CN219599922U - Automatic gypsum line production equipment - Google Patents

Abstract

Automatic gypsum line production equipment belongs to gypsum line production facility technical field. The method is characterized in that: including gypsum line forming device, elevating gear, output device, input device and transfer device, output device and input device all set up between elevating gear and transfer device, and output device is located input device's upside, and gypsum line forming device sets up directly over elevating gear, is provided with mould pusher on the elevating gear, and gypsum line forming device sets up along the output direction of perpendicular to output device. This gypsum line production automation equipment has realized the cyclic utilization of mould, and because the mould carries along width direction, has optimized equipment overall arrangement, has reduced the space that equipment occupy greatly, and then has reduced the area of equipment installation workshop.

Description

Automatic gypsum line production equipment

Technical Field

Automatic gypsum line production equipment belongs to gypsum line production facility technical field.

Background

A gypsum product, consisting essentially of: angular, flat, curved, etc. The gypsum powder as raw material is mixed with water in certain proportion, and the mixture is poured into mould and added with fiber to increase toughness, so that it can be made into various patterns.

The gypsum line is usually produced by using a groove-shaped mould and a scraping plate, namely, gypsum powder and water are mixed and poured into the groove-shaped mould, then the scraping plate scrapes slurry in the mould to form the gypsum line, and the gypsum line can be separated from the groove-shaped mould after solidification.

The gypsum line is produced by the gypsum line production device, but the existing gypsum line production device has the following problems in the use process: 1) The existing gypsum line production device is generally fixed by a slurry storage tank and a scraping plate, a die passes through the bottom of the slurry storage tank, and then the gypsum line production is realized, the slurry storage tank cannot stop delivering slurry in the whole production process, so that the slurry in the slurry storage tank is prevented from being solidified, and the gypsum line production cannot be stopped. In order to ensure production efficiency, a plurality of moulds are generally required to realize continuous production, in the production process of gypsum lines, the moulds can be taken down after the gypsum lines in the moulds are solidified, the existing gypsum line production equipment can only move along the length direction due to the limitation of the working mode, the moulds are butted along the length direction in the production process, the equipment is long, and the length requirement on workshops is high; 2) Because the amount of the slurry needed by the gypsum lines of different types is different, the gypsum powder and the water are continuously fed into the slurry storage tank in the working process of the existing slurry storage tank, and the slurry feeding speed of the slurry storage tank is constant, the existing gypsum line production equipment can only produce gypsum lines of one type at a time, if the produced gypsum lines need to be replaced, the gypsum powder and the water need to be stopped to be added into the slurry storage tank, the slurry in the slurry storage tank is used up, and the discharging speed of the slurry storage tank is adjusted, namely, the existing gypsum line production equipment can only produce gypsum lines of one type at a time, if the gypsum lines of different types need to be produced, the existing gypsum line production equipment needs to be stopped for adjustment, and the use is very inconvenient.

Disclosure of Invention

The utility model aims to solve the technical problems that: overcomes the defects of the prior art, and provides an automatic gypsum line production device which reduces the occupied space of the device and does not obstruct the production of the gypsum line.

The technical scheme adopted for solving the technical problems is as follows: this gypsum line production automation equipment, its characterized in that: including gypsum line forming device, elevating gear, output device, input device and transfer device, output device and input device all set up between elevating gear and transfer device, and output device is located input device's upside, and gypsum line forming device sets up directly over elevating gear, is provided with mould pusher on the elevating gear, and gypsum line forming device sets up along the output direction of perpendicular to output device.

Preferably, the transfer device include transfer cylinder, transfer frame and pole is put to the arm, transfer cylinder's piston rod is connected with transferring the frame to drive transfer frame and reciprocate between output device and input device, the arm is put the pole and is set up in transferring the frame and be close to one side of input device, the arm is put the pole and is had two that the symmetry set up in transferring the frame both sides, input device's input is located two arms and puts between the pole.

Preferably, the output end of the output device and the loading rod are arranged side by side along the output direction.

Preferably, the lifting device comprises a lifting frame, a lifting motor and a lifting screw rod, wherein the lifting screw rod is vertically arranged, the lifting screw rod is in threaded connection with the lifting frame, and the lifting motor is connected with the lifting screw rod.

