CN216505863U - Transfer device is used in production of electric stove magnesia carbon brick - Google Patents

Abstract

The utility model discloses a transfer device for producing magnesia carbon bricks of an electric furnace, which comprises a base and a battery, wherein a main hydraulic press and the battery are arranged on the upper wall of the base, a rotary table is arranged at the output end of the main hydraulic press, an auxiliary hydraulic press is rotatably arranged on the upper wall of the rotary table, an adapter is arranged on the upper wall of the auxiliary hydraulic press, a bracket is welded on the right side wall of the adapter, and a storage hopper is welded on the inner side wall of the bracket. The quality of the magnesia carbon brick is improved.

Description

Transfer device is used in production of electric stove magnesia carbon brick

Technical Field

The utility model relates to the technical field of magnesia carbon brick production equipment, in particular to a transfer device for producing magnesia carbon bricks of an electric furnace.

Background

The electric furnace magnesia carbon brick is a refractory product for an electric furnace, which is made of magnesia and graphite as raw materials, and has the characteristics of high fire resistance, high erosion resistance, excellent heat spalling resistance, high temperature volume stability, high thermal shock resistance and the like.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a transfer device for producing magnesia carbon bricks of an electric furnace, which aims to solve the problems in the background technology.

In order to achieve the purpose, the utility model provides the following technical scheme: the transfer device for producing the magnesia carbon bricks of the electric furnace comprises a base and a battery, wherein a main hydraulic press and the battery are installed on the upper wall of the base, a rotary table is installed at the output end of the main hydraulic press, an auxiliary hydraulic press is installed on the upper wall of the rotary table in a rotating mode, an adapter is installed on the upper wall of the auxiliary hydraulic press, a support is welded on the right side wall of the adapter, a storage hopper is welded on the inner side wall of the support, and the main hydraulic press and the auxiliary hydraulic press are both electrically connected with the battery;

the backup pad is installed through the bolt to the lateral wall of storage hopper, main automatically controlled push rod and vice automatically controlled push rod are installed to the lateral wall of backup pad, main automatically controlled push rod all is connected with the battery electricity with vice automatically controlled push rod, the striker plate is installed to main automatically controlled push rod's output, the one end of branch is installed to vice automatically controlled push rod's output, and the fixed block is installed to the other end of branch, the lateral wall welding of fixed block has the projection, the lateral wall of projection rotates installs the scraper blade, the one end of spring is installed to the lateral wall of branch, the other end of spring is installed with the lateral wall of scraper blade.

Preferably, the left side wall welding of adapter has the control frame, the controller is installed to the lateral wall of control frame, the controller is connected with battery, main hydraulic press, vice hydraulic press, main electric control push rod and vice electric control push rod are equal electrically, the steerable main hydraulic press of controller, vice hydraulic press, main electric control push rod and vice electric control push rod stretch out and draw back.

Preferably, the side wall of the rotary table is provided with a sliding chute, the inner side wall of the sliding chute is connected with a rotating ring in a sliding mode, one end of an inclined frame is welded on the side wall of the rotating ring, a lantern ring is welded on the other end of the inclined frame, and the lantern ring is sleeved on the side wall of the support.

Preferably, a handle is mounted on the side wall of the control frame.

Preferably, reinforcing ribs are welded on the side wall of the output end of the main hydraulic press, and the upper wall of each reinforcing rib is welded with the lower wall of the rotary table.

Preferably, universal wheels are mounted at four corners of the lower wall of the base.

Compared with the prior art, the utility model has the beneficial effects that: this device makes its staff accessible control frame adjust the position of storage hopper, still can control main electric control push rod through the controller, make opening and closing of its control storage hopper discharge end, avoid the staff to get into the below of press, reduce the possibility that dangerous emergence, the vice electric control push rod of controller still can control in addition stretches out and draws back, make its scraper blade shakeout the magnesium carbon raw materials in to the mould, make the magnesium carbon brick that its press compressed out everywhere density is roughly the same, improve the quality of magnesium carbon brick.

Drawings

FIG. 1 is a schematic view of the structure of the present invention.

FIG. 2 is a schematic view of a storage hopper according to the present invention.

Fig. 3 is a schematic structural diagram of fig. 2A.

