CN218049924U - Automatic feeding type die and feeding mechanism in die thereof - Google Patents

Abstract

The application discloses autoloading type mould for shifting at least a work piece, autoloading type mould includes a mould component, at least one linkage subassembly, at least one direction area moves the component, at least one connection operation control and at least one removal operation control, the mould component includes a first mould subassembly and a second mould subassembly, direction area moves the component including a direction area, the linkage subassembly is installed in slidable way in the top of direction area moves the component, connect operation control and remove operation control homonymy setting, connect operation control and linkage subassembly be installed respectively in first mould subassembly and second mould subassembly, when the distance between first mould subassembly and the second mould subassembly reduces gradually, connect operation control and remove operation control cooperation control the linkage subassembly and move to this shifts with the work piece that the linkage subassembly is connected.

Description

Automatic feeding type die and feeding mechanism in die thereof

Technical Field

The utility model relates to the technical field of mold, especially, relate to automatic feeding type mould and feeding mechanism in mould thereof.

Background

In order to improve the production efficiency of the product, a progressive die is generally adopted for processing. When the progressive die is used, a punch feeder moves a long strip sheet material according to a preset step pitch so that the material sequentially passes through each station, and various working procedures such as blanking, bending forming, stretching and the like are realized. Due to the structural characteristics of the material, the material in the mold needs to be cut and removed to ensure that the material is processed into individual products.

At present, products in a mold are usually taken out by means of wind power, and an air flow is conveyed to the products at the discharging position of the mold by a fan, so that the products are pushed by the air flow to move along the air flow direction, and feeding is realized. However, when the fan is used, the strength of the blown wind is insufficient, so that the product is not blown out of the die in time. In addition, if the punching oil adheres the product to the mold and the product is moved by only the wind force, there may be a case where the wind force acting on the product is insufficient to separate the product from the mold. This can result in the product being present at the discharge of the mold simultaneously with the next product to be discharged, so that the mold and the product are damaged during closing. Thus, not only is it not ensured that the product can be efficiently delivered, but also the probability of damage to the mold is increased.

In addition, in the feeding mode, an external power supply is required to be used for supplying electric energy to the fan, the production cost of the product is increased, and the energy conservation and the environmental protection are insufficient.

SUMMERY OF THE UTILITY MODEL

An advantage of the present invention is to provide automatic feeding type mould, the utility model discloses set up a mould component, a linkage subassembly, a direction area and move component, a connection operation control and a removal operation control, the mould component includes a first mould subassembly and a second mould subassembly, connection operation control with removal operation control homonymy setting, and with the linkage subassembly set up respectively in first mould subassembly with second mould subassembly, so that first mould subassembly is close to during the second mould subassembly, connection operation control with removal operation control can the cooperative control the linkage subassembly shifts the work piece realizes the autoloading of work piece compares traditional material feeding unit, and the pay-off mode of this kind of machinery not only can ensure the work piece is effectively shifted, only can accomplish the pay-off with the help of the mould operation that opens and shuts moreover, need not external power supply, and the simple operation, the practicality is higher.

An advantage of the present invention is that it provides automatic material feeding type mould, the interlock subassembly includes a moving part and a linkage piece, the moving part includes a movable body and a sliding structure, a first inclined plane of activity body definition, the direction area moves the component and includes that a direction area moves the subassembly, the direction area moves the subassembly and includes a guide, the guide includes a direction body and a guide structure, connect operation control definition first contact surface, it can promote to connect operation control the activity body along the direction body slides the predetermined distance, so that install in the activity body the interlock piece connect in the work piece, sliding structure with the incline direction on first inclined plane is the same, makes the activity body is losing under the condition of the drive force of connecting operation control, the activity body receives self action of gravity and resets, interlock synchronous motion, remove with the connection of work piece, in this process, need not with the help of external force, conveniently right the continuity pay-off is carried out to the work piece.

The utility model discloses an advantage lies in providing automatic material type mould that send, interlock spare by detachably install in the moving part to the staff basis different specifications are changed to the actual size of work piece interlock spare satisfies multiple size with this the transfer of work piece.

An advantage of the utility model is that an automatic material feeding type mould is provided, the interlock piece is kept away from one side of moving part is implemented as flexible material, in order to avoid the damage appears when the work piece is by the centre gripping.

An advantage of the utility model is that an automatic material conveying type mould is provided, the direction area moves the component and includes that one resets, it can be right that the piece resets the direction area moves the subassembly and resets to carry out next round of pay-off.

The utility model discloses an advantage lies in providing automatic pay-off type mould, the interlock subassembly the direction area move the component connect the operation control with it all is provided with two to remove the operation control, so that two the interlock subassembly can be right simultaneously the work piece carries out the centre gripping, in order to increase the stability that the work piece removed guarantees the pay-off is stabilized to the work piece.

An advantage of the present invention is to provide an automatic feeding type mold, the lateral distance between the high-end of first inclined plane and the bottom can be designed into different sizes, so that connect the operation control and can bulldoze the activity body along the direction body carries out different removal, with this satisfy to different lateral dimensions the work piece carries out the centre gripping.