Preferably, the lifting device further comprises a worm and a worm wheel, the worm wheel is connected with the lifting screw and drives the lifting screw to rotate, the worm is arranged on an output shaft of the lifting motor, and the worm is meshed with the worm wheel.

Preferably, the die pushing device comprises a die electric push rod and a die electromagnet, the die electromagnet is arranged on a piston rod of the die electric push rod, and the extension direction of the die electric push rod is perpendicular to the output direction of the output device.

Preferably, the gypsum line forming device comprises a translation device, a slurry adding device and a scraping plate, wherein the translation device is connected with the slurry adding device and the scraping plate at the same time, the translation direction of the translation device is perpendicular to the output direction of the output device, and the scraping plate and the slurry adding device are sequentially arranged along the movement direction of the translation device. The translation device drives the slurry adding device and the scraping plate to move along the length direction of the die, the slurry adding device injects slurry into the die, the scraping plate can scrape slurry in the die to form gypsum lines, intermittent production of the gypsum lines is achieved, when the slurry adding device moves to the end of the die, the slurry in the slurry adding device is just used up, the slurry is added into the slurry adding device according to different dies, and accordingly the model of the produced gypsum lines can be adjusted according to needs, switching among different gypsum lines can be achieved without stopping, and the use is more convenient.

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

this gypsum line production automation equipment's gypsum line forming device sets up along the output direction of perpendicular to output unit, mould perpendicular to output unit's output direction sets up promptly, mould pusher can push the mould after the shaping to output unit on, output unit sends out the gypsum line after the shaping, after the solidification of gypsum line, the staff takes out the gypsum line in with the mould on the output unit, and send back the mould to transfer device again on, transfer device transfers empty mould to input unit on, input unit carries empty mould to elevating gear, and under the effect of mould pusher, empty mould on the input unit pushes up to elevating gear on, the cyclic utilization of mould has been realized, and because the mould is carried along width direction, and optimize equipment layout, the space that equipment occupy has been reduced greatly, and then the area of equipment installation workshop has been reduced.

Drawings

Fig. 1 is a schematic front view of an automated gypsum line production facility.

Fig. 2 is a right side view schematically showing a gypsum line molding apparatus.

Fig. 3 is a schematic front cross-sectional view of the crane.

Fig. 4 is a perspective view of the rotating frame.

Fig. 5 is a schematic top view of the engagement of the transfer frame with the output belt.

In the figure: 1. the molding frame 2, the lifting frame 3, the mold electric push rod 4, the mold electromagnet 5, the lifting screw rod 6, the lifting motor 7, the mold 8, the worm wheel 9, the worm 10, the scraping plate 11, the charging barrel 12, the stirring motor 13, the lifting frame 14, the stirring blade 15, the lifting screw rod 16, the lifting motor 17, the driving gear 18, the driven gear 19, the charging barrel electric push rod 20, the charging barrel electromagnet 21, the roller 22, the cushion block 23, the pressing block 24, the connecting piece 25, the mounting shaft 26, the conveying frame 27, the input belt 28, the output belt 29, the conveying frame 30, the supporting rod 31, the rotating frame 3101, the supporting groove 32 and the protecting frame.

Detailed Description

The present utility model will be further described with reference to specific embodiments, however, it will be appreciated by those skilled in the art that the detailed description herein with reference to the accompanying drawings is for better illustration, and that the utility model is not necessarily limited to such embodiments, but rather is intended to cover various equivalent alternatives or modifications, as may be readily apparent to those skilled in the art.

Fig. 1 to 5 are diagrams illustrating preferred embodiments of the present utility model, and the present utility model is further described below with reference to fig. 1 to 5.

Automatic equipment for gypsum line production, which is characterized in that: including gypsum line forming device, elevating gear, output device, input device and transfer device, output device and input device all set up between elevating gear and transfer device, and output device is located input device's upside, and gypsum line forming device sets up directly over elevating gear, is provided with mould pusher on the elevating gear, and gypsum line forming device sets up along the output direction of perpendicular to output device. This gypsum line production automation equipment's gypsum line forming device sets up along the output direction of perpendicular to output unit, mould 7 perpendicular to output unit's output direction sets up promptly, mould pusher can push the mould 7 after the shaping to output unit on, output unit sends out the gypsum line after the shaping, after the solidification of gypsum line, the staff takes out the gypsum line in mould 7 on the output unit, and send back mould 7 on the transfer device again, transfer device is with empty mould 7 transport to input unit on, input unit carries empty mould 7 to elevating gear, and under the effect of mould pusher, empty mould 7 on the input unit pushes up to elevating gear on, the cyclic utilization of mould 7 has been realized, and because mould 7 carries along width direction, and optimize the equipment layout, the space that the equipment occupy has been reduced greatly, and then the area of equipment installation workshop has been reduced.

