CN116921647A - Automobile engine end cover die casting device - Google Patents

Abstract

The application relates to the technical field of die casting devices, in particular to an automobile engine end cover die casting device, which comprises a bearing component, a die casting machine body, a first mounting plate, a first die, a bearing seat and a motor, wherein the die casting machine body comprises a die clamping device arranged on the die casting machine body, the first mounting plate is arranged on the die clamping device, the first die is arranged on the first mounting plate, the bearing seat is arranged on one side of the die casting machine body, and the motor is arranged on the bearing seat; the replacing component comprises a storage component arranged on the motor, a guide component arranged on one side of the rotating component, a clamping component arranged on the guide component, the rotating component arranged on the clamping component, a locking component arranged on the clamping component and a switching component arranged on the locking component; the anti-drop assembly comprises a limiting assembly arranged on the storage assembly, the limiting assembly can automatically and rapidly replace a die, and the die is not easy to damage in the replacement process.

Description

Automobile engine end cover die casting device

Technical Field

The application relates to the technical field of die casting devices, in particular to a die casting device for an automobile engine end cover.

Background

When the engine end cover is produced, the production is generally carried out in a die casting mode, a common die casting device is a die casting machine, the die casting machine is divided into a horizontal die casting machine and a vertical die casting machine, the common horizontal die casting machine consists of a left die and a right die, and when the engine end cover is used, the two dies are matched, then molten metal is injected into the dies, and then the dies are cooled to form the engine end cover.

In the use, because the car engine end cover of different brands is different, thereby just also need to use different moulds, when carrying out the change of mould, common mode is that the workman uses the crane to hoist old mould and puts the place of storage, then send the die casting machine with the crane with new mould on, the rethread clamp mould ware carries out the fixed of mould, this kind of mode is because the required time of needs workman operation crane to slowly remove the mould, thereby the mould change efficiency is influenced, and the in-process of lifting is easy because rocking causes the mould to drop from the lifting rope, cause the damage of mould, though also have the manipulator to change the mould, the manipulator generally cost is expensive, be unfavorable for small-size enterprise's competition.

Disclosure of Invention

This section is intended to outline some aspects of embodiments of the application and to briefly introduce some preferred embodiments. Some simplifications or omissions may be made in this section as well as in the description of the application and in the title of the application, which may not be used to limit the scope of the application.

In view of the above or the problems that in the prior art, when the die of the die casting machine is replaced, a worker needs to operate the crane to slowly move the die, the time required for the operation is long, the die replacement efficiency is affected, and in the lifting process, the die is easy to drop from the lifting rope due to shaking, so that the die is damaged, the application is provided.

It is therefore an object of the present application to provide an automotive engine end cap die casting apparatus.

In order to solve the technical problems, the application provides the following technical scheme: the die casting machine comprises a bearing component, a first die, a bearing seat and a motor, wherein the bearing component comprises a die casting machine body, a die clamping device arranged on the die casting machine body, a first mounting plate arranged on the die clamping device, a first die arranged on the first mounting plate, the bearing seat arranged on one side of the die casting machine body, and the motor arranged on the bearing seat; the replacing component comprises a storage component arranged on the motor, a guide component arranged on one side of the storage component, a clamping component arranged on the guide component, a rotating component arranged on the clamping component, a locking component arranged on the clamping component and a switching component arranged on the locking component; the anti-drop assembly comprises a limiting assembly arranged on the storage assembly, a lifting assembly arranged on the limiting assembly and a transmission assembly arranged on the lifting assembly.

As a preferred embodiment of the die casting device for an engine end cover of an automobile, the die casting device comprises: the storage assembly comprises a disc arranged on the motor, a plurality of storage frames arranged on the disc, a baffle arranged on the storage frames, a second mounting plate arranged on the storage frames and a second die arranged on the second mounting plate; wherein, a plurality of second moulds on the storage rack are all different.

As a preferred embodiment of the die casting device for an engine end cover of an automobile, the die casting device comprises: the guide assembly comprises a support frame arranged on one side of the disc, an electric sliding rail arranged on the support frame, and a sliding block arranged on the electric sliding rail.

