CN214639989U

CN214639989U - Multi-station hot die forging press for spiral bevel gear

Info

Publication number: CN214639989U
Application number: CN202120892175.3U
Authority: CN
Inventors: 凌伟
Original assignee: Chongqing Sanqi Machinery Manufacturing Co ltd
Current assignee: Chongqing Sanqi Machinery Manufacturing Co ltd
Priority date: 2021-04-28
Filing date: 2021-04-28
Publication date: 2021-11-09
Anticipated expiration: 2031-04-28

Abstract

The utility model belongs to the technical field of hot die forging, and discloses a multi-station hot die forging press for spiral bevel gears, which comprises a machine body, wherein an operation opening is arranged inside the machine body, the bottom end inside the operation opening is rotationally connected with two conveyor belts and a fixedly connected mounting plate, the two conveyor belts are respectively arranged on two sides of the mounting plate, a die plate groove is arranged at the top end of the mounting plate, an ejection device is arranged inside the die plate groove, a push rod is fixedly connected between the two conveyor belts and is arranged on the top end of the mounting plate, a motor is arranged inside the machine body, the conveyor belts and the push rod are arranged on the machine body, the conveyor belts are driven by the motor to rotate, the conveyor belts drive the push rod to move on the surface of the mounting plate, and scrap iron on the surface of the mounting plate is scraped by the push rod, thereby avoiding manual scrap iron cleaning and reducing labor cost and workload of workers, the working efficiency of the machine body is improved.

Description

Multi-station hot die forging press for spiral bevel gear

Technical Field

The utility model belongs to the technical field of the hot die forging, a spiral bevel gear multistation hot die forging press is disclosed.

Background

The hot die forging is to process heated metal into a required forge piece shape and size, is one of forging process technologies, and is mainly processed by a press; at present, the spiral bevel gear multistation hot die forging press is at work, and the module receives the slider extrusion can drop a large amount of iron fillings on the bottom plate, needs the manual work to clear up many times, unusual trouble to, iron fillings can be deepened in the gap among bottom plate internally mounted's ejecting device, cause ejecting device to block up or increase the frictional force between ejecting device and the bottom plate, influence ejecting device's normal use.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a spiral bevel gear multistation hot die forging press to solve the iron fillings that present spiral bevel gear multistation hot die forging press processing produced and need artifical clearance, unusual trouble, and iron fillings also can cause ejecting device to block up or increase ejecting device's frictional force, influence ejecting device's the problem of normal use.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a spiral bevel gear multistation hot die forging press, includes the organism, the operation mouth has been seted up to the inside of organism, the inside bottom of operation mouth is rotated and is connected with two conveyer belts and fixedly connected with mounting panel, two the conveyer belt is located the both sides of mounting panel respectively, the template groove has been seted up on the top of mounting panel, template inslot portion is provided with ejecting device, two fixedly connected with push rod between the conveyer belt, the push rod is located the top of mounting panel, the inside of organism is provided with the motor, the motor is located one side of operation mouth, and the motor rotates with the conveyer belt to be connected, the inside top of operation mouth is provided with forging and pressing device.

Preferably, ejecting device includes the ejector pin, the top groove has been seted up to template groove bottom, the extrusion groove has been seted up to the bottom of top groove one side, the inside sliding connection of top groove has the ejector pin, sliding connection has the voussoir in the extrusion groove, the bottom of voussoir top and ejector pin is the hypotenuse setting, and the bottom of voussoir top and ejector pin mutually supports, the pneumatic cylinder is installed to one side that the top groove was kept away from to the voussoir, pneumatic cylinder and one side fixed connection of extrusion inslot portion.

Preferably, the top ends of the two sides of the ejector rod are provided with first convex blocks, the two sides inside the top groove are provided with second convex blocks, the two second convex blocks are respectively located on the two sides of the ejector rod, and the two second convex blocks are respectively located above the two first convex blocks and are respectively matched with the two first convex blocks.