Specific: as shown in fig. 1-2: the gypsum line forming device comprises a slurry adding device, a translation device, a scraping plate 10 and a die pushing device, wherein a discharge hole of the slurry adding device is arranged at the bottom, the translation device is connected with the slurry adding device and the scraping plate 10 simultaneously, the translation device drives the slurry adding device and the scraping plate 10 to reciprocate, the scraping plate 10 and the slurry adding device are sequentially arranged along the moving direction of the translation device, the die pushing device is located at the lower side of the slurry adding device, and the scraping plate 10 protrudes downwards in the slurry adding device. This gypsum line production slip casting design equipment's translation device drives thick liquids interpolation device and scraper blade 10 along the length direction motion of mould 7, thick liquids interpolation device is in injecting the mould 7 with thick liquids, scraper blade 10 can strickle the thick liquids in the mould 7 to form the gypsum line, realized the intermittent type nature production of gypsum line, when thick liquids interpolation device moved to the mould 7 tip, thick liquids in the thick liquids interpolation device were used up just this moment, added thick liquids in to thick liquids interpolation device according to different mould 7, thereby can adjust the model of the gypsum line of production as required, can realize the switching between the different gypsum lines without stopping, it is more convenient to use.

The gypsum line forming device further comprises a forming frame 1 and a lifting device, wherein the translation device is arranged at the top of the frame 1, and the slurry adding device is arranged on the translation device and moves back and forth along with the translation device. The elevating gear sets up in the lower part of frame 1, elevating gear sets up under slurry feeding device, be provided with the mould station on the elevating gear, with conveniently place mould 7, translation device drives slurry feeding device and moves along the length direction of mould 7, scraper blade 10 installs on translation device, the vertical setting of scraper blade 10, and scraper blade 10 sets up directly over the mould station, scraper blade 10 and slurry feeding device set gradually along translation device's direction of movement, and scraper blade 10 is less than slurry feeding device setting, when the production gypsum line, the lower part of scraper blade 10 stretches into in the mould 7, scraper blade 10 and slurry feeding device move along mould 7, thereby realized the automated production of gypsum line. The mould pusher is installed in elevating gear's upside, and mould pusher is located one side of mould station, and mould pusher can both release mould 7 that has produced the gypsum line out the mould station, can pull empty mould 7 into the mould station again.

The lifting device can drive the die 7 to lift, so that the die 7 for producing the gypsum line is conveniently pushed out, the empty die 7 is conveniently fed in, and the continuous production of the gypsum line is conveniently realized.

The lifting device comprises a lifting frame 2, a lifting motor 6 and a lifting screw 5, wherein a vertical lifting guide rail is arranged on a frame 1, the lifting frame 2 is slidably arranged on the lifting guide rail, the lifting screw 5 is rotatably arranged on the frame 1, the lifting screw 5 is in threaded connection with the lifting frame 2, the lifting motor 6 is arranged at the lower part of the frame 1, an output shaft of the lifting motor 6 is connected with the lifting screw 5, and the lifting screw 5 is driven to rotate, so that lifting of the lifting frame 2 is realized.

The bottom of the lifting screw 5 is coaxially provided with a worm wheel 8, the output shaft of the lifting motor 6 is coaxially provided with a worm 9, the worm 9 is meshed with the worm wheel 8, and the lifting motor 6 drives the lifting screw 5 to rotate through the worm 9 and the worm wheel 8, so that the lifting of the lifting frame 2 is realized. The lifting motor 6 can adopt a servo motor, so that the position of the lifting frame 2 can be conveniently and accurately controlled. Because the worm gear mechanism has the characteristic of reverse self-locking, the lifting screw 5 is matched, and the free falling of the lifting frame 2 can be avoided when the lifting motor 6 is accidentally damaged.

