CN113697595B - Glass fiber yarn winding component device - Google Patents

Abstract

The invention relates to a component device, in particular to a glass fiber yarn winding component device. The invention aims to solve the technical problems: the glass fiber yarn winding component device can automatically cut off glass fiber yarns and ensure the consistent quantity of glass fiber yarn components. The utility model provides a fine yarn winding weight device of glass, includes connecting frame, fixed plate, go-between, drive mechanism and clamping mechanism, and the inside both sides of connecting frame all have the fixed plate through the bolt rigid coupling, all are connected with the go-between on the fixed plate, are equipped with between one side of go-between and being used for driving fine yarn winding drive mechanism of glass, are equipped with the clamping mechanism that is used for pressing from both sides tight fine yarn of glass between fixed plate one side. Through control sliding connection board, just can make the rotation cutting knife cut glass fiber yarn to need not the manual work and hold the scissors and cut glass fiber yarn, and can guarantee that the incision is level and smooth.

Description

Glass fiber yarn winding component device

Technical Field

The invention relates to a component device, in particular to a glass fiber yarn winding component device.

Background

When the glass fiber yarn is produced, the produced glass fiber yarn is directly wound on a large winding drum, when the glass fiber yarn is needed to be used, the glass fiber yarn needs to be subjected to component, and the glass fiber yarn needs to be generally subjected to component, the glass fiber yarn needs to be manually wound on a small winding drum, then the small winding drum is controlled to rotate, the glass fiber yarn is wound on the small winding drum, and when the glass fiber yarn is wound to a certain amount, the glass fiber yarn is disconnected by scissors. This operation requires much labor, and the incisions of the scissors cannot be kept flat, and the amount of glass fiber components cannot be ensured to be uniform.

Therefore, it is needed to develop a glass fiber yarn winding component device capable of automatically cutting glass fiber yarns and ensuring the consistent quantity of the glass fiber yarn components.

Disclosure of Invention

In order to overcome the defects that more manpower is required to be consumed for the glass fiber yarn component, the incision of the scissors cannot be kept flat, and the consistent quantity of the glass fiber component cannot be ensured, the technical problem is that: the glass fiber yarn winding component device can automatically cut off glass fiber yarns and ensure the consistent quantity of glass fiber yarn components.

The technical proposal is as follows: the utility model provides a fine yarn winding weight device of glass, includes connecting frame, fixed plate, go-between, drive mechanism and clamping mechanism, and the inside both sides of connecting frame all have the fixed plate through the bolt rigid coupling, all are connected with the go-between on the fixed plate, are equipped with between one side of go-between and being used for driving fine yarn winding drive mechanism of glass, are equipped with the clamping mechanism that is used for pressing from both sides tight fine yarn of glass between fixed plate one side.

Optionally, the driving mechanism comprises a motor, a rotary driving ring and a transmission assembly, the motor is arranged on the connecting frame, the rotary driving ring is connected to the connecting ring in a rotary mode, a winding cylinder can be placed between the rotary driving rings, and the transmission assembly is connected between the rotary driving ring and output shafts on two sides of the motor respectively.

Optionally, the clamping mechanism comprises a first placing plate, a first sliding sleeve, a sliding clamping plate and a first spring, wherein the first placing plate is connected between the fixed plates, the first sliding sleeves are connected to two sides of the first placing plate, the sliding clamping plate is connected between the first sliding sleeves in a sliding mode, the first spring is connected between the sliding clamping plate and the first sliding sleeve, and the first spring is sleeved on the sliding clamping plate.

Optionally, still including cutting mechanism, cutting mechanism is including head rod, sliding connection board, shear cutter, second spring and second place the board, is connected with the head rod on the first board of placing, and the last sliding connection who is connected with sliding connection board on the head rod is connected with the shear cutter on the sliding connection board, is connected with two second springs between sliding connection board and the head rod, and the board is placed to the first second of placing on being connected with the second.

Optionally, the automatic mechanism further comprises a second connecting rod, a first inclined plane driving plate, a third spring and a second inclined plane driving plate, wherein the second connecting rod is connected to the first connecting rod, the first inclined plane driving plate is connected to the second connecting rod in a sliding mode, the first inclined plane driving plate is connected with the sliding connecting plate, the third spring is connected between the first inclined plane driving plate and the second connecting rod, the second inclined plane driving plate is connected to the sliding clamping plate, and the second inclined plane driving plate is matched with the first inclined plane driving plate.

