CN214349368U - Forging die for processing electric energy storage guide rod and electric energy storage guide rod - Google Patents

Abstract

The utility model relates to the technical field of forging dies, and discloses a forging die for processing an electrical energy storage guide rod and the electrical energy storage guide rod, which comprises an upper die, a lower die, a first punching rod, a second punching rod, a first ejection mechanism and a second ejection mechanism, wherein blanks of the two guide rods are simultaneously placed in a die cavity, the end parts of the two guide rods are ensured to be abutted, then the upper die is driven to move downwards to be matched with the lower die, so that the forging forming of a reinforcing section and a guide section on the guide rods is realized, then the horizontal movement of the first punching rod and the second punching rod is driven, guide holes are punched on rod bodies of the guide rods through punches on the first punching rod and the second punching rod, so that two products which can be formed at one time have higher processing efficiency, materials can be saved by punching the guide holes through the punches, the waste is avoided, and the flash can be reduced by combining the forging forming and punching, the product quality is ensured.

Description

Forging die for processing electric energy storage guide rod and electric energy storage guide rod

Technical Field

The utility model relates to a forge the technical field of mould, especially relate to a forge mould and electric energy storage guide bar for processing electric energy storage guide bar.

Background

The switch that electric energy storage guide bar generally was used for the switch board through the cover is equipped with a spring on the guide bar, and the elastic action power of spring is used for realizing the break-make electricity of switch on the guide bar.

The existing electric energy storage guide rod is generally formed by machining, more materials are easily wasted due to the structural characteristics of the guide rod, the machining efficiency is low, and more flashes are easily generated in the machining process.

Disclosure of Invention

The utility model aims at providing a forging mould and electric energy storage guide bar for processing electric energy storage guide bar to the current electric energy storage guide bar of solution adopts the easy extravagant more material of machine tooling, and machining efficiency is lower moreover, produces the problem of more overlap easily in the course of working.

In order to solve the problem, the utility model provides a forge mould for processing electric energy storage guide bar, including last mould, lower mould, first towards stick, second towards stick, first ejection mechanism and second ejection mechanism, be equipped with on the lower mould and be used for placing the die cavity of electric energy storage guide bar blank, the upper end of lower mould is equipped with the boss, the lower extreme of going up the mould be equipped with the corresponding cavity of boss, first towards the stick with the second towards the stick to be located the both sides of die cavity, just first towards the stick with the second towards the stick front end and is equipped with the drift that is used for the shaping guiding hole, first ejection mechanism with second ejection mechanism locates respectively go up the mould with in the lower mould.

Further, the upper end of the upper die is provided with a first mounting groove, the first ejection mechanism comprises a first seat body, a first ejector rod and a first spring, the first seat body is located in the first mounting groove, the first ejector rod is slidably arranged in the upper die, one end of the first ejector rod is connected with the first seat body, the other end of the first ejector rod can slidably extend into the die cavity, the first spring is sleeved on the first ejector rod, and two ends of the first ejector rod are respectively abutted against the first seat body and the first mounting groove.

Furthermore, a second mounting groove is formed in the lower end of the lower die, the second ejection mechanism comprises a second seat body, a second ejector rod and a second spring, the second seat body is located in the second mounting groove, the second ejector rod is slidably arranged in the lower die, one end of the second ejector rod is connected with the second seat body, the other end of the second ejector rod can slidably extend into the die cavity, the second spring is sleeved on the second ejector rod, and two ends of the second spring are respectively abutted against the second seat body and the second mounting groove.

Furthermore, a first clamping groove is formed in the outer wall of the upper die, and a second clamping groove is formed in the outer wall of the lower die.

Furthermore, the electric energy storage guide rod comprises an end head and a rod body connected to the end head, the end head is arranged in a conical shape extending outwards from the rod body, round platforms are convexly arranged on two sides of the end head respectively, a guide hole is formed in the rod body along the axial direction of the rod body, the rod body comprises a reinforcing section and a guide section, the reinforcing section is connected with the end head, and the size of the guide section is smaller than that of the reinforcing section.

Furthermore, a plurality of reinforcing ribs are arranged on the peripheral wall of the reinforcing section at intervals and uniformly.

Further, the reinforcing bead is disposed along an axial direction of the reinforcing segment.

The utility model provides a forging mould for processing electric energy storage guide bar, which comprises an upper die, the lower mould, first towards the stick, the second dashes the stick, first ejection mechanism and second ejection mechanism, place the blank of two guide bars simultaneously in the die cavity, and guarantee that the tip of two guide bars wants to support and lean on, then go up the mould through the drive and cooperate with the lower mould down, realize the forging shaping of strengthening section and guide section on the guide bar, then dash excellent horizontal motion through first towards stick of drive and second, dash out the guiding hole through first drift that dashes on stick and the second towards the stick on the body of rod of guide bar, thus, its machining efficiency of one-shot two products of formability is higher, it can save material to dash out the guiding hole through the drift, avoid extravagant, and combine the reducible overlap of shaping that punches a hole through forging shaping, guarantee product quality.

