CN220837822U - Molybdenum alloy slab forming die - Google Patents

Abstract

The utility model belongs to the technical field of forming tools, and particularly relates to a molybdenum alloy plate blank forming die which comprises a bottom die holder, wherein a bottom die plate is fixedly assembled at the top of the bottom die holder, a first side die plate is symmetrically and movably assembled at two ends of the top of the bottom die plate, a second side die plate is symmetrically and movably assembled at two sides of the top of the bottom die plate, a top die plate is movably assembled above the bottom die plate, double-threaded screws are rotatably arranged at the tops of two ends of the bottom die holder, an operating rod frame is movably assembled at the top of the bottom die holder and positioned at the outer side of the second side die plate, two ends of the operating rod frame are respectively provided with a straight groove and a chute in a penetrating mode, and limiting blocks for limiting the two positions of the second side die plate are fixedly arranged at two ends of the outer wall of the second side die plate. The utility model can realize complete disassembly of the die, and each die plate is disassembled in sequence, so that the die is more convenient for demoulding of the plate blank, the demoulding speed is higher, the die structure is simple and compact, and excessive space is not occupied.

Description

Molybdenum alloy slab forming die

Technical Field

The utility model belongs to the technical field of forming tools, and particularly relates to a molybdenum alloy plate blank forming die.

Background

A mold, a variety of molds and tools for industrially producing the desired product by injection molding, blow molding, extrusion, die casting or forging, smelting, stamping, etc.; in short, a mold is a tool for making a molded article, which is composed of various parts, and different molds are composed of different parts; the processing of the appearance of the article is realized mainly by changing the physical state of the formed material.

Problems of the prior art:

In the casting work of slab-shaped section bar, after the section bar casting is accomplished, comparatively complicated process is the drawing of patterns process, and traditional slab mould all separates each template and slab one by one, and this drawing of patterns mode step is numerous, and drawing of patterns speed is slow, but if accomplish the dismantlement of each template in proper order with power equipment, each template all needs to have corresponding power equipment to connect, causes whole mould to occupy more space because of other equipment's existence, and inner structure is also comparatively complicated.

Disclosure of utility model

The utility model aims to provide a molybdenum alloy plate blank forming die which can realize complete disassembly of the die, and each die plate is disassembled in sequence, so that the die plate blank can be more conveniently demoulded, the demoulding speed is higher, the die structure is simple and compact, and excessive space cannot be occupied.

The technical scheme adopted by the utility model is as follows:

The molybdenum alloy plate blank forming die comprises a bottom die seat, wherein a bottom die plate is fixedly assembled at the top of the bottom die seat, side die plates I are symmetrically and movably assembled at two ends of the top of the bottom die plate, side die plates II are symmetrically and movably assembled at two sides of the top of the bottom die plate, a top die plate is movably assembled above the bottom die plate, and a push rod for pushing out a plate blank finished product is movably arranged at the inner side of the bottom die seat and positioned at the bottom of the bottom die plate;

The tops of the two ends of the bottom die holder are respectively provided with a double-thread screw in a rotating way;

The bottom die seat top and be located the outside movable set of sideform board two have the action bars frame, the fixed screwed pipe that is provided with of both ends integral type of action bars frame, just screwed pipe activity spiro union is in the surface of twin-screw, straight flute and chute have all been seted up in the both ends of action bars frame, just the chute sets up in the one end of straight flute, the both ends outer wall of sideform board one is all fixed and is provided with the back of the body bar frame, just the activity of back of the body bar frame end runs through in straight flute and chute, the fixed blank pipe that is provided with in middle part both ends integral type of action bars frame, just the one end activity grafting of blank pipe has interior pole, just interior pole fixed mounting is in the outer wall of sideform board two, be connected with the spring between the inner wall of one end of interior pole and blank pipe.

And the middle parts of the double-threaded screws are fixedly provided with helical gears I.

Motors are fixedly arranged on two sides of the bottom die seat, and a bevel gear II meshed with the bevel gear I is fixedly arranged at the output end of each motor.

