CN108579530B - Suspension type dissolving and emulsifying device - Google Patents

Abstract

The invention relates to a dissolving and emulsifying device and solves the problems that a thickening agent is easy to generate a caking and sedimentation phenomenon when being emulsified and cannot be installed in a hanging mode. The utility model provides a suspension type dissolves emulsification device, includes the container and sets up in the agitator of container, the container is equipped with the discharging pipe, the agitator includes the pivot and sets up in the pivot and be located a plurality of stirring vane of container, its characterized in that still includes scrapes wall paddle, static chamber and backup pad, scrape wall paddle laminating container diapire internal surface setting, the pivot extends along upper and lower direction, static chamber cover is established in the pivot, the pivot is connected with shearing blade, shearing blade is located static intracavity, be equipped with the intercommunicating pore on the wall in static chamber, stirring vane is located static chamber outside, the container is connected in the backup pad, and the backup pad is equipped with the suspension frame.

Description

Suspension type dissolving and emulsifying device

The application is a divisional application named as a suspension type dissolving and emulsifying device with the application number of 201410801501X1, application date 2014, 12 and 22.

Technical Field

The invention relates to a dissolving and emulsifying device, in particular to a suspension type dissolving and emulsifying device.

Background

In the process flow for preparing the colloid electrolyte, the thickening agent needs to be dissolved and emulsified in advance, and the existing dissolving and emulsifying of the thickening agent is completed in a stirring kettle in an operation mode of electric heating and synchronous stirring. A conventional stirred tank is disclosed in chinese patent application No. 2013102815248, published as 2014, 10 and 2, entitled "stirred tank with dual stirrers". The existing stirring kettle comprises a container and a stirrer arranged in the container, wherein the container is provided with a discharge pipe, the inlet end of the discharge pipe is positioned at the middle lower part of the container, and the stirrer comprises a plurality of stirring blades of a rotating shaft. When the thickener is used, the thickener is placed in the container, the rotating shaft is driven to rotate, and the rotating shaft drives the stirring blades to rotate so as to stir objects in the container. The colloid in the container is then discharged through a discharge pipe.

The following defects generally exist when the existing stirring kettle is used for dissolving and emulsifying the thickening agent: the colloid is easy to generate the phenomena of agglomeration and deposition, and the colloid in the container can not be naturally discharged through self weight; the inside of the container cannot be conveniently observed; the material can not be efficiently stirred when the height of the material is changed, and the phenomenon that the stirring blades are idle can not be generated; cannot be installed in a suspended manner.

Disclosure of Invention

The invention provides a suspension type dissolving and emulsifying device capable of preventing a deposition and agglomeration phenomenon, and solves the problems that the existing dissolving and emulsifying device is easy to cause the agglomeration and agglomeration phenomenon when emulsifying a thickening agent and cannot be installed in a suspension manner.

The technical problem is solved by the following technical scheme: the utility model provides a suspension type dissolves emulsification device, includes the container and sets up in the agitator of container, the container is equipped with the discharging pipe, the agitator includes the pivot and sets up in the pivot and be located a plurality of stirring vane of container, its characterized in that still includes scrapes wall paddle, static chamber and backup pad, scrape wall paddle laminating container diapire internal surface setting, the pivot extends along upper and lower direction, static chamber cover is established in the pivot, the pivot is connected with shearing blade, shearing blade is located static intracavity, be equipped with the intercommunicating pore on the wall in static chamber, stirring vane is located static chamber outside, the container is connected in the backup pad, the backup pad is equipped with the mounted frame. When the device is used, the device is hung by the suspension bracket for installation, the rotating shaft and the wall scraping blade are driven to rotate, but the static cavity is kept static, the rotating shaft drives the stirring blade and the shearing blade to rotate, and the stirring blade stirs objects which are positioned in the container and outside the static cavity so as to promote mixing and dissolving; when the object flows through the static cavity, the shearing blade produces shearing action on the material to prevent the caking phenomenon; the scraping blade scrapes and stirs the bottom of the container to prevent the bottom wall of the container from depositing. The wall scraping blades can be driven together through the rotating shaft, and an independent driving system can be arranged for driving.

Preferably, the suspension frame comprises 5 shock-absorbing rods, each of the 5 shock-absorbing rods is a transverse shock-absorbing rod), two longitudinal shock-absorbing rods and two vertical shock-absorbing rods, one end of each of the two longitudinal shock-absorbing rods is connected with one end of each of the transverse shock-absorbing rods, one end of each of the two vertical shock-absorbing rods is connected with the other end of each of the two longitudinal shock-absorbing rods, and the other end of each of the two vertical shock-absorbing rods is connected with the support plate. When in use, the other end of the transverse shock-absorbing rod is connected with the mounting part to realize the suspension type mounting of the invention. The suspension bracket can reduce the amount of vibration of the three-dimensional space generated during stirring transmitted to peripheral objects, so the effect and the damping effect are good.

