CN216707830U - Magnesia carbon brick mould - Google Patents

Abstract

The utility model relates to the technical field of dies, in particular to a magnesia carbon brick die which comprises a processing table, a stamping device, a male die, an upright post, a female die and a material taking device, wherein the male die is arranged on the processing table; the stamping equipment is fixedly connected with the processing table, the male die is fixedly connected with the stamping equipment, the upright post is fixedly connected with the processing table, and the female die is fixedly connected with the upright post; extracting device is including the slip roof, a supporting bench, get the material push pedal, the slip table, place the case, lifting unit and promotion subassembly, the slip roof passes through lifting unit with the processing platform and is connected, a supporting bench and processing platform fixed connection, it passes through the promotion subassembly with a supporting bench to get the material push pedal and is connected, slip table and processing platform fixed connection, it respectively with processing platform and slip table fixed connection to place the case, lifting unit sets up on the processing platform, the promotion subassembly sets up on a supporting bench, promote the magnesia carbon brick to the left side removal through getting the material push pedal and magnesia carbon brick butt, thereby human and stamping equipment direct contact have been avoided, and then the potential safety hazard that stamping equipment caused to the human body has been avoided.

Description

Magnesia carbon brick mould

Technical Field

The utility model relates to the technical field of molds, in particular to a magnesia carbon brick mold.

Background

At present, magnesia carbon bricks are made of high-melting-point alkaline oxide magnesia and high-melting-point carbon materials which are difficult to be infiltrated by slag, various non-oxide additives are added, and carbon bonding agents are used for combining the raw materials to form the unburned carbon composite refractory material.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a magnesia carbon brick die, and aims to solve the technical problems that an existing material ejecting device in the prior art is complex, meanwhile, a hand needs to be manually inserted above the die in integral stamping equipment to take out ejected magnesia carbon bricks, and any wrong operation can cause personal safety hidden dangers and further damage to human bodies.

In order to achieve the purpose, the magnesia carbon brick mold adopted by the utility model comprises a processing table, a stamping device, a male mold, an upright post, a female mold and a material taking device;

the stamping equipment is fixedly connected with the processing table and positioned at one side of the processing table, the male die is fixedly connected with the stamping equipment and positioned at one side of the stamping equipment, the upright post is fixedly connected with the processing table and positioned at one side of the processing table close to the stamping equipment, and the female die is fixedly connected with the upright post and positioned at one side of the upright post close to the male die;

the extracting device includes slip roof, brace table, gets material push pedal, slip table, places case, lifting unit and promotion subassembly, the slip roof with the processing platform passes through lifting unit connects, and is located the processing platform is close to one side of die, the brace table with processing platform fixed connection, and be located one side of processing platform, get the material push pedal with the brace table passes through promote the subassembly to connect, and be located one side of brace table, the slip table with processing platform fixed connection, and be located one side of processing platform, place the case respectively with the processing platform with slip table fixed connection, it is located to place the case the processing platform is close to one side of slip table, lifting unit sets up processing bench, it is in to promote the subassembly setting on the brace table.

The lifting assembly comprises a first hydraulic cylinder and a first hydraulic rod, and the first hydraulic cylinder is fixedly connected with the processing table and is positioned on one side, close to the female die, of the processing table; one end of the first hydraulic rod is connected with the output end of the first hydraulic cylinder, the other end of the first hydraulic rod is fixedly connected with the sliding top plate, and the first hydraulic rod is located between the first hydraulic cylinder and the sliding top plate.

The pushing assembly comprises a second hydraulic cylinder and a second hydraulic rod, and the second hydraulic cylinder is fixedly connected with the supporting platform and is positioned on one side, close to the material taking push plate, of the supporting platform; one end of the second hydraulic rod is connected with the output end of the second hydraulic cylinder, the other end of the second hydraulic rod is fixedly connected with the material taking push plate, and the second hydraulic rod is located between the second hydraulic cylinder and the material taking push plate.

The female die is provided with a lateral bulge, and the lateral bulge is positioned on one side of the female die.