In the figure: the device comprises a base 1, a battery 2, a main hydraulic press 3, a rotary table 4, a hydraulic press 5, a rotary joint 6, a support 7, a storage hopper 8, a support plate 9, a main electric control push rod 10, an electric control push rod 11, a striker plate 12, a support rod 13, a fixing block 14, a convex column 15, a scraping plate 16, a spring 17, a control frame 18, a controller 19, a chute 20, a rotary ring 21, an inclined frame 22, a lantern ring 23, a handle 24, a reinforcing rib 25 and a universal wheel 26.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-3, the present invention provides a technical solution: a transfer device for producing magnesia carbon bricks of an electric furnace comprises a base 1 and a battery 2, wherein the upper wall of the base 1 is provided with a main hydraulic press 3 and the battery 2, the battery 2 is the main hydraulic press 3, an auxiliary hydraulic press 5 and a main electric control push rod 10, the auxiliary electric control push rod 11 and the controller 19 provide electric power, the output end of the main hydraulic machine 3 is provided with the rotary table 4, the upper wall of the rotary table 4 is rotatably provided with the auxiliary hydraulic machine 5, the auxiliary hydraulic machine 5 can rotate on the rotary table 4, so that the support 7 and the storage hopper 8 can do circular motion by taking the adapter 6 as a circle center, the main hydraulic machine 3 and the auxiliary hydraulic machine 5 are matched with each other to enlarge the movable range of the height of the storage hopper 8, the adapter 6 is arranged on the upper wall of the auxiliary hydraulic machine 5, the support 7 is welded on the right side wall of the adapter 6, the storage hopper 8 is welded on the inner side wall of the support 7, the storage hopper 8 is used for storing magnesium carbon raw materials, and the main hydraulic machine 3 and the auxiliary hydraulic machine 5 are both electrically connected with the battery 2;

the side wall of the storage hopper 8 is provided with a supporting plate 9 through bolts, the side wall of the supporting plate 9 is provided with a main electric control push rod 10 and an auxiliary electric control push rod 11, the main electric control push rod 10 and the auxiliary electric control push rod 11 are both electrically connected with the battery 2, the output end of the main electric control push rod 10 is provided with a baffle plate 12, when the main electric control push rod 10 extends out, the baffle plate 12 at the output end can seal the discharge end of the storage hopper 8 to prevent magnesium carbon raw materials in the storage hopper 8 from flowing out, when the controller 19 controls the main electric control push rod 10 to retract, the baffle plate 12 shifts to enable the storage hopper 8 to start discharging, the output end of the auxiliary electric control push rod 11 is provided with one end of a support rod 13, the other end of the support rod 13 is provided with a fixed block 14, the side wall of the fixed block 14 is welded with a convex column 15, the outer side wall of the convex column 15 is rotatably provided with a scraper 16, the side wall of the support rod 13 is provided with one end of a spring 17, and the other end of the spring 17 is arranged with the side wall of the scraper 16, after the discharging is finished, the controller 19 can control the auxiliary electric control push rod 11 to repeatedly push out and retract, so that the support rod 13 drives the scraper 16 to flatten the magnesia carbon raw material in the die, the density of each part of the magnesia carbon brick compressed by the press is approximately the same, and the quality of the magnesia carbon brick is improved.

Specifically, a control frame 18 is welded on the left side wall of the adapter 6, a controller 19 is installed on the side wall of the control frame 18, the controller 19 is electrically connected with the battery 2, the main hydraulic press 3, the auxiliary hydraulic press 5, the main electric control push rod 10 and the auxiliary electric control push rod 11, and the controller 19 can control the main hydraulic press 3, the auxiliary hydraulic press 5, the main electric control push rod 10 and the auxiliary electric control push rod 11 to stretch and retract.

Particularly, spout 20 has been seted up to the lateral wall of revolving stage 4, and the inside wall sliding connection of spout 20 has swivel 21, and the sloping 22 can support 7, avoids support 7 to warp because of the gravity of its storage hopper 8, and the one end of sloping 22 is welded to the lateral wall of swivel 21, and the other end welding of sloping 22 has lantern ring 23, and lantern ring 23 cup joints the lateral wall at support 7.

Specifically, a handle 24 is mounted to a side wall of the control frame 18, and the handle 24 is conveniently held by a worker.

Specifically, the reinforcing rib 25 is welded on the side wall of the output end of the main hydraulic press 3, the upper wall of the reinforcing rib 25 is welded with the lower wall of the rotary table 4, and the reinforcing rib 25 improves the bearing capacity and stability of the rotary table 4.

