CN113953056B - Utilize inside quantity control of vibration response to smash complete cement manufacture equipment - Google Patents
Utilize inside quantity control of vibration response to smash complete cement manufacture equipment Download PDFInfo
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- CN113953056B CN113953056B CN202111140999.6A CN202111140999A CN113953056B CN 113953056 B CN113953056 B CN 113953056B CN 202111140999 A CN202111140999 A CN 202111140999A CN 113953056 B CN113953056 B CN 113953056B
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- movably connected
- vibration
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- block
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B02—CRUSHING, PULVERISING, OR DISINTEGRATING; PREPARATORY TREATMENT OF GRAIN FOR MILLING
- B02C—CRUSHING, PULVERISING, OR DISINTEGRATING IN GENERAL; MILLING GRAIN
- B02C19/00—Other disintegrating devices or methods
- B02C19/16—Mills provided with vibrators
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B02—CRUSHING, PULVERISING, OR DISINTEGRATING; PREPARATORY TREATMENT OF GRAIN FOR MILLING
- B02C—CRUSHING, PULVERISING, OR DISINTEGRATING IN GENERAL; MILLING GRAIN
- B02C23/00—Auxiliary methods or auxiliary devices or accessories specially adapted for crushing or disintegrating not provided for in preceding groups or not specially adapted to apparatus covered by a single preceding group
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- C—CHEMISTRY; METALLURGY
- C04—CEMENTS; CONCRETE; ARTIFICIAL STONE; CERAMICS; REFRACTORIES
- C04B—LIME, MAGNESIA; SLAG; CEMENTS; COMPOSITIONS THEREOF, e.g. MORTARS, CONCRETE OR LIKE BUILDING MATERIALS; ARTIFICIAL STONE; CERAMICS; REFRACTORIES; TREATMENT OF NATURAL STONE
- C04B7/00—Hydraulic cements
- C04B7/36—Manufacture of hydraulic cements in general
- C04B7/38—Preparing or treating the raw materials individually or as batches, e.g. mixing with fuel
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P40/00—Technologies relating to the processing of minerals
- Y02P40/10—Production of cement, e.g. improving or optimising the production methods; Cement grinding
Abstract
The invention relates to the technical field of architectural decoration, and provides cement production equipment capable of controlling complete crushing by utilizing vibration induction of internal quantity. This utilize inside quantity control of vibration response to smash complete cement manufacture equipment, the rotational speed of inner gear diminishes, the centrifugal force that the centrifugal plate received diminishes, centrifugal spring resets the centrifugal plate, the centrifugal plate diminishes the pan feeding mouth, constantly reduces inside limestone load, reduces along with the speed of adding the limestone, the increase of play powder volume, the load diminishes, smashes the ball and resumes to pound the dynamics of hitting, utilizes resonance to judge to pound the dynamics of hitting and reduce internal load gradually and make and smash completely.
Description
Technical Field
The invention relates to the technical field of architectural decoration, in particular to cement production equipment for controlling complete crushing by utilizing vibration induction of internal quantity.
Background
The cement is a common decorative material, has high strength after hardening, can resist erosion of fresh water and salt-containing water, is used as an important cementing material, and is widely applied to civil construction, water conservancy and national defense engineering.
In prior art, cement utilizes limestone to smash production, and the ball mill can smash the limestone, and the crushing speed of ball mill decides out the powder rate, and the speed that the ball mill was strikeed is not enough crushing effect incomplete, and bulky limestone can be plugged up the powder outlet, influences the lime powder and flows out, therefore a utilize inside quantity control of vibration induction smashes complete cement production equipment and deliver to come.
Disclosure of Invention
The invention aims to provide cement production equipment for controlling complete crushing by using vibration induction internal quantity so as to solve the problems in the background art.
To achieve the above object, the present invention provides the following technical solutions
The utility model provides an utilize inside quantity control of vibration response to smash complete cement manufacture equipment, includes the organism, the inside swing joint of organism has rubbing crusher to construct, and rubbing crusher's bottom swing joint has vibration mechanism, and the equal swing joint in the left and right sides of vibration mechanism has single mechanism, and vibration mechanism's top swing joint has the power of holding mechanism, and the top swing joint who holds the power of holding mechanism has knocking mechanism.
Further, rubbing crusher constructs including rotary drum, meal outlet and crushing ball, and the back fixedly connected with meal outlet of rotary drum, the inside swing joint of rotary drum has crushing ball, and the inside of rotary drum is equipped with the lime stone.
