CN114348942A - Environment-friendly long-life lubricating oil processing system and lubricating oil - Google Patents

Abstract

The invention relates to the field of filling, in particular to an environment-friendly long-life lubricating oil processing system and lubricating oil, which comprise a device bracket, a bottom mechanism, a conveying mechanism, a moving bracket and a filling mechanism, wherein the device bracket is connected with the bottom mechanism; an environment-friendly long-life lubricating oil comprises the following components in percentage by weight: 2-5 parts of pour point depressant; 36-55 parts of an antioxidant; 12 to 22 portions of antiwear agent; 7-12 parts of extreme pressure agent; 4 to 9 parts of synthetic ester; 5 to 11 parts of finger adhesive; the lubricating oil can be efficiently added to the cartridge.

Description

Environment-friendly long-life lubricating oil processing system and lubricating oil

Technical Field

The invention relates to the field of filling, in particular to an environment-friendly long-life lubricating oil processing system and lubricating oil.

Background

In the development process of modern industry, lubricating oil plays a very important role in the mechanical field, and can be lubricated, cooled, cleaned, antirust and the like, and a device facilitating the filling of the lubricating oil is also provided in the prior art, for example, patent No. CN2018222753806, which is named an automatic lubricating oil filling line, wherein although a flow line is used for filling the lubricating oil, a containing cylinder is stopped during filling, so that the filling efficiency is greatly influenced, and the invention has the defect that the lubricating oil cannot be efficiently added into the containing cylinder.

Disclosure of Invention

The invention aims to provide an environment-friendly long-life lubricating oil processing system and lubricating oil, which can be efficiently added into a containing cylinder.

The purpose of the invention is realized by the following technical scheme:

an environment-friendly long-life lubricating oil processing system comprises a device support, a bottom mechanism, two conveying mechanisms, a moving mechanism, a moving support and filling mechanisms, wherein the bottom mechanism is connected to the device support, the two conveying mechanisms are rotatably connected to the bottom mechanism, each conveying mechanism is provided with a power mechanism I for driving the conveying mechanism to rotate, the power mechanism I is preferably a servo motor, the device support is connected with the moving mechanism, the device support is slidably connected with the moving support, a reset spring is fixedly connected between the moving support and the device support, the moving support and the moving mechanism are in intermittent contact, and the moving support is fixedly connected with a plurality of filling mechanisms;

the device support comprises a mounting support, two telescopic mechanisms I and elastic baffles, wherein the two telescopic mechanisms I are fixedly connected to the mounting support, and the elastic baffles are fixedly connected to the telescopic ends of the two telescopic mechanisms I;

the bottom mechanism comprises two bidirectional screw rods I, a bottom support, support rings and bottom rotating wheels, the two bidirectional screw rods I are arranged, the two bidirectional screw rods I are rotationally connected to the mounting support, power mechanisms II for driving the two bidirectional screw rods I to rotate are arranged on the two bidirectional screw rods I, the power mechanisms II are preferably servo motors, the screw thread turning directions of the two ends of each bidirectional screw rod I are opposite, the two ends of each bidirectional screw rod I are connected with the bottom support through screw threads, the two ends of each bottom support are fixedly connected with the support rings, a plurality of bottom rotating wheels are rotationally connected between the two bottom supports, and compression springs I are fixedly connected between the bottom rotating wheels and the bottom supports;

the conveying mechanism comprises two rotating discs, limiting rods, a two-way screw rod II, extrusion side plates and an elastic spiral body, wherein a plurality of limiting rods are fixedly connected between the two rotating discs, the two-way screw rod II is rotatably connected between the two rotating discs, a power mechanism III for driving the two-way screw rod II to rotate is arranged on the two-way screw rod II, the power mechanism III is preferably a servo motor, the screwing directions of threads at two ends of the two-way screw rod II are opposite, two ends of the two-way screw rod II are both connected with the extrusion side plates through threads, the two extrusion side plates are both connected onto the limiting rods in a sliding mode, the elastic spiral body is fixedly connected between the two extrusion side plates and is connected onto the limiting rods in a sliding mode, and the four support rings are all rotatably connected with the rotating discs;

