CN113899172A - Glass magnesium flat plate drying and maintaining equipment - Google Patents

Abstract

The invention discloses a glass magnesium flat plate drying and maintaining device which comprises a bottom plate, a driving part, a three-dimensional drying and maintaining part and a lifter, wherein the driving part is arranged on one side behind the bottom plate, the three-dimensional drying and maintaining part is arranged on the bottom plate, the lifter is positioned right in front of the three-dimensional drying and maintaining part, bears a glass magnesium flat plate to be dried and maintained, changes the height relative to the three-dimensional drying and maintaining part, facilitates the feeding and the taking out of the glass magnesium flat plate, the driving part is used for driving the glass magnesium flat plate to be fed into the three-dimensional drying and maintaining part or taken out of the three-dimensional drying and maintaining part, and the three-dimensional drying and maintaining part is composed of a plurality of layers of drying and maintaining layers and is used for drying and maintaining the glass magnesium flat plate placed in the three-dimensional drying and maintaining part. According to the invention, the air output of different areas of the glass magnesium flat plate is changed according to the humidity of different areas of the glass magnesium flat plate, so that the drying maintenance of different hot air quantities of the glass magnesium flat plate placed on the bearing layer of the glass magnesium flat plate is realized, and the phenomenon of tilting of the dried and maintained glass magnesium flat plate is ensured.

Description

Glass magnesium flat plate drying and maintaining equipment

Technical Field

The invention relates to the technical field of drying and maintaining of building materials, in particular to a glass magnesium flat plate drying and maintaining device.

Background

The glass magnesium flat plate is a magnesium cementing material which is prepared by a ternary system of magnesium oxide, magnesium chloride and water through preparation and addition of a modifier and has stable performance. After the magnesium oxide flat plate is formed by rolling, drying and maintenance are needed, and at present, the magnesium oxide flat plate is placed on a three-dimensional shelf, and then heating air is supplied to a room, so that the drying and maintenance of the magnesium oxide flat plate are realized. The drying maintenance method has the following problems: 1) the humidity of each area of the rolled and formed glass magnesium flat plate is different, and the indiscriminate drying inevitably leads to the tilting of the dried glass magnesium flat plate, so that the flatness of a large number of glass magnesium flat plates cannot meet the requirement; 2) the whole room is heated, and waste of heat resources is caused.

Disclosure of Invention

The purpose of the invention is as follows: in order to overcome the defects of the background art, the invention discloses a drying and maintaining device for a glass magnesium flat plate.

The technical scheme is as follows: the invention discloses a glass magnesium flat plate drying and maintaining device which comprises a bottom plate, a driving part, a three-dimensional drying and maintaining part and a lifter, wherein the driving part is arranged on one side behind the bottom plate, the three-dimensional drying and maintaining part is arranged on the bottom plate, the lifter is positioned right in front of the three-dimensional drying and maintaining part, bears a glass magnesium flat plate to be dried and maintained, changes the height relative to the three-dimensional drying and maintaining part, facilitates the feeding and the taking out of the glass magnesium flat plate, the driving part is used for driving the glass magnesium flat plate to be fed into the three-dimensional drying and maintaining part or taken out of the three-dimensional drying and maintaining part, and the three-dimensional drying and maintaining part is composed of a plurality of layers of drying and maintaining layers and is used for drying and maintaining the glass magnesium flat plate placed in the three-dimensional drying and maintaining part.

Further, drive assembly comprises a main drive layer and a plurality of follow drive layer that piles up on the main drive layer in proper order, the main drive layer includes No. two motors, belt seat bearing, drive shaft, electromagnetic clutch, No. two synchronous pulleys and No. two hold-in ranges, the bottom surface on main drive layer is located to No. two motors, the drive shaft passes through the belt seat bearing and installs in main drive layer bottom surface, the one end of drive shaft pass through the shaft coupling with the output shaft transmission of No. two motors is connected, electromagnetic clutch is installed to the other end of drive shaft, be equipped with No. two synchronous pulleys in the drive shaft, include the drive shaft unanimous with main drive layer structure from the drive layer, No. two synchronous pulleys in the main drive layer drive shaft are connected through No. two synchronous belt transmissions with No. two synchronous pulleys of all drive shafts from the drive layer.

Further, the three-dimensional drying maintenance layer comprises a hot air supply layer and a glass magnesium flat plate bearing layer, wherein the hot air supply layer blows hot air to the upper surface of the glass magnesium flat plate placed on the glass magnesium flat plate bearing layer to dry and maintain the glass magnesium flat plate.

Furthermore, the hot air supply layer comprises an outer frame, a power distribution assembly and a shutter assembly in linear array layout, a plurality of hot air inlets are arranged at the edge of the outer frame, the power distribution assembly is used for driving fan blades of the shutter assembly to rotate, and the size of an air outlet is changed, so that drying and maintenance of different hot air volumes of a glass magnesium panel placed on the glass magnesium panel bearing layer are realized.

Further, 16 shutter assembly mounting grooves are arranged on the outer frame and used for mounting shutter assemblies, and an upper supporting bar, a lower supporting bar, a left supporting bar, a middle supporting bar and a right supporting bar which are used for mounting power distribution assemblies are arranged on the outer frame.

Furthermore, the power distribution assembly comprises a steering engine, a plurality of T-shaped commutators, an L-shaped commutators, a cross-shaped commutators and an electromagnetic clutch. The third L-shaped commutator is arranged at the intersection of the left supporting bar and the upper supporting bar, the third cross commutator, the fifth T-shaped commutator, the third T-shaped commutator and the first cross commutator are sequentially arranged on the left supporting bar in a straight line shape, the second L-shaped commutator is arranged at the intersection of the left supporting bar and the lower supporting bar, the sixth T-shaped commutator is arranged at the intersection of the upper supporting bar and the middle supporting bar, the fourth cross commutator, the seventh T-shaped commutator, the fourth T-shaped commutator and the second cross commutator are sequentially arranged on the middle supporting bar in a straight line shape, the second T-shaped commutator is arranged at the intersection of the middle supporting bar and the lower supporting bar, the fourth L-shaped commutator is arranged at the intersection of the upper supporting bar and the right supporting bar, the first L-shaped commutator is arranged at the intersection of the lower supporting bar and the right supporting bar, the first T-shaped commutator is arranged on the right supporting bar and is in a straight line with the fourth L-shaped commutator and the first L-shaped commutator, and the steering engine is arranged in the middle position of one side of the right support bar, and an output shaft of the steering engine is in transmission connection with an input shaft of the first T-shaped commutator through a coupler.