Optionally, the locking mechanism is further comprised, the locking mechanism comprises a third connecting rod, a rotary clamping rod and a torsion spring, the third connecting rod is connected to the first connecting rod, the rotary clamping rod is rotatably connected to the third connecting rod, the rotary clamping rod is matched with the sliding connecting plate, and the torsion spring is connected between the rotary clamping rod and the third connecting rod.

Optionally, the device further comprises an unlocking mechanism, the unlocking mechanism comprises a second sliding sleeve, a first sliding driving plate, a fourth spring, a fourth connecting rod, a second sliding driving plate and a fifth spring, the second sliding sleeve is connected between the connecting rings, the first sliding driving plate is connected to the second sliding sleeve in a sliding mode, the fourth spring is connected between the first sliding driving plate and the second sliding sleeve, the fourth connecting rod is fixedly connected to the second sliding sleeve through a bolt, the second sliding driving plate is connected to the fourth connecting rod in a sliding mode, the second sliding driving plate is matched with the first sliding driving plate, the second sliding driving plate is matched with the rotary clamping rod, and the fifth spring is connected between the second sliding driving plate and the fourth connecting rod.

Optionally, the motor switch further comprises a closing mechanism, the closing mechanism comprises a fifth connecting rod, a third sliding driving plate and a sixth spring, the second sliding sleeve is fixedly connected with the fifth connecting rod through a bolt, the third sliding driving plate is connected to the fifth connecting rod in a sliding mode and matched with the first sliding driving plate, the third sliding driving plate is matched with the motor switch, and the sixth spring is connected between the third sliding driving plate and the fifth connecting rod.

The beneficial effects of the invention are as follows: 1. through control sliding connection board, just can make the rotation cutting knife cut glass fiber yarn to need not the manual work and hold the scissors and cut glass fiber yarn, and can guarantee that the incision is level and smooth.

2. When the sliding connecting plate is pulled to move towards the front side, the first inclined surface driving plate is matched with the second inclined surface driving plate, so that the sliding clamping plate can move upwards, and the sliding clamping plate does not need to be controlled to move upwards manually; after the glass fiber yarn winding component is finished, the sliding connection plate is not controlled any more, and at the moment, the sliding clamping plate automatically moves downwards to clamp and fix the glass fiber yarn, so that when the rotary cutting knife cuts the glass fiber yarn, the glass fiber yarn can be automatically fixed, and the cutting effect is better.

3. Through slide connection board and rotatory screens pole cooperation, and then make rotatory screens pole can block slide connection board, alright need not the manual work at this moment and control fixed slide connection board always.

4. When the glass fiber yarn is continuously wound, the first sliding driving plate is matched with the second sliding driving plate, and the rotating clamping rod can be automatically driven to rotate anticlockwise, so that the glass fiber yarn can be automatically fixed and cut when the glass fiber yarn is wound to a certain component, the winding component is not required to be manually judged, and the consistency of the quantity of the winding component every time can be guaranteed.

5. When the glass fiber yarn is continuously wound, the motor switch can be automatically pressed downwards through the matching of the first sliding driving plate and the third sliding driving plate, so that the motor automatically stops operating, and when the glass fiber yarn is wound to a certain component, the glass fiber yarn is automatically stopped from being wound.

Drawings

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

Fig. 2 is a schematic view of a partial perspective structure of the present invention.

Fig. 3 is a schematic diagram of a first perspective structure of the driving mechanism of the present invention.

Fig. 4 is a schematic diagram of a second perspective structure of the driving mechanism of the present invention.

Fig. 5 is a schematic diagram of a first three-dimensional structure of the clamping mechanism of the present invention.

Fig. 6 is a schematic diagram of a second perspective structure of the clamping mechanism of the present invention.

Fig. 7 is a schematic view of a first perspective structure of the cutting mechanism of the present invention.

Fig. 8 is a schematic view of a second perspective structure of the cutting mechanism of the present invention.

Fig. 9 is a schematic view of a first perspective of the automatic mechanism of the present invention.

Fig. 10 is a schematic view of a second perspective of the automatic mechanism of the present invention.

Fig. 11 is a schematic view showing a first perspective structure of the locking mechanism of the present invention.

Fig. 12 is a schematic view showing a second perspective structure of the locking mechanism of the present invention.

Fig. 13 is a schematic view of a first perspective structure of an unlocking mechanism according to the present invention.

Fig. 14 is a schematic view of a second perspective structure of the unlocking mechanism of the present invention.

