CN210025685U

CN210025685U - Automatic pressing and forming device for refractory materials

Info

Publication number: CN210025685U
Application number: CN201920435576.9U
Authority: CN
Inventors: 罗晨旭; 张奇; 李伟峰; 宋利杰
Original assignee: Luoyang Yuanhua Metallurgical High Temperature Material Co Ltd
Current assignee: Luoyang Yuanhua Metallurgical High Temperature Material Co Ltd
Priority date: 2019-04-02
Filing date: 2019-04-02
Publication date: 2020-02-07
Anticipated expiration: 2029-04-02

Abstract

The utility model discloses an automatic pressure forming device of refractory material, including shaping hydraulic press body, shell and motor, install the shell on the hydraulic press body that takes shape, and install the motor on the shell to install on the motor and move. The power rod is installed on the shell, and the power rod is connected with the rotating plate, and the rotating plate is installed on the function groove, be fixed with first extrusion piece on the rotating plate, the inside in board groove is installed to the fly leaf, the inboard at first chain is installed to the motor, install the flabellum on the first gangbar, the connecting rod is installed to the inboard of second chain, second extrusion piece and vibration board are connected. This automatic compression moulding device of refractory material has designed the structure that has the vibrations function, has solved the inhomogeneous problem of material shop on the traditional device, has designed the structure that has the collection function simultaneously, has solved the inconvenient problem of collecting unnecessary material of traditional device.

Description

Automatic pressing and forming device for refractory materials

Technical Field

The utility model relates to a refractory material processing technology field specifically is a refractory material automatic pressure brake forming device.

Background

The materials used in the high-temperature environment are called refractory materials, the refractory materials do not change at high temperature, the refractory materials are widely applied to various production fields such as cement, steel, boilers and the like, are essential basic materials for ensuring normal operation production and production technology development of production industries, and simultaneously play an important role in the development of the high-temperature industry.

With the continuous application and development of high-temperature refractory materials, the production technology of the high-temperature refractory materials is also continuously improved, powdery refractory material raw materials are often extruded and formed through an automatic press forming hydraulic machine, and the high-temperature refractory materials are convenient for people to use, but the existing press forming device has the defects of uneven material laying and inconvenience in collection of redundant materials during operation. In order to solve the above problems, innovative design based on the original press forming device is urgently needed.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a refractory material automatic pressure brake forming device to propose the problem that the material shop was uneven and inconvenient to be collected unnecessary material among the solution above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: an automatic refractory material pressing and forming device comprises a forming hydraulic press body, a shell and a motor, wherein the forming hydraulic press body is provided with the shell, the shell is provided with the motor, the motor is provided with a power rod, the power rod is arranged on the shell, the power rod is connected with a rotating plate, the rotating plate is arranged on a function groove, the function groove is arranged on the shell, the rotating plate is fixedly provided with a first extrusion block, the first extrusion block is connected with a fixed rod, the fixed rod is fixed on a movable plate, the movable plate is arranged in the plate groove, the plate groove is arranged on a forming frame, the forming frame is arranged on the shell, the motor is arranged on the inner side of a first chain, a first linkage rod is arranged on the inner side of the first chain, the first linkage rod is arranged on the forming hydraulic press body, and fan blades are arranged on the first linkage rod, and first gangbar installs the inboard at the second chain to the second gangbar is installed to the inboard of second chain, installs the flabellum on the second gangbar simultaneously, the connecting rod is installed to the inboard of second chain, and the connecting rod installs on the shell to be fixed with the second extrusion piece on the connecting rod, second extrusion piece and vibration board are connected, and the vibration board is installed in the inside in work groove, and the work groove is seted up on the shell, installs the filter screen on the vibration board simultaneously.

Preferably, the power rod and the rotating plate are both provided with bevel gears, the power rod and the rotating plate are in meshed connection through the bevel gears, and the rotating plate is in sliding connection with the functional groove.

Preferably, the first extrusion blocks are symmetrically arranged about the central line of the rotating plate, the first extrusion blocks are connected with the fixed rod in a clamping manner, the fixed rod is connected with the movable plate in a welding manner, and the movable plate is connected with the plate groove in a sliding manner.

