CN112683065A - Novel heating device for decorative material development - Google Patents

Abstract

The invention discloses a heating device for developing a novel decorative material, and relates to the technical field of development of novel decorative materials; the method aims to solve the problem that the existing heating furnace cannot well meet the requirements because different gases are required to be introduced into the furnace to create a calcining atmosphere for modifying the shell powder; the furnace body heating device comprises a base, wherein a furnace body mechanism is installed at the top of the base in a rotating mode, a sealing cover is fixedly installed at the end portion of the furnace body mechanism, a stepping motor is fixedly installed at the top of the base, an output shaft of the stepping motor is connected with the furnace body mechanism in a transmission mode through a chain, and a plurality of main heaters are embedded inside the furnace body mechanism. According to the invention, the driving motor is used for driving the shaft body and the stirring mechanism inside to rotate, the secondary heater is arranged, the shell powder is heated inside and outside simultaneously, the calcining efficiency and uniformity of the shell powder are improved, the shell powder is continuously rolled and stirred in the calcining process, and the layering and caking phenomena of the shell powder are avoided.

Description

Novel heating device for decorative material development

Technical Field

The invention relates to the technical field of novel decorative material development, in particular to a novel heating device for decorative material development.

Background

Decoration is also known as decoration or decoration. The decoration method is carried out in a certain area and range, and comprises water and electricity construction, wall bodies, floors, ceilings, landscapes and the like, a whole set of construction scheme and design scheme are formed according to a certain design concept and aesthetic rules, people who advocate nature in the society now and desire to combine modern decoration style with traditional natural charms for people who live at low carbon, and novel decoration materials are produced one by one. In the urban reinforced cement, the natural and truthful feeling is brought to people.

The coating is a necessary material in decoration, no matter high-grade decoration, or ordinary decoration all needs to use the coating, shell powder is as one kind of ecological coating, utilize shell powder as the material of interior decoration, multiple functions such as air-purifying, humidity regulation, do not inhale the dust, life overlength, calcination treatment is used very extensively in shell powder coating development process, at present, mostly rely on behind placing the shell powder in the crucible, heat it in the heating furnace inside, in order to modify shell powder, still need to let in different gases in the stove and build the atmosphere of calcining, cause the unable fine satisfied demand of current heating furnace, and the crucible holds and causes the shell powder after calcining to appear hardening layering phenomenon easily, need mill the separation once more, influence development effect.

Disclosure of Invention

Based on the technical problems in the background art, the invention provides a novel heating device for decorative material development.

The invention provides a heating device for developing a novel decorative material, which comprises a machine base, wherein a furnace body mechanism is rotatably arranged at the top of the machine base, a sealing cover is fixedly arranged at the end part of the furnace body mechanism, a stepping motor is fixedly arranged at the top of the machine base, an output shaft of the stepping motor is in transmission connection with the furnace body mechanism through a chain, a plurality of main heaters are embedded in the furnace body mechanism, a driving motor is fixedly arranged at the end part of the furnace body mechanism, a shaft body is connected to the end part of an output shaft of the driving motor through a coupling in a transmission manner, the end part of the shaft body extends into the furnace body mechanism, an auxiliary heater is fixedly arranged in the shaft body, a plurality of stirring mechanisms distributed in an annular array manner are fixedly arranged on the outer side of the shaft body, a sealing plug is fixedly arranged in the sealing cover, a shunting mechanism is fixedly arranged on the inner side of the sealing, and the outer side of the sealing plug is fixedly provided with a control valve communicated with the ventilation flow channel, the other sides of the two control valves are respectively and fixedly provided with an air inlet pipe and an exhaust pipe, and a material supplementing mechanism is fixedly arranged between the end parts of the air inlet pipe and the exhaust pipe.

Preferably, the furnace body mechanism comprises a shell, a heat insulation layer and a liner body, the heat insulation layer is arranged between the shell and the liner body, the furnace body mechanism further comprises a temperature measuring instrument and a pressure measuring instrument which are arranged on the outer side, and the temperature measuring instrument and the pressure measuring instrument are arranged at the top end of the furnace body mechanism.