Fig. 15 is a schematic view showing a first perspective structure of the closing mechanism of the present invention.

Fig. 16 is a schematic view showing a second perspective structure of the closing mechanism of the present invention.

Reference numerals illustrate: the device comprises a 1-connecting frame, a 2-fixing plate, a 3-connecting ring, a 4-driving mechanism, a 41-motor, a 42-rotating driving ring, a 43-driving component, a 5-clamping mechanism, a 51-first placing plate, a 52-first sliding sleeve, a 53-sliding clamping plate, a 54-first spring, a 6-cutting mechanism, a 61-first connecting rod, a 62-sliding connecting plate, a 63-rotating cutting knife, a 64-second spring, a 65-second placing plate, a 7-automatic mechanism, a 71-second connecting rod, a 72-first inclined surface driving plate, a 73-third spring, a 74-second inclined surface driving plate, a 8-locking mechanism, a 81-third connecting rod, a 82-rotating clamping rod, a 83-torsion spring, a 9-unlocking mechanism, a 91-second sliding sleeve, a 92-first sliding driving plate, a 93-fourth spring, a 94-fourth connecting rod, a 95-second sliding driving plate, a 96-fifth spring, a 10-closing mechanism, a 101-fifth connecting rod, a 102-third sliding driving plate and a 103-sixth spring.

Detailed Description

The following description is of the preferred embodiments of the invention, and is not intended to limit the scope of the invention.

Example 1

The utility model provides a fine yarn winding component device of glass, as shown in fig. 1-6, including connecting frame 1, fixed plate 2, go-between 3, drive mechanism 4 and clamping mechanism 5, both sides all have fixed plate 2 through the bolt rigid coupling around the inside of connecting frame 1, and the upper portion inboard of fixed plate 2 all is connected with go-between 3 and the left side of connecting frame 1 of go-between is equipped with drive mechanism 4, is equipped with clamping mechanism 5 between the fixed plate 2 right side.

When the glass fiber yarn winding component is required, the glass fiber yarn passes through the clamping mechanism 5 to be wound on the winding drum, then the winding drum is placed on the driving mechanism 4, then the driving mechanism 4 is started, the driving mechanism 4 drives the winding drum to rotate, and then the glass fiber yarn is wound, when the glass fiber yarn is wound to a certain amount, the driving mechanism 4 can be closed, then the clamping mechanism 5 is controlled to clamp the glass fiber yarn, and then people can conveniently cut the glass fiber yarn, the glass fiber yarn with the winding component can be taken out after cutting, and then the operation is repeated.

The driving mechanism 4 comprises a motor 41, a rotary driving ring 42 and a transmission assembly 43, wherein the motor 41 is arranged on the inner side of the left part of the connecting frame 1, the rotary driving ring 42 is rotatably connected on the inner side of the connecting ring 3, a winding cylinder can be placed between the rotary driving rings 42, the transmission assembly 43 is connected between the outer sides of the rotary driving rings 42 and output shafts on two sides of the motor 41 respectively, the transmission assembly 43 consists of two belt pulleys and a flat belt respectively, one belt pulley is arranged on the rotary driving ring 42, the other belt pulley is arranged on the output shaft of the motor 41, and the flat belt is wound between the two belt pulleys.

The clamping mechanism 5 comprises a first placing plate 51, a first sliding sleeve 52, a sliding clamping plate 53 and a first spring 54, wherein the first placing plate 51 is connected between the right sides of the fixed plates 2, the first sliding sleeve 52 is connected to the front side and the rear side of the upper portion of the first placing plate 51, the sliding clamping plate 53 is connected between the first sliding sleeves 52 in a sliding mode, the first spring 54 is connected between the sliding clamping plate 53 and the upper side of the first sliding sleeve 52, and the first spring 54 is sleeved on the sliding clamping plate 53.

When the glass fiber yarn winding component is required, the sliding clamping plate 53 is controlled to move upwards, the first spring 54 is stretched, then the glass fiber yarn passes through the space between the first placing plate 51 and the sliding clamping plate 53, the glass fiber yarn passing through the space can be wound on the winding drum, then the winding drum is placed between the rotating driving rings 42, the motor 41 is started, the motor 41 drives the transmission assembly 43 to operate through the output shaft, then the rotating driving rings 42 are rotated, the winding drum is driven to rotate, the glass fiber yarn is wound, when the glass fiber yarn is wound to a certain amount, the motor 41 is closed, then the sliding clamping plate 53 is not controlled any more, at this time, the first spring 54 is retracted to drive the sliding clamping plate 53 to move downwards, and then the sliding clamping plate 53 clamps the glass fiber yarn, so that people can conveniently cut the glass fiber yarn with the winding component, then the glass fiber yarn can be taken out, and the operation is repeated.

