CN116766330A - Device for disassembling automobile windshield glass - Google Patents

Abstract

The application relates to a device for removing a vehicle windscreen, comprising: the main machine and the auxiliary machine are respectively arranged on the outer surface and the inner surface of the glass, and each of the main machine and the auxiliary machine comprises a shell, and a limiting assembly, a moving assembly and a cutting assembly are arranged on the shell; when the device works, a glass clamping space is formed between the two limiting assemblies, a steel wire is connected between the two cutting assemblies and used for controlling the steel wire to reciprocate, and the moving assembly is used for driving the shell to move. According to the glass glue cutting device, the limiting assembly is used for limiting, when the main machine and the auxiliary machine are temporarily limited at one position of glass, the cutting assembly controls the steel wire to reciprocate, so that the glass glue is cut electrically, and the working efficiency is improved; after the glass is cut, the shell is driven to move through the moving assembly, so that the cutting assembly is driven to cut glass cement at different positions of the glass, the front windshield glass can be disassembled by single operator, the labor cost is reduced, and the windshield glass with any shape can be cut.

Description

Device for disassembling automobile windshield glass

Technical Field

The application relates to the field of automobiles, in particular to a device for disassembling automobile windshields.

Background

In the disassembly of the automobile windshield, the rubber ring around the automobile windshield needs to be cut off to remove the automobile windshield. In order to avoid damage to the automobile frame, steel wires are usually used to cut the rubber ring of the automobile windshield before, the steel wires pass through the rubber ring of the automobile windshield from outside to inside, the first ends of the steel wires are positioned on the inner side of the automobile windshield, the second ends of the steel wires are positioned on the outer side of the automobile windshield, two workers, one worker and the other worker are positioned outside the automobile, pull the first ends and the second ends of the steel wires to pull the steel wires back respectively, and the positions are moved continuously until the rubber ring of the automobile windshield is completely cut off, and the automobile windshield is taken down. In order to solve the problem that a plurality of people are needed for the disassembly of the automobile windshield, an automobile windshield disassembly device for achieving the single disassembly of the automobile windshield is designed at present, but when a cutting line cuts a rubber ring, the position of the device cannot move, the cutting line can have the problem of being far away from the device, the cutting process is not stable enough, and the risk of cutting paint and interior decoration parts exists.

Disclosure of Invention

The embodiment of the application provides a device for disassembling an automobile windshield glass, which aims to solve the problems that in the related art, a device cannot move, a cutting line is far away from the device, the cutting process is not stable enough, and the risk of cutting paint and interior parts exists.

In order to achieve the above purpose, the present application provides the following technical solutions: an apparatus for removing an automotive windshield, comprising: the main machine and the auxiliary machine are respectively arranged on the outer surface and the inner surface of the glass, and each of the main machine and the auxiliary machine comprises a shell, and a limiting assembly, a moving assembly and a cutting assembly are arranged on the shell; when the device works, a glass clamping space is formed between the two limiting assemblies, a steel wire is connected between the two cutting assemblies and used for controlling the steel wire to reciprocate, and the moving assembly is used for driving the shell to move.

In some embodiments, the apparatus further comprises: the guide assembly is arranged on the shell, one end of the guide assembly extends to the outside of the shell, the two guide assemblies are positioned between the two cutting assemblies, and the guide assemblies are connected with the steel wire in a sliding mode.

In some embodiments, the guide assembly comprises: the traction telescopic piece is connected with the shell at one end, extends towards the outside of the shell at the other end, and is adjustable in distance from the other end of the traction telescopic piece to the outer surface of the shell; the guide plate is connected with the traction telescopic piece, and one side of the guide plate is connected with the steel wire in a sliding manner.

In some embodiments, the end of the guide plate remote from the traction telescoping is bent.

In some embodiments, the moving assembly includes a roller coupled to one side of the housing, the roller surface being a glass coupling surface.

In some embodiments, the roller axis direction is the same as the direction in which the guide assembly length extends.