Preferably, a heat insulation sealing gasket is arranged between the sealing cover and the furnace body mechanism, and a convex ring part extending into the furnace body mechanism is arranged at the end part of the heat insulation sealing gasket.

Preferably, the stirring mechanism comprises a stirring blade and a shovel blade, the stirring blade is of an arc structure, the shovel blade is fixed at the end of the stirring blade, the outer arc surface of the shovel blade is matched with the inner wall of the furnace body mechanism, the surface of the stirring blade is provided with a plurality of dispersing slotted holes with V-shaped sections, and the stirring blade is internally provided with a plurality of first heaters which are staggered with the dispersing slotted holes.

Preferably, the surface of the shovel plate blade is provided with two rectangular grooves, the shovel plate blade is internally provided with a plurality of second heaters which are distributed in a staggered manner with the rectangular grooves, the two ends of the outer side of the shovel plate blade are provided with ceramic scrapers, and the outer surfaces of the two ceramic scrapers are provided with diversion groove holes distributed in a staggered manner

Preferably, the inner wall of the furnace body mechanism is provided with a plurality of heat conduction slip rings, a furnace cylinder is rotatably connected between the inner walls of the heat conduction slip rings, and a plurality of arc-shaped convex mark parts are arranged inside the furnace cylinder.

Preferably, the shunting mechanism comprises a cover body with gradually extending thickness, a partition plate is arranged in the cover body, the two sides of the cover body are respectively provided with a material supplementing groove and a capillary hole which are of arc structures, the material supplementing groove is communicated with the air inlet pipe, and the capillary hole is communicated with the exhaust pipe.

Preferably, feed supplement mechanism includes the shell cover, and the inside welding of shell cover has a heat exchanger section of thick bamboo, and the top fixed mounting of heat exchanger section of thick bamboo has the air supplement pipe, the bottom and the intake pipe intercommunication of heat exchanger section of thick bamboo, shell cover and blast pipe intercommunication, and the bottom of shell cover is provided with the exhaust end, and the side fixed mounting of shell cover has the interpolation mouth that runs through the heat exchanger section of thick bamboo inside.

According to the invention, the stepping motor is started to drive the furnace body mechanism to swing above the base in a reciprocating manner, meanwhile, the driving motor is utilized to drive the internal shaft body and the stirring mechanism to rotate, through the arrangement of the auxiliary heater, the internal and external heating can improve the efficiency and the uniformity of shell powder calcination, the shell powder is continuously rolled and stirred in the calcination process, the phenomenon of layering and caking of the shell powder is avoided, meanwhile, gas can be introduced into the furnace body mechanism through the ventilation runner, the control valve, the gas inlet pipe and the gas exhaust pipe in the calcination process, the atmosphere environment of shell powder calcination is changed by utilizing different gas replacement, the gas consumption for changing the calcination atmosphere is low, the method is safer, great convenience is provided for shell powder calcination research, and the efficiency of development and research is improved.

The extrados of shovel board leaf is the inner wall looks adaptation of furnace body mechanism, when stirring the mechanism and rotate, can shovel the shell powder through shovel board leaf, avoids its phenomenon that hardens to appear in the inner wall of furnace body mechanism, and shovels the back and is stirred the leaf and raise, and then carries out abundant dispersion with the shell powder in inside, makes it accomplish for contact between the gas that lets in, and makes it remain powdered throughout calcining the in-process for calcine the efficiency of processing, practice thrift the time of development research.

When stirring the leaf and rotating, carry out abundant heating with its surface through first heater, reach calcination temperature after, when stirring the leaf and contact with the shell powder, heat it, and through the setting of dispersion slotted hole, when stirring the shell powder, disperse the shell powder and raise, further excite shell powder motion process, the effectual area of contact who improves between shell powder and heat source and the atmosphere gas, further improve the shell powder effect of calcining, shorten the calcination time.