The die pushing device comprises a die electric push rod 3 and a die electromagnet 4, the die electric push rod 3 is arranged on the upper side of the lifting frame 2, the die electric push rod 3 is perpendicular to the moving direction of the translation device, and the die electric push rod 3 is arranged on one side of a die station, so that a die 7 on the die station is pushed away from the lifting frame 2. The die electric push rods 3 are arranged in a plurality of rows along the die station, and in the embodiment, the die electric push rods 3 are arranged in two rows along the die station at intervals so as to ensure that the die is pushed away from the die station.

Be provided with mould electro-magnet 4 on each mould electric putter 3, mould electro-magnet 4 can absorb mould 7 to make drag mould 7 to on the mould station of crane 2, and then realized the automatic interpolation of empty mould 7.

The translation device includes translation motor, translation frame, translation rack and translation gear, and the top of frame 1 is provided with horizontal translation guide rail, and the translation frame sets up in the upside of translation guide rail, and the bottom and the translation guide rail slidable of translation frame are connected to guarantee translation frame linear motion, translation guide rail just is provided with two side by side and the interval, can guarantee that the removal of translation frame is more stable. The translation motor is installed on the translation frame, and the translation motor drives translation frame synchronous motion, and translation gear installs on the output shaft of translation motor, and translation rack is installed in frame 1, and translation rack level sets up at the top of frame 1, translation gear and translation rack meshing, and then realized the removal of translation frame.

The slurry adding device comprises a charging barrel 11, a stirring device, a jacking device and a charging barrel pushing device, wherein the charging barrel pushing device comprises a charging barrel electric push rod 19 horizontally arranged on a translation frame.

The feed cylinder 11 is the drum of vertical setting, and the top of feed cylinder 11 is uncovered to be set up, and the bottom of feed cylinder 11 is provided with the discharge gate, and the discharge gate of feed cylinder 11 is provided with the valve to make things convenient for the break-make of control thick liquids output. In the embodiment, the valve adopts a flap valve to ensure smoother opening and closing of the discharge port. The diameter of the lower part of the charging barrel 11 gradually decreases from top to bottom, so that slurry can be discharged smoothly through the discharge hole, and the positioning and the supporting of the charging barrel 11 are facilitated.

The translation frame is provided with a charging barrel positioning part, the charging barrel electric push rod 19 is parallel to the die electric push rod 3, the charging barrel electric push rod 19 and the die electric push rod 3 are positioned on the same side of the charging barrel positioning part, and the charging barrel positioning part is positioned right above the die station. The charging barrel positioning part is arranged at one side of the charging barrel electric cylinder push rod 19, which is far away from the charging barrel electric cylinder push rod, so that the charging barrel 11 can be conveniently pushed in or pushed out of the charging barrel positioning part. The cartridge electromagnet 20 is provided on the cartridge electric push rod 19 to form a suction portion, and the cartridge electric push rod 19 can push the empty cartridge 11 away from the cartridge positioning portion and move the cartridge filled with slurry into the cartridge positioning portion.

The gypsum line forming device further comprises a water adding device, a gypsum powder adding device and a temporary storage device which are arranged on the forming frame 1, wherein the water adding device and the gypsum powder adding device are respectively positioned at two ends of the translation frame, and the temporary storage device and the gypsum powder adding device are arranged at the same end of the translation frame.

The water adding device comprises a water inlet pipe and a metering pump, the water outlet of the metering pump is communicated with the water inlet of the water inlet pipe, the water outlet of the metering pump is higher than the charging barrel 11, and the charging barrel 11 can move to the position right above the water outlet of the water inlet pipe along with the translation frame, so that quantitative water adding for the charging barrel 11 can be realized.

The gypsum powder adding device comprises a storage bin and an auger arranged at the bottom of the storage bin, wherein a weight sensor is arranged at the bottom of the storage bin, a discharge hole of the auger is also higher than the setting of the charging barrel 11, and the charging barrel 11 can move to the position right below the discharge hole of the auger along with the translation frame, so that quantitative gypsum powder adding can be realized. The water adding device and the gypsum powder adding device can be directly realized by adopting the existing devices.

