阅读说明：本技术 一种带有润滑功能的高速电机 (High-speed motor with lubricating function ) 是由 熊俊 于 2021-08-17 设计创作，主要内容包括：本发明涉及一种高速电机,尤其涉及一种带有润滑功能的高速电机。本发明的目的是提供一种带有润滑功能,多样化功能特点,适用范围更广的带有润滑功能的高速电机。本发明的技术方案为：一种带有润滑功能的高速电机,包括：润滑组件,高速电机内侧之间连接有润滑组件；脱离组件,高速电机的输出轴上连接有脱离组件；驱动组件,高速电机一侧连接有驱动组件。本发明通过储料缸、活塞缸、第一活塞和第一推杆的配合,以达到对高速电机上润滑油的目的。(The invention relates to a high-speed motor, in particular to a high-speed motor with a lubricating function. The invention aims to provide a high-speed motor with a lubricating function, which has the characteristics of lubricating function, diversified functions and wider application range. The technical scheme of the invention is as follows: a high-speed electric machine with a lubricating function, comprising: the lubricating component is connected between the inner sides of the high-speed motors; the output shaft of the high-speed motor is connected with the disengaging assembly; and one side of the high-speed motor is connected with the driving component. The invention achieves the purpose of lubricating oil on the high-speed motor by matching the storage cylinder, the piston cylinder, the first piston and the first push rod.)

1. The utility model provides a high-speed motor with lubricating function, characterized by includes:

the lubricating component (2) is connected between the inner sides of the high-speed motors (1);

the output shaft of the high-speed motor (1) is connected with the disengaging component (3);

the driving component (4) is connected with one side of the high-speed motor (1).

2. A high-speed electric machine with lubrication according to claim 1, characterised in that the lubricating package (2) comprises:

the storage cylinder (201) is connected to the high-speed motor (1);

one side of the storage vat (201) is connected with the one-way feeding port (202);

the feeding pipe (207) is connected to the inner side of the storage vat (201), and the feeding pipe (207) penetrates through the storage vat (201);

the top side of the feeding pipe (207) is connected with the piston cylinder (203);

the first piston (204) is connected in the piston cylinder (203) in a sliding manner;

the top side of the first piston (204) is connected with a first push rod (205);

a first spring (206), wherein the first spring (206) is arranged between the first piston (204) and the piston cylinder (203);

a discharge pipe (208) is connected to one side of the piston cylinder (203);

keep off material lid (209), discharging pipe (208) one side is connected with keeps off material lid (209), keeps off material lid (209) bottom side and is connected with high-speed motor (1) top side.

3. A high-speed electric machine with lubrication according to claim 2, characterised in that the disengagement assembly (3) comprises:

one side of the high-speed motor (1) is connected with the supporting rod (302);

one side of the support rod (302) is connected with the bearing (303);

the inner side of the bearing (303) is connected with the shaft sleeve (304);

the first transmission assembly (301) is wound between the shaft sleeve (304) and an output shaft of the high-speed motor (1);

the first rotating shaft (305) is connected with the shaft sleeve (304) in a sliding manner; a second spring (306), wherein the second spring (306) is connected between the top side of the first rotating shaft (305) and the top wall of the shaft sleeve (304);

a first guide rod (307), wherein one side of the bearing (303) is connected with the first guide rod (307);

the top rod (308) is connected with the first guide rod (307) in a sliding way;

and a third spring (309), wherein the third spring (309) is arranged between the first guide rod (307) and the top rod (308), and the third spring (309) is positioned on one side of the top rod (308).

4. A high-speed electric machine with lubrication according to claim 3, characterised in that the drive assembly (4) comprises:

the supporting frame (402) is connected to one side of the high-speed motor (1);

the second rotating shaft (404) is connected in the supporting frame (402) in a rotating mode;

the bevel gear set (403), the bevel gear set (403) is connected to the second rotating shaft (404), and the support frame (402) is rotatably connected with the bevel gear set (403);

the support rod (302) is rotatably connected with the rotating shaft (409);

the second transmission assembly (401) is wound between the rotating shaft (409) and a square bevel gear set (403);

a worm (405), the second rotating shaft (404) being connected with the worm (405);

one side of the material storage cylinder (201) is connected with the first supporting block (406);

the first wedge block (408) is connected in the first supporting block (406) in a rotating manner;

the tail end of the first wedge block (408) is connected with a worm wheel (407), and the worm wheel (407) is meshed with the worm (405).