As a preferred embodiment of the die casting device for an engine end cover of an automobile, the die casting device comprises: the clamping assembly comprises a limiting groove arranged on the second mounting plate, a transverse plate arranged on the sliding block, a rotating shaft arranged on the transverse plate, a supporting disc arranged on the rotating shaft, a vertical plate arranged on the supporting disc and cutting arranged on the vertical plate.

As a preferred embodiment of the die casting device for an engine end cover of an automobile, the die casting device comprises: the rotating assembly comprises a gear ring arranged on the supporting disc, a fixed plate arranged on the supporting frame and a toothed plate arranged on the fixed plate.

As a preferred embodiment of the die casting device for an engine end cover of an automobile, the die casting device comprises: the locking assembly comprises a limiting frame arranged on the limiting groove, a cavity arranged on the cutting, a through opening arranged on the cavity and a wedge block arranged on the through opening.

As a preferred embodiment of the die casting device for an engine end cover of an automobile, the die casting device comprises: the switching assembly comprises a moving block arranged on the cavity, a transmission rod arranged on the moving block, a sliding groove arranged on the moving block, a guide block arranged on the sliding groove, an L-shaped rod arranged on the guide block, a support plate arranged in the cavity, a first guide groove arranged on the support plate, a second guide groove arranged on the first guide groove, a third guide groove arranged on the second guide groove, a fourth guide groove arranged on the third guide groove and a fifth guide groove arranged on the fourth guide groove; and the joint of the third guide groove and the fourth guide groove forms a concave point, and the slope of the third guide groove is larger than that of the fourth guide groove.

As a preferred embodiment of the die casting device for an engine end cover of an automobile, the die casting device comprises: the limiting assembly comprises an installation cavity arranged in the storage rack, a penetrating opening arranged on the installation cavity, a lifting block arranged on the installation cavity, a top block arranged on the lifting block, a notch arranged on the top block and a first spring arranged on the lifting block.

As a preferred embodiment of the die casting device for an engine end cover of an automobile, the die casting device comprises: the lifting assembly comprises a first U-shaped plate arranged on the lifting block, an extension cavity arranged on the mounting cavity, a push block arranged on the extension cavity, a second U-shaped plate arranged on the push block and a transmission plate arranged on the first U-shaped plate; one end of the transmission plate is rotationally connected with the first U-shaped plate, and the other end of the transmission plate is rotationally connected with the second U-shaped plate.

As a preferred embodiment of the die casting device for an engine end cover of an automobile, the die casting device comprises: the transmission assembly comprises a strip-shaped groove arranged on the storage rack, a long strip plate arranged on the strip-shaped groove, a second spring arranged on the long strip plate, a round opening arranged on the strip-shaped groove, a long rod arranged in the round opening, a first L-shaped plate arranged on the long strip plate and a second L-shaped plate arranged on the transverse plate; wherein, first L shaped plate and second L shaped plate looks adaptation.

The die casting device for the automobile engine end cover has the beneficial effects that: through setting up the change part, can carry out the change of die casting machine body upper die automatically, need not the workman and use the crane to carry out the lifting or put down of mould, and only need electronic slide rail to make the slider move about, can accomplish the change, make the change more quick, and owing to set up the clamping assembly, can avoid the mould to take place to drop, realize the protection of mould, the setting of anticreep part simultaneously, can be spacing the mould on the storage frame, guarantee the stability that the mould was placed, thereby when having solved the change die casting machine mould, need workman's operation crane slowly move the mould, required time is longer, influence mould change efficiency, and the in-process of lifting is easy because rocking causes the mould to drop from lifting rope, cause the problem of the damage of mould, the quick automatic change of mould has been reached, and the not fragile effect of in-process of changing the mould.

Drawings

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

Fig. 1 is an overall schematic diagram of an automotive engine end cap die casting apparatus.

Fig. 2 is a schematic view of the disc bottom structure of the die casting device of the automobile engine end cover.

Fig. 3 is a schematic view showing the structure of a riser and a support plate separated from each other in a die casting device for an end cover of an automobile engine.

Fig. 4 is a schematic view of the exterior structure of a storage assembly of an automotive engine end cap die casting device.

Fig. 5 is a schematic cross-sectional structural view of a second mounting plate of an automotive engine end cover die casting apparatus.

Fig. 6 is a schematic illustration of a first cross-sectional configuration of a cutting insert for an automotive engine end cap die casting apparatus.