The temporary storage device is arranged on one side of the translation frame, which is close to the output device, and comprises a rotating motor and a rotating frame 31, wherein the rotating frame 31 is rotatably arranged on the forming frame 1, the rotating motor is arranged on the forming frame 1, an output shaft of the rotating motor is connected with the rotating frame 31 and drives the rotating frame 31 to rotate, a rotating shaft of the rotating frame 31 is vertical, and a space for accommodating the charging barrel 11 is arranged on the side part of the rotating frame 31.

The quantitative water is added into the charging barrel 11 firstly, then the quantitative gypsum powder is added, the charging barrel electric push rod 19 pushes the charging barrel 11 into one space of the rotary frame 31, and meanwhile, the well soaked charging barrel 11 in the other space is moved into the charging barrel positioning groove of the translation frame, so that the need of waiting for gypsum powder soaking is eliminated, and the time is saved.

The jacking device comprises a jacking motor 16, a jacking frame 13 and a jacking screw rod 15, wherein a vertical jacking guide rail is arranged on the translation frame, the jacking frame 13 is slidably arranged on the jacking guide rail, the jacking screw rod 15 is vertically arranged, the jacking screw rod 15 is rotatably arranged on the translation frame, the jacking screw rod 15 is in threaded connection with the jacking frame 13, the jacking motor 16 is arranged on the translation frame, a driving gear 17 is arranged on an output shaft of the jacking motor 16, a driven gear 18 is arranged on the jacking screw rod 15, the driving gear 17 is meshed with the driven gear 18, and the jacking motor 16 drives the jacking screw rod 15 to rotate through gear transmission, so that the jacking frame 13 is lifted. The stirring device is arranged on the jacking frame 13 and is lifted along with the jacking frame 13, and the stirring device can be moved into or out of the charging barrel 11 due to the existence of the jacking frame 13, so that the blocking of the stirring device on the movement of the charging barrel 11 can be avoided.

The stirring device comprises a stirring motor 12 and stirring paddles 14, wherein the stirring motor is arranged on a jacking frame 13, the stirring paddles 14 are arranged on the lower side of the jacking frame 13, the stirring paddles 14 are rotatably arranged on the jacking frame 13, an output shaft of the stirring motor 12 is connected with the stirring paddles 14, and the stirring paddles 14 are driven to rotate so as to stir slurry in a charging barrel 11.

The gypsum line production automation equipment further comprises a transfer frame 26, wherein the output device is an output belt 28, the input device is an input belt 27, the input belt 27 is arranged right below the output belt 28, the output end of the input belt 27 protrudes right to the output end of the output belt 28, and the input belt 27 and the output belt 28 are both arranged on the transfer frame 26. The transfer device is mounted at the right end of the carriage 26, the transfer device being arranged between the input end of the input belt 27 and the output end of the output belt 28.

The lifting frame 2 reciprocates between an output end of the input belt 27 and an input end of the output belt 28. The input belt 27 conveys the empty mold 7 to one side of the lifting frame 2, the mold electromagnet 4 sucks the empty mold 7 at the output end of the input belt 27, and the mold electric push rod 3 transfers the empty mold 7 at the output end of the input belt 27 onto the lifting frame 2. After the gypsum line is formed, the die electric push rod 3 pushes the die 7 on the lifting frame 2 to the upper side of the input end of the output belt 28.

As shown in fig. 1 and 5: the transfer device comprises a transfer cylinder, a transfer frame 29 and a supporting rod 30, wherein vertical transfer guide rails are arranged on the transfer frame 26, the transfer guide rails are arranged side by side and are arranged at intervals, the transfer frame 29 is slidably arranged on the transfer guide rails, the transfer cylinder is vertically arranged on the transfer frame 26, a piston rod of the transfer cylinder is connected with the transfer frame 29, and the transfer frame 29 is pushed to lift. The pole 30 is put to the arm and is put the pole 30 and set up in the one side that the transportation frame 29 is close to output belt 28, and the arm is put the pole 30 level and is set up, and the arm is put the pole 30 one end and is transported frame 29 fixed connection, and the other end unsettled setting, arm put the pole 30 have two that the symmetry set up in transportation frame 29 both sides. The spacing of the loading bars 30 is greater than the width of the input end of the input belt 27, and the input end of the input belt 27 is located between the loading bars 30.