5. A high-speed electric motor with lubrication according to claim 4, further comprising a clamping unit (5), wherein the clamping unit (5) comprises:

the top side of the support rod (302) is connected with the second support block (501);

the clamping block (502) is connected to the second supporting block (501) in an inward sliding mode;

one side of the clamping block (502) is connected with the pull rod (504);

and a fourth spring (503) is arranged between the fixture block (502) and the second supporting block (501).

6. A high-speed electric machine with lubrication according to claim 5, further comprising a reset assembly (6), the reset assembly (6) comprising:

the third supporting block (601) is connected between the inner sides of the supporting frames (402);

the first sliding rod (602) is connected with the third supporting block (601) in an inward sliding manner;

the two sides of the top of the first sliding rod (602) are both connected with a fifth spring (603), and the fifth spring (603) is connected with the top wall of the third supporting block (601);

a second sliding rod (604), one side of the first sliding rod (602) is connected with the second sliding rod (604), and the bottom side of the second sliding rod (604) is contacted with the top side of the first push rod (205);

the second push rod (605), the second sliding rod (604) is connected with the second push rod (605) in a sliding way;

a sixth spring (606), wherein the sixth spring (606) is connected between the inner wall of one side of the second push rod (605) and one side of the second sliding rod (604);

and one side of the ejector rod (308) is connected with a second wedge block (607).

7. A high-speed electric machine with lubrication according to claim 6, further comprising an observation assembly (7), the observation assembly (7) comprising:

the pulley (702) is rotatably connected in both sides of the piston cylinder (203);

the two sides of one part of the storage cylinder (201) are connected with the second guide rod (704);

the connecting rod (705) is connected between the second guide rods (704) in a sliding manner;

the top side of the connecting rod (705) is connected with the pointer (706);

the second piston (701) is connected with the storage cylinder (201) in a sliding manner;

the pull rope (703) is connected to both sides of the top of the connecting rod (705), and the pull rope (703) is connected with the second piston (701) by bypassing the pulley (702);

the scale plate (707) is connected to one side of the storage cylinder (201).

8. A high-speed electric machine with lubrication according to claim 2, characterised in that the first spring (206) is an extension spring.

Technical Field

The invention relates to a high-speed motor, in particular to a high-speed motor with a lubricating function.

Background

The high-speed motor generally refers to a motor with the rotating speed exceeding 10000r/min, is small in size, can be directly connected with a high-speed load, saves a traditional mechanical speed increasing device, reduces system noise and improves system transmission efficiency, and at present, induction motors, permanent magnet motors and switched reluctance motors are mainly used for successfully realizing high speed.

The high-speed motor is mainly characterized by high rotor speed, high stator winding current and magnetic flux frequency in an iron core, and high power density and loss density, and the characteristics determine that the high-speed motor has a special key technology and a special design method different from a normal-speed motor, and the design and manufacturing difficulty is usually doubled and larger than that of a common-speed motor.

The invention researches and develops a high-speed motor with a lubricating function, which has the characteristics of lubricating function, diversified functions and wider application range.

Disclosure of Invention

In order to overcome the defects of single function and small application range, the technical problems to be solved are as follows: the high-speed motor with the lubricating function has the characteristics of lubricating function, diversified functions and wider application range.

The technical scheme is as follows: a high-speed electric machine with a lubricating function, comprising:

the lubricating component is connected between the inner sides of the high-speed motors;

the output shaft of the high-speed motor is connected with the disengaging assembly;

and one side of the high-speed motor is connected with the driving component.