Preferably, the first linkage rod forms a chain transmission structure through a first chain and the power rod, the first linkage rod forms a chain transmission structure through a second chain and the second linkage rod, and the second linkage rod is symmetrically arranged about the center line of the shell.

Preferably, the first linkage rod forms a chain transmission structure through a second chain and a connecting rod, the second extrusion block is arranged at an equal angle relative to the center line of the connecting rod, and the second extrusion block is connected with the vibration plate in a clamping manner.

Preferably, the vibration plate is connected with the working groove in a sliding mode, and the upper end of the vibration plate is higher than the upper ends of the fan blades.

Compared with the prior art, the beneficial effects of the utility model are that: the automatic compression molding device for the refractory material adopts a novel structural design, designs a structure with a vibration function, solves the problem of uneven material laying on the traditional device, designs a structure with a collection function, and solves the problem that the traditional device is inconvenient to collect redundant materials;

1. the forming hydraulic machine comprises a forming hydraulic machine body, a shell, a motor, a power rod, a rotating plate, a functional groove, a first extrusion block, a fixed rod, a movable plate, a plate groove and a forming frame, wherein the structure formed by the forming hydraulic machine body, the shell, the motor, the power rod, the rotating plate, the functional groove, the first extrusion block, the fixed rod, the movable plate, the plate groove and the forming frame is a structural basis for realizing a vibration function of the forming hydraulic machine;

2. the forming hydraulic press comprises a forming hydraulic press body, a shell, a motor, a first chain, a first linkage rod, fan blades, a second chain, a second linkage rod, a connecting rod, a second extrusion block, a vibration plate, a working groove and a filter screen, wherein the motor drives the fan blades to move, so that redundant materials of a fan blade driving device move, the motor drives the vibration plate to vibrate, the vibration plate drives the filter screen to vibrate, and the problem that the traditional device is inconvenient to collect the redundant materials is solved.

Drawings

Fig. 1 is a schematic view of the front cross-sectional structure of the present invention;

FIG. 2 is a schematic top view of the cross-sectional structure of the present invention;

FIG. 3 is a schematic view of the structure at A in FIG. 1 according to the present invention;

fig. 4 is a schematic view of the top view cross-sectional structure of the movable plate of the present invention;

fig. 5 is a schematic side view of the second extrusion block of the present invention.

In the figure: 1. forming a hydraulic press body; 2. a housing; 3. a motor; 4. a power rod; 5. rotating the plate; 6. a functional groove; 7. a first extrusion block; 8. fixing the rod; 9. a movable plate; 10. a plate groove; 11. a forming frame; 12. a first chain; 13. a first linkage rod; 14. a fan blade; 15. a second chain; 16. a second linkage rod; 17. a connecting rod; 18. a second extrusion block; 19. a vibrating plate; 20. a working groove; 21. and (5) filtering by using a filter screen.

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. 1-5, the present invention provides a technical solution: an automatic refractory material pressing and forming device comprises a forming hydraulic press body 1, a shell 2, a motor 3, a power rod 4, a rotating plate 5, a functional groove 6, a first extrusion block 7, a fixed rod 8, a movable plate 9, a plate groove 10, a forming frame 11, a first chain 12, a first linkage rod 13, fan blades 14, a second chain 15, a second linkage rod 16, a connecting rod 17, a second extrusion block 18, a vibrating plate 19, a working groove 20 and a filter screen 21, wherein the forming hydraulic press body 1 is provided with the shell 2, the shell 2 is provided with the motor 3, the motor 3 is provided with the power rod 4, the power rod 4 is arranged on the shell 2, the power rod 4 is connected with the rotating plate 5, the rotating plate 5 is arranged on the functional groove 6, the functional groove 6 is arranged on the shell 2, the rotating plate 5 is fixedly provided with the first extrusion block 7, the first extrusion block 7 is connected with the fixed rod 8, the fixed rod 8 is fixed on the movable plate 9, the movable plate 9 is arranged inside the plate groove 10, the plate groove 10 is arranged on the forming frame 11, the forming frame 11 is arranged on the shell 2, the motor 3 is arranged on the inner side of the first chain 12, the inner side of the first chain 12 is provided with a first linkage rod 13, and the first linkage rod 13 is arranged on the forming hydraulic press body 1, the fan blades 14 are arranged on the first linkage rod 13, the first linkage rod 13 is arranged on the inner side of the second chain 15, and a second linkage bar 16 is installed at the inner side of the second chain 15, and fan blades 14 are installed on the second linkage bar 16, a connecting rod 17 is installed at the inner side of the second chain 15, and the connecting rod 17 is installed on the housing 2, and a second extrusion block 18 is fixed on the connecting rod 17, the second extrusion block 18 is connected with a vibration plate 19, and the vibration plate 19 is installed inside the working groove 20, the working tank 20 is opened in the housing 2, and the vibrating plate 19 is provided with a strainer 21.