Fig. 7 is a schematic diagram of a second cross-sectional configuration of a cutting for an automotive engine end cap die casting device.

Fig. 8 is a schematic view of the structure of the anti-drop component of the die casting device of the end cover of the automobile engine.

Fig. 9 is a schematic cross-sectional view of an anti-drop component of an automotive engine end cap die casting device.

In the figure: 100. a carrier member; 101. a die casting machine body; 102. a die clamping device; 103. a first mounting plate; 104. a first mold; 105. a bearing seat; 106. a motor; 200. replacing the component; 201. a storage component; 201a, a disc; 201b, a storage rack; 201c, a baffle; 201d, a second mounting plate; 201e, a second mold; 202. a guide assembly; 202a, a supporting frame; 202b, an electric sliding rail; 202c, a slider; 203. a clamping assembly; 203a, a limit groove; 203b, a cross plate; 203c, a rotating shaft; 203d, a supporting plate; 203e, risers; 203f, cutting; 204. a rotating assembly; 204a, a gear ring; 204b, a fixed plate; 204c, tooth plates; 205. a locking assembly; 205a, a limit frame; 205b, cavity; 205c, a through opening; 205d, wedge blocks; 206. a switching assembly; 206a, a moving block; 206b, a transmission rod; 206c, a chute; 206d, guide blocks; 206e, L-shaped bar; 206f, a first guide groove; 206g, a second guide groove; 206h, a third guide groove; 206i, fourth guide grooves; 206j, fifth guide grooves; 300. an anti-falling component; 301. a limit component; 301a, a mounting cavity; 301b, a through-hole; 301c, lifting blocks; 301d, a top block; 301e, notch; 301f, a first spring; 302. a lifting assembly; 302a, a first U-shaped plate; 302b, an elongated cavity; 302c, pushing blocks; 302d, a second U-shaped plate; 302e, a drive plate; 303. a transmission assembly; 303a, a bar-shaped groove; 303b, a long slat; 303c, a second spring; 303d, a circular port; 303e, a long rod; 303f, a first L-shaped plate; 303g, a second L-shaped plate.

Detailed Description

In order that the above-recited objects, features and advantages of the present application will become more readily apparent, a more particular description of the application will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present application, but the present application may be practiced in other ways other than those described herein, and persons skilled in the art will readily appreciate that the present application is not limited to the specific embodiments disclosed below.

Further, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic can be included in at least one implementation of the application. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

Example 1

Referring to fig. 1 to 7, in a first embodiment of the present application, an automobile engine end cover die casting device is provided, which can realize the effect of automatically replacing a die of a die casting machine, and includes a carrier 100, including a die casting machine body 101, a die clamper 102 disposed on the die casting machine body 101, a first mounting plate 103 disposed on the die clamper 102, a first die 104 disposed on the first mounting plate 103, a carrier seat 105 disposed on one side of the die casting machine body 101, and a motor 106 disposed on the carrier seat 105; the replacement component 200 comprises a storage component 201 arranged on the motor 106, a guide component 202 arranged on one side of the storage component 201, a clamping component 203 arranged on the guide component 202, a rotating component 204 arranged on the clamping component 203, a locking component 205 arranged on the clamping component 203 and a switching component 206 arranged on the locking component 205; the anti-drop assembly comprises a limit assembly 301 arranged on the storage assembly 201, a lifting assembly 302 arranged on the limit assembly 301, and a transmission assembly 303 arranged on the lifting assembly 302.

Specifically, the die-casting machine translates left and right, and is L-shaped, and can compress the first die 104, and can limit the first die 104 to keep the stability of the first die 104, and here the die-casting machine is last to be fixedly connected with to stop the position board, can carry out the support of first mounting panel 103, so that carry out the installation of first mounting panel 103, and here die-casting machine body 101 is prior art, and here first die 104 and first mounting panel 103 fixed connection, bear seat 105 and be fixed in one side subaerial of die-casting machine body 101, motor 106 and bear seat 105 fixed connection.