Further, the power distribution assembly further includes: the two ends of the first transmission shaft are respectively in transmission connection with the left output shaft of the first T-shaped commutator and the input shaft of the first L-shaped commutator through couplers;

the second transmission shaft is arranged between the output shaft of the first L-shaped commutator and the input shaft of the second T-shaped commutator, two ends of the second transmission shaft are respectively in transmission connection with the output shaft of the first L-shaped commutator and the input shaft of the second T-shaped commutator through couplers, one side output shaft of the second T-shaped commutator is in transmission connection with the input shaft of the second cross-shaped commutator through couplers, and two side output shafts of the second cross-shaped commutator are respectively in transmission connection with driving fan blade shafts of the shutter assemblies positioned on the left side and the right side of the second cross-shaped commutator through electromagnetic clutches;

the driving fan blade shaft is arranged on the left side and the right side of the driving fan blade shaft, and the driving fan blade shaft is arranged on the right side and the left side of the driving fan blade shaft;

the first cross-shaped commutator input shaft is in transmission connection with the second L-shaped commutator output shaft through the coupler, and the output shafts on the two sides of the first cross-shaped commutator are in transmission connection with the driving fan blade shafts of the shutter assemblies on the left and right sides of the first cross-shaped commutator through electromagnetic clutches;

the four transmission shafts are arranged between one output shaft of the first cross-shaped commutator and an input shaft of the third T-shaped commutator, two ends of the four transmission shafts are in transmission connection with one output shaft of the first cross-shaped commutator and the input shaft of the third T-shaped commutator through couplers respectively, and two output shafts of the third T-shaped commutator are in transmission connection with driving fan blade shafts of the shutter assemblies positioned on the left side and the right side of the three T-shaped commutator through electromagnetic clutches respectively;

the nine-number transmission shaft is arranged between the input shaft of the fourth L-shaped commutator and the right output shaft of the first T-shaped commutator, and two ends of the nine-number transmission shaft are respectively in transmission connection with the input shaft of the fourth L-shaped commutator and the right output shaft of the first T-shaped commutator through couplers;

the eight-number transmission shaft is arranged between an input shaft of a six-number T-shaped commutator and an output shaft of a four-number L-shaped commutator, two ends of the eight-number transmission shaft are respectively in transmission connection with the input shaft of the six-number T-shaped commutator and the output shaft of the four-number L-shaped commutator through couplers, the input shaft of the four-number cross commutator is in transmission connection with one output shaft of the six-number T-shaped commutator through a coupler, and the output shafts on the left side and the right side of the four-number cross commutator are respectively in transmission connection with driving fan blade shafts of shutter assemblies (313) positioned on the left side and the right side of the four-number cross commutator through electromagnetic clutches;

the ten-type transmission shaft is arranged between one output shaft of the four-type cross commutator and an input shaft of the seven-type T commutator, two ends of the ten-type transmission shaft are respectively in transmission connection with one output shaft of the four-type cross commutator and the input shaft of the seven-type T commutator through couplers, and two output shafts of the seven-type T commutator are respectively in transmission connection with driving fan blade shafts of the louver assemblies positioned on the left side and the right side of the seven-type T commutator through electromagnetic clutches;

the seven transmission shaft is arranged between one output shaft of the six T-shaped commutator and an input shaft of the three L-shaped commutator, two sides of the seven transmission shaft are respectively in transmission connection with one output shaft of the six T-shaped commutator and the three L-shaped commutator through couplers, an output shaft of the three L-shaped commutator is in transmission connection with an input shaft of the three cross-shaped commutator through couplers, and output shafts on the left side and the right side of the three cross-shaped commutator are respectively in transmission connection with driving fan blade shafts of shutter assemblies positioned on the left side and the right side of the three cross-shaped commutator through electromagnetic clutches;

the six-number transmission shaft is arranged between one output shaft of the three-number cross-shaped commutator and an input shaft of the five-number T-shaped commutator, two ends of the six-number transmission shaft are respectively in transmission connection with one output shaft of the three-number cross-shaped commutator and the input shaft of the five-number T-shaped commutator through a coupler, and two output shafts of the five-number T-shaped commutator are respectively in transmission connection with driving fan blade shafts of the shutter assemblies positioned on the left side and the right side of the five-number T-shaped commutator through electromagnetic clutches;

when the inclination angle of the fan blade of a certain shutter component needs to be changed, the electromagnetic clutch connected with the driving fan blade shaft of the shutter component is electrified, then the steering engine is started to rotate for a certain angle, the inclination angle of the fan blade of the shutter component is changed, and therefore the ventilation quantity of the area, below the shutter component, of the glass magnesium flat plate is changed.

Furthermore, the shutter assembly comprises a shutter outer frame and a plurality of fan blades which are rotatably arranged in the shutter outer frame, a synchronous belt wheel is arranged on a rotating shaft at the end part of each fan blade and is connected with the corresponding synchronous belt wheel through a synchronous belt, and when one fan blade rotates under the driving of the power distribution assembly, other fan blades also rotate synchronously, so that the synchronous adjustment of the inclination angles of all the fan blades is realized.

Furthermore, glass magnesium flat plate carrier layer includes curb plate, No. three synchronous pulley, No. three hold-in range, driving roll and many driven drums of both sides, and driving roll and many driven drums install between the curb plate of both sides, No. three synchronous pulley is all installed to driving roll and driven drum's tip to connect through No. three synchronous belt and synchronous, driving roll's the end and the main drive layer that the driver part corresponds or pass through electromagnetic clutch transmission connection from the drive shaft on drive layer.

