CN220838044U

CN220838044U - Carburetor idling measuring hole head processing device

Info

Publication number: CN220838044U
Application number: CN202322174189.3U
Authority: CN
Inventors: 张勇
Original assignee: Fuding Mckeny Locomotive Parts Co ltd
Current assignee: Fuding Mckeny Locomotive Parts Co ltd
Priority date: 2023-08-14
Filing date: 2023-08-14
Publication date: 2024-04-26
Anticipated expiration: 2033-08-14

Abstract

The utility model relates to the technical field of carburetors, in particular to a processing device for the head of a secondary oil hole of a carburetor, which comprises a feeding mechanism, a first drilling machine, a second drilling machine, a third drilling machine, a conveying pipe, a main shaft pulling claw, a first driving component and a second driving component, wherein the conveying pipe is fed through a vibration feeding disc, an idle speed hole of the conveying pipe is conveyed to the feeding mechanism, the idle speed hole is positioned to the main shaft pulling claw by the feeding mechanism, and the platform is moved in the X direction and the Y direction through the cooperation of the first driving component and the second driving component, so that the processing and the manufacturing of the idle speed hole are realized.

Description

Carburetor idling measuring hole head processing device

Technical Field

The utility model relates to the technical field of carburettors, in particular to a processing device for a carburetor auxiliary oil quantity hole head.

Background

The carburetor (carburetor) is a mechanical device that mixes a certain proportion of gasoline with air under the vacuum created by the operation of the engine. The carburetor acts as a precision mechanical device that utilizes the kinetic energy of the intake air flow to effect atomization of the gasoline. Its important role in an engine may be referred to as the "heart" of the engine.

The assembly of the idle metering orifice of the carburetor is indispensable, the idle metering orifice is an important part of an idle device for controlling the carburetor, the existing idle metering orifice is processed and is generally divided into two working procedures, firstly, the idle metering orifice which needs to be processed is manually placed at a clamping station, then, the idle metering orifice head is drilled through a drilling machine, after the idle metering orifice is drilled, the idle metering orifice is taken out and placed at the clamping station of the next drilling machine, the edge milling operation is carried out on the aperture of the idle metering orifice, after the edge milling operation is finished, the whole idle metering orifice is finished, but the efficiency is low, and the idle metering orifice is required to be placed at the clamping station manually for a long time, so that deviation can occur, and the accuracy of the aperture of a drilled channel is reduced.

Disclosure of utility model

The technical problems to be solved by the utility model are as follows: the device for processing the head of the idle measuring hole of the carburetor not only can improve efficiency, but also can improve the precision of manufacturing the idle measuring hole.

In order to solve the technical problems, the utility model adopts the following technical scheme: an idle metering orifice head processing device of a carburetor, comprising:

a base;

the first driving assembly is connected to the base;

the first sliding block is movably connected to the base along the X direction, and the first driving component is used for driving the first sliding block to move;

the second driving assembly is connected to the first sliding block;

the second sliding block is movably connected to the base along the Y direction, and the second driving assembly is used for driving the second sliding block to move;

The platform is connected to the second sliding block, a feeding mechanism, a first drilling machine, a second drilling machine and a third drilling machine are sequentially arranged on the platform along the X direction, the axis of the first drilling machine is the Y direction, the axes of the feeding mechanism, the second drilling machine and the third drilling machine are parallel to the axis of the first drilling machine, the axes of the feeding mechanism, the first drilling machine, the second drilling machine and the third drilling machine are located at the same height, the feeding mechanism is a circular pipe, and an opening is formed in the upper part of the circumferential surface of the circular pipe;

the push rod is movably arranged in the circular tube along the Y direction;

The cylinder body of the cylinder is connected to the platform, the axial direction of the cylinder is in the Y direction, and the cylinder is used for driving the push rod to move;

The main shaft pulling claw is connected to the base, the axis of the main shaft pulling claw is parallel to the axial direction of the first drilling machine, and the axis of the main shaft pulling claw and the axis of the first drilling machine are located at the same height;

One end of the material conveying pipe is connected with the vibration feeding disc, and the other end of the material conveying pipe is positioned above the main shaft pulling claw;

The first driving assembly enables the platform to be switched among a first state, a second state, a third state, a fourth state and a fifth state;

in the first state, one end of the conveying pipe is positioned above the opening;

in the second state, the axis of the main shaft pulling claw is coincident with the axis of the feeding mechanism;

in the third state, the axis of the main shaft pulling claw is coincident with the axis of the first drilling machine;

in a fourth state, the axis of the main shaft pulling claw is coincident with the axis of the second drilling machine;

In the fifth state, the axis of the main shaft pulling claw coincides with the axis of the third drilling machine.

