CN111975994B - Dry-mixed mortar prevents segregation storage cylinder - Google Patents

Abstract

The application relates to a dry-mixed mortar anti-segregation storage cylinder which comprises a cylinder body, a stirring roller and a driving assembly. The upper part of the cylinder body is provided with a feed inlet, and the lower part of the cylinder body is provided with a discharge outlet. The stirring rollers are arranged side by side, four stirring grooves are formed in the periphery of any one stirring roller at intervals along the circumferential direction, the side wall of each stirring groove is arc-shaped, the radius of each arc-shaped stirring groove is equal to that of each stirring roller, and meanwhile, when the stirring rollers rotate, the track circle swept by the circle center of each stirring groove coincides with the axis of the other stirring roller. The driving assembly is arranged on the cylinder body and used for driving the stirring roller to intermittently rotate. This application has two stirring rollers and rotates 90 ︒ in proper order intermittent type formula to utilize the stirred tank to continuously stir, mix dry-mixed mortar, reduce likepowder and particulate matter separation's probability, in order to realize improving the effect of dry-mixed mortar's "segregation" phenomenon.

Description

Dry-mixed mortar prevents segregation storage cylinder

Technical Field

The application relates to the field of mixture storage, in particular to a dry-mixed mortar anti-segregation storage cylinder.

Background

The dry-mixed mortar is generally prepared from cement, sand, fly ash, slag and additives with special properties, is a granular or powdery mixture, is uniformly mixed and prepared by a dry-mixed mortar mixing station, is sent to a construction site in a bag mode or in a bulk mode by using a dry-mixed mortar transport vehicle, and is mixed with water in a certain proportion for use. The dry-mixed mortar has the advantages of stable quality, high efficiency, excellent quality, complete variety, convenient use and the like.

In view of the above-mentioned related art, the inventors consider that there is a defect that the dry-mixed mortar may be separated from the powder and the particles during storage, i.e., the "segregation" phenomenon of the dry-mixed mortar occurs.

Disclosure of Invention

In order to improve the segregation phenomenon of the dry-mixed mortar, the application provides an anti-segregation storage cylinder for the dry-mixed mortar.

The application provides a dry-mixed mortar prevents segregation storage cylinder adopts following technical scheme:

a dry-mixed mortar segregation-preventing storage cylinder comprising:

the upper part of the cylinder is provided with a feed inlet, and the lower part of the cylinder is provided with a discharge outlet;

the stirring rollers are arranged in the barrel body in a parallel rotating mode, stirring grooves are formed in the peripheries of the stirring rollers at intervals along the circumferential direction, the side walls of the stirring grooves are arc-shaped, and in two adjacent stirring rollers, a track circle swept by the circle center of the arc-shaped side wall of the stirring groove on one stirring roller is overlapped with the axis of the other stirring roller; and

and the driving assembly is arranged on the barrel and used for driving the stirring rollers to intermittently rotate, and one of the two adjacent stirring rollers is driven to rotate until the axis of the side wall of the stirring tank on the stirring roller is superposed with the axis of the other stirring roller, and then the other stirring roller is driven to rotate.

By adopting the technical scheme, the driving assembly is utilized to drive the stirring roller to intermittently rotate in the storage process of the dry-mixed mortar, so that the stirring tank is utilized to continuously stir and mix the dry-mixed mortar, the probability of separating powder materials and particles is reduced, and the separation phenomenon of the dry-mixed mortar is improved;

meanwhile, in the process of intermittently rotating the mixing rollers, the periphery of one mixing roller in two adjacent mixing rollers is in sliding butt joint with the side wall of the mixing tank on the other mixing roller, so that dry-mixed mortar is prevented from being attached and adhered to the mixing rollers, and the normal use of the mixing rollers is ensured in the long-term use process.

