CN114618659A - Rock wool electric furnace lining processing device based on silicon-carbon composite material and processing method thereof - Google Patents

Abstract

The invention discloses a rock wool electric furnace lining processing device based on a silicon-carbon composite material and a processing method thereof. According to the invention, when materials enter the inverted cone processing barrel, the gravity of the materials is pressed downwards under the action of the baffle plate, so that the telescopic shell moves up and down along the inside of the chute under the action of the gravity ball, and therefore, an effect of turning the materials up and down can be achieved while the solid materials are rotationally stirred, so that the effect of passing the materials through the sieving holes is enhanced.

Description

Rock wool electric furnace lining processing device based on silicon-carbon composite material and processing method thereof

Technical Field

The invention relates to the technical field of electric furnaces, in particular to a rock wool electric furnace lining processing device based on a silicon-carbon composite material and a processing method thereof.

Background

It is known that, in the heat energy consumption during the operation of an industrial furnace, only the heat energy for heating the workpiece is effective energy consumption, and in the ineffective energy consumption, the energy consumption for heating the tool clamp lifting appliance and heating the control atmosphere is required by the process, and under the conditions of reasonable design and correct process, the energy consumption can not be saved, and in the ineffective energy consumption which can be saved, the heat energy consumption of the furnace lining is the largest and is divided into two parts, namely heat storage energy consumption and heat dissipation energy consumption, wherein the former is 'one-time' energy consumption which is irrelevant to the continuous working time of the industrial furnace, and the latter is a function of the working time, but both of the two parts are relevant to the material and the structure of the furnace lining.

Along with the development of industry and science and technology, the furnace lining materials and structures of industrial furnaces in China are continuously improved, the energy-saving effect is continuously improved from the original light refractory bricks and vermiculite powder to the microbead bricks and the aluminum silicate fiber felt and the perlite to the fiber-based prefabricated part structure and the full fiber structure, the common carbon materials are used as the furnace lining of rock wool and are extremely easy to be corroded and consumed by slag, the silicon recovery material special for the rock wool furnace designed by the special formula has excellent slag corrosion resistance, the service life of the furnace lining of the rock wool furnace can reach more than 3 times of that of the common carbon furnace lining, the slag corrosion resistance is realized, the consumption is reduced, the air oxidation resistance is realized, the service life is prolonged, and the construction at normal temperature is carried out without heating.

In the prior art, when the silicon-carbon composite material is used for processing and producing the furnace lining, a plurality of substances are required to be mixed together, so that the quality of the furnace lining is enhanced, but when the silicon-carbon composite material is produced, a plurality of materials are mixed, a large solid material possibly exists in the silicon-carbon composite material, and the large solid material can cause the mixture to be mixed unevenly, so that the preparation of the silicon-carbon composite material is influenced, and the quality effect of the furnace lining is seriously influenced.

Disclosure of Invention

In order to solve the technical problems, the invention provides a rock wool electric furnace lining processing device based on a silicon-carbon composite material, which comprises a processing box, wherein the top opening of the processing box is arranged, the upper side wall of the processing box is communicated with a liquid feeding pipe, the lower side wall of the processing box is communicated with a discharge valve, a stirring shaft is arranged at the inner middle shaft of the processing box, the bottom of the stirring shaft is rotatably connected with the inner wall of the bottom side of the processing box through a bearing, the top of the stirring shaft extends to the outer side of the top of the processing box, the top of the stirring shaft is fixedly connected with a motor, the upper side inside of the processing box is fixedly connected with a reverse conical processing cylinder, the top opening of the reverse conical processing cylinder is arranged, the bottom of the reverse conical processing cylinder is provided with a sieve separating hole, the bottom wall of the reverse conical processing cylinder penetrates through the stirring shaft, and the inside of the stirring shaft is hollowed, the spout has been seted up to the lateral wall of (mixing) shaft, the inside slip of upside of (mixing) shaft is provided with the gravity ball, the outer wall of gravity ball sets up with the inner wall contact of (mixing) shaft, the outer wall fixedly connected with telescopic shell of gravity ball, the one end that the gravity ball was kept away from to telescopic shell slides and runs through the inside of spout and extend to the outside, wherein, the inside slip of telescopic shell is provided with the telescopic link, the one end fixedly connected with extension spring of telescopic link, the one end that the telescopic link was kept away from to the extension spring and the outer wall fixed connection of gravity ball, the one end fixedly connected with arc carriage release lever of extension spring is kept away from to the telescopic link, the outer wall of arc carriage release lever sets up with the inner wall contact of back taper processing section of thick bamboo.

