CN212915936U - Gluconate rotates breaker - Google Patents

Abstract

The application relates to the technical field of gluconate breaker, and discloses a gluconate rotates breaker, and it includes the support frame, the broken bucket of fixedly connected with on the support frame, broken bucket slope sets up on the support frame, the feed inlet has been seted up to broken bucket upper end, be provided with broken mechanism in the broken bucket, the discharge gate has been seted up to the position that broken bucket lateral wall is close to ground. The blocky gluconate semi-finished product that will get into broken barrel from the feed inlet is broken up, and the gluconate semi-finished product that is broken up leaves broken barrel from the discharge gate under the action of gravity, and the material that leaves from the discharge gate is sent into the fluidized bed and is carried out drying process on next step, and this application has the effect that improves the drying efficiency of semi-finished product in the fluidized bed.

Description

Gluconate rotates breaker

Technical Field

The application relates to the field of gluconate breaker, especially relates to a gluconate rotates broken loading attachment.

Background

The gluconate is prepared by using glucose, calcium carbonate and water as raw materials, performing oxidation, filtering, crystallization and centrifugation to obtain a mother solution of the gluconate, performing decoloration treatment on the mother solution, performing filtering, crystallization and centrifugation treatment again, washing a semi-finished product obtained after the treatment, putting the semi-finished product into a fluidized bed for hot drying after washing, and crushing the semi-finished product after drying to obtain a finished product of the gluconate.

At present, during the production of gluconate, most of washed gluconate semi-finished products are directly put into a fluidized bed, and the semi-finished products of the gluconate are dried by the fluidized bed.

In view of the above-mentioned related technologies, the inventors consider that there is a defect that drying efficiency is low because gluconate which is in a block form due to moisture hardening after washing is directly dried.

SUMMERY OF THE UTILITY MODEL

In order to improve the drying efficiency of semi-manufactured goods in the ebullated bed, this application provides a breaker is rotated to gluconate.

The application provides a pair of gluconate rotates breaker adopts following technical scheme:

the utility model provides a breaker is rotated to gluconate, includes the support frame, the broken bucket of fixedly connected with on the support frame, broken bucket slope sets up on the support frame, the feed inlet has been seted up to broken bucket upper end, be provided with broken mechanism in the broken bucket, the discharge gate has been seted up to the position that broken bucket lateral wall is close to ground.

Through adopting above-mentioned technical scheme, cubic semi-manufactured goods gluconate gets into broken bucket from the feed inlet, utilizes crushing mechanism to break up cubic gluconate, on the fixed connection support of broken bucket slope, the discharge gate has been seted up to the position that broken bucket lateral wall is close to ground, and broken-up gluconate semi-manufactured goods falls into broken barrel head portion, and the broken bucket is left from the discharge gate to the semi-manufactured goods of gluconate of broken barrel head portion under the action of gravity.

Preferably, the crushing mechanism comprises a rotating assembly, the rotating assembly is connected with the crushing barrel in a sealing and rotating mode, the lower end of the rotating assembly is connected with a driving assembly, and the upper end of the driving assembly is fixedly connected with a stirring assembly.

Through adopting above-mentioned technical scheme, the sealed rotation of runner assembly is connected inside the staving, utilizes drive assembly drive runner assembly to rotate, and the runner assembly rotates and drives stirring subassembly and rotate, and stirring subassembly rotates the in-process and extrudees the breakage to the gluconate semi-manufactured product.

Preferably, the runner assembly includes the dwang, the dwang rotates with the coaxial sealing of broken bucket to be connected, the coaxial sliding connection of dwang has the connecting rod, set up the waist type groove of vertical setting on the lateral wall of dwang, perpendicular fixedly connected with gag lever post on the lateral wall of connecting rod, gag lever post sliding connection is at waist type inslot, the position that the gag lever post lateral wall is close to stirring subassembly is connected with the spring, the inner wall fixed connection in gag lever post one end and waist type groove is kept away from to the spring, be connected with the vibration subassembly on the connecting rod.