Drawings

Fig. 1 is a schematic structural diagram of a forging die for processing an electrical energy storage guide bar in an open die state according to an embodiment of the present invention.

Fig. 2 is a schematic structural diagram of a forging die for processing an electrical energy storage guide bar in a die assembly state according to an embodiment of the present invention.

Fig. 3 is a schematic structural diagram of a forging die for processing an electrical energy storage guide rod in an in-place state of a first punch rod and a second punch rod in an embodiment of the present invention.

Fig. 4 is a schematic structural diagram of a forging die for processing an electrical energy storage guide rod in an embodiment of the present invention.

Fig. 5 is a schematic sectional view along a-a in fig. 4.

Fig. 6 is a schematic front view of the electrical energy storage guide bar according to an embodiment of the present invention.

Fig. 7 is a schematic side view of the embodiment of the present invention for processing the electrical energy storage guide bar.

In the figure, 1, an upper die; 2. a lower die; 3. a first punch bar; 4. a second punch bar; 5. a first ejection mechanism; 6. a second ejection mechanism; 7. a guide bar; 11. a concave cavity; 12. a first mounting groove; 13. a first card slot; 21. a boss; 22. a second mounting groove; 23. a second card slot; 51. a first seat body; 52. a first ejector rod; 53. a first spring; 61. a second seat body; 62. a second ejector rod; 63. a second spring; 71. a tip; 72. a rod body; 711. a circular truncated cone; 721. a guide hole; 722. a reinforcement section; 723. a guide section; 724. and (5) reinforcing ribs.

Detailed Description

The following detailed description of the embodiments of the present invention is provided with reference to the accompanying drawings and examples. The following examples are intended to illustrate the invention, but are not intended to limit the scope of the invention.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "left", "right", "top", "bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present invention.

Combine shown in fig. 1~7, schematically show the utility model discloses a forging mould for processing electric energy storage guide bar of embodiment, including last mould 1, lower mould 2, first towards stick 3, the second towards stick 4, first ejection mechanism 5 and second ejection mechanism 6, be equipped with the die cavity that is used for placing electric energy storage guide bar 7 blank on the lower mould 2, the upper end of lower mould 2 is equipped with boss 21, the lower extreme of going up mould 1 is equipped with cavity 11 corresponding with boss 21, positioning accuracy can be guaranteed through the positioning assembly of boss 21 with cavity 11, improve product quality, first towards stick 3 and second towards the both sides that stick 4 is located the die cavity, and first towards stick 3 and second towards the 4 front ends of stick and be equipped with the drift that is used for the shaping guiding hole, first ejection mechanism 5 and second ejection mechanism 6 are located respectively in last mould 1 and lower mould 2.

Specifically, by using the multidirectional forging die in the embodiment, two guide rods 7 can be simultaneously machined and formed, blanks of the two guide rods 7 are simultaneously placed in a die cavity, the end portions of the two guide rods 7 are ensured to be abutted against each other, then the upper die 1 is driven to move downwards to be matched with the lower die 2, the forging and forming of the reinforcing section and the guide section on the guide rods 7 are realized, then the first punching rod 3 and the second punching rod 4 are driven to move horizontally, guide holes are punched on the rod bodies of the guide rods 7 through the punches on the first punching rod 3 and the second punching rod 4, the structural strength of the guide sections can be improved through the punch punching, after the machining is finished, the upper die 1 moves upwards, finished products are ejected and demoulded through the first ejection mechanism 5 and the second ejection mechanism 6, therefore, the machining efficiency of the two products which can be formed at one time is high, materials can be saved by punching the guide holes through the punches, and waste is avoided, and the flash can be reduced by combining forging forming with punching forming, and the product quality is ensured.

Further, the upper end of the upper die 1 is provided with a first mounting groove 12, the first ejection mechanism 5 includes a first seat body 51, a first ejector rod 52 and a first spring 53, the first seat body 51 is located in the first mounting groove 12, the first ejector rod 52 is slidably disposed in the upper die 1, one end of the first ejector rod 52 is connected to the first seat body 51, the other end of the first ejector rod 52 can slidably extend into the die cavity, the first spring 53 is sleeved on the first ejector rod 52, and two ends of the first ejector rod 52 are respectively abutted to the first seat body 51 and the first mounting groove 12, after forming is completed, the driving mechanism drives the first seat body 51 to move along the first mounting groove 12 to drive the first ejector rod 52 to slidably extend into the die cavity to eject the formed part, after ejection is completed, the driving force is removed, the first ejector rod 52 is reset under the restoring force of the first spring 53, the structure is simple, and the operation is convenient and labor-saving.