Furthermore, a baffle is fixedly connected between every two telescopic shells, an inclined swinging rod is hinged to the bottom center shaft of the baffle, a connecting spring is fixedly connected to the outer wall center shaft of the inclined swinging rod, and one end, far away from the inclined swinging rod, of the connecting spring is fixedly connected with the outer wall of the stirring shaft.

Furthermore, one end of the inclined swinging rod, which is far away from the baffle plate, is fixedly connected with a grinding ball, and one end of the grinding ball, which is far away from the inclined swinging rod, is in contact with the inner wall of the bottom side of the inverted cone-shaped processing cylinder.

Further, the bottom side outer wall axis department fixedly connected with connecting rod of gravity ball, the one end fixedly connected with auxiliary ball that the gravity ball was kept away from to the connecting rod, the outer wall of auxiliary ball sets up with the inner wall contact of (mixing) shaft, the one end fixedly connected with extension spring that the connecting rod was kept away from to the auxiliary ball, wherein, the one end that the auxiliary ball was kept away from to the extension spring is fixedly connected with the bottom side inner wall of (mixing) shaft.

Further, the outer wall fixedly connected with centrifugal rod of supplementary ball, the inside of centrifugal rod is hollowed out and is set up, the one end that supplementary ball was kept away from to the centrifugal rod slides and runs through the inside of spout and extends to the outside, the inside slip of centrifugal rod is provided with centrifugal push rod.

Furthermore, one end of the centrifugal push rod is arranged in a spherical shape, one end of the centrifugal push rod is fixedly connected with a centrifugal spring, and one end, far away from the centrifugal push rod, of the centrifugal spring is fixedly connected with the outer wall of the auxiliary ball.

Furthermore, one end of the centrifugal push rod, which is far away from the centrifugal spring, is fixedly connected with a mixing reinforcing rod, and an elastic pushing net is fixedly connected between every two mixing reinforcing rods.

Furthermore, the bottom of the mixing reinforcing rod is arranged in a spherical shape, inertia rings are sleeved on the outer surface of the mixing reinforcing rod in a sliding mode, every two inertia rings are provided with inertia balls, two side walls of each inertia ball are fixedly connected with inertia springs respectively, and one ends, far away from the inertia balls, of the inertia springs are fixedly connected with the outer walls of the inertia rings.

A rock wool electric furnace lining processing device based on silicon-carbon composite material comprises the following processing methods:

s1: the working personnel can add the solid material into the inverted cone-shaped processing barrel, add the liquid material into the processing box through the liquid feeding pipe, meanwhile, the motor is started, the stirring shaft is driven to rotate by the starting of the motor, so that the aim of stirring materials is fulfilled, when the materials enter the inverted cone-shaped processing barrel, under the action of the baffle plate, the gravity of the material can be pressed downwards, so that the telescopic shell can move up and down along the inner part of the chute under the action of the gravity ball, therefore, the stirring device has an effect of stirring the solid materials up and down while rotating the solid materials, thereby enhancing the effect of passing the materials through the sieving holes, when the telescopic shell moves up and down, the telescopic rod can drive the arc-shaped moving rod to move up and down along the inner wall of the inverted cone-shaped processing cylinder, therefore, the materials adsorbed on the inner part of the inverted cone-shaped processing barrel can be cleaned, and the processing effect of the device is enhanced;

s2: when the baffle moves up and down, the inclined swinging rod can be forced to rotate, so that the grinding balls can be driven to transversely move back and forth along the inner wall of the bottom side of the inverted cone-shaped processing cylinder, the effect of grinding massive solid materials can be achieved by utilizing the moving effect, the contact area of the solid materials and liquid materials is increased, the solid materials can conveniently pass through the sieving holes, and the processing effect of the device is enhanced;

s3: when the gravity ball moves up and down, the connecting rod and the auxiliary ball are driven to move up and down, so that the centrifugal rod and the elastic pushing net can be driven to move up and down, and on the other hand, when the centrifugal rod rotates, the centrifugal force generated can drive the centrifugal push rod to move transversely, so that the mixing enhancement rod can drive the elastic pushing net to move transversely along the inner part of the mixed material, and the mixing effect of the device on the materials is enhanced in all directions;

s4: when mixing the reinforcing bar and reciprocating, under the effect of inertial force, can make inertia ring move inertia ball and inertia spring and reciprocate along mixing the outer wall of reinforcing bar, simultaneously because the inertia spring has elasticity, when just so making inertia ball reciprocate under the inertia ring drives, utilize centrifugal effect, can outwards swing, and then improved the device to the frequency of material stirring to this processing effect that has strengthened the device.