The material taking device further comprises a lateral baffle, wherein the lateral baffle is fixedly connected with the sliding table and is positioned on one side of the sliding table.

In the magnesia carbon brick mold, the male mold is driven to press down by the stamping equipment, and the magnesia carbon brick is molded in the female mold by matching with the female mold, the sliding top plate is driven to ascend through the driving of the lifting component, the formed magnesia carbon brick is ejected out of the concave die, the left side of the material taking push plate is driven to move through the pushing component, thereby the material taking push plate is abutted against the magnesia carbon bricks to push the magnesia carbon bricks to move towards the left side, so that the magnesia carbon bricks move above the sliding table to be contacted with the sliding table, the magnesia carbon bricks slide into the placing box through the inclined angle of the sliding table, the magnesia carbon bricks which are processed and molded and then slide into the placing box through the sliding table can be conveniently taken by the placing box, thereby avoided the human body with stamping equipment direct contact, and then avoided stamping equipment causes the potential safety hazard to the human body.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the prior art descriptions will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

Fig. 1 is a schematic structural view of a magnesia carbon brick mold of the present invention.

Fig. 2 is a schematic structural view of the lifting assembly of the present invention.

Fig. 3 is a schematic structural view of the pushing assembly of the present invention.

In the figure: 1-processing table, 2-punching equipment, 3-male die, 4-upright post, 5-female die, 6-material taking device, 51-lateral bulge, 61-sliding top plate, 62-supporting table, 63-material taking push plate, 64-sliding table, 65-placing box, 66-lifting component, 67-pushing component, 68-lateral baffle, 661-first hydraulic cylinder, 662-first hydraulic rod, 671-second hydraulic cylinder and 672-second hydraulic rod.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the utility model and are not to be construed as limiting the utility model.

In the description of the present invention, it is to be understood that the terms "length", "width", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships illustrated in the drawings, and are used merely for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be construed as limiting the present invention. Further, in the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

Referring to fig. 1 to 3, the present invention provides a magnesia carbon brick mold, which comprises a processing table 1, a stamping device 2, a male mold 3, an upright column 4, a female mold 5 and a material taking device 6; the stamping device 2 is fixedly connected with the processing table 1 and is positioned at one side of the processing table 1, the male die 3 is fixedly connected with the stamping device 2 and is positioned at one side of the stamping device 2, the upright post 4 is fixedly connected with the processing table 1 and is positioned at one side of the processing table 1 close to the stamping device 2, and the female die 5 is fixedly connected with the upright post 4 and is positioned at one side of the upright post 4 close to the male die 3; the material taking device 6 comprises a sliding top plate 61, a support table 62, a material taking push plate 63, a sliding table 64, a placing box 65, a lifting assembly 66 and a pushing assembly 67, the sliding top plate 61 is connected with the processing table 1 through the lifting assembly 66 and is positioned on one side of the processing table 1 close to the female die 5, the support table 62 is fixedly connected with the processing table 1 and is positioned on one side of the processing table 1, the material taking push plate 63 is connected with the support table 62 through the pushing assembly 67 and is positioned on one side of the support table 62, the sliding table 64 is fixedly connected with the processing table 1 and is positioned on one side of the processing table 1, the placing box 65 is respectively fixedly connected with the processing table 1 and the sliding table 64, the placing box 65 is positioned on one side of the processing table 1 close to the sliding table 64, the lifting assembly 66 is arranged on the processing table 1, the pushing assembly 67 is disposed on the support table 62.