Further, the lubrication assembly includes:

the high-speed motor is connected with the storage cylinder;

one side of the storage vat is connected with the one-way feeding port;

the inner side of the storage vat is connected with a feeding pipe, and the feeding pipe penetrates through the storage vat;

the top side of the feeding pipe is connected with the piston cylinder;

the first piston is connected in the piston cylinder in a sliding manner;

the top side of the first piston is connected with a first push rod;

a first spring is arranged between the first piston and the piston cylinder;

one side of the piston cylinder is connected with a discharge pipe;

and the material blocking cover is connected to one side of the discharge pipe, and the bottom side of the material blocking cover is connected with the top side of the high-speed motor.

Further, the disengaging assembly comprises:

one side of the high-speed motor is connected with the supporting rod;

one side of the support rod is connected with a bearing;

the inner side of the bearing is connected with the shaft sleeve;

the first transmission assembly is wound between the shaft sleeve and the output shaft of the high-speed motor;

the first rotating shaft is connected in the shaft sleeve in a sliding manner;

the second spring is connected between the top side of the first rotating shaft and the top wall of the shaft sleeve;

one side of the bearing is connected with a first guide rod;

the first guide rod is connected with the ejector rod in a sliding manner;

and a third spring is arranged between the first guide rod and the ejector rod and is positioned on one side of the ejector rod.

Further, the driving assembly includes:

one side of the high-speed motor is connected with the support frame;

the second rotating shaft is connected in the supporting frame in a rotating manner;

the second rotating shaft is connected with a bevel gear set, and the support frame is rotatably connected with the bevel gear set;

the support rod is internally and rotatably connected with a rotating shaft;

the second transmission component is wound between the rotating shaft and the bevel gear set;

the second rotating shaft is connected with a worm;

one side of the storage cylinder is connected with a first supporting block;

the first wedge block is connected in the first supporting block in a rotating manner;

the tail end of the first wedge block is connected with a worm wheel, and the worm wheel is meshed with the worm.

Further, still including the chucking subassembly, the chucking subassembly includes:

the top side of the supporting rod is connected with a second supporting block;

the clamping block is connected with the second supporting block in a sliding manner;

one side of the clamping block is connected with a pull rod;

and a fourth spring is arranged between the clamping block and the second supporting block.

Further, still including reset assembly, reset assembly includes:

the third supporting block is connected between the inner sides of the supporting frames;

the third supporting block is internally connected with a first sliding rod in a sliding manner;

the two sides of the top of the first sliding rod are both connected with fifth springs, and the fifth springs are connected with the top wall of the third supporting block;

one side of the first sliding rod is connected with a second sliding rod, and the bottom side of the second sliding rod is in contact with the top side of the first push rod;

the second push rod is connected with the second sliding rod in a sliding manner;

a sixth spring is connected between the inner wall of one side of the second push rod and one side of the second slide rod;

and one side of the ejector rod is connected with the second wedge block.

Further, still including observation subassembly, observation subassembly includes:

the pulleys are rotatably connected in two sides of the piston cylinder;

the two sides of one part of the storage cylinder are both connected with second guide rods;

the connecting rod is connected between the second guide rods in a sliding manner;

the top side of the connecting rod is connected with a pointer;

the storage cylinder is internally connected with a first piston in a sliding manner;

the two sides of the top of the connecting rod are both connected with pull ropes, and the pull ropes are connected with the second piston by bypassing the pulleys;

the scale plate is connected to one side of the storage cylinder.

Further, the first spring is an extension spring.

The invention has the beneficial effects that: 1. through the cooperation of storage cylinder, piston cylinder, first piston and first push rod to reach the purpose to lubricating oil on the high-speed motor.

2. Through the cooperation of first transmission assembly, axle sleeve, first rotation axis and ejector pin to reach the purpose that realizes intermittent type and drive other subassembly movements.

3. Through the cooperation of second transmission assembly, second rotation axis, turbine and first wedge to reach the automatic mesh of intermittent type nature transport lubricating oil.

4. Through the cooperation of second supporting shoe, fixture block, fourth spring and pull rod to reach chucking device, convenient to use's purpose.