Compared with the prior art, the invention has the beneficial effects that:

(1) according to the invention, when materials enter the inverted cone processing barrel, under the action of the baffle, the gravity of the materials can be pressed downwards, so that the telescopic shell moves up and down along the inside of the chute under the action of the gravity ball, and therefore, the effect of turning the materials up and down can be achieved while the solid materials are rotationally stirred, so that the effect of passing the materials through the sieving holes is enhanced, when the telescopic shell moves up and down, the telescopic rod can drive the arc-shaped moving rod to move up and down along the inner wall of the inverted cone processing barrel, so that the materials adsorbed on the inside of the inverted cone processing barrel can be cleaned, and the processing effect of the device is enhanced.

(2) When the baffle plate moves up and down, the inclined swinging rod can be forced to rotate, so that the grinding balls can be driven to transversely move back and forth along the inner wall of the bottom side of the inverted cone-shaped processing cylinder, the effect of grinding massive solid materials can be achieved by utilizing the moving effect, the contact area of the solid materials and liquid materials is increased, the solid materials can conveniently pass through the sieving holes, and the processing effect of the device is enhanced.

(3) When the gravity ball moves up and down, the connecting rod and the auxiliary ball are driven to move up and down, so that the centrifugal rod and the elastic pushing net can be driven to move up and down, and on the other hand, when the centrifugal rod rotates, the centrifugal force generated can drive the centrifugal push rod to move transversely, so that the mixing reinforcing rod can drive the elastic pushing net to move transversely along the inner part of the mixed material, and the mixing effect of the device on the materials is enhanced in all directions.

(4) According to the invention, when the mixing reinforcing rod moves up and down, the inertia ring can drive the inertia ball and the inertia spring to move up and down along the outer wall of the mixing reinforcing rod under the action of the inertia force, and meanwhile, the inertia spring has elasticity, so that the inertia ball can swing outwards by utilizing a centrifugal effect while moving up and down under the driving of the inertia ring, and the frequency of the device for stirring materials is further improved, thereby enhancing the processing effect of the device.

Drawings

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

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

FIG. 3 is an enlarged view of A in FIG. 2 according to the present invention;

FIG. 4 is an enlarged view of B of FIG. 2 according to the present invention;

FIG. 5 is a schematic view of the overall structure of the grinding ball of the present invention;

FIG. 6 is a schematic view of the overall structure of the inverted cone-shaped processing cylinder of the present invention;

FIG. 7 is a schematic view of the overall structure of the elastic push net of the present invention;

FIG. 8 is a schematic view of the overall structure of the inertia ball of the present invention;

FIG. 9 is an overall flow chart of the processing method of the present invention.

In the figure: 1. a processing box; 11. a liquid feed pipe; 12. a discharge valve; 13. a stirring shaft; 14. a motor; 2. an inverted cone shaped processing cylinder; 21. dividing sieve pores; 22. a chute; 3. a gravity ball; 31. a telescoping shell; 32. a telescopic rod; 33. a tension spring; 34. an arc-shaped moving rod; 4. a baffle plate; 41. a tilt swing lever; 42. a connecting spring; 43. grinding balls; 5. a connecting rod; 51. an auxiliary ball; 52. a tension spring; 6. a centrifugal lever; 61. a centrifugal push rod; 62. a centrifugal spring; 7. a hybrid reinforcement rod; 71. elastically pushing the net; 8. an inertia ring; 81. an inertial ball; 82. an inertia spring.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments. The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Example 1

