CN219956178U - Smelting furnace for mineral processing - Google Patents

Abstract

The utility model discloses a smelting furnace for mineral processing, which comprises a furnace body, a controller, a feed pipe, a discharge pipe, an accelerating flow component, a heating device and a heating device, wherein the accelerating flow component comprises a servo motor, a worm, a rotating shaft, a worm wheel, a stirring rod, a balancing weight, a connecting column, a scraping rod, a sleeve, stirring blades, a protection box, a vibrating rod, a bottom plate, an air pressure sensor and an exhaust valve. The utility model belongs to the technical field of mineral processing, in particular to a smelting furnace for mineral processing, which is characterized in that the rotating speed of a rotating shaft is reduced, the rotating resistance of a stirring rod can be reduced by matching with a through hole on the stirring rod, stirring blades can rotate along with the stirring rod after stirring and flowing molten mineral metal, the flowing effect of the molten mineral metal is improved, the scraping rod can scrape the molten mineral metal on a furnace body to flow together, the flowing of the molten mineral metal is accelerated by the arrangement of a vibrating rod, and the occurrence of the condition of uneven local temperature is avoided.

Description

Smelting furnace for mineral processing

Technical Field

The utility model belongs to the technical field of mineral processing, and particularly relates to a smelting furnace for mineral processing.

Background

The smelting furnace is equipment for smelting metal ingots, minerals and some waste metals into required alloy by adding necessary alloy components, slagging off, refining and the like, and is mainly characterized by light equipment, high heating speed and high efficiency; particularly, electricity is saved, and the electricity consumption with the load is saved by 60% compared with the high-frequency machine of the valve; the metal heating device has various protection functions such as overcurrent, overvoltage, overheat and the like, is simple to operate and convenient to install, and is suitable for various occasions needing to heat metal. In the process of smelting minerals in a smelting furnace, mineral metals are generally in a molten state under high-temperature conditions, but the mineral metals have high density and poor fluidity, so that local temperature can be in an uneven state.

Disclosure of Invention

Aiming at the situation, in order to overcome the defects of the prior art, the utility model provides the smelting furnace for mineral processing, which reduces the rotating speed of a rotating shaft, is matched with the through hole on the stirring rod, so that the rotating resistance of the stirring rod is reduced, the stirring rod can rotate along with the stirring blade after stirring and flowing the molten mineral metal, the flowing effect of the molten mineral metal is improved, the scraping rod can scrape the molten mineral metal on the furnace body to flow together, the flow of the molten mineral metal is accelerated by the arrangement of the vibrating rod, and the occurrence of the condition of uneven local temperature is avoided.

The technical scheme adopted by the utility model is as follows: the smelting furnace for mineral processing comprises a furnace body, a controller, a feeding pipe and a discharging pipe, wherein the controller is arranged on the outer side wall of the furnace body, the feeding pipe is arranged at the top of the furnace body, the discharging pipe is arranged at the center of the bottom of the furnace body, the smelting furnace further comprises an accelerating flow component, the accelerating flow component is arranged inside the furnace body, and the accelerating flow component comprises a servo motor, a worm, a rotating shaft, a worm wheel, a stirring rod, a balancing weight, a connecting column, a scraping rod, a sleeve, stirring blades, a protection box, a vibrating rod, a bottom plate, an air pressure sensor and an exhaust valve; the utility model provides a furnace body, including furnace body, upper wall, bottom plate, vibrating rod, air pressure sensor, servo motor fixed mounting is at the furnace body roof, servo motor output is located to the worm, the pivot runs through the furnace body top and rotates with the furnace body to be connected, the pivot intermediate position is located to the worm wheel is fixed, the puddler runs through the pivot lower extreme and with pivot fixed connection, the puddler upper end is located to the balancing weight is fixed, the puddler lateral wall is located to the spliced pole is fixed, the spliced pole is fixed to be located spliced pole one end, the sleeve runs through the puddler and rotates with the puddler to be connected, the sleeve is vertical equidistant range setting, the stirring leaf is fixed to be located the sleeve lateral wall, the stirring leaf is evenly arranged and sets up, the protection box is fixed to be located between the furnace body inside wall, vibrating rod fixed mounting is inside the protection box, the vibrating rod lower extreme passes the protection box and with protection box fixed connection, the bottom plate is fixed to be located the furnace body inner bottom wall, the bottom plate is the symmetry setting, air pressure sensor is fixed to be located the furnace body roof, the discharge valve is fixed to be located at the top.