Preferably, the shock-absorbing rod is of a tubular structure, a plurality of partition plates are arranged in the shock-absorbing rod, the partition plates isolate the inside of the shock-absorbing rod into a plurality of cavities distributed along the extending direction of the shock-absorbing rod, elastic diaphragms are arranged in the cavities, the elastic diaphragms divide the cavities into filling cavities and vacant cavities, the elastic diaphragms face the bowl-shaped structures arched in the filling cavities, quicksand is filled in the filling cavities, resistance-increasing plates are arranged in the filling cavities, the resistance-increasing plates divide the filling cavities into first filling cavities and second filling cavities, friction holes communicated with the first filling cavities and the second filling cavities are formed in the resistance-increasing plates, and air holes communicated with the shock-absorbing rod are formed in the vacant cavities. When vibration is generated, the shock absorption rod deforms to enable the elastic diaphragm to deform towards the vacant cavity and reset, and meanwhile, the quicksand flows back and forth between the first filling cavity and the second filling cavity, the quicksand rubs with each other when flowing and consumes vibration energy, the quicksand rubs with the friction hole when flowing through the friction hole and rubs between the quicksand, and the vibration absorption effect of the suspension frame is more remarkable.

Preferably, the outer circumferential surface of the shock absorbing rod is provided with a plurality of outer deformation guide grooves distributed along the axial direction of the shock absorbing rod, the inner circumferential surface of the shock absorbing rod is provided with a plurality of inner deformation guide grooves distributed along the axial direction of the shock absorbing rod, the outer deformation guide grooves and the inner deformation guide grooves are annular grooves extending along the circumferential direction of the shock absorbing rod, and the outer deformation guide grooves and the inner deformation guide grooves are aligned. The reliability of the damping rod driving the flowing sand to flow when the vibrating rod is vibrated can be improved. Meanwhile, the shock absorption rod has a good shock absorption effect.

Preferably, the suspension bracket is connected with a coating type heating mechanism, the suspension bracket further comprises an arc-shaped connecting rod which arches upwards or downwards, one end of the connecting rod is connected with the other end of the transverse damping rod, the coating type heating mechanism comprises a swing rod, a swing shaft which drives the swing rod to swing, a swing gear which drives the swing shaft to rotate, a forward driving gear, a reverse driving gear, a reversing gear meshed with the swing wheel and a power input shaft, the forward driving gear and the reverse driving gear are distributed along the axial direction of the power input shaft and connected with the power input shaft, the forward driving gear and the reverse driving gear are sector gears, the forward driving gear and the swing gear are meshed together discontinuously, the reverse driving gear and the reversing gear are meshed together discontinuously, and when the forward driving gear and the swing gear are meshed together, the reverse driving gear and the swing gear are meshed together, The reverse driving gear is disconnected with the reversing gear, when the reverse driving gear is meshed with the reversing gear, the forward driving gear is disconnected with the swinging gear, the forward driving gear drives the rotating angle of the swinging gear to be equal to the rotating angle of the swinging gear driven by the reverse driving gear through the reversing gear, and the swinging rod is provided with a coating head for transmitting heat to the connecting rod. The curved connecting rod can reduce the cross-sectional area of the connecting rod to achieve weight reduction while ensuring connection strength. During the use, give the coating head through with the heat, the coating head is along the connecting rod with heat transfer for the connecting rod when stretching the direction round trip swing for the connecting rod keeps in required temperature range, thereby avoids producing the phenomenon of rupture in cold environment. The reliability of the invention in use is improved. The way to transfer heat to the applicator head is: the coating head is provided with a water absorption structure (such as a cleaning cloth), so that the coating head absorbs hot water from the water tank in the swinging process (the water in the water tank is at the required temperature), and then the connection is insulated in a way that the water absorption structure slides on the connecting rod to coat the hot water on the connecting rod; the coating head is provided with the heater, the coating head is heated to a set temperature through the heater, and then the coating head makes the connecting rod heated and insulated when passing through the connecting rod back and forth. The motor for driving the power input shaft does not need to be reversed, so that the high-frequency swing of the swing rod is convenient to realize. So that the connecting rod can be kept at the required temperature when the ambient temperature is low.

Preferably, the coating head is annular, the coating head is sleeved on the connecting rod, a liquid flow channel extending along the circumferential direction of the coating head is arranged in the coating head, and the inner side wall of the liquid flow channel is made of a heat conducting material. When the heat preservation device is used, hot water flows through the liquid flow channel, so that the heat of the hot water is transferred to the connecting rod to preserve the heat of the connecting rod.