In the embodiment, the power rod 4 and the rotating plate 5 are both provided with bevel gears, the power rod 4 and the rotating plate 5 are in meshed connection through the bevel gears, and the rotating plate 5 is in sliding connection with the functional groove 6, so that the design ensures that the power rod 4 can effectively drive the rotating plate 5 to move, and the rotating plate 5 can effectively slide on the functional groove 6;

the first extrusion blocks 7 are symmetrically arranged about the central line of the rotating plate 5, the first extrusion blocks 7 are connected with the fixed rod 8 in a clamping manner, the fixed rod 8 is connected with the movable plate 9 in a welding manner, and the movable plate 9 is connected with the plate groove 10 in a sliding manner, so that the first extrusion blocks 7 can effectively extrude the fixed rod 8, and the fixed rod 8 can effectively drive the movable plate 9 to slide on the plate groove 10;

the first linkage rod 13 forms a chain transmission structure through the first chain 12 and the power rod 4, the first linkage rod 13 forms a chain transmission structure through the second chain 15 and the second linkage rod 16, and the second linkage rod 16 is symmetrically arranged about the central line of the shell 2, the design ensures that the power rod 4 can effectively drive the first linkage rod 13 to move through the first chain 12, the first linkage rod 13 can effectively drive the second linkage rod 16 to move through the second chain 15, and the second linkage rod 16 can effectively drive the structure with the air draft function on the device to effectively operate;

the first linkage rod 13 forms a chain transmission structure through the second chain 15 and the connecting rod 17, the second extrusion block 18 is arranged at an equal angle relative to the center line of the connecting rod 17, and the second extrusion block 18 is connected with the vibrating plate 19 in a clamping manner, so that the first linkage rod 13 can effectively drive the connecting rod 17 to move through the second chain 15, and the connecting rod 17 can effectively drive the second extrusion block 18 to extrude the vibrating plate 19;

the vibrating plate 19 is connected with the working groove 20 in a sliding mode, the upper end of the vibrating plate 19 is higher than the upper end of the fan blades 14, the design ensures that the vibrating plate 19 can effectively slide on the working groove 20, and the vibrating plate 19 can effectively block redundant materials on the device.

The working principle is as follows: the forming hydraulic press body 1 in the device is the prior mature technology and is well known by persons skilled in the art, and the detailed description is omitted;

when the device is used, firstly, the forming hydraulic machine body 1 and the motor 3 in the device are powered on;

the forming hydraulic machine body 1 and the motor 3 are opened, the motor 3 drives the power rod 4 to rotate through a rotary bearing connected with the power rod 4 and the shell 2, the power rod 4 drives the rotating plate 5 to move, the rotating plate 5 slides on the function groove 6, the rotating plate 5 drives the first extrusion block 7 to move, the first extrusion block 7 periodically extrudes the fixed rod 8, the fixed rod 8 drives the movable plate 9 to reciprocate on the plate groove 10, a spring connected with the plate groove 10 and the movable plate 9 pulls the movable plate 9 to reset, the movable plate 9 and the inner wall of the plate groove 10 collide and vibrate, the forming frame 11 vibrates, powdery raw materials needing to be extruded and formed are placed inside the forming frame 11, the forming frame 11 vibrates to drive powdery materials inside the forming frame 11 to be tiled inside the forming frame 11, and the forming hydraulic machine body 1 is convenient to extrude and form the materials inside the forming frame 11;

