阅读说明：本技术 一种玻璃棉纤维管自动生产设备 (Automatic production equipment for glass wool fiber pipe ) 是由 栗晴 于 2020-07-31 设计创作，主要内容包括：本发明公开了一种玻璃棉纤维管自动生产设备,由控制柜、传输带、加工柜、碎料柜、运输带组成,传输带的左侧表面嵌入安装于加工柜的内部,加工柜的左侧与碎料柜的右侧相连接,碎料柜的左上端安装于运输带的右上方,运输带的右侧设于加工柜的左侧,加工柜由加热装置、搅拌装置、成型装置、出线装置组成,加热装置的右侧安装于成型装置的左侧,搅拌装置的右侧与出线装置的左侧相连接,成型装置的上方位于出线装置的下方,搅拌装置的左侧设于碎料柜的右侧,出线装置安装于传输带的左侧,在加工时通过对原材料的破碎研磨,使得材料加速溶解,通过装置自动拉丝,与成型,减少人工接触,避免安全事故的发生,增加了加工效率。(The invention discloses automatic production equipment for glass cotton fiber tubes, which consists of a control cabinet, a transmission belt, a processing cabinet, a material crushing cabinet and a transmission belt, wherein the left surface of the transmission belt is embedded and arranged inside the processing cabinet, the left side of the processing cabinet is connected with the right side of the material crushing cabinet, the left upper end of the material crushing cabinet is arranged above the right side of the transmission belt, the right side of the transmission belt is arranged on the left side of the processing cabinet, the processing cabinet consists of a heating device, a stirring device, a forming device and a wire outlet device, the right side of the heating device is arranged on the left side of the forming device, the right side of the stirring device is connected with the left side of the wire outlet device, the upper part of the forming device is positioned below the wire outlet device, the left side of the stirring device is arranged on the right side of the material crushing cabinet, the wire outlet device is arranged on the left side of, with the shaping, reduce artifical contact, avoid the emergence of incident, increased machining efficiency.)

1. An automatic production device for glass cotton fiber tubes is characterized by comprising a device body, wherein the device body consists of a control cabinet (1), a transmission belt (2), a processing cabinet (3), a crushing cabinet (4) and a conveying belt (5);

the upper surface of the control cabinet (1) is attached to the lower side of the conveying belt (2), the left side surface of the conveying belt (2) is embedded and installed inside the processing cabinet (3), the left side of the processing cabinet (3) is connected with the right side of the material crushing cabinet (4), the upper left end of the material crushing cabinet (4) is installed on the upper right side of the conveying belt (5), and the right side of the conveying belt (5) is arranged on the left side of the processing cabinet (3);

processing cabinet (3) are installed in the left side of forming device (33) by heating device (31), agitating unit (32), forming device (33), be qualified for the next round of competitions device (34) and constitute, the right side of heating device (31) is installed, the right side of agitating unit (32) is connected with the left side of being qualified for the next round of competitions device (34), the top of forming device (33) is located the below of being qualified for the next round of competitions device (34), the right side of crushed aggregates cabinet (4) is located in the left side of agitating unit (32), the left side in transmission band (2) is installed in device (34) of being qualified for the next round of competitions.

2. The automatic production equipment for the glass wool fiber pipe according to claim 1, characterized in that: heating device (31) comprises shell (311), play thick liquid valve (312), heater (313), heating pipe (314), heating chamber (315), it installs in the inside of shell (311) to go out thick liquid valve (312), heater (313) are connected and are installed in the inside of shell (311) with play thick liquid valve (312) electricity, the lower surface embedding of heating pipe (314) is installed in the inside of heater (313), the internal surface laminating in shell (311) of heating chamber (315), agitating unit (32)'s below is located to the top of heating pipe (314), it is connected with crushed aggregates cabinet (4) through agitating unit (32) to go out thick liquid valve (312), urceolus (346) head end and heating chamber (315) right surface weld mutually.

