CN222448219U - A modular splicing high-strength production mold frame - Google Patents

Abstract

The utility model relates to the technical field of production die frames, in particular to a module spliced high-strength production die frame which comprises a lower die frame and an upper die frame, wherein four guide rails are fixedly arranged on the upper surface of the lower die frame, four positioning holes are uniformly formed in the surface of the upper die frame, the sizes of the positioning holes are matched with those of the guide rails, an assembly structure is arranged on the surface of the lower die frame and comprises two connecting plates fixedly connected to the side wall of the lower die frame, sliding pins are connected inside the connecting plates in a sliding manner, guide grooves are formed in the surfaces of the sliding pins, clamping blocks are fixedly connected to the end sides of the sliding pins, and a plurality of jacks are uniformly formed in the side wall of the upper die frame. According to the utility model, by arranging the assembly structure, the quick assembly and disassembly work between the upper die frame and the lower die frame is facilitated, the efficiency of positioning and assembling between the upper die frame and the lower die frame is improved, and the efficiency of producing products is further improved.

Description

Module spliced type high-strength production die carrier

Technical Field

The utility model relates to the technical field of production die frames, in particular to a module splicing type high-strength production die frame.

Background

The production die carrier is a device for supporting and fixing the die, is generally used in the process of manufacturing, processing and assembling the die, is generally made of steel or aluminum, has a stable structure and enough bearing capacity, and can ensure that the die is kept stable and accurate in the production process.

One chinese patent with publication number CN218638543U discloses a module spliced high-strength production mould frame, which comprises a base, one side surface of the base is connected with a lower mould, one side surface of the lower mould is provided with a positioning mechanism, one side surface of the positioning mechanism is connected with an upper mould, one side surface of the upper mould is provided with an injection molding opening, and the other surface of the upper mould is provided with a fixing mechanism. This module concatenation formula high strength production die carrier, through the setting of recess, threaded rod, nut, connecting plate and rotation axis, when using, at first will go up the die sleeve and establish the surface at the locating lever, the rotation axis that rethread locating lever one end set up rotates the connecting plate, when rotating the position to the recess, establishes the connecting plate cover on the surface of threaded rod, at this moment again establishes the nut cover into the surface of threaded rod and carries out sliding connection with the threaded rod, when the nut slides the threaded rod bottom, just accomplished the installation and the fixed of whole die carrier.

The prior related technology has the defects that in the process of assembling an upper die frame and a lower die frame, the upper die frame and the lower die frame are fixed through bolts, and a worker needs to spend a long time to realize screwing operation of the bolts, so that the assembling operation of the upper die frame and the lower die frame can be realized, the operation process is complicated, and the assembling efficiency of the upper die frame and the lower die frame by the worker is reduced.

Therefore, the utility model provides a module splicing type high-strength production die carrier.

Disclosure of utility model

The utility model aims to solve the defect that in the prior art, quick assembly is inconvenient between an upper die carrier and a lower die carrier, and provides a module splicing type high-strength production die carrier.

In order to achieve the purpose, the module spliced high-strength production die frame comprises a lower die frame and an upper die frame, wherein four guide rails are fixedly arranged on the upper surface of the lower die frame, four positioning holes are uniformly formed in the surface of the upper die frame, the size of the positioning holes is matched with the size of the guide rails, an assembly structure is arranged on the surface of the lower die frame and comprises two connecting plates fixedly connected to the side walls of the lower die frame, sliding pins are connected inside the connecting plates in a sliding mode, guide grooves are formed in the surfaces of the sliding pins, clamping blocks are fixedly connected to the end sides of the sliding pins, and a plurality of jacks are uniformly formed in the side walls of the upper die frame.

The clamping blocks are inserted into the inner walls of the corresponding jacks on the upper die frame after the lower die frame and the upper die frame are moved to the mutually attached positions, so that the rapid assembly work between the lower die frame and the upper die frame is realized.

Preferably, the clamping block is of a T-shaped structure, and an inclined plane is arranged at the end side of the clamping block.

The effect achieved by the components is that the inclined plane of the clamping block has irreversible effect in the process of relative movement between the clamping block and the row of jacks.

Preferably, the surface of the sliding pin is sleeved with a spring, and two ends of the spring are fixedly connected with the clamping block and the connecting plate respectively.

The clamping blocks are inserted into the inner walls of the corresponding jacks on the upper die frame under the action of the elastic force of the springs on the connecting plates.

Preferably, the end side of the sliding pin is rotatably connected with a supporting rod.

The supporting rod has the advantage that the supporting rod facilitates the pulling work of the sliding pin.

Preferably, a preformed hole is formed in the surface of the connecting plate.

The above components have the effect that when the support rod rotates to the position corresponding to the preformed hole, the sliding pin is loosened, and the support rod can be sleeved into the inner side of the preformed hole.

Preferably, the surface of the lower die carrier is provided with a supporting structure, the supporting structure comprises two connecting pins, the side walls of the connecting pins are connected with sliding plates in a sliding mode, and the end sides of the sliding plates are fixedly connected with steel plates.