the moving mechanism is preferably a belt transmission mechanism, a power mechanism IV for driving the moving mechanism to move is arranged on the moving mechanism, and the power mechanism IV is preferably a servo motor;

the movable support comprises a sliding support, a telescopic mechanism II, a telescopic mechanism III and a friction disc, the telescopic mechanism II is fixedly connected to the sliding support, the telescopic mechanism II is preferably a double-head hydraulic cylinder, the two telescopic ends of the telescopic mechanism II are fixedly connected with a filling mechanism, the sliding support is fixedly connected with the telescopic mechanism III, the telescopic end of the telescopic mechanism III is fixedly connected with the friction disc, the friction disc can be contacted with the movable mechanism, the sliding support is slidably connected to the mounting support, and a reset spring is fixedly connected between the mounting support and the sliding support;

the filling mechanism comprises a telescopic mechanism IV, a filling cavity, a feeding pipeline, an extrusion column, a discharge pipeline, a one-way mechanism I and a one-way mechanism II, wherein the filling cavity is fixedly connected to the telescopic end of the telescopic mechanism IV, the feeding pipeline, the extrusion pipeline and the discharge pipeline are fixedly connected to the filling cavity, the one-way mechanism I is arranged in the feeding pipeline, the one-way mechanism II is arranged in the discharge pipeline, the extrusion column is slidably connected in the extrusion pipeline, and a compression spring II is fixedly connected between the extrusion column and the extrusion pipeline;

a plurality of containing cylinders are placed between the two conveying mechanisms, and the periphery of each containing cylinder is fixedly connected with a protection cavity.

An environment-friendly long-life lubricating oil comprises the following components in percentage by weight: 2-5 parts of pour point depressant; 36-55 parts of an antioxidant; 12 to 22 portions of antiwear agent; 7-12 parts of extreme pressure agent; 4 to 9 parts of synthetic ester; 5 to 11 parts of adhesive.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic diagram of an environmentally friendly, long life lubricating oil processing system of the present invention;

FIG. 2 is a schematic diagram of the overall architecture of the environmentally friendly long life lubricant processing system of the present invention;

FIG. 3 is a schematic view of the device support structure of the present invention;

FIG. 4 is a schematic view of the bottom mechanism of the present invention;

FIG. 5 is a schematic view of the transport mechanism of the present invention;

FIG. 6 is a schematic view of the moving mechanism of the present invention;

FIG. 7 is a schematic view of the mobile carriage configuration of the present invention;

FIG. 8 is a schematic view of the loading mechanism of the present invention;

FIG. 9 is a first schematic sectional view of the loading mechanism of the present invention;

FIG. 10 is a second structural schematic view of a cross-sectional view of the loading mechanism of the present invention;

fig. 11 is a schematic view of the cartridge of the present invention.

In the figure:

a device holder 1; a mounting bracket 11; a telescoping mechanism I12; an elastic baffle 13;

a bottom mechanism 2; a bidirectional screw rod I21; a bottom bracket 22; a support ring 23; a bottom runner 24;

a transport mechanism 3; a rotating disk 31; a stopper rod 32; a bidirectional screw rod II 33; pressing the side plates 34; an elastic spiral body 35;

a moving mechanism 4;

a movable support 5; a slide bracket 51; a telescoping mechanism II 52; a telescoping mechanism III 53; a friction disc 54;

a filling mechanism 6; a telescoping mechanism IV 61; a priming chamber 62; a feed line 63; the extrusion conduit 64; an extrusion column 65; a discharge conduit 66; a one-way mechanism I67; a one-way mechanism II 68;

a containing cylinder 7; a guard chamber 71.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

In order to solve the technical problem of how to efficiently add the lubricating oil into the container, the structure and function of an environment-friendly and long-life lubricating oil processing system will be described in detail with reference to fig. 1 to 11;

an environment-friendly long-life lubricating oil processing system comprises a device support 1, a bottom mechanism 2, conveying mechanisms 3, moving mechanisms 4, a moving support 5 and filling mechanisms 6, wherein the bottom mechanism 2 is connected to the device support 1, the two conveying mechanisms 3 are connected to the bottom mechanism 2 in a rotating mode, each conveying mechanism 3 is provided with a power mechanism I for driving the conveying mechanism to rotate, the power mechanism I is preferably a servo motor, the moving mechanism 4 is connected to the device support 1, the moving support 5 is connected to the device support 1 in a sliding mode, a reset spring is fixedly connected between the moving support 5 and the device support 1, the moving support 5 and the moving mechanisms 4 are in intermittent contact, and the plurality of filling mechanisms 6 are fixedly connected to the moving support 5;