Further, the top wall of the bottom plate is obliquely arranged.

Further, through holes are formed in the stirring rod and are arranged at equal intervals.

Further, the worm wheel is meshed with the worm.

Further, the controller is electrically connected with the servo motor, the vibrating rod, the air pressure sensor and the exhaust valve.

After the structure is adopted, the utility model has the following beneficial effects: according to the smelting furnace for mineral processing, the density of mineral metal in a molten state is high, so that the rotating speed of a rotating shaft is reduced through meshing transmission of a worm and a worm wheel, the rotating resistance of a stirring rod can be reduced, stirring blades rotate along with the stirring rod after stirring and flowing the mineral metal in the molten state, the flowing effect of the mineral metal in the molten state is improved, the scraper rod can scrape the mineral metal in the molten state on a furnace body to flow together, the vibration rod accelerates the flowing of the mineral metal in the molten state, the occurrence of uneven local temperature is avoided, the air pressure is monitored by the air pressure sensor in order to prevent the air pressure in the furnace body from being too high, the air pressure is ensured to be stable by opening an exhaust valve to discharge air if the air pressure is high, the whole structure design is simple and reasonable, and the practicability is improved.

Drawings

The accompanying drawings are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate the utility model and together with the embodiments of the utility model, serve to explain the utility model.

FIG. 1 is a schematic diagram of the overall structure of a smelting furnace for mineral processing according to the present utility model;

fig. 2 is a sectional view of a smelting furnace for mineral processing according to the present utility model.

In the drawings: 1. furnace body, 2, controller, 3, inlet pipe, 4, discharging pipe, 5, acceleration flow subassembly, 6, servo motor, 7, worm, 8, pivot, 9, worm wheel, 10, puddler, 11, balancing weight, 12, spliced pole, 13, scrape the pole, 14, sleeve, 15, stirring leaf, 16, protection box, 17, vibrating spear, 18, bottom plate, 19, air pressure sensor, 20, discharge valve, 21, through-hole.

Detailed Description

As shown in figure 1, the smelting furnace for mineral processing comprises a furnace body 1, a controller 2, a feeding pipe 3 and a discharging pipe 4, wherein the controller 2 is arranged on the outer side wall of the furnace body 1, the feeding pipe 3 is arranged at the top of the furnace body 1, and the discharging pipe 4 is arranged at the center of the bottom of the furnace body 1.

As shown in fig. 1-2, the device further comprises an accelerating flow component 5, wherein the accelerating flow component 5 is arranged inside the furnace body 1, and the accelerating flow component 5 comprises a servo motor 6, a worm 7, a rotating shaft 8, a worm wheel 9, a stirring rod 10, a balancing weight 11, a connecting column 12, a scraping rod 13, a sleeve 14, stirring blades 15, a protection box 16, a vibrating rod 17, a bottom plate 18, an air pressure sensor 19 and an exhaust valve 20.

Preferably, in order to accelerate the flow of the mineral metal in the molten state, avoid the uneven condition of local temperature to take place, servo motor 6 fixed mounting is at furnace body 1 roof, servo motor 6 output is located to worm 7, pivot 8 runs through furnace body 1 top and rotates with furnace body 1 to be connected, worm wheel 9 is fixed to be located pivot 8 intermediate position, puddler 10 runs through pivot 8 lower extreme and with pivot 8 fixed connection, balancing weight 11 is fixed to be located puddler 10 upper end, spliced pole 12 is fixed to be located puddler 10 lateral wall, spliced pole 12 is vertical equidistant arrangement setting, scraper bar 13 is fixed to be located spliced pole 12 one end, sleeve 14 runs through puddler 10 and rotates with puddler 10 to be connected, sleeve 14 is vertical equidistant arrangement setting, stirring leaf 15 is fixed to be located sleeve 14 lateral wall, stirring leaf 15 is evenly arranged setting, protection box 16 is fixed to be located between the furnace body 1 inside wall, vibrating rod 17 fixed mounting is inside protection box 16, vibrating rod 17 lower extreme passes protection box 16 and is fixed with protection box 16, bottom plate 18 is fixed to be located furnace body 1 inner wall, bottom plate 18 is symmetrical setting, barometric sensor 19 is fixed to be located in 1 roof, 20 fixed to be located in top 1, 20 are fixed to be equipped with 21 on stirring rod 10, 21 is equidistant arrangement setting through hole.

