionally, the nylon lamination clearance cutter still includes two second clearance blades, two second clearance blades are connected respectively the both ends of installation body, two second clearance blade symmetries set up the both sides of the plane of symmetry of guide way, the orientation of the cutting edge of second clearance blade with the orientation of the cutting edge of first clearance blade is the same.

Optionally, the structure of the second cleaning blade is a structure of the first cleaning blade after being scaled down.

Optionally, the hardness of the first cleaning blade is less than the hardness of the bottom surface of the guide groove, and the hardness of the first cleaning blade is greater than the hardness of nylon and the hardness of lead nylon.

The technical scheme provided by the embodiment of the disclosure has the following beneficial effects: when the lamination on the bottom surface of the guide groove needs to be cleaned, the nylon lamination cleaning tool can be placed between the two guide grooves, and the position of the installation body is righted, so that the two first cleaning blades on the installation body are respectively abutted against the bottom surfaces of the two guide grooves. The driving element drives the installation body to move along the length direction of the guide groove, the first cleaning blade with the cutting edge completely attached to the bottom surface of the guide groove moves along the length direction of the guide groove along with the installation body, and the cutting edge on the first cleaning blade cleans the lamination on the bottom surface of the guide groove. The structure is not influenced by the narrow space between the two guide grooves, the cutting edge of the first cleaning blade can also directly scrape the lamination on the bottom surface, the removing efficiency of the lamination is greatly improved compared with the method of using sand paper to polish the lamination in the traditional method,

drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present disclosure, the drawings used in the description of the embodiments will be briefly introduced,

FIG. 1 is a schematic illustration of a mechanical structure provided by an embodiment of the present disclosure;

FIG. 2 is a schematic structural diagram of a nylon lamination cleaning tool provided by the embodiment of the present disclosure;

FIG. 3 is a schematic view of the overall structure of a nylon laminated cleaning tool provided by the embodiment of the present disclosure;

FIG. 4 is a schematic structural view of a first cleaning blade provided by an embodiment of the present disclosure;

fig. 5 is a side view of a nylon build-up layer cleaning tool provided by an embodiment of the present disclosure.

Detailed Description

To make the objects, technical solutions and advantages of the present disclosure more apparent, embodiments of the present disclosure will be described in detail with reference to the accompanying drawings.

Fig. 1 is a schematic view of a mechanical structure provided by an embodiment of the present disclosure, and the nylon lamination cleaning tool in the embodiment of the present disclosure is suitable for the mechanical structure shown in fig. 1, as shown in fig. 1, the mechanical structure includes a sliding member 100 and two symmetrically arranged guide grooves 200, openings of the two guide grooves 200 are opposite, the sliding member 100 abuts against bottom surfaces 200a of the two guide grooves 200, the sliding member 100 slides along a length direction of the two guide grooves 200, and the bottom surfaces 200a of the two guide grooves 200 guide the sliding member 100.

In fig. 1, a large number of build-up layers 300 are accumulated on the bottom surface 200 a.

Fig. 2 is a schematic structural diagram of a nylon laminated cleaning tool provided in an embodiment of the present disclosure, and as shown in fig. 2, the nylon laminated cleaning tool includes two first cleaning blades 1, a mounting body 2, and a driving element 3.

The two first cleaning blades 1 are respectively connected to both ends of the mounting body 2, and the driving member 3 is used to drive the mounting body 2 to move along the guide groove 200.

The two first cleaning blades 1 are symmetrically arranged on two sides of the symmetrical surface C of the guide groove 200, and the cutting edges 1a of the first cleaning blades 1 are completely attached to the bottom surface 200a of the guide groove 200.

When the stack 300 on the bottom surfaces 200a of the guide grooves 200 needs to be cleaned, the nylon stack cleaning tool can be placed between the two guide grooves 200, and the position of the mounting body 2 is adjusted, so that the two first cleaning blades 1 on the mounting body 2 respectively abut against the bottom surfaces 200a of the two guide grooves 200. The driving element 3 drives the mounting body 2 to move along the longitudinal direction of the guide groove 200, the first cleaning blade 1 having the cutting edge 1a completely attached to the bottom surface 200a of the guide groove 200 moves along the longitudinal direction of the guide groove 200 with the mounting body 2, and the cutting edge 1a of the first cleaning blade 1 cleans the build-up layer 300 on the bottom surface 200a of the guide groove 200. This structure is not affected by a narrow space between the two guide grooves 200, and the cutting edge 1a of the first cleaning blade 1 can also directly scrape the build-up layer 300 on the bottom surface 200a, greatly improving the removal efficiency of the build-up layer 300 compared to the conventional method in which the build-up layer 300 is sanded with sand paper,