Drawings

Fig. 1 is a schematic sectional view of a heating device for developing a novel decorative material according to the present invention;

FIG. 2 is a schematic sectional view of a furnace body of a heating device for developing a new decorative material according to the present invention;

FIG. 3 is a schematic cross-sectional view of a stirring mechanism of the heating device for developing a new decorative material according to the present invention;

fig. 4 is a schematic structural view of a flow distribution mechanism of a heating device for developing a novel decorative material, which is provided by the invention;

fig. 5 is a schematic view of a partial sectional structure of a bladder of the heating device for developing a novel decorative material according to the present invention.

Fig. 6 is a schematic sectional structure view of a feeding mechanism of the heating device for developing a novel decorative material according to the present invention.

In the figure: the device comprises a base 1, a stepping motor 2, 3 auxiliary heaters, 4 stirring blades, 41 dispersing slotted holes, 42 first heaters, 5 shovel plate blades, 51 second heaters, 52 rectangular grooves, 53 flow guide slotted holes, 54 ceramic scrapers, 6 shafts, 7 liner bodies, 71 heat conduction sliding rings, 72 hearth cylinders, 73 arc convex mark parts, 8 main heaters, 9 heat preservation layers, 10 shells, 11 driving motors, 12 heat insulation sealing gaskets, 13 sealing plugs, 14 exhaust pipes, 15 control valves, 16 ventilation flow channels, 17 sealing covers, 18 flow dividing mechanisms, 181 cover bodies, 182 partition plates, 183 material supplementing grooves, 184 capillary holes, 19 air inlet pipes, 20 material supplementing mechanisms, 201 shell covers, 202 heat exchange cylinders, 203 adding ports and 204 air supplementing pipes.

Detailed Description

Reference will now be made in detail to embodiments of the present patent, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary only for the purpose of explaining the present patent and are not to be construed as limiting the present patent.

In the description of this patent, it is to be understood that the terms "center," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in the orientations and positional relationships indicated in the drawings for the convenience of describing the patent and for the simplicity of description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and are not to be considered limiting of the patent.

In the description of this patent, it is noted that unless otherwise specifically stated or limited, the terms "mounted," "connected," and "disposed" are to be construed broadly and can include, for example, fixedly connected, disposed, detachably connected, disposed, or integrally connected and disposed. The specific meaning of the above terms in this patent may be understood by those of ordinary skill in the art as appropriate.

Referring to fig. 1-6, a novel heating device for decorating material development comprises a base 1, a furnace body mechanism is rotatably installed on the top of the base 1, a sealing cover 17 is fixedly installed on the end portion of the furnace body mechanism, a stepping motor 2 is fixedly installed on the top of the base 1, an output shaft of the stepping motor 2 is in transmission connection with the furnace body mechanism through a chain, a plurality of main heaters 8 are embedded inside the furnace body mechanism, a driving motor 11 is fixedly installed on the end portion of the furnace body mechanism, the end portion of the output shaft of the driving motor 11 is in transmission connection with a shaft body 6 through a shaft coupling, the end portion of the shaft body 6 extends into the furnace body mechanism, a sub-heater 3 is fixedly installed inside the shaft body 6, a plurality of stirring mechanisms distributed in an annular array are fixedly installed on the outer side of the shaft body 6, a sealing plug 13 is fixedly installed inside the sealing, two ventilation flow passages 16 communicated with a flow dividing mechanism 18 are arranged in the sealing plug 13, control valves (15) communicated with the ventilation flow passages (16) are fixedly arranged on the outer sides of the sealing plug (13), air inlet pipes (19) and exhaust pipes (14) are respectively and fixedly arranged on the other sides of the two control valves (15), a material supplementing mechanism (20) is fixedly arranged between the end parts of the air inlet pipes (19) and the exhaust pipes (14), the shell powder is put into the furnace body mechanism, the furnace body mechanism is heated by a main heater 8, a stepping motor 2 is started to drive the furnace body mechanism to reciprocate above a machine base 1, meanwhile, a shaft body 6 and a stirring mechanism in the furnace body mechanism are driven to rotate by a driving motor 11, the efficiency and the uniformity of shell powder calcination are improved by simultaneously heating the inside and the outside through an auxiliary heater 3, and the shell powder is continuously rolled and stirred in the calcination, avoid the shell powder layering and caking phenomenon to appear, simultaneously, can pass through ventilation runner 16, control valve 15, intake pipe (19) and blast pipe (14) and let in gas to furnace body mechanism inside at the in-process of calcining, utilize different gas replacement to change the atmosphere environment that the shell powder was calcined, it is few to the gas consumption that changes the atmosphere of calcining, and safer, for the shell powder calcines research provides very big facility, improves the efficiency of development and research.