Preferably, the driving assembly includes:

the driven disc is coaxially connected with the stirring roller;

the driven rods are arranged and equal to the number of the stirring grooves in one stirring roller, the driven rods are arranged at intervals along the circumferential direction of the driven disc, and the driven rods are parallel to the axis of the driven disc and are arranged on the driven disc in an axially sliding manner;

the control panel is arranged on the cylinder and is positioned on one axial side of the driven panel, and the end surface of the control panel is used for slidably abutting against one end of the driven rod and enabling the other end of one driven rod to extend out of the driven panel;

the driving rods are arranged and are equal to the driven discs in number, the driving rods are rotatably arranged on the cylinder body, the rotating axes of the driving rods are coaxially arranged with the corresponding driven discs, the driving rods are perpendicular to the driven rods, and the peripheries of the driving rods are used for slidably abutting against the peripheries of the driven rods at one ends, far away from the control disc, of the driven rods; and

and the motor is used for driving the driving rod to rotate.

By adopting the technical scheme, the motor drives the driving rods to continuously rotate, the other end of one driven rod extends out of the driven disc through the control disc, the driving rods push the driven rods to further drive the stirring rollers to transmit, when one stirring roller rotates until the axis of the side wall of the stirring tank on the stirring roller is overlapped with the axis of the other stirring roller, the driven rods retract into the driven disc, and the stirring rollers stop rotating; at this time, the other stirring roller starts to rotate;

repeating the above process, realizing the intermittent rotation of the stirring roller and keeping the motor in a continuous rotation state.

Preferably, the axis of the control panel coincides with the axis of the driven panel, and a sliding groove is formed in the end surface, facing the driven panel, of the control panel, and extends along the circumferential direction of the control panel so as to be used for the end part of the driven rod to be embedded in a sliding manner;

the drive assembly still includes the guide part, the guide part inlays and locates in the spout, and is located self extending direction one end is followed to the spout, the guide part extends to the terminal surface of control panel from the tank bottom of spout towards the terminal surface of driven plate for the slip butt the tip of driven lever.

Through adopting above-mentioned technical scheme, when the tip of driven lever slides to inlay and locates in the spout, in the other end withdrawal driven plate of driven lever, avoid contacting with the actuating lever, afterwards, the driven lever slides in the spout, removes to guide part department to the terminal surface along the guide part removes, and then makes the driven lever stretch out the driven plate gradually, in order to be used for the butt actuating lever.

Preferably, the control panel is provided with a caulking groove which is communicated with the sliding groove, and the caulking groove is used for embedding the end face of the driven rod;

the drive assembly further includes:

the embedded spring is connected with the driven disc at one end and the driven rod at the other end, and the embedded spring enables the driven rod to tightly abut against the control disc;

the separation block is slidably embedded in the embedded groove, the end face of the separation block is used for abutting against the end face of the driven rod, and the end face is used for aligning with the groove bottom of the sliding groove; and

and the driving piece is arranged on the control panel and used for driving the separation block to move.

By adopting the technical scheme, the driven rod is ensured to tightly abut against the control panel, and the driven rod is matched with the control panel to realize the extension and retraction of the driven rod on the driven panel;

meanwhile, when one stirring roller rotates to the position that the axis of the side wall of the stirring groove on the stirring roller is superposed with the axis of the other stirring roller, the end part of the driven rod is embedded into the embedding groove, and the stopping and the positioning of the stirring roller are realized.

Preferably, an installation cavity is arranged in the control panel, the installation cavity is communicated with the caulking groove, and the guide part penetrates into the installation cavity along the axial direction of the control panel;

the driving member includes:

the driving block is arranged in the mounting cavity in a sliding mode and slides along the axial direction of the control panel, the separation block and the guide part are connected with the driving block, and when the end face of the separation block is aligned with the bottom of the sliding groove, the guide part extends out of the sliding groove; and

the separation spring is arranged in the mounting cavity, one end of the separation spring is connected with the control disc, the other end of the separation spring is connected with the driving block, and the driving block is enabled to have a tendency of approaching to the driven disc;

and when the stop ring abuts against the driven disc, the end part of the driven rod abuts against the end surface of the control disc.