An advantage of the present invention is to provide an automatic feeding type mold, the lateral distance between the high end of guide structure and the bottom can be designed into different sizes, so that the connection operation control can push and press the activity body carries out different longitudinal movement, with this satisfy to different longitudinal sizes the work piece carries out the centre gripping.

An advantage of the present invention is to provide an automatic feeding type mold, the guiding belt moves the component and includes a base, the guiding belt moves the subassembly and includes that a area moves the piece, remove operation control definition second contact surface, the lateral distance between the high-end of second inclined plane and the bottom can be designed into different length, so that it can bulldoze to remove operation control the area moves the piece along the base carries out the removal of different degrees to this satisfies not unidimensional the work piece shifts, in order to avoid the work piece is because the big and removal stroke of size is short, leads to adjacently the work piece produces the interference.

For reaching the utility model discloses above at least one advantage, the utility model provides an automatic feeding type mould for shift an at least work piece, automatic feeding type mould includes:

a die member including a first die assembly and a second die assembly, the first die assembly being configured to move up and down relative to the second die assembly, the second die assembly including a support for supporting the workpiece;

at least one linkage assembly for abutting against the workpiece;

at least one guide belt moving component, wherein the guide belt moving component comprises a guide belt moving component, and the linkage component is slidably arranged at the top of the guide belt moving component;

at least one connecting operation control part, wherein the connecting operation control part is arranged opposite to the linkage component, the connecting operation control part and the linkage component are respectively arranged on the first die component and the second die component, and when the distance between the first die component and the second die component is gradually reduced, the connecting operation control part controls the linkage component to move close to the supporting part along the guide belt moving component so as to enable the linkage component to abut against the workpiece;

the connecting operation control piece and the moving operation control piece are arranged on the same side, when the distance between the first die assembly and the second die assembly is gradually reduced, the moving operation control piece controls the guide belt moving assembly to move for a preset distance, and the movement track of the guide belt moving assembly and the movement track of the linkage assembly controlled by the connecting operation control piece are crossed, so that the linkage assembly connected to the guide belt moving assembly drives the workpiece to move.

According to the utility model discloses an embodiment, the interlock subassembly is installed in first mould subassembly, connect operation control with remove operation control all installed in second mould subassembly.

According to the utility model discloses an embodiment, the interlock subassembly is installed in the second mould subassembly, connect operation control with remove operation control all installed in first mould subassembly.

According to the utility model discloses an embodiment, the area of direction moves the subassembly and includes a guide piece, the interlock subassembly includes a moving part, it can control to connect the operation control piece by setting up the moving part along the guide piece slides and is close to support piece.

According to the utility model discloses an embodiment, the moving part includes a movable body and a sliding structure, sliding structure form in the movable body, the guide includes a direction body and a guide structure, the guide structure form in the direction body, guide structure's size with sliding structure's size looks adaptation, a first inclined plane of movable body definition, first inclined plane with contained angle between the upper surface of movable body is the obtuse angle, guide structure slope design and incline direction with first inclined plane incline direction keeps the unanimity, a connection operation control definition first contact surface, first contact surface is set up can be attached in first inclined plane connection operation control receive the drive effect application of first mould subassembly in during the moving part, first contact surface with first inclined plane is parallel, connection operation control is set up and can be promoted the movable body along the guide structure is close to slide support piece, when the movable body does not receive the drive effect of connection operation in the moving part application of force, the movable body is along the guide structure slides the control under the action of gravity and is kept away from support piece.

According to an embodiment of the present invention, the guiding structure is implemented as being formed in the groove of the guiding body, the sliding structure is implemented as being provided in the rib of the movable body, the dimension of the rib being adapted to the groove, the rib being slidably mounted in the groove.

According to an embodiment of the present invention, the guiding structure is implemented as a rib provided in the guiding body, the sliding structure is implemented as a groove formed in the movable body, a dimension of the rib being adapted to the groove, the rib being slidably mounted in the groove.

According to the utility model discloses an embodiment, the interlock subassembly still includes a interlock piece, interlock piece be installed in the moving part, interlock piece is used for the butt the work piece.

According to the utility model discloses an embodiment, the interlock piece by detachably install in the moving part, the interlock piece is kept away from one side of moving part is implemented as flexible material.

According to the utility model discloses an embodiment, the interlock subassembly is provided with one, the quantity of interlock subassembly with connect the operation control with the quantity of removal operation control keeps unanimous, the moving part is implemented as an L type push rod.

According to the utility model discloses an embodiment, the interlock subassembly is provided with two, and two the interlock subassembly sets up relatively, the quantity of interlock subassembly with the guidance tape move the component connect the operation control with the quantity that removes the operation control keeps unanimous.