According to the invention, the furnace body mechanism comprises a shell 10, a heat insulation layer 9 and a liner body 7, the heat insulation layer 9 is arranged between the shell 10 and the liner body 7, the heating and heat insulation effects of the furnace body mechanism are improved by arranging the shell 10, the heat insulation layer 9 and the liner body 7, the furnace body mechanism further comprises a temperature measuring instrument and a pressure measuring instrument which are arranged on the outer side, the temperature measuring instrument and the pressure measuring instrument are arranged at the top end position of the furnace body mechanism, and through the arranged temperature measuring instrument and the arranged pressure measuring instrument, the temperature and the pressure in the furnace body mechanism can be conveniently controlled by workers, so that the over-temperature.

In the invention, the heat insulation sealing gasket 12 is arranged between the sealing cover 17 and the furnace body mechanism, the end part of the heat insulation sealing gasket 12 is provided with a convex ring part extending to the interior of the furnace body mechanism, and the sealing effect of the sealing cover 17 is improved by the arrangement of the heat insulation sealing gasket 12.

In the invention, the stirring mechanism comprises a stirring blade 4 and a shovel blade 5 which are of arc structures, the shovel blade 5 is fixed at the end part of the stirring blade 4, the outer arc surface of the shovel blade 5 is matched with the inner wall of the furnace body mechanism, when the stirring mechanism rotates, the shovel blade 5 can shovel the shell powder to avoid the hardening phenomenon on the inner wall of the furnace body mechanism, the shell powder is lifted by the stirring blade 4 after being shoveled, the shell powder is fully dispersed inside, the shell powder is contacted with introduced gas, the shell powder is kept powdery all the time in the calcining process, the calcining treatment efficiency is accelerated, the development and research time is saved, the surface of the stirring blade 4 is provided with a plurality of dispersing slot holes 41 with V-shaped sections, the stirring blade 4 is internally provided with a plurality of first heaters 42 which are staggered with the dispersing slot holes 41, and when the stirring blade 4 rotates, the surface of the stirring blade is fully heated by the first heaters 42, after the calcining temperature is reached, when the stirring blade 4 is in contact with the shell powder, the shell powder is heated, and through the arrangement of the dispersing slotted holes 41, when the shell powder is stirred, the shell powder is dispersed and raised, the motion process of the shell powder is further activated, the contact area between the shell powder and a heat source and atmosphere is effectively improved, the calcining effect on the shell powder is further improved, and the calcining time is shortened.

According to the invention, two rectangular grooves 52 are arranged on the surface of the shovel blade 5, a plurality of second heaters 51 distributed in a staggered manner with the rectangular grooves 52 are arranged inside the shovel blade 5, when the shovel blade 5 shovels the shell powder along the inner wall of the furnace mechanism, the shell powder is further heated and dispersed by the arrangement of the second heaters 51 and the rectangular grooves 52, the shell powder is prevented from staying on the inner wall of the furnace mechanism to cause a coagulation phenomenon, ceramic scrapers 54 are arranged at both ends of the outer side of the shovel blade 5, and guide slotted holes 53 distributed in a staggered manner are arranged on the outer surfaces of the two ceramic scrapers 54, when the shovel blade 5 moves along the inner wall of the furnace mechanism, the ceramic scrapers 54 are arranged to produce a grinding effect when the shell powder is calcined, so that the possibility of hardening of the shell powder is effectively avoided, and the guide slotted holes 53 are arranged to increase the area of grinding, and the extended guide slot 53 can be conveyed towards two sides during grinding, so that the flowability of the shell powder in the calcining process is increased, and the calcining effect is improved.