Through adopting above-mentioned technical scheme, the actuating lever promotes the driven lever, and then when making the driven plate rotate, next driven lever moves to the guide part along the spout on for guide part, driver block move and compression break away from the spring, and simultaneously, break away from in the piece retraction caulking groove, the realization utilizes caulking groove location driven lever.

Preferably, the driven disc is provided with abdicating grooves at intervals along the circumferential direction;

the drive assembly further includes:

the sliding block is slidably embedded in the abdicating groove and slides along the circumferential direction of the driven disc, and the driven rod penetrates through the sliding block;

and the abutting spring is arranged in the abdicating groove, one end of the abutting spring is connected with the driven disc, and the other end of the abutting spring is connected with the sliding block.

By adopting the technical scheme, at least one driven rod is embedded in the embedding groove, and meanwhile, one driven rod abuts against the guide part and extends out of the driven disc;

the driving rod abuts and pushes the driven rod and the sliding block to overcome the elastic force of the abutting spring and slide, so that the driven rod leaves the guide part, then the driving block moves towards the direction close to the driven disc under the action of the separation spring, and the separation block pushes the driven rod embedded in the caulking groove to separate from the caulking groove.

Preferably, the driving assembly further comprises:

and the transmission mechanism is arranged on the cylinder body and used for transmitting power between the motor and the driving rods and enabling the driving rods to synchronously rotate.

Through adopting above-mentioned technical scheme, a plurality of stirring roller intermittent type formula of synchronous drive rotate.

Preferably, an included angle exists between a plurality of the driving rods, and the included angle between two driving rods =360 ︒/number N of the stirring grooves on the stirring roller, where N is a positive integer.

Through adopting above-mentioned technical scheme, in the long-term use, be favorable to guaranteeing normal work between a plurality of stirring rollers.

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

1. the two stirring rollers rotate 90 ︒ intermittently in sequence to utilize the stirring tank to continuously stir and mix the dry-mixed mortar, reduce the probability of separating the powdery material and the particles and realize the improvement of the segregation phenomenon of the dry-mixed mortar;

2. when the circle center of the circular arc-shaped side wall of the stirring groove on one stirring roller is superposed with the axis of the other stirring roller and the other stirring roller rotates, the periphery of the other stirring roller is in sliding contact with the circular arc-shaped side wall of the stirring groove, and dry-mixed mortar attached to the side wall of the stirring groove is scraped.

Drawings

Fig. 1 is a schematic overall structure diagram of an embodiment of the present application.

Fig. 2 is a schematic view of the internal structure of the cartridge.

Fig. 3 is a schematic view of the structure of the stirring roller.

Fig. 4 is a schematic structural diagram of the transmission mechanism.

Fig. 5 is a schematic structural view of the driving assembly.

Fig. 6 is a schematic view of the structure of the driven disk.

Fig. 7 is a sectional view of the driving assembly.

Fig. 8 is a schematic diagram of the structure at a in fig. 7.

FIG. 9 is an exploded view of the control disc, drive block and disengagement spring.

FIG. 10 is a schematic view of the structure of the control panel.

Fig. 11 is a schematic view of the link between the driven lever and the control disk.

Description of reference numerals: 1. a barrel; 11. a feed inlet; 12. a discharge port; 2. a stirring roller; 21. a stirring tank; 22. a rotating shaft; 3. a drive assembly; 31. a motor; 32. a transmission mechanism; 321. a driving wheel; 322. a drive bar; 33. a drive rod; 34. a driven plate; 341. a yielding groove; 342. positioning a groove; 343. a slider; 3431. embedding holes; 3432. a stopper; 3433. a spring slot; 3434. positioning blocks; 344. the spring is tightly propped; 345. a driven lever; 3451. a baffle ring; 346. a spring is embedded; 35. a control panel; 351. a chute; 352. caulking grooves; 353. a mounting cavity; 36. a drive block; 361. a guide portion; 362. a disengagement block; 37. disengaging the spring.

Detailed Description

The present application is described in further detail below with reference to figures 1-11.