when the device is used, the plurality of containing cylinders 7 are placed between the two conveying mechanisms 3, the two conveying mechanisms 3 push the plurality of containing cylinders 7 to move forwards, the containing cylinders 7 can be set to be different types according to different using requirements, and the corresponding two conveying mechanisms 3 can drive the containing cylinders 7 of different types;

the two transportation mechanisms 3 drive the plurality of filling cylinders 7 to pass through the plurality of filling mechanisms 6, the moving support 5 is in intermittent contact with the moving mechanism 4, the moving mechanism 4 drives the moving support 5 to move, the moving speed of the moving mechanism 4 driving the moving support 5 to move is the same as the speed of the two transportation mechanisms 3 pushing the plurality of filling cylinders 7 to move, so that the moving speed of the moving support 5 driving the plurality of filling mechanisms 6 to move is the same as the speed of the plurality of filling cylinders 7 to move, the plurality of filling mechanisms 6 and the plurality of filling cylinders 7 relatively move still, the plurality of filling mechanisms 6 are started to respectively fill the filling cylinders 7, after filling is completed, the moving mechanism 4 and the moving support 5 respectively reset under the pushing of a reset spring, the plurality of filling cylinders 7 of the next batch are prepared to be filled, the filling device works circularly, and the plurality of filling cylinders 7 do not need to stop moving during filling, thus greatly increasing the operating efficiency of the device.

As shown in FIG. 3, the structure and function of the device holder 1 will be described in detail;

the device support 1 comprises a mounting support 11, two telescopic mechanisms I12 and elastic baffles 13, wherein the mounting support 11 is fixedly connected with the two telescopic mechanisms I12, and the telescopic ends of the two telescopic mechanisms I12 are fixedly connected with the elastic baffles 13;

the mounting bracket 11 can provide mounting and sliding positions for the device, the elastic baffle 13 is preferably made of elastic materials, the elastic baffle 13 can be in contact with the moving bracket 5 to limit the moving bracket 5, and the elastic baffle 13 can also relieve impact force generated when the moving bracket 5 resets;

furthermore, a telescopic mechanism I12 can be started, the telescopic mechanism I12 can be a hydraulic cylinder or an electric push rod, a telescopic end of the telescopic mechanism I12 drives the elastic baffle 13 to move, the position of the elastic baffle 13 is further adjusted, the position of the movable support 5 during resetting is further adjusted, and when the type of the containing barrel 7 is changed, the position of the corresponding movable support 5 can be adjusted, so that different use requirements are met;

as shown in fig. 4, the structure and function of the bottom mechanism 2 will be described in detail;

the bottom mechanism 2 comprises two bidirectional screw rods I21, bottom supports 22, support rings 23 and bottom rotating wheels 24, the number of the bidirectional screw rods I21 is two, the two bidirectional screw rods I21 are rotatably connected to the mounting support 11, power mechanisms II for driving the two bidirectional screw rods I21 to rotate are arranged on the two bidirectional screw rods I21, the power mechanisms II are preferably servo motors, the rotating directions of threads at two ends of each bidirectional screw rod I21 are opposite, the bottom supports 22 are connected between two ends of each bidirectional screw rod I21 through threads, the support rings 23 are fixedly connected to two ends of each bottom support 22, a plurality of bottom rotating wheels 24 are rotatably connected between the two bottom supports 22, and compression springs I are fixedly connected between the bottom rotating wheels 24 and the bottom supports 22;

as shown in fig. 5, the structure and function of the transport mechanism 3 will be described in detail below;