The upper die frame can be sleeved on the guide rail after the steel plates are moved to the position between the lower die frame and the upper die frame by sliding the sliding plate on the connecting pin before die assembly is required to be carried out between the upper die frame and the lower die frame, and the temporary supporting work of the upper die frame can be realized by the four steel plates.

Preferably, the inside rotation of steel sheet is connected with the pivot, the lateral wall fixedly connected with gyro wheel of pivot.

The component has the advantages that the two sliding plates are drawn, the roller wheels can move relatively with the upper die carrier, and the resistance of drawing the sliding plates is reduced.

To sum up:

1. according to the utility model, by arranging the assembly structure, the quick assembly and disassembly work between the upper die frame and the lower die frame is facilitated, the efficiency of positioning and assembling between the upper die frame and the lower die frame is improved, and the efficiency of producing products is further improved.

2. According to the utility model, by arranging the supporting structure, temporary supporting work of the upper die frame is facilitated when the upper die frame and the lower die frame are subjected to die assembly, and further the safety of die assembly between the upper die frame and the lower die frame is improved.

Drawings

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is an enlarged view of the utility model at A;

FIG. 3 is an enlarged view of the utility model at B;

Fig. 4 is a schematic view of the structure of the support structure according to the present utility model.

The illustration comprises 1, a lower die carrier, 2, a guide rail, 3, an upper die carrier, 4, a positioning hole, 5, an assembling structure, 51, an inserting hole, 52, a connecting plate, 53, a sliding pin, 54, a clamping block, 55, a spring, 56, a supporting rod, 57, a reserved hole, 58, a guide groove, 6, a supporting structure, 61, a connecting pin, 62, a sliding plate, 63, a steel plate, 64, a roller, 65 and a rotating shaft.

Detailed Description

Referring to FIG. 1, the utility model provides a technical scheme that a module spliced high-strength production die carrier comprises a lower die carrier 1 and an upper die carrier 3, wherein four guide rails 2 are fixedly arranged on the upper surface of the lower die carrier 1, four positioning holes 4 are uniformly formed in the surface of the upper die carrier 3, the size of the positioning holes 4 is matched with the size of the guide rails 2, an assembly structure 5 is arranged on the surface of the lower die carrier 1, and a supporting structure 6 is arranged on the surface of the lower die carrier 1.

The specific arrangement and function of the assembly structure 5 and the support structure 6 will be described in detail below.

Referring to fig. 1-3, in this embodiment, the assembly structure 5 includes two connection plates 52 fixedly connected to the side wall of the lower mold frame 1, a sliding pin 53 is slidably connected to the inside of the connection plates 52, a guide groove 58 is formed on the surface of the sliding pin 53, a clamping block 54 is fixedly connected to the end side of the sliding pin 53, and a plurality of insertion holes 51 are uniformly formed in the side wall of the upper mold frame 3. After the lower die carrier 1 and the upper die carrier 3 are moved to the mutually attached positions, the clamping blocks 54 are inserted into the inner walls of the corresponding jacks 51 on the upper die carrier 3, so that the rapid assembly work between the lower die carrier 1 and the upper die carrier 3 is realized. The clamping block 54 is of a T-shaped structure, and an inclined surface is arranged at the end side of the clamping block 54. By providing the inclined surface of the clip 54, the clip 54 has an irreversible effect in the process of relative movement with the row of insertion holes 51. The surface of the sliding pin 53 is sleeved with a spring 55, and two ends of the spring 55 are fixedly connected with the clamping block 54 and the connecting plate 52 respectively. The clamping block 54 is inserted into the inner wall of the corresponding jack 51 of the upper die carrier 3 under the elastic action of the spring 55 of the connecting plate 52. A support rod 56 is rotatably connected to the end side of the slide pin 53. The support bar 56 facilitates the pulling operation of the slide pin 53. The surface of the connection plate 52 is provided with a preformed hole 57. When the support rod 56 is rotated to a position corresponding to the preformed hole 57, the slide pin 53 is released, and the support rod 56 is fitted inside the preformed hole 57.

Referring to fig. 1 and 4, specifically, the support structure 6 includes two connection pins 61, a slide plate 62 is slidably connected to a side wall of the connection pins 61, and a steel plate 63 is fixedly connected to an end side of the slide plate 62. Before the die assembly is required to be carried out between the upper die frame 3 and the lower die frame 1, the sliding plate 62 on the connecting pin 61 is slid firstly, the steel plate 63 is moved to a position between the lower die frame 1 and the upper die frame 3, the upper die frame 3 can be sleeved on the guide rail 2, and the temporary supporting work of the upper die frame 3 can be realized by the four steel plates 63. The inside rotation of steel sheet 63 is connected with pivot 65, and pivot 65's lateral wall fixedly connected with gyro wheel 64. By pulling the two sliding plates 62, the roller 64 and the upper die frame 3 can move relatively, so that the resistance when the sliding plates 62 are pulled is reduced.