Preferably, a controller is installed on one side of the machine body and is located on one side of the operation opening.

Preferably, the forging and pressing device includes the slider, slider and operation mouth sliding connection, and the slider is located the top of mounting panel, the top sliding connection of slider has the transmission voussoir, transmission voussoir and the horizontal sliding connection of operation mouth, the both sides of the adjacent operation mouth of organism all rotate and are connected with the bent axle, two one side that the bent axle is relative all rotates and is connected with the connecting rod, two the connecting rod rotates with the both sides of transmission voussoir respectively and is connected, servo motor is installed to one side that the inside of organism is located the operation mouth, servo motor all rotates with two bent axles and is connected.

Preferably, the bottom end of the sliding block is coated with a wear-resistant coating and a heat dissipation coating, and the heat dissipation coating is located at the top end of the wear-resistant coating.

Compared with the prior art, the beneficial effects of the utility model are that:

(1) the utility model discloses set up conveyer belt and push rod on the organism, utilized the motor to drive the conveyer belt and rotate, the conveyer belt then drives the push rod and removes at the mounting panel surface to strike off the iron fillings on mounting panel surface through the push rod, thereby avoided artifical clearance iron fillings, reduced cost of labor and staff's burden, improved the work efficiency of organism.

(2) The utility model discloses set up voussoir and extrusion groove in the mounting panel in the organism, utilized the extrusion groove to avoid the top groove for iron fillings on the mounting panel directly fall to the bottom in top groove, avoid hydraulic pump drive's pneumatic cylinder to be infected with iron fillings, thereby hydraulic pump drive's pneumatic cylinder can normal operating in the time, can not receive iron fillings jam's influence.

Drawings

Fig. 1 is a schematic structural view of the present invention;

FIG. 2 is an enlarged view of a portion A of FIG. 1;

FIG. 3 is a schematic view showing the cooperation between the conveyor belt and the push rod according to the present invention;

FIG. 4 is a schematic structural view of the present invention;

in the figure: 1-body; 2-a crankshaft; 3-a connecting rod; 4-driving the wedge block; 5-an operation port; 6-a slide block; 7-a push rod; 8-mounting a plate; 9-a conveyor belt; 10-a template slot; 11-a first bump; 12-a second bump; 13-a mandril; 14-top groove; 15-extrusion groove; 16-a hydraulic cylinder; 17-wedges; 18-a controller; 19-a motor; 20-a heat dissipation coating; 21-wear resistant coating.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides the following technical solutions: a multi-station hot die forging press for a spiral bevel gear comprises a press body 1, wherein an operation opening 5 is formed in the press body 1, the bottom end of the interior of the operation opening 5 is rotatably connected with two conveyor belts 9 and a fixedly connected mounting plate 8, the two conveyor belts 9 are respectively positioned on two sides of the mounting plate 8, a template groove 10 is formed in the top end of the mounting plate 8, an ejection device is arranged in the template groove 10, a push rod 7 is fixedly connected between the two conveyor belts 9, the push rod 7 is positioned at the top end of the mounting plate 8, a motor 19 is arranged in the press body 1, the motor 19 is positioned on one side of the operation opening 5 and is rotatably connected with the conveyor belts 9, and a forging device is arranged at the top end of the interior of the operation opening 5;

the operation opening 5 is used for limiting the moving range of the sliding block 6 and the transmission wedge block 4, the conveyor belt 9 is used for driving the push rod 7 to move, the push rod 7 is used for scraping scrap iron on the surface of the mounting plate 8, the mounting plate 8 is used for stabilizing the template groove 10, the template groove 10 is used for placing processed objects, and the motor 19 is electrically connected with the controller 18 and used for driving the conveyor belt 9 to rotate.