In some embodiments, the roller comprises a fixed wheel and a steering wheel; the mobile assembly further includes: the steering motor and the steering movement mechanism are arranged in the shell; one end of the steering movement mechanism is connected with the steering motor, and the other end of the steering movement mechanism is connected with the steering wheel.

In some embodiments, the apparatus further comprises a control switch electrically connected to the steering motor.

In some embodiments, the cutting assembly on the host machine comprises a motion motor, the motion motor is arranged on a shell on the host machine, and the motion motor is connected with one end of the steel wire; the cutting assembly on the auxiliary machine comprises a slewing mechanism, the slewing mechanism is arranged on a shell on the auxiliary machine and is connected with the other end of the steel wire, and the slewing mechanism is used for tightening the steel wire in a rotating mode.

In some embodiments, the limiting component includes a magnet, the magnet is disposed on the housing, and the magnet on the main unit and the magnet on the auxiliary unit are symmetrical with respect to the glass, so that a glass clamping space is formed between the two magnets.

The technical scheme provided by the application has the beneficial effects that:

the embodiment of the application provides a device for disassembling automobile windshield glass, wherein a main machine and an auxiliary machine are temporarily limited at one position of glass through limiting of a limiting component, a cutting component controls a steel wire to reciprocate, so that electric glass cement cutting can be realized, and the working efficiency is improved; after the glass is cut, the shell can be driven to move through the moving assembly, so that the cutting assembly is driven to cut glass cement at different positions of the glass, the front windshield glass can be disassembled by single operator, the labor cost is reduced, and the windshield glass with any shape can be cut.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings required for the description of the embodiments will be briefly described below, and it is apparent that the drawings in the following description are only some embodiments of the present application, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic cross-sectional front view of an overall structure provided by an embodiment of the present application;

FIG. 2 is a schematic bottom view of an overall structure according to an embodiment of the present application;

FIG. 3 is a schematic top view of an overall structure according to an embodiment of the present application;

FIG. 4 is a schematic diagram of the working state of the overall structure according to the embodiment of the present application;

FIG. 5 is a schematic diagram of the working state of the overall structure according to the embodiment of the present application;

fig. 6 is a schematic diagram of an overall structure working state according to an embodiment of the present application.

In the figure: 1. a host; 2. an auxiliary machine; 3. a limit component; 30. a magnet; 300. a center magnet; 301. a peripheral magnet; 4. a moving assembly; 40. a roller; 400. a fixed wheel; 401. a steering wheel; 41. a steering motor; 5. a cutting assembly; 50. a motion motor; 51. a slewing mechanism; 6. a guide assembly; 60. traction telescoping pieces; 61. a guide plate; 7. a housing; 8. a control switch; 9. an operation handle; 10. a steel wire; 11. glass cement; 12. and (5) vehicle body sheet metal.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present application more apparent, the technical solutions of the embodiments of the present application will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present application, and it is apparent that the described embodiments are some embodiments of the present application, but not all embodiments of the present application. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

Referring to fig. 1 to 6, the embodiment of the application provides a device for disassembling a windshield of an automobile, which can solve the problems that the device cannot move, the cutting line can be far away from the device, the cutting process is unstable, and the risk of cutting paint and interior parts exists.

In the disassembly of the automobile windshield, the rubber ring around the automobile windshield needs to be cut off to remove the automobile windshield. In order to avoid damage to the automobile frame, the steel wire 10 is used for cutting the rubber ring of the automobile windshield, the steel wire 10 passes through the rubber ring of the automobile windshield from outside to inside, the first end of the steel wire 10 is positioned on the inner side of the automobile windshield, the second end of the steel wire 10 is positioned on the outer side of the automobile windshield, two workers, one worker and the other worker are positioned outside the automobile, pull the first end and the second end of the steel wire 10 to pull the steel wire 10 back respectively, and the steel wire is continuously moved until the rubber ring of the automobile windshield is completely cut off, and the automobile windshield is taken down.