Example 2

On the basis of embodiment 1, as shown in fig. 2, 7, 8, 9, 10, 11, 12, 13, 14, 15 and 16, the utility model further comprises a cutting mechanism 6, the cutting mechanism 6 comprises a first connecting rod 61, a sliding connecting plate 62, a rotary cutting knife 63, a second spring 64 and a second placing plate 65, the middle part of the first placing plate 51 is connected with the first connecting rod 61, the upper part of the first connecting rod 61 is connected with the sliding connecting plate 62 in a sliding manner, the lower side of the sliding connecting plate 62 is connected with the rotary cutting knife 63, a left second spring 64 and a right second spring 64 are connected between the sliding connecting plate 62 and the rear side of the first connecting rod 61, and the upper part of the first placing plate 51 is connected with the second placing plate 65.

When the glass fiber yarn winding component is required, the sliding connection plate 62 can be pulled to move towards the front side, so that the second spring 64 is stretched, when the glass fiber yarn winding component is completed, the sliding connection plate 62 can be not controlled any more, at the moment, the second spring 64 retracts to drive the sliding connection plate 62 to move towards the rear side for resetting, and when the sliding connection plate 62 moves towards the rear side, the rotary cutting knife 63 is driven to move towards the rear side, so that the rotary cutting knife 63 is used for cutting the glass fiber yarn, and therefore the glass fiber yarn is cut without holding scissors manually, and the trouble of manual operation is reduced.

The automatic mechanism 7 comprises a second connecting rod 71, a first inclined plane driving plate 72, a third spring 73 and a second inclined plane driving plate 74, wherein the right side of the upper part of the first connecting rod 61 is connected with the second connecting rod 71, the second connecting rod 71 is connected with the first inclined plane driving plate 72 in a sliding manner, the first inclined plane driving plate 72 is connected with the sliding connecting plate 62, the third spring 73 is connected between the first inclined plane driving plate 72 and the rear side of the second connecting rod 71, the upper side of the front part of the sliding clamping plate 53 is connected with the second inclined plane driving plate 74, and the second inclined plane driving plate 74 is matched with the first inclined plane driving plate 72.

When the sliding connection plate 62 is pulled to move forward, the first inclined plane driving plate 72 is driven to move forward, the third spring 73 is stretched, and when the first inclined plane driving plate 72 moves to be in contact with the second inclined plane driving plate 74, the second inclined plane driving plate 74 is driven to move upward, so that the sliding clamping plate 53 moves upward, and the sliding clamping plate 53 does not need to be controlled to move upward manually; when the glass fiber yarn winding component is completed, the sliding connection plate 62 is not controlled any more, at this time, the sliding connection plate 62 automatically moves to the rear side for resetting, meanwhile, the third spring 73 retracts to drive the first inclined plane driving plate 72 to move to the rear side for resetting, the first inclined plane driving plate 72 moves to the rear side and is separated from the second inclined plane driving plate 74, at this time, the sliding clamping plate 53 automatically moves downwards to clamp and fix the glass fiber yarn, and the second inclined plane driving plate 74 moves downwards for resetting, so that when the rotary cutting knife 63 cuts the glass fiber yarn, the glass fiber yarn can be automatically fixed, and the cutting effect is better.

The locking mechanism 8 comprises a third connecting rod 81, a rotary clamping rod 82 and a torsion spring 83, wherein the third connecting rod 81 is connected to the left side of the front portion of the first connecting rod 61, the rotary clamping rod 82 is rotatably connected to the rear side of the upper portion of the third connecting rod 81, the rotary clamping rod 82 is matched with the sliding connecting plate 62, and the torsion spring 83 is connected between the rotary clamping rod 82 and the third connecting rod 81.

