CN210048669U - Place stable steelframe platform for production of vitrified micro bubbles - Google Patents

Abstract

The utility model discloses a place stable steelframe platform for vitrified micro bubble production, including the steelframe plate body, the bottom four corners outer wall of steelframe plate body all has the supporting leg through bolted connection, and the bottom outer wall of supporting leg has rubber base through bolted connection, the first strengthening rib of slope is all welded to the bottom four corners outer wall of steelframe plate body, and one end that the steelframe plate body was kept away from to first strengthening rib welds with one side outer wall of supporting leg mutually, the top outer wall of steelframe plate body has the screening casing through bolted connection, and screens casing one side outer wall and have the material loading casing through bolted connection, the top and the bottom inner wall of material loading casing rotate through the bearing and are connected with the rotation axis that same. The utility model discloses in, be provided with first strengthening rib and second strengthening rib, what make steelframe plate body and supporting leg can be more stable fixes on the workplace, and the work that makes the device can be stable has improved the production quality of vitrification microballon.

Description

Place stable steelframe platform for production of vitrified micro bubbles

Technical Field

The utility model relates to a vitrified micro bubble production technical field especially relates to a place stable steelframe platform for vitrified micro bubble production.

Background

The vitrified micro bubbles have certain particle strength due to surface vitrification, are very stable in physical and chemical properties and strong in aging resistance and weather resistance, have excellent heat insulation, fire prevention and sound absorption properties, and are suitable for being used as light filling aggregates and heat insulation, fire prevention, sound absorption and heat insulation materials in various fields. In the building material industry, the vitrified micro bubbles are used as lightweight aggregate, so that the workability and the self-resistance strength of mortar can be improved, the material shrinkage rate is reduced, the comprehensive performance of products is improved, and the comprehensive production cost is reduced.

A plurality of production facilities need be used in vitrified micro bubble production, very big occupation land space like this, these equipment are all installed on the steelframe platform, but present steelframe platform is fixed unstable, the fixed production facility that can not be reasonable on present steelframe platform moreover to production facility on the steelframe platform does not have the function of carrying out the screening with smashing the back ore sand, can not obtain high-quality vitrified micro bubble like this.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the defects existing in the prior art, and providing a steel frame platform for placing stable vitrified micro bubbles for production, which can effectively solve the problem provided by the background technology.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a steel frame platform for placing stable vitrified micro bubbles for production comprises a steel frame plate body, wherein the outer walls of the four corners at the bottom of the steel frame plate body are all connected with supporting legs through bolts, the outer walls of the bottom of the supporting legs are connected with rubber bases through bolts, the outer walls of the four corners at the bottom of the steel frame plate body are all welded with inclined first reinforcing ribs, one end, far away from the steel frame plate body, of each first reinforcing rib is welded with the outer wall of one side of each supporting leg, the outer wall of the top of the steel frame plate body is connected with a screening shell through bolts, the outer wall of one side of the screening shell is connected with a feeding shell through bolts, the inner walls at the top and the bottom of the feeding shell are rotatably connected with a rotating shaft which is obliquely placed through bearings, the outer wall of the circumference of the rotating shaft is connected with spiral blades which are distributed equidistantly through, the inner walls of the two ends of the screening shell are connected with a dispersion plate placed in the same inclined mode through tension springs, and the outer wall of the bottom of the dispersion plate is connected with a vibration motor through bolts.

Preferably, the outer wall of the bottom of the feeding shell is connected with a motor through a bolt, and the output end of the motor is fixedly connected with the outer wall of the bottom of the rotating shaft through a bolt.

Preferably, the top of the inner walls of the two sides of the screening shell is provided with a first sliding groove, the inner wall of the first sliding groove is connected with a first screening screen plate which is placed in an inclined mode in a sliding mode, the bottom of the inner walls of the two sides of the screening shell is provided with a second sliding groove, and the inner wall of the second sliding groove is connected with a second screening screen plate which is placed in an inclined mode in a sliding mode.

Preferably, the inner wall of the bottom of the screening shell is connected with a storage shell in a sliding mode, and the outer wall of one end of the storage shell is connected with a third handle through a bolt.

Preferably, the outer wall of one side of the screening shell is connected with the heating shell through a bolt, the inner walls of the two sides of the heating shell are connected with heating wires distributed at equal intervals through screws, and the top of the inner wall of one side of the screening shell is connected with a filter screen through a screw.

Preferably, the outer wall of one side of the top of the steel frame plate body is connected with an air pump through a bolt, the air inlet end of the air pump is connected with a connecting air pipe through a flange, and one end, far away from the air pump, of the connecting air pipe extends to the inside of the heating shell.

Preferably, the outer wall of the other side of the top of the steel frame plate body is connected with an electric heating furnace through a bolt, the feeding end of the electric heating furnace is connected with a connecting hopper through a bolt, one end, far away from the electric heating furnace, of the connecting hopper extends to the inside of the steel frame plate body, and the outer wall of one end of the top of the steel frame plate body is connected with a storage shell through a bolt.