Preferably, the top wall of the bottom plate 18 is inclined in order to facilitate the outflow of the mineral metal in the molten state.

The worm wheel 9 is meshed with the worm 7, and the controller 2 is electrically connected with the servo motor 6, the vibrating rod 17, the air pressure sensor 19 and the exhaust valve 20.

When the stirring rod 10 is rotated, the stirring blades 15 rotate, the flowing effect of the mineral metal in the molten state is improved, the scraping rod 13 scrapes the mineral metal in the molten state on the inner side wall of the furnace body 1, the difference between the temperature of the mineral metal in the molten state on the inner wall of the furnace body 1 and the temperature inside the furnace body 1 is prevented, the vibrating rod 17 is started, the vibrating rod 17 also increases the flowing effect of the mineral metal in the molten state, the air pressure sensor 19 monitors the air pressure, if the air pressure is higher, the air outlet valve 20 is opened to discharge air, the air pressure stability can be ensured, and the air pressure inside the furnace body 1 is prevented.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents. In summary, if one of ordinary skill in the art is informed by this disclosure, a structural manner and an embodiment similar to the technical solution should not be creatively devised without departing from the gist of the present utility model.

Claims (5)

1. The utility model provides a smelting furnace for mineral processing, includes furnace body, controller, inlet pipe and discharging pipe, the controller is installed on the furnace body lateral wall, the furnace body top is located to the inlet pipe, furnace body bottom center department, its characterized in that are located to the discharging pipe: the device comprises a furnace body, a stirring rod, a balancing weight, a connecting column, a scraping rod, a sleeve, stirring blades, a protection box, a vibrating rod, a bottom plate, an air pressure sensor and an exhaust valve, and is characterized by further comprising an accelerating flow component, wherein the accelerating flow component is arranged inside the furnace body and comprises a servo motor, a worm, a rotating shaft, a worm wheel, the stirring rod, the balancing weight, the connecting column, the scraping rod, the sleeve, the stirring blades, the protection box, the vibrating rod, the bottom plate, the air pressure sensor and the exhaust valve;

the utility model provides a furnace body, including furnace body, upper wall, bottom plate, vibrating rod, air pressure sensor, servo motor fixed mounting is at the furnace body roof, servo motor output is located to the worm, the pivot runs through the furnace body top and rotates with the furnace body to be connected, the pivot intermediate position is located to the worm wheel is fixed, the puddler runs through the pivot lower extreme and with pivot fixed connection, the puddler upper end is located to the balancing weight is fixed, the puddler lateral wall is located to the spliced pole is fixed, the spliced pole is fixed to be located spliced pole one end, the sleeve runs through the puddler and rotates with the puddler to be connected, the sleeve is vertical equidistant range setting, the stirring leaf is fixed to be located the sleeve lateral wall, the stirring leaf is evenly arranged and sets up, the protection box is fixed to be located between the furnace body inside wall, vibrating rod fixed mounting is inside the protection box, the vibrating rod lower extreme passes the protection box and with protection box fixed connection, the bottom plate is fixed to be located the furnace body inner bottom wall, the bottom plate is the symmetry setting, air pressure sensor is fixed to be located the furnace body roof, the discharge valve is fixed to be located at the top.

2. A smelting furnace for mineral processing in accordance with claim 1 wherein: the top wall of the bottom plate is obliquely arranged.

3. A smelting furnace for mineral processing in accordance with claim 2 wherein: the stirring rod is provided with through holes which are arranged at equal intervals.

4. A smelting furnace for mineral processing as claimed in claim 3, wherein: the worm wheel is meshed with the worm.

5. A smelting furnace for mineral processing as defined in claim 4, wherein: the controller is electrically connected with the servo motor, the vibrating rod, the air pressure sensor and the exhaust valve.