Furthermore, the elevator comprises an elevator base plate, upright posts, a guide rod, a fourth synchronous belt wheel, a fourth synchronous belt, a fourth motor and a glass magnesium flat plate bearing assembly, through holes are arranged at two ends of a side plate of the glass magnesium flat plate bearing assembly, the upright posts are respectively arranged at four corners of the elevator base plate, the front upright post and the rear upright post are respectively connected through a cross beam, the guide rod is arranged between the cross beam and the elevator base plate through a flange type polished rod mounting seat, the glass magnesium flat plate bearing assembly is arranged on the guide rod through the through holes, universal wheels are arranged at the bottom surface of the elevator base plate, the fourth motor is respectively arranged at the four corners of the elevator base plate through L-shaped plates, the fourth synchronous belt wheel is arranged on an output shaft at the upper end of the upright post, the fourth synchronous belt wheel arranged on an output shaft of the fourth motor is connected with the fourth synchronous belt wheel arranged on an extension shaft at the upper end of the upright post through a fourth synchronous belt, one side of No. four hold-in ranges links firmly mutually through the curb plate of fastening pinion rack with glass magnesium flat board carrier assembly, and after No. four motors started, the rotation through No. four hold-in ranges drove glass magnesium flat board carrier assembly and reciprocates along the guide bar to change glass magnesium flat board carrier assembly's height, make things convenient for sending into and taking out of glass magnesium flat board.

Has the advantages that: compared with the prior art, the invention has the advantages that:

1. according to the invention, the air output of different areas of the glass magnesium flat plate is changed according to the humidity of different areas of the glass magnesium flat plate, so that the drying maintenance of different hot air quantities of the glass magnesium flat plate placed on the bearing layer of the glass magnesium flat plate is realized, and the phenomenon of tilting of the dried and maintained glass magnesium flat plate is ensured;

2. in the process of drying and maintaining the glass magnesium flat plate, hot air is only supplied to the glass magnesium flat plate bearing layer, so that compared with the traditional method of supplying warm air to the whole room, a large amount of heat resources are saved;

3. the driving part respectively controls the rotation of the rollers of the multiple layers of glass magnesium flat plate bearing layers through one driving motor, and compared with the traditional method that the rotation of the rollers of one glass magnesium flat plate bearing layer is independently controlled by one driving motor, the invention saves a large number of driving motors, simplifies the complexity of a control system and reduces the cost;

4. the power distribution assembly of the hot air supply layer respectively controls the rotation of the fan blades of the shutter assemblies through one steering engine, and compared with the traditional method that the rotation of the fan blades of one shutter assembly is independently controlled by one steering engine, the power distribution assembly saves a large number of steering engines, simplifies the complexity of a control system and reduces the cost.

Drawings

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

FIG. 2 is a schematic view of the driving member of the present invention;

FIG. 3 is an enlarged view of FIG. 2 at A;

FIG. 4 is a composition diagram of the drying curing layer according to the present invention;

FIG. 5 is a schematic view showing the internal structure of the hot air supply layer according to the present invention;

FIG. 6 is a top view of FIG. 5;

FIG. 7 is an enlarged view taken at A of FIG. 6;

FIG. 8 is a schematic view of the outer frame structure of the present invention

FIG. 9 is a schematic view of the power distribution assembly of the present invention;

FIG. 10 is an enlarged view taken at A of FIG. 9;

FIG. 11 is a schematic view of the structure of the blind assembly of the present invention

FIG. 12 is an enlarged view of FIG. 11 at A;

FIG. 13 is a schematic structural diagram of a glass magnesium plate bearing layer according to the present invention;

FIG. 14 is an enlarged view at A of FIG. 13;

FIG. 15 is a schematic view of the elevator of the present invention;

FIG. 16 is an enlarged view at A of FIG. 15;

FIG. 17 is an enlarged view at B of FIG. 15;

fig. 18 is an enlarged view of fig. 15 at C.

Detailed Description

The technical solution of the present invention is further described below with reference to the accompanying drawings and examples.

The drying and maintaining equipment for the glass magnesium flat plate shown in figure 1 comprises a bottom plate 1, a driving part 2, a three-dimensional drying and maintaining part 3 and a lifter 4. The driving part 2 is arranged on one side of the rear part of the bottom plate 1, the three-dimensional drying and maintaining part 3 is arranged on the bottom plate 1, the lifter 4 is positioned right ahead the three-dimensional oven 3, the height of a glass magnesium flat plate to be dried and maintained relative to the three-dimensional drying and maintaining part 3 is changed, the feeding and taking of the glass magnesium flat plate are facilitated, the driving part 2 is used for driving the glass magnesium flat plate to be fed into the three-dimensional drying and maintaining part 3 or taken out of the three-dimensional drying and maintaining part 3, the three-dimensional drying and maintaining part 3 is composed of multiple layers of drying and maintaining layers, and the glass magnesium flat plate placed in the three-dimensional drying and maintaining part is dried and maintained.

As shown in fig. 2 and 3, the driving member 2 is composed of a main driving layer 21 and a plurality of auxiliary driving layers 22, and the main driving layer 21 includes a second motor 211, a belt bearing 212, a driving shaft 213, an electromagnetic clutch 214, a second timing pulley 215, and a second timing belt 216. The second motor 211 is installed on the bottom surface of the main driving layer 21 through a motor installation bracket, the driving shaft 213 is installed on the bottom surface of the main driving layer 21 through a belt seat bearing 212, one end of the driving shaft 213 is in transmission connection with an output shaft of the second motor 211 through a coupling, the other end of the driving shaft 213 is installed with an electromagnetic clutch 214, a second synchronous pulley 215 is installed in the middle position of the driving shaft 213, the auxiliary driving layer 22 is similar to the main driving layer 21 in structure, the driving shaft of the auxiliary driving layer 22 is not directly driven by the motor, the second synchronous pulley 215 installed on the driving shaft 213 of the main driving layer 21 and all the second synchronous pulleys installed on the driving shaft of the auxiliary driving layer 22 are in transmission connection through a second synchronous belt 216, and when the second motor 211 rotates, the driving shafts of the main driving layer 21 and all the auxiliary driving layers 22 are driven to rotate in the same direction. When the glass magnesium flat plate needs to be sent into the glass magnesium flat plate bearing layer 32 or taken out of the glass magnesium flat plate bearing layer 32, the electromagnetic clutch 214 of the corresponding layer is electrified, and the roller of the glass magnesium flat plate bearing layer 32 rotates under the driving of the second motor 211, so that the glass magnesium flat plate is sent into the glass magnesium flat plate bearing layer 32 of the three-dimensional drying and curing component 3, or the glass magnesium flat plate is sent out of the glass magnesium flat plate bearing layer 32 of the three-dimensional drying and curing component 3.