Through adopting above-mentioned technical scheme, the dwang is connected with the sealed rotation of broken bucket, and connecting rod sliding connection slides up and down in the dwang, the connecting rod can follow the length direction of dwang. Set up the waist type groove of vertical setting on the lateral wall of dwang, perpendicular fixed connection's gag lever post sliding connection makes connecting rod and dwang link together in waist type groove on the connecting rod lateral wall, can drive the connecting rod synchronous rotation when the dwang rotates simultaneously. The connecting rod is connected with a vibration component, and the vibration component drives the connecting rod to move up and down along the axis direction of the barrel.

Preferably, the vibration subassembly includes the rolling disc, the rolling disc cover is established on the connecting rod, rolling disc and connecting rod fixed connection, rolling disc lower extreme fixedly connected with ball, the ball has two, two the ball symmetry sets up, the vibration subassembly is still including holding the tray, the annular has been seted up to holding the tray upper end, the bottom of annular is the wave, two ball sliding connection is in the annular, hold the inner wall fixed connection of tray and broken bucket.

Through adopting above-mentioned technical scheme, fixed connection rolling disc on the connecting rod, the connecting rod rotates under the drive of dwang to drive the rolling disc and rotate. The lower end of the rotating disc is fixedly connected with two symmetrically arranged balls, the two balls slide in a ring groove formed in the upper end of the bearing plate, and the balls are abutted against the bottom of the ring groove. The bottom of the ring groove is wavy, the bearing plate is fixedly connected with the inner wall of the crushing barrel, and the ball moves up and down along with the fluctuation of the bottom of the ring groove in the sliding process, so that the rotating disc is driven to move up and down along the axis direction of the connecting rod, and the connecting rod can move up and down along the axis direction of the barrel body

Preferably, the drive assembly comprises a first motor, the motor is fixedly connected with the outer wall of the bottom of the crushing barrel, and the rotating rod is fixedly connected with the spindle of the motor in a coaxial mode.

Through adopting above-mentioned technical scheme, utilize the motor drive dwang to rotate, the shell of motor and the outer wall fixed connection of broken bottom of the barrel portion make the main shaft and the broken bucket relative rotation of motor, the coaxial fixed connection of main shaft of dwang and motor realizes the relative rotation of dwang and broken bucket.

Preferably, the stirring assembly comprises a plurality of first stirring rods, and the first stirring rods are vertically and fixedly connected with the connecting rod.

Through adopting above-mentioned technical scheme, many first puddlers of fixedly connected with on the connecting rod, the connecting rod rotates and drives first puddler and rotates, stirs the semi-manufactured goods of gluconate. The connecting rod drives first puddler and reciprocates along broken bucket's axis direction when driving first puddler pivoted, extrudees the semi-manufactured goods of gluconate to the realization is broken blocky gluconate semi-manufactured goods.

Preferably, a plurality of second stirring rods are vertically and fixedly connected to the inner wall of the box body, and the first stirring rod penetrates through a gap between every two adjacent second stirring rods.

By adopting the technical scheme, the first stirring rod penetrates through the space between the two adjacent second stirring rods when rotating, and shearing and extrusion on the gluconate semi-finished product are formed through relative movement between the two stirring rods, so that the crushing effect on the gluconate semi-finished product is enhanced.

Preferably, the cover is equipped with the sieve on the dwang, the sieve mesh has been seted up on the sieve, the outer wall of sieve and the inner wall fixed connection of broken bucket.