When the transfer cylinder drives the transfer frame 29 to rise to be flush with the output belt 28, at this time, the worker moves the mold 7 on the output belt 28 to the supporting rod 30, and takes out the gypsum line in the mold 7. The transfer cylinder drives the transfer frame 29 downwards until the ends of the carrying bar 30 are below the feed belt 27, by means of which the space-time mould 7 is fed to the lifting frame 2.

As shown in fig. 3: the two ends of the lifting frame 2 are provided with pressing devices, the mold station is positioned between the two pressing devices, and the two pressing devices can respectively clamp the reinforcing net, so that the reinforcing net is arranged in the produced gypsum line.

The pressing device comprises a cushion block 22, a pressing block 23 and a connecting piece 24, wherein the cushion block 22 is arranged on the upper side of the lifting frame 2, the pressing block 23 is positioned on the upper side of the cushion block 22, and the top surface of the cushion block 22 is higher than the bottom of a die cavity of the die 7, so that the reinforcing net is positioned in the middle of a produced gypsum line. The connecting piece 24 is located the one side that the briquetting 23 kept away from the mould station, and the right-hand member level of connecting piece 24 sets up to with the top fixed connection of briquetting 23, the left end of connecting piece 24 is buckled downwards, and through the rotatable tip of installing axle 25 at crane 2. The installation shaft 25 is connected with a briquetting motor, the briquetting motor is installed on the lifting frame 2, the briquetting motor drives the installation shaft 25 to rotate, and then the connecting piece 24 drives the briquetting 23 to move so as to clamp or loosen the reinforcing net.

One side of the lifting frame 2 far away from the die electric push rod 3 is provided with a supporting component, both ends of the die station are provided with supporting components so as to support the die 7, and the die 7 can be moved out or in from the lifting frame 2 more smoothly.

The supporting component comprises a roller 21, the roller 21 is rotatably arranged on the lifting frame 2, the axis of the roller 21 is parallel to the length direction of the die 7, the top of the roller 21 protrudes upwards from the lifting frame 2, and the die 7 is supported by the roller 21, so that the die 7 moves more smoothly.

Furthermore, in order to avoid the excessive spacing between the rollers 21, each two adjacent rollers 21 are arranged side by side in the axial direction at intervals, and an overlapping portion is arranged between each two adjacent rollers 21 to ensure more stable support of the mold 7

As shown in fig. 4: both sides of the rotating frame 31 are provided with bearing grooves 3101 to form a space for accommodating the material cylinder 11, the upper side of the rotating frame 31 is provided with a protecting frame 32, and the upper side of each bearing groove 3101 is provided with a protecting frame 32, so that the material cylinder 11 can be prevented from toppling over.

When the material cylinder 11 enters the bearing groove 3101, the lower part of the material cylinder 11 stretches into the bearing groove 3101, and the upper part of the material cylinder 11 is positioned in the protection frame 32, so that the material cylinder 11 is stable.

The rotary frame 31 is provided at a central portion thereof with a shaft hole to be rotatably installed on the molding frame 1 by a main shaft.

As shown in fig. 1: the working process of the gypsum line production automation equipment is as follows: after the gypsum line is produced, the metering pump adds quantitative water into the empty charging barrel 11, then the translational motor drives the charging barrel 11 to move to the other end of the forming frame 1 through the translational frame, a charging barrel positioning groove of the translational frame is aligned with an empty bearing groove 3101 of the rotary frame 31, after quantitative gypsum powder is added into the charging barrel 11 through the auger, the charging barrel electric push rod 19 pushes the charging barrel 11 on the translational frame, the charging barrel 11 enters into the corresponding bearing groove 3101, the rotary motor drives the rotary frame 31 to rotate 180 degrees, the soaked charging barrel 11 is opposite to the charging barrel positioning groove of the translational frame, the charging barrel electromagnet 20 attracts the corresponding charging barrel 11, and meanwhile the charging barrel electric push rod 19 contracts, so that the charging barrel 11 on the rotary frame 31 moves into the charging barrel positioning groove of the translational frame.

