CN219096047U - Synchronous forming die about glass-frame riser ware - Google Patents

Abstract

The utility model relates to the technical field of dies, in particular to an up-down synchronous forming die of a glass lifter, which comprises a fixed frame, a placing seat and a processing assembly, wherein the processing assembly comprises a control block, a moving cone block, an upper supporting rod, an upper forming plate, a lower supporting rod, a lower forming plate, a sliding member and a control member, the moving cone block is fixedly connected with the control block, the upper supporting rod is in sliding connection with the fixed frame through the sliding member and is matched with the moving cone block, the upper forming plate is fixedly connected with the upper supporting rod, the lower supporting rod is in sliding connection with the fixed frame through the sliding member and is matched with the moving cone block, the lower forming plate is fixedly connected with the lower supporting rod, the control block is made to move leftwards through the work of the control member, so that the moving cone block is made to move leftwards, the upper supporting rod and the lower supporting rod are made to move oppositely, and the upper forming plate and the lower forming plate are made to synchronously form materials on the placing seat, and further the working efficiency is improved.

Description

Synchronous forming die about glass-frame riser ware

Technical Field

The utility model relates to the technical field of molds, in particular to an up-down synchronous forming mold of a glass lifter.

Background

The glass lifter is a lifting device for automobile door and window glass, and the current forming die does not have a buffering function, so that the die is easy to damage, and the die production efficiency is reduced.

Prior art CN213972764U discloses a glass-frame riser ware mold processing, including the bottom plate, first fixed block is fixed, the dead lever, the second fixed block, the lower bolster, damping spring, the shock attenuation board, the slider, locating plate and riser, through the top fixedly connected with lower bolster of second fixed block, damping spring fixedly connected with shock attenuation board is passed through to the bottom of lower bolster, the both sides fixedly connected with slider of shock attenuation board, slider sliding connection has played the absorbing effect in the inner chamber of spout, thereby can effectually prevent vibrations to bring the damage to the mould, thereby the production efficiency of mould has been improved.

The glass lifter needs to be processed up and down in the forming process, but processing dies in the prior art need to process the upper surface and the lower surface respectively, and the time required by forming is long, so that the working efficiency is low.

Disclosure of Invention

The utility model aims to provide an up-down synchronous forming die of a glass lifter, which aims to better reduce forming time and improve working efficiency.

In order to achieve the aim, the utility model provides an up-down synchronous forming die of a glass lifter, which comprises a fixing frame and a placing seat, wherein the placing seat is fixedly connected with the fixing frame and is positioned in the fixing frame,

also comprises a processing component which is used for processing the steel plate,

the processing assembly comprises a control block, a movable cone block, an upper supporting rod, an upper forming plate, a lower supporting rod, a lower forming plate, a sliding member and a control member, wherein the control block is in sliding connection with the fixed frame and is positioned on one side of the fixed frame, which is close to the placement seat, the movable cone block is fixedly connected with the control block and is positioned on one side of the control block, which is close to the placement seat, the upper supporting rod is in sliding connection with the fixed frame through the sliding member and is matched with the movable cone block and is positioned on one side of the fixed frame, which is close to the movable cone block, the upper forming plate is fixedly connected with the upper supporting rod and is positioned on one side of the upper supporting rod, which is close to the placement seat, the lower supporting rod is in sliding connection with the fixed frame and is positioned on one side of the fixed frame, which is close to the movable cone block, the lower forming plate is fixedly connected with the lower supporting rod and is positioned on one side of the lower supporting rod, which is close to the placement seat, and the control member controls the sliding of the control block.

The control component comprises a fixed rail and a driving piece, wherein the fixed rail is fixedly connected with the fixed frame, is in sliding connection with the control block and is positioned on one side of the fixed frame, which is close to the control block; the driving piece drives the control block to slide.

The driving piece comprises a driving rotating rod and a driving motor, wherein the driving rotating rod is rotationally connected with the fixed track, penetrates through the control block and is positioned on one side of the fixed track, which is close to the control block; the driving motor is fixedly connected with the fixing frame and is positioned on one side, close to the driving rotating rod, of the fixing frame, and the output end of the driving motor is connected with the driving rotating rod.