Both ends of the bottom template are fixedly connected with side rods, the bottom of the outer wall of the side template I is fixedly provided with a guide pipe, and the guide pipe is movably sleeved on the outer surface of the side rods.

Guide sleeves are embedded at two ends of the top of the second side template, and limiting blocks for limiting the second position of the second side template are fixedly arranged at two ends of the outer wall of the second side template.

Guide rods are fixedly connected to two sides of the lower surface of the top template, the guide rods are movably inserted into the guide sleeve, and handles are fixedly connected to two ends of the top template.

The inside equidistance of bottom die board is run through and is provided with cooling water pipe one, the inside equidistance of top die board is run through and is provided with cooling water pipe two.

The utility model has the technical effects that:

According to the utility model, the top template, the side template I and the side template II are sequentially separated from the plate blank, so that the effect of complete disassembly of the die can be realized, the plate blank can be more conveniently demolded, and the demolding speed is higher; in addition, the demolding power of the first side template and the second side template is derived from the movement of the operating rod frame, so that the structure of the mold is more compact and simple, excessive space is not occupied, the mold is distributed in both dismantling and assembling, the sequential assembling of the templates is more beneficial to ensuring the sealing effect between the mold plates, and the sequential dismantling of the templates is more beneficial to protecting the plate blanks; finally, the first side template is assembled with the side rod in a sliding manner through the guide pipe in the moving process, so that the moving direction and the moving distance of the first side template are ensured, and in addition, the setting of the limiting block is convenient for maintaining the position relation between the bottom template and the second side template.

Drawings

FIG. 1 is a block diagram of a mold provided by an embodiment of the present utility model;

FIG. 2 is an exploded view of a base form, a sideform I, a sideform II, and a lever arm according to an embodiment of the present utility model;

FIG. 3 is an assembled plan view of a first sideform and a second sideform provided by an embodiment of the present utility model;

Fig. 4 is an internal cross-sectional view of a hollow tube provided by an embodiment of the present utility model.

In the drawings, the list of components represented by the various numbers is as follows:

1. A bottom template; 101. a side bar; 102. a first cooling water pipe; 2. a bottom die holder; 201. a double-flighted screw; 202. a first helical gear; 3. a first side template; 301. a back bar frame; 302. a conduit; 4. a second side template; 401. guide sleeve; 402. a limiting block; 5. a top template; 501. a guide rod; 502. a handle; 503. a cooling water pipe II; 6. a lever frame; 601. an empty pipe; 602. an inner rod; 603. a spring; 604. a straight groove; 605. a chute; 606. a solenoid; 7. a motor; 701. a helical gear II; 8. and (5) a push rod.

Detailed Description

The present utility model will be specifically described with reference to examples below in order to make the objects and advantages of the present utility model more apparent. It should be understood that the following text is intended to describe only one or more specific embodiments of the utility model and does not limit the scope of the utility model strictly as claimed.

As shown in fig. 1-4, a molybdenum alloy slab forming die comprises a die holder 2, wherein a die plate 1 is fixedly assembled at the top of the die holder 2, a side die plate I3 is symmetrically and movably assembled at two ends of the top of the die plate 1, a side die plate II 4 is symmetrically and movably assembled at two sides of the top of the die plate 1, a top die plate 5 is movably assembled above the die plate 1, and a push rod 8 for ejecting a slab finished product is movably arranged at the inner side of the die holder 2 and positioned at the bottom of the die plate 1.

Referring to the drawing, the tops of two ends of the bottom die seat 2 are respectively provided with a double-threaded screw 201 in a rotating way, and the middle parts of the double-threaded screws 201 are respectively fixedly provided with a first bevel gear 202; the two sides of the bottom die holder 2 are fixedly provided with a motor 7, and the output end of the motor 7 is fixedly provided with a bevel gear II 701 meshed with the bevel gear I202.

According to the above structure, after completing the casting operation of a molybdenum alloy slab, the mold is removed, the top mold plate 5 is moved upward and removed, and then the motor 7 is started simultaneously, and the operation thereof drives the bevel gear two 701 to rotate, and then the double-threaded screw 201 is driven to rotate by the engagement of the bevel gear one 202 and the bevel gear two 701.