Further, the storage assembly 201 includes a disc 201a disposed on the motor 106, a plurality of storage racks 201b disposed on the disc 201a, a blocking piece 201c disposed on the storage racks 201b, a second mounting plate 201d disposed on the storage racks 201b, and a second mold 201e disposed on the second mounting plate 201 d; wherein the second molds 201e on the plurality of storage racks 201b are all different; the motor and the electric sliding rail can be precisely controlled by programming, and the start and stop of the motor and the start and stop of the electric sliding rail are controlled by the program in the prior art, which is not described herein, and the guide assembly 202 comprises a support frame 202a arranged at one side of the disc 201a, an electric sliding rail 202b arranged on the support frame 202a, and a sliding block 202c arranged on the electric sliding rail 202 b; the clamping assembly 203 includes a limit groove 203a provided on the second mounting plate 201d, a transverse plate 203b provided on the slider 202c, a rotating shaft 203c provided on the transverse plate 203b, a supporting plate 203d provided on the rotating shaft 203c, a vertical plate 203e provided on the supporting plate 203d, and a cutting 203f provided on the vertical plate 203 e.

The disc 201a is fixedly connected with an output shaft of the motor 106, the storage rack 201b is fixedly connected with the disc 201a, the storage rack 201b is frame-shaped, an outer end of the storage rack is open, the storage rack 201d can be placed, two pairs of baffle plates 201c are arranged, the baffle plates are respectively and fixedly connected to the side wall of the storage rack 201b, the second mounting plate 201d is arranged in the storage rack 201b, the second die 201e is fixedly connected with the second mounting plate 201d, the support racks 202a are fixedly connected with the ground, the two support racks 202a are respectively provided with an electric slide rail 202b, the electric slide rails 202b drive the slide blocks 202c to slide left and right, the limiting grooves 203a are formed in the second mounting plate 201d and the first mounting plate 103, the transverse plates 203b are fixedly connected with the slide blocks 202c, the rotary shafts 203c are rotatably connected with the transverse plates 203b, the rotary shafts 203c are damped, the rotary shafts 203c are prevented from self-rotating, the support plates 203d are fixedly connected with the vertical plates 203e, the insert strips 203f are fixedly connected with the vertical plates 203e, and the insert strips 203f are provided with four insert strips 203f.

Preferably, the rotating assembly 204 includes a gear ring 204a disposed on a supporting plate 203d, a fixed plate 204b disposed on a supporting frame 202a, and a toothed plate 204c disposed on the fixed plate 204 b; the locking assembly 205 comprises a limit frame 205a arranged on the limit groove 203a, a cavity 205b arranged on the cutting 203f, a through hole 205c arranged on the cavity 205b, and a wedge block 205d arranged on the through hole 205 c; the switching component 206 includes a moving block 206a disposed on the cavity 205b, a transmission rod 206b disposed on the moving block 206a, a sliding slot 206c disposed on the moving block 206a, a guide block 206d disposed on the sliding slot 206c, an L-shaped rod 206e disposed on the guide block 206d, a support plate disposed in the cavity 205b, a first guide slot 206f disposed on the support plate, a second guide slot 206g disposed on the first guide slot 206f, a third guide slot 206h disposed on the second guide slot 206g, and a fourth guide slot 206i disposed on the third guide slot 206h, and a fifth guide slot 206j disposed on the fourth guide slot 206 i; wherein, the junction of the third guide groove 206h and the fourth guide groove 206i forms a concave point, and the slope of the third guide groove 206h is greater than the slope of the fourth guide groove 206 i.

It should be noted that, the gear ring 204a is fixedly connected with the outer side wall of the supporting disc 203d, the fixed plate 204b is fixedly connected with the supporting frame 202a, the toothed plate 204c is fixedly connected with the fixed plate 204b, the limiting frame 205a is fixedly connected with the inner wall of the limiting groove 203a, the wedge-shaped block 205d is slidably connected with the through hole 205c, the two wedge-shaped blocks 205d are fixedly connected with connecting pieces, the two connecting pieces are elastically connected through a return spring, wherein the middle part of the return spring is glued with the middle part of the inner wall of the cavity 205b, so that the return spring main body cannot slide left and right, and can drive the connecting pieces to reset, so that the wedge-shaped block 205d is reset, the moving block 206a is slidably connected with the inner wall of the cavity 205b, the driving rod 206b is fixedly connected with the moving block 206a, the driving rod 206b penetrates through the insert 203f and is slidably connected with the insert 203f, the guiding block 206d is slidably connected with the sliding groove 206c, the L-shaped rod 206e is fixedly connected with the guiding block 206d, the first guiding groove 206f is communicated with the second guiding groove 206g, the second guiding groove 206g is communicated with the third guiding groove 206h, the third guiding groove 206h is communicated with the fifth guiding groove 206j, the fifth guiding groove is communicated with the fifth guiding groove 206i, and the fifth guiding groove is communicated with the fifth guiding groove 206 i.