the conveying mechanism 3 comprises two rotating discs 31, limiting rods 32, two-way screw rods II 33, two extrusion side plates 34 and elastic screws 35, the number of the rotating discs 31 is two, a plurality of limiting rods 32 are fixedly connected between the two rotating discs 31, the two-way screw rods II 33 are rotatably connected between the two rotating discs 31, a power mechanism III for driving the two-way screw rods II 33 to rotate is arranged on the two-way screw rods II 33, the power mechanism III is preferably a servo motor, the thread turning directions of two ends of each two-way screw rod II 33 are opposite, two ends of each two-way screw rod II 33 are both connected with the extrusion side plates 34 through threads, the two extrusion side plates 34 are both slidably connected to the limiting rods 32, the elastic screws 35 are fixedly connected between the two extrusion side plates 34, the elastic screws 35 are slidably connected to the limiting rods 32, and the four support rings 23 are both rotatably connected with the rotating discs 31;

when the packaging barrel is used, the packaging barrel 7 is placed between the gaps of the two elastic spiral bodies 35, the power mechanism I is started, the power mechanism I can be fixedly connected to the bottom support 22, the output shaft of the power mechanism I is in transmission connection with the rotating disc 31, the output shaft of the power mechanism I drives the rotating disc 31 to rotate, the rotating disc 31 drives the limiting rods 32 to rotate, the limiting rods 32 drive the elastic spiral bodies 35 to rotate, the two elastic spiral bodies 35 rotate together, and the two elastic spiral bodies 35 generate forward driving force when rotating so as to further push the packaging barrel 7 to move forwards;

furthermore, in order to enable the device to be capable of filling the containing barrels 7 with different sizes and models, the power mechanism II is started, the power mechanism II can be fixedly connected to the mounting support 11, an output shaft of the power mechanism II is in transmission connection with the bidirectional screw rod I21, the output shaft of the power mechanism II drives the bidirectional screw rod I21 to rotate, the two bottom supports 22 are driven to mutually approach or move away through threads when the bidirectional screw rod I21 rotates, the relative distance between the two bottom supports 22 is further adjusted, and the relative distance between the two elastic spiral bodies 35 is further adjusted;

further, a power mechanism III is started, the power mechanism III can be fixedly connected to the rotating disc 31, an output shaft of the power mechanism III is in transmission connection with the two-way screw rod II 33, the output shaft of the power mechanism III drives the two-way screw rod II 33 to rotate, the two extrusion side plates 34 are driven to move close to or away from each other through threads when the two-way screw rod II 33 rotates, the two extrusion side plates 34 are further enabled to extrude the elastic spiral body 35, the deformation size of the elastic spiral body 35 is further adjusted, the elastic spiral body 35 is preferably made of spring steel, the thread pitch of the elastic spiral body 35 is adjusted, and the device can be suitable for different types of containing barrels 7;

as shown in fig. 6, the structure and function of the moving mechanism 4 will be described in detail;

the moving mechanism 4 is preferably a belt transmission mechanism, a power mechanism IV for driving the moving mechanism 4 to move is arranged on the moving mechanism 4, and the power mechanism IV is preferably a servo motor;

as shown in fig. 7, the following describes the structure and function of the moving rack 5 in detail;

the movable support 5 comprises a sliding support 51, a telescopic mechanism II 52, a telescopic mechanism III 53 and a friction disc 54, the telescopic mechanism II 52 is fixedly connected to the sliding support 51, the telescopic mechanism II 52 is preferably a double-head hydraulic cylinder, the two telescopic ends of the telescopic mechanism II 52 are both fixedly connected with a filling mechanism 6, the telescopic mechanism III 53 is fixedly connected to the sliding support 51, the friction disc 54 is fixedly connected to the telescopic end of the telescopic mechanism III 53, the friction disc 54 can be contacted with the movable mechanism 4, the sliding support 51 is slidably connected to the mounting support 11, and a reset spring is fixedly connected between the mounting support 11 and the sliding support 51;

when the two conveying mechanisms 3 push the containing cylinders 7 to move forwards, the telescopic mechanism III 53 is started, the telescopic mechanism III 53 can be a hydraulic cylinder or an electric push rod, the telescopic end of the telescopic mechanism III 53 drives the friction disc 54 to move downwards, so that the friction disc 54 is contacted with the moving mechanism 4, the moving mechanism 4 is preferably a belt transmission mechanism, the friction disc 54 is contacted with a belt of the moving mechanism 4, the moving mechanism 4 drives the friction disc 54 to move, the friction disc 54 drives the moving support 5 to move, the moving support 5 drives the plurality of filling mechanisms 6 to move forwards, the moving speeds of the plurality of filling mechanisms 6 are the same as those of the plurality of containing cylinders 7, so that the plurality of filling mechanisms 6 and the plurality of containing cylinders 7 are relatively static, and the plurality of filling mechanisms 6 fill the plurality of containing cylinders 7;