When the sliding connection plate 62 is pulled to move forward, the sliding connection plate 62 is contacted with the rotary clamping rod 82, the rear side of the rotary clamping rod 82 is an inclined plane, so that the rotary clamping rod 82 is driven to rotate anticlockwise, the torsion spring 83 is deformed, when the sliding connection plate 62 moves to be separated from the rotary clamping rod 82, the torsion spring 83 is restored to drive the rotary clamping rod 82 to rotate reversely and reset, and then the rotary clamping rod 82 clamps the sliding connection plate 62, and at the moment, the fixed sliding connection plate 62 is not required to be controlled all the time manually; when the glass fiber yarn winding component is completed, the rotary clamping rod 82 can be controlled to rotate anticlockwise, when the rotary clamping rod 82 rotates to be separated from the sliding connection plate 62, the sliding connection plate 62 can automatically move backwards to reset, at the moment, the glass fiber yarn can be automatically and fixedly cut, then the rotary clamping rod 82 is not controlled any more, and the torsion spring 83 is restored to drive the rotary clamping rod 82 to rotate reversely to reset.

The unlocking mechanism 9 comprises a second sliding sleeve 91, a first sliding driving plate 92, a fourth spring 93, a fourth connecting rod 94, a second sliding driving plate 95 and a fifth spring 96, wherein the second sliding sleeve 91 is connected between the lower parts of the connecting rings 3, the first sliding driving plate 92 is connected in a sliding mode to the middle of the second sliding sleeve 91, the fourth spring 93 is connected between the first sliding driving plate 92 and the second sliding sleeve 91, the fourth connecting rod 94 is fixedly connected to the lower side of the second sliding sleeve 91 through bolts, the second sliding driving plate 95 is connected to the right part of the fourth connecting rod 94 in a sliding mode, the second sliding driving plate 95 is matched with the first sliding driving plate 92, the second sliding driving plate 95 is matched with the rotary clamping rod 82, and the fifth spring 96 is connected between the second sliding driving plate 95 and the fourth connecting rod 94.

When the glass fiber yarn is continuously wound, the first sliding driving plate 92 is continuously pressed to move downwards, the fourth spring 93 is compressed, when the first sliding driving plate 92 moves to be in contact with the second sliding driving plate 95, the second sliding driving plate 95 is driven to move downwards, the fifth spring 96 is compressed, so that the second sliding driving plate 95 is pressed downwards to rotate the left side of the rotary clamping rod 82, and then the rotary clamping rod 82 is driven to rotate anticlockwise, and when the glass fiber yarn is wound to a certain component, the glass fiber yarn is automatically and fixedly cut, so that the winding component is not required to be judged manually, and the consistent quantity of each winding component can be ensured; after the glass fiber yarn winding component is completed, the glass fiber yarn with the winding component is taken out, at the moment, the fourth spring 93 rebounds to drive the first sliding driving plate 92 to move upwards for resetting, the fifth spring 96 rebounds to drive the second sliding driving plate 95 to move upwards for resetting, and the rotating clamping rod 82 can rotate reversely for resetting automatically.

The closing mechanism 10 comprises a fifth connecting rod 101, a third sliding driving plate 102 and a sixth spring 103, wherein the fifth connecting rod 101 is fixedly connected to the lower side of the second sliding sleeve 91 through bolts, the third sliding driving plate 102 is connected to the left side of the fifth connecting rod 101 in a sliding mode, the third sliding driving plate 102 is matched with the first sliding driving plate 92, the third sliding driving plate 102 is matched with the motor 41 in a switching mode, and the sixth spring 103 is connected between the third sliding driving plate 102 and the fifth connecting rod 101.

When the glass fiber yarn is continuously wound, the first sliding driving plate 92 is continuously pressed to move downwards, the fourth spring 93 is compressed, when the first sliding driving plate 92 moves to be in contact with the third sliding driving plate 102, the third sliding driving plate 102 is driven to move downwards, the sixth spring 103 is compressed, so that the third sliding driving plate 102 downwards presses the motor 41 to switch, at the moment, the motor 41 automatically stops operating, and when the glass fiber yarn is wound to a certain component, the glass fiber yarn winding is automatically stopped; after the glass fiber yarn with the winding component is taken out, the fourth spring 93 rebounds to drive the first sliding driving plate 92 to move upwards for resetting, the sixth spring 103 rebounds to drive the third sliding driving plate 102 to move upwards for resetting, at the moment, the third sliding driving plate 102 is separated from the switch of the motor 41, and when the motor 41 needs to be started again, the switch of the motor 41 is manually pressed again.

Although embodiments of the present invention have been shown and described, it would be appreciated by those skilled in the art that changes may be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the claims and their equivalents.