Preferably, the supporting plate is provided with a plurality of supporting bulges, the upper ends of the supporting bulges are connected with suckers which can be turned over to cover the supporting bulges with downward openings, and the container is sucked on the supporting plate through the suckers. During the equipment, adsorb the container through the sucking disc and fix the container in the backup pad, overturn the sucking disc of vacant region and cover on supporting the arch in order to prevent that the edge of sucking disc from being walked by the people in the backup pad and leading to damaging and lose the adsorption and adsorb and live the walking personnel and influence the people and walk in the backup pad, thereby set up the sucking disc in the backup pad and make backup pad surface become unsmooth and play skid-proof effect. This technical scheme has that antiskid and mounting in the backup pad can be general, use region and vacant region can conveniently change the advantage in order to adapt to the size change of container, has solved current backup pad and can not conveniently support and guarantee skid resistance ability to the object of equidimension not and the not general problem between antiskid and the mounting. In this patent document, "use area" refers to an area of the support plate occupied by the container, and "free area" refers to an area of the support plate other than the use area.

Preferably, the shearing blade comprises a vertically arranged substrate, the surface of the substrate is provided with a plurality of blades, the substrate is provided with a sieve hole, and the sieve hole penetrates through the substrate. The arrangement of the cutting edge can improve the shearing effect; the sieve holes are arranged, so that large material blocks cannot pass through and are returned to the knife edge to be sheared and broken. The shearing effect is better.

Preferably, the direction of the cutting edge of the blade is tangent to a cylindrical surface which takes the rotating shaft as a central line and passes through the cutting edge. When the shearing blade rotates, the material can flow along the axial direction of the rotating shaft, and the arrangement mode of the cutting edge can be crossed with the flow direction to play a role in improving the shearing effect.

Preferably, the container is provided with an observation port, an observation tube is connected in the observation port, a spherical pit is arranged in the observation port, the observation tube is provided with a spherical connector, and the observation tube is matched with the spherical pit and is hinged with the spherical surface of the observation port. This technical scheme has and to adjust observation angle as required, to the advantage of observing in the container, has solved current stirred tank and has observed inconvenient problem to container inside.

Preferably, a magnifying glass and an illuminating lamp are arranged in the observation tube. The condition inside the container can be observed more conveniently and clearly.

Preferably, the inner end of the observation tube is provided with a partition plate with a transparent structure, the partition plate, the observation tube and the magnifier enclose a sealed cavity, and the illuminating lamp is positioned in the sealed cavity. Can prevent the articles in the container from damaging the illuminating lamp.

The observation tube is fixedly connected with the observation port through the locking mechanism, the locking mechanism comprises a pressing block and a locking screw for driving the pressing block to press the surface, matched with the observation port, of the observation tube, the locking screw is in threaded connection with the observation port, the pressing block is in spherical surface matching with the observation tube, and the center line of the locking screw passes through the center of the matching surface of the observation tube and the observation port. During the use, rotate locking screw and make according to the pressing block and loosen the fixed action of pressing down to the observation pipe, then adjust the direction of observing the pipe according to the needs of observing and to observing corresponding position, reverse rotation locking screw again, locking screw drive is pressed the pressing block and is compressed tightly on the observation pipe, thereby realize observing the fixed of pipe and viewing aperture. The viewing tube can be locked after being angularly adjusted in place to prevent displacement. The fact that the central line of the locking screw passes through the center of the matching surface of the observation tube and the observation port can reduce damage to the surface of the observation tube when the pressing block is pressed on the surface of the observation tube.

The invention also comprises a sealing ring which connects the observation tube and the observation port together in a sealing way, and the observation tube and the observation port are in clearance fit. Not only can ensure that the joint of the observation tube and the observation port is not leaked, but also can ensure that the observation tube is easy and labor-saving to rotate.

Preferably, the seal ring is fixed to the observation port. The sealing ring can reliably connect the observation tube and the observation port together in a sealing way no matter which angle the observation tube rotates to.

The invention also comprises a wall scraping paddle driving motor for driving the wall scraping paddle to rotate, wherein the wall scraping paddle driving motor is positioned at the bottom of the container, and the wall scraping paddle is disconnected with the rotating shaft. The wall scraping paddle and the rotating shaft are driven separately, and the reliability is good. The driving motor is arranged on the bottom wall of the container, and the stability is good.

Preferably, the stationary chamber is defined by a bottom wall, a top wall and a side wall, and the communication hole includes an upper communication hole provided in the top wall, a lower communication hole provided in the bottom wall and a lateral communication hole provided in the side wall. The static cavity can more effectively isolate internal and external objects to prevent the internal and external materials from generating synchronous motion, thereby playing the role of improving the shearing effect of the materials entering the static cavity.

Preferably, the upper communication hole and the lower communication hole are staggered. The material can be prevented from flowing through the static cavity directly, and the effect of improving the shearing effect on the material is achieved.

Preferably, the blade is elongated and extends in the vertical direction. The cutting edge is long-strip-shaped, so that the effect is good when the cutting is carried out. The blade extends in the up-down direction, and particles can be prevented from being deposited on the blade without being sheared.

Preferably, the mesh is disposed between adjacent blades. The proportion of colloidal particles that are not sheared can be further reduced.