3. The automatic production equipment for the glass wool fiber pipe according to claim 1, characterized in that: the stirring device (32) consists of a central wheel (321), a connecting plate (322), a transmission gear (323), a turntable (324), a driving gear (325), a driving rotating shaft (326), a turbine box (327), a turntable rotating shaft (328), a stirring motor (329) and a stirring cam (3210), wherein the central wheel (321) and the turntable (324) are on the same axis, the outer side of the connecting plate (322) is connected with the inner side of the transmission gear (323), the transmission gear (323) is meshed with the turntable (324), the turntable (324) and the driving gear (325) are on the same axis, a chain is arranged on the front side of the driving gear (325), the lower end of the driving rotating shaft (326) is parallel to the upper end of the central wheel (321), the front side of the turbine box (327) is arranged on the rear side of the driving rotating shaft (326), and the turntable rotating shaft (328) is perpendicular to the driving rotating shaft (326), the stirring motor (329) is electrically connected with the turbine box (327), the upper part of the stirring cam (3210) is arranged below the rotating shaft (328) of the rotating disc, the right side of the stirring motor (329) is arranged on the left side of the forming device (33), and the stirring cam (3210) is arranged on the right side of the stirring device (32).

4. The automatic production equipment for the glass wool fiber pipe according to claim 1, characterized in that: the forming device (33) is composed of an air cylinder (331), a forming motor (332), a spring (333), a deflector rod (334), a forming cam (335), a rotary disc (336), a forming rod (337), a transmission worm gear (338), an air cylinder piston (339) and a threading hole (3310), wherein the air cylinder (331) is electrically connected with the forming motor (332), the right side of the forming motor (332) is perpendicular to the forming rod (337), the back surface of the spring (333) is arranged on the front side of the rotary disc (336), the lower part of the deflector rod (334) is connected with the left upper end of the forming rod (337), the forming cam (335) and the rotary disc (336) are arranged on the same axis and are arranged on the rear side of the deflector rod (334), the front side of the forming rod (337) is meshed with the rear side of the transmission worm gear (338), the upper part of the transmission worm gear (338) is embedded and arranged in the rotary disc (336), and the air cylinder piston (339) and the air cylinder (331) are on the same, the back of threading hole (3310) is located the front side of driving lever (334), shaping pole (337) is installed in transmission band (2) left side, install in shell (311) internal surface carousel (336) bottom, rotatory inner tube (341) is parallel to each other with cylinder (331).

5. The automatic production equipment for the glass wool fiber pipe according to claim 1, characterized in that: the wire outlet device (34) is composed of a rotary inner cylinder (341), a rotary motor (342), an inner cylinder hole (343), an outer cylinder hole (344), a rotary turbine box (345) and an outer cylinder (346), wherein the right side of the rotary inner cylinder (341) is connected with the left side of the outer cylinder hole (344), the rotary motor (342) is electrically connected with the rotary turbine box (345), the upper side of the inner cylinder hole (343) is parallel to the lower side of the outer cylinder hole (344), the upper side of the rotary turbine box (345) is perpendicular to the outer cylinder hole (344), the head end of the rotary inner cylinder (341) is installed on the right side of the slurry outlet valve (312), and the outer side of the rotary turbine box (345) is installed on the inner side of the shell (311).

6. The automatic production equipment for the glass wool fiber pipe according to claim 1, characterized in that: crushed aggregates cabinet (4) comprise eccentric block (41), left fragment (42), right fragment (43), crushed aggregates turbine box (44), crushed aggregates motor (45), silo (46), feed valve (47), the inboard of right fragment (43) is located in the outside of eccentric block (41), the right side surface of left side fragment (42) is on a parallel with the left side of right fragment (43), crushed aggregates turbine box (44) is connected with crushed aggregates motor (45) electricity, the left side of feed valve (47) is located on the right side of crushed aggregates motor (45), the right side of silo (46) is connected with the left side of feed valve (47), the left side in heater (313) is installed on the right side of feed valve (47), the upper left side of agitating unit (32) is located to the right-hand member of right fragment (43).