after filling is finished, the telescopic mechanism III 53 is started, the telescopic end of the telescopic mechanism III 53 is retracted, the telescopic end of the telescopic mechanism III 53 drives the friction disc 54 to move, so that the friction disc 54 is out of contact with the moving mechanism 4, and the moving support 5 is reset under the pushing of the reset spring to prepare for next processing;

further, due to the change of the type of the cartridge 7, the distance between the two filling mechanisms 6 may need to be changed, and the distance between the two filling mechanisms 6 can be adjusted by starting the telescopic mechanism II 52;

as shown in fig. 8 to 10, the structure and function of the filling mechanism 6 will be described in detail;

the filling mechanism 6 comprises a telescopic mechanism IV 61, a filling cavity 62, a feeding pipeline 63, an extrusion pipeline 64, an extrusion column 65, a discharge pipeline 66, a one-way mechanism I67 and a one-way mechanism II 68, wherein the telescopic end of the telescopic mechanism IV 61 is fixedly connected with the filling cavity 62, the filling cavity 62 is fixedly connected with the feeding pipeline 63, the extrusion pipeline 64 and the discharge pipeline 66, the feeding pipeline 63 is internally provided with the one-way mechanism I67, the discharge pipeline 66 is internally provided with the one-way mechanism II 68, the extrusion column 65 is connected in the extrusion pipeline 64 in a sliding manner, and a compression spring II is fixedly connected between the extrusion column 65 and the extrusion pipeline 64;

as shown in fig. 11, the structure and function of the cartridge 7 will be described in detail;

a plurality of containing cylinders 7 are arranged between the two conveying mechanisms 3, and the periphery of each containing cylinder 7 is fixedly connected with a protection cavity 71;

the filling process is explained in detail below, during filling, the telescopic mechanism iv 61 is started, the telescopic end of the telescopic mechanism iv 61 drives the filling cavity 62 to move downwards, the feeding pipeline 63, the extruding pipeline 64, the extruding column 65, the discharging pipeline 66, the one-way mechanism i 67 and the one-way mechanism ii 68 move downwards together, the extruding column 65 is in contact with the protection cavity 71, the protection cavity 71 pushes the extruding column 65 to move upwards, and the extruding column 65 extrudes the lubricating oil in the extruding pipeline 64, so that the lubricating oil enters the containing barrel 7 through the discharging pipeline 66;

under the condition that the distance of downward movement of the telescopic mechanism IV 61 is fixed each time, the higher the protective cavity 71 is, the larger the extrusion movement amount of the extrusion column 65 is, namely, the larger the filling amount is;

when the containing barrel 7 is set to be different models, the protection cavity 71 needs to be correspondingly set, the protection cavity 71 is a hollow cavity, the containing barrel 7 can be protected from being collided during transportation, the height of the protection cavity 71 can be set according to different use requirements, and when the model of the containing barrel 7 is increased, namely the filling quantity is increased, the protection cavity 71 needs to be increased, the corresponding filling quantity is increased, and the corresponding filling requirements under different models are further met;

when the telescopic end of the telescopic mechanism IV 61 is retracted, the extrusion column 65 resets under the action of the compression spring II, the lubricating oil pipeline is connected to the feeding pipeline 63 in advance, the one-way mechanism I67 ensures that lubricating oil can only flow into the feeding pipeline 63 from the outside, the one-way mechanism I67 ensures that lubricating oil can only flow out of the discharging pipeline 66, and then when the extrusion column 65 resets, the lubricating oil in the lubricating oil pipeline can be automatically pumped into the feeding pipeline 63 under the action of pressure intensity to prepare for next processing;

an environment-friendly long-life lubricating oil comprises the following components in percentage by weight: 2-5 parts of pour point depressant; 36-55 parts of an antioxidant; 12 to 22 portions of antiwear agent; 7-12 parts of extreme pressure agent; 4 to 9 parts of synthetic ester; 5 to 11 parts of adhesive.