As shown in fig. 4, the three-dimensional drying maintenance layer includes a hot air supply layer 31 and a glass magnesium plate support layer 32. The magnesium plate bearing layer 32 can be used for placing a magnesium plate, and the hot air supply layer 31 blows hot air to the upper surface of the magnesium plate placed on the magnesium plate bearing layer 32 to dry and maintain the magnesium plate.

As shown in fig. 5 to 6, the hot air supply layer 31 includes an outer frame 311, a power distribution assembly 312, and louver assemblies 313 arranged in a line array. The edge of the outer frame 311 is provided with a plurality of hot air inlets 311.1. The power distribution component 312 is used for driving the fan blades of the louver component 313 to rotate, and changing the size of the air outlet, thereby realizing the drying and maintenance of the glass magnesium flat plate placed on the glass magnesium flat plate bearing layer 32 with different hot air quantities.

As shown in fig. 8, 16 blind assembly 313 mounting slots are arranged on the outer frame 311 for mounting the blind assemblies 313, and an upper support bar 311.2, a lower support bar 311.5, a left support bar 311.6, a middle support bar 311.4 and a right support bar 311.3 are arranged on the outer frame 311. An upper support bar 311.2, a lower support bar 311.5, a left support bar 311.6, a middle support bar 311.4 and a right support bar 311.3 are used for mounting various commutators and steering engines 31201 of the power distribution assembly 312.

As shown in fig. 7, 9, and 10, the power distribution assembly 312 includes a steering engine 31201, seven T-type commutators, four L-type commutators, four cross-type commutators, and sixteen electromagnetic clutches. The third L-shaped commutator 31218 is mounted at the intersection of the left supporting bar 311.6 and the upper supporting bar 311.2 of the outer frame 311, the third cross commutator 31217, the fifth T-shaped commutator 31215, the third T-shaped commutator 31211 and the first cross commutator 31209 are mounted in the straight line form on the left supporting bar 311.6 of the outer frame 311 in turn, the second L-shaped commutator 31208 is mounted at the intersection of the left supporting bar 311.6 and the lower supporting bar 311.5, the sixth T-shaped commutator 31220 is mounted at the intersection of the upper supporting bar 311.2 and the middle supporting bar 311.4 of the outer frame 311, the fourth cross commutator 31223, the seventh T-shaped commutator 31226, the fourth T-shaped commutator 31214 and the second cross commutator 31212 are mounted in the straight line form on the middle supporting bar 311.4 of the outer frame 311 in turn, the second T-shaped commutator 31206 is mounted at the intersection of the middle supporting bar 311.4 and the lower supporting bar 311.5 of the outer frame 311, the fourth L-shaped commutator 31222 is mounted at the intersection of the upper supporting bar 3122 and the right supporting bar 311.3, first L-shaped commutator 31204 is installed at the intersection of lower supporting bar 311.5 and right supporting bar 311.3 of outer frame 311, first T-shaped commutator 31202 is installed on right supporting bar 311.3 of outer frame 311, and is a straight line with fourth L-shaped commutator 31222 and first L-shaped commutator 31204, and is located the intermediate position of fourth L-shaped commutator 31222 and first L-shaped commutator 31204, steering engine 31201 is installed at the intermediate position of right supporting bar 311.3 side of outer frame 311, and the output shaft of steering engine 31201 is in transmission connection with the input shaft of first T-shaped commutator 31201 through shaft coupling 31228.

The first transmission shaft 31203 is installed between the left output shaft of the first T-shaped commutator 31202 and the input shaft of the first L-shaped commutator 31204, and the two ends of the first transmission shaft 31203 are in transmission connection with the left output shaft of the first T-shaped commutator 31202 and the input shaft of the first L-shaped commutator 31204 through a coupling 31228.

No. two transmission shafts 31205 are installed between No. one L type commutator 31204 output shaft and No. two T type commutator 31206 input shafts, No. two transmission shaft 31205 both ends respectively with No. one L type commutator 31204 output shaft and No. two T type commutator 31206 input shafts through shaft coupling 31228 transmission connection. One side output shaft of the second T-shaped commutator 31206 is in transmission connection with the input shaft of the second cross-shaped commutator 31212 through a coupling 31228, and two side output shafts of the second cross-shaped commutator 31212 are in transmission connection with driving fan blade shafts of the louver assemblies 313 located on the left and right sides of the second cross-shaped commutator 31212 through electromagnetic clutches 31227.

The fifth transmission shaft 31213 is installed between one output shaft of the second cross-shaped commutator 31212 and an input shaft of the fourth T-shaped commutator 31214, two ends of the fifth transmission shaft 31213 are respectively in transmission connection with one output shaft of the second cross-shaped commutator 31212 and the input shaft of the fourth T-shaped commutator 31214 through a coupling 31228, and two output shafts of the fourth T-shaped commutator 31214 are respectively in transmission connection with driving fan blade shafts of the louver assemblies 313 located on the left side and the right side of the fourth T-shaped commutator 31214 through electromagnetic clutches 31227.