Further, the vibration mechanism includes vibrating mass, vibration spring, vibration mechanism, lever and rack plate, and the equal swing joint in upper and lower both sides of vibrating mass has the vibration spring, and the equal swing joint in the left and right sides of vibrating mass has the slide rail, and the equal swing joint in the left and right sides of vibration spring has the lever, and one side swing joint that the vibration spring was kept away from to the lever has the rack plate, and slide rail fixed mounting all is equipped with two and about vibrating mass central symmetry in the inside of organism, lever, vibration spring.
Further, the one-way mechanism includes external gear, pressure spring, fixture block, internal gear, swivel, centrifugal plate and centrifugal spring, and the inside swing joint of external gear has the pressure spring, and the surperficial swing joint of pressure spring has the fixture block, and the surperficial swing joint of fixture block has the internal gear, and the inside fixedly connected with swivel of internal gear, the inside swing joint of swivel has the centrifugal plate, and the surperficial swing joint of centrifugal plate has the centrifugal spring, and the back swing joint of centrifugal plate has the pan feeding mouth.
Furthermore, the power storage mechanism comprises an ejector rod, a top spring, a concave plate and a convex block, wherein the top of the ejector rod is movably connected with the top spring, the top of the top spring is movably connected with the concave plate, and the surface of the concave plate is movably connected with the convex block.
Furthermore, the knocking mechanism comprises a rotating block, a reciprocating clamp and a knocking head, the surface of the rotating block is movably connected with the reciprocating clamp, and the surface of the reciprocating clamp is fixedly connected with the knocking head.
Furthermore, the top of the vibrating block is movably connected with a rotating cylinder, the surface of the rack plate is movably connected with an outer gear, and the top of the rack plate is fixedly connected with an ejector rod.
Furthermore, the top of the bump is fixedly connected with a rotating block, a rolling ball is movably connected between the rotating block and the reciprocating clamp, the surface of the knocking head is movably connected with a powder outlet, and the rotating block and the knocking head are provided with two rotating blocks and are symmetrical about the center of the rotating cylinder.
Compared with the prior art, the invention has the following beneficial effects:
1. this utilize inside quantity control of vibration response to smash complete cement manufacture equipment, it removes to drive crushing ball through the rotary drum rotation, crushing ball smashes the lime stone, when crushing ball is not enough to the power of pounding of lime stone, the vibration that crushing ball pounded and hit the arouses diminishes, the resonant frequency of vibrating mass diminishes, the vibrating spring control vibrating mass constantly vibrates, the vibrating mass utilizes the position of lever adjustment rack board, rack board drives the external gear and rotates, because the existence of pressure spring and fixture block external gear clockwise rotation can't drive the internal gear and rotate, the external gear anticlockwise rotation drives the internal gear, increase the required vibration frequency of internal gear rotation, when the vibration frequency is not enough, the rotational speed of internal gear diminishes, the centrifugal force that the centrifugal plate received diminishes, centrifugal spring resets the centrifugal plate, the centrifugal plate diminishes the pan feeding mouth, constantly reduce the inside lime stone load, along with the speed that adds the lime stone reduces, the increase of powder output, the load diminishes, crushing ball resumes to pound the power, thereby realize utilizing resonance to judge to pound the power and reduce the inside load gradually and make and smash complete effect.
2. This utilize inside quantity control of vibration response to smash complete cement manufacture equipment, drive the ejector pin when moving through the rack board, the ejector pin utilizes the top spring to pass the concave plate, the concave plate is controlled by the lug, lug increase concave plate removes required thrust, the thrust of ejector pin is enough, the concave plate just can remove, the concave plate drives the commentaries on classics piece rotation, change the piece and reciprocal double-layered combined action messenger and strike first reciprocating motion, strike the head and constantly strike to a powder mouth, prevent that a powder mouth from being plugged up by incomplete kibbling lime stone, thereby realize vibrating the garrulous effect of remaining incomplete lime stone and preventing to influence a powder through rate.
Drawings
FIG. 1 is a schematic front view of the body structure of the present invention;
FIG. 2 is a schematic front view of the vibrating mechanism of the present invention;
FIG. 3 is a schematic front view of the one-way mechanism of the present invention;
FIG. 4 is a front view of the power storage mechanism of the present invention;
FIG. 5 is a front view of the knocking mechanism of the present invention.