The embodiment of the application discloses a dry-mixed mortar segregation-prevention storage cylinder.

Referring to fig. 1 and 2, the dry-mixed mortar segregation-preventing storage cylinder includes a cylinder body 1, a stirring roller 2, and a driving assembly 3.

The upper part of the cylinder body 1 is provided with a feed inlet 11, and the lower part of the cylinder body 1 is provided with a discharge outlet 12.

Referring to fig. 2 and 3, two stirring rollers 2 are arranged side by side, four stirring grooves 21 are arranged on the periphery of any one stirring roller 2 at intervals along the circumferential direction, the side walls of the stirring grooves 21 are arc-shaped, the radius of the arc-shaped is equal to that of the stirring roller 2, and when the stirring roller 2 rotates, a track circle swept by the center of the stirring groove 21 coincides with the axis of the other stirring roller 2.

The driving component 3 is arranged on the cylinder body 1 and used for driving the stirring roller 2 to intermittently rotate.

The two stirring rollers 2 rotate 90 ︒ intermittently in sequence to continuously stir and mix the dry-mixed mortar by using the stirring tank 21, so that the probability of separating powder materials and particles is reduced, and the separation phenomenon of the dry-mixed mortar is improved; meanwhile, when the circle center of the circular arc-shaped side wall of the stirring groove 21 on one stirring roller 2 coincides with the axis of the other stirring roller 2, and the other stirring roller 2 rotates, the periphery of the other stirring roller 2 is in sliding contact with the circular arc-shaped side wall of the stirring groove 21, and dry-mixed mortar attached to the side wall of the stirring groove 21 is scraped.

Referring to fig. 2 and 4, the driving assembly 3 includes a motor 31, a transmission mechanism 32, a driving lever 33, a driven disc 34, and a control disc 35.

The motor 31 is arranged at the top of the barrel 1 and is positioned at one side of the feeding hole 11.

The transmission mechanism 32 can adopt synchronous belt transmission or chain transmission, and includes two transmission wheels 321 and a transmission strip 322, the two transmission wheels 321 correspond to the two stirring rollers 2 one by one, the transmission strip 322 is wound on the two transmission wheels 321, and an output shaft of the motor 31 is coaxially connected with one transmission wheel 321.

Referring to fig. 4 and 5, two driving rods 33 are provided and correspond to the driving wheels 321 one by one, the driving rods 33 are arranged along the radial direction of the driving wheels 321, and the two driving rods 33 are parallel to each other and are located at a phase difference of 180 ︒.

Referring to fig. 5 and 6, the upper end of the stirring roller 2 coaxially extends to form a rotating shaft 22, and the driven disc 34 is coaxially connected with the rotating shaft 22 and can be fixedly connected by welding, interference fit and other methods; and a space is formed between the upper end of the rotating shaft 22 and the transmission wheel 321.

Referring to fig. 6, four yielding grooves 341 are circumferentially arranged on the driven disc 34 at intervals, a slider 343 is slidably embedded in each yielding groove 341, the slider 343 slides along the circumferential direction of the driven disc 34, a resisting spring 344 is arranged in each yielding groove 341 and on one side of the slider 343 in the rotation direction of the driven disc 34, the resisting spring 344 extends and retracts along the circumferential direction of the driven disc 34, one end of the resisting spring 344 is connected with the driven disc 34, and the other end of the resisting spring 343 is connected with the slider 343.

Referring to fig. 6 and 7, a fitting hole 3431 is formed in the slider 343, the fitting hole 3431 penetrates through the slider 343 in the axial direction of the driven plate 34, a driven rod 345 is slidably fitted in the fitting hole 3431, the upper end of the driven rod 345 extends out of the fitting hole 3431 to abut against the driving rod 33, and the upper end of the driven rod 345 is retracted into the fitting hole 3431 to avoid the driving rod 33.