Compared with the prior art, the beneficial effects of the utility model are that:

1. through being provided with first strengthening rib and second strengthening rib, make the work that steelframe plate body and supporting leg can be more stable fix on the workplace, make the device can be stable, improved vitrified micro bubble's production quality.

2. Through being provided with motor, rotation axis and helical blade, can enter into the screening casing through hopper after smashing, make things convenient for the material loading, improve work efficiency, be provided with first screening otter board and second screening otter board, can filter the ore sand after smashing, enter into the electric heat stove through the connecting hopper with the ore sand of qualified size, be favorable to obtaining the vitrification microballon of high quality.

3. Through being provided with dispersion board and vibrating motor, can disperse the ore sand that drops, improved the screening quality, be provided with aspiration pump and heater strip, can heat the inside ore sand of screening casing, the convenience next electric heater has improved work efficiency to the processing of ore sand.

Drawings

FIG. 1 is a schematic view of a cross-sectional structure of a steel frame platform for stably placing vitrified micro bubbles;

FIG. 2 is a schematic structural view of a stable steel frame platform for vitrified microsphere production according to the present invention;

fig. 3 is a schematic view of a local side structure of a steel frame platform for placing a stable vitrified small ball production according to the present invention.

In the figure: 1 heater strip, 2 feeding hoppers, 3 helical blade, 4 rotation axes, 5 motors, 6 air pumps, 7 first strengthening ribs, 8 second screening otter boards, 9 first screening otter boards, 10 storage casings, 11 rubber bases, 12 supporting legs, 13 steel frame boards, 14 electric heating furnaces, 15 connecting hoppers, 16 screening casings, 17 dispersion plates, 18 vibrating motors, 19 blanking hoppers, 20 filter screens, 21 feeding casings, 22 heating casings and 23 storage casings.

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.

Referring to fig. 1-3, a steel frame platform for producing vitrified micro bubbles with stable placement comprises a steel frame plate body 13, wherein the outer walls of four corners at the bottom of the steel frame plate body 13 are all connected with supporting legs 12 through bolts, the outer walls of the bottom of the supporting legs 12 are connected with rubber bases 11 through bolts, the outer walls of the four corners at the bottom of the steel frame plate body 13 are all welded with inclined first reinforcing ribs 7, one end of each first reinforcing rib 7, which is far away from the steel frame plate body 13, is welded with the outer wall of one side of each supporting leg 12, the bottom of the outer wall of one side, which is opposite to the adjacent two supporting legs 12, is welded with the same horizontally placed second reinforcing rib, the outer wall at the top of the steel frame plate body 13 is connected with a screening shell 16 through bolts, the outer wall at one side of the screening shell 16 is connected with a feeding shell 21 through bolts, the bottom of the outer wall at, and the circumference outer wall of rotation axis 4 has equidistant distribution's helical blade 3 through bolted connection, it has feeding funnel 2 to peg graft in feeding casing 21 one side outer wall bottom, and it has lower hopper 19 to peg graft in the opposite side outer wall top of feeding casing 21, the one end that feeding casing 21 was kept away from to lower hopper 19 extends to the inside of screening casing 16, the inner wall of screening casing 16 both ends is connected with the dispersion board 17 that same slope was placed through the extension spring, and there is vibrating motor 18 bottom outer wall of dispersion board 17 through bolted connection.

In the utility model, the bottom outer wall of the feeding shell 21 is connected with a motor 5 through a bolt, the output end of the motor 5 is fixedly connected with the bottom outer wall of the rotating shaft 4 through a bolt, the top parts of the inner walls at two sides of the screening shell 16 are provided with first sliding grooves, the inner walls of the first sliding grooves are connected with a first screening mesh plate 9 which is obliquely arranged in a sliding way, the outer wall at one end of the first screening mesh plate 9 is connected with a first handle through a screw, the bottom parts of the inner walls at two sides of the screening shell 16 are provided with second sliding grooves, the inner wall of the second sliding grooves is connected with a second screening mesh plate 8 which inclines downwards in a sliding way, the outer wall at one end of the second screening mesh plate 8 is connected with a second handle through a screw, the bottom inner wall of the screening shell 16 is connected with a storage shell 10 in a sliding way, the outer, the inner walls of two sides of the heating shell 22 are connected with heating wires 1 which are distributed equidistantly through screws, the outer wall of the top of the screening shell 16 is inserted with an air inlet pipe, one end of the air inlet pipe, which is far away from the heating shell 22, extends into the screening shell 16, the top of the inner wall of one side of the screening shell 16 is connected with a filter screen 20 through screws, the filter screen 20 is positioned on the outer wall of one side of the air inlet pipe, the outer wall of one side of the top of the steel frame plate body 13 is connected with an air extracting pump 6 through bolts, the air inlet end of the air extracting pump 6 is connected with a connecting air pipe through a flange, one end of the connecting air pipe, which is far away from the air extracting pump 6, extends into the screening shell 16, the outer wall of the other side of the top of the steel frame plate body 13 is connected with an electric heating furnace 14 through bolts, and, connecting hopper 15 keeps away from the inside that the one end of electric heater 14 extends to steelframe plate body 13, and connecting hopper 15's top outer wall has the governing valve through flange joint, and steelframe plate body 13 top one end outer wall has storage casing 23 through bolted connection, and 16 one end outer walls of screening casing are pegged graft and are had a hopper, and it is inside that the one end of keeping away from screening casing 16 extends to storage casing 23 to go out the hopper, goes out the hopper and is located the top of second screening otter board 8.