Technical Field

The invention relates to automatic production equipment for a glass wool fiber tube, belonging to the field of glass tube manufacturing.

Background

The glass wool fiber tube is an inorganic non-metallic material with excellent performance, has various types, has the advantages of good insulativity, strong heat resistance, good corrosion resistance and high mechanical strength, is manufactured by taking glass balls or waste glass as a raw material through processes of high-temperature melting, wire drawing, winding, weaving and the like, but in the prior art, the raw material needs to be heated for a long time to be melted during processing, and the virgin stock needs to be drawn manually, so the safety is poor, and the processing efficiency is low.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide automatic production equipment for a glass cotton fiber pipe, which aims to solve the problems that raw materials need to be heated for a long time to be dissolved during processing, raw stock needs to be drawn manually, the safety is poor, and the processing efficiency is low.

In order to achieve the purpose, the invention is realized by the following technical scheme: an automatic production device of glass cotton fiber tubes, which consists of a control cabinet, a transmission belt, a processing cabinet, a crushing cabinet and a conveying belt, the upper surface of the control cabinet is attached below the conveying belt, the left side surface of the conveying belt is embedded and installed inside the processing cabinet, the left side of the processing cabinet is connected with the right side of the particle cabinet, the left upper end of the particle cabinet is arranged at the right upper part of the conveying belt, the right side of the conveyer belt is arranged at the left side of the processing cabinet, the processing cabinet consists of a heating device, a stirring device, a forming device and a wire outlet device, the right side of the heating device is arranged at the left side of the forming device, the right side of the stirring device is connected with the left side of the wire outlet device, the upper portion of the forming device is located below the wire outlet device, the left side of the stirring device is arranged on the right side of the material crushing cabinet, and the wire outlet device is installed on the left side of the conveying belt.

In order to optimize the technical scheme, the method further comprises the following steps:

according to a preferred mode, heating device comprises shell, play thick liquid valve, heater, heating pipe, heating chamber, it installs in the inside of shell to go out the thick liquid valve, the heater is connected and is installed in the inside of shell with a thick liquid valve electricity, the lower surface embedding of heating pipe is installed in the inside of heater, the surface laminating in the internal surface of shell in the heating chamber, agitating unit's below is located to the top of heating pipe, it is connected with crushed aggregates cabinet through agitating unit to go out the thick liquid valve, urceolus head end welds with heating chamber right side surface mutually.

According to a preferred mode, the stirring device consists of a central wheel, a connecting plate, a transmission gear, a turntable, a driving gear, a driving rotating shaft, a turbine box, a turntable rotating shaft, a stirring motor and a stirring cam, the central wheel and the turntable are on the same axle center, the outer side of the connecting plate is connected with the inner side of the transmission gear, the transmission gear is meshed with the turntable, the turntable and the driving gear are on the same axis, the front side of the driving gear is provided with a chain, the lower end of the driving rotating shaft is parallel to the upper end of the central wheel, the front side of the turbine box is arranged at the rear side of the driving rotating shaft, the rotating shaft of the rotating disc is vertical to the driving rotating shaft, the stirring motor is electrically connected with the turbine box, the upper part of the stirring cam is arranged below the rotating shaft of the rotating disc, the right side of the stirring motor is arranged on the left side of the forming device, and the stirring cam is arranged on the right side of the stirring device.