According to the utility model discloses an embodiment, the direction area moves the subassembly and still includes that one takes to move the piece, the area move the piece install in the direction body, the direction area moves the component and still includes a base and a connection structure, connection structure set up in the direction area move the subassembly with between the base, it can control to remove the setting of operation control piece the guide with it is whole relative that the piece is moved to the area the base slides the predetermined distance remove the operation control piece and drive the direction area moves the subassembly and removes behind the predetermined distance, the interlock subassembly with it staggers to connect the operation control piece.

According to the utility model discloses an embodiment, the area moves a definition second inclined plane, the second inclined plane with the area moves the contained angle between the piece upper surface for the obtuse angle, remove operation control part definition second contact surface, the second contact surface be set up can attach in the second inclined plane remove operation control part receive the drive effect application of force of first mould subassembly in during the guide, the second contact surface is parallel with the second inclined plane.

According to the utility model discloses an embodiment, connection structure includes a spacing groove and a fixture block, the fixture block by slidable install in the spacing groove, the size adaptation of spacing groove in the fixture block, the spacing groove with the fixture block form respectively in the guiding strip move the subassembly with the base.

According to the utility model discloses an embodiment, second mould subassembly includes a lower mould subassembly, support piece set up in lower mould subassembly, lower mould subassembly with first mould subassembly sets up relatively, lower mould subassembly includes a module, support piece set up in lower module, second mould subassembly have one place the chamber and one with place the entry of chamber intercommunication, it is used for placing to place the chamber the guiding strip moves the subassembly, place the chamber and be formed at lower module.

According to the utility model discloses an embodiment, the direction area moves the component and still includes one and resets the piece, reset the piece install in the direction area moves the subassembly, reset the piece and be used for driving after removing the direction area moves the subassembly and resets, lower mould subassembly still includes a connecting piece, reset the piece set up in the connecting piece with the direction area moves between the subassembly, the connecting piece be installed in place the chamber.

According to an embodiment of the present invention, the second mold assembly further includes a lower pad, the lower pad being installed in the lower mold, the lower pad and the lower mold forming the placing cavity, the lower pad being used to support the guide belt moving member and the connecting member.

According to the utility model discloses an embodiment, first mould subassembly includes a last module, a last folder and one takes off the material piece, it is located to go up the folder go up the module with take off between the material piece, connect operation control with remove operation control all installed in go up the folder first mould subassembly move down be close to with when the second mould subassembly, the module is located take off the material piece with between the backing member down.

In order to achieve the utility model discloses above at least one advantage, the utility model provides a feeding mechanism in the mould for shift an at least work piece, feeding mechanism includes in the mould:

at least one linkage assembly, wherein the linkage assembly is used for abutting against the workpiece;

at least one guide belt moving component, wherein the guide belt moving component comprises a guide belt moving component, and the linkage component is slidably arranged at the top of the guide belt moving component;

at least one connecting operation control piece, wherein the connecting operation control piece is arranged opposite to the linkage component, and the connecting operation control piece can control the linkage component to move a preset distance along the guide belt moving component in a downward moving mode so as to enable the linkage component to abut against the workpiece;

the moving operation control piece is arranged opposite to the guide belt moving assembly, the connecting operation control piece and the moving operation control piece are arranged on the same side, the moving operation control piece can control the guide belt moving assembly to move for a preset distance in a downward moving mode, and the motion track of the guide belt moving assembly and the motion track of the linkage assembly controlled by the connecting operation control piece are crossed so that the linkage assembly connected to the guide belt moving assembly drives the workpiece to move.

Drawings

Fig. 1 shows the structure of the automatic feeding mold of the present invention.

Fig. 2 shows the structure section of the automatic feeding type mold of the present invention.

Fig. 3 shows the structure explosion diagram of the automatic feeding type mold of the present invention.

Fig. 4 shows the structure schematic diagram of the automatic feeding type mold before moving.

Fig. 5 shows a schematic structural diagram of a motion state of the automatic feeding type mold of the present invention.

Fig. 6 shows a schematic structural view of another moving state of the automatic feeding die of the present invention.

Fig. 7 shows the schematic structural diagram of the automatic feeding type mold after movement.

Fig. 8 shows a schematic structural diagram of an embodiment of the automatic feeding type mold of the present invention.

Detailed Description

The following description is presented to disclose the invention so as to enable any person skilled in the art to practice the invention. The preferred embodiments in the following description are given by way of example only, and other obvious variations will occur to those skilled in the art. The underlying principles of the invention, as defined in the following description, may be applied to other embodiments, variations, modifications, equivalents, and other technical solutions without departing from the spirit and scope of the invention.

It will be understood by those skilled in the art that in the present disclosure, the terms "longitudinal," "lateral," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in a generic and descriptive sense only and not for purposes of limitation, as the terms are used in the description to indicate that the referenced device or element must have the specified orientation, be constructed and operated in the specified orientation, and not for the purpose of limitation.

It is understood that the terms "a" and "an" should be interpreted as meaning that a number of one element or element is one in one embodiment, while a number of other elements is one in another embodiment, and the terms "a" and "an" should not be interpreted as limiting the number.