The working principle is as follows: in the spare part of the device, all driving parts, which refer to power elements, electric devices and adaptive power supplies, are connected through leads, and a specific connection means refers to the following working principle that the electric devices are electrically connected in sequence, and the detailed connection means is a known technology in the field, and the following main introduces the working principle and process without describing the electric control, the device is fixed on a working place, then the power supply is externally connected, crushed ore sand enters a feeding shell 21 through a feeding hopper 2, then a motor 5 is started through a switch, a spiral blade 3 is driven to rotate through a rotating shaft 4, the ore sand flows into a screening shell 16 through a discharging hopper 19, then a first screening screen plate 9 and a second screen plate 8 which are suitable for the size specification are inserted into the screening shell 16, and then a vibration motor 18 is started to drive a dispersion plate 17 to vibrate, dispersing the falling ore sand, then starting the heating wire 1 and the air pump 6 to heat the ore sand, and then screening the ore sand with qualified size to enter the electric heating furnace 14 through the connecting hopper 15 to vitrify the ore sand to obtain vitrified micro bubbles.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (7)

1. The steel frame platform for placing the stable vitrified micro bubbles for production comprises a steel frame plate body (13) and is characterized in that the outer walls of the four corners of the bottom of the steel frame plate body (13) are respectively connected with a supporting leg (12) through a bolt, the outer wall of the bottom of the supporting leg (12) is connected with a rubber base (11) through a bolt, the outer wall of the four corners of the bottom of the steel frame plate body (13) is welded with a first inclined reinforcing rib (7), one end, away from the steel frame plate body (13), of the first reinforcing rib (7) is welded with the outer wall of one side of the supporting leg (12), the outer wall of the top of the steel frame plate body (13) is connected with a screening shell (16) through a bolt, the outer wall of one side of the screening shell (16) is connected with a feeding shell (21) through a bolt, and the inner walls of, and the circumference outer wall of rotation axis (4) has helical blade (3) that the equidistance distributes through bolted connection, it has feeding funnel (2) to peg graft in feeding casing (21) one side outer wall bottom, and pegs graft in the opposite side outer wall top of feeding casing (21) has down hopper (19), screening casing (16) both ends inner wall is connected with dispersion board (17) that same slope was placed through the extension spring, and the bottom outer wall of dispersion board (17) has vibrating motor (18) through bolted connection.

2. The placed and stabilized steel frame platform for vitrified microsphere production according to claim 1, wherein the outer wall of the bottom of the feeding shell (21) is connected with a motor (5) through a bolt, and the output end of the motor (5) is fixedly connected with the outer wall of the bottom of the rotating shaft (4) through a bolt.

3. The stable placement steel frame platform for vitrified micro bubble production of claim 2, wherein the screening shell (16) is provided with a first sliding groove on the top of the inner wall at both sides, the inner wall of the first sliding groove is slidably connected with a first screening net plate (9) which is obliquely placed, the bottom of the inner wall at both sides of the screening shell (16) is provided with a second sliding groove, and the inner wall of the second sliding groove is slidably connected with a second screening net plate (8) which is obliquely downward.

4. The stable placement steel frame platform for vitrified microsphere production according to claim 3, characterized in that the inner wall of the bottom of the screening shell (16) is connected with the storage shell (10) in a sliding way, and the outer wall of one end of the storage shell (10) is connected with a third handle through a bolt.

5. The placed and stabilized steel frame platform for vitrified micro bubble production according to claim 4, characterized in that the outer wall of one side of the screening shell (16) is connected with the heating shell (22) through bolts, the inner walls of the two sides of the heating shell (22) are connected with heating wires (1) which are distributed equidistantly through screws, and the top of the inner wall of one side of the screening shell (16) is connected with the filter screen (20) through screws.

6. The placed and stabilized steel frame platform for vitrified microsphere production according to claim 5, wherein the outer wall of one side of the top of the steel frame plate body (13) is connected with an air suction pump (6) through a bolt, the air inlet end of the air suction pump (6) is connected with a connecting air pipe through a flange, and one end of the connecting air pipe, which is far away from the air suction pump (6), extends to the inside of the heating shell (22).

7. The placed and stabilized steel frame platform for vitrified microsphere production according to claim 6, wherein the outer wall of the other side of the top of the steel frame plate body (13) is connected with an electric heating furnace (14) through bolts, the feeding end of the electric heating furnace (14) is connected with a connecting hopper (15) through bolts, one end of the connecting hopper (15) far away from the electric heating furnace (14) extends into the steel frame plate body (13), and the outer wall of one end of the top of the steel frame plate body (13) is connected with a storage shell (23) through bolts.

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