5. The purpose of automatically controlling the operation of the device is achieved through the matching of the first sliding rod, the second push rod, the second sliding rod and the second wedge-shaped block.

6. Through the cooperation of second piston, connecting rod, pointer and scale plate to reach the purpose that facilitates the use personnel and survey lubricating oil surplus, convenient to use.

Drawings

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

Fig. 2 is a schematic perspective view of another perspective structure according to the present invention.

FIG. 3 is a schematic diagram of a first partial structure according to the present invention.

FIG. 4 is a second partial structure diagram of the present invention.

FIG. 5 is a third partial structural diagram of the present invention.

FIG. 6 is a schematic diagram of a fourth partial structure of the present invention.

FIG. 7 is a schematic diagram of a fifth partial structure according to the present invention.

FIG. 8 is a schematic diagram of a sixth partial structure according to the present invention.

In the reference symbols: 1-a high-speed motor, 2-a lubricating component, 201-an accumulator, 202-a one-way inlet, 203-a piston cylinder, 204-a first piston, 205-a first push rod, 206-a first spring, 207-an inlet pipe, 208-an outlet pipe, 209-a material blocking cover, 3-a disengaging component, 301-a first transmission component, 302-a support rod, 303-a bearing, 304-a shaft sleeve, 305-a first rotating shaft, 306-a second spring, 307-a first guide rod, 308-an ejector rod, 309-a third spring, 4-a driving component, 401-a second transmission component, 402-a support frame, 403-a bevel gear set, 404-a second rotating shaft, 405-a worm, 406-a first support block, 407-a turbine and 408-a first wedge block, 409-a rotating shaft, 5-a clamping assembly, 501-a second supporting block, 502-a clamping block, 503-a fourth spring, 504-a pull rod, 6-a reset assembly, 601-a third supporting block, 602-a first sliding rod, 603-a fifth spring, 604-a second sliding rod, 605-a second push rod, 606-a sixth spring, 607-a second wedge-shaped block, 7-an observation assembly, 701-a second piston, 702-a pulley, 703-a pull rope, 704-a second guide rod, 705-a connecting rod, 706-a pointer and 707-a scale plate.

Detailed Description

The invention is described in detail below with reference to the figures and the embodiments.

Example 1

A high-speed motor with a lubricating function is shown in figures 1 and 2 and comprises a high-speed motor 1, a lubricating component 2, a separating component 3 and a driving component 4, wherein the lubricating component 2 is connected between the inner sides of the high-speed motor 1, the separating component 3 is connected to an output shaft of the high-speed motor 1, and the driving component 4 is connected to the front side of the high-speed motor 1.

When the equipment is needed to be used, a user can pour lubricating oil into the lubricating component 2 to achieve the purpose of lubricating oil on the high-speed motor 1, the initial state of the disengaging component 3 is a compression state, the disengaging component 3 is loosened, the disengaging component 3 slides downwards at the moment, the high-speed motor 1 is started, the high-speed motor 1 rotates reversely to drive the disengaging component 3 to rotate reversely, the disengaging component 3 rotates reversely to drive the driving component 4 to rotate reversely, when the driving component 4 rotates reversely to be in contact with the lubricating component 2, the lubricating component 2 slides upwards, the lubricating component 2 is compressed at the moment, when the driving component 4 rotates reversely to be not in contact with the lubricating component 2, the lubricating component 2 is driven to slide downwards under the reset action of the lubricating component 2, the lubricating oil can pass through the lubricating component 2 to the high-speed motor 1 to achieve the purpose of intermittently driving other components to move, the disengaging component 3 is pushed rightwards, so that the separation component 3 slides upwards, the separation component 3 is compressed at the moment, after the operation is finished, the high-speed motor 1 is closed, and when the motor is used again, the operation is repeated.