Preferably, the upper surface of the sucker is provided with an anti-skid structure. When the sucking disc upset, the skid resistant course can be outstanding in the outside of sucking disc to play the effect that promotes anti-skidding effect.

Preferably, the anti-slip structure is a plurality of convex points. The antiskid effect is good and the preparation is convenient.

Preferably, the supporting plate further comprises a bracket, the bracket is provided with a hanging arm, the lower surface of the supporting plate is provided with a sliding rail, and the hanging arm is slidably suspended on the sliding rail. The tub filled with the gel (hereinafter, referred to as a gel storage tub) is stored in a space in a lower portion of the support plate by being rested on the bracket. The position of the bracket away from the edge of the supporting plate is changed by moving the hanging arm on the sliding rail, so that a user can conveniently take and place the glue storage barrel without entering the lower space of the supporting plate.

Preferably, the number of the slide rails is two, the number of the hanging arms is two, the lower ends of the two hanging arms are connected to two ends of the bracket, and the upper ends of the two hanging arms are connected to the two slide rails in a one-to-one corresponding mode. The bracket and the wall can not be easily disconnected, and the abrasion between the hanging arm and the sliding rail can be reduced.

Preferably, the discharge hole is located between the two slide rails. The colloid in the container can be conveniently discharged into the colloid storage barrel through the discharge pipe passing through the supporting plate.

Preferably, the height of the support protrusion is 2 cm or less. The antiskid effect is good and the travelling comfort is good when walking on the supporting plate.

Preferably, the support plate is provided with a discharge aperture, the inlet of the tapping pipe being located in the bottom wall of the vessel, the tapping pipe extending through the discharge aperture to below the support plate. After the colloid is made, the barrel containing the colloid is placed below the supporting plate and aligned with the outlet of the discharging pipe, and then the colloid is discharged into the barrel through the discharging pipe. The inlet of the tapping pipe is located in the bottom wall of the container and the container is supported by the support plate, so that the tapping pipe can be emptied by its own weight.

The invention has the following advantages: the thickener can be stirred to promote the dissolving and mixing of the thickener, can be sheared to prevent agglomeration, can be prevented from generating a deposition phenomenon, and can be installed in a hanging mode.

Drawings

Fig. 1 is a schematic view of an emulsifying device in the first embodiment of the present invention.

Fig. 2 is a schematic sectional view B-B of the shear blade of fig. 1.

Fig. 3 is a schematic view of a support plate according to a second embodiment.

Fig. 4 is a partially enlarged schematic view of a portion a of fig. 3.

FIG. 5 is a schematic view of an emulsifying apparatus according to a second embodiment.

FIG. 6 is a schematic view showing the connection between the observation tube and the observation port in the third embodiment.

Fig. 7 is a partial schematic view of a fourth embodiment of the invention.

FIG. 8 is a cross-sectional schematic view of a shock rod.

Fig. 9 is a schematic view of a coating type heating mechanism.

FIG. 10 is a schematic cross-sectional view of the connection of the applicator head to the connecting rod.

In the figure: support plate 1, stairs 12, support legs 13, discharge holes 14, motor through holes 15, slide rails 16, bracket 17, hanging arm 171, support protrusion 18, suction cup 19, antiskid structure 191, suction cup 192 in use area, suction cup 193 in vacant area, container 2, feed hopper 21, observation port 22, spherical pit 221, sealing ring 222, observation tube 23, spherical connector 231, free end 2311 of spherical connector, magnifier 232, partition plate 233, illuminating lamp 234, sealed cavity 235, discharge tube 24, discharge valve 25, stirrer 3, mounting plate 31, connecting rod 311, bolt 312, rotating shaft driving mechanism 32, driving motor 321, driven gear 322, driving gear 323, static cavity 33, bottom wall 331, top wall 332, side wall 333, upper communication hole 334, lower communication hole 335, lateral communication hole 336, rotating shaft 34, stirring blade 35, shearing blade 36, substrate, cutting edge 362, sieve mesh 363, The wall scraping device comprises a wall scraping blade 4, a wall scraping blade driving motor 41, a locking mechanism 5, a pressing block 51, a locking screw 52, a coating type heating mechanism 8, a box shell 80, a swinging shaft 81, a swinging gear 82, a forward driving gear 83, a reverse driving gear 84, a reversing gear 85, a power input shaft 86, a swinging rod 87, a coating head 871, a liquid flow channel 872, an inner side wall 8721 of the liquid flow channel, a driving motor 88, a suspension frame 9, a connecting rod 91, a damping rod 92, a transverse damping rod 921, a longitudinal damping rod 922, a vertical damping rod 923, a shape-changing guide groove 924, an inner shape-changing guide groove 925, a partition plate 93, a cavity 94, a filling cavity 941, a first filling cavity 9411, a second filling cavity 9412, an empty cavity 942, an air hole 9421, an elastic diaphragm 95, a resistance increasing plate 96, a friction hole 961, a direction line L of a cutting edge of the cutting edge, and a.