Referring to fig. 1-3 and 6, the rock wool electric furnace lining processing device based on silicon-carbon composite material of the present invention includes a processing box 1, the top of the processing box 1 is opened for facilitating the processing of the material, the top of the processing box 1 is opened for facilitating the feeding, the upper side wall of the processing box 1 is communicated with a liquid feeding pipe 11 for facilitating the feeding of the liquid material, the lower side wall of the processing box 1 is communicated with a discharging valve 12 for facilitating the discharging, a stirring shaft 13 is arranged at the center axis of the processing box 1 for facilitating the stirring of the material, the bottom of the stirring shaft 13 is rotatably connected with the bottom inner wall of the processing box 1 through a bearing, the top of the stirring shaft 13 extends to the outside of the top of the processing box 1, the purpose that sets up like this is for the convenience of stirring shaft 13's spacing, the top fixedly connected with motor 14 of stirring shaft 13, the purpose that sets up like this is for the convenience of providing external power, the inside upside fixedly connected with back taper processing cylinder 2 of processing case 1, the purpose that sets up like this is for the convenience of placing the material, the open-top of back taper processing cylinder 2 sets up, the purpose that sets up like this is for the convenience of the entering of material, the bottom of back taper processing cylinder 2 has been seted up and has been divided sieve mesh 21, the purpose that sets up like this is for the convenience of dividing the sieve to the material, the diapire that runs through back taper processing cylinder 2 of stirring shaft 13, the purpose that sets up like this is for the convenience of carrying out spacing to stirring shaft 13, the inside of stirring shaft 13 is hollowed out the setting up, the purpose that sets up like this is for the convenience of setting up inner structure, spout 22 has been seted up to the lateral wall of stirring shaft 13, the purpose that sets up like this is for the convenience of the removal of gravity ball 3, the gravity ball 3 is arranged inside the upper side of the stirring shaft 13 in a sliding manner, the purpose of the arrangement is to facilitate utilization of impact force when materials fall, the outer wall of the gravity ball 3 is arranged in contact with the inner wall of the stirring shaft 13, the purpose of the arrangement is to facilitate limiting of the gravity ball 3, the outer wall of the gravity ball 3 is fixedly connected with the telescopic shell 31, the purpose of the arrangement is to facilitate auxiliary utilization of impact force when materials fall, one end, far away from the gravity ball 3, of the telescopic shell 31 slides to penetrate through the inside of the sliding chute 22 and extend to the outside, the purpose of the arrangement is to facilitate movement of the telescopic shell 31, the telescopic rod 32 is arranged inside the telescopic shell 31 in a sliding manner, the purpose of the arrangement is to facilitate utilization of extrusion force of the inverted cone-shaped processing barrel 2, one end of the telescopic rod 32 is fixedly connected with the telescopic spring 33, and the purpose of the arrangement is to facilitate quick resetting of the telescopic rod 32, telescopic spring 33 keeps away from the one end of telescopic link 32 and the outer wall fixed connection of gravity ball 3, the purpose that sets up like this is for the convenience of fixing telescopic spring 33, telescopic link 32 keeps away from the one end fixedly connected with arc carriage release lever 34 of telescopic link 33, the purpose that sets up like this is for the convenience of utilizing the removal effect of telescopic link 32, the outer wall of arc carriage release lever 34 sets up with the inner wall contact of an inverted cone processing section of thick bamboo 2, the purpose that sets up like this is for the convenience of clearing up the lateral wall to an inverted cone processing section of thick bamboo 2.

Preferably, in this embodiment, in order to further utilize the gravity impact force when the material descends, a baffle 4 is fixedly connected between every two telescopic shells 31, which is set to facilitate utilizing the gravity of the material, a bottom center shaft of the baffle 4 is hinged with an inclined swinging rod 41, which is set to facilitate rotating the inclined swinging rod 41, a center shaft of an outer wall of the inclined swinging rod 41 is fixedly connected with a connecting spring 42, which is set to facilitate quick resetting of the inclined swinging rod 41, one end of the connecting spring 42, which is far away from the inclined swinging rod 41, is fixedly connected with the outer wall of the stirring shaft 13, and which is set to facilitate fixing the connecting spring 42.

Preferably, in this embodiment, in order to grind the materials, the end of the inclined oscillating rod 41 away from the baffle 4 is fixedly connected with the grinding ball 43, and this is set to facilitate the crushing of the large materials, and the end of the grinding ball 43 away from the inclined oscillating rod 41 is set to contact with the bottom inner wall of the inverted cone-shaped processing barrel 2, and this is set to facilitate the movement of the grinding ball 43.