According to the invention, the inner wall of the furnace body mechanism is provided with the plurality of heat conduction sliding rings 71, the inner walls of the heat conduction sliding rings 71 are rotatably connected with the furnace barrel 72, the plurality of arc-shaped convex mark parts 73 are arranged inside the furnace barrel 72, when the stirring mechanism inside the furnace body mechanism rotates, the furnace barrel 72 is blocked by shell powder to generate a damping effect, and then the furnace barrel 72 inside is driven to slowly rotate, the stirring effect on the shell powder is increased through the continuous movement of the furnace barrel 72, and the grinding effect between the furnace barrel and the ceramic scraper 54 is increased through the arrangement of the arc-shaped convex mark parts 73, so that the efficiency of calcining the shell powder is further improved.

According to the invention, the flow dividing mechanism 18 comprises a cover body 181 with gradually extending thickness, a partition plate 182 is arranged inside the cover body 181, a supplement groove 183 and a capillary hole 184 with arc structures are respectively arranged on two sides of the cover body 181, the supplement groove 183 is communicated with an air inlet pipe 19, the capillary hole 184 is communicated with an exhaust pipe 14, when shell powder is calcined, powder inside the supplement mechanism 20 can be blown into the device by the supplement groove 183 to be mixed with the shell powder, exhaust can be carried out through the capillary hole 184 to complete replacement of the gas atmosphere inside the furnace body mechanism, the capillary hole 184 can prevent the internal material from being brought out, so that the gas replacement efficiency is accelerated, and the efficiency of changing the calcining atmosphere is further improved.

In the invention, the material supplementing mechanism (20) comprises a shell cover (201), a heat exchange cylinder (202) is welded in the shell cover (201), an air supplement pipe (204) is fixedly arranged at the top end of the heat exchange cylinder (202), the bottom end of the heat exchange cylinder (202) is communicated with an air inlet pipe (19), a shell cover (201) is communicated with an exhaust pipe (14), an exhaust end is arranged at the bottom end of the outer casing (201), an adding port (203) penetrating through the interior of the heat exchange cylinder (202) is fixedly arranged on the side surface of the outer casing (201), when in use, the exhausted hot gas is adopted to go up and down to be discharged, the heat exchange cylinder (202) is wrapped in the hot gas exhausted by the exhaust pipe (14), the powder is injected into the heat exchange cylinder 202, and then the powder is fully dispersed by changing the environmental gas in the device, the gas is blown into the furnace body mechanism through the gas inlet pipe (19) to complete the effect of fully contacting the shell powder.

When the device is used, the shell powder is put into the furnace body mechanism, the furnace body mechanism is heated by the main heater 8, the stepping motor 2 is started to drive the furnace body mechanism to swing above the base 1 in a reciprocating manner, meanwhile, the driving motor 11 is used for driving the internal shaft body 6 and the stirring mechanism to rotate, through the arrangement of the auxiliary heater 3, the efficiency and the uniformity of shell powder calcination are improved by heating inside and outside simultaneously, the shell powder is continuously rolled and stirred in the calcination process, the phenomenon of layering and caking of the shell powder is avoided, meanwhile, gas can be introduced into the furnace body mechanism through the ventilation runner 16, the control valve 15, the gas inlet pipe (19) and the exhaust pipe (14) in the calcination process, different gas replacement is utilized to change the atmosphere environment of shell powder calcination, the gas consumption for changing the calcination atmosphere is low, the device is safer, and great convenience is provided for the research of shell powder calcination, the efficiency of development and research is improved.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (8)