In the figure: 1. a body; 2. a crushing mechanism; 21. a rotating drum; 22. a powder outlet; 23. crushing the balls; 3. A vibration mechanism; 31. vibrating the block; 32. a vibrating spring; 33. a slide rail; 34. a lever; 35. a rack plate; 4. a one-way mechanism; 41. an outer gear; 42. compressing the spring; 43. a clamping block; 44. an internal gear; 45. rotating the ring; 46. A centrifugal plate; 47. a centrifugal spring; 5. a force storage mechanism; 51. a top rod; 52. a spring is supported; 53. a concave plate; 54. A bump; 6. a knocking mechanism; 61. rotating the block; 62. carrying out reciprocating clamping; 63. a knocking head.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
The first embodiment is as follows:
referring to fig. 1 and 3, a cement production equipment capable of controlling complete crushing by using vibration to sense internal quantity comprises a machine body 1, wherein the inside of the machine body 1 is movably connected with a crushing mechanism 2, the bottom of the crushing mechanism 2 is movably connected with a vibration mechanism 3, the left side and the right side of the vibration mechanism 3 are respectively movably connected with a one-way mechanism 4, the top of the vibration mechanism 3 is movably connected with a force storage mechanism 5, and the top of the force storage mechanism 5 is movably connected with a knocking mechanism 6.
Further, the one-way mechanism 4 includes an external gear 41, a pressure spring 42, a fixture block 43, an internal gear 44, a rotary ring 45, a centrifugal plate 46 and a centrifugal spring 47, the internal portion of the external gear 41 is movably connected with the pressure spring 42, the surface of the pressure spring 42 is movably connected with the fixture block 43, the surface of the fixture block 43 is movably connected with the internal gear 44, the internal portion of the internal gear 44 is fixedly connected with the rotary ring 45, the internal portion of the rotary ring 45 is movably connected with the centrifugal plate 46, and the surface of the centrifugal plate 46 is movably connected with the centrifugal spring 47.
Existence through pressure spring 42 and fixture block 43 outer gear 41 clockwise rotation can't drive inner gear 44 rotatory, outer gear 41 anticlockwise rotation drives inner gear 44, increase the rotatory required vibration frequency of inner gear 44, when vibration frequency is not enough, inner gear 44's rotational speed diminishes, centrifugal force that centrifugal plate 46 received diminishes, centrifugal spring 47 resets centrifugal plate 46, centrifugal plate 46 diminishes the pan feeding mouth, constantly reduce inside limestone load, along with the speed that adds the limestone reduces, the increase of powder output volume, the load diminishes, crushing ball 23 resumes to pound the power of hitting, utilize resonance to judge to pound the power of hitting and reduce inside load gradually and make and smash completely.
Example two:
referring to fig. 1 and 4, a cement production device capable of controlling complete crushing by sensing internal quantity through vibration comprises a machine body 1, wherein a crushing mechanism 2 is movably connected inside the machine body 1, a vibration mechanism 3 is movably connected to the bottom of the crushing mechanism 2, one-way mechanisms 4 are movably connected to the left side and the right side of the vibration mechanism 3, a force storage mechanism 5 is movably connected to the top of the vibration mechanism 3, and a knocking mechanism 6 is movably connected to the top of the force storage mechanism 5.
Further, the power storage mechanism 5 comprises a top rod 51, a top spring 52, a concave plate 53 and a convex block 54, wherein the top of the top rod 51 is movably connected with the top spring 52, the top of the top spring 52 is movably connected with the concave plate 53, and the surface of the concave plate 53 is movably connected with the convex block 54.
Utilize ejector pin 51 to push away concave plate 53 through spring 52, concave plate 53 is controlled by lug 54, lug 54 increases concave plate 53 and removes required thrust, ejector pin 51's thrust is enough, concave plate 53 just can remove, concave plate 53 drives and changes the rotation of piece 61, change piece 61 and reciprocal clamp 62 combined action make and strike head 63 reciprocating motion, strike head 63 and constantly strike powder outlet 22, prevent that powder outlet 22 from being blockked up by incomplete kibbling limestone, shake garrulous incomplete limestone of remaining and prevent to influence the powder through rate.