When the upper die frame 3 and the lower die frame 1 are required to be assembled, the supporting rod 56 is pulled firstly, so that the sliding pin 53 can be drawn in the connecting plate 52, when the supporting rod 56 rotates to a position corresponding to the reserved hole 57, the sliding pin 53 is loosened, the supporting rod 56 can be sleeved in the inner side of the reserved hole 57, the guide groove 58 plays a role in limiting the moving direction of the sliding pin 53, the horizontal drawing operation of the sliding pin 53 is facilitated, the positioning hole 4 on the upper die frame 3 is sleeved on the guide rail 2 on the lower die frame 1, the quick positioning operation of the upper die frame 3 and the lower die frame 1 can be realized, the jack 51 on the upper die frame 3 can be moved relative to the clamping block 54 in the process of relative movement between the upper die frame 3 and the lower die frame 1, and the inclined surface of the clamping block 54 is arranged, the clamping blocks 54 have irreversible action in the process of relative movement with the row of jacks 51, after the lower die frame 1 and the upper die frame 3 are moved to the mutually attached positions, the clamping blocks 54 can be inserted into the inner walls of the corresponding jacks 51 on the upper die frame 3 under the action of the elastic force of the springs 55 on the connecting plates 52, so that the rapid assembly work of the lower die frame 1 and the upper die frame 3 is realized, when the upper die frame 3 and the lower die frame 1 need to be opened, the sliding pins 53 can be drawn, the supporting rods 56 can be rotated to the positions facing the surfaces of the connecting plates 52, the temporary supporting work of the positions of the clamping blocks 54 after drawing can be realized, the rapid demoulding work of the upper die frame 3 and the lower die frame 1 is facilitated, the rapid disassembly work of the upper die frame 3 and the lower die frame 1 is facilitated by arranging the assembly structure 5, the positioning assembly efficiency of the upper die frame 3 and the lower die frame 1 is improved, thereby improving the production efficiency of the product.

Before the upper die frame 3 and the lower die frame 1 are required to be clamped, the sliding plate 62 on the connecting pin 61 is slid firstly, the steel plate 63 is moved to a position between the lower die frame 1 and the upper die frame 3, then the upper die frame 3 can be sleeved on the guide rail 2, the four steel plates 63 can realize temporary supporting work for the upper die frame 3, the phenomenon that the upper die frame 3 can be extruded between the lower die frame 1 and the upper die frame 3 by hands to easily cause industrial injury is avoided in the process of directly placing the upper die frame 3, after the upper die frame 3 is placed on the steel plate 63, the two sliding plates 62 can be drawn, the roller 64 and the upper die frame 3 can move relatively, the resistance when the sliding plate 62 is drawn is reduced, and after the roller 64 is completely drawn out from the position between the upper die frame 3 and the lower die frame 1, the clamping work for the upper die frame 3 and the lower die frame 1 can be realized, and the temporary supporting work for the upper die frame 3 when the upper die frame 3 and the lower die frame 1 are clamped is facilitated by arranging the supporting structure 6, and the safety of clamping the upper die frame 3 and the lower die frame 1 is improved.

In the description of the present utility model, unless explicitly stated or limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected, mechanically connected, electrically connected, directly connected, indirectly connected via an intervening medium, or in communication between two elements. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art in a specific case.

Claims (7)

1. The utility model provides a module concatenation formula high strength production die carrier, includes die carrier (1) and last die carrier (3), its characterized in that, the upper surface fixed mounting of die carrier (1) has four guide rails (2), four locating holes (4) have evenly been seted up on the surface of going up die carrier (3), the size of locating hole (4) and the size looks adaptation of guide rail (2), the surface of die carrier (1) is equipped with package assembly (5), package assembly (5) include two connecting plates (52) of fixed connection at die carrier (1) lateral wall down, the inside sliding connection of connecting plate (52) has slide pin (53), guide slot (58) have been seted up on the surface of slide pin (53), the terminal side fixedly connected with fixture block (54) of slide pin (53), a plurality of jack (51) have evenly been seted up to the lateral wall of going up die carrier (3).

2. The modular splice type high-strength production die carrier of claim 1, wherein the clamping blocks (54) are of a T-shaped structure, and inclined surfaces are arranged on the end sides of the clamping blocks (54).

3. The module splicing type high-strength production die carrier of claim 1, wherein the surface of the sliding pin (53) is sleeved with a spring (55), and two ends of the spring (55) are fixedly connected with the clamping block (54) and the connecting plate (52) respectively.

4. The modular splice type high-strength production die carrier as claimed in claim 1, wherein the end side of the sliding pin (53) is rotatably connected with a supporting rod (56).

5. The modular splice type high-strength production die carrier as claimed in claim 1, wherein the surface of the connecting plate (52) is provided with preformed holes (57).

6. The module splicing type high-strength production die frame according to claim 1, wherein a supporting structure (6) is arranged on the surface of the lower die frame (1), the supporting structure (6) comprises two connecting pins (61), sliding plates (62) are slidably connected to the side walls of the connecting pins (61), and steel plates (63) are fixedly connected to the end sides of the sliding plates (62).

7. The module splicing type high-strength production die carrier of claim 6, wherein a rotating shaft (65) is rotatably connected to the inside of the steel plate (63), and a roller (64) is fixedly connected to the side wall of the rotating shaft (65).