Referring to fig. 7 and 8, a stopper 3432 is coaxially disposed in the insertion hole 3431, a stop ring 3451 is coaxially disposed on the outer periphery of the driven rod 345, the stopper 3432 is used for abutting against the upper end of the stop ring 3451, an insertion spring 346 is further disposed in the insertion hole 3431, the insertion spring 346 stretches along the axial direction of the insertion hole 3431, one end of the insertion spring 346 is connected to the stopper 3432, the other end of the insertion spring 346 is connected to the stop ring 3451, and the lower end of the driven rod 345 abuts against the control disk 35, so that the control disk 35 is matched, and the lower end of the driven rod 345 is provided as a ball head.

The lower end of the stop 3432 is further provided with a spring groove 3433, the embedded spring 346 can be completely embedded into the spring groove 3433 after being pressed and deformed, so that the stop ring 3451 abuts against the stop 3432, meanwhile, both ends of the slide block 343 in the radial direction of the driven disc 34 are provided with positioning blocks 3434, and the side wall of the yielding groove 341 is provided with a positioning groove 342 for slidably embedding the positioning blocks 3434, so as to limit the position of the slide block 343 in the axial direction of the driven disc 34.

Referring to fig. 5 and 7, the control panel 35 is fixedly connected to the upper end of the barrel 1, and the control panel 35 is sleeved on the periphery of the rotating shaft 22 and rotates relatively therebetween.

Referring to fig. 7 and 9, the upper end of the control disk 35 is provided with a sliding groove 351, the sliding groove 351 extends along the circumferential direction 270 ︒ of the control disk 35 for the end portion of the driven rod 345 to be slidably inserted, and referring to fig. 10 and 11, two insertion grooves 352 are provided at the groove bottom of the sliding groove 351, and the insertion grooves 352 are used for the end portion of the driven rod 345 to be inserted.

Referring to fig. 7 and 9, an installation cavity 353 is further provided inside the control disk 35, a driving block 36 and a disengaging spring 37 are embedded in the installation cavity 353, the driving block 36 is annular and slides along the axial direction of the control disk 35, a guide portion 361 and a disengaging block 362 are provided at the upper end of the driving block 36, the guide portion 361 is used for penetrating through the control disk 35 and being embedded into the sliding groove 351, the guide portion 361 is located along the driven disk 34 of the sliding groove 351, the disengaging block 362 is used for being embedded into the embedding groove 352, and the end portion of the disengaging block 362 is used for abutting against the driven rod 345; and the highest point of the guide portion 361 is flush with the end surface of the control disk 35, the upper end of the disengagement block 362 is located in the insertion groove 352, that is, the upper end of the disengagement block 362 is lower than the groove bottom of the sliding groove 351.

The disengagement spring 37 expands and contracts in the axial direction of the control plate 35, and one end of the disengagement spring 37 is connected to the cylinder 1 and the other end is connected to the lower end of the drive block 36, so that the drive block 36 has a tendency to approach the driven plate 34, i.e., so that the upper end of the disengagement block 362 is flush with the bottom of the groove of the slide groove 351, so that the driven rod 345 is disengaged from the insertion groove 352.

Referring to fig. 6 and 7, when the lower end of the driven rod 345 is inserted into the insertion groove 352, the upper end of the driven rod 345 is retracted into the insertion hole 3431; when the lower end of the driven rod 345 abuts against the groove bottom of the sliding groove 351, the upper end of the driven rod 345 is flush with the end part of the driven disc 34; when the lower end of the driven lever 345 abuts against the end surface of the control disk 35, the stopper 3451 abuts against the stopper 3432, and the upper end of the driven lever 345 protrudes out of the fitting hole 3431 for abutting against the drive lever 33.