Example 2

Referring to fig. 4, 5, 7-9, the invention relates to a rock wool electric furnace lining processing device based on silicon-carbon composite material, which comprises a processing box 1, wherein the top of the processing box 1 is opened for facilitating material processing, the top of the processing box 1 is opened for facilitating material feeding, a liquid feeding pipe 11 is communicated with the upper side wall of the processing box 1 for facilitating liquid material entering, a discharging valve 12 is communicated with the lower side wall of the processing box 1 for facilitating material discharging, a stirring shaft 13 is arranged at the central axis in the processing box 1 for facilitating material stirring, the bottom of the stirring shaft 13 is rotatably connected with the inner wall of the bottom side of the processing box 1 through a bearing, and the stirring shaft 13 is rotatably arranged for facilitating rotation of the stirring shaft 13, the top of (mixing) shaft 13 extends to the top outside of processing case 1, the purpose that sets up like this is for the convenience of the spacing of (mixing) shaft 13, the top fixedly connected with motor 14 of (mixing) shaft 13, the purpose that sets up like this is for the convenience of providing external power, the inside upside fixedly connected with back taper processing section of thick bamboo 2 of processing case 1, the purpose that sets up like this is for the convenience of placing the material, the open-top setting of back taper processing section of thick bamboo 2, the purpose that sets up like this is for the convenience of the entering of material, branch sieve mesh 21 has been seted up to the bottom of back taper processing section of thick bamboo 2, the purpose that sets up like this is for the convenience of dividing the sieve to the material, the diapire that runs through back taper processing section of thick bamboo 2 of (mixing) shaft 13, the purpose that sets up like this is for the convenience of spacing to (mixing) shaft 13, the inside hollowed setting of (mixing) shaft 13, the purpose that sets up like this is for the convenience of setting up inner structure, lateral wall spout 22 has been seted up of (mixing shaft 13, the purpose of such setting is to facilitate movement of the gravity ball 3, the gravity ball 3 is slidably disposed inside the upper side of the stirring shaft 13, the purpose of such setting is to facilitate utilization of impact force when the material descends, the outer wall of the gravity ball 3 is disposed in contact with the inner wall of the stirring shaft 13, the purpose of such setting is to facilitate limiting of the gravity ball 3, the outer wall of the gravity ball 3 is fixedly connected with a telescopic shell 31, the purpose of such setting is to facilitate auxiliary utilization of impact force when the material descends, one end, away from the gravity ball 3, of the telescopic shell 31 slidably penetrates through the inside of the chute 22 and extends to the outside, the purpose of such setting is to facilitate movement of the telescopic shell 31, wherein a telescopic rod 32 is slidably disposed inside the telescopic shell 31, the purpose of such setting is to facilitate utilization of extrusion force of the inverted cone-shaped processing barrel 2, and a telescopic spring 33 is fixedly connected to one end of the telescopic rod 32, the purpose that sets up like this is in order to facilitate the quick reset of telescopic link 32, the one end that telescopic link 32 was kept away from to extension spring 33 and the outer wall fixed connection of gravity ball 3, the purpose that sets up like this is in order to facilitate fixed extension spring 33, the one end fixedly connected with arc carriage release lever 34 that telescopic link 32 kept away from extension spring 33, the purpose that sets up like this is in order to facilitate utilizing the removal effect of telescopic link 32, the outer wall of arc carriage release lever 34 sets up with the inner wall contact of back taper processing section of thick bamboo 2, the purpose that sets up like this is in order to facilitate clearing up the lateral wall of back taper processing section of thick bamboo 2.

Preferably, in this embodiment, in order to further utilize the gravity impact force when the material descends, a baffle 4 is fixedly connected between every two telescopic shells 31, which is set to facilitate utilizing the gravity of the material, a bottom center shaft of the baffle 4 is hinged with an inclined swinging rod 41, which is set to facilitate rotating the inclined swinging rod 41, a center shaft of an outer wall of the inclined swinging rod 41 is fixedly connected with a connecting spring 42, which is set to facilitate quick resetting of the inclined swinging rod 41, one end of the connecting spring 42, which is far away from the inclined swinging rod 41, is fixedly connected with the outer wall of the stirring shaft 13, and which is set to facilitate fixing the connecting spring 42.

Preferably, in this embodiment, in order to grind the materials, the end of the inclined oscillating rod 41 away from the baffle 4 is fixedly connected with the grinding ball 43, and this is set to facilitate the crushing of the large materials, and the end of the grinding ball 43 away from the inclined oscillating rod 41 is set to contact with the bottom inner wall of the inverted cone-shaped processing barrel 2, and this is set to facilitate the movement of the grinding ball 43.

Preferably, in this embodiment, in order to facilitate utilization of the up-and-down movement effect of the gravity ball 3, a connecting rod 5 is fixedly connected to a bottom outer wall center axis of the gravity ball 3, the purpose of the setting is to facilitate conduction of the movement effect of the gravity ball 3, an auxiliary ball 51 is fixedly connected to one end of the connecting rod 5 away from the gravity ball 3, the purpose of the setting is to facilitate auxiliary setting of the centrifugal rod 6, an outer wall of the auxiliary ball 51 is in contact with an inner wall of the stirring shaft 13, the purpose of the setting is to facilitate movement of the auxiliary ball 51, an extension spring 52 is fixedly connected to one end of the auxiliary ball 51 away from the connecting rod 5, the purpose of the setting is to facilitate quick return of the auxiliary ball 51, wherein one end of the extension spring 52 away from the auxiliary ball 51 is fixedly connected to the bottom inner wall of the stirring shaft 13, and the purpose of the setting is to facilitate fixing of the extension spring 52.