Detailed Description

The invention is further described with reference to the following figures and examples.

First embodiment, referring to fig. 1, an emulsifying apparatus includes a support plate 1, a container 2, and a stirrer 3.

The support plate 1 is provided with a discharge hole 14 and a motor via hole 15. Two ends of the supporting plate 1 are respectively provided with a suspension bracket 9.

A feed hopper 21 and a viewing port 22 are provided in the top wall of the vessel 2. An observation tube 23 is fixed to the observation port 22. The bottom wall of the container 2 is provided with a discharge pipe 24. The tapping pipe 24 extends through the tapping opening 14 into the lower space of the support plate 1. The discharge pipe 24 is provided with a discharge valve 25. The discharge valve 25 is an electric valve. The container 2 is fixed to the support plate 1. A wall scraping paddle 4 is also arranged in the container 2. The wall scraping paddle 4 is arranged to be attached to the inner surface of the bottom wall of the container 2. The wall scraping paddle 4 is driven by a wall scraping paddle drive motor 41. The wall scraping paddle drive motor 41 is located on the bottom outer surface of the vessel 1. The wall scraping paddle driving motor 41 is inserted into the motor through hole 15 to prevent interference. The container is also provided with an electric heating device (not shown in the figure)

The agitator 3 includes a mounting plate 31, a spindle drive mechanism 32, a static chamber 33, and a spindle 34.

The mounting plate 31 is secured to the top wall of the vessel 2 by bolts 312.

The spindle drive mechanism 32 includes a drive motor 321. The driving motor 321 is fixed above the mounting plate 31 in a vertically disposed manner.

The stationary chamber 33 is suspended below the mounting plate 31 by the connecting rod 311 being fixed together with the mounting plate 31. The resting chamber 33 is located inside the container 2. The static chamber 33 is bounded by a bottom wall 331, a top wall 332 and side walls 333. The side wall 333 is circular. The top wall 331 is provided with an upper communication hole 334. The bottom wall 332 is provided with a lower communication hole 335. The upper communication hole 334 and the lower communication hole 335 are staggered. Lateral communication holes 336 of the side wall 333.

The rotation shaft 34 extends in the up-down direction. The shaft 34 is disconnected from the wall scraping paddle 4. The upper end of the rotary shaft 34 is coaxially connected with the power take-off shaft of the driving motor 321. The lower end of the rotating shaft 34 is inserted into the stationary chamber 33. The shaft 34 is provided with a plurality of stirring blades 35 and a plurality of shearing blades 36. The stirring blade 35 is located inside the vessel 2. The stirring vanes 35 are located above the static chamber 34. The shear blades 36 are located within the static chamber 34. The shear blade 36 includes a vertically disposed base plate 361.

Referring to fig. 2, a plurality of elongated blades 362 and a plurality of mesh 363 are formed on a surface of a substrate 361. The blade 363 extends in the up-down direction. Mesh 363 is disposed between adjacent blades 362. The adjacent blades 362 are provided with sieve holes 363. Mesh 363 extends through substrate 361. The substrate 361 is provided with blades 362 on both sides. The direction line L of the cutting edge is tangent to the cylindrical surface S which takes the rotating shaft as the central line and passes through the cutting edge.

Referring to fig. 1 and 2, in use, the present invention is mounted in a suspended manner by means of two suspension brackets 9. The method for emulsifying the colloid electrolyte thickener comprises the following steps: firstly, a solvent for preparing the lead-acid storage battery colloidal electrolyte thickener is filled in the container 2, then a solute for preparing the lead-acid storage battery colloidal electrolyte thickener is added into the container 2 from the feed hopper 21, the electric heating device is heated, meanwhile, the driving motor 321 drives the rotating shaft 34 to rotate, and the rotating shaft 34 drives the stirring blade 35 and the shearing blade 36 to rotate together. The stirring blade 35 rotates to fully dissolve and mix the materials located in the container and outside the static chamber 33. After entering the static cavity 33, the material is sheared by the shearing blades 36 and then flows out of the static cavity, so that the shearing of the caking blocks can prevent the caking from being generated, and the caking amount is small or even none. The wall scraping blade driving motor 41 drives the wall scraping blade 4 to rotate so as to scrape and stir the inner surface of the bottom wall of the container 1, thereby preventing the deposition phenomenon. The state in the container 2 is observed through the observation tube 23. The glue storage barrel is arranged below the supporting plate 1 and aligned with the discharge hole 14, after the glue is manufactured, the discharge valve 25 is opened, and the glue in the container 2 is discharged into the glue storage barrel through the discharge pipe 24.