The end part of the driven rod 345 is embedded in the embedding groove 352, so that the driven disc 34 is positioned, the position of the stirring roller 2 is further positioned, the driving rod 33 extrudes and pushes the driven rod 345, the slide block 343 overcomes the elastic force of the abutting spring 344 to move, the driven rod 345 is separated from the guide part 361, under the elastic force of the separating spring 37, the driving block 36 is close to the driven disc 34, the end surface of the separating block 362 is flush with the groove bottom of the slide groove 351, so that the driven rod 345 is separated from the embedding groove 352, at the moment, the driven disc 34 starts to rotate, and meanwhile, the guide part 361 pushes the next driven rod 345 to extend out of the slide block 343;

the upper end of the guide portion 361 is in a state of extending out of the sliding groove 351 until the stopper 3451 abuts against the stopper 3432, the driven disc 34 continues to rotate, and the axial position of the next driven rod 345 is locked, so that the driven rod 345 reversely pushes the guide portion 361 and makes the guide portion 361 away from the driven disc 34, and at the same time, the driving block 36 and the disengaging block 362 integrated with the guide portion 361 are away from the driven disc 34, that is, the upper end of the disengaging block 362 retracts into the embedding groove 352, so that the end portion of the driven rod 345 is embedded into the embedding groove 352, and the stop and the positioning of the driven disc 34 are completed.

The implementation principle of the dry-mixed mortar anti-segregation storage cylinder in the embodiment of the application is as follows: the motor 31 continuously rotates, the two stirring rollers 2 are driven by the driving assembly 3 to sequentially and intermittently rotate 90 ︒, so that the dry-mixed mortar is continuously stirred and mixed by using the stirring tank 21, the probability of separating powder materials and particles is reduced, and the separation phenomenon of the dry-mixed mortar is improved; meanwhile, when the circle center of the circular arc-shaped side wall of the stirring groove 21 on one stirring roller 2 coincides with the axis of the other stirring roller 2, and the other stirring roller 2 rotates, the periphery of the other stirring roller 2 is in sliding contact with the circular arc-shaped side wall of the stirring groove 21, and dry-mixed mortar attached to the side wall of the stirring groove 21 is scraped.

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 dry-mixed mortar prevents segregation storage cylinder which characterized in that includes:

the upper part of the cylinder body (1) is provided with a feed inlet (11), and the lower part is provided with a discharge outlet (12);

the stirring rollers (2) are arranged in the barrel body (1) in a side-by-side rotating mode, stirring grooves (21) are formed in the periphery of each stirring roller (2) at intervals along the circumferential direction, the side walls of the stirring grooves (21) are arc-shaped, and in two adjacent stirring rollers (2), a track circle swept by the circle center of the arc-shaped side wall of the stirring groove (21) on one stirring roller (2) coincides with the axis of the other stirring roller (2); and

and the driving assembly (3) is arranged on the barrel body (1) and used for driving the stirring rollers (2) to intermittently rotate, every two stirring rollers are adjacent to each other, one stirring roller (2) is driven to rotate to the axis of the side wall of the stirring groove (21) on the stirring roller (2) and the axis of the other stirring roller (2) to coincide, and the other stirring roller (2) is driven to rotate.

2. The dry-mixed mortar segregation-preventing storage cylinder as claimed in claim 1, wherein the drive assembly (3) comprises:

a driven plate (34) coaxially connected to the stirring roller (2);

the driven rods (345) are arranged and are equal to the number of the stirring grooves (21) in one stirring roller (2), the driven rods (345) are arranged at intervals along the circumferential direction of the driven disc (34), and the driven rods (345) are parallel to the axis of the driven disc (34) and are arranged on the driven disc (34) in an axially sliding manner;

the control disc (35) is arranged on the barrel (1) and is positioned on one axial side of the driven disc (34), the end face of the control disc (35) is used for being in sliding contact with one end of a driven rod (345) and enabling the other end of one driven rod (345) to extend out of the driven disc (34);

the driving rods (33) are provided with a plurality of driving rods, the number of the driving rods is equal to that of the driven disks (34), the driving rods (33) are rotatably arranged on the cylinder body (1), the rotating axes of the driving rods (33) are coaxially arranged with the corresponding driven disks (34), the driving rods (33) are perpendicular to the driven rods (345), and the peripheries of the driving rods (33) are used for abutting against the peripheries of the driven rods (345) at one ends far away from the control disk (35); and

and the motor (31) is used for driving the driving rod (33) to rotate.