Claims (1)

1. The glass fiber yarn winding component device is characterized by comprising a connecting frame (1), a fixed plate (2), connecting rings (3), a driving mechanism (4) and a clamping mechanism (5), wherein the two sides of the inside of the connecting frame (1) are fixedly connected with the fixed plate (2) through bolts, the connecting rings (3) are connected to the fixed plate (2), the driving mechanism (4) for driving the glass fiber yarn to wind is arranged between the connecting rings (3) and one side of the connecting frame (1), and the clamping mechanism (5) for clamping the glass fiber yarn is arranged between one side of the fixed plate (2);

the driving mechanism (4) comprises a motor (41), a rotary driving ring (42) and a transmission assembly (43), the motor (41) is arranged on the connecting frame (1), the rotary driving ring (42) is rotationally connected on the connecting ring (3), a winding cylinder can be placed between the rotary driving rings (42), and the transmission assembly (43) is respectively connected between the rotary driving rings (42) and output shafts on two sides of the motor (41);

the clamping mechanism (5) comprises a first placing plate (51), a first sliding sleeve (52), a sliding clamping plate (53) and a first spring (54), wherein the first placing plate (51) is connected between the fixed plates (2), the first sliding sleeve (52) is connected to two sides of the first placing plate (51), the sliding clamping plate (53) is connected between the first sliding sleeves (52) in a sliding mode, the first spring (54) is connected between the sliding clamping plate (53) and the first sliding sleeve (52), and the first springs (54) are sleeved on the sliding clamping plate (53);

the cutting mechanism (6) comprises a first connecting rod (61), a sliding connecting plate (62), a rotary cutting knife (63), a second spring (64) and a second placing plate (65), wherein the first connecting rod (61) is connected to the first placing plate (51), the sliding connecting plate (62) is connected to the first connecting rod (61), the rotary cutting knife (63) is connected to the sliding connecting plate (62), two second springs (64) are connected between the sliding connecting plate (62) and the first connecting rod (61), and the second placing plate (65) is connected to the first placing plate (51);

the automatic mechanism (7) comprises a second connecting rod (71), a first inclined plane driving plate (72), a third spring (73) and a second inclined plane driving plate (74), wherein the second connecting rod (71) is connected to the first connecting rod (61), the first inclined plane driving plate (72) is connected to the second connecting rod (71) in a sliding mode, the first inclined plane driving plate (72) is connected with the sliding connecting plate (62), the third spring (73) is connected between the first inclined plane driving plate (72) and the second connecting rod (71), the second inclined plane driving plate (74) is connected to the sliding clamping plate (53), and the second inclined plane driving plate (74) is matched with the first inclined plane driving plate (72);

the locking mechanism (8) comprises a third connecting rod (81), a rotary clamping rod (82) and a torsion spring (83), the third connecting rod (81) is connected to the first connecting rod (61), the rotary clamping rod (82) is rotatably connected to the third connecting rod (81), the rotary clamping rod (82) is matched with the sliding connecting plate (62), and the torsion spring (83) is connected between the rotary clamping rod (82) and the third connecting rod (81);

the novel anti-theft lock is characterized by further comprising an unlocking mechanism (9), wherein the unlocking mechanism (9) comprises a second sliding sleeve (91), a first sliding driving plate (92), a fourth spring (93), a fourth connecting rod (94), a second sliding driving plate (95) and a fifth spring (96), the second sliding sleeve (91) is connected between the connecting rings (3), the first sliding driving plate (92) is connected on the second sliding sleeve (91) in a sliding manner, the fourth spring (93) is connected between the first sliding driving plate (92) and the second sliding sleeve (91), the fourth connecting rod (94) is fixedly connected on the second sliding sleeve (91) through bolts, the second sliding driving plate (95) is matched with the first sliding driving plate (92), and the fifth spring (96) is connected between the second sliding driving plate (95) and the fourth connecting rod (94);

the novel sliding type electric motor is characterized by further comprising a closing mechanism (10), wherein the closing mechanism (10) comprises a fifth connecting rod (101), a third sliding driving plate (102) and a sixth spring (103), the fifth connecting rod (101) is fixedly connected to the second sliding sleeve (91) through bolts, the third sliding driving plate (102) is connected to the fifth connecting rod (101) in a sliding mode, the third sliding driving plate (102) is matched with the first sliding driving plate (92), the third sliding driving plate (102) is matched with a motor (41) in a switching mode, and the sixth spring (103) is connected between the third sliding driving plate (102) and the fifth connecting rod (101).