fig. 3 is a schematic structural view of a first cleaning blade provided by an embodiment of the present disclosure, fig. 4 is a schematic structural view of a first cleaning blade provided by an embodiment of the present disclosure, and in conjunction with fig. 2 to 4, each first cleaning blade 1 includes a connecting surface 11, a rake surface 12, two side surfaces 13, two spaced-apart relief surfaces 14, a back surface 15, and a minor relief surface 16. The connecting surface 11 is parallel to the symmetrical plane C, the rake face 12 is opposite to the back face 15, the two side faces 13 are opposite, the connecting surface 11 is opposite to the secondary flank face 16, the connecting surface 11 is simultaneously intersected with the rake face 12, the two side faces 13 and the back face 15, and each flank face 14 is intersected with the rake face 12, one side face 13, the secondary flank face 16 and the back face 15.

The cutting edge 1a is an intersection line of the rake face 12 and the minor flank face 16, and each side face 13 is provided with a chip groove 17, and the chip groove 17 extends from the rake face 12 to the tool back face 15.

By adopting the structure, the first cleaning blade 1 is convenient for cleaning the lamination 300 on the guide groove 200 by the first cleaning blade 1, and when the lamination 300 on the guide groove 200 is cleaned, the chip discharge of the lamination 300 cleaned by the first cleaning blade 1 can be discharged from the chip discharge groove 17 of the first cleaning blade 1, so that the cleaning efficiency of the guide groove 200 is ensured.

As shown in fig. 3, the projection of the rake face 12 on a plane perpendicular to the plane of symmetry C and located between the two flank faces 13 can be a line 18 which is convex towards the rake face 15.

The projection of the rake face 12 on the plane perpendicular to the symmetry plane C and located between the two side faces 13 is a line 18 protruding toward the cutter back face 15, and this arrangement enables the chip removal of the laminated layer 300 to smoothly move to the protruding part of the rake face 12 corresponding to the line 18 when the first cleaning blade 1 works, and then the chip removal groove 17 is discharged, so that the chip removal efficiency is improved, and the cleaning of the laminated layer 300 is facilitated.

As shown in fig. 3, the line 18 includes a first oblique line 181, an arc 182, and a second oblique line 183 connected in sequence, the first oblique line 181 and the second oblique line 183 are respectively tangent to both ends of the arc 182, and are located on a plane perpendicular to the symmetry plane C and between the two side surfaces 13, and a projection of an intersection line of the flute 17 and the rake face 12 is located on the first oblique line 181.

The line 18 formed by the projection of the rake face 12 comprises a first oblique line 181, an arc 182 and a second oblique line 183 which are connected in sequence, the first oblique line 181 and the second oblique line 183 are respectively tangent to two ends of the arc 182, and are positioned on a plane which is perpendicular to the symmetrical plane C and is positioned between the two side faces 13, and the projection of the intersection line of the chip removal groove 17 and the rake face 12 is positioned on the first oblique line 181; in this arrangement, when the chip discharged from the buildup layer 300 moves to the protrusion of the rake surface 12, the chip discharged from the buildup layer 300 is restricted by the portion corresponding to the second oblique line 183 of the rake surface 12, and the chip discharged from the buildup layer 300 is not flown out of the position of the second oblique line 183 but restricted by the portion corresponding to the arc 182 of the rake surface 12, and most of the chip is finally discharged from the chip discharge groove 17 having the opening located on the first oblique line 181 to the first cleaning blade 1.

Wherein, the included angle α between the first oblique line 181 and the symmetric plane C is 120-150 degrees.

When the included angle α between the first oblique line 181 and the symmetric plane C is within the above range, the chip removal efficiency of the first cleaning blade 1 during operation is higher.

Illustratively, the angle α between the first oblique line 181 and the symmetry plane C may be 130 °.

The chip removal efficiency of the rake face 12 is high.

The included angle β between the second oblique line 183 and the symmetric plane C may be 30-65 °.

When the included angle β between the second oblique line 183 and the symmetric surface C is within the above range, most chips can be discharged from the chip discharge groove 17 of the first cleaning blade 1, the chip discharge efficiency of the first cleaning blade 1 is good, and the cleaning efficiency is high.

Illustratively, the angle β between the first oblique line 181 and the symmetry plane C may be 45 °.

The chip removal efficiency of the first cleaning blade 1 is higher at this time.