The jacking motor 16 drives the jacking frame 13 to descend, so that the stirring blade 14 enters the charging barrel 11, and in the process, the stirring motor 12 drives the stirring blade 14 to rotate, so that the stirring blade 14 can smoothly enter the charging barrel 11.

The pressing blocks 23 at the two ends are matched with the cushion blocks 22 to clamp the reinforcing net, then the lifting motor 6 drives the lifting frame 2 to lift until the scraping plate 10 enters the die 7, then the translation motor drives the translation frame to move, the slurry in the charging barrel 11 is added into the die 7, and meanwhile the scraping plate 10 scrapes the slurry in the die 7, so that a gypsum line is formed in the die 7.

After the gypsum line is produced, the die 7 is pushed to the input end of the output belt 28 by the die electric push rod 3 from the lifting frame 2. The output belt 28 carries mould 7, and the gypsum line in the mould solidifies in the transportation process, and when mould 7 moves to the output of output belt 28, the staff pulls mould 7 to the transportation frame 29 this moment, takes out the gypsum line in the mould 7 simultaneously.

The transfer cylinder moves the transfer frame 29 downwards until the carrying bar 30 is below the input end of the input belt 27, and the space-time mould 7 moves onto the input belt 27 and along with the input belt 27 to the output end. In the process, the lifting motor 6 drives the lifting frame 2 to descend through the lifting screw 5 and is flush with the input belt 29, and the die electric push rod 3 drags the die 7 at the output end of the input belt 27 to the lifting frame 2 through the die electromagnet 4, so that the production of the next gypsum line is realized.

The above description is only a preferred embodiment of the present utility model, and is not intended to limit the utility model in any way, and any person skilled in the art may make modifications or alterations to the disclosed technical content to the equivalent embodiments. However, any simple modification, equivalent variation and variation of the above embodiments according to the technical substance of the present utility model still fall within the protection scope of the technical solution of the present utility model.

Claims (7)

1. Automatic equipment for gypsum line production, which is characterized in that: including gypsum line forming device, elevating gear, output device, input device and transfer device, output device and input device all set up between elevating gear and transfer device, and output device is located input device's upside, and gypsum line forming device sets up directly over elevating gear, is provided with mould pusher on the elevating gear, and gypsum line forming device sets up along the output direction of perpendicular to output device.

2. The automated gypsum line production apparatus of claim 1, wherein: the transfer device comprises a transfer cylinder, a transfer frame (29) and a supporting rod (30), wherein a piston rod of the transfer cylinder is connected with the transfer frame (29) and drives the transfer frame (29) to reciprocate between the output device and the input device, the supporting rod (30) is arranged on one side, close to the input device, of the transfer frame (29), the supporting rod (30) is symmetrically arranged on two sides of the transfer frame (29), and the input end of the input device is positioned between the two supporting rods (30).

3. The automated gypsum line production apparatus of claim 2, wherein: the output end of the output device and the loading rod (30) are arranged side by side along the output direction.

4. The automated gypsum line production apparatus of claim 1, wherein: the lifting device comprises a lifting frame (2), a lifting motor (6) and a lifting screw (5), wherein the lifting screw (5) is vertically arranged, the lifting screw (5) is in threaded connection with the lifting frame (2), and the lifting motor (6) is connected with the lifting screw (5).

5. The automated gypsum line production apparatus of claim 4, wherein: the lifting device also comprises a worm (9) and a worm wheel (8), wherein the worm wheel (8) is connected with the lifting screw (5) and drives the lifting screw (5) to rotate, the worm (9) is mounted on an output shaft of the lifting motor (6), and the worm (9) is meshed with the worm wheel (8).

6. The automated gypsum line production apparatus of claim 1, wherein: the die pushing device comprises a die electric push rod (3) and a die electromagnet (4), the die electromagnet (4) is mounted on a piston rod of the die electric push rod (3), and the extension direction of the die electric push rod (3) is perpendicular to the output direction of the output device.

7. The automated gypsum line production apparatus of claim 1, wherein: the gypsum line forming device comprises a translation device, a slurry adding device and a scraping plate (10), wherein the translation device is connected with the slurry adding device and the scraping plate (10) at the same time, the translation direction of the translation device is perpendicular to the output direction of the output device, and the scraping plate (10) and the slurry adding device are sequentially arranged along the movement direction of the translation device.