The sliding component comprises an upper sliding sleeve and a lower sliding rod, wherein the upper sliding sleeve is fixedly connected with the fixing frame, is in sliding connection with the upper supporting rod and is positioned at one side of the fixing frame, which is close to the upper supporting rod; the lower slide bar is fixedly connected with the lower support rod, is in sliding connection with the fixing frame and is positioned on one side of the lower support rod, which is close to the fixing frame.

The sliding component further comprises a reset spring, wherein the reset spring is respectively connected with the fixing frame and the lower supporting rod, and the reset spring is sleeved on the lower sliding rod.

According to the up-down synchronous forming die for the glass lifter, through the operation of the control component, the control block moves leftwards, so that the moving cone block moves leftwards, the upper supporting rod and the lower supporting rod move oppositely, the upper forming plate and the lower forming plate move oppositely, and the upper forming plate and the lower forming plate synchronously form materials on the placing seat, so that the working efficiency is improved.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below.

Fig. 1 is an overall construction diagram of a glass lifter up-down synchronous molding die according to a first embodiment of the present utility model.

Fig. 2 is a front view of a glass lifter up-down synchronous molding die of a first embodiment of the present utility model.

Fig. 3 is an overall construction diagram of a glass lifter up-down synchronous molding die according to a second embodiment of the present utility model.

Fig. 4 is a front view of a glass lifter up-down synchronous molding die of a second embodiment of the present utility model.

In the figure: 101-fixing frame, 102-placing seat, 103-control block, 104-moving cone block, 105-upper supporting rod, 106-upper forming plate, 107-lower supporting rod, 108-lower forming plate, 109-fixing track, 110-driving rotating rod, 111-driving motor, 201-upper sliding sleeve, 202-lower sliding rod and 203-reset spring.

Detailed Description

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative and intended to explain the present utility model and should not be construed as limiting the utility model.

First embodiment

Referring to fig. 1 and 2, fig. 1 is an overall structure diagram of a glass lifter up-down synchronous molding die according to a first embodiment of the present utility model. Fig. 2 is a front view of a glass lifter up-down synchronous molding die of a first embodiment of the present utility model.

The utility model provides a synchronous forming die for up and down of a glass lifter, which comprises a die body, a die body and a die body, wherein the die body is provided with a die body, the die body is provided with a die cavity, the die cavity is provided with a die cavity, the die: including mount 101, place seat 102 and processing subassembly, processing subassembly includes control block 103, removal taper piece 104, upper strut 105, upper shaping board 106, lower strut 107, lower shaping board 108, slide member and control member, the control member includes fixed track 109 and driver, the driver includes drive bull stick 110 and driving motor 111. The problem that the upper and lower surfaces need to be processed respectively is solved by the above scheme, and it can be understood that the above scheme can be used in the case of short molding time and can also be used for solving the problem that the lower strut 107 is difficult to reset.

In this embodiment, the placement base 102 is fixedly connected to the fixing frame 101 and is located in the fixing frame 101. The fixing frame 101 is in a shape like a Chinese character 'hui', the fixing frame 101 is arranged above the ground, the placing seat 102 is an L-shaped seat body, the placing seat 102 is fixedly arranged inside the fixing frame 101, and the placing seat 102 is used for placing materials to be formed.