Example 2

On the basis of embodiment 1, as shown in fig. 3, the lubricating assembly 2 comprises an accumulator 201, a one-way inlet 202, a piston cylinder 203, a first piston 204, the device comprises a first push rod 205, a first spring 206, a feeding pipe 207, a discharging pipe 208 and a material blocking cover 209, wherein a storage cylinder 201 is connected to a high-speed motor 1, a unidirectional feeding port 202 is connected to the right side of the storage cylinder 201, the feeding pipe 207 is connected to the inner side of the storage cylinder 201, the feeding pipe 207 penetrates through the storage cylinder 201, a piston cylinder 203 is connected to the upper side of the feeding pipe 207, a first piston 204 is connected to the inner sliding side of the piston cylinder 203, the upper side of the first piston 204 is connected with the first push rod 205, the first spring 206 is arranged between the first piston 204 and the piston cylinder 203, the first spring 206 is located at the upper side of the storage cylinder 201, the discharging pipe 208 is connected to the left side of the piston cylinder 203, the material blocking cover 209 is connected to the left side of the discharging pipe 208, and the lower side of the material blocking cover 209 is connected with the upper side of the high-speed motor 1.

When the equipment needs to be used, a user can pour lubricating oil into the one-way feeding port 202, the lubricating oil enters the storage tank 201 through the one-way feeding port 202, the high-speed motor 1 is started, the high-speed motor 1 rotates reversely to drive the separation component 3 to rotate reversely, the separation component 3 rotates reversely to drive the driving component 4 to rotate reversely, when the driving component 4 rotates reversely to be in contact with the first push rod 205, the first push rod 205 is driven to move upwards, the first push rod 205 moves upwards to drive the first piston 204 to slide upwards in the piston cylinder 203, the lubricating oil enters the piston cylinder 203 through the feeding pipe 207, when the driving component 4 rotates reversely to be out of contact with the first push rod 205, the first push rod 205 is driven to move downwards under the reset action of the first spring 206, the first push rod 205 moves downwards to drive the first piston 204 to slide downwards, and the lubricating oil enters the discharging pipe 208 through the piston cylinder 203, and finally, the lubricating oil enters the material blocking cover 209 through the material discharging pipe 208 and flows onto the high-speed motor 1, so that the purpose of lubricating the high-speed motor 1 is achieved, subsequent operation is continued, after the operation is finished, the high-speed motor 1 is closed, and when the motor is used again, the operation is repeated.

As shown in fig. 4, the detaching assembly 3 includes a first transmission assembly 301, a support rod 302, a bearing 303, a shaft sleeve 304, a first rotation shaft 305, a second spring 306, a first guide rod 307, a top rod 308 and a third spring 309, the support rod 302 is connected to the left side of the high-speed motor 1, the bearing 303 is connected to the left side of the support rod 302, the shaft sleeve 304 is connected to the inner side of the bearing 303, the first transmission assembly 301 is wound between the shaft sleeve 304 and the output shaft of the high-speed motor 1, the first rotation shaft 305 is connected to the shaft sleeve 304 in a sliding manner, the second spring 306 is connected between the top side of the first rotation shaft 305 and the top wall of the shaft sleeve 304, the first guide rod 307 is connected to the left side of the bearing 303, the top rod 308 is connected to the first guide rod 307 in a sliding manner, the third spring 309 is arranged between the first guide rod 307 and the top rod 308, and the third spring 309 is located at the right side of the top rod 308.

When the high-speed motor 1 rotates reversely, the first transmission assembly 301 is driven to rotate reversely, the first transmission assembly 301 rotates reversely to drive the shaft sleeve 304 to rotate reversely in the bearing 303, the initial state of the third spring 309 is a compression state, the push rod 308 is released, under the reset action of the third spring 309, the push rod 308 is driven to slide leftwards on the first guide rod 307, the initial state of the second spring 306 is a compression state, under the reset action of the second spring 306, the first rotating shaft 305 is driven to slide downwards in the shaft sleeve 304, so that the purpose of intermittently driving other assemblies to move is achieved, the push rod 308 is pushed rightwards, at the moment, the third spring 309 is compressed, the first rotating shaft 305 slides upwards through the rightward movement of the push rod 308, after the operation is finished, the high-speed motor 1 is closed, and when the high-speed motor is used again, the operation is repeated.