In order to solve the problem that a plurality of people are needed to be matched when the automobile windshield is dismounted, an automobile windshield dismounting device for realizing single person dismounting of the automobile windshield is designed in the prior art, but when a cutting line cuts a rubber ring, the device position cannot move, the cutting line can have the problem of being far away from the device, the cutting process is not stable enough, and the risk of cutting paint and interior decoration parts exists.

The cutting device aims at solving the problems that in the prior art, the position of the cutting device cannot be moved, the cutting line is far away from the device, the cutting process is not stable enough, and the risks of cutting paint and interior parts exist. The embodiment of the application provides a device for disassembling an automobile windshield, which comprises the following components: the glass cutting device comprises a main machine 1 and an auxiliary machine 2, wherein the main machine 1 and the auxiliary machine 2 are respectively arranged on the outer surface and the inner surface of glass, the main machine 1 and the auxiliary machine 2 comprise a shell 7, and a limiting component 3, a moving component 4 and a cutting component 5 are arranged on the shell 7; when the device works, a glass clamping space is formed between the two limiting assemblies 3, a steel wire 10 is connected between the two cutting assemblies 5 and used for controlling the steel wire 10 to reciprocate, and the moving assembly 4 is used for driving the shell 7 to move.

In the application, when the main machine 1 and the auxiliary machine 2 are temporarily limited at one position of glass by the limiting component 3, the cutting component 5 controls the steel wire 10 to reciprocate, so that the glass cement 11 can be cut electrically, and the working efficiency is improved; after the glass is cut, the shell 7 can be driven to move through the moving assembly 4, so that the cutting assembly 5 is driven to cut glass cement 11 at different positions of the glass, the front windshield glass can be disassembled by single operator, the labor cost is reduced, and the windshield glass with any shape can be cut.

In the application, the main machine 1 and the auxiliary machine 2 synchronously move, and the movement tracks are the same.

When the device is used, the main machine 1 and the auxiliary machine 2 are respectively arranged outside the vehicle body and inside the vehicle body, and the specific arrangement of the main machine 1 and the auxiliary machine 2 is not limited in actual operation. Meanwhile, in order to facilitate the installation and the movement of the main machine 1 and the auxiliary machine 2, an operation handle 9 is fixedly connected on the shell 7 of the main machine 1 and the shell 7 of the auxiliary machine 2; the operating handle 9 can be mounted on the shell 7 through a connecting piece such as a bolt, and can be integrally injection molded with the shell 7; the operation handle 9 on the main machine 1 can be operated to move the main machine 1 on the glass surface, and at the moment, the auxiliary machine 2 and the main machine 1 move simultaneously, and the movement track is the same.

In order to realize the synchronous movement of the main machine 1 and the auxiliary machine 2, the movement track is the same:

the limiting assembly 3 comprises a magnet 30, the magnet 30 is arranged on the shell 7, and the magnet 30 on the main machine 1 and the magnet 30 on the auxiliary machine 2 are symmetrically arranged relative to glass, so that a glass clamping space is formed between the two magnets 30. In the present embodiment, the magnet 30 on the main unit 1 and the magnet 30 on the auxiliary unit 2 attract each other, so that the main unit 1 and the auxiliary unit 2 can clamp glass and maintain relative positions; the magnet 30 on the main machine 1 can also provide traction force, when the operating handle 9 on the main machine 1 is operated to move the main machine 1, the magnet 30 on the main machine 1 pulls the magnet 30 on the auxiliary machine 2 to move through the traction force, so that the auxiliary machine 2 is driven to move along with the main machine 1 at the same time, and the same movement track is kept.