The control block 103 is slidably connected with the fixing frame 101 through the control member and is located at a side of the fixing frame 101 close to the placement seat 102, the movable cone block 104 is fixedly connected with the control block 103 and is located at a side of the control block 103 close to the placement seat 102, the upper support rod 105 is slidably connected with the fixing frame 101 through the sliding member and is matched with the movable cone block 104 and is located at a side of the fixing frame 101 close to the movable cone block 104, the upper forming plate 106 is fixedly connected with the upper support rod 105 and is located at a side of the upper support rod 105 close to the placement seat 102, the lower support rod 107 is slidably connected with the fixing frame 101 through the sliding member and is matched with the movable cone block 104 and is located at a side of the fixing frame 101 close to the movable cone block 104, the lower forming plate 108 is fixedly connected with the lower support rod 107 and is located at a side of the lower support rod 107 close to the placement seat 102, and the control member controls the control block 103 to slide. The control block 103 is a rectangular block with a threaded through hole, the control block 103 is slidably connected with the fixing frame 101 through the control member and is installed in the fixing frame 101, the movable cone block 104 is a cone block with a left end larger than a right end, the movable cone block 104 is fixedly installed on the outer side of the control block 103, the upper support rod 105 is a rod body with an inclined bottom end, the upper support rod 105 is slidably connected with the fixing frame 101 through the sliding member and is installed above the movable cone block 104, the upper forming plate 106 is a rectangular plate, the upper forming plate 106 is fixedly installed on the right side of the upper support rod 105, the lower support rod 107 is a rod body with an inclined top end, the lower supporting rod 107 and the fixing frame 101 pass through the sliding member and are installed below the moving cone block 104, the lower forming plate 108 is a rectangular plate, the lower forming plate 108 is fixedly installed on the right side of the lower supporting rod 107, the control block 103 is moved leftwards by the operation of the control member, so that the moving cone block 104 is moved leftwards, the upper supporting rod 105 and the lower supporting rod 107 are moved oppositely, the upper forming plate 106 and the lower forming plate 108 are further moved oppositely, so that the upper forming plate 106 and the lower forming plate 108 synchronously form materials on the placing seat 102, and further the working efficiency is improved.

Secondly, the fixing rail 109 is fixedly connected with the fixing frame 101, is slidably connected with the control block 103, and is located at one side of the fixing frame 101 close to the control block 103; the driving member drives the control block 103 to slide. The fixed rail 109 is a rectangular rail with a rectangular control groove, the fixed rail 109 is fixedly installed inside the fixed frame 101 and is slidably connected with the control block 103 through an internal roller, the control block 103 is located in the rectangular control groove of the fixed rail 109, and the control block 103 slides along the fixed rail 109 through the operation of the driving member, so that the movement of the movable cone block 104 is more stable.

Again, the driving lever 110 is rotatably connected to the fixed rail 109, penetrates the control block 103, and is located at a side of the fixed rail 109 near the control block 103; the driving motor 111 is fixedly connected with the fixing frame 101 and is located at one side of the fixing frame 101 near the driving rotating rod 110, and an output end of the driving motor 111 is connected with the driving rotating rod 110. The drive bull stick 110 is the cylinder pole that has the external screw thread, the external screw thread of drive bull stick 110 with the screw thread through-hole cooperation of control block 103, drive bull stick 110 with fixed track 109 passes through the bearing and rotates to be connected, and runs through the screw thread through-hole the control piece, and transversely set up in the rectangular control groove of fixed track 109, driving motor 111 is direct current motor, driving motor 111 fixed mounting is in the tip of mount 101, driving motor 111's output with drive bull stick 110 fixed connection, through driving motor 111's work drives drive bull stick 110 rotates about, thereby drives control block 103 slides in the fixed track 109.

When the glass lifter of the present utility model is used for up-down synchronous molding, the driving motor 111 operates to drive the driving rotating rod 110 to rotate left and right, so as to drive the control block 103 to move left in the fixed rail 109, further move the moving cone block 104 leftwards, further move the upper support rod 105 and the lower support rod 107 oppositely, further move the upper molding plate 106 and the lower molding plate 108 oppositely, further synchronously mold the material on the placing seat 102 by the upper molding plate 106 and the lower molding plate 108, and further improve the working efficiency.

Second embodiment

Referring to fig. 3 and 4, fig. 3 is an overall structure diagram of a glass lifter up-down synchronous molding die according to a second embodiment of the present utility model. Fig. 4 is a front view of a glass lifter up-down synchronous molding die of a second embodiment of the present utility model. On the basis of the first embodiment, the sliding member includes an upper sliding sleeve 201, a lower sliding rod 202, and a return spring 203.