Further, the first drive assembly includes first lead screw pivot, first driving motor and first track, and the axis of first lead screw pivot is X to, and first orbital direction is X to, and first slider and lead screw pivot and first track sliding connection, first driving motor and first lead screw pivot transmission are connected.

Further, the second drive assembly includes base, second lead screw pivot, second driving motor and second track, and the axial of second lead screw pivot is Y to, and second orbital direction is Y to, second slider and second lead screw pivot and second track sliding connection, second driving motor and second lead screw pivot transmission are connected.

Further, idle measuring pore head processingequipment still includes first belt pulley, second belt pulley, third belt pulley and third driving motor, and first belt pulley is connected with the transmission of second rig, and the second belt pulley is connected with the transmission of third rig, and third driving motor connects on the platform, and third belt pulley is connected with the transmission of third driving motor, and first belt pulley, second belt pulley and third belt pulley pass through belt transmission and are connected.

Further, the idle measuring hole head processing device further comprises a conveying groove, the conveying groove is located below the main shaft pulling claw, and the conveying groove is connected to the platform.

Further, be equipped with circular baffle on the pipe, circular baffle coaxial coupling is in the outer wall of pipe, and circular baffle is located the top of conveyer trough, and circular baffle's diameter is greater than the diameter of main shaft draws the claw.

The utility model has the beneficial effects that: the feeding mechanism, the first drilling machine, the second drilling machine, the third drilling machine, the conveying pipe, the main shaft pulling claw, the first driving component and the second driving component are sequentially arranged on the platform along the X direction, the conveying pipe is fed through the vibration feeding disc, the idle measuring hole of the conveying pipe is conveyed to the feeding mechanism, the idle measuring hole is positioned to the main shaft pulling claw through the feeding mechanism, the platform is enabled to move in the X direction and the Y direction through the cooperation of the first driving component and the second driving component, the processing and manufacturing of the idle measuring hole are achieved, and compared with the prior art, the efficiency can be improved, the problem that deviation can occur when the idle measuring hole is placed on a clamping station through manual operation for a long time is solved through mechanical control, and the precision of idle measuring hole manufacturing is improved.

Drawings

FIG. 1 is a schematic view of a carburetor idle metering orifice head processing device according to an embodiment of the present utility model;

FIG. 2 is a top view of a carburetor idle metering orifice head processing device according to an embodiment of the present utility model;

FIG. 3 is a side view of a carburetor idle metering orifice head processing device according to an embodiment of the present utility model;

FIG. 4 is a front view of a carburetor idle metering orifice head processing device according to an embodiment of the present utility model.

Description of the reference numerals:

1. A base; 2. a first drive assembly; 21. a first screw spindle; 22. a first driving motor; 23. a first track; 3. a first slider; 4. a second drive assembly; 41. a base; 42. a second screw spindle; 43. a second driving motor; 44. a second track; 5. a second slider; 6. a platform; 61. a first drilling machine; 62. a second drilling machine; 621. a first pulley; 63. a third drilling machine; 631. a second pulley; 64. a round tube; 641. an opening; 7. a push rod; 8. a cylinder; 9. a main shaft pulling claw; 10. a material conveying pipe; 101. a third driving motor; 102. a third pulley; 103. a conveying trough; 104. a circular baffle.

Detailed Description

In order to describe the technical contents, the achieved objects and effects of the present utility model in detail, the following description will be made with reference to the embodiments in conjunction with the accompanying drawings.