The magnets 30 include a center magnet 300 and a peripheral magnet 301, the center magnet 300 on the main unit 1 is mounted at the center of the bottom of the housing 7 of the main unit 1, the center magnet 300 on the auxiliary unit 2 corresponds to the center magnet 300 on the main unit 1 in position, and is symmetrically mounted at the center of the bottom of the housing 7 of the auxiliary unit 2 with respect to glass. The peripheral magnet 301 on the main machine 1 is arranged around the bottom of the shell 7 of the main machine 1, the peripheral magnet 301 on the auxiliary machine 2 is arranged around the bottom of the shell 7 of the auxiliary machine 2, and the peripheral magnet 301 on the main machine 1 is symmetrical relative to glass.

When the operating handle 9 is manipulated to move the main unit 1 and the auxiliary unit 2, the moving assembly 4 comprises a roller 40, the roller 40 is connected to one side of the housing 7, and the surface of the roller 40 is a glass connecting surface in order to make the movement of the main unit 1 and the auxiliary unit 2 more labor-saving. Specifically, the roller 40 on the main unit 1 is used to move the main unit 1 on the outer surface of the glass, and the roller 40 on the sub-unit 2 is used to move the sub-unit 2 on the inner surface of the glass. Because the cutting assembly 5 produces pulling force when controlling the steel wire 10 to reciprocate, the main machine 1 and the auxiliary machine 2 move on the glass, and in order to avoid the situation, the axial direction of the roller 40 is the same as the length extending direction of the guiding assembly 6: the glass is pressed by the attractive force of the magnets 30 on the main machine 1 and the auxiliary machine 2, the friction force generated by the tires of the roller 40 and the glass provides the friction force forming 90 degrees with the movement direction of the roller 40, the counterforce in the process of reciprocating the steel wire 10 is formed, the pulling force in the process of reciprocating the steel wire 10 is overcome, and the main machine 1 and the auxiliary machine 2 are kept at relative positions.

Further, the roller 40 includes a fixed wheel 400 and a steering wheel 401; at least two fixed wheels 400 are arranged on the main machine 1, at least two fixed wheels 400 are also arranged on the auxiliary machine 2, the number of the fixed wheels is the same as that of the fixed wheels 400 on the main machine 1, and the setting positions are corresponding. Since the fixed sheave 400 on the main unit 1 and the fixed sheave 400 on the sub-unit 2 are symmetrically disposed with respect to the glass, the fixed sheave 400 on the main unit 1 is taken as an example here: the fixed wheels 400 are mounted on the housing 7 and are coaxially arranged, the axial direction of the fixed wheels 400 is the same as the length extension direction of the guide assembly 6, the fixed wheels 400 are used for moving on the surface of glass, and the counter force generated in the reciprocating process of the steel wire 10 is overcome through the friction force generated by the tires and the glass, so that the main machine 1 and the auxiliary machine 2 are kept at opposite positions.

The steering wheel 401 is provided for steering the main machine 1 and the sub-machine 2 on the glass surface, and the moving assembly 4 is provided further comprising: a steering motor 41 and a steering movement mechanism, the steering motor 41 being mounted inside the housing 7; one end of the steering movement mechanism is connected to the steering motor 41, and the other end is connected to the steering wheel 401. The steering wheel 401 on the auxiliary machine 2 is symmetrical to the steering wheel 401 on the main machine 1 relative to the glass, and the steering wheel 401 on the auxiliary machine 2 acts the same as the steering wheel 401 on the main machine 1, so only the main machine 1 is taken as an example for explanation, and the steering wheel 401, the steering motor 41 and the steering movement mechanism on the auxiliary machine 2 are not described in detail.

Specific: the turning wheels 401 are installed on the symmetrical parts of the shell 7 of the host machine 1 and the fixed wheels 400, and are used for turning the host machine 1 on the glass surface, and the number of the turning wheels 401 is the same as that of the fixed wheels 400. When the host machine 1 needs to be kept stationary, the axial direction of the steering wheel 401 is the same as the length extending direction of the guide assembly 6, and a friction force which is 90 degrees with the movement direction of the steering wheel 401 is provided; when the host 1 needs to move, the steering motor 41 works to drive the steering movement mechanism and the steering wheel 401 to rotate, so that the movement direction of the steering wheel 401 is the same as the movement direction of the host 1 to be moved.