EXAMPLE III
Referring to fig. 1-5, a cement production equipment utilizing vibration induction to control the internal quantity to completely crush comprises a machine body 1, a crushing mechanism 2 is movably connected in the machine body 1, the crushing mechanism 2 comprises a rotary drum 21, a powder outlet 22 and crushing balls 23, the back of the rotary drum 21 is fixedly connected with the powder outlet 22, the inner part of the rotary drum 21 is movably connected with the crushing balls 23, the bottom of the crushing mechanism 2 is movably connected with a vibrating mechanism 3, the vibrating mechanism 3 comprises a vibrating block 31, a vibrating spring 32, the vibrating mechanism 3, a lever 34 and a rack plate 35, the upper side and the lower side of the vibrating block 31 are both movably connected with the vibrating spring 32, the top of the vibrating block 31 is movably connected with the rotary drum 21, the surface of the rack plate 35 is movably connected with an outer gear 41, the top of the rack plate 35 is fixedly connected with an ejector rod 51, the left side and the right side of the vibrating block 31 are both movably connected with a slide rail 33, and the left side and the right side of the vibrating spring 32 are both movably connected with the lever 34, one side of the lever 34 far away from the vibrating spring 32 is movably connected with a rack plate 35, the left side and the right side of the vibrating mechanism 3 are movably connected with a one-way mechanism 4, the one-way mechanism 4 comprises an external gear 41, a pressure spring 42, a clamping block 43, an internal gear 44, a rotating ring 45, a centrifugal plate 46 and a centrifugal spring 47, the internal part of the external gear 41 is movably connected with the pressure spring 42, the surface of the pressure spring 42 is movably connected with the clamping block 43, the surface of the clamping block 43 is movably connected with the internal gear 44, the internal part of the internal gear 44 is fixedly connected with the rotating ring 45, the internal part of the rotating ring 45 is movably connected with the centrifugal plate 46, the surface of the centrifugal plate 46 is movably connected with the centrifugal spring 47, the top of the vibrating mechanism 3 is movably connected with a force storage mechanism 5, the force storage mechanism 5 comprises a mandril 51, a jacking spring 52, a concave plate 53 and a convex block 54, the top of the mandril 51 is movably connected with the jacking spring 52, the surface swing joint of concave plate 53 has lug 54, the top fixedly connected with of lug 54 changes the piece 61, swing joint has the spin between piece 61 and the reciprocal clamp 62, the surface swing joint that strikes head 63 has powder outlet 22, the top swing joint that holds power mechanism 5 has striking mechanism 6, striking mechanism 6 includes changes piece 61, reciprocal clamp 62 and strikes head 63, the surface swing joint that changes piece 61 has reciprocal clamp 62, the fixed surface of reciprocal clamp 62 is connected with strikes head 63.
When the limestone pulverizer is used, firstly, the rotary drum 21 rotates to drive the grinding ball 23 to move, the grinding ball 23 grinds limestone, when the hitting power of the grinding ball 23 on limestone is insufficient, vibration caused by hitting of the grinding ball 23 is reduced, the resonance frequency of the vibrating block 31 is reduced, the vibrating spring 32 controls the vibrating block 31 to vibrate continuously, the vibrating block 31 adjusts the position of the rack plate 35 through the lever 34, the rack plate 35 drives the outer gear 41 to rotate, the outer gear 41 cannot drive the inner gear 44 to rotate clockwise due to the existence of the pressure spring 42 and the fixture block 43, the outer gear 41 drives the inner gear 44 to rotate anticlockwise, and the vibration frequency required by rotation of the inner gear 44 is increased.
Then, when the vibration frequency is insufficient, the rotating speed of the internal gear 44 is reduced, the centrifugal force applied to the centrifugal plate 46 is reduced, the centrifugal spring 47 resets the centrifugal plate 46, the feed inlet of the centrifugal plate 46 is reduced, the internal limestone load is reduced continuously, the powder output amount is increased along with the reduction of the limestone adding speed, the load is reduced, the smashing ball 23 recovers the smashing force, and the internal load is reduced gradually by utilizing the resonance judgment of the smashing force and the smashing is completed.
Finally, the rack plate 35 drives the ejector rod 51 while moving, the ejector rod 51 pushes the concave plate 53 by using the ejector spring 52, the concave plate 53 is controlled by the convex block 54, the convex block 54 increases the thrust required by the movement of the concave plate 53, the thrust of the ejector rod 51 is enough, the concave plate 53 can move, the concave plate 53 drives the rotating block 61 to rotate, the rotating block 61 and the reciprocating clamp 62 jointly act to enable the knocking head 63 to reciprocate, the knocking head 63 continuously knocks the powder outlet 22, the powder outlet 22 is prevented from being blocked by incompletely crushed limestone, the incompletely crushed limestone is vibrated, and the passing rate of the powder is prevented from being influenced.
It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising a … …" does not exclude the presence of another identical element in a process, method, article, or apparatus that comprises the element.
Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that various changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.