In use, first, the second mold 201e is placed on each of the plurality of storage racks 201b, one of the storage racks 201b is empty, when the empty storage rack 201b is opposite to the support frame 202a, the motor 106 is started to move the cutting 203f to the left and opposite to the limit groove 203a on the first mounting plate 103, then the electric slide rail 202b is started to drive the slider 202c to move to the left, so that the transverse plate 203b moves to the left, the support plate 203d moves to the left, the vertical plate 203e moves to the left, the cutting 203f moves to be inserted into the limit groove 203a, at this time, the wedge 205d does not extend out of the through hole 205c, at this time, the cutting 203f can pass through the limit frame 205a smoothly, when the transmission rod 206b on the cutting 203f abuts against the inner wall of the limit groove 203a, the electric slide rail 202b continues to move, and due to the arrangement of the mold clamping device 102, the first mounting plate 103 will not slide, so that the transmission rod 206b is extruded to move to the wedge 205d, the moving block 206a moves towards the moving block 206a, so that the moving block 206a pushes the two wedge blocks 205d to move outwards, the side wall of the wedge block 205d is propped against the side wall of the limiting frame 205a, at the moment, the cutting 203f cannot slide outwards, and cannot be separated from the limiting groove 203a, when the moving block 206a moves, the guide block 206d can be driven to move, the L-shaped rod 206e moves, the L-shaped rod 206e is positioned in the first guide groove 206f, the L-shaped rod 206e moves from the first guide groove 206f to the second guide groove 206g and then enters the third guide groove 206h, stays at the concave points of the third guide groove 206h and the fourth guide groove 206i, during the process, the guide groove can slide left and right on the sliding groove 206c, the phenomenon that the L-shaped rod 206e is blocked is avoided, when the L-shaped rod 206e is positioned at the concave point, the L-shaped rod 206e can be prevented from automatically resetting, and the guide block 206d is prevented from resetting, the movable block 206a is prevented from being reset, the wedge-shaped block 205d is kept stable, an anti-falling groove is formed in the sliding groove 206c, and an anti-falling block is arranged on the guide block 206d and is matched with the anti-falling block, so that the guide block 206d can be prevented from falling out of the sliding groove 206c.

Then the die holder 102 is released, the electric slide rail 202b is started to drive the sliding block 202c to move rightwards, four cutting bars 203f are driven to move rightwards through transmission, the four cutting bars 203f support the first supporting plate, the wedge-shaped block 205d is propped against the limiting frame 205a, the first supporting plate can be driven to move rightwards, the first die 104 is enabled to move rightwards, when the first mounting plate 103 and the die casting machine body 101 leave a safe distance, the gear ring 204a is meshed with the toothed plate 204c to move rightwards continuously, the gear ring 204a is driven to rotate, the tooth number of the gear ring 204a is 2 times that of the toothed plate 204c, so that the gear ring 204a is driven to rotate 180 degrees, and when the gear ring 204a rotates 180 degrees, the vertical plate 203e is driven to rotate 180 degrees, the cutting bars 203f are driven to rotate 180 degrees, the first mounting plate 103 rotates 180 degrees, the first die 104 rotates 180 degrees, the first mounting plate 103 is opposite to the empty storage frame, at the moment, the electric slide rail 202b is only required to move continuously, the first mounting plate 103 and the first mold 104 can be sent into an empty storage frame, when the first mounting plate 103 completely enters the storage frame, the electric slide rail 202b continues to move, the cutting 203f continues to move through transmission, the transmission rod 206b can be pushed to move, the moving block 206a moves, the L-shaped rod 206e moves, the slope of the third guide groove 206h is larger than that of the fourth guide groove 206i, the L-shaped rod 206e moves into the fifth guide groove 206j, then the electric slide rail 202b is started, the sliding block 202c moves leftwards, the cutting 203f slowly breaks away from the limit groove 203a, in the process, the L-shaped rod 206e resets, the moving block 206a resets, the wedge-shaped block 205d resets, the driving rod 206b can pass through the limit frame 205a, so that the cutting 203f is taken out, after the cutting 203f leaves the limit groove 203a, the motor 106 rotates the output shaft, the disc 201a is driven to rotate, the required second mold 201e is opposite to the first mold 104, then, similarly, the second die 201e is inserted onto the die casting machine body 101 by the insert 203f, and the die replacement process is completed.