According to a preferred mode, the forming device consists of a cylinder, a forming motor, a spring, a deflector rod, a forming cam, a turntable, a forming rod, a transmission worm gear, a cylinder piston and a threading hole, the cylinder is electrically connected with a forming motor, the right side of the forming motor is vertical to the forming rod, the back surface of the spring is arranged on the front side of the turntable, the lower part of the deflector rod is connected with the left upper end of the forming rod, the forming cam and the turntable are arranged on the same axis and at the rear side of the deflector rod, the front side of the forming rod is meshed with the rear side of the transmission worm wheel, the upper part of the transmission worm wheel is embedded and arranged in the turntable, the cylinder piston and the cylinder are on the same central line, the back of the threading hole is arranged at the front side of the deflector rod, the shaping pole is installed in the transmission band left side, the carousel bottom is installed in the shell internal surface, rotatory inner tube is parallel to each other with the cylinder.

According to a preferred mode, the wire outlet device is composed of a rotary inner cylinder, a rotary motor, an inner cylinder hole, an outer cylinder hole, a rotary turbine box and an outer cylinder, wherein the right side of the rotary inner cylinder is connected with the left side of the outer cylinder hole, the rotary motor is electrically connected with the rotary turbine box, the upper side of the inner cylinder hole is parallel to the lower side of the outer cylinder hole, the upper side of the rotary turbine box is perpendicular to the outer cylinder hole, the head end of the rotary inner cylinder is installed on the right side of the slurry outlet valve, and the outer side of the rotary turbine box is installed on the inner side of.

According to a preferred mode, the crushed aggregates cabinet comprises eccentric block, left fragment, right fragment, crushed aggregates turbine box, crushed aggregates motor, silo, feed valve, the inside of right fragment is located in the outside of eccentric block, the crushed aggregates right side surface is on a parallel with the crushed aggregates left side in the right side, crushed aggregates turbine box is connected with crushed aggregates motor electricity, feed valve's left side is located on crushed aggregates motor's right side, the right side of silo is connected with feed valve's left side, feed valve's right side is installed in the left side of heater, agitating unit's upper left side is located to the crushed aggregates right-hand member in the right side.

The automatic production equipment for the glass wool fiber pipe has the beneficial effects that: through the broken grinding to raw and other materials when adding man-hour for the material dissolves with higher speed, through the automatic wire drawing of device, with the shaping, reduces artifical contact, avoids the emergence of incident, has increased machining efficiency.

The invention relates to automatic production equipment for glass cotton fiber tubes, which is characterized in that raw materials are placed in a conveying belt, enter a crushing cabinet through the conveying belt, are crushed and ground by the crushing cabinet, and are heated and smelted by a heating device, a stirring device accelerates the smelting process to reduce the smelting time, smelted raw stock is processed into filaments by a wire outlet device, a forming device is woven into a tube shape by using the filaments, and the tube is automatically conveyed to a conveying belt after the processing is finished.

Drawings

Other features, objects, and advantages of the present invention will become more apparent from the following detailed description of the embodiments of the invention when taken in conjunction with the accompanying drawings, in which:

FIG. 1 is a schematic structural diagram of an automatic production apparatus for glass wool fiber tubes according to the present invention.

FIG. 2 is a schematic structural diagram of a processing cabinet of an automatic glass wool fiber tube production device of the present invention.

FIG. 3 is a schematic structural diagram of a heating device, a stirring device, a forming device and a wire outlet device of the automatic production equipment of the glass wool fiber pipe.

FIG. 4 is a schematic view of a partial structure of a forming device A of an automatic glass wool fiber tube production equipment of the invention.

FIG. 5 is a schematic structural diagram of a particle cabinet of an automatic glass wool fiber tube production device according to the present invention.