Specifically, universal wheels 26 are mounted at four corners of the lower wall of the base 1, and the universal wheels 26 enable the device to move.

The working principle is as follows: the device is moved to a proper position through a universal wheel 26 on the lower wall of a base 1, a controller 19 controls a main hydraulic press 3 and an auxiliary hydraulic press 5 to be lifted to a proper height, the upper end of a storage hopper 8 is slightly lower than the discharge hole of an external storage device, then a control frame 18 is pulled to rotate the auxiliary hydraulic press 5, the storage hopper 8 is moved to the lower end of the discharge hole of the external storage device, the external storage device conveys materials into the storage hopper 8, the device is moved again after the materials are discharged, the storage hopper 8 is adjusted to be positioned at the upper end of a mold, a main electric control push rod 10 is controlled by the controller 19 to retract, a material baffle plate 12 is controlled by the controller 19 to displace, the storage hopper 8 starts discharging, after the discharging is finished, an auxiliary electric control push rod 11 is controlled by the controller 19 to repeatedly push out and retract, a support rod 13 drives a scraper 16 to flatten magnesium-carbon raw materials in the mold, the density of all parts of the magnesia carbon brick compressed by the press is approximately the same, and the quality of the magnesia carbon brick is improved.

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 utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides an electric stove is transfer device for magnesia carbon brick production, includes base (1) and battery (2), its characterized in that: the hydraulic press is characterized in that a main hydraulic press (3) and a battery (2) are installed on the upper wall of the base (1), a rotary table (4) is installed at the output end of the main hydraulic press (3), an auxiliary hydraulic press (5) is installed on the upper wall of the rotary table (4) in a rotating mode, an adapter (6) is installed on the upper wall of the auxiliary hydraulic press (5), a support (7) is welded to the right side wall of the adapter (6), a storage hopper (8) is welded to the inner side wall of the support (7), and the main hydraulic press (3) and the auxiliary hydraulic press (5) are both electrically connected with the battery (2);

backup pad (9) are installed through the bolt to the lateral wall of storage hopper (8), main electric control push rod (10) and vice electric control push rod (11) are installed to the lateral wall of backup pad (9), main electric control push rod (10) all are connected with battery (2) electricity with vice electric control push rod (11), striker plate (12) are installed to the output of main electric control push rod (10), the one end of branch (13) is installed to the output of vice electric control push rod (11), and fixed block (14) are installed to the other end of branch (13), the lateral wall welding of fixed block (14) has projection (15), scraper blade (16) are installed in the lateral wall rotation of projection (15), the one end of spring (17) is installed to the lateral wall of branch (13), the other end of spring (17) is installed with the lateral wall of scraper blade (16).

2. The transfer device for producing the magnesia carbon bricks of the electric furnace according to claim 1, which is characterized in that: the left side wall welding of adapter (6) has control frame (18), controller (19) are installed to the lateral wall of control frame (18), controller (19) and battery (2), main hydraulic press (3), vice hydraulic press (5), main electric control push rod (10) and vice electric control push rod (11) equal electricity is connected, controller (19) steerable main hydraulic press (3), vice hydraulic press (5), main electric control push rod (10) and vice electric control push rod (11) stretch out and draw back.

3. The transfer device for producing the magnesia carbon bricks of the electric furnace according to claim 1, which is characterized in that: spout (20) have been seted up to the lateral wall of revolving stage (4), the inside wall sliding connection of spout (20) has swivel (21), the lateral wall welding of swivel (21) has the one end of sloping (22), the other end welding of sloping (22) has lantern ring (23), the lateral wall at support (7) is cup jointed in lantern ring (23).

4. The transfer device for producing magnesia carbon bricks of electric furnaces according to claim 2, characterized in that: the side wall of the control frame (18) is provided with a handle (24).

5. The transfer device for producing the magnesia carbon bricks of the electric furnace according to claim 1, which is characterized in that: the side wall of the output end of the main hydraulic press (3) is welded with a reinforcing rib (25), and the upper wall of the reinforcing rib (25) is welded with the lower wall of the rotary table (4).

6. The transfer device for producing the magnesia carbon bricks of the electric furnace according to claim 1, which is characterized in that: universal wheels (26) are installed at four corners of the lower wall of the base (1).

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