Claims (10)

1. The utility model provides an environmental protection high life lubricating oil processing system, includes device support (1) and bottom mechanism (2) of connection on device support (1), rotates on bottom mechanism (2) and is connected with two transport mechanism (3), its characterized in that: a plurality of containing cylinders (7) are placed between the two conveying mechanisms (3), the device support (1) is connected with a moving support (5) in a sliding mode, a reset spring is fixedly connected between the moving support (5) and the device support (1), the moving support (5) is in intermittent contact with the moving mechanism (4), a plurality of filling mechanisms (6) are fixedly connected to the moving support (5), and the moving mechanism (4) is connected to the device support (1).

2. The environmentally friendly, long life lubricant processing system of claim 1, wherein: the device support (1) comprises a mounting support (11) and two telescopic mechanisms I (12) fixedly connected to the mounting support (11), and elastic baffles (13) are fixedly connected to the telescopic ends of the two telescopic mechanisms I (12).

3. The environmentally friendly, long life lubricant processing system of claim 1, wherein: bottom mechanism (2) include two-way lead screw I (21), all have bottom support (22) through threaded connection between the both ends of two-way lead screw I (21), the equal fixedly connected with support ring (23) in both ends of two bottom supports (22), rotate between two bottom supports (22) and be connected with a plurality of bottom runners (24), fixedly connected with compression spring I between bottom runner (24) and bottom support (22).

4. The environmentally friendly, long life lubricant processing system of claim 3, wherein: the thread directions of the two ends of the bidirectional screw rod I (21) are opposite.

5. The environmentally friendly, long life lubricant processing system of claim 1, wherein: transport mechanism (3) include two rolling discs (31), a plurality of gag lever posts of fixedly connected with (32) between two rolling discs (31), it is connected with two-way lead screw II (33) to rotate between two rolling discs (31), the both ends of two-way lead screw II (33) all have extrusion curb plate (34) through threaded connection, two equal sliding connection of extrusion curb plate (34) are on gag lever post (32), fixed connection has elastic spirochaeta (35) between two extrusion curb plate (34), elastic spirochaeta (35) sliding connection is on gag lever post (32).

6. The environmentally friendly, long life lubricant processing system of claim 5, wherein: and the thread directions of the two ends of the bidirectional screw rod II (33) are opposite.

7. The environmentally friendly, long life lubricant processing system of claim 1, wherein: the movable support (5) comprises a sliding support (51) and a telescopic mechanism II (52) fixedly connected to the sliding support (51), the telescopic mechanism II (52) is a double-head hydraulic cylinder, two telescopic ends of the telescopic mechanism II (52) are fixedly connected with a filling mechanism (6), the sliding support (51) is fixedly connected with a telescopic mechanism III (53), the telescopic ends of the telescopic mechanism III (53) are fixedly connected with friction discs (54), and the friction discs (54) can be in contact with the movable mechanism (4).

8. The environmentally friendly, long life lubricant processing system of claim 7, wherein: the filling mechanism (6) comprises a telescoping mechanism IV (61) and a filling cavity (62) fixedly connected to the telescopic end of the telescoping mechanism IV (61), a feeding pipeline (63), an extrusion pipeline (64) and a discharging pipeline (66) are fixedly connected to the filling cavity (62), a one-way mechanism I (67) is arranged in the feeding pipeline (63), a one-way mechanism II (68) is arranged in the discharging pipeline (66), an extrusion column (65) is slidably connected to the extrusion pipeline (64), and a compression spring II is fixedly connected between the extrusion column (65) and the extrusion pipeline (64).

9. The environmentally friendly, long life lubricant processing system of claim 1, wherein: a plurality of containing cylinders (7) are arranged between the two conveying mechanisms (3), and the periphery of each containing cylinder (7) is fixedly connected with a protection cavity (71).

10. The lubricating oil processed by using the environment-friendly long-life lubricating oil processing system of claim 1, wherein: the lubricating oil comprises the following components in percentage by weight: 2-5 parts of pour point depressant; 36-55 parts of an antioxidant; 12 to 22 portions of antiwear agent; 7-12 parts of extreme pressure agent; 4 to 9 parts of synthetic ester; 5 to 11 parts of adhesive.

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