Referring to fig. 1 to 4, a carburetor idle measuring hole head processing device includes:

a base 1;

A first driving assembly 2, the first driving assembly 2 being connected to the base 1;

The first sliding block 3, the first sliding block 3 is movably connected to the base 1 along the X direction, and the first driving component 2 is used for driving the first sliding block 3 to move;

a second driving assembly 4, the second driving assembly 4 being connected to the first slider 3;

The second sliding block 5 is movably connected to the base 1 along the Y direction, and the second driving component 4 is used for driving the second sliding block 5 to move;

The platform 6 is connected to the second sliding block 5, a feeding mechanism, a first drilling machine 61, a second drilling machine 62 and a third drilling machine 63 are sequentially arranged on the platform 6 along the X direction, the axis of the first drilling machine 61 is in the Y direction, the feeding mechanism, the second drilling machine 62 and the third drilling machine 63 are parallel to the axis of the first drilling machine 61, the axes of the feeding mechanism, the first drilling machine 61, the second drilling machine 62 and the third drilling machine 63 are positioned at the same height, the feeding mechanism is a circular tube 64, and an opening 641 is formed in the upper part of the circumferential surface of the circular tube 64;

The push rod 7, the push rod 7 is set in the round tube 64 along Y direction movement;

The cylinder body of the cylinder 8 is connected to the platform 6, the axial direction of the cylinder 8 is Y-direction, and the cylinder 8 is used for driving the push rod 7 to move;

a main shaft pulling claw 9, wherein the main shaft pulling claw 9 is connected to the base 1, the axis of the main shaft pulling claw 9 is parallel to the axial direction of the first drilling machine 61, and the axis of the main shaft pulling claw 9 and the axis of the first drilling machine 61 are positioned at the same height;

The conveying pipe 10, one end of the conveying pipe 10 is connected to the vibration feeding disc, and the other end of the conveying pipe 10 is positioned above the main shaft pulling claw 9;

the first drive assembly 2 switches the platform 6 in the first, second, third, fourth and fifth states;

in the first state, one end of the feed conveying pipe 10 is located above the opening 641;

in the second state, the axis of the main shaft pulling claw 9 coincides with the axis of the feeding mechanism;

in the third state, the axis of the spindle pull claw 9 coincides with the axis of the first drilling machine 61;

in the fourth state, the axis of the spindle pull claw 9 coincides with the axis of the second drilling machine 62;

in the fifth state, the axis of the spindle pull tab 9 coincides with the axis of the third drilling machine 63.

In the above embodiment, the device further includes a PLC controller electrically connected to the first driving assembly 2, the second driving assembly 4, and the air cylinder 8, and the following operations are completed by the setup program: the vibration feeding tray sends the idle hole into the feeding pipe 10 to be prior art, in the first state, the feeding pipe 10 sends the head of idle hole downwards into pipe 64, make the head of idle hole towards the direction of push rod 7, the second state, then cylinder 8 drive push rod 7 removes, make push rod 7 impel the idle hole into main shaft pull claw 9, main shaft pull claw 9 presss from both sides idle hole, through the feeding mode like this, replace manual place idle hole in the clamping station, the efficiency is improved, in the third state, through second drive assembly 4 in Y direction removal, main shaft pull claw 9 high-speed rotation, make first drilling machine 61 carry out preliminary location at the head of idle hole, first drill a shallow hole, improve the precision of its back drilling, in the fourth state, through second drive assembly 4 along Y direction removal, make the center drilling of the hole of idle hole that second drilling machine 62 aimed at idle hole preliminary location, in the fifth state, through second drive along Y direction removal, make third drilling machine 63 carry out the operation to the hole that second drilling machine 62 is finished, then carry out the operation along Y drive assembly 4 and pop out idle hole pulling claw 9, make the whole hole along the direction, in the fourth state, make idle hole drilling machine is far away from the idle hole 9, the whole is popped up the hole is moved along the main shaft pull claw 9. Compared with the prior art, the efficiency can be improved, and the precision of hole manufacturing of the idle measuring hole can be improved.

As an alternative embodiment, the first driving assembly 2 includes a first screw shaft 21, a first driving motor 22 and a first rail 23, the axis of the first screw shaft 21 is in the X direction, the direction of the first rail 23 is in the X direction, the first slider 3 is slidably connected with the screw shaft and the first rail 23, and the first driving motor 22 is in transmission connection with the first screw shaft 21.

In the above embodiment, the first slider 3 can be stably moved in the X direction by the engagement of the first rail 23 and the first screw shaft 21, and the processing accuracy of the idle hole can be improved without being shifted.

As an alternative embodiment, the second driving assembly 4 includes a base 41, a second screw shaft 42, a second driving motor 43 and a second rail 44, the axial direction of the second screw shaft 42 is the Y direction, the direction of the second rail 44 is the Y direction, the second slider 5 is slidably connected with the second screw shaft 42 and the second rail 44, and the second driving motor 43 is in transmission connection with the second screw shaft 42.