Claims (1)
1. The utility model provides an utilize inside quantity control of vibration response to smash complete cement manufacture equipment, includes organism (1), its characterized in that: the crushing mechanism (2) is movably connected inside the machine body (1), the bottom of the crushing mechanism (2) is movably connected with a vibration mechanism (3), the left side and the right side of the vibration mechanism (3) are movably connected with one-way mechanisms (4), the top of the vibration mechanism (3) is movably connected with a force storage mechanism (5), and the top of the force storage mechanism (5) is movably connected with a knocking mechanism (6);
the crushing mechanism (2) comprises a rotary drum (21), a powder outlet (22) and crushing balls (23), the back surface of the rotary drum (21) is fixedly connected with the powder outlet (22), and the inside of the rotary drum (21) is movably connected with the crushing balls (23); the vibration mechanism (3) comprises a vibration block (31), a vibration spring (32), a vibration mechanism (3), a lever (34) and a rack plate (35), wherein the vibration spring (32) is movably connected to the upper side and the lower side of the vibration block (31), slide rails (33) are movably connected to the left side and the right side of the vibration block (31), the lever (34) is movably connected to the left side and the right side of the vibration spring (32), and the rack plate (35) is movably connected to one side, away from the vibration spring (32), of the lever (34); the one-way mechanism (4) comprises an external gear (41), a pressure spring (42), a clamping block (43), an internal gear (44), a rotating ring (45), a centrifugal plate (46) and a centrifugal spring (47), wherein the internal part of the external gear (41) is movably connected with the pressure spring (42), the surface of the pressure spring (42) is movably connected with the clamping block (43), the surface of the clamping block (43) is movably connected with the internal gear (44), the internal part of the internal gear (44) is fixedly connected with the rotating ring (45), the internal part of the rotating ring (45) is movably connected with the centrifugal plate (46), and the surface of the centrifugal plate (46) is movably connected with the centrifugal spring (47); the force storage mechanism (5) comprises an ejector rod (51), a top spring (52), a concave plate (53) and a convex block (54), wherein the top of the ejector rod (51) is movably connected with the top spring (52), the top of the top spring (52) is movably connected with the concave plate (53), and the surface of the concave plate (53) is movably connected with the convex block (54);
the knocking mechanism (6) comprises a rotating block (61), a reciprocating clamp (62) and a knocking head (63), the surface of the rotating block (61) is movably connected with the reciprocating clamp (62), and the surface of the reciprocating clamp (62) is fixedly connected with the knocking head (63);
the top of the vibrating block (31) is movably connected with a rotating drum (21), the surface of the rack plate (35) is movably connected with an external gear (41), and the top of the rack plate (35) is fixedly connected with an ejector rod (51);
the top of the bump (54) is fixedly connected with a rotating block (61), a rolling ball is movably connected between the rotating block (61) and the reciprocating clamp (62), and the surface of the knocking head (63) is movably connected with a powder outlet (22);
when the limestone crusher is used, firstly, the rotary drum (21) rotates to drive the crushing ball (23) to move, the crushing ball (23) crushes limestone, when the smashing force of the crushing ball (23) on the limestone is insufficient, vibration caused by smashing of the crushing ball (23) is reduced, the resonance frequency of the vibrating block (31) is reduced, the vibrating spring (32) controls the vibrating block (31) to vibrate continuously, the vibrating block (31) adjusts the position of the rack plate (35) through the lever (34), the rack plate (35) drives the outer gear (41) to rotate, the outer gear (41) cannot be driven to rotate when the outer gear (41) rotates clockwise due to the existence of the pressure spring (42) and the fixture block (43), and the inner gear (44) can be driven to rotate only when the outer gear (41) rotates anticlockwise;
then, when the vibration frequency is insufficient, the rotating speed of the internal gear (44) is reduced, the centrifugal force borne by the centrifugal plate (46) is reduced, the centrifugal spring (47) resets the centrifugal plate (46), after the centrifugal plate (46) resets, the feed inlet is reduced, the load weight of the limestone in the limestone is continuously reduced, the load is reduced along with the reduction of the limestone adding speed, the powder output amount is increased, and the smashing force of the smashing ball (23) is restored;
finally, the rack plate (35) moves while driving the ejector rod (51), the ejector rod (51) pushes the concave plate (53) through the ejector spring (52), the concave plate (53) is limited by the convex block (54), the convex block (54) increases the thrust required by the movement of the concave plate (53), only when the thrust of the ejector rod (51) is large enough, the concave plate (53) can move, the concave plate (53) moves to drive the rotating block (61) to rotate, the rotating block (61) and the reciprocating clamp (62) act together to enable the knocking head (63) to move in a reciprocating mode, the knocking head (63) continuously knocks the powder outlet (22), and the powder outlet (22) is prevented from being blocked by incompletely crushed limestone.
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| CN202111140999.6A CN113953056B (en) | 2021-09-28 | 2021-09-28 | Utilize inside quantity control of vibration response to smash complete cement manufacture equipment |
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