CN216324728U - Three-station die carrier - Google Patents

Abstract

The utility model discloses a three-station die carrier which comprises an upper die plate and a lower die plate, wherein a guide sleeve is arranged on the lower die plate, a guide pillar is arranged on the upper die plate, the guide pillar is inserted into the guide sleeve to enable the upper die plate to be connected with the lower die plate, three upper die blocks are arranged at the bottom of the upper die plate, three lower die blocks are arranged at the top of the lower die plate, the upper die blocks correspond to the lower die blocks, an upper die core is arranged in the center of each upper die block, a lower die core is arranged in the center of each lower die block, an upper ejector rod is arranged above the upper die core, and a lower ejector rod is arranged below the lower die core. The utility model has reasonable and ingenious structural design, the steel billet is placed in the die carrier, the steel billet is sequentially molded from the first group of modules to the third group of modules, after each group of modules is molded, the semi-finished product is positioned by the lower ejector rod, and the semi-finished product is moved to the next group of modules by the manipulator, so the working efficiency is high, and the heat loss is small.

Description

Three-station die carrier

Technical Field

The utility model relates to a three-station die carrier.

Background

The shaping of gear needs the billet to carry out the mould pressing a bit, and the mould that has mostly single-station is currently, can only carry out the mould pressing of a gear once to need to trade the station and carry out the mould pressing of higher accuracy, consume time, because mould pressing has certain requirement to the temperature of part at every turn simultaneously, consequently can cause a large amount of thermal losses.

SUMMERY OF THE UTILITY MODEL

The utility model relates to a three-station die carrier which can be used for carrying out three-time die pressing simultaneously, has high working efficiency and saves energy.

In order to realize the purpose, the structure adopted by the utility model is as follows: the three-station die carrier comprises an upper die plate and a lower die plate, wherein a guide sleeve is arranged on the lower die plate, the upper die plate is provided with a guide pillar, the guide pillar is inserted into the guide sleeve to enable the upper die plate to be connected with the lower die plate, three upper modules are arranged at the bottom of the upper die plate, three lower modules are arranged at the top of the lower die plate corresponding to the positions of the upper modules, the upper modules correspond to the lower modules to form three groups of modules, each upper module is provided with an upper die pressing block, an upper die sleeve is arranged below the upper die pressing block, the center of the upper die sleeve is provided with an upper die core, each lower module is provided with a lower die holder, the lower die sleeve is arranged on the lower die holder, and the center of the lower die sleeve is provided with a lower die core.

An upper ejector rod is arranged above the upper die core, and a lower ejector rod is arranged below the lower die core.

The beneficial effects are as follows: the utility model has reasonable and ingenious structural design, the steel billet is placed in the die carrier, the steel billet is sequentially molded from the first group of modules to the third group of modules, after each group of modules is molded, the semi-finished product is positioned by the lower ejector rod, and the semi-finished product is moved to the next group of modules by the manipulator, so the working efficiency is high, and the heat loss is small.

Drawings

The utility model will now be described, by way of example, with reference to the accompanying drawings, in which:

FIG. 1 is a side view block diagram of the present invention;

fig. 2 is a cross-sectional structural view of the present invention.

Detailed Description

All of the features disclosed in this specification, or all of the steps in any method or process so disclosed, may be combined in any combination, except combinations of features and/or steps that are mutually exclusive.

Any feature disclosed in this specification (including any accompanying claims, abstract and drawings), may be replaced by alternative features serving equivalent or similar purposes, unless expressly stated otherwise. That is, unless expressly stated otherwise, each feature is only an example of a generic series of equivalent or similar features.

The three-station die set shown in fig. 1 and 2 comprises an upper die plate 2 and a lower die plate 1, wherein a guide sleeve 6 is arranged on the lower die plate 1, the upper die plate 2 is provided with a guide pillar 5, the guide pillar 5 is inserted into the guide sleeve 6 to enable the upper die plate 2 to be connected with the lower die plate 1, the top of the upper die plate 2 is connected with a pressing device, three upper die blocks 4 are arranged at the bottom of the upper die plate 2, three lower die blocks 3 are arranged at positions, corresponding to the upper die blocks 4, at the top of the lower die plate 1, three groups of the upper die blocks 4 and the lower die blocks 3 are correspondingly formed, each upper die block 4 is provided with an upper die block 41, an upper die sleeve 43 is arranged below the upper die block 41, an upper die core 42 is arranged in the center of the upper die sleeve 43, a lower die base 31 is arranged on each lower die block 3, a lower die sleeve 33 is arranged on the lower die base 31, a lower die core 32 is arranged in the center of the lower die sleeve 33, and the three groups of the pre-forging die cores, the finish-forging die cores and the trimming die cores are sequentially arranged from left to right.

An upper mandril 44 is arranged above the upper mold core 42, and a lower mandril 34 is arranged below the lower mold core 32.

The utility model has reasonable and ingenious structural design, the steel billet is placed in the die carrier, the steel billet is sequentially molded from the first group of modules to the third group of modules, after each group of modules is molded, the semi-finished product is positioned by the lower ejector rod, and the semi-finished product is moved to the next group of modules by the manipulator, so the working efficiency is high, and the heat loss is small.

The utility model is not limited to the foregoing embodiments. The utility model extends to any novel feature or any novel combination of features disclosed in this specification and any novel method or process steps or any novel combination of features disclosed.

Claims (2)

1. The three-station die carrier comprises an upper die plate and a lower die plate, wherein a guide sleeve is arranged on the lower die plate, the upper die plate is provided with a guide pillar, the guide pillar is inserted in the guide sleeve to connect the upper die plate and the lower die plate, and the three upper die blocks are arranged at the bottom of the upper die plate, the three lower die blocks are arranged at the top of the lower die plate corresponding to the upper die blocks, the upper die blocks and the lower die blocks correspond to form three groups of modules, each upper die block is provided with an upper die pressing block, an upper die sleeve is arranged below the upper die pressing block, the center of the upper die sleeve is provided with an upper die core, each lower die block is provided with a lower die base, the lower die sleeve is arranged on the lower die base, and the center of the lower die sleeve is provided with a lower die core.

2. The three-station die carrier of claim 1, wherein an upper ejector rod is arranged above the upper die core, and a lower ejector rod is arranged below the lower die core.

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