Description of reference numerals: a control cabinet-1, a transmission belt-2, a processing cabinet-3, a particle cabinet-4, a conveying belt-5, a heating device-31, a stirring device-32, a forming device-33, a wire outlet device-34, a shell-311, a slurry outlet valve-312, a heater-313, a heating pipe-314, a heating cavity-315, a central wheel-321, a connecting plate-322, a transmission gear-323, a rotary disc-324, a driving gear-325, a driving rotary shaft-326, a turbine box-327, a rotary disc rotary shaft-328, a stirring motor-329, a stirring cam-3210, an air cylinder-331, a forming motor-332, a spring-333, a deflector rod-334, a forming cam-335, a rotary disc-336, a forming rod-337, a transmission worm gear-338, a stirring rod-334, The device comprises a cylinder piston-339, a threading hole-3310, a rotary inner cylinder-341, a rotary motor-342, an inner cylinder hole-343, an outer cylinder hole-344, a rotary turbine box-345, an outer cylinder-346, an eccentric block-41, a left fragment-42, a right fragment-43, a crushed material turbine box-44, a crushed material motor-45, a material groove-46 and a feeding valve-47.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

Referring to fig. 1 to 5, the present invention provides an automatic production apparatus for glass wool fiber tubes, comprising: constitute by switch board 1, transmission band 2, processing cabinet 3, crushed aggregates cabinet 4, transportation area 5, the upper surface laminating of switch board 1 is in the below of transmission band 2, the left side surface embedding of transmission band 2 is installed in the inside of processing cabinet 3, the left side of processing cabinet 3 is connected with the right side of crushed aggregates cabinet 4, the upper left end of crushed aggregates cabinet 4 is installed in the upper right side of transportation area 5, the left side of processing cabinet 3 is located on the right side of transportation area 5, processing cabinet 3 comprises heating device 31, agitating unit 32, forming device 33, play line device 34, the left side of heating device 31 is installed in the left side of forming device 33, the right side of agitating unit 32 is connected with the left side of play line device 34, the top of forming device 33 is located the below of play line device 34, the right side of crushed aggregates cabinet 4 is located in the left side of agitating unit 32, play line device 34 is installed in the left side of transmission band 2, the heating device 31 comprises a shell 311, a slurry outlet valve 312, a heater 313, a heating pipe 314 and a heating cavity 315, the slurry outlet valve 312 is installed inside the shell 311, the heater 313 is electrically connected with the slurry outlet valve 312 and installed inside the shell 311, the lower surface of the heating pipe 314 is embedded inside the heater 313, the outer surface of the heating cavity 315 is attached to the inner surface of the shell 311, the upper part of the heating pipe 314 is arranged below the stirring device 32, the slurry outlet valve 312 is connected with the particle cabinet 4 through the stirring device 32, the head end of the outer cylinder 346 is welded with the right surface of the heating cavity 315, the stirring device 32 comprises a central wheel 321, a connecting plate 322, a transmission gear 323, a rotating disk 324, a driving gear 325, a driving rotating shaft 326, a turbine box 321327, a rotating disk rotating shaft 328, a stirring motor 329 and a stirring cam 0, the central wheel 321 and the rotating disk 324 are on the same axis, the outer side of the connecting plate 322 is connected with the inner side of the transmission gear 323, the transmission gear 323 is meshed with the rotary disc 324, the rotary disc 324 and the driving gear 325 are on the same axis, a chain is arranged on the front side of the driving gear 325, the lower end of the driving rotating shaft 326 is parallel to the upper end of the central wheel 321, the front side of the turbine box 327 is arranged on the rear side of the driving rotating shaft 326, the rotary disc rotating shaft 328 is perpendicular to the driving rotating shaft 326, the stirring motor 329 is electrically connected with the turbine box 327, the upper part of the stirring cam 3210 is arranged below the rotary disc rotating shaft 328, the right side of the stirring motor 329 is arranged on the left side of the forming device 33, the stirring cam 3210 is arranged on the right side of the stirring device 32, the forming device 33 is composed of an air cylinder 331, a forming motor 332, a spring 333, a shift lever 334, a forming cam 335, a, The wire drawing device comprises a wire drawing hole 3310, wherein the cylinder 331 is electrically connected with the forming motor 332, the right side of the forming motor 332 is perpendicular to the forming rod 337, the back of the spring 333 is arranged at the front side of the rotary disc 336, the lower part of the shift lever 334 is connected with the left upper end of the forming rod 337, the forming cam 335 and the rotary disc 336 are arranged on the same axis and are arranged at the rear side of the shift lever 334, the front side of the forming rod 337 is meshed with the rear side of the transmission worm wheel 338, the upper part of the transmission worm wheel 338 is embedded and arranged in the rotary disc 336, the cylinder piston 339 and the cylinder 331 are arranged on the same central line, the back of the wire drawing hole 3310 is arranged at the front side of the shift lever 334, the forming rod 337 is arranged at the left side of the conveying belt 2, the bottom end of the rotary disc 336 is arranged on the inner surface of the shell 311, the rotary inner cylinder 341 and the cylinder, The crushing bin 4 comprises an eccentric block 41, a left fragment 42, a right fragment 43, a crushing turbine box 44, a crushing motor 45, a trough 46 and a feeding valve 47, wherein the outer side of the eccentric block 41 is arranged at the inner side of the right fragment 43, the right surface of the left fragment 42 is parallel to the left side of the right fragment 43, the crushing turbine box 44 is electrically connected with the crushing motor 45, the right side of the crushing motor 45 is arranged at the left side of the feeding valve 47, the right side of the trough 46 is connected with the left side of a feeding valve 47, the right side of the feeding valve 47 is arranged on the left side of the heater 313, and the right end of the right fragment 43 is arranged on the upper left of the stirring device 32.