In summary, through the movement of the cutting 203f, the first die 104 on the die casting machine body 101 can be placed on the storage rack 201b on the disc 201a, then the second die 201e on the storage rack 201b is moved to the die casting machine body 101, so that the die on the die casting machine body 101 is replaced, automatic replacement is realized, the die replacement is more rapid, the replacement process can be realized only by the motor 106 and the electric sliding rail 202b, the cost is lower, and the enterprise development is facilitated.

Example 2

Referring to fig. 8 to 9, in a second embodiment of the present application, unlike the previous embodiment, the present embodiment provides a limit component 301 of an automobile engine end cap die casting device, which solves the problem of avoiding dropping of a second mold 201e on a storage rack 201b, wherein the limit component 301 includes a mounting cavity 301a disposed in the storage rack 201b, a penetrating opening 301b disposed on the mounting cavity 301a, a lifting block 301c disposed on the mounting cavity 301a, a notch 301e disposed on a top block 301d, an extension cavity 302b disposed on the mounting cavity 301a, and a first spring 301f disposed on the lifting block 301 c.

Specifically, two installation cavities 301a are provided, which are divided into an upper installation cavity 301a and a lower installation cavity 301a, the penetrating opening 301b penetrates through the storage rack 201b, the lifting block 301c is slidably connected with the inner wall of the installation cavity 301a, the lifting block 301c is elastically connected with the inner wall of the installation cavity 301a through the first spring 301f, and the top block 301d extends to the outer side of the storage rack 201 b.

When the second mounting plate 201d is placed on the storage rack 201b in use, the second mounting plate 201d is matched with the notch 301e, so that the top block 301d can be pushed to move downwards, the lifting block 301c moves downwards, the first spring 301f is compressed, when the second mounting plate 201d passes over the top block 301d, the first spring 301f rebounds, the top block 301d protrudes to be blocked on the outer side of the second mounting plate 201d, limiting of the second mounting plate 201d is performed, movement of the second mounting plate 201d is avoided, and stability of the second mounting plate 201d on the storage rack 201b is guaranteed.

In summary, when the second mold 201e is placed on the storage rack 201b, the second mold 201e can be automatically limited, so that the phenomenon that the second mold 201e automatically slides off when placed on the storage rack 201b is avoided, the stability of the second mold 201e when placed is ensured, and the protection of the second mold 201e is realized.

Example 3

Referring to fig. 8 to 9, in a third embodiment of the present application, unlike the previous embodiment, the present application provides a lifting assembly 302 of an automobile engine end cap die casting device, which solves the problem of how to release the limit and take out the second mounting plate and the second mold, and includes a first U-shaped plate 302a disposed on a lifting block 301c, a top block 301d disposed on the lifting block 301c, a push block 302c disposed on an extension cavity 302b, a second U-shaped plate 302d disposed on the push block 302c, and a transmission plate 302e disposed on the first U-shaped plate 302 a; one end of the driving plate 302e is rotatably connected with the first U-shaped plate 302a, and the other end of the driving plate 302e is rotatably connected with the second U-shaped plate 302 d; the transmission assembly 303 includes a bar slot 303a provided on the storage rack 201b, a bar plate 303b provided on the bar slot 303a, a second spring 303c provided on the bar plate 303b, a circular opening 303d provided on the bar slot 303a, a bar 303e provided in the circular opening 303d, a first L-shaped plate 303f provided on the bar plate 303b, and a second L-shaped plate 303g provided on the cross plate 203 b;

wherein the first L-shaped plate 303f is adapted to the second L-shaped plate 303 g.