Preferably, in this embodiment, in order to facilitate utilization of a centrifugal force generated when the centrifugal rod 6 rotates, the centrifugal rod 6 is fixedly connected to an outer wall of the auxiliary ball 51, and is arranged to facilitate utilization of an up-and-down movement effect of the auxiliary ball 51, an inner portion of the centrifugal rod 6 is hollowed, and is arranged to facilitate arrangement of an inner structure, one end of the centrifugal rod 6, which is far away from the auxiliary ball 51, slidably penetrates through an inner portion of the sliding groove 22 and extends to an outer side, and is arranged to facilitate movement of the centrifugal rod 6, and a centrifugal push rod 61 is slidably arranged inside the centrifugal rod 6, and is arranged to facilitate movement of the centrifugal push rod 61.

Preferably, in this embodiment, in order to facilitate quick resetting of the centrifugal push rod 61, one end of the centrifugal push rod 61 is disposed in a spherical shape, and the purpose of the disposition is to facilitate disposing the centrifugal spring 62, one end of the centrifugal push rod 61 is fixedly connected with the centrifugal spring 62, and the purpose of the disposition is to facilitate disposing the centrifugal spring 62, one end of the centrifugal spring 62 far away from the centrifugal push rod 61 is fixedly connected with the outer wall of the auxiliary ball 51, and the purpose of the disposition is to facilitate fixedly connecting the centrifugal spring 62.

Preferably, in the present embodiment, in order to facilitate utilization of the moving effect of the centrifugal push rod 61, one end of the centrifugal push rod 61, which is far away from the centrifugal spring 62, is fixedly connected with the mixing enhancement rod 7, and this is provided to facilitate enhancement of the mixing effect of the device on the materials, and an elastic pushing net 71 is fixedly connected between every two mixing enhancement rods 7, and this is provided to facilitate utilization of the moving effect of the mixing enhancement rod 7.

Preferably, in this embodiment, in order to facilitate utilization of the movement effect of the mixing reinforcing rod 7, the bottom of the mixing reinforcing rod 7 is disposed in a spherical shape, the purpose of the spherical shape is to facilitate limiting of the inertia ring 8, the outer surface of the mixing reinforcing rod 7 is slidably sleeved with the inertia ring 8, the purpose of the spherical shape is to facilitate up-down movement of the inertia ring 8, an inertia ball 81 is disposed between every two inertia rings 8, the purpose of the spherical shape is to facilitate utilization of the movement effect of the inertia ring 8, two side walls of the inertia ball 81 are respectively and fixedly connected with an inertia spring 82, the purpose of the spherical shape is to facilitate limiting of the inertia ball 81, one end of the inertia spring 82, which is far away from the inertia ball 81, is fixedly connected with the outer wall of the inertia ring 8, and the purpose of the spherical shape is to facilitate fixing of the inertia spring 82.

A rock wool electric furnace lining processing device based on silicon-carbon composite material comprises the following processing method:

s1: the staff can add the solid material into the inverted cone processing barrel 2, add the liquid material into the processing box 1 through the liquid feeding pipe 11, start the motor 14 at the same time, the start of the motor 14 can drive the stirring shaft 13 to rotate, thereby achieving the purpose of stirring the material, when the material enters the inverted cone processing barrel 2, under the action of the baffle 4, the gravity of the material can be pressed down, and further the telescopic shell 31 can move up and down along the inside of the chute 22 under the action of the gravity ball 3, thereby, the effect of material turning up and down can be achieved when the solid material is stirred in a rotating way, thereby the effect of the material passing through the sieving hole 21 is enhanced, when the telescopic shell 31 moves up and down, the telescopic rod 32 can drive the arc-shaped moving rod 34 to move up and down along the inner wall of the inverted cone processing barrel 2, thereby the material adsorbed on the inside of the inverted cone processing barrel 2 can be cleaned, thereby enhancing the processing effect of the device;

s2: when the baffle 4 moves up and down, the inclined swinging rod 41 can be forced to rotate, so that the grinding balls 43 can be driven to transversely move back and forth along the inner wall of the bottom side of the inverted cone-shaped processing barrel 2, the effect of grinding massive solid materials can be achieved by utilizing the moving effect, the contact area of the solid materials and liquid materials is increased, the solid materials can conveniently pass through the sieving holes 21, and the processing effect of the device is enhanced;