The third transmission shaft 31207 is located between one output shaft of the second T-shaped commutator 31206 and the input shaft of the second L-shaped commutator 31208, and two ends of the third transmission shaft 31207 are in transmission connection with one output shaft of the second T-shaped commutator 31206 and the input shaft of the second L-shaped commutator 31208 through a coupling 31228. An input shaft of the first cross-shaped commutator 31209 is in transmission connection with an output shaft of the second L-shaped commutator 31208 through a coupling 31228, and output shafts on both sides of the first cross-shaped commutator 31209 are in transmission connection with driving vane shafts of the louver assemblies 313 on both left and right sides thereof through electromagnetic clutches 31227.

The fourth transmission shaft 31210 is located between one output shaft of the first cross-shaped commutator 31209 and the input shaft of the third T-shaped commutator 31211, two ends of the fourth transmission shaft 31210 are respectively in transmission connection with one output shaft of the first cross-shaped commutator 31209 and the input shaft of the third T-shaped commutator 31211 through a coupling 31228, and two output shafts of the third T-shaped commutator 31211 are respectively in transmission connection with driving fan blade shafts of the louver assemblies 313 located on the left side and the right side of the third T-shaped commutator 31211 through electromagnetic clutches 31227.

The nine-number transmission shaft 31224 is positioned between the input shaft of the four-number L-shaped commutator 31322 and the right output shaft of the first-number T-shaped commutator 31202, and two ends of the nine-number transmission shaft 31224 are respectively in transmission connection with the input shaft of the four-number L-shaped commutator 31322 and the right output shaft of the first-number T-shaped commutator 31202 through a coupler 31228.

The eight-type transmission shaft 31221 is positioned between an input shaft of a six-type T-shaped commutator 31220 and an output shaft of a four-type L-shaped commutator 31322, two ends of the eight-type transmission shaft 31221 are respectively in transmission connection with the input shaft of the six-type T-shaped commutator 31220 and the output shaft of the four-type L-shaped commutator 31322 through a coupling 31228, the input shaft of the four-type cross-shaped commutator 31223 is in transmission connection with one output shaft of the six-type T-shaped commutator 31220 through the coupling 31228, and the output shafts on the left side and the right side of the four-type cross-shaped commutator 31223 are respectively in transmission connection with driving fan blade shafts of the louver assemblies 313 positioned on the left side and the right side of the four-type cross-shaped commutator 31223 through electromagnetic clutches 31227.

The ten-type transmission shaft 31225 is positioned between one output shaft of the four-type cross commutator 31223 and the input shaft of the seven-type T-shaped commutator 31226, two ends of the ten-type transmission shaft 31225 are respectively in transmission connection with one output shaft of the four-type cross commutator 31223 and the input shaft of the seven-type T-shaped commutator 31226 through a coupling 31228, and two output shafts of the seven-type T-shaped commutator 31226 are respectively in transmission connection with driving fan blade shafts of the louver assemblies 313 positioned at the left side and the right side of the seven-type T-shaped commutator 31226 through electromagnetic clutches 31227.

The seventh transmission shaft 31219 is located between one output shaft of the sixth T-shaped commutator 31220 and the input shaft of the third L-shaped commutator 31218, two sides of the seventh transmission shaft 31219 are respectively in transmission connection with one output shaft of the sixth T-shaped commutator 31220 and the third L-shaped commutator 31218 through a coupling 31228, the output shaft of the third L-shaped commutator 31218 is in transmission connection with the input shaft of the third cross-shaped commutator 31217 through a coupling 31228, and the output shafts on the left side and the right side of the third cross-shaped commutator 31217 are respectively in transmission connection with the driving fan blade shafts of the louver assemblies 313 located on the left side and the right side of the third cross-shaped commutator 31217 through electromagnetic clutches 31227.

The sixth transmission shaft 31216 is located between one output shaft of the third cross-shaped commutator 31217 and the input shaft of the fifth T-shaped commutator 31215, two ends of the sixth transmission shaft 31216 are respectively in transmission connection with one output shaft of the third cross-shaped commutator 31217 and the input shaft of the fifth T-shaped commutator 31215 through a coupling 31228, and two output shafts of the fifth T-shaped commutator 31215 are respectively in transmission connection with driving fan blade shafts of the louver assemblies 313 located on the left side and the right side of the fifth T-shaped commutator 31215 through electromagnetic clutches 31227.

When the inclination angle of the fan blade of a certain shutter assembly 313 needs to be changed, the electromagnetic clutch 31227 connected with the driving fan blade shaft of the shutter assembly 313 is electrified, then the steering engine 31201 is started, and the fan blade is rotated by a certain angle, so that the inclination angle of the fan blade of the shutter assembly 313 is changed, and the ventilation quantity of the area, below the shutter assembly 313, of the glass magnesium flat plate is changed.

As shown in fig. 11 and 12, the louver assembly 313 includes a louver housing 3133, blades 3134, a plurality of blades 3134 rotatably installed in the louver housing 3133, a synchronous pulley 3132 rotatably installed on one end of each blade 3134, and a synchronous pulley 3132 installed on one end of each blade 3134 and connected through a synchronous belt 3131, wherein when one blade 3134 is driven by the power distribution assembly 312 to rotate, the other blades 3134 also rotate, thereby adjusting the tilt angles of all blades 3134.

As shown in fig. 13 and 14, the magnesium plate bearing layer 32 includes two side plates 321, a third synchronous pulley 322, a third synchronous belt 323, a driving roller 324 and a plurality of driven rollers 325. A driving roller 324 and a plurality of driven rollers 325 are arranged between the two side plates 321, three synchronous pulleys 322 are arranged at one ends of the driving roller 324 and the driven rollers 325, and the three synchronous pulleys 322 arranged at one ends of the driving roller 324 and the driven rollers 325 are connected through a three synchronous belt 323. The end of the driving roller 324 is in transmission connection with the driving shaft 213 of the main driving layer 21 or the auxiliary driving layer 22 corresponding to the driving component 2 through the electromagnetic clutch 214.