wherein the power rod 4 drives the first linkage rod 13 to rotate through the first chain 12, the first linkage rod 13 rotates through a rotary bearing connected with the shell 2 through the first linkage rod 13, the first linkage rod 13 drives the second linkage rod 16 to move through the second chain 15, the first linkage rod 13 drives the connecting rod 17 to rotate through the second chain 15, the connecting rod 17 drives the rest of the second linkage rods 16 on the device to rotate through the second chain 15 on the other side of the device, the first linkage rod 13 and the second linkage rod 16 drive the fan blades 14 to rotate, the fan blades 14 blow the materials overflowing after the upper end of the shell 2 is extruded by the forming hydraulic machine body 1, the materials fall on the filter screen 21, meanwhile, the connecting rod 17 drives the second extrusion block 18 to rotate, the second extrusion block 18 extrudes the vibrating plate 19, the vibrating plate 19 slides in the working groove 20, the spring connected with the vibrating plate 19 and the working groove 20 pulls the vibrating plate 19 to reset in the working groove 20, the vibrating plate 19 reciprocates on the working groove 20, the vibrating plate 19 drives the filter screen 21 to vibrate, and materials on the filter screen 21 fall into a lower box under the vibration of the filter screen 21, so that the collection of redundant materials is realized.

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 an automatic pressure forming device of refractory material, includes shaping hydraulic press body (1), shell (2) and motor (3), its characterized in that: the forming hydraulic machine is characterized in that a shell (2) is installed on a forming hydraulic machine body (1), a motor (3) is installed on the shell (2), a power rod (4) is installed on the motor (3), the power rod (4) is installed on the shell (2), the power rod (4) is connected with a rotating plate (5), the rotating plate (5) is installed on a function groove (6), the function groove (6) is formed in the shell (2), a first extrusion block (7) is fixed on the rotating plate (5), the first extrusion block (7) is connected with a fixing rod (8), the fixing rod (8) is fixed on a movable plate (9), the movable plate (9) is installed inside the plate groove (10), the plate groove (10) is formed in a forming frame (11), the forming frame (11) is installed on the shell (2), and the motor (3) is installed on the inner side of a first chain (12), and the inner side of the first chain (12) is provided with a first linkage rod (13), and the first linkage rod (13) is arranged on the forming hydraulic machine body (1), the first linkage rod (13) is provided with fan blades (14), the first linkage rod (13) is arranged on the inner side of the second chain (15), a second linkage rod (16) is arranged on the inner side of the second chain (15), and fan blades (14) are arranged on the second linkage rod (16), a connecting rod (17) is arranged on the inner side of the second chain (15), the connecting rod (17) is arranged on the shell (2), and a second extrusion block (18) is fixed on the connecting rod (17), the second extrusion block (18) is connected with a vibration plate (19), the vibration plate (19) is arranged in the working groove (20), the working groove (20) is arranged on the shell (2), and the vibrating plate (19) is provided with a filter screen (21).

2. The automatic press-forming apparatus for a refractory material according to claim 1, wherein: the power rod (4) and the rotating plate (5) are both provided with bevel gears, the power rod (4) and the rotating plate (5) are in meshed connection through the bevel gears, and the rotating plate (5) is in sliding connection with the functional groove (6).

3. The automatic press-forming apparatus for a refractory material according to claim 1, wherein: the first extrusion blocks (7) are symmetrically arranged about the central line of the rotating plate (5), the first extrusion blocks (7) are connected with the fixed rod (8) in a clamping mode, the fixed rod (8) is connected with the movable plate (9) in a welding mode, and meanwhile the movable plate (9) is connected with the plate groove (10) in a sliding mode.

4. The automatic press-forming apparatus for a refractory material according to claim 1, wherein: the first linkage rod (13) forms a chain transmission structure through a first chain (12) and the power rod (4), the first linkage rod (13) forms a chain transmission structure through a second chain (15) and a second linkage rod (16), and the second linkage rod (16) is symmetrically arranged relative to the center line of the shell (2).

5. The automatic press-forming apparatus for a refractory material according to claim 1, wherein: the first linkage rod (13) forms a chain transmission structure through a second chain (15) and a connecting rod (17), the second extrusion block (18) is arranged at an equal angle relative to the center line of the connecting rod (17), and the second extrusion block (18) is connected with the vibration plate (19) in a clamping mode.

6. The automatic press-forming apparatus for a refractory material according to claim 1, wherein: the vibration plate (19) is connected with the working groove (20) in a sliding mode, and the upper end of the vibration plate (19) is higher than the upper end of the fan blade (14).