Referring to fig. 2, 3 and 4, an operating rod frame 6 is movably assembled at the top of the bottom die holder 2 and located at the outer side of the second side die plate 4, two ends of the operating rod frame 6 are integrally and fixedly provided with a screw pipe 606, the screw pipe 606 is movably connected to the outer surface of the double-threaded screw 201 in a screwed mode, two ends of the operating rod frame 6 are respectively provided with a straight groove 604 and a chute 605 in a penetrating mode, the chute 605 is arranged at one end of the straight groove 604, two outer walls of the first side die plate 3 are respectively fixedly provided with a back rod frame 301, the tail ends of the back rod frame 301 are respectively and movably provided with a straight groove 604 and a chute 605, two ends of the middle of the operating rod frame 6 are integrally and fixedly provided with an empty pipe 601, one end of the empty pipe 601 is movably inserted with an inner rod 602, the inner rod 602 is fixedly installed on the outer wall of the second side die plate 4, and a spring 603 is connected between one end of the inner rod 602 and the inner wall of the empty pipe 601.

According to the above structure, since the two ends of the double-threaded screw 201 are provided with threads and the threads are opposite in rotation, when the two double-threaded screws 201 on two sides rotate, the two operation rod frames 6 are driven to move back at the same time, and since the back rod frame 301 penetrates through the straight groove 604 and the chute 605, the back rod frame 301 moves from the chute 605 to the straight groove 604, in the process, the two side templates I3 are separated from the slab together, the inner rod 602 and the hollow pipe 601 relatively move, the springs 603 are stretched at the same time, and then when the back rod frame 301 moves along the straight groove 604, the side templates I3 are not moved any more, but at the moment, the two side templates II 4 are driven to be separated from the slab together, the above process can realize that the top template 5, the side templates I3 and the side templates II 4 are separated from the slab in sequence, the effect of complete disassembly and assembly of the die is realized, the demolding of the slab is more convenient, and the demolding speed is faster; in addition, the demolding power of the first side template 3 and the second side template 4 is derived from the movement of the operating rod frame 6, so that the structure of the mold is more compact and simple, the mold is distributed in both dismantling and assembling, the sequential assembling of the templates is more beneficial to ensuring the sealing effect between the templates, and the sequential dismantling of the templates is more beneficial to protecting slabs.

Referring to fig. 1 and 2, two ends of a bottom template 1 are fixedly connected with side rods 101, the bottoms of the outer walls of a side template one 3 are fixedly provided with guide pipes 302, the guide pipes 302 are movably sleeved on the outer surfaces of the side rods 101, and two ends of the outer walls of a side template two 4 are fixedly provided with limiting blocks 402 for limiting the positions of the side template two 4.

According to the above structure, the first sideform 3 is slidably assembled with the side lever 101 through the guide pipe 302 during the movement, so that the movement direction and the movement distance of the first sideform 3 are ensured, and in addition, the positioning of the stopper 402 is convenient for maintaining the positional relationship between the bottom form 1 and the second sideform 4.

Referring to fig. 1 and 2, guide sleeves 401 are embedded at two ends of the top of a second side template 4, guide rods 501 are fixedly connected to two sides of the lower surface of a top template 5, the guide rods 501 are movably inserted into the guide sleeves 401, and handles 502 are fixedly connected to two ends of the top template 5; the first cooling water pipes 102 are arranged in the bottom template 1 in an equidistant penetrating manner, and the second cooling water pipes 503 are arranged in the top template 5 in an equidistant penetrating manner.