Through adopting above-mentioned technical scheme, utilize the sieve to screen gluconate semi-manufactured goods, bulky gluconate semi-manufactured goods are detained and continue to carry out the breakage in the sieve top, reach the broken requirement and get into the sieve below through the sieve mesh, leave broken bucket from the discharge gate that broken bucket lateral wall was seted up near ground position under the action of gravity.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the crushing mechanism is arranged in the crushing barrel, so that the blocky gluconate semi-finished products entering the crushing barrel from the feeding hole are crushed, the crushed gluconate semi-finished products leave the crushing barrel from the discharging hole under the action of gravity, the next drying processing is carried out, and the drying efficiency is improved;

2. the plurality of second stirring rods are vertically and fixedly connected to the inner wall of the crushing barrel, the first stirring rod penetrates through the space between two adjacent second stirring rods when rotating, and the shearing and extrusion of the gluconate semi-finished product are formed through the relative motion between the two stirring rods, so that the crushing effect of the gluconate semi-finished product is enhanced;

3. the sieve plate is sleeved on the rotating rod and is fixedly connected with the inner wall of the crushing barrel. The screening plate is utilized to screen the gluconate semi-finished products, the massive gluconate semi-finished products are retained above the screening plate to be continuously crushed, and the gluconate semi-finished products leaving from the crushing barrel are all gluconate with smaller volume, so that the crushing is more thorough.

Drawings

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

FIG. 2 is a schematic view of a partial structure of the rotating assembly and the driving assembly of the present embodiment;

fig. 3 is a partial structural schematic diagram of the vibration assembly of the present embodiment.

Description of reference numerals: 100. a support frame; 200. a crushing barrel; 210. a feed inlet; 220. a discharge port; 230. a second stirring rod; 300. a crushing mechanism; 310. a rotating assembly; 311. rotating the rod; 312. a connecting rod; 313. a waist-shaped groove; 314. a limiting rod; 320. a drive assembly; 321. a motor; 330. a stirring assembly; 331. a first stirring rod; 340. a vibrating assembly; 341. rotating the disc; 342. a ball bearing; 343. a support tray; 344. a ring groove; 400. a sieve plate; 410. and (4) screening holes.

Detailed Description

The present application is described in further detail below with reference to figures 1-3.

The embodiment of the application discloses a rotary crushing device for gluconate. Referring to fig. 1 and 2, the rotary crushing device for gluconate comprises a support frame 100, wherein a crushing barrel 200 is fixedly connected to the support frame 100, and the crushing barrel 200 is obliquely arranged on the support frame 100. The upper end of the crushing barrel 200 is provided with a feed inlet 210, and the washed cake-shaped gluconate semi-finished product enters the crushing barrel 200 from the feed inlet 210. The crushing barrel 200 is rotatably connected with a crushing mechanism 300, and the crushing mechanism 300 is used for crushing the blocky gluconate semi-finished product. The discharge port 220 is opened at the position on the side wall of the crushing barrel 200 close to the ground, and the crushed gluconate semi-finished product leaves the crushing barrel 200 from the discharge port 220.

Referring to fig. 1 and 2, the crushing mechanism 300 includes a rotating assembly 310, the rotating assembly 310 is coaxially and rotatably connected with the crushing barrel 200, and the rotating assembly 310 is hermetically and rotatably connected with the bottom of the crushing barrel 200. The lower end of the rotating assembly 310 is connected with a driving assembly 320, and the driving assembly 320 drives the rotating assembly 310 to rotate. Fixedly connected with stirring subassembly 330 on the lateral wall of the drive assembly 320 one end is kept away from to runner assembly 310, and stirring subassembly 330 rotates with runner assembly 310 synchronous, stirs the crushing to cubic gluconate semi-manufactured product in the stirring subassembly 330 rotation in-process.

Referring to fig. 1 and 2, the rotating assembly 310 includes a rotating rod 311, the rotating rod 311 is vertically and hermetically and rotatably connected to the center of the bottom of the crushing barrel 200, and one end of the rotating rod 311 away from the bottom of the barrel is axially and slidably connected to a connecting rod 312. Two waist type grooves 313 have been seted up on the lateral wall of dwang 311, two waist type groove 313 symmetries set up, waist type groove 313 is seted up along the length direction of dwang 311, connecting rod 312 is close to perpendicular fixedly connected with gag lever post 314 on the lateral wall of dwang 311 one end, gag lever post 314 sliding connection is in waist type groove 313, the position that gag lever post 314 lateral wall is close to stirring subassembly 330 is connected with spring 315, spring 315 keeps away from the inner wall fixed connection of gag lever post 314 one end and waist type groove 313, be connected with vibration subassembly 340 on the connecting rod 312, when dwang 311 axis direction is gliding, along with dwang 311 synchronous rotation under the drive of dwang 311.