Referring to fig. 1 to 3, a autoloading mold for transferring at least one workpiece 90 according to a preferred embodiment of the present invention, which includes a mold member 10, at least one linkage assembly 20, at least one guide belt moving member 30, at least one connecting operation controller 40, and at least one moving operation controller 50, will be described in detail below.

The die member 10 includes a first die assembly 11 and a second die assembly 12, the first die assembly 11 being configured to move up and down relative to the second die assembly 12, the second die assembly 12 including a support 121, the support 121 being configured to support the workpiece 90.

The linkage assembly 20 is used for abutting against the workpiece 90. The guide belt moving member 30 includes a guide belt moving member 31, and the linkage assembly 20 is slidably mounted on the top of the guide belt moving member 31.

The connecting operation control member 40 and the interlocking unit 20 are respectively installed to the first mold unit 11 and the second mold unit 12. The moving operation control member 50 and the guide belt moving assembly 31 are respectively installed at the first mold assembly 11 and the second mold assembly 12, and the connecting operation control member 40 and the moving operation control member 50 are disposed at the same side.

When the distance between the first mold assembly 11 and the second mold 12 gradually decreases, the connecting operation control member 40 controls the linkage assembly 20 to move closer to the support 121 along the guide belt moving assembly 31, so that the linkage assembly 20 abuts against the workpiece 90. And, the moving operation control member 50 controls the guide belt moving assembly 31 to move for a predetermined distance, and the movement track of the guide belt moving assembly 31 and the movement track of the linkage assembly 20 controlled by the connection operation control member 40 are crossed, so that the linkage assembly 20 connected to the guide belt moving assembly 31 drives the workpiece 90 to move, thereby realizing feeding.

Preferably, the linkage assembly 20 is mounted to the second mold assembly 12, and the connecting-operation control member 40 and the moving-operation control member 50 are both mounted to the first mold assembly 11. By so doing, the connecting-operation controller 40 and the moving-operation controller 50 can be moved close to the second die 12 as the first die assembly 11, so that the connecting-operation controller 40 and the moving-operation controller 50 cooperatively control the linkage assembly 20 to transfer the workpiece 90.

The interlocking unit 20 is attached to the first mold unit 11 in a deformable manner, and the connecting-operation controller 40 and the moving-operation controller 50 are both attached to the second mold unit 12. The same object can be achieved, and the description is omitted.

In order to enable those skilled in the art to understand the present embodiment, in at least one of the following embodiments and the corresponding drawings, the linkage assembly 20 is mounted to the second mold assembly 12, and the connecting operation control member 40 and the moving operation control member 50 are both mounted to the first mold assembly 11 for illustration, which should be understood by those skilled in the art as not limiting the present invention.

Referring to fig. 4 to 6, further, the guide belt moving assembly 31 includes a guide element 311, the linking assembly 20 includes a movable element 21, and the connecting operation control element 40 is configured to control the movable element 21 to slide along the guide element 311 to approach the supporting element 121, so that the movable element 21 abuts against the workpiece 90 disposed on the supporting element 121.

Further, the movable member 21 includes a movable body 211 and a sliding structure 212, and the sliding structure 212 is formed on the movable body 211. The guide 311 includes a guide body 3111 and a guide structure 3112, and the guide structure 3112 is formed on the guide body 3111. The dimensions of the guide structure 3112 are adapted to the dimensions of the glide structure 212. The movable body 211 defines a first inclined surface 21101, and an included angle between the first inclined surface 21101 and the upper surface of the movable body 211 is an obtuse angle. The guide structure 3112 is designed to be inclined in a direction corresponding to the direction in which the first inclined surface 21101 is inclined. The connection operation control member 40 defines a first contact surface 401, and the first contact surface 401 is configured to be attached to the first inclined surface 21101. When the connecting operation control member 40 is driven by the first mold component 11 to apply a force to the movable member 21, the first contact surface 401 is parallel to the first inclined surface 21101. The connection operation control member 40 is configured to push the movable body 211 to slide along the guide structure 3112 to approach the support member 121, and when the movable body 211 is not pushed by the connection operation control member 40, the movable body 211 slides along the guide structure 3112 to move away from the support member 121 under the action of gravity.

Preferably, the guide structure 3112 is implemented as a rib provided on the guide body 3111, the sliding structure 212 is implemented as a groove formed on the movable body 211, the rib having a size adapted to the groove, the rib being slidably mounted in the groove so that the movable body 211 is pushed by the connection operation control member 40, and the movable body 211 can move along the rib.

As a deformable matter, the guide structure 3112 is implemented as a groove formed in the guide body 3111, and the slide structure 212 is implemented as a rib provided to the movable body 211, the rib having a size adapted to the groove, the rib being slidably mounted to the groove so that the movable body 211 is pressed by the connection operation control member 40, and the movable body 211 can move along the groove.