Specifically, the first U-shaped plate 302a is fixedly connected with the lifting block 301c, the pushing block 302c is slidably connected with the extension cavity 302b, the second U-shaped plate 302d is fixedly connected with the pushing block 302c, the bar-shaped groove 303a is arranged on the vertical side of the storage rack 201b, the bar-shaped groove 303a penetrates through the bottom of the disc 201a, the bar-shaped plate 303b is slidably connected with the storage rack 201b, the bar-shaped plate 303b is elastically connected with the inner wall of the bar-shaped groove 303a through the second spring 303c, the first L-shaped plate 303f is fixedly connected with the bar-shaped plate 303b, the second L-shaped plate 303g is fixedly connected with the transverse plate 203b, the circular opening 303d is communicated with the mounting groove, the long rod 303e penetrates through the circular opening 303d, one end of the long rod 303e is fixedly connected with the pushing block 302c, and the other end of the long rod 303e is fixedly connected with the bar-shaped plate 303 b.

In use, when the cutting 203f drives the second mounting plate 201d to move onto the storage rack 201b, the second L-shaped plate 303g abuts against the first L-shaped plate 303f, and pushes the first L-shaped plate 303f to move towards the motor 106, so that the long strip plate 303b moves, the second spring 303c compresses, and when the long strip plate 303b moves, the long rod 303e can be driven to move, the push block 302c moves, the transmission plate 302e moves, the lifting block 301c moves downwards, and the second mounting plate 201d on the storage rack 201b and the second die 201e can be taken out, so that the dies can be replaced.

In summary, when taking out the second mold 201e, the limit on the second mounting plate 201d can be automatically released, so that the second mounting plate 201d is taken out, and the second mold 201e is taken out, so that the mold is replaced conveniently, and when the contact is limited, other power is not needed, so that the use is more convenient.

It is important to note that the construction and arrangement of the application as shown in the various exemplary embodiments is illustrative only. Although only a few embodiments have been described in detail in this disclosure, those skilled in the art who review this disclosure will readily appreciate that many modifications are possible (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters (e.g., temperature, pressure, etc.), mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter described in this application. For example, elements shown as integrally formed may be constructed of multiple parts or elements, the position of elements may be reversed or otherwise varied, and the nature or number of discrete elements or positions may be altered or varied. Accordingly, all such modifications are intended to be included within the scope of present application. The order or sequence of any process or method steps may be varied or re-sequenced according to alternative embodiments. In the claims, any means-plus-function clause is intended to cover the structures described herein as performing the recited function and not only structural equivalents but also equivalent structures. Other substitutions, modifications, changes and omissions may be made in the design, operating conditions and arrangement of the exemplary embodiments without departing from the scope of the present applications. Therefore, the application is not limited to the specific embodiments, but extends to various modifications that nevertheless fall within the scope of the appended claims.

Furthermore, in order to provide a concise description of the exemplary embodiments, all features of an actual implementation may not be described (i.e., those not associated with the best mode presently contemplated for carrying out the application, or those not associated with practicing the application).

It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions may be made. Such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure.

It should be noted that the above embodiments are only for illustrating the technical solution of the present application and not for limiting the same, and although the present application has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solution of the present application may be modified or substituted without departing from the spirit and scope of the technical solution of the present application, which is intended to be covered in the scope of the claims of the present application.

Claims (10)

1. An automobile engine end cover die casting device which characterized in that: comprising the steps of (a) a step of,

a carrier (100) comprising a die casting machine body (101), a die clamper (102) arranged on the die casting machine body (101), a first mounting plate (103) arranged on the die clamper (102), a first die (104) arranged on the first mounting plate (103), a carrier seat (105) arranged on one side of the die casting machine body (101), and a motor (106) arranged on the carrier seat (105);

a replacement part (200) comprising a storage component (201) arranged on the motor (106), a guide component (202) arranged on one side of the storage component (201), a clamping component (203) arranged on the guide component (202), a rotating component (204) arranged on the clamping component (203), a locking component (205) arranged on the clamping component (203), and a switching component (206) arranged on the locking component (205);

the anti-falling component (300) comprises a limiting component (301) arranged on the storage component (201), a lifting component (302) arranged on the limiting component (301) and a transmission component (303) arranged on the lifting component (302).

2. The automotive engine end cover die casting apparatus of claim 1, wherein: the storage assembly (201) comprises a disc (201 a) arranged on the motor (106), a plurality of storage frames (201 b) arranged on the disc (201 a), a baffle (201 c) arranged on the storage frames (201 b), a second mounting plate (201 d) arranged on the storage frames (201 b), and a second die (201 e) arranged on the second mounting plate (201 d);

wherein the second molds (201 e) on the plurality of storage racks (201 b) are different.