The second embodiment is different from the first embodiment in that:

referring to fig. 3, the upper surface of the support plate 1 is provided with a plurality of support protrusions 18. The height of the support projection 18 is 2 cm or less. The upper end of the support protrusion 18 is connected with a suction cup 19. The suction cup 19 is turned down to open downwards and cover the support protrusion 18. A bracket 17 is arranged below the support plate 1. The lower surface of the supporting plate 1 is provided with a slide rail 16. There are two slide rails 16. The slide rails 16 extend to the edge of the support plate 1. The discharge opening 14 is located between two slide rails 16. The bracket 17 is provided with two hanging arms 171. The lower ends of the two hanging arms 171 are connected to both ends of the bracket 17. The upper ends of the two hanging arms 171 are slidably hung on the two slide rails 16 in a one-to-one correspondence.

Referring to fig. 4, the upper surface of the suction cup 19 is provided with a slip prevention structure 191. The anti-slip structure 191 is a plurality of convex points.

Referring to fig. 5, when assembling the present invention, the container 2 is placed on the use area with the opening of the suction cup 192 positioned at the use area facing upward, and the container 2 is sucked and fixed to the support plate 1 by the suction cup 192 at the use area. The opening of the suction cup 193 in the vacant area is downward, so that the anti-skid function can be realized, and the walking on the support plate 1 can not be damaged or influenced.

In use, the cradle 17 is moved to the edge of the surface, the glue cartridge is then placed on the cradle 17, and the cradle 17 is pushed inwardly to align the glue cartridge with the dispensing tube 24.

The third embodiment is different from the second embodiment in that:

referring to fig. 6, the observation tube 23 is fixed to the observation port 22 by the locking mechanism 5.

The observation tube 23 is provided with a ball joint 231. A spherical pit 221 is provided in the viewing port 22. The sight tube 23 is spherically hinged to the sight glass 22 by a spherical joint 231 received in the spherical recess 221. The spherical connector 231 and the spherical recess 221 are in clearance fit. The spherical connector 231 and the spherical recess 221 are connected together in a sealing manner through the sealing ring 222. The seal ring 222 is fixed to the observation port 22. The free ends 2311 of the ball joint are all received within the spherical recess 221 (i.e., within the range of rotation of the reversing tube, the free ends of the ball joint are all located within the spherical recess).

A magnifying glass 232, a partition plate 233 and an illuminating lamp 234 are arranged in the observation tube 23. The partition plate 233 is a transparent structure such as glass. The spacer 233 is located on the inner side of the magnifying glass 232, i.e. the side facing into the container. The isolation plate 233, the observation tube 23 and the magnifying lens 232 enclose a sealed cavity 235. The illumination lamp 234 is located within the sealed cavity 235.

The locking mechanism 5 includes a pressing block 51 and a locking screw 52. The pressing block 51 is recessed in the wall of the spherical recess 221. The pressing block 51 presses against the surface of the observation tube that mates with the observation port, i.e., the surface of the spherical joint 231. The pressing block 51 is in spherical fit with the spherical connector 231. The locking screw 52 is threaded into engagement with the wall of the viewing port 22, i.e., the top wall of the container. The threaded end of the locking screw 52 abuts against the pressing block 51. The center line of the locking screw 52 passes through the center of the fitting surface of the observation tube and the observation port, that is, the spherical center of the spherical surface on which the surface of the spherical joint 231 is located.

When the inside of the container 2 needs to be observed, the illuminating lamp 234 is turned on, the locking mechanism 5 is loosened, the observation tube 23 is rotated to observe the corresponding part in the container 2, and then the inside of the container can be observed through the observation tube 23. After the observation is finished, the observation tube 23 and the observation port 22 are locked together by the locking mechanism 5 from the beginning. The process of loosening and locking the locking mechanism 5 is as follows: the locking screw 51 is rotated to drive the pressing block 52 to move.

The fourth embodiment is different from the third embodiment in that:

referring to fig. 7, the hanger 9 includes a connecting bar 91 and 5 shock-absorbing bars 92. The connector rail 91 is an upwardly (although downwardly is also possible) arched configuration. The 5 shock absorbing rods 92 are a transverse shock absorbing rod 921, two longitudinal shock absorbing rods 922 and two vertical shock absorbing rods 923. One end of the connecting rod 91 is connected to one end of the lateral cushion bar 921. One ends of the two longitudinal damper bars 922 and the other end of the transverse damper bar 921 are connected together. The upper ends of the two vertical shock absorbing rods 923 are connected with the other ends of the two vertical shock absorbing rods 922. The lower ends of the two vertical shock absorbing rods 923 are connected to the upper surface of the support plate 1 (the support plate is schematically shown).

The coating type heating mechanism 8 includes a case 80, a swing lever 87, and a drive motor 88. The pendulum 87 is provided with an applicator head 871. The applicator head 871 is ring-shaped. The applicator head 871 fits over the connector bar 91. The drive motor 88 is fixed to the case 80.