The working principle of the utility model is as follows: after completing the casting work of a molybdenum alloy plate blank, removing the die, moving upwards and removing the top die plate 5, then simultaneously starting the motor 7, driving the bevel gear II 701 to rotate, and driving the double-threaded screw 201 to rotate through the meshing of the bevel gear I202 and the bevel gear II 701; because the two ends of the double-threaded screw 201 are provided with threads and the threads are opposite in rotation, when the two double-threaded screws 201 on two sides rotate, the two operation rod frames 6 are driven to move back at the same time, and because the back rod frame 301 penetrates through the straight groove 604 and the chute 605, the back rod frame 301 moves from the chute 605 to the straight groove 604, in the process, the two side templates I3 are separated from the slab together, the inner rod 602 and the hollow pipe 601 relatively move, the spring 603 is stretched at the same time, and then when the back rod frame 301 moves along the straight groove 604, the side templates I3 are not moved any more, but at the moment, the two side templates II 4 are driven to move away from each other and are separated from the slab together.

The foregoing is merely a preferred embodiment of the present utility model and it should be noted that modifications and adaptations to those skilled in the art may be made without departing from the principles of the present utility model, which are intended to be comprehended within the scope of the present utility model. Structures, devices and methods of operation not specifically described and illustrated herein, unless otherwise indicated and limited, are implemented according to conventional means in the art.

Claims (7)

1. The molybdenum alloy plate blank forming die comprises a bottom die holder (2), and is characterized in that: the top of the bottom die seat (2) is fixedly provided with a bottom die plate (1), two ends of the top of the bottom die plate (1) are symmetrically and movably provided with side die plates I (3), two sides of the top of the bottom die plate (1) are symmetrically and movably provided with side die plates II (4), the upper part of the bottom die plate (1) is movably provided with a top die plate (5), and the inner side of the bottom die seat (2) and the bottom of the bottom die plate (1) are movably provided with a top rod (8) for ejecting a plate blank finished product;

The tops of the two ends of the bottom die seat (2) are respectively provided with a double-thread screw (201) in a rotating way;

The bottom die seat (2) top and be located the outside movable set of side form two (4) and have action bars frame (6), action bars frame (6) both ends integral type is fixedly provided with screwed pipe (606), just screwed pipe (606) activity spiro union is in the surface of double-threaded screw rod (201), straight flute (604) and chute (605) have all been seted up in the both ends of action bars frame (6), just chute (605) set up in the one end of straight flute (604), the both ends outer wall of side form one (3) is all fixed and is provided with back of the body pole frame (301), just back of the body pole frame (301) end activity is run through in straight flute (604) and chute (605), the middle part both ends integral type of action bars frame (6) is fixedly provided with empty pipe (601), and the one end activity grafting of empty pipe (601) has interior pole (602), just interior pole (602) fixed mounting is in the outer wall of side form two (4), and be connected with spring (603) between the inner wall of interior pole (602) and empty pipe (603).

2. A molybdenum alloy slab forming die as defined in claim 1, wherein: the middle parts of the double-thread screws (201) are fixedly provided with helical gears I (202).

3. A molybdenum alloy slab forming die as defined in claim 1, wherein: two sides of the bottom die seat (2) are fixedly provided with motors (7), and the output ends of the motors (7) are fixedly provided with bevel gears II (701) meshed with the bevel gears I (202).

4. A molybdenum alloy slab forming die as defined in claim 1, wherein: both ends of the bottom template (1) are fixedly connected with side rods (101), the bottom of the outer wall of the side template I (3) is fixedly provided with a guide pipe (302), and the guide pipe (302) is movably sleeved on the outer surface of the side rods (101).

5. A molybdenum alloy slab forming die as defined in claim 1, wherein: guide sleeves (401) are embedded at two ends of the top of the second side template (4), and limiting blocks (402) used for limiting the position of the second side template (4) are fixedly arranged at two ends of the outer wall of the second side template (4).

6. The molybdenum alloy slab forming die as defined in claim 5, wherein: guide rods (501) are fixedly connected to two sides of the lower surface of the top template (5), the guide rods (501) are movably inserted into the guide sleeve (401), and handles (502) are fixedly connected to two ends of the top template (5).

7. A molybdenum alloy slab forming die as defined in claim 1, wherein: the inside equidistance of bottom die board (1) is run through and is provided with cooling water pipe one (102), the inside equidistance of cope match-plate pattern (5) is run through and is provided with cooling water pipe two (503).