It should be noted that when the first mold assembly 11 drives the connection operation control member 40 to move downward to approach the movable member 21, the first contact surface 401 of the connection operation control member 40 is attached to the first inclined surface 21101, and the connection operation control member 40 applies pressure to the movable member 21, so that the movable member 21 moves along the guide structure 3112 to the guide body 3111. When the first mold assembly 11 drives the connection operation control member 40 to move upward and away from the movable member 21, the movable member 21 is subjected to the action of its own weight, and the movable member 21 moves in the opposite direction along the guide body 3111, so as to reset the movable member 21.

It will be appreciated by those skilled in the art that the lateral distance between the high end and the bottom end of the first inclined surface 21101 can be designed to be different sizes so that the connecting-operation control member 40 can push the movable body 211 to move along the guide body 3111 differently, thereby satisfying clamping of the workpiece 90 with different lateral sizes.

Specifically, the greater the transverse distance between the high end and the bottom end of the first inclined surface 21101, the longer the stroke of the connecting and operating control member 40 pushing the movable body 211 along the guide body 3111 is, so as to satisfy the clamping of the workpiece 90 of small transverse dimension; the smaller the transverse distance between the high end and the bottom end of the first inclined surface 21101, the shorter the stroke of the connecting-operation control member 40 pushing the movable body 211 along the guide body 3111 is, so as to satisfy the gripping of the workpiece 90 having a large transverse dimension.

It is noted that the lateral distance between the upper and lower ends of the guide structure 3112 can be designed to be different sizes so that the connecting-operation control member 40 can push the movable body 211 to perform different longitudinal movements, thereby satisfying the clamping of the workpieces 90 of different longitudinal sizes.

Specifically, based on the length of the guide structure 3112 being constant, the smaller the lateral distance between the high end and the bottom end of the guide structure 3112, the longer the longitudinal stroke of the connecting operation control member 40 for pushing the movable body 211 to move, so as to satisfy the clamping of the workpiece 90 having a large longitudinal dimension; the greater the transverse distance between the high end and the bottom end of the guide structure 3112, the smaller the longitudinal stroke of the connecting-operation control member 40 moving to push the movable body 211, so as to satisfy the gripping of the workpiece 90 having a small longitudinal dimension.

Further, the linkage assembly 20 further includes a linkage member 22, the linkage member 22 is mounted on the movable member 21, and the linkage member 22 is configured to abut against the workpiece 90.

Preferably, the linkage 22 is detachably mounted to the movable member 21, so that a worker can replace the linkage 22 with different specifications according to the actual size of the workpiece 90.

Preferably, the side of the linkage 22 facing away from the movable element 21 is made of a flexible material to avoid damage to the workpiece 90 when clamped.

Referring to fig. 4 to 5, in a preferred embodiment, two linkage assemblies 20 are provided, and the two linkage assemblies 20 are disposed oppositely. The number of the interlocking units 20 is the same as the number of the guide belt moving member 30, the connection operation control member 40 and the movement operation control member 50. Thus, when the first die assembly 11 drives the two connecting operation control members 40 to move down and press the two movable members 21, the two movable members 21 move toward the two guide members 311, so that the linking members 22 connected to the two movable members 21 approach each other to clamp the workpiece 90 at a predetermined position.

Referring to fig. 6, as a variant, the linkage assembly 20 is provided with one, the number of the linkage assemblies 20 is identical to the number of the connection operation control member 40 and the movement operation control member 50, and the linkage member 22 is implemented as an L-shaped push rod. Thus, when the first die assembly 11 drives the connecting operation control member 40 to move downward to press the movable member 21, the movable member 21 moves on the guide member 311, and drives the L-shaped push rod to approach the workpiece 90, and a part of the rod body of the L-shaped push rod is located adjacent to the workpiece 90, so as to push the workpiece 90 subsequently, so that the workpiece 90 moves.

In order to enable those skilled in the art to understand the present embodiment, at least one of the following embodiments and the corresponding drawings are only illustrated by providing two linkage assemblies 20, and those skilled in the art should understand that the present invention is not limited thereto.

Referring to fig. 7 to 8, the guide belt moving assembly 31 further includes a belt moving member 312, and the belt moving member 312 is mounted to the guide body 3111. The guide belt moving member 30 further includes a base 32 and a connecting structure 33, the connecting structure 33 being disposed between the guide belt moving assembly 31 and the base 32. The moving operation control member 50 is configured to control the guide member 311 and the belt moving member 312 to integrally slide a predetermined distance relative to the base 32, so that the linkage assembly 20 connected to the guide member 311 moves, and the workpiece 90 abutted to the linkage assembly 20 is driven to move, thereby realizing feeding. After the moving operation control member 50 drives the guide belt moving assembly 31 to move for a predetermined distance, the linkage assembly 20 and the connection operation control member 40 are staggered.