As shown in fig. 15 to 18, the elevator 4 includes an elevator base plate 402, a column 403, a guide rod 405, a fourth synchronous pulley 407, a fourth synchronous belt 409, a fourth motor 411, and a magnesium plate carrier assembly 406, wherein the structure of the magnesium plate carrier assembly 406 is similar to that of the magnesium plate carrier layer 32, and through holes are formed at two ends of side plates of the magnesium plate carrier assembly 406. The four corners of the elevator base plate 402 are respectively provided with upright posts 403, the two upright posts 403 in front are respectively connected with the two upright posts 403 in rear through a cross beam 404, a guide rod 405 is arranged between the cross beam 404 and the elevator base plate 402 through a flange type polish rod mounting base 408, a glass magnesium flat plate bearing component 406 is arranged on the guide rod 405 through holes in the four corners of the glass magnesium flat plate bearing component, and the bottom surface of the elevator base plate 402 is provided with a plurality of universal wheels 401. Four motors 411 are respectively installed at four corners of the bottom plate 402 through L-shaped plates, four synchronous belt wheels 407 are installed on output shafts of the four motors 411, four synchronous belt wheels 407 are installed on extension shafts 403.1 at the upper ends of the upright posts 403, the four synchronous belt wheels installed on the output shafts of the four motors and the four synchronous belt wheels installed on the extension shafts 403.1 at the upper ends of the upright posts 403 are connected through four synchronous belts 409, and one side of each of the four synchronous belts 409 is fixedly connected with a side plate of the glass magnesium plate bearing component 406 through a fastening toothed plate 410. After the fourth motor 411 is started, the fourth synchronous belt 409 rotates to drive the glass magnesium panel bearing component 406 to move up and down along the guide rod 405, so that the height of the glass magnesium panel bearing component 406 is changed, and the glass magnesium panel is conveniently sent in and taken out.

The working method of the invention is as follows:

1. the fourth motor 411 is started, the fourth synchronous belt 409 rotates to drive the glass magnesium panel bearing assembly 406 to move up and down along the guide rod 405, the glass magnesium panel bearing assembly 406 stops at a proper height, and the glass magnesium panel is manually conveyed to the glass magnesium panel bearing assembly 406;

2. the fourth motor 411 is started again, the fourth synchronous belt 409 rotates to drive the glass magnesium panel bearing component 406 to move up and down along the guide rod 405, and the height of the glass magnesium panel bearing component 406 is the same as that of a corresponding glass magnesium panel bearing layer;

3. the electromagnetic clutch 214 on the layer corresponding to the driving part 2 is electrified, the second motor 211 is started to drive the driving roller 324 and the driven roller 325 on the layer to rotate, and meanwhile, the motor of the glass magnesium flat plate bearing assembly 406 is started to drive the driving roller and the driven roller to rotate, so that the glass magnesium flat plate on the glass magnesium flat plate bearing assembly 406 is conveyed into the glass magnesium flat plate bearing layer;

4. the shutter component 313 changes the inclination angle of the fan blades of the magnesium oxide panel according to the humidity of the magnesium oxide panel in the area, so that the air output of the magnesium oxide panel in the area below the shutter component 313 is changed, the drying and maintenance of the magnesium oxide panel placed on the magnesium oxide panel bearing layer 32 with different hot air amounts are realized, and the phenomenon that the dried and maintained magnesium oxide panel is tilted is avoided.

Claims (10)

1. The utility model provides a dull and stereotyped stoving curing means of glass magnesium which characterized in that: including bottom plate (1), driver part (2), three-dimensional stoving maintenance part (3) and lift (4), bottom plate (1) rear side is located in driver part (2), and three-dimensional stoving maintenance part (3) are arranged in on bottom plate (1), lift (4) are located three-dimensional stoving maintenance part (3) dead ahead, bear the weight of the glass magnesium flat board of treating the stoving maintenance and change the height for three-dimensional stoving maintenance part (3), make things convenient for sending into of glass magnesium flat board and take out three-dimensional stoving maintenance part (3), driver part (2) are used for driving glass magnesium flat board and send into three-dimensional stoving maintenance part (3) or take out from three-dimensional stoving maintenance part (3), three-dimensional stoving maintenance part (3) comprise multilayer stoving maintenance layer, dry the maintenance to the glass magnesium flat board of placing wherein.

2. The glass magnesium flat plate drying and maintaining equipment of claim 1, which is characterized in that: the driving component (2) is composed of a main driving layer (21) and a plurality of auxiliary driving layers (22) sequentially stacked on the main driving layer (21), the main driving layer (21) comprises a second motor (211), a belt seat bearing (212), a driving shaft (213), an electromagnetic clutch (214), a second synchronous pulley (215) and a second synchronous belt (216), the second motor (211) is arranged on the bottom surface of the main driving layer (21), the driving shaft (213) is arranged on the bottom surface of the main driving layer (21) through the belt seat bearing (212), one end of the driving shaft (213) is in transmission connection with an output shaft of the second motor (211) through a coupler, the electromagnetic clutch (214) is arranged at the other end of the driving shaft (213), the second synchronous pulley (215) is arranged on the driving shaft (213), the auxiliary driving layer (22) comprises the driving shaft (213) with the structure of the main driving layer (21), and a second synchronous pulley (215) on a driving shaft (213) of the main driving layer (21) is in transmission connection with second synchronous pulleys of driving shafts on all the auxiliary driving layers (22) through a second synchronous belt (216).

3. The glass magnesium flat plate drying and maintaining equipment of claim 2, which is characterized in that: the three-dimensional drying maintenance layer comprises a hot air supply layer (31) and a glass magnesium flat plate bearing layer (32), wherein the hot air supply layer (31) blows hot air to the upper surface of the glass magnesium flat plate placed on the glass magnesium flat plate bearing layer (32) to dry and maintain the glass magnesium flat plate.