Referring to fig. 8, the outer circumferential surface of the damper rod 92 is provided with a plurality of profile varying guide grooves 924. The outer deformation guide grooves 924 are axially distributed along the damper rod 92. The inner circumferential surface of the shock-absorbing rod 92 is provided with a plurality of inner deformation guide grooves 925. The inner deformation guide grooves 925 are axially distributed along the shock-absorbing rod 92. The outer shape varying guide groove 924 and the inner shape varying guide groove 925 are annular grooves extending in the circumferential direction of the shock-absorbing rod 92. The outer shape-changing guide grooves 924 and the inner shape-changing guide grooves 925 are aligned. Inside the shock-absorbing rod 92, 4 partition plates 93 are provided. The 4 partitions 93 separate the interior of the shock rod 92 into 3 chambers 94. The 3 cavities 94 are distributed along the extension direction of the shock-absorbing rod 92. An elastic diaphragm 95 is disposed within the cavity 94. The elastomeric septum 95 divides the cavity 94 into a filled cavity 941 and an empty cavity 942. The elastomeric diaphragm 95 is a bowl-shaped structure that arches toward the fill cavity 941. An increasing resistance plate 96 is provided in the filling cavity 941. The resistance increasing plate 96 divides the filling cavity 941 into a first filling cavity 9411 and a second filling cavity 9412. The resistance increasing plate 96 is provided with a friction hole 961 communicating the first filling cavity 9411 and the second filling cavity 9412. The filling cavity 941 is filled with quicksand, which is not shown in the figure. The empty chamber 942 is provided with an air hole 9421 penetrating the damper rod 92.

Referring to fig. 9, the applicator heating mechanism 8 further includes a power input shaft 86, a swing shaft 81, and a swing gear 82, a forward drive gear 83, a reverse drive gear 84, and a reverse gear 85 located within the housing. The swing shaft 81 is rotatably connected to the housing 80. The swing gear 82 is connected to the swing shaft 81. The forward drive gear 83 is connected to a power input shaft 86. The power input shaft 86 is rotatably connected to the housing 80. The power input shaft 86 is connected to a power output shaft of a drive motor 88 (see fig. 7). The forward drive gear 83 is a sector gear. The forward drive gear 83 may be rotated to mesh with the swing gear 82. The reverse drive gear 84 is connected to a power input shaft 86. The reverse drive gear 84 and the forward drive gear 83 are distributed along the axial direction of the power input shaft 86. The reverse drive gear 84 is a sector gear. The reverse drive gear 84 may be rotated into meshing engagement with the reversing gear 85. The reverse drive gear 84 and the wobble gear 82 are misaligned so that they cannot mesh together. The reversing gear 85 and the swinging gear 82 mesh together. The swing link 87 is connected with the swing shaft 81.

Referring to fig. 10, a flow channel 872 is provided in the applicator head 871. The flow channel 872 extends circumferentially of the applicator head 871. The inner side wall 8721 of the fluid flow channel is made of a thermally conductive material.

Referring to fig. 7, the suspended mounting of the present invention is accomplished by attaching the other end of the connector rail 91 (i.e., the end that is free in the drawing) to the mounting portion in use.

Referring to fig. 7, 9 and 10, the process of heating the connection bar 91 by the coating type heating mechanism 8 is: a fluid (engine cooling water of an automobile in the present invention) having a desired temperature is caused to flow through the flow passage 872, the drive motor 88 drives the power input shaft 86 to rotate continuously, and the power input shaft 86 drives the forward drive gear 83 and the reverse drive gear 84 to rotate clockwise. When the forward driving gear 83 is meshed with the swinging gear 82, the reverse driving gear 84 is disconnected from the reversing gear 85, the forward driving gear 83 drives the swinging gear 82 to rotate anticlockwise, the swinging gear 82 drives the swinging rod 87 to swing anticlockwise through the swinging shaft 81, and the coating head 871 on the swinging rod 87 slides anticlockwise on the connecting rod 91. When the reverse driving gear 84 is meshed with the reversing gear 85, the forward driving gear 83 is disconnected with the swinging gear 82, the reverse driving gear 84 drives the reversing gear 85 to rotate anticlockwise, the reversing gear 85 drives the swinging gear 82 to swing clockwise, the swinging gear 82 drives the swinging rod 87 to swing clockwise through the swinging shaft 81, and the coating head 871 on the swinging rod 87 slides clockwise on the connecting rod 91. The applicator head 871, while sliding on the stem 91, conducts heat to the stem 91 through the inner sidewall 8721 of the flow channel to heat the stem 91 to a desired temperature, thereby preventing embrittlement due to low temperature. In order to avoid the position deviation when the applicator head 871 slides back and forth and cannot reliably slide on the connecting rod 91, the angle at which the forward driving gear 83 drives the swing gear 82 to swing and the angle at which the reverse driving gear 84 drives the swing gear to swing through the reversing gear are equal.