1. A novel heating device for decorating material development comprises a base (1), wherein a furnace body mechanism is rotatably installed at the top of the base (1), a sealing cover (17) is fixedly installed at the end part of the furnace body mechanism, a stepping motor (2) is fixedly installed at the top of the base (1), an output shaft of the stepping motor (2) is in transmission connection with the furnace body mechanism through a chain, a plurality of main heaters (8) are embedded inside the furnace body mechanism, the novel heating device is characterized in that a driving motor (11) is fixedly installed at the end part of the furnace body mechanism, the end part of the output shaft of the driving motor (11) is connected with a shaft body (6) through shaft coupling transmission, the end part of the shaft body (6) extends to the inside of the furnace body mechanism, a secondary heater (3) is fixedly installed inside the shaft body (6), and a plurality of stirring mechanisms distributed in an annular array are fixedly installed on, the inside fixed mounting of closing cap (17) has sealing plug (13), and the inboard fixed mounting of sealing plug (13) has reposition of redundant personnel mechanism (18), the inside of sealing plug (13) is provided with two flow channel (16) of ventilating that are linked together with reposition of redundant personnel mechanism (18), and the outside fixed mounting of sealing plug (13) has control valve (15) that are linked together with flow channel (16) of ventilating, two control valve (15) opposite side fixed mounting respectively has intake pipe (19) and blast pipe (14), and fixed mounting has feed supplement mechanism (20) between intake pipe (19) and blast pipe (14) tip.

2. The heating device for developing a novel decorative material according to claim 1, wherein the furnace body mechanism comprises a shell (10), a heat insulating layer (9) and a liner body (7), the heat insulating layer (9) is arranged between the shell (10) and the liner body (7), the furnace body mechanism further comprises a temperature measuring instrument and a pressure measuring instrument which are arranged on the outer side, and the temperature measuring instrument and the pressure measuring instrument are arranged at the top end position of the furnace body mechanism.

3. The heating device for developing a novel decoration material according to claim 2, wherein a heat-insulating gasket (12) is provided between the cover (17) and the furnace body mechanism, and a convex ring part extending to the inside of the furnace body mechanism is provided at an end part of the heat-insulating gasket (12).

4. The novel heating device for decorating material development according to claim 1, wherein the stirring mechanism comprises a stirring blade (4) and a shovel plate blade (5) which are arc-shaped, the shovel plate blade (5) is fixed at the end of the stirring blade (4), the outer arc surface of the shovel plate blade (5) is adapted to the inner wall of the furnace body mechanism, the surface of the stirring blade (4) is provided with a plurality of dispersing slot holes (41) which are V-shaped in cross section, and the stirring blade (4) is internally provided with a plurality of first heaters (42) which are staggered with the dispersing slot holes (41).

5. The novel heating device for decorating material development according to claim 4, wherein the surface of the blade (5) is provided with two rectangular grooves (52), the inside of the blade (5) is provided with a plurality of second heaters (51) which are distributed in a staggered manner with the rectangular grooves (52), both ends of the outer side of the blade (5) are provided with ceramic scrapers (54), and the outer surfaces of the two ceramic scrapers (54) are provided with guide slot holes (53) which are distributed in a staggered manner.

6. The novel heating device for decorating material development as claimed in claim 2, wherein the inner wall of the furnace body mechanism is provided with a plurality of heat conducting slip rings (71), and a furnace barrel (72) is rotatably connected between the inner walls of the heat conducting slip rings (71), and a plurality of arc-shaped convex marks (73) are arranged inside the furnace barrel (72).

7. The novel heating device for decorating material development according to claim 1, wherein the flow dividing mechanism (18) comprises a cover body (181) with gradually extending thickness, a partition plate (182) is arranged inside the cover body (181), a feeding groove (183) and capillary holes (184) with arc structures are respectively arranged on two sides of the cover body (181), the feeding groove (183) is communicated with the air inlet pipe (19), and the capillary holes (184) are communicated with the exhaust pipe (14).

8. The novel heating device for decorating material development according to claim 7, wherein the material supplementing mechanism (20) comprises a shell cover (201), a heat exchange cylinder (202) is welded inside the shell cover (201), a gas supplementing pipe (204) is fixedly installed at the top end of the heat exchange cylinder (202), the bottom end of the heat exchange cylinder (202) is communicated with a gas inlet pipe (19), the shell cover (201) is communicated with a gas outlet pipe (14), a gas outlet end is arranged at the bottom end of the shell cover (201), and an adding port (203) penetrating through the interior of the heat exchange cylinder (202) is fixedly installed on the side surface of the shell cover (201).

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