4. The glass magnesium flat plate drying and maintaining equipment of claim 3, which is characterized in that: the hot air supply layer (31) comprises an outer frame (311), a power distribution assembly (312) and louver assemblies (313) which are arranged in a linear array mode, a plurality of hot air inlets (311.1) are arranged at the edge of the outer frame (311), the power distribution assembly (312) is used for driving fan blades of the louver assemblies (313) to rotate, the size of an air outlet is changed, and therefore drying maintenance of different hot air volumes of a glass magnesium flat plate placed on the glass magnesium flat plate bearing layer (32) is achieved.

5. The glass magnesium flat plate drying and maintaining equipment of claim 4, which is characterized in that: the outer frame (311) is provided with 16 blind window component mounting grooves for mounting blind window components (313), and the outer frame (311) is provided with an upper supporting bar (311.2), a lower supporting bar (311.5), a left supporting bar (311.6), a middle supporting bar (311.4) and a right supporting bar (311.3) for mounting a power distribution component (312).

6. The glass magnesium flat plate drying and maintaining equipment of claim 5, which is characterized in that: the power distribution assembly (312) comprises a steering engine (31201), a plurality of T-shaped commutators, L-shaped commutators, cross-shaped commutators and an electromagnetic clutch, a third L-shaped commutators (31218) is installed at the intersection of a left supporting strip (311.6) and an upper supporting strip (311.2), a third cross-shaped commutators (31217), a fifth T-shaped commutators (31215), a third T-shaped commutators (31211) and a first cross-shaped commutators (31209) are sequentially installed on the left supporting strip (311.6) in a straight line shape, a second L-shaped commutators (31208) is installed at the intersection of the left supporting strip (311.6) and a lower supporting strip (311.5), a sixth T-shaped commutators (31220) is installed at the intersection of the upper supporting strip (311.2) and a middle supporting strip (311.4), a fourth cross-shaped commutators (31223), a seventh T-shaped commutators (31226), a fourth T-shaped commutators (31214) and a second cross-shaped commutators (31212) are sequentially installed on the supporting strip (311.4), the second T-shaped commutator (31206) is installed at the intersection of the middle support bar (311.4) and the lower support bar (311.5), the fourth L-shaped commutator (31222) is installed at the intersection of the upper support bar (311.2) and the right support bar (311.3), the first L-shaped commutator (31204) is installed at the intersection of the lower support bar (311.5) and the right support bar (311.3), the first T-shaped commutator (31202) is installed on the right support bar (311.3), a straight line is formed by the fourth L-shaped commutator (31222) and the first L-shaped commutator (31204), the straight line is located in the middle positions of the fourth L-shaped commutator (31222) and the first L-shaped commutator (31204), the steering engine (31201) is installed in the middle position of one side of the right support bar (311.3), and an output shaft of the steering engine (31201) is in transmission connection with an input shaft of the first T-shaped commutator (31201) through a coupling (31228).

7. The apparatus for drying and maintaining a magnesium slab as claimed in claim 6, wherein the power distribution assembly (312) further comprises:

the first transmission shaft (31203) is mounted between a left output shaft of the first T-shaped commutator (31202) and an input shaft of the first L-shaped commutator (31204), and two ends of the first transmission shaft (31203) are in transmission connection with the left output shaft of the first T-shaped commutator (31202) and the input shaft of the first L-shaped commutator (31204) through a coupling (31228);

a second transmission shaft (31205) which is installed between an output shaft of the first L-shaped commutator (31204) and an input shaft of the second T-shaped commutator (31206), two ends of the second transmission shaft (31205) are respectively in transmission connection with the output shaft of the first L-shaped commutator (31204) and the input shaft of the second T-shaped commutator (31206) through a coupling (31228), an output shaft at one side of the second T-shaped commutator (31206) is in transmission connection with the input shaft of the second cross-shaped commutator (31212) through a coupling (31228), and output shafts at two sides of the second cross-shaped commutator (31212) are respectively in transmission connection with driving fan blade shafts of the louver assemblies (313) positioned at the left side and the right side of the second cross-shaped commutator (31227) through electromagnetic clutches;

the five-type transmission shaft (31213) is mounted between one output shaft of the second cross-type commutator (31212) and an input shaft of the fourth T-type commutator (31214), two ends of the five-type transmission shaft (31213) are in transmission connection with one output shaft of the second cross-type commutator (31212) and the input shaft of the fourth T-type commutator (31214) through a coupling (31228), and two output shafts of the fourth T-type commutator (31214) are in transmission connection with driving fan blade shafts of the louver assemblies (313) positioned on the left side and the right side of the four-type commutator (31227) through electromagnetic clutches (31227);

the three-number transmission shaft (31207) is mounted between one output shaft of the two-number T-shaped commutator (31206) and an input shaft of the two-number L-shaped commutator (31208), two ends of the three-number transmission shaft (31207) are respectively in transmission connection with one output shaft of the two-number T-shaped commutator (31206) and an input shaft of the two-number L-shaped commutator (31208) through a coupling (31228), an input shaft of the one-number cross-shaped commutator (31209) is in transmission connection with an output shaft of the two-number L-shaped commutator (31208) through a coupling (31228), and output shafts on two sides of the one-number cross-shaped commutator (31209) are respectively in transmission connection with driving fan blade shafts of the louver assemblies (313) positioned on the left side and the right side of the one-number cross-shaped commutator (31227);

the fourth transmission shaft (31210) is mounted between one output shaft of the first cross-shaped commutator (31209) and an input shaft of the third T-shaped commutator (31211), two ends of the fourth transmission shaft (31210) are in transmission connection with one output shaft of the first cross-shaped commutator (31209) and the input shaft of the third T-shaped commutator (31211) through a coupling (31228), and two output shafts of the third T-shaped commutator (31211) are in transmission connection with driving fan blade shafts of the louver assemblies (313) positioned on the left side and the right side of the third T-shaped commutator (31227) through electromagnetic clutches (31227);

the nine-number transmission shaft (31224) is installed between an input shaft of the four-number L-shaped commutator (31322) and a right output shaft of the first T-shaped commutator (31202), and two ends of the nine-number transmission shaft (31224) are in transmission connection with the input shaft of the four-number L-shaped commutator (31322) and the right output shaft of the first T-shaped commutator (31202) through a coupler 31228;