Further, the device also comprises a control switch 8, wherein the control switch 8 is electrically connected with the steering motor 41, namely, the steering motor 41 on the main machine 1 and the steering motor 41 on the auxiliary machine 2. Specifically, for convenient control, the control switch 8 is installed on the surface of the operating handle 9 on the casing 7 of the main machine 1, and the steering motor 41 is controlled by the control switch 8 to drive the steering wheel 401 to steer, so that the symmetrical steering of the steering wheels 401 of the main machine 1 and the auxiliary machine 2 is ensured.

On the basis of the above embodiment, in this embodiment, the cutting assembly 5 on the main machine 1 includes the movement motor 50, the movement motor 50 is installed on the body 7 on the main machine 1, the movement motor 50 is connected with one end of the steel wire 10; the cutting assembly 5 on the auxiliary machine 2 comprises a slewing mechanism 51, the slewing mechanism 51 is arranged on the shell 7 on the auxiliary machine 2, the slewing mechanism 51 is connected with the other end of the steel wire 10, and the slewing mechanism 51 is used for rotationally tightening the steel wire 10; alternatively, the cutting assembly 5 on the main machine 1 includes a swing mechanism 51, and the cutting assembly 5 on the sub-machine 2 includes a movement motor 50. Here, the case where the movement motor 50 is mounted on the housing 7 of the main unit 1 and the swing mechanism 51 is mounted on the housing 7 of the sub-unit 2 will be described as an example.

In this embodiment, the movement motor 50 is used for controlling the wire 10 to reciprocate, so as to cut glass, and is mounted and fixed on the inner edge of the housing 7 of the main machine 1, so as to facilitate the movement of the wire 10. The slewing mechanism 51 is installed at the inner edge of the shell 7 of the auxiliary machine 2 and is symmetrical to the motion motor 50 on the main machine 1 relative to the glass surface. By the swivel mechanism 51 capable of realizing the rotation and tightening of the steel wire 10, the steel wire 10 which moves reciprocally can be tightened, and the reciprocal pulling force is provided, thereby realizing the cutting of glass.

Since the steel wire 10 will contact with environmental elements such as interior trim parts during the reciprocating motion, in order to avoid damaging the environmental elements by the steel wire 10, in the above embodiment, the device further includes: the guiding component 6, the guiding component 6 sets up on casing 7, and guiding component 6 one end extends to casing 7 outside, and two guiding components 6 are located between two cutting components 5, and here two cutting components 5 refer to cutting component 5 on the host computer 1 and cutting component 5 on the auxiliary engine 2, and guiding component 6 and steel wire 10 sliding connection. The guide assembly 6 is arranged between the steel wires 10 and the glass, guides the steel wires 10 to move around the edge of the glass, and provides protection for the glass from damage of the glass and environmental elements by the steel wires 10.

Specifically, the guide assembly 6 includes: the traction telescopic piece 60 and the guide plate 61, one end of the traction telescopic piece 60 is connected with the shell 7, the other end extends to the outside of the shell 7, and the interval between the other end of the traction telescopic piece 60 and the outer surface of the shell 7 is adjustable; the guide plate 61 is connected with the traction telescoping member 60, the traction telescoping member 60 provides support for the guide plate 61, and one side of the guide plate 61 is in sliding connection with the steel wire 10.