3. The automotive engine end cover die casting apparatus of claim 2, wherein: the guide assembly (202) comprises a support frame (202 a) arranged on one side of the disc (201 a), an electric sliding rail (202 b) arranged on the support frame (202 a), and a sliding block (202 c) arranged on the electric sliding rail (202 b).

4. A die casting device for an automotive engine end cover as defined in claim 3, wherein: the clamping assembly (203) comprises a limiting groove (203 a) arranged on a second mounting plate (201 d), a transverse plate (203 b) arranged on the sliding block (202 c), a rotating shaft (203 c) arranged on the transverse plate (203 b), a supporting plate (203 d) arranged on the rotating shaft (203 c), a vertical plate (203 e) arranged on the supporting plate (203 d) and an inserting strip (203 f) arranged on the vertical plate (203 e).

5. The automobile engine end cover die casting apparatus as defined in claim 4, wherein: the rotating assembly (204) comprises a gear ring (204 a) arranged on the supporting disc (203 d), a fixed plate (204 b) arranged on the supporting frame (202 a), and a toothed plate (204 c) arranged on the fixed plate (204 b).

6. The automobile engine end cover die casting apparatus as defined in claim 4, wherein: the locking assembly (205) comprises a limiting frame (205 a) arranged on a limiting groove (203 a), a cavity (205 b) arranged on the cutting (203 f), a through hole (205 c) arranged on the cavity (205 b), and a wedge block (205 d) arranged on the through hole (205 c).

7. The automotive engine end cover die casting apparatus of claim 6, wherein: the switching assembly (206) comprises a moving block (206 a) arranged on a cavity (205 b), a transmission rod (206 b) arranged on the moving block (206 a), a sliding groove (206 c) arranged on the moving block (206 a), a guide block (206 d) arranged on the sliding groove (206 c), an L-shaped rod (206 e) arranged on the guide block (206 d), a first guide groove (206 f) arranged on the cavity (205 b), a second guide groove (206 g) arranged on the first guide groove (206 f), a third guide groove (206 h) arranged on the second guide groove (206 g), and a fourth guide groove (206 i) arranged on the fourth guide groove (206 i);

wherein, the joint of the third guide groove (206 h) and the fourth guide groove (206 i) forms a concave point, and the slope of the third guide groove (206 h) is larger than that of the fourth guide groove (206 i).

8. The automotive engine end cover die casting apparatus of claim 7, wherein: the limiting assembly (301) comprises an installation cavity (301 a) arranged in the storage rack (201 b), a penetrating opening (301 b) arranged on the installation cavity (301 a), a lifting block (301 c) arranged on the installation cavity (301 a), a top block (301 d) arranged on the lifting block (301 c), a notch (301 e) arranged on the top block (301 d) and a first spring (301 f) arranged on the lifting block (301 c).

9. The automotive engine end cover die casting apparatus of claim 8, wherein: the lifting assembly (302) comprises a first U-shaped plate (302 a) arranged on a lifting block (301 c), an extension cavity (302 b) arranged on the installation cavity (301 a), a push block (302 c) arranged on the extension cavity (302 b), a second U-shaped plate (302 d) arranged on the push block (302 c) and a transmission plate (302 e) arranged on the first U-shaped plate (302 a);

one end of the transmission plate (302 e) is rotatably connected with the first U-shaped plate (302 a), and the other end of the transmission plate is rotatably connected with the second U-shaped plate (302 d).

10. The automotive engine end cover die casting apparatus of claim 9, wherein: the transmission assembly (303) comprises a strip-shaped groove (303 a) arranged on the storage rack (201 b), a strip plate (303 b) arranged on the strip-shaped groove (303 a), a second spring (303 c) arranged on the strip plate (303 b), a round opening (303 d) arranged on the strip-shaped groove (303 a), a long rod (303 e) arranged in the round opening (303 d), a first L-shaped plate (303 f) arranged on the strip plate (303 b) and a second L-shaped plate (303 g) arranged on the transverse plate (203 b);

wherein the first L-shaped plate (303 f) is adapted to the second L-shaped plate (303 g).