It should be noted that when the moving operation control member 50 controls the guide belt moving assembly 31 to slide along the base 32 for a predetermined distance, the guide belt moving assembly 31 drives the linkage assembly 20 to move synchronously, and in this process, the first inclined surface 21101 of the moving member 21 is always attached to the first contact surface 401 of the connection operation control member 40, so that the linkage assembly 20 clamps the workpiece 90, and further the workpiece 90 and the linkage assembly 20 move synchronously to realize feeding. After the linkage assembly 20 moves, the movable element 21 is no longer pushed by the connection operation control member 40, the movable element 21 moves along the guide structure 3112 in a direction away from the support member 121 on the guide body 3111 due to its own gravity, the movable element 21 releases the workpiece 90 to complete the transfer of the workpiece 90, and the movable element 21 is reset, so that the next round of feeding is facilitated.

The belt moving member 312 defines a second inclined surface 31201, and an included angle between the second inclined surface 31201 and the upper surface of the belt moving member 312 is an obtuse angle. The moving operation control member 50 defines a second contact surface 501, and the second contact surface 501 is configured to be attached to the second inclined surface 31201. When the moving-operation control member 50 is forced to the guide member 311 by the driving action of the first mold assembly 11, the second contact surface 501 is parallel to the second inclined surface 31201.

The connecting structure 33 includes a limiting groove 331 and a blocking block 332, the blocking block 332 is slidably mounted in the limiting groove 331, the size of the limiting groove 331 is adapted to the blocking block 332, and the limiting groove 331 and the blocking block 332 are respectively formed on the guide belt moving assembly 31 and the base 32.

Preferably, the limiting groove 331 is formed in the base 32, and the latching block 332 is disposed on the guide body 3111. Thus, when the belt moving member 312 is pushed by the moving operation control member 50, the belt moving member 312 drives the guide body 3111 to move along the limiting groove 331 to the base 32.

The stopper groove 331 is formed in the guide body 3111 to be deformable, and the latch 332 is provided in the base 32. Thus, when the belt moving element 312 is pressed by the moving operation control element 50, the belt moving element 312 drives the guide body 3111 to move along the latch 332 to the base 32.

The stopper 331 is formed in the belt moving member 312 to be deformable, and the latch 332 is provided in the base 32. Thus, when the belt moving member 312 is pushed by the moving operation control member 50, the belt moving member 312 moves along the latch 332 to the base 32, and the belt moving member 312 drives the guide body 3111 to move synchronously.

The stopper 331 is formed in the base 32 in a deformable manner, and the latch 332 is provided in the belt moving member 312. Thus, when the belt moving member 312 is pressed by the moving operation control member 50, the belt moving member 312 moves along the limiting groove 331 to the base 32, and the belt moving member 312 drives the guide body 3111 to move synchronously.

It will be understood by those skilled in the art that the lateral distance between the upper end and the lower end of the second inclined surface 31201 can be designed to have different lengths, so that the moving operation control member 50 can push the belt moving member 312 to move along the base 32 differently, thereby satisfying the requirement of transferring the workpieces 90 of different sizes to avoid the interference between the adjacent workpieces 90 due to the large size and short moving stroke of the workpieces 90.

Specifically, the greater the lateral distance between the high end and the bottom end of the second inclined surface 31201, the longer the stroke of the moving-operation control member 50 pushing the belt-moving member 312 along the base 32 is, to satisfy the transfer of the large-sized workpiece 90; the smaller the lateral distance between the high end and the low end of the second inclined surface 31201, the shorter the stroke of the link operation control member 40 pushing the belt moving member 312 along the base 32 is, so as to satisfy the transfer of the small-sized workpiece 90.

Preferably, the tape transfer member 312 is detachably attached to the guide member 311 so as to replace the tape transfer member 312 of a different size, thereby satisfying the transfer of the work pieces 90 of a different size.

Referring to fig. 3, further, the guide belt moving member 30 further includes a reset element 34, the reset element 34 is installed on the guide belt moving assembly 31, and the reset element 34 is used for driving the moved guide belt moving assembly 31 to reset.

Preferably, return element 34 is embodied as a spring.

The second mold assembly 12 includes a lower mold assembly 122, the support 121 is disposed on the lower mold assembly 122, and the lower mold assembly 122 is disposed opposite to the first mold assembly 11. The lower mold assembly 122 includes a lower mold 1221, and the supporter 121 is disposed on the lower mold 1221. The second mold assembly 12 has a placing cavity 1201 and an inlet 1202 communicating with the placing cavity 1201, the placing cavity 1201 is used for placing the guide belt moving assembly 30, and the placing cavity 1201 is formed in the lower mold member 1221.

Further, the lower mold assembly 122 further includes a connecting member 1222, the restoring member 34 is disposed between the connecting member 1222 and the guide belt moving assembly 31, and the connecting member 1222 is installed in the placing cavity 1201.

Preferably, the reset element 34 is disposed between the connecting element 1222 and the guide body 3111, and the connecting element 1222 is located on a side of the guide body 3111 away from the belt shifter 312. When the moving operation control member 50 drives the belt moving member 312 to move along the base 32, the guide body 3111 moves synchronously, and the guide body 3111 presses the reset member 34 to compress the reset member 34, so as to provide power for resetting the guide belt moving assembly 31.