Claims (6)

1. A suspended dissolving and emulsifying device comprises a container and an agitator arranged in the container, wherein the container is provided with a discharge pipe, the agitator comprises a rotating shaft and a plurality of stirring blades which are arranged on the rotating shaft and are positioned in the container, the suspended dissolving and emulsifying device is characterized by also comprising a wall scraping blade, a static cavity and a supporting plate, the wall scraping blade is attached to the inner surface of the bottom wall of the container, the rotating shaft extends along the vertical direction, the static cavity is sleeved on the rotating shaft, the rotating shaft is connected with a shearing blade, the shearing blade is positioned in the static cavity, a communicating hole is arranged on the wall of the static cavity, the stirring blades are positioned outside the static cavity, the container is connected on the supporting plate, the supporting plate is provided with a suspension bracket, the shearing blade comprises a vertically arranged substrate, the surface of the substrate is provided with a plurality of cutting edges, the substrate, the direction of the cutting edge is tangent to a cylindrical surface which is on the central line of the rotating shaft and passes through the cutting edge, the cutting edge is in a strip shape, and the cutting edge extends along the vertical direction; the suspension bracket comprises 5 shock-absorbing rods, the 5 shock-absorbing rods comprise a transverse shock-absorbing rod, two longitudinal shock-absorbing rods and two vertical shock-absorbing rods, one ends of the two longitudinal shock-absorbing rods are connected with one end of the transverse shock-absorbing rod, one ends of the two vertical shock-absorbing rods are respectively connected with the other ends of the two longitudinal shock-absorbing rods, and the other ends of the two vertical shock-absorbing rods are connected with the support plate; the utility model discloses a damping rod, including damping rod, baffle, packing chamber, reinforcing plate, damping rod, cushion, damping rod, be equipped with a plurality of baffles in the damping rod, the baffle keeps apart the inside of damping rod a plurality of cavitys that distribute along the extending direction of damping rod, be equipped with elastic diaphragm in the cavity, elastic diaphragm will the cavity is split into packing chamber and vacant chamber, elastic diaphragm is the orientation the bowl-shaped structure of packing chamber hunch-up, it has the running sand to pack the intracavity packing, be equipped with the resistance-increasing board in the packing chamber, the resistance-increasing board will the packing chamber is split into first packing chamber and second and is filled the chamber, the resistance-increasing board is equipped with the first friction hole of filling the chamber of intercommunication and second packing chamber, vacant.

2. The suspended type dissolving and emulsifying device according to claim 1, wherein the outer circumference of the shock-absorbing rod is provided with a plurality of outer shape-changing guide grooves distributed along the axial direction of the shock-absorbing rod, the inner circumference of the shock-absorbing rod is provided with a plurality of inner shape-changing guide grooves distributed along the axial direction of the shock-absorbing rod, the outer shape-changing guide grooves and the inner shape-changing guide grooves are annular grooves extending along the circumferential direction of the shock-absorbing rod, and the outer shape-changing guide grooves and the inner shape-changing guide grooves are aligned.

3. The suspended dissolving and emulsifying device according to claim 1 or 2, wherein the suspension bracket is connected with a coating heating mechanism, the suspension bracket further comprises an arc-shaped connecting rod which is arched upwards or downwards, one end of the connecting rod is connected with the other end of the transverse shock-absorbing rod, the coating heating mechanism comprises a swing rod, a swing shaft which drives the swing rod to swing, a swing gear which drives the swing shaft to rotate, a forward driving gear, a reverse driving gear, a reversing gear and a power input shaft which are meshed with the swing wheel, the forward driving gear and the reverse driving gear are distributed along the axial direction of the power input shaft and are connected with the power input shaft, the forward driving gear and the reverse driving gear are sector gears, the forward driving gear and the swing gear are meshed together discontinuously, and the reverse driving gear and the reversing gear are meshed together discontinuously, when the forward driving gear is meshed with the swinging gear, the reverse driving gear is disconnected with the reversing gear, when the reverse driving gear is meshed with the reversing gear, the forward driving gear is disconnected with the swinging gear, the rotating angle of the swinging gear driven by the forward driving gear is equal to the rotating angle of the swinging gear driven by the reverse driving gear through the reversing gear, and the swinging rod is provided with a coating head for transmitting heat to the connecting rod.

4. The suspended dissolving and emulsifying device according to claim 3, wherein the coating head is ring-shaped, the coating head is sleeved on the connecting rod, a liquid flow channel extending along the circumferential direction of the coating head is arranged in the coating head, and the inner side wall of the liquid flow channel is made of heat-conducting material.

5. The suspended dissolving and emulsifying device according to claim 1 or 2, wherein the supporting plate is provided with a plurality of supporting protrusions, the upper ends of the supporting protrusions are connected with suction cups which can be turned to open downwards and cover the supporting protrusions, and the containers are sucked on the supporting plate through the suction cups.

6. The suspended dissolving and emulsifying device according to claim 1 or 2, wherein the container has a viewing port, a viewing tube is connected to the viewing port, a spherical recess is provided in the viewing port, the viewing tube has a spherical connector, and the viewing tube is hinged to the viewing port through the spherical connector matching with the spherical recess.

Images