Further, the ejection device comprises an ejector rod 13, an ejector groove 14 is formed in the bottom end of the template groove 10, an extrusion groove 15 is formed in the bottom end of one side of the ejector groove 14, the ejector rod 13 is connected inside the ejector groove 14 in a sliding mode, a wedge block 17 is connected inside the extrusion groove 15 in a sliding mode, the top end of the wedge block 17 and the bottom end of the ejector rod 13 are both arranged in a bevel edge mode, the top end of the wedge block 17 and the bottom end of the ejector rod 13 are matched with each other, a hydraulic cylinder 16 is installed on one side, far away from the ejector groove 14, of the wedge block 17, and the hydraulic cylinder 16 is fixedly connected with one side inside the extrusion groove 15;

the ejector rod 13 is used for ejecting a processed object in the template groove 10, the extrusion groove 15 is used for limiting the moving range of the wedge block 17, the ejector rod 13 can be lifted through the inclined edge of the wedge block 17, and the hydraulic cylinder 16 is in driving connection with the hydraulic pump and used for driving the wedge block 17 to move transversely.

Specifically, the top ends of two sides of the ejector rod 13 are both provided with first convex blocks 11, two sides inside the top groove 14 are both provided with second convex blocks 12, the two second convex blocks 12 are respectively located at two sides of the ejector rod 13, and the two second convex blocks 12 are respectively located above the two first convex blocks 11 and are respectively matched with the two first convex blocks 11;

the first projection 11 and the second projection 12 block each other in order to prevent the ejector pin 13 from completely escaping from the ejector groove 14.

It is worth to say that, a controller 18 is installed on one side of the machine body 1, and the controller 18 is located on one side of the operation opening 5;

the controller 18 is electrically connected to the power supply and is used for controlling each electrical device of the machine body 1.

Furthermore, the forging device comprises a slide block 6, the slide block 6 is in sliding connection with an operation opening 5, the slide block 6 is positioned above a mounting plate 8, the top end of the slide block 6 is in sliding connection with a transmission wedge block 4, the transmission wedge block 4 is in transverse sliding connection with the operation opening 5, two sides of the machine body 1 adjacent to the operation opening 5 are rotatably connected with crankshafts 2, one sides of the two crankshafts 2 opposite to each other are rotatably connected with connecting rods 3, the two connecting rods 3 are respectively rotatably connected with two sides of the transmission wedge block 4, a servo motor is arranged on one side of the machine body 1 positioned at the operation opening 5, and the servo motor is rotatably connected with the two crankshafts 2;

slider 6 is used for the extrusion forging to need the metal article of processing, transmission voussoir 4 is used for driving slider 6 and goes up and down, the top of transmission voussoir 4 and the inside top of operation mouth 5 all are the hypotenuse setting, when transmission voussoir 4 removed, the top of transmission voussoir 4 can slide along the inside top of operation mouth 5, utilize the hypotenuse to change transmission voussoir 4 direction of motion, bent axle 2 is used for driving connecting rod 3 and rotates, connecting rod 3 is used for connecting bent axle 2 and transmission voussoir 4, servo motor and 18 electric connection of controller, be used for driving bent axle 2 and rotate.

Specifically, the bottom end of the sliding block 6 is coated with a wear-resistant coating 21 and a heat dissipation coating 20, and the heat dissipation coating 20 is located at the top end of the wear-resistant coating 21;

the wear-resistant coating 21 is used to improve the wear resistance of the slider 6, and the heat-dissipating coating 20 is used to improve the heat-dissipating capability of the slider 6.

The controller 18 has the following model: 900U.

The motor 19 model is: GH 28-750-S.

The hydraulic cylinder 16 model is: FPY-10D.