In the embodiment, the bolt fixed mounting of the punching equipment 2 is on the processing platform 1, through the processing platform 1 is right the fixed stay when the punching equipment 2 is stamping formed, the bolt fixed mounting of the terrace die 3 is on the punching equipment 2, through the punching equipment 2 realizes the terrace die 3 is pressed down or raised, thereby cooperating the die 5 forms the extrusion forming to the magnesia carbon brick, the column 4 is welded on the processing platform 1, the die 5 is welded on the column 4, through the column 4 realizes the fixed stay when the die 5 is processed, through the die 5 and the terrace die 3 cooperate to make the magnesia carbon brick in the extrusion forming in the die 5, the sliding top plate 61 is connected on the processing platform 1 through the lifting component 66, thereby drives the up-and-down movement of the sliding top plate 61 through the driving of the lifting component 66, the welding of brace table 62 is in processing platform 1, it connects to get the material push pedal 63 through promote the subassembly 67 on the brace table 62, realize through the brace table 62 to get the support when material push pedal 63 removes, through promote the subassembly 67 drive get the removal of material push pedal 63, the slip table 64 welding is in processing platform 1, through promote the subassembly 67 drive get the material push pedal 63 drive the magnesia carbon brick after the shaping in die 5 moves to the left side to make the magnesia carbon brick move to on the slip table 64, slide through the inclination of slip table 64, it fixes to place case 65 bolt fastening on processing platform 1, through place case 65 make things convenient for the manual work to get the magnesia carbon brick that slides into after the processing shaping in placing case 65 through slip table 64, lifting unit 66 sets up on processing platform 1, through lifting unit 66 does sliding roof 61's removal provides the power supply, promotion subassembly 67 sets up on the brace table 62, through promotion subassembly 67 is for get the removal of material push pedal 63 and provide corresponding power supply, thereby realized through stamping equipment 2 drives terrace die 3 pushes down, cooperation die 5 makes magnesia carbon brick be in shaping in die 5, thereby drive through lifting unit 66 sliding roof 61 rises, with the magnesia carbon brick after the shaping follow ejecting in die 5, through promote subassembly 67 drive get the left side of material push pedal 63 and move, thereby make get material push pedal 63 and magnesia carbon brick butt and promote magnesia carbon brick to move to the left side, thereby make magnesia carbon brick move to slip table 64 top with slip table 64 contacts, slide into through the inclination of slip table 64 place the incasement 65, through place case 65 and make things convenient for the manual work to pass through behind the machine-shaping slip table 64 slides in place the magnesia carbon brick in the case 65 and take to avoided the human body with stamping equipment 2 direct contact, and then avoided stamping equipment 2 is to the potential safety hazard that the human body caused.

Further, referring to fig. 2, the lifting assembly 66 includes a first hydraulic cylinder 661 and a first hydraulic rod 662, and the first hydraulic cylinder 661 is fixedly connected to the processing table 1 and is located on a side of the processing table 1 close to the female die 5; one end of the first hydraulic rod 662 is connected with the output end of the first hydraulic cylinder 661, the other end of the first hydraulic rod 662 is fixedly connected with the sliding top plate 61, and the first hydraulic rod 662 is located between the first hydraulic cylinder 661 and the sliding top plate 61.

In this embodiment, the first hydraulic cylinder 661 is welded to the processing table 1, the first hydraulic cylinder 661 provides power for extending and retracting the first hydraulic rod 662 in the extending and retracting process, one end of the first hydraulic rod 662 is connected to the output end of the first hydraulic cylinder 661, the other end of the first hydraulic rod 662 is welded to the sliding top plate 61, the first hydraulic rod 662 is arranged between the first hydraulic cylinder 661 and the sliding top plate 61, and the first hydraulic rod 662 is extended and retracted by the output power provided by the first hydraulic cylinder 661 to realize ejection of the magnesia carbon brick formed by driving the sliding top plate 61 from the die 5.

Further, referring to fig. 3, the pushing assembly 67 includes a second hydraulic cylinder 671 and a second hydraulic rod 672, the second hydraulic cylinder 671 is fixedly connected to the supporting platform 62 and is located at a side of the supporting platform 62 close to the material-taking push plate 63; one end of the second hydraulic rod 672 is connected with the output end of the second hydraulic cylinder 671, the other end of the second hydraulic rod 672 is fixedly connected with the material taking push plate 63, and the second hydraulic rod 672 is located between the second hydraulic cylinder 671 and the material taking push plate 63.