It will be understood by those skilled in the art that the reset element 34 is disposed between the connecting element 1222 and the guide body 3111, and the connecting element 1222 is located on a side of the guide body 3111 adjacent to the belt shifter 312. The same object can be achieved, and the description is omitted.

As a deformable, the restoring element 34 is disposed between the connecting element 1222 and the belt moving element 312, and the connecting element 1222 is disposed on the same side of the second inclined surface 31201 of the belt moving element 312. When the moving operation control member 50 moves the belt moving member 312 along the base 32, the belt moving member 312 presses the restoring member 34 to compress the restoring member 34, so as to power the restoration of the guide belt moving assembly 31.

It will be understood by those skilled in the art that the restoring member 34 is disposed between the connecting member 1222 and the belt moving member 312, and the connecting member 1222 is disposed at the opposite side of the second inclined surface 31201 of the belt moving member 312. The same object can be achieved, and the description is omitted.

Referring to fig. 1 to 2, the second mold assembly 12 further includes a lower pad 123, the lower pad 123 is mounted to the lower mold 1221, the lower pad 123 and the lower mold 1221 form the placing cavity 1201, and the lower pad 123 is configured to support the guide belt moving member 30 and the connecting member 1222.

The first mold assembly 11 includes an upper mold member 111, an upper clamp member 112 and a stripping member 113, the upper clamp member 112 is located between the upper mold member 111 and the stripping member 113, and the connecting operation control member 40 and the moving operation control member 50 are mounted to the upper clamp member 112. When the first mold assembly 11 moves down to close to the second mold assembly 12, the lower mold member 1221 is located between the stripper 113 and the lower pad 123.

The use method of the automatic feeding type die comprises the following steps:

(A) The first mold assembly 11 moves down close to the second mold assembly 12;

(B) The two connecting operation control members 40 move along with the first die assembly 11, and the two connecting operation control members 40 press the two linkage assemblies 20, so that the two linkage assemblies 20 move close to each other and move upwards along the guide belt moving assembly 31 to clamp the workpiece 90 at a predetermined position;

(C) The two moving operation control members 50 move along with the first mold assembly 11, and the two moving operation control members 50 squeeze the two guide belt moving assemblies 31, so that the guide belt moving assemblies 31 move along the base 32, and at this time, the guide belt moving assemblies 31 drive the linkage assemblies 20 to move synchronously, so as to drive the workpiece 90 clamped on the linkage assemblies 20 to move.

(D) After the linkage assembly 20 moves, the linkage assembly 20 is no longer extruded by the connecting operation control part 40, and the linkage assembly 20 moves downwards along the guide belt moving assembly 31 under the action of self gravity and moves reversely, so that the clamping of the workpiece 90 is released;

(E) The first mold assembly 11 moves upward and away from the second mold assembly 12, the first mold assembly 11 drives the connecting operation control member 40 and the moving operation control member 50 to move synchronously, and at this time, the linkage assembly 20 and the guide belt moving assembly 31 are reset under the action of the resetting member 34.

It will be understood by those skilled in the art that the embodiments of the present invention as described above and shown in the drawings are given by way of example only and are not limiting of the present invention. The advantages of the present invention are complete and effective. The functional and structural principles of the present invention have been shown and described in the embodiments without departing from the principles, embodiments of the present invention may have any deformation or modification.

Claims (10)

1. Automatic pay-off type mould for shift at least a work piece, its characterized in that, automatic pay-off type mould includes:

a die member including a first die assembly and a second die assembly, the first die assembly being configured to move up and down relative to the second die assembly, the second die assembly including a support for supporting the workpiece;

at least one linkage assembly, wherein the linkage assembly is used for abutting against the workpiece;

at least one guide belt moving component, wherein the guide belt moving component comprises a guide belt moving component, and the linkage component is slidably arranged at the top of the guide belt moving component;

at least one connecting operation control piece, wherein the connecting operation control piece is arranged opposite to the linkage component, the connecting operation control piece and the linkage component are respectively arranged on the first die component and the second die component, and when the distance between the first die component and the second die component is gradually reduced, the connecting operation control piece controls the linkage component to move close to the supporting piece along the guide belt moving component so as to enable the linkage component to abut against the workpiece;

the connecting operation control piece and the moving operation control piece are arranged on the same side, when the distance between the first die assembly and the second die assembly is gradually reduced, the moving operation control piece controls the guide belt moving assembly to move for a preset distance, and the movement track of the guide belt moving assembly and the movement track of the linkage assembly controlled by the connecting operation control piece are crossed, so that the linkage assembly connected to the guide belt moving assembly drives the workpiece to move.

2. The automatic feed type mold according to claim 1, wherein the link assembly is mounted to the second mold assembly, the connecting operation control member and the moving operation control member are both mounted to the first mold assembly, the guide belt moving assembly includes a guide member, the link assembly includes a movable member, and the connecting operation control member is configured to control the movable member to slide along the guide member to approach the support member.