In this embodiment, the traction telescoping member 60 is connected with the housing 7, and the distance between the two ends of the traction telescoping member 60 is adjustable, so that one end of the traction telescoping member 60 away from the housing 7 can be close to or away from the housing 7. Since the wire 10 reciprocates on the guide plate 61, the guide plate 61 is made of a wear-resistant material such as: the guide plate 61 is a metal plate, a groove is formed in the end, far away from one end of the shell 7, of the guide plate 61, the steel wire 10 is located at the groove, the steel wire 10 can be directly contacted with glass to cut the glass, and the side wall of the groove can limit the steel wire 10. Further, the end of the guide plate 61 far away from the traction telescoping member 60 is bent, specifically, the end of the guide plate 61 on the main machine 1 is bent by 90 ° towards the side close to the auxiliary machine 2, through the arrangement of the structure, the end of the guide plate 61 can be buckled on the edge of glass for guiding the steel wire 10 to move around the edge of the glass and protecting the glass from being damaged by the steel wire 10. The guide plate 61 is the guide plate 61 on the main machine 1, and the guide plate 61 on the auxiliary machine 2 can have the same structure as the guide plate 61 on the main machine 1, but the end of the guide plate 61 is bent by 90 degrees towards the side close to the main machine 1; as shown in fig. 1, the structure of the auxiliary machine 2 may be different from that of the guide plate 61 of the main machine 1, and the guide plate 61 may be directly connected to the casing 7 of the auxiliary machine 2 without providing the traction expansion and contraction member 60. However, the functions of the guide plate 61 on the main unit 1 and the guide plate 61 on the sub-unit 2 are different from each other: the guide plate 61 on the host 1 is connected with the steel wire 10 at one side far away from the glass, and is used for guiding the steel wire 10 to move around the edge of the glass and protecting the glass from being damaged by the steel wire 10; the guide plate 61 on the auxiliary machine 2 is connected with the steel wire 10 near one side of the glass, and is used for guiding the steel wire 10 to move close to the inner surface of the glass, stabilizing the movement track of the steel wire 10, avoiding the contact between the steel wire 10 and environmental parts such as interior trim parts and avoiding damaging the environmental parts.

Thus, the wire 10 is used to cut the glass cement 11. One end of the steel wire 10 is connected with the motion motor 50, bypasses the guide plate 61 on the main machine 1 through the traction telescopic piece 60, and is ensured to be connected with the rotary mechanism 51 on the auxiliary machine 2 after being in clearance with glass through the guide plate 61 on the auxiliary machine 2.

The device is used when: firstly, symmetrically placing a main machine 1 and an auxiliary machine 2 relative to glass, enabling a traction telescopic piece 60 on the main machine 1 to be consistent with a guide plate 61 on the auxiliary machine 2 in direction, enabling the main machine 1 and the auxiliary machine 2 to be adsorbed and fixed on the glass through a magnet 30, and enabling the guide plate 61 of the main machine 1 to be tightly attached to the edge of the glass; then, an electric drill or other mechanisms are used for perforating the cross section of the glass cement 11, the steel wire 10 passes through the holes, one end of the steel wire 10 is fixed on the moving motor 50 on the main machine 1, bypasses the guide plate 61 of the main machine 1, passes through the guide plate 61 of the auxiliary machine 2, and the other end is fixed on the rotary mechanism 51 of the auxiliary machine 2; then, the motor 50 is started by operating the motor 50 switch. By holding the host 1 on the operating handle 9, the host 1 is pushed along the glass edge. The motion motor 50 is matched with the rotation mechanism 51 to realize the reciprocating motion of the steel wire 10 and cut the glass cement 11; when the glass is moved to the corner, the steering wheel 401 is correspondingly steered by operating the control switch 8, so that the direction of the host machine 1 is adjusted, the cutting at different positions of the glass is realized, and finally, all the glass cement 11 is cut, and the glass is disassembled.

In sum, through the device, the front windshield glass can be disassembled by a single operator, and the labor cost is reduced; the electric cutting can be realized, and the working efficiency is improved; the steel wire 10 can be effectively prevented from damaging the vehicle body interior trim parts and the vehicle body sheet metal 12 paint during cutting; any shape of the windshield may be cut.

In the description of the present application, it should be noted that the azimuth or positional relationship indicated by the terms "upper", "lower", etc. are based on the azimuth or positional relationship shown in the drawings, and are merely for convenience of describing the present application and simplifying the description, and are not indicative or implying that the apparatus or element in question must have a specific azimuth, be constructed and operated in a specific azimuth, and thus should not be construed as limiting the present application. Unless specifically stated or limited otherwise, the terms "mounted," "connected," and "coupled" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art according to the specific circumstances.