The utility model discloses a theory of operation and use flow: when the utility model is used, a processed object is placed in the template groove 10, the servo motor is started to drive the crankshaft 2 to rotate, the crankshaft 2 drives the connecting rod 3 to rotate, and the connecting rod 3 drives the transmission wedge block 4 to transversely move in the operation opening 5, the transmission wedge block 4 drives the slide block 6 to lift in the operation opening 5, and the slide block 6 extrudes the processed object on the template groove 10;

the hydraulic pump is started to drive the hydraulic cylinder 16 to drive the wedge block 17 to move transversely, the wedge block 17 enters the top groove 14 from the extrusion groove 15 and drives the ejector rod 13 to ascend, part of the ejector rod 13 extends out of the top groove 14 and ejects a processed object in the template groove 10, then the starting motor 19 drives the conveyor belt 9 to rotate, the conveyor belt 9 drives the push rod 7 to move on the surface of the mounting plate 8, and scrap iron and the processed object at the top end of the mounting plate 8 are scraped.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a spiral bevel gear multistation hot die forging press, includes organism (1), its characterized in that: operation mouth (5) have been seted up to the inside of organism (1), the bottom of operation mouth (5) inside is rotated and is connected with two conveyer belts (9) and fixedly connected with mounting panel (8), two conveyer belt (9) are located the both sides of mounting panel (8) respectively, template groove (10) have been seted up on the top of mounting panel (8), inside ejecting device, two of being provided with in template groove (10) fixedly connected with push rod (7) between conveyer belt (9), push rod (7) are located the top of mounting panel (8), the inside of organism (1) is provided with motor (19), motor (19) are located one side of operation mouth (5), and motor (19) rotate with conveyer belt (9) and are connected, the inside top of operation mouth (5) is provided with the forging device.

2. The multi-station hot die forging press for spiral bevel gears according to claim 1, wherein: the ejection device comprises an ejector rod (13), an ejector groove (14) is formed in the bottom end of the template groove (10), an extrusion groove (15) is formed in the bottom end of one side of the ejector groove (14), the ejector rod (13) is connected to the inside of the ejector groove (14) in a sliding mode, a wedge block (17) is connected to the extrusion groove (15) in the sliding mode, the top end of the wedge block (17) and the bottom end of the ejector rod (13) are both arranged in a bevel edge mode, the top end of the wedge block (17) and the bottom end of the ejector rod (13) are matched with each other, a hydraulic cylinder (16) is installed on one side, away from the ejector groove (14), of the wedge block (17), and the hydraulic cylinder (16) is fixedly connected with one side of the inside of the extrusion groove (15).

3. The multi-station hot die forging press for spiral bevel gears according to claim 2, wherein: the top end of ejector pin (13) both sides all is provided with first lug (11), the inside both sides in apical trough (14) all are provided with second lug (12), two second lug (12) are located the both sides of ejector pin (13) respectively, and just two second lugs (12) are located the top of two first lugs (11) respectively to mutually support with two first lugs (11) respectively.

4. The multi-station hot die forging press for spiral bevel gears according to claim 1, wherein: a controller (18) is installed on one side of the machine body (1), and the controller (18) is located on one side of the operation opening (5).

5. The multi-station hot die forging press for spiral bevel gears according to claim 1, wherein: the forging and pressing device comprises a sliding block (6), the sliding block (6) is connected with an operation opening (5) in a sliding mode, the sliding block (6) is located above a mounting plate (8), the top end of the sliding block (6) is connected with a transmission wedge block (4), the transmission wedge block (4) is connected with the operation opening (5) in a transverse sliding mode, both sides of the adjacent operation opening (5) of the machine body (1) are connected with a crankshaft (2) in a rotating mode, the two sides of the opposite side of the crankshaft (2) are connected with a connecting rod (3) in a rotating mode, the two connecting rod (3) are connected with both sides of the transmission wedge block (4) in a rotating mode respectively, a servo motor is installed on one side, located at the operation opening (5), of the inside of the machine body (1), and is connected with the two crankshafts (2) in a rotating mode.

6. The multi-station hot die forging press for spiral bevel gears according to claim 5, wherein: the bottom end of the sliding block (6) is coated with a wear-resistant coating (21) and a heat dissipation coating (20), and the heat dissipation coating (20) is located at the top end of the wear-resistant coating (21).