In this embodiment, the second hydraulic cylinder 671 is welded on the support platform 62, the second hydraulic cylinder 671 provides power for extending and retracting the second hydraulic cylinder 672 in the extending and retracting process, one end of the second hydraulic cylinder 672 is connected to the output end of the second hydraulic cylinder 671, the other end of the second hydraulic cylinder 672 is welded on the material taking push plate 63, the second hydraulic cylinder 672 is arranged between the second hydraulic cylinder 671 and the material taking push plate 63, the second hydraulic cylinder 672 extends and retracts by the aid of the output power provided by the second hydraulic cylinder 671 to realize the movement of the material taking push plate 63, and accordingly, the magnesia carbon brick is pushed by the movement of the material taking push plate 63.

Further, referring to fig. 2, the concave mold 5 has a lateral protrusion 51, and the lateral protrusion 51 is located on one side of the concave mold 5.

In this embodiment, the die 5 has the lateral protrusions 51, and the lateral protrusions 51 fix and support the sliding top plate 61 when the sliding top plate 61 is used for stamping magnesia carbon bricks, so that the magnesia carbon bricks can be better molded in the die 5.

Further, referring to fig. 1, the material taking device 6 further includes a lateral blocking plate 68, and the lateral blocking plate 68 is fixedly connected to the sliding table 64 and is located at one side of the sliding table 64.

In this embodiment, there are two side direction baffles 68, two side direction baffles 68 weld the left and right sides on slip table 64, through two side direction baffles 68 make fashioned magnesia carbon brick be in spacing when sliding on slip table 64 to prevent that magnesia carbon brick from dropping out the both sides of slip table 64.

While the utility model has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the utility model.

Claims (5)

1. A magnesia carbon brick die is characterized by comprising a processing table, a stamping device, a male die, an upright post, a female die and a material taking device;

the stamping equipment is fixedly connected with the processing table and positioned at one side of the processing table, the male die is fixedly connected with the stamping equipment and positioned at one side of the stamping equipment, the upright post is fixedly connected with the processing table and positioned at one side of the processing table close to the stamping equipment, and the female die is fixedly connected with the upright post and positioned at one side of the upright post close to the male die;

the extracting device includes slip roof, brace table, gets material push pedal, slip table, places case, lifting unit and promotion subassembly, the slip roof with the processing platform passes through lifting unit connects, and is located the processing platform is close to one side of die, the brace table with processing platform fixed connection, and be located one side of processing platform, get the material push pedal with the brace table passes through promote the subassembly to connect, and be located one side of brace table, the slip table with processing platform fixed connection, and be located one side of processing platform, place the case respectively with the processing platform with slip table fixed connection, it is located to place the case the processing platform is close to one side of slip table, lifting unit sets up processing bench, it is in to promote the subassembly setting on the brace table.

2. The magnesia carbon brick mold of claim 1,

the lifting assembly comprises a first hydraulic cylinder and a first hydraulic rod, and the first hydraulic cylinder is fixedly connected with the processing table and is positioned on one side of the processing table close to the female die; one end of the first hydraulic rod is connected with the output end of the first hydraulic cylinder, the other end of the first hydraulic rod is fixedly connected with the sliding top plate, and the first hydraulic rod is located between the first hydraulic cylinder and the sliding top plate.

3. The magnesia carbon brick mold of claim 1,

the pushing assembly comprises a second hydraulic cylinder and a second hydraulic rod, and the second hydraulic cylinder is fixedly connected with the supporting platform and is positioned on one side, close to the material taking push plate, of the supporting platform; one end of the second hydraulic rod is connected with the output end of the second hydraulic cylinder, the other end of the second hydraulic rod is fixedly connected with the material taking push plate, and the second hydraulic rod is located between the second hydraulic cylinder and the material taking push plate.

4. The magnesia carbon brick mold of claim 1,

the female die is provided with a lateral bulge, and the lateral bulge is positioned on one side of the female die.

5. The magnesia carbon brick mold of claim 1,

the material taking device further comprises a lateral baffle, and the lateral baffle is fixedly connected with the sliding table and is positioned on one side of the sliding table.

Images