s3: when the gravity ball 3 moves up and down, the connecting rod 5 and the auxiliary ball 51 are driven to move up and down, so that the centrifugal rod 6 and the elastic pushing net 71 can be driven to move up and down, and on the other hand, when the centrifugal rod 6 rotates, the centrifugal force generated can drive the centrifugal push rod 61 to move transversely, so that the mixing reinforcing rod 7 can drive the elastic pushing net 71 to move transversely along the inner part of the mixture, so that the mixing effect of the device on the materials is enhanced in all directions;

s4: when mixing reinforcing bar 7 and reciprocating, under the effect of inertial force, can make inertia ring 8 drive inertia ball 81 and inertia spring reciprocate along the outer wall that mixes reinforcing bar 7, simultaneously because the inertia spring has elasticity, just so when making inertia ball 81 reciprocate under inertia ring 8 drives, utilize centrifugal effect, can outwards swing, and then improved the frequency of the device to the material stirring to this processing effect that has strengthened the device.

It should be apparent that the described embodiments are only some of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by one of ordinary skill in the art and related arts based on the embodiments of the present invention without any creative effort, shall fall within the protection scope of the present invention. Structures, devices, and methods of operation not specifically described or illustrated herein are generally practiced in the art without specific recitation or limitation.

Claims (9)

1. The utility model provides a rock wool electric stove furnace lining processingequipment based on silicon carbon combined material, includes processing case (1), its characterized in that: the top of the processing box (1) is provided with an opening, the upper side wall of the processing box (1) is communicated with a liquid feeding pipe (11), the lower side wall of the processing box (1) is communicated with a discharge valve (12), a stirring shaft (13) is arranged at the middle shaft in the processing box (1), the bottom of the stirring shaft (13) is rotatably connected with the inner wall of the bottom side of the processing box (1) through a bearing, the top of the stirring shaft (13) extends to the outer side of the top of the processing box (1), and the top of the stirring shaft (13) is fixedly connected with a motor (14);

an inverted cone-shaped processing cylinder (2) is fixedly connected to the upper side in the processing box (1), the top of the inverted cone-shaped processing cylinder (2) is provided with an opening, the bottom of the inverted cone-shaped processing cylinder (2) is provided with a sieve separating hole (21), and the stirring shaft (13) penetrates through the bottom wall of the inverted cone-shaped processing cylinder (2);

the stirring shaft (13) is hollowed, a sliding groove (22) is formed in the side wall of the stirring shaft (13), a gravity ball (3) is arranged inside the upper side of the stirring shaft (13) in a sliding mode, the outer wall of the gravity ball (3) is arranged in contact with the inner wall of the stirring shaft (13), a telescopic shell (31) is fixedly connected to the outer wall of the gravity ball (3), and one end, far away from the gravity ball (3), of the telescopic shell (31) penetrates through the inside of the sliding groove (22) in a sliding mode and extends to the outside;

wherein, the inside of flexible shell (31) slides and is provided with telescopic link (32), the one end fixedly connected with extension spring (33) of telescopic link (32), the outer wall fixed connection of the one end that telescopic link (32) and gravity ball (3) were kept away from in extension spring (33), the one end fixedly connected with arc carriage release lever (34) of extension spring (33) is kept away from in telescopic link (32), the outer wall of arc carriage release lever (34) sets up with the inner wall contact of back taper processing section of thick bamboo (2).

2. The rock wool electric furnace lining processing device based on the silicon-carbon composite material as claimed in claim 1, is characterized in that: every two fixedly connected with baffle (4) between flexible shell (31), the bottom axis department of baffle (4) articulates there is slope swinging arms (41), the outer wall axis department fixedly connected with of slope swinging arms (41) connects spring (42), the one end that connects spring (42) kept away from slope swinging arms (41) and the outer wall fixed connection of (mixing) shaft (13).

3. The rock wool electric furnace lining processing device based on the silicon-carbon composite material as claimed in claim 2, is characterized in that: one end of the inclined swinging rod (41) far away from the baffle (4) is fixedly connected with a grinding ball (43), and one end of the grinding ball (43) far away from the inclined swinging rod (41) is in contact arrangement with the inner wall of the bottom side of the inverted cone-shaped processing cylinder (2).

4. The rock wool electric furnace lining processing device based on the silicon-carbon composite material as claimed in claim 3, is characterized in that: a connecting rod (5) is fixedly connected to the bottom side outer wall middle shaft of the gravity ball (3), an auxiliary ball (51) is fixedly connected to one end, far away from the gravity ball (3), of the connecting rod (5), the outer wall of the auxiliary ball (51) is arranged in contact with the inner wall of the stirring shaft (13), and a tension spring (52) is fixedly connected to one end, far away from the connecting rod (5), of the auxiliary ball (51);

one end of the tension spring (52) far away from the auxiliary ball (51) is fixedly connected with the inner wall of the bottom side of the stirring shaft (13).