The principle of use; a user places raw materials on a transmission belt 2, the transmission belt 2 is used for driving the raw materials to enter an inlet of a particle cabinet 4, a particle motor 45 is started, a particle turbine box 44 is used for pressurizing so that an eccentric block 41 rotates, the interval potential difference generated by rotation of the eccentric block 41 is used for crushing the raw materials at the inner sides of a left fragment 42 and a right fragment 43, the size of the raw materials is reduced, the raw materials are convenient to process, the raw materials are sent to a heating device 31 through a feeding valve 47, a heating pipe 314 is heated through a heater 313, the raw materials are forged and smelted in a heating cavity 315, a pulp outlet valve 312 is opened, raw pulp enters a rotating inner cylinder 341, a rotating motor 342 is started, the rotating inner cylinder 341 is braked at a high speed through a rotating turbine box 345, the rotating inner cylinder 341 rotates, inner cylinder holes 343 in the rotating inner cylinder 341 are used, the raw pulp is thrown out into filaments from the, the produced filament is stretched out by outer cylinder hole 344, insert the filament in through wires hole 3310 through manual operation, make one end bypass shaping pole 337, through starting shaping cam 335 rear motor, make shaping cam 335 take place to rotate, utilize shaping cam 335 rotation track to promote driving lever 334 and use the head end as the terminal point and move, shaping motor 332 will drive shaping pole 337 rotation simultaneously, make the filament will be processed into the tubulose on shaping pole 337, after processing, cylinder 331 will start, cylinder piston 339 will produce the finished product pipe and push out to the transmission band 2 on.

According to the invention, through the mutual combination of the components, the raw materials are crushed and ground during processing, so that the materials are accelerated to be dissolved, and the raw materials are automatically drawn by the device to be formed, so that the manual contact is reduced, the safety accident is avoided, and the processing efficiency is increased, thereby solving the problems that the raw materials need to be heated for a long time to be dissolved during processing, and the raw stock needs to be drawn manually, so that the safety is poor and the processing efficiency is low.

The motors are all the DFGA60R motors, the device is high in anti-interference capacity and good in heat dissipation effect, the turbine boxes are all reduction boxes adopting NMRV/50 motors, and the reduction boxes are small in size, stable in rotating speed and low in noise.

The specific embodiments described herein are merely illustrative of the invention. Various modifications or additions may be made to the described embodiments or alternatives may be employed by those skilled in the art without departing from the scope of the invention or exceeding the scope of the claims appended hereto.