The corresponding central angle of the circular arc 182 may be 60-110 °.

When the angle of the central angle is in the range, the chip removal efficiency of the first cleaning blade 1 is better, and the cleaning efficiency is higher.

Illustratively, the radius of the circular arc 182 may be 8.5-12.5 mm.

In the disclosed embodiment, the radius of the circular arc 182 may be 10 mm.

As shown in fig. 3, the area of the cross section of the first cleaning insert 1 may gradually decrease in the direction from the rake face 12 to the rake face 15.

In the direction from the rake face 12 to the rake face 15, the area of the cross section of the first cleaning blade 1 gradually decreases, and in this arrangement, the movement resistance of the first cleaning blade 1 is small, and the cleaning efficiency of the first cleaning blade 1 can be ensured.

As shown in fig. 3, the included angle г between the flank surface 14 and the connecting surface 11 is 7 ° to 15 °.

When the included angle г between the flank face 14 and the connecting face 11 is within the above range, the resistance that the first cleaning blade 1 will receive during the moving process is small, so that the first cleaning blade 1 can have high cleaning efficiency.

Illustratively, the included angle г between the flank surface 14 and the connecting surface 11 is 10 °.

At this time, the resistance that the first cleaning blade 1 may receive in the moving process is small, so that the first cleaning blade 1 can have high cleaning efficiency.

As shown in fig. 3, the first cleaning blade 1 and the mounting body 2 may be connected by a connecting pin 4.

This kind of structure can make things convenient for the dismouting between first clearance blade 1 and the installation body 2.

As shown in fig. 3, the mounting body 2 is provided with a mounting groove 21, the first cleaning blade 1 is provided with a connecting protrusion 19, the connecting protrusion 19 is inserted into the mounting groove 21, and the first cleaning blade 1 and the connecting protrusion 19 are inserted and connected through the connecting pin 4.

Wherein the axis of the connecting pin 4 may be parallel to the connecting surface 11.

This arrangement facilitates disassembly and assembly.

Optionally, a spring groove 191 is formed in the connecting protrusion 19, the connecting pin 4 is inserted into the connecting protrusion 19 and penetrates through the spring groove 191, a spring 5 is arranged in the spring groove 191, the spring 5 is coaxially sleeved on the connecting pin 4, and two ends of the spring 5 abut against two side walls of the spring groove 191.

The arrangement of the spring 5 can increase the friction force between the connecting protrusion 19 and the connecting pin 4, reduce the rotation of the connecting protrusion 19 relative to the connecting pin 4, and ensure that the blade cannot rotate when the first connecting blade works normally.

In other embodiments provided by the present disclosure, the driving element 3 may also include a motor, an output shaft of the motor is fixedly connected to the mounting body 2, and the movement of the mounting body 2 is realized by controlling the extension and contraction of the output shaft of the motor, so as to realize the movement of the nylon laminated layer cleaning tool. As shown in fig. 1.

In other embodiments provided by the present disclosure, the driving element 3 may also include a connecting rod and a pulling rope, the connecting rod is fixed with the mounting body 2, and one end of the pulling rope is fixed on the connecting rod.

Can come the pulling installation body 2 to remove through the pulling haulage rope, and then realize the removal of nylon lamination clearance cutter.

Fig. 5 is a side view of the nylon laminated cleaning tool provided by the embodiment of the present disclosure, and as shown in fig. 5, the nylon laminated cleaning tool may further include two second cleaning blades 6, the two second cleaning blades 6 are respectively connected to two ends of the mounting body 2, the two second cleaning blades 6 are symmetrically disposed on two sides of the symmetric plane C of the guide groove 200, and the orientation of the cutting edge 1a of the second cleaning blade 6 is the same as the orientation of the cutting edge 1a of the first cleaning blade 1.

The nylon lamination cleaning tool comprises two second cleaning blades 6, the cleaning efficiency of the nylon lamination cleaning tool in the working process can be improved, and the working efficiency of the nylon lamination cleaning tool is improved.

Optionally, the structure of the second cleaning blade 6 is the structure of the first cleaning blade 1 after being scaled down.

The structure of second clearance blade 6 is the structure after first clearance blade 1 scaling down for second clearance blade 6 can not influence the normal chip removal of first clearance blade 1 when clearing up the nylon lamination, improves the clearance efficiency of nylon lamination clearance cutter.

Alternatively, the driving element 3 may comprise a connecting cord 31, one end of the connecting cord 31 being fixedly connected with the mounting body 2.