3. The automatic feed type mold according to claim 2, wherein the movable member includes a movable body and a slide structure, the slide structure is formed on the movable body, the guide member includes a guide body and a guide structure, the guide structure is formed on the guide body, a size of the guide structure is adapted to a size of the slide structure, the movable body defines a first inclined surface, an included angle between the first inclined surface and an upper surface of the movable body is an obtuse angle, the guide structure is designed to be inclined and an inclined direction thereof is consistent with an inclined direction of the first inclined surface, the connection operation control member defines a first contact surface, the first contact surface is disposed to be attachable to the first inclined surface, the first contact surface is parallel to the first inclined surface when the connection operation control member is urged by a driving force of the first mold assembly against the movable member, the connection operation control member is disposed to urge the movable slide body to approach the support member along the guide structure, and the movable body is away from the slide structure along the guide structure under a gravity force when the movable body is not urged by the connection operation control member.

4. The mold of claim 3, wherein the guide structure is implemented as a rib provided to the guide body, and the slide structure is implemented as a groove formed in the movable body, the rib being sized to fit into the groove, the rib being slidably mounted in the groove.

5. The automatic feeding type mold as claimed in claim 4, wherein the linkage member further includes a linkage member, the linkage member is mounted to the movable member, the linkage member is configured to abut against the workpiece, the linkage member is detachably mounted to the movable member, and a side of the linkage member away from the movable member is implemented as a flexible material.

6. The automatic feeding type mold as claimed in claim 5, wherein there is one linkage member, the number of the linkage members is identical to the number of the connection operation control member and the movement operation control member, and the movable member is implemented as an L-shaped push rod.

7. The automatic feed type mold according to claim 5, wherein there are two of said interlocking members, and two of said interlocking members are disposed oppositely, and the number of said interlocking members is kept in agreement with the number of said guide belt moving member, said connecting operation control member and said moving operation control member.

8. The automatic feed type mold according to claim 7, wherein the guide belt moving unit further includes a belt moving member, the belt moving member is mounted to the guide body, the guide belt moving member further includes a base and a connecting structure, the connecting structure is provided between the guide belt moving unit and the base, the moving operation control member is provided to control the guide member and the belt moving member to integrally slide a predetermined distance with respect to the base, the link assembly is staggered with respect to the connecting operation control member after the moving operation control member drives the guide belt moving unit to move the predetermined distance, the belt moving member defines a second inclined surface, an included angle between the second inclined surface and an upper surface of the belt moving member is an obtuse angle, the moving operation control member defines a second contact surface, the second contact surface is provided to be capable of being attached to the second inclined surface, the second contact surface is parallel to the second inclined surface when the moving operation member is driven by the first mold unit, the second contact surface is forced to be parallel to the guide member, the connecting structure includes a stopper groove and a stopper, the stopper is slidably mounted to the stopper groove, the stopper groove is adapted to the size of the guide belt moving member and the stopper groove, and the base, and the stopper member is adapted to the size of the guide belt moving member.

9. The automatic feed type mold according to claim 8, wherein the guide belt moving member further includes a returning member, the returning member being mounted to the guide belt moving member, the returning member being adapted to return the moved guide belt moving member, the second mold unit includes a lower mold unit, the support member being provided to the lower mold unit, the lower mold unit being disposed opposite to the first mold unit, the lower mold unit includes a lower mold unit, the support member being provided to the lower mold unit, the second mold unit has a placement chamber for placing the guide belt moving member and an inlet communicating with the placement chamber, the placement chamber being formed in the lower mold unit, the lower mold unit further includes a connecting member, the reset piece is arranged between the connecting piece and the guide belt moving assembly, the connecting piece is installed in place the chamber, the second die assembly further comprises a lower cushion piece, the lower cushion piece is installed in the lower die piece, the lower cushion piece and the lower die piece form the place chamber, the lower cushion piece is used for supporting the guide belt moving member and the connecting piece, the first die assembly comprises an upper die piece, an upper clamping piece and a stripping piece, the upper clamping piece is located between the upper die piece and the stripping piece, the connecting operation control piece and the moving operation control piece are both installed in the upper clamping piece, when the first die assembly moves downwards to be close to the second die assembly, the lower die piece is located between the stripping piece and the lower cushion piece.

10. The feeding mechanism in mould for shift at least a work piece, its characterized in that, the feeding mechanism in mould includes:

at least one linkage assembly for abutting against the workpiece;

at least one guide belt moving component, wherein the guide belt moving component comprises a guide belt moving component, and the linkage component is slidably arranged at the top of the guide belt moving component;

at least one connecting operation control piece, wherein the connecting operation control piece is arranged opposite to the linkage component, and the connecting operation control piece can control the linkage component to move a preset distance along the guide belt moving component in a downward moving mode so as to enable the linkage component to abut against the workpiece;

the connecting operation control piece and the moving operation control piece are arranged on the same side, the moving operation control piece can be arranged to control the guide belt moving assembly to move for a preset distance in a downward moving mode, and the motion track of the guide belt moving assembly and the motion track of the linkage assembly controlled by the connecting operation control piece are crossed so that the linkage assembly connected to the guide belt moving assembly drives the workpiece to move.

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