As shown in fig. 5, the driving assembly 4 includes a second transmission assembly 401, a supporting frame 402, a bevel gear set 403, a second rotating shaft 404, the high-speed motor comprises a worm 405, a first supporting block 406, a worm wheel 407, a first wedge block 408 and a rotating shaft 409, wherein the front side of the high-speed motor 1 is connected with a supporting frame 402, the supporting frame 402 is rotatably connected with a second rotating shaft 404, the second rotating shaft 404 is connected onto the second rotating shaft 404, the supporting frame 402 is rotatably connected with the bevel gear set 403, the rotating shaft 409 is rotatably connected onto the supporting rod 302, a second transmission assembly 401 is wound between the rotating shaft 409 and the upper bevel gear set 403, the first rotating shaft 305 is matched with the second transmission assembly 401, the second rotating shaft 404 is connected with the worm 405, the front side of the material storage cylinder 201 is connected with the first supporting block 406, the first wedge block 408 is rotatably connected onto the first supporting block 406, the tail end of the first wedge block 408 is connected with the worm wheel 407, and the worm wheel 407 is meshed with the worm 405.

When the first rotating shaft 305 slides downwards to be inserted into the second transmission assembly 401, the second transmission assembly 401 is driven to rotate reversely, the second transmission assembly 401 rotates reversely to drive the rotating shaft 409 to rotate reversely in the supporting rod 302, the second transmission assembly 401 rotates reversely to drive the upper bevel gear set 403 to rotate reversely in the supporting frame 402, then the lower bevel gear set 403 is driven to rotate forward in the supporting frame 402, the lower bevel gear set 403 rotates forward to drive the second rotating shaft 404 to rotate forward in the supporting frame 402, the second rotating shaft 404 rotates forward to drive the worm 405 to rotate forward, the worm 405 rotates forward to drive the turbine 407 to rotate reversely, the turbine 407 rotates reversely to drive the first wedge block 408 to rotate reversely in the first supporting block 406, when the first wedge block 408 rotates reversely to contact with the first push rod 205, the first push rod 205 is driven to slide upwards, when the first wedge block 408 rotates reversely to not contact with the first push rod 205, the first push rod 205 slides downwards, so as to achieve the purpose of automatic intermittent lubricant delivery, the subsequent operation is continued, when the first rotating shaft 305 slides upwards, the second transmission assembly 401 stops rotating, and then the first wedge block 408 stops rotating, and when the first wedge block is used again, the operation is repeated.

As shown in fig. 6, the clamping device further includes a clamping assembly 5, the clamping assembly 5 includes a second supporting block 501, a clamping block 502, a fourth spring 503 and a pull rod 504, the second supporting block 501 is connected to the upper side of the supporting rod 302, the clamping block 502 is connected to the second supporting block 501 in a sliding manner, the pull rod 504 is connected to the rear side of the clamping block 502, and the fourth spring 503 is disposed between the clamping block 502 and the second supporting block 501.

When the push rod 308 is required to be separated from the first rotating shaft 305, a user can pull the pull rod 504 backwards, the pull rod 504 moves backwards to drive the fixture block 502 to slide backwards in the second supporting block 501, at the moment, the fourth spring 503 is compressed, the push rod 308 is driven to slide leftwards under the reset action of the third spring 309, subsequent operation is continued, when the push rod 308 is required to clamp the first rotating shaft 305, the user can push the push rod 308 rightwards, then the pull rod 504 is released, the fixture block 502 is driven to slide forwards under the reset action of the fourth spring 503, the fixture block 502 slides forwards to drive the pull rod 504 to move forwards, subsequent operation is continued, the clamping device is achieved, the purpose of using is facilitated, and when the device is used again, the operation can be repeated.