5. The rock wool electric furnace lining processing device based on the silicon-carbon composite material is characterized in that: the outer wall fixedly connected with centrifugal rod (6) of supplementary ball (51), the inside of centrifugal rod (6) is hollowed out and is set up, the one end slip that supplementary ball (51) was kept away from in centrifugal rod (6) runs through the inside of spout (22) and extends to the outside, the inside slip of centrifugal rod (6) is provided with centrifugal push rod (61).

6. The rock wool electric furnace lining processing device based on the silicon-carbon composite material as claimed in claim 5, is characterized in that: one end of the centrifugal push rod (61) is arranged in a spherical shape, one end of the centrifugal push rod (61) is fixedly connected with a centrifugal spring (62), and one end, far away from the centrifugal push rod (61), of the centrifugal spring (62) is fixedly connected with the outer wall of the auxiliary ball (51).

7. The rock wool electric furnace lining processing device based on the silicon-carbon composite material as claimed in claim 6, is characterized in that: one end, far away from the centrifugal spring (62), of the centrifugal push rod (61) is fixedly connected with a mixing reinforcing rod (7), and an elastic pushing net (71) is fixedly connected between every two mixing reinforcing rods (7).

8. The rock wool electric furnace lining processing device based on the silicon-carbon composite material as claimed in claim 7, is characterized in that: the bottom of the mixing reinforcing rod (7) is arranged in a spherical shape, inertia rings (8) are sleeved on the outer surface of the mixing reinforcing rod (7) in a sliding mode, an inertia ball (81) is arranged between every two inertia rings (8), and two side walls of each inertia ball (81) are fixedly connected with inertia springs (82) respectively;

one end of the inertia spring (82) far away from the inertia ball (81) is fixedly connected with the outer wall of the inertia ring (8).

9. A processing method of a rock wool electric furnace lining processing device based on a silicon-carbon composite material is characterized by comprising the following steps: the processing method comprises the following steps:

s1: the staff can add the solid material into the reverse taper processing barrel (2), add the liquid material into the processing box (1) through the liquid feeding pipe (11), start the motor (14) at the same time, the start of the motor (14) can drive the stirring shaft (13) to rotate, thereby achieving the purpose of stirring the material, when the material enters the reverse taper processing barrel (2), under the action of the baffle (4), the gravity of the material can be pressed down, and further the telescopic shell (31) can move up and down along the inside of the chute (22) under the action of the gravity ball (3), thereby, the effect of material turning up and down can be achieved when the solid material is stirred in a rotating way, thereby the effect of the material passing through the sieving hole (21) is enhanced, when the telescopic shell (31) moves up and down, the telescopic rod (32) can drive the arc moving rod (34) to move up and down along the inner wall of the reverse taper processing barrel (2), therefore, the materials adsorbed on the inner part of the inverted cone-shaped processing cylinder (2) can be cleaned, and the processing effect of the device is enhanced;

s2: when the baffle (4) moves up and down, the inclined swinging rod (41) can be forced to rotate, so that the grinding balls (43) can be driven to transversely move back and forth along the inner wall of the bottom side of the inverted cone-shaped processing cylinder (2), the moving effect can be utilized, the effect of grinding massive solid materials can be achieved, the contact area of the solid materials and liquid materials is increased, the solid materials can conveniently pass through the sieving holes (21), and the processing effect of the device is enhanced;

s3: when the gravity ball (3) moves up and down, the connecting rod (5) and the auxiliary ball (51) are driven to move up and down, so that the centrifugal rod (6) and the elastic pushing net (71) can be driven to move up and down, and on the other hand, when the centrifugal rod (6) rotates, the centrifugal force generated can drive the centrifugal push rod (61) to move transversely, so that the mixing reinforcing rod (7) can drive the elastic pushing net (71) to move transversely along the interior of the mixed material, and the mixing effect of the device on the materials is enhanced in all directions;

s4: when mixing reinforcing bar (7) and reciprocating, under the effect of inertial force, can make inertia ring (8) drive inertia ball (81) and inertia spring and reciprocate along the outer wall that mixes reinforcing bar (7), simultaneously because the inertia spring has elasticity, just so when just making inertia ball (81) reciprocate under inertia ring (8) drive, utilize centrifugal effect, can outwards swing, and then improved the device to the frequency of material stirring to this processing effect that has strengthened the device.

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