Referring to fig. 1 and 2, the driving assembly 320 includes a motor 321, a housing of the motor 321 is fixedly connected to an outer wall of the bottom of the crushing barrel 200, a main shaft of the motor 321 is coaxially and fixedly connected to the rotating rod 311, and the rotating shaft is driven to rotate by the motor 321.

Referring to fig. 1 and 2, the stirring assembly 330 includes six first stirring rods 331, the first stirring rods 331 are circumferentially and vertically fixedly connected to the side wall of the connecting rod 312 at equal intervals, and any three first stirring rods 331 are located on the same plane. The first stirring rod 331 is driven by the connecting rod 312 to rotate, so as to stir the gluconate semi-finished product in the crushing barrel 200. Nine second stirring rods 230 are vertically and fixedly connected to the inner wall of the crushing barrel 200 at equal intervals in the circumferential direction, any three second stirring rods 230 are located on the same plane, and the first stirring rod 331 penetrates through a gap between two adjacent second stirring rods 230 in the axial direction of the rotating rod 311 when rotating. Through the relative motion between the first stirring rod 331 and the second stirring rod 230, the semi-finished gluconate product is sheared, and the crushing effect on the semi-finished gluconate product is enhanced.

Referring to fig. 2 and 3, the vibration assembly 340 includes a rotating disc 341, the rotating disc 341 is coaxially and fixedly connected with the connecting rod 312, four balls 342 are fixedly connected to the lower end of the rotating disc 341, and the four balls 342 are symmetrically arranged. The inner wall of the crushing barrel 200 is vertically and fixedly connected with a fixing rod, one end of the fixing rod, far away from the inner wall of the box body, is fixedly connected with a bearing disc 343, the bearing disc 343 is located below the rotating disc 341, the bearing disc 343 is sleeved on the connecting rod 312, an annular groove 344 is formed in the upper portion of the bearing disc 343, the bottom of the annular groove 344 is wavy, four balls 342 slide in the annular groove 344, and the balls 342 are abutted to the bottom of the annular groove 344. The balls 342 move upward as the bottom of the groove 344 rises during sliding, thereby moving the rotating disk 341 in the axial direction of the connecting rod 312. The connecting rod 312 drives the limiting rod 314 to press the spring 315 during the ascending process, and the spring 315 pushes the limiting rod 314 so that the ball 342 moves downwards along with the descending of the bottom of the ring groove 344. The connecting rod 312 moves up and down along the axial direction of the cylinder body, so that the first stirring rod 331 and the second stirring rod 230 extrude the gluconate semi-finished product while shearing the gluconate semi-finished product.

Referring to fig. 2 and 3, the rotating rod 311 is sleeved with a sieve plate 400, the sieve plate 400 is provided with a sieve hole 410, and the outer wall of the sieve plate 400 is fixedly connected with the inner wall of the crushing barrel 200. Screening the gluconate semi-finished products by using the sieve plate 400, and retaining the blocky gluconate semi-finished products above the sieve plate 400 for continuous crushing.

The implementation principle of the rotary crushing device for gluconate provided by the embodiment of the application is as follows: the wet block-shaped gluconate semi-finished product is put into the crushing barrel 200 from the feeding port, the motor 321 is started, the main shaft of the motor 321 rotates to drive the rotating rod 311 to rotate, the rotating rod 311 is connected with the connecting rod 312 in a sliding manner, the rotating rod 311 is provided with a waist-shaped groove 313, the limiting rod 314 which is vertically and fixedly connected with the connecting rod 312 is connected in the waist-shaped groove 313 in a sliding manner, and the rotating rod 311 rotates to drive the connecting rod 312 to rotate. The connecting rod 312 rotates to drive the first stirring rod 331 to rotate. The rotating disc 341 on the connecting rod 312 rotates synchronously with the connecting rod 312, the balls 342 fixedly connected with the lower end of the rotating disc 341 slide in the sliding grooves formed in the upper end of the bearing tray 343, and the balls 342 move up and down along with the fluctuation of the bottom of the annular groove 344 in the sliding process, so that the rotating disc 341 is driven to move up and down along the axis direction of the connecting rod 312, and the connecting rod 312 moves up and down along the axis direction of the cylinder. The first stirring rod 331 rotates by the connecting rod 312 and moves up and down along the axial direction of the connecting rod 312 while rotating. The first stirring rod 331 and the second stirring rod 230 on the side wall of the crushing barrel 200 move relatively, the first stirring rod 331 and the second stirring rod 230 shear and extrude the gluconate semi-finished product, the blocky gluconate semi-finished product is crushed, and the crushed gluconate semi-finished product leaves the crushing barrel 200 from the discharge hole 220 through the sieve plate 400.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides a breaker is rotated to gluconate which characterized in that: including support frame (100), fixedly connected with broken bucket (200) on support frame (100), broken bucket (200) slope sets up on support frame (100), feed inlet (210) have been seted up to broken bucket (200) upper end, be provided with crushing mechanism (300) in broken bucket (200), discharge gate (220) have been seted up to the position that broken bucket (200) lateral wall is close to ground.

2. The gluconate rotation and crushing device according to claim 1, wherein: broken mechanism (300) include runner assembly (310), runner assembly (310) and broken bucket (200) are sealed to be rotated and are connected, runner assembly (310) lower extreme is connected with drive assembly (320), drive assembly (320) upper end fixedly connected with stirring subassembly (330).

3. The gluconate rotation and crushing device according to claim 2, wherein: rotating assembly (310) is including dwang (311), dwang (311) is rotated with broken bucket (200) coaxial seal and is connected, dwang (311) coaxial sliding connection has connecting rod (312), set up waist type groove (313) of vertical setting on the lateral wall of dwang (311), perpendicular fixedly connected with gag lever post (314) on the lateral wall of connecting rod (312), gag lever post (314) sliding connection is in waist type groove (313), the position that gag lever post (314) lateral wall is close to stirring subassembly (330) is connected with spring (315), the inner wall fixed connection of gag lever post (314) one end and waist type groove (313) is kept away from in spring (315), be connected with vibration subassembly (340) on connecting rod (312).

4. The gluconate rotation and crushing device according to claim 3, wherein: vibration subassembly (340) include rolling disc (341), rolling disc (341) are established on connecting rod (312), rolling disc (341) and connecting rod (312) fixed connection, rolling disc (341) lower extreme fixedly connected with ball (342), ball (342) have two, two ball (342) symmetry sets up, vibration subassembly (340) are still including bearing tray (343), annular (344) have been seted up to bearing tray (343) upper end, the bottom of annular (344) is the wave, two ball (342) sliding connection is in annular (344), the inner wall fixed connection of bearing tray (343) and broken bucket (200).

5. The gluconate rotation and crushing device according to claim 4, wherein: drive assembly (320) includes motor (321), motor (321) and broken bucket (200) bottom outer wall fixed connection, the coaxial fixed connection of main shaft of dwang (311) and motor (321).

6. The gluconate rotation and crushing device according to claim 2, wherein: the stirring assembly (330) comprises a plurality of first stirring rods (331), and the first stirring rods (331) are vertically and fixedly connected with the connecting rod (312).

7. The gluconate rotation and crushing device according to claim 6, wherein: the inner wall of the crushing barrel (200) is vertically and fixedly connected with a plurality of second stirring rods (230), and the first stirring rod (331) penetrates through a gap between two adjacent second stirring rods (230).

8. The gluconate rotation and crushing device according to claim 4, wherein: the cover is equipped with sieve (400) on dwang (311), sieve mesh (410) have been seted up on sieve (400), the outer wall of sieve (400) and the inner wall fixed connection of broken bucket (200).

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