As shown in fig. 7, the device further includes a reset assembly 6, the reset assembly 6 includes a third supporting block 601, a first sliding rod 602, a fifth spring 603, a second sliding rod 604, a second push rod 605, a sixth spring 606 and a second wedge-shaped block 607, the third supporting block 601 is connected between the inner sides of the supporting frames 402, the first sliding rod 602 is connected in the third supporting block 601 in a sliding manner, the fifth spring 603 is connected to both the left and right sides of the upper portion of the first sliding rod 602, the fifth spring 603 is connected to the top wall of the third supporting block 601, the second sliding rod 604 is connected to the rear side of the first sliding rod 602, the lower side of the second sliding rod 604 contacts with the upper side of the first push rod 205, the second sliding rod 604 is connected in a sliding manner to a second push rod 605, the sixth spring 606 is connected between the right wall of the second push rod 605 and the left side of the second sliding rod 604, and the left side of the top rod 308 is connected to a second wedge-shaped block 607.

When the fixture block 502 slides backwards, under the reset action of the third spring 309, the top rod 308 is driven to slide leftwards, the top rod 308 slides leftwards to drive the second wedge 607 to move leftwards, the top rod 308 slides leftwards to drive the second push rod 605 to slide leftwards on the second slide rod 604, at this time, the fifth spring 603 is stretched, when the first push rod 205 moves upwards, the second slide rod 604 is driven to move upwards, the second slide rod 604 moves upwards to drive the first slide rod 602 to slide upwards in the third support block 601, at this time, the fifth spring 603 is compressed, the second slide rod 604 moves upwards to drive the second push rod 605 to move upwards, the second push rod 605 moves upwards to drive the second wedge 607 to move rightwards, the second wedge 607 moves rightwards to drive the top rod 308 to slide rightwards, at this time, the third spring 309 is compressed, when the first push rod 205 moves downwards, the second slide rod 604 moves downwards to drive the first slide rod 602 to slide downwards, the second sliding rod 604 moves downwards to drive the second push rod 605 to move downwards, under the reset action of the sixth spring 606, the second push rod 605 is driven to slide rightwards, meanwhile, the fifth spring 603 resets, and subsequent operations are continued, so that the purpose of automatically controlling the operation of the device is achieved, and when the device is used again, the operation is repeated.

As shown in fig. 8, the observing device 7 further comprises an observing assembly 7, the observing assembly 7 comprises a second piston 701, a pulley 702, a pull rope 703, a second guide rod 704, a connecting rod 705, a pointer 706 and a scale plate 707, the pulleys 702 are rotatably connected in the left side and the right side of the piston cylinder 203, the second guide rods 704 are connected on the front side and the rear side of the right portion of the storage cylinder 201, the connecting rod 705 is slidably connected between the second guide rods 704, the pointer 706 is connected on the upper side of the connecting rod 705, the second piston 701 is slidably connected in the storage cylinder 201, the pull rope 703 is connected on the front side and the rear side of the upper portion of the connecting rod 705, the pull rope 703 bypasses the pulley 702 and is connected with the second piston 701, and the scale plate 707 is connected on the right side of the storage cylinder 201.

After the lubricating oil enters the storage cylinder 201, the second piston 701 slides upwards in the storage cylinder 201, the second piston 701 slides upwards to drive the pull rope 703 to move, the pull rope 703 moves to drive the pulley 702 to rotate forwards in the piston cylinder 203, so that the connecting rod 705 slides on the second guide rod 704, the connecting rod 705 drives the pointer 706 to move, so that people can observe the residual quantity of the lubricating oil in the storage cylinder 201 through the scale plate 707, after the lubricating oil is drawn out of the storage cylinder 201, the second piston 701 slides downwards in the storage cylinder 201, the second piston 701 slides downwards to drive the pull rope 703 to move, the pull rope 703 moves to rotate backwards so that the pulley 702 rotates backwards, the connecting rod 705 moves to drive the pointer 706 to move, so that people can observe the residual quantity of the lubricating oil in the storage cylinder 201 through the scale plate 707 conveniently, so as to achieve the purpose of conveniently observing the residual quantity of the lubricating oil by a user and being convenient to use, when the mask is used again, the operation is repeated.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by the present specification, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.