It should be noted that in the present application, relational terms such as "first" and "second" and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

The foregoing is only a specific embodiment of the application to enable those skilled in the art to understand or practice the application. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the application. Thus, the present application is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. A device for removing a vehicle windshield, comprising:

the glass cutting device comprises a main machine (1) and an auxiliary machine (2), wherein the main machine (1) and the auxiliary machine (2) are respectively arranged on the outer surface and the inner surface of glass, the main machine (1) and the auxiliary machine (2) both comprise a shell (7), and a limiting assembly (3), a moving assembly (4) and a cutting assembly (5) are arranged on the shell (7);

when the device works, a glass clamping space is formed between the two limiting assemblies (3), a steel wire (10) is connected between the two cutting assemblies (5), the steel wire (10) is controlled to reciprocate, and the moving assembly (4) is used for driving the shell (7) to move.

2. An apparatus for removing a windshield of an automobile as recited in claim 1, further comprising:

the guide assembly (6), guide assembly (6) sets up on casing (7), guide assembly (6) one end extends to casing (7) outside, and two guide assembly (6) are located two between cutting assembly (5), guide assembly (6) and steel wire (10) sliding connection.

3. A device for removing a vehicle windscreen according to claim 2, wherein said guiding assembly (6) comprises:

the traction telescopic piece (60), one end of the traction telescopic piece (60) is connected with the shell (7), the other end of the traction telescopic piece extends to the outside of the shell (7), and the interval between the other end of the traction telescopic piece (60) and the outer surface of the shell (7) is adjustable;

the guide plate (61), the guide plate (61) is connected with the traction expansion piece (60), and one side of the guide plate (61) is connected with the steel wire (10) in a sliding mode.

4. A device for removing a vehicle windscreen as set forth in claim 3 wherein: one end of the guide plate (61) far away from the traction telescopic piece (60) is bent.

5. A device for removing a vehicle windscreen as set forth in claim 2 wherein: the moving assembly (4) comprises a roller (40), the roller (40) is connected to one side of the shell (7), and the surface of the roller (40) is a glass connecting surface.

6. An apparatus for removing a windshield of an automobile as defined in claim 5, wherein: the axial direction of the roller (40) is the same as the length extension direction of the guide component (6).

7. An apparatus for removing a windshield of an automobile as defined in claim 5, wherein: the roller (40) comprises a fixed wheel (400) and a steering wheel (401);

the mobile assembly (4) further comprises:

a steering motor (41), the steering motor (41) being mounted inside the housing (7);

and one end of the steering movement mechanism is connected with the steering motor (41), and the other end of the steering movement mechanism is connected with the steering wheel (401).

8. A device for removing a vehicle windscreen according to claim 7, further comprising a control switch (8), said control switch (8) being electrically connected to the steering motor (41).

9. A device for removing a vehicle windscreen as set forth in claim 1 wherein: the cutting assembly (5) on the main machine (1) comprises a motion motor (50), wherein the motion motor (50) is arranged on a shell (7) on the main machine (1), and the motion motor (50) is connected with one end of a steel wire (10);

the cutting assembly (5) on the auxiliary machine (2) comprises a slewing mechanism (51), the slewing mechanism (51) is arranged on a shell (7) on the auxiliary machine (2), the slewing mechanism (51) is connected with the other end of the steel wire (10), and the slewing mechanism (51) is used for rotationally tightening the steel wire (10).

10. A device for removing a vehicle windscreen as set forth in claim 1 wherein: the limiting assembly (3) comprises magnets (30), the magnets (30) are arranged on the shell (7), and the magnets (30) on the main machine (1) and the magnets (30) on the auxiliary machine (2) are symmetrical relative to glass, so that a glass clamping space is formed between the two magnets (30).