The upper sliding sleeve 201 is fixedly connected with the fixing frame 101, is slidably connected with the upper supporting rod 105, and is positioned at one side of the fixing frame 101 close to the upper supporting rod 105; the lower slide bar 202 is fixedly connected with the lower support rod 107, is slidably connected with the fixing frame 101, and is located at one side of the lower support rod 107 close to the fixing frame 101. The upper sliding sleeve 201 is a circular sleeve with a sliding groove at the bottom end, the upper sliding sleeve 201 is fixedly arranged at the top end of the fixing frame 101 and is in sliding connection with the upper supporting rod 105, the lower sliding rod 202 is a cylindrical rod, the top end of the lower sliding rod 202 is fixedly connected with the bottom end of the lower supporting rod 107, the bottom end of the lower sliding rod 202 is in sliding connection with the fixing frame 101 through a ball, and the upper supporting rod 105 and the lower supporting rod 107 can vertically slide relative to the fixing frame 101 through the connection effect of the upper sliding sleeve 201 and the lower sliding rod 202.

The return spring 203 is respectively connected with the fixing frame 101 and the lower supporting rod 107, and the return spring 203 is sleeved on the lower sliding rod 202. The return spring 203 is a cylindrical spring that can extend up and down, two ends of the return spring 203 are respectively connected with the fixing frame 101 and the lower support rod 107 through a spring mounting seat, and are sleeved on the outer side of the lower slide bar 202, when the lower support rod 107 slides, the return spring 203 extends and contracts, and the lower support rod 107 can return to an initial position under the action of the elasticity of the return spring 203.

The above disclosure is only a preferred embodiment of the present utility model, and it should be understood that the scope of the utility model is not limited thereto, and those skilled in the art will appreciate that all or part of the procedures described above can be performed according to the equivalent changes of the claims, and still fall within the scope of the present utility model.

Claims (5)

1. The up-down synchronous forming die of the glass lifter comprises a fixing frame and a placing seat, wherein the placing seat is fixedly connected with the fixing frame and is positioned in the fixing frame,

also comprises a processing component which is used for processing the steel plate,

the processing assembly comprises a control block, a movable cone block, an upper supporting rod, an upper forming plate, a lower supporting rod, a lower forming plate, a sliding member and a control member, wherein the control block is in sliding connection with the fixed frame and is positioned on one side of the fixed frame, which is close to the placement seat, the movable cone block is fixedly connected with the control block and is positioned on one side of the control block, which is close to the placement seat, the upper supporting rod is in sliding connection with the fixed frame through the sliding member and is matched with the movable cone block and is positioned on one side of the fixed frame, which is close to the movable cone block, the upper forming plate is fixedly connected with the upper supporting rod and is positioned on one side of the upper supporting rod, which is close to the placement seat, the lower supporting rod is in sliding connection with the fixed frame and is positioned on one side of the fixed frame, which is close to the movable cone block, the lower forming plate is fixedly connected with the lower supporting rod and is positioned on one side of the lower supporting rod, which is close to the placement seat, and the control member controls the sliding of the control block.

2. The glass lifter up-down synchronous molding die according to claim 1, wherein,

the control component comprises a fixed rail and a driving piece, wherein the fixed rail is fixedly connected with the fixed frame, is in sliding connection with the control block and is positioned at one side of the fixed frame, which is close to the control block; the driving piece drives the control block to slide.

3. The glass lifter up-down synchronous molding die according to claim 2, wherein,

the driving piece comprises a driving rotating rod and a driving motor, wherein the driving rotating rod is rotationally connected with the fixed track, penetrates through the control block and is positioned at one side of the fixed track, which is close to the control block; the driving motor is fixedly connected with the fixing frame and is positioned on one side, close to the driving rotating rod, of the fixing frame, and the output end of the driving motor is connected with the driving rotating rod.

4. The glass lifter up-down synchronous molding die according to claim 1, wherein,

the sliding component comprises an upper sliding sleeve and a lower sliding rod, wherein the upper sliding sleeve is fixedly connected with the fixing frame, is in sliding connection with the upper supporting rod and is positioned at one side of the fixing frame, which is close to the upper supporting rod; the lower slide bar is fixedly connected with the lower support rod, is in sliding connection with the fixing frame and is positioned on one side of the lower support rod, which is close to the fixing frame.

5. The glass lifter up-down synchronous molding die of claim 4, wherein,

the sliding component further comprises a reset spring, wherein the reset spring is respectively connected with the fixing frame and the lower support rod, and the reset spring is sleeved on the lower slide rod.

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