the eight-number transmission shaft (31221) is mounted between an input shaft of a six-number T-shaped commutator (31220) and an output shaft of a four-number L-shaped commutator (31322), two ends of the eight-number transmission shaft (31221) are in transmission connection with the input shaft of the six-number T-shaped commutator (31220) and the output shaft of the four-number L-shaped commutator (31322) through a coupling (31228), the input shaft of the four-number cross-shaped commutator (31223) is in transmission connection with one output shaft of the six-number T-shaped commutator (31220) through the coupling (31228), and output shafts on the left side and the right side of the four-number cross-shaped commutator (31223) are in transmission connection with driving fan blade shafts of shutter assemblies (313) positioned on the left side and the right side of the four-number cross-shaped commutator (31223) through electromagnetic clutches (31227);

the ten-type transmission shaft (31225) is mounted between one output shaft of the four-type cross commutator (31223) and an input shaft of the seven-type T-shaped commutator (31226), two ends of the ten-type transmission shaft (31225) are respectively in transmission connection with one output shaft of the four-type cross commutator (31223) and the input shaft of the seven-type T-shaped commutator (31226) through a coupling (31228), and two output shafts of the seven-type T-shaped commutator (31226) are respectively in transmission connection with driving fan blade shafts of the louver assemblies (313) positioned at the left side and the right side of the seven-type T-shaped commutator (31227);

the seven-transmission shaft (31219) is mounted between one output shaft of a six-T-shaped commutator (31220) and an input shaft of a three-L-shaped commutator (31218), two sides of the seven-transmission shaft (31219) are in transmission connection with one output shaft of the six-T-shaped commutator (31220) and the three-L-shaped commutator (31218) through a coupling (31228), an output shaft of the three-L-shaped commutator (31218) is in transmission connection with the input shaft of the three-cross commutator (31217) through a coupling (31228), and output shafts on the left side and the right side of the three-cross commutator (31217) are in transmission connection with driving fan blade shafts of the louver assemblies (313) positioned on the left side and the right side of the three-cross commutator (31217) through electromagnetic clutches (31227);

the six-transmission shaft (31216) is mounted between one output shaft of the three-cross commutator (31217) and an input shaft of the five-T commutator (31215), two ends of the six-transmission shaft (31216) are in transmission connection with one output shaft of the three-cross commutator (31217) and the input shaft of the five-T commutator (31215) through a coupling (31228), and two output shafts of the five-T commutator (31215) are in transmission connection with driving fan blade shafts of the louver assemblies (313) positioned on the left side and the right side of the five-T commutator (31215) through electromagnetic clutches (31227);

when the fan blade of a certain shutter assembly (313) needs to change the inclination angle, the electromagnetic clutch (31227) connected with the driving fan blade shaft of the shutter assembly (313) is powered on, then the steering engine (31201) is started, and the fan blade is rotated for a certain angle, so that the inclination angle of the fan blade of the shutter assembly (313) is changed, and the ventilation quantity of the area, below the shutter assembly (313), of the glass magnesium flat plate is changed.

8. The glass magnesium flat plate drying and maintaining equipment of claim 7, which is characterized in that: the shutter assembly (313) comprises a shutter outer frame (3133) and a plurality of fan blades (3134) rotatably mounted in the shutter outer frame (3133), a first synchronous pulley (3132) is mounted on a rotating shaft at the end part of each fan blade (3134) and connected through a first synchronous belt (3131), and when one fan blade (3134) rotates under the driving of the power distribution assembly (312), other fan blades also rotate synchronously, so that the synchronous adjustment of the inclination angles of all the fan blades (3134) is realized.

9. The glass magnesium flat plate drying and maintaining equipment of claim 8, which is characterized in that: glass magnesium flat plate carrier layer (32) include curb plate (321) of both sides, No. three synchronous pulley (322), No. three hold-in range (323), drive roller (324) and many driven cylinder (325), and install between curb plate (321) of both sides drive roller (324) and many driven cylinder (325), No. three synchronous pulley (322) are all installed to the tip of drive roller (324) and driven cylinder (325) to connect through No. three synchronous belt (323) and synchronous, the end of drive roller (324) is connected through electromagnetic clutch (214) transmission with main drive layer (21) that driving part (2) correspond or from drive shaft (213) on drive layer (22).

10. The glass magnesium flat plate drying and maintaining equipment of claim 9, characterized in that: the elevator (4) comprises an elevator base plate (402), upright columns (403), guide rods (405), four synchronous belt wheels (407), four synchronous belts (409), four motors (411) and a glass magnesium plate bearing assembly (406), through holes are formed in two ends of a side plate of the glass magnesium plate bearing assembly (406), the upright columns (403) are respectively installed at four corners of the elevator base plate (402), the two upright columns (403) at the front and the rear are respectively connected through a cross beam (404), the guide rods (405) are installed between the cross beam (404) and the elevator base plate (402) through flange type polish rod installation bases (408), the glass magnesium plate bearing assembly (406) is installed on the guide rods (405) through the through holes, universal wheels (401) are installed on the bottom surface of the elevator base plate (402), the four motors (411) are respectively installed at the four corners of the elevator base plate (402) through L-shaped plates, a fourth synchronous pulley (407) is mounted on an output shaft of the vertical column (403), a fourth synchronous pulley (407) is mounted on an extension shaft (403.1) at the upper end of the vertical column (403), the fourth synchronous pulley mounted on the output shaft of a fourth motor (411) is connected with the fourth synchronous pulley mounted on the extension shaft (403.1) at the upper end of the vertical column (403) through a fourth synchronous belt (409), one side of the fourth synchronous belt (409) is fixedly connected with a side plate of the glass magnesium panel bearing component (406) through a fastening toothed plate (410), and after the fourth motor (411) is started, the glass magnesium panel bearing component (406) is driven to move up and down along a guide rod (405) through rotation of the fourth synchronous belt (409), so that the height of the glass magnesium panel bearing component (406) is changed, and feeding and taking out of a glass magnesium panel are facilitated.

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