Similarly, the lower end of the lower die 2 is provided with a second mounting groove 22, the second ejection mechanism 6 includes a second seat body 61, a second ejector rod 62 and a second spring 63, the second seat body 61 is located in the second mounting groove 22, the second ejector rod 62 is slidably disposed in the lower die 2, one end of the second ejector rod 62 is connected to the second seat body 61, the other end of the second ejector rod 62 is slidably extended into the die cavity, the second spring 63 is sleeved on the second ejector rod 62, and two ends of the second spring are respectively abutted against the second seat body 61 and the second mounting groove 22, so as to realize ejection and demolding of the second ejector rod 62.

In this embodiment, be equipped with first draw-in groove 13 on the outer wall of last mould 1, be equipped with second draw-in groove 23 on the outer wall of lower mould 2, realize going up the positioning assembly of mould 1 and lower mould 2 through clamp plate and first draw-in groove 13 and the cooperation installation of second draw-in groove 23, the die setting is convenient.

In this embodiment, the electrical energy storage guide rod 7 includes a head 71 and a rod 72 connected to the head 71, the head 71 is set in a tapered shape extending outward from the rod 72, two sides of the head 71 are respectively provided with a boss 711 in a protruding manner, a guide hole 721 is provided in the rod 72 along an axial direction thereof, the rod 72 includes a reinforcing section 722 and a guide section 723, the reinforcing section 722 is connected to the head 71, and the guide section 723 is smaller than the reinforcing section 722 in size. Further, in order to ensure the structural strength of the guide rod 7, several ribs 724 are provided on the outer circumferential wall of the reinforcing section 722 at intervals and uniformly, and preferably, the ribs 724 are provided along the axial direction of the reinforcing section 722.

It should be understood that the terms "first", "second", etc. are used herein to describe various information, but the information should not be limited to these terms, and these terms are only used to distinguish one type of information from another. For example, "first" information may also be referred to as "second" information, and similarly, "second" information may also be referred to as "first" information, without departing from the scope of the present invention.

The above is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of modifications and substitutions can be made without departing from the technical principle of the present invention, and these modifications and substitutions should also be regarded as the protection scope of the present invention.

Claims (7)

1. The utility model provides a forge mould for processing electric energy storage guide bar, its characterized in that includes and goes up mould, lower mould, first towards stick, second towards stick, first ejection mechanism and second ejection mechanism, be equipped with on the lower mould and be used for placing the die cavity of electric energy storage guide bar blank, the upper end of lower mould is equipped with the boss, the lower extreme of going up the mould be equipped with the corresponding cavity of boss, first towards the stick with the second towards the stick to be located the both sides of die cavity, just first towards the stick with the second towards the stick front end and is equipped with the drift that is used for the shaping guiding hole, first ejection mechanism with second ejection mechanism locates respectively go up the mould with in the lower mould.

2. The forging die for machining the electrical energy storage guide bar as recited in claim 1, wherein a first mounting groove is formed at an upper end of the upper die, the first ejection mechanism comprises a first seat body, a first ejector rod and a first spring, the first seat body is located in the first mounting groove, the first ejector rod is slidably disposed in the upper die, one end of the first ejector rod is connected with the first seat body, the other end of the first ejector rod can slidably extend into the die cavity, the first spring is sleeved on the first ejector rod, and two ends of the first spring respectively abut against the first seat body and the first mounting groove.

3. The forging die for machining the electrical energy storage guide bar as recited in claim 2, wherein a second mounting groove is formed at a lower end of the lower die, the second ejection mechanism includes a second seat body, a second ejector rod and a second spring, the second seat body is located in the second mounting groove, the second ejector rod is slidably disposed in the lower die, one end of the second ejector rod is connected to the second seat body, the other end of the second ejector rod is slidably extended into the die cavity, the second spring is sleeved on the second ejector rod, and two ends of the second spring respectively abut against the second seat body and the second mounting groove.

4. The forging die for machining the electric energy storage guide rod as claimed in claim 3, wherein a first clamping groove is formed in the outer wall of the upper die, and a second clamping groove is formed in the outer wall of the lower die.

5. The electric energy storage guide rod is characterized by comprising an end and a rod body connected to the end, wherein the end is arranged in a conical shape extending outwards from the rod body, round platforms are convexly arranged on two sides of the end respectively, a guide hole is formed in the rod body along the axial direction of the rod body, the rod body comprises a reinforcing section and a guide section, the reinforcing section is connected with the end, and the size of the guide section is smaller than that of the reinforcing section.

6. An electrical energy storage guide bar as claimed in claim 5 wherein the peripheral wall of the reinforcement section is provided with a plurality of ribs spaced apart and uniformly.

7. An electrical energy storage guide bar according to claim 6 wherein the reinforcing ribs are disposed in the axial direction of the reinforcing segments.

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