In the above embodiment, by utilizing the cooperation of the first driving assembly 2 and the second driving assembly 4, the platform 6 can be moved in the X direction and the Y direction, and the head processing accuracy of the idle measuring hole is ensured.

As an alternative embodiment, the idle measuring hole head processing device further comprises a first belt pulley 621, a second belt pulley 631, a third belt pulley 102 and a third driving motor 101, wherein the first belt pulley 621 is in transmission connection with the second drilling machine, the second belt pulley 631 is in transmission connection with the third drilling machine, the third driving motor 101 is connected to the platform 6, the third belt pulley 102 is in transmission connection with the third driving motor 101, and the first belt pulley 621, the second belt pulley 631 and the third belt pulley 102 are in transmission connection through a belt.

In the above embodiment, by providing the first pulley 621, the second pulley 631 and the third pulley 102, only one third driving motor 101 is required to simultaneously rotate the second drilling machine 62 and the third drilling machine 63, reducing the power consumption and cost for driving the second drilling machine and the third drilling machine.

As an alternative embodiment, the idle metering orifice head processing device further comprises a conveying groove 103, the conveying groove 103 is located below the spindle pull claw 9, and the conveying groove 103 is connected to the platform 6.

In the above embodiment, when the main shaft pulling claw 9 ejects the idle measuring hole along the reverse direction of Y, the idle measuring hole falls onto the conveying groove 103 through the elasticity and self gravity, and the idle measuring hole is conveyed to the collecting area by the conveying groove 103.

As an alternative embodiment, the circular baffle 104 is disposed on the circular tube 64, the circular baffle 104 is coaxially connected to the outer wall of the circular tube 64, the circular baffle 104 is located above the conveying groove 103, and the diameter of the circular baffle 104 is larger than that of the spindle pull claw 9.

In the above embodiment, by arranging the circular baffle 104, in order to prevent the elastic force of the spindle pulling claw 9 from being too large, the idle metering orifice is ejected out of the conveying groove 103, so that when the idle metering orifice is ejected along the reverse direction of Y, the conveying groove 103 falling below the baffle is blocked by the baffle, each idle metering orifice can accurately fall into the conveying groove 103, and the efficiency of conveying the idle metering orifice to a collecting area is improved.

The foregoing description is only illustrative of the present utility model and is not intended to limit the scope of the utility model, and all equivalent changes made by the specification and drawings of the present utility model, or direct or indirect application in the relevant art, are included in the scope of the present utility model.

Claims

1. A carburetor idle metering orifice head processing device, comprising:

a base;

the first driving assembly is connected to the base;

the second driving assembly is connected to the first sliding block;

the push rod is movably arranged in the circular tube along the Y direction;

2. The carburetor idle metering orifice head processing device of claim 1, wherein the first drive assembly includes a first screw shaft, a first drive motor and a first rail, the axis of the first screw shaft is in the X direction, the direction of the first rail is in the X direction, the first slider is slidably connected to the screw shaft and the first rail, and the first drive motor is in driving connection with the first screw shaft.

3. The carburetor idle metering orifice head processing device according to claim 1, wherein the second driving assembly comprises a base, a second screw spindle, a second driving motor and a second track, the second screw spindle is in a Y direction in the axial direction, the second track is in a Y direction in the direction, the second slider is in sliding connection with the second screw spindle and the second track, and the second driving motor is in transmission connection with the second screw spindle.

4. The carburetor idle metering orifice head processing device of claim 1, further comprising a first pulley, a second pulley, a third pulley, and a third drive motor, wherein the first pulley is drivingly connected to the second drill, the second pulley is drivingly connected to the third drill, the third drive motor is coupled to the platform, the third pulley is drivingly connected to the third drive motor, and the first pulley, the second pulley, and the third pulley are drivingly connected by a belt.

5. The carburetor idle port head processing device of claim 1, further comprising a feed slot positioned below the spindle pull tab, the feed slot being coupled to the platform.

6. The device for processing the idle measuring hole head of the carburetor of claim 5, wherein the circular baffle is arranged on the circular tube and is coaxially connected to the outer wall of the circular tube, the circular baffle is positioned above the conveying groove, and the diameter of the circular baffle is larger than that of the main shaft pulling claw.