When the nylon lamination cleaning tool works, the nylon lamination cleaning tool can move along the guide groove 200 by pulling the connecting rope 31.

For example, the hardness of the first cleaning blade 1 may be less than that of the bottom surface 200a of the guide groove 200, and the hardness of the first cleaning blade 1 is greater than that of nylon and that of lead nylon.

The hardness of the first cleaning blade 1 is less than the hardness of the bottom surface 200a of the guide groove 200, and the hardness of the first cleaning blade 1 is greater than the hardness of nylon and the hardness of lead nylon, so that the first cleaning blade 1 can scrape the lamination layer 300 without damaging the bottom surface 200a of the guide groove 200, and the normal operation of the guide groove 200 is ensured.

The above description is only exemplary of the present disclosure and is not intended to limit the present disclosure, so that any modification, equivalent replacement, or improvement made within the spirit and principle of the present disclosure should be included in the scope of the present disclosure.

Claims

1. A nylon lamination cleaning tool is suitable for two guide grooves (200) which are symmetrically arranged and have opposite openings, and is characterized by comprising two first cleaning blades (1), an installation body (2) and a driving element (3),

the two first cleaning blades (1) are respectively connected with two ends of the mounting body (2), the driving element (3) is used for driving the mounting body (2) to move along the guide groove (200),

two first clearance blade (1) symmetry sets up the both sides of the plane of symmetry (C) of guide way (200), cutting edge (1a) of first clearance blade (1) with bottom surface (200a) of guide way (200) laminate completely.

2. The nylon stack cleaning tool according to claim 1, characterized in that each first cleaning blade (1) comprises a connecting surface (11), a rake surface (12), two side surfaces (13), two spaced-apart relief surfaces (14), a land surface (15) and a minor relief surface (16), the connecting surface (11) being parallel to the symmetry plane (C), the rake surface (12) being opposite the land surface (15), the two side surfaces (13) being opposite, the connecting surface (11) being opposite the minor relief surface (16), the connecting surface (11) simultaneously intersecting the rake surface (12), the two side surfaces (13) and the land surface (15), each relief surface (14) intersecting the rake surface (12), one of the side surfaces (13), the minor relief surface (16) and the land surface (15),

cutting edge (1a) do rake face (12) with the intersection of vice flank (16), every all opened a chip groove (17) on side (13), chip groove (17) by rake face (12) extend to the back of the knife face (15).

3. The nylon insert cleaning tool according to claim 2, characterized in that the projection of the rake face (12) on a plane perpendicular to the symmetry plane (C) and located between the two side faces (13) is a line (18) that is convex towards the back face (15).

4. The nylon laminate cleaning tool as claimed in claim 3, wherein the line (18) comprises a first oblique line (181), an arc (182) and a second oblique line (183) which are connected in sequence, the first oblique line (181) and the second oblique line (183) are respectively tangent to two ends of the arc (182), and a projection of an intersection line of the chip discharge groove (17) and the rake face (12) is located on the first oblique line (181) on a plane which is perpendicular to the symmetry plane (C) and located between the two side faces (13).

5. The nylon laminate cleaning tool according to claim 4, wherein an included angle (α) between the first oblique line (181) and the symmetry plane (C) is 120-150 °.

6. The nylon laminate cleaning tool according to any one of claims 2 to 5, wherein the area of the cross section of the first cleaning blade (1) is gradually reduced in a direction from the rake surface (12) to the back surface (15).

7. The nylon laminate cleaning tool according to any one of claims 2 to 5, wherein an included angle (г) between the flank surface (14) and the connecting surface (11) is 7 ° to 15 °.

8. The nylon laminate cleaning tool as claimed in any one of claims 2 to 5, further comprising two second cleaning blades (6), wherein the two second cleaning blades (6) are respectively connected to two ends of the mounting body (2), the two second cleaning blades (6) are symmetrically arranged on two sides of a symmetrical plane (C) of the guide groove (200), and the orientation of the cutting edge (1a) of the second cleaning blade (6) is the same as that of the cutting edge (1a) of the first cleaning blade (1).

9. The nylon laminate cleaning tool according to claim 8, wherein the second cleaning blade (6) has a structure in which the first cleaning blade (1) is reduced in equal proportion.

10. The nylon laminate cleaning tool according to any one of claims 2 to 5, wherein the hardness of the first cleaning blade (1) is less than the hardness of the bottom surface (200a) of the guide groove (200), and the hardness of the first cleaning blade (1) is greater than the hardness of nylon and the hardness of lead nylon.