3. The dry-mixed mortar segregation-preventing storage cylinder as claimed in claim 2, wherein: the axis of the control disc (35) is overlapped with the axis of the driven disc (34), a sliding groove (351) is formed in the end face, facing the driven disc (34), of the control disc (35), and the sliding groove (351) extends along the circumferential direction of the control disc (35) and is used for enabling the end portion of the driven rod (345) to be embedded in a sliding mode;

the driving assembly (3) further comprises a guide portion (361), the guide portion (361) is embedded in the sliding groove (351) and located at one end of the sliding groove (351) in the extending direction of the sliding groove, and the end face of the guide portion (361) faces the driven disc (34) and extends to the end face of the control disc (35) from the groove bottom of the sliding groove (351) and is used for being in sliding abutting connection with the end portion of the driven rod (345).

4. The dry-mixed mortar segregation-preventing storage cylinder as claimed in claim 3, wherein: the control panel (35) is provided with a caulking groove (352), the caulking groove (352) is communicated with a sliding groove (351), and the caulking groove (352) is used for the end face of the driven rod (345) to be embedded;

the drive assembly (3) further comprises:

the embedded spring (346), one end of the embedded spring (346) is connected with the driven disc (34), the other end of the embedded spring (346) is connected with the driven rod (345), and the embedded spring (346) enables the driven rod (345) to tightly abut against the control disc (35);

the disengaging block (362) is slidably embedded in the embedding groove (352), the end face of the disengaging block (362) is used for abutting against the end face of the driven rod (345), and the end face is used for aligning with the groove bottom of the sliding groove (351); and

and the driving piece is arranged on the control panel (35) and is used for driving the disengagement block (362) to move.

5. The dry-mixed mortar segregation-preventing storage cylinder as claimed in claim 4, wherein: an installation cavity (353) is formed in the control panel (35), the installation cavity (353) is communicated with the caulking groove (352), and the guide part (361) penetrates into the installation cavity (353) along the axial direction of the control panel (35);

the driving member includes:

the driving block (36) is arranged in the mounting cavity (353) in a sliding mode and slides along the axial direction of the control panel (35), the disengagement block (362) and the guide portion (361) are connected with the driving block (36), and when the end face of the disengagement block (362) is aligned with the bottom of the sliding groove (351), the guide portion (361) extends out of the sliding groove (351); and

the disengaging spring (37) is arranged in the mounting cavity (353), one end of the disengaging spring (37) is connected with the control disc (35), the other end of the disengaging spring is connected with the driving block (36), and the driving block (36) has a tendency of approaching to the driven disc (34);

and a stop ring (3451) is arranged on the driven rod (345), and when the stop ring (3451) abuts against the driven disc (34), the end part of the driven rod (345) abuts against the end surface of the control disc (35).

6. The dry-mixed mortar segregation-preventing storage cylinder as claimed in claim 5, wherein: the driven disc (34) is provided with abdicating grooves (341) at intervals along the circumferential direction;

the drive assembly (3) further comprises:

the sliding block (343) is slidably embedded in the receding groove (341) and slides along the circumferential direction of the driven disc (34), and the driven rod (345) penetrates through the sliding block (343);

and the abutting spring (344) is arranged in the yielding groove (341), one end of the abutting spring (344) is connected with the driven disc (34), and the other end of the abutting spring (344) is connected with the sliding block (343).

7. The dry-mixed mortar segregation-preventing storage cylinder as claimed in claim 2, wherein the drive assembly (3) further comprises:

the transmission mechanism (32) is arranged on the barrel body (1) and used for transmitting power between the motor (31) and the driving rods (33) and enabling the driving rods (33) to rotate synchronously.

8. The dry-mixed mortar segregation-preventing storage cylinder as claimed in claim 7, wherein: the periphery of arbitrary stirring roller (2) is equipped with four along circumference interval stirring groove (21), actuating lever (33) are equipped with two, two there is the contained